Physics Lab Equipment
Pioneers in the industry, we offer physics lab equipment school experiment kits complete teaching tools colleges, silicon electronic configuration school project model, windmill working model, mutual induction model, oersted law apparatus model and dc dc power supply from India.
Physics Lab Equipment School Experiment Kits Complete Teaching Tools Colleges
Request Callback
₹ 1000 / Piece Get Latest Price
| Usage/Application | schoo coleege university iti polytechnic laboratory |
| Model Name/Number | ASINTPHY1 |
| Material | various metal wood plastic acrylic foam glass |
| Packaging Type | In carton and kit packagin in plastic wooden or metal boxes |
| Color | Steel grey white red blue |
| Size | 30 inches |
| Brand | ASIntl |
| Country of Origin | Made in India |
Minimum order quantity: 1 Piece
Physics Lab Equipment | School Physics Equipment | Physics Experiment Kits | Complete Physics Teaching Tools for Schools & Colleges ��
We are leading manufacturers and exporters of complete Physics Lab Equipment, School Physics Kits, and Experimental Apparatus for middle school, secondary school, higher secondary, engineering, and university-level laboratories.
Our products are designed to align with CBSE, ICSE, State Boards, NCERT, and International Curricula (IGCSE, IB, Cambridge) with practical, interactive, and conceptual learning in mind.
✅ Complete Range of Physics Lab Equipment Includes:-
Mechanics Equipment:
Inclined Plane, Pulley Sets, Lever Apparatus, Parallelogram of Forces, Friction Board, Ballistic Pendulum, Atwood Machine, Flywheel, Newton’s Cradle, Moment of Inertia Kit -
Optics Equipment:
Optical Bench, Lenses & Mirrors Set, Ray Box, Prism, Diffraction Grating, Plane Mirror, Concave/Convex Mirror, Glass Slab, Spectrometer, Polarimeter -
Heat & Thermodynamics:
Calorimeter, Thermometer, Thermal Conductivity Apparatus, Expansion of Solids & Liquids, Boyle's Law Apparatus, Charles Law Apparatus, Jolly’s Bulb, Newton's Law of Cooling -
Electricity & Magnetism:
Rheostat, Galvanometer, Ammeter, Voltmeter, Ohm’s Law Apparatus, Electric Bell, Electromagnet, Magnetic Needle, Solenoid, Electric Circuit Boards, Wheatstone Bridge, Potentiometer -
Waves & Sound:
Tuning Fork Set, Resonance Tube, Kundt’s Tube, Sonometer, Sound Level Meter, Microphone and Loudspeaker Kit, Oscilloscope for Waveform Analysis -
Modern Physics:
Photoelectric Effect Apparatus, Planck's Constant Apparatus, PN Junction Diodes, Transistor Characteristics, CRO, GM Counter, Hall Effect, Millikan’s Oil Drop Apparatus -
Measurement Tools:
Vernier Caliper, Screw Gauge, Meter Scale, Stopwatch, Pendulum, Spirit Level, Travelling Microscope, Spherometer, Spring Balance -
Electric Circuits & Accessories:
Switches, Breadboard, Resistor & Capacitor Banks, Connecting Wires, DC & AC Power Supply, Function Generator, LED Modules -
Physics Experiment Kits (Class 6 to 12):
Readymade kits covering Newton's Laws, Energy Transformation, Magnetism, Light, Force & Motion, Simple Machines, Electromagnetic Induction, and Circuit Design -
STEM & DIY Physics Kits:
Hands-on kits for science exhibitions, CBSE project work, Olympiad preparation, and NEP-based activity kits -
Complete Lab Setups:
Pre-configured Physics Lab setups with lab manuals, experiment kits, workbenches, and demonstration charts for 30 students per batch
Physics Practical Kit, Physics Lab Apparatus, High School Physics Equipment, College Physics Experiments, CBSE Practical Physics Kit, Optical Instruments, Electrical Instruments, Magnetism Apparatus, Physics STEM Kits, CBSE Physics Practical, Physics Project Kits, IndiaMART Physics Supplier, Scientific Educational Equipment, Physics Laboratory Furniture, Physics Teaching Models, Export Quality Physics Instruments, Buy Physics Kits Online India, Bulk Physics Kit Supplier
Silicon Electronic Configuration School Project Model
Request Callback
₹ 1400 / Piece Get Latest Price
| Material | Silicon |
| Kit Required | No |
| Model Type | 2D Model |
| Country of Origin | Made in India |
| Color | White |
| Shape | Square |
| Size | 10 x 10 Inch |
Minimum order quantity: 100 Piece
The Silicon Electronic Configuration School Project Model is an educational and visually engaging tool designed to help students understand the atomic structure and electron arrangement of the element silicon. Constructed using high-quality materials, this model offers a clear and interactive representation of the electronic configuration of silicon, making it ideal for science exhibitions, classroom demonstrations, and self-guided learning projects. With its compact 10 x 10 inch square shape and clean white color, the model provides a structured and easy-to-follow layout for students to grasp the abstract concepts of atomic structure, sub-shell filling, and electron distribution.
This working model focuses specifically on silicon, a vital element in the periodic table with the atomic number 14. The model effectively illustrates how the 14 electrons of a silicon atom are arranged across different energy levels and orbitals. It displays the classic electronic configuration of silicon as 2, 8, 4, demonstrating that the element has two electrons in the first shell, eight in the second, and four in the third shell. This configuration is essential for students to understand silicon’s chemical properties, bonding behavior, and significance in the field of semiconductors and electronics.
Designed for school-level science education, the Silicon Electronic Configuration Model is both sturdy and lightweight, ensuring durability while being easy to handle during demonstrations or exhibitions. Its white surface provides a clear background that enhances the visibility of the orbitals and electron positions, allowing teachers and students to interact with the model without confusion. The use of contrasting indicators to represent electrons makes it easier to differentiate between shells and visualize the gradual filling of orbitals according to the Aufbau principle, Pauli exclusion principle, and Hund’s rule.
The educational value of this model extends beyond just showing electron placement. It serves as a gateway for discussing atomic theory, chemical bonding, valency, and periodic trends. Teachers can use the model to explain how silicon forms covalent bonds by sharing its four valence electrons and why it is a crucial element in forming complex compounds such as silicon dioxide (SiO₂) and silicones. Additionally, students are able to relate this knowledge to real-world applications in electronics, where silicon is widely used in integrated circuits and photovoltaic cells due to its semiconductor properties.
With its square layout and labeled structure, the model encourages visual learning and improves retention of concepts related to atomic structure and periodic classification. It fits seamlessly into school curriculums for classes ranging from middle to senior secondary levels. Its simplicity and clarity make it especially suitable for younger students who are being introduced to atomic models for the first time, while its technical accuracy ensures that it remains a reliable reference for advanced learners as well.
In conclusion, the Silicon Electronic Configuration School Project Model is a valuable resource for enriching science education. It simplifies complex scientific concepts into a hands-on, engaging, and visually appealing format that helps students gain a solid foundation in chemistry and atomic theory. Its thoughtful design, durability, and educational relevance make it an ideal teaching aid for classrooms, science fairs, and educational displays focused on the structure and behavior of atoms, particularly silicon.
This working model focuses specifically on silicon, a vital element in the periodic table with the atomic number 14. The model effectively illustrates how the 14 electrons of a silicon atom are arranged across different energy levels and orbitals. It displays the classic electronic configuration of silicon as 2, 8, 4, demonstrating that the element has two electrons in the first shell, eight in the second, and four in the third shell. This configuration is essential for students to understand silicon’s chemical properties, bonding behavior, and significance in the field of semiconductors and electronics.
Designed for school-level science education, the Silicon Electronic Configuration Model is both sturdy and lightweight, ensuring durability while being easy to handle during demonstrations or exhibitions. Its white surface provides a clear background that enhances the visibility of the orbitals and electron positions, allowing teachers and students to interact with the model without confusion. The use of contrasting indicators to represent electrons makes it easier to differentiate between shells and visualize the gradual filling of orbitals according to the Aufbau principle, Pauli exclusion principle, and Hund’s rule.
The educational value of this model extends beyond just showing electron placement. It serves as a gateway for discussing atomic theory, chemical bonding, valency, and periodic trends. Teachers can use the model to explain how silicon forms covalent bonds by sharing its four valence electrons and why it is a crucial element in forming complex compounds such as silicon dioxide (SiO₂) and silicones. Additionally, students are able to relate this knowledge to real-world applications in electronics, where silicon is widely used in integrated circuits and photovoltaic cells due to its semiconductor properties.
With its square layout and labeled structure, the model encourages visual learning and improves retention of concepts related to atomic structure and periodic classification. It fits seamlessly into school curriculums for classes ranging from middle to senior secondary levels. Its simplicity and clarity make it especially suitable for younger students who are being introduced to atomic models for the first time, while its technical accuracy ensures that it remains a reliable reference for advanced learners as well.
In conclusion, the Silicon Electronic Configuration School Project Model is a valuable resource for enriching science education. It simplifies complex scientific concepts into a hands-on, engaging, and visually appealing format that helps students gain a solid foundation in chemistry and atomic theory. Its thoughtful design, durability, and educational relevance make it an ideal teaching aid for classrooms, science fairs, and educational displays focused on the structure and behavior of atoms, particularly silicon.
Windmill Working Model
Request Callback
₹ 450 / Piece Get Latest Price
| Material | Plastic |
| Project Subject | Science |
| Kit Required | No |
| Model Type | Working Model |
| Country of Origin | Made in India |
| Size | 10 Inch (Height) |
| Finish | Polished |
Minimum order quantity: 1 Piece
The Windmill Working Model made of high-quality plastic is a dynamic educational tool designed to enhance science learning through hands-on experimentation and visual demonstration. This 10-inch tall windmill model is perfectly suited for classroom science projects, exhibitions, and STEM learning modules. Constructed with durable materials and polished to a smooth finish, this windmill stands on a sturdy black base, featuring a vibrant orange tower and green rotating blades that capture attention and clearly illustrate the core principle of wind energy conversion. The integrated motor further elevates the learning experience by allowing students to witness how wind power can be transformed into mechanical energy, making the model both engaging and informative.
This science working model is a popular choice for educators and students who aim to understand renewable energy systems in a simplified and interactive manner. It accurately demonstrates the functionality of wind turbines, including the basic mechanics of how wind rotation activates the blades, which in turn generates power through the motor. Ideal for middle school and high school levels, this model helps reinforce key curriculum topics like energy conversion, sustainability, environmental science, and electricity generation. The presence of a working motor makes it particularly impactful, offering real-time insights into the application of green technology in daily life and future energy solutions.
The plastic used in this windmill model is non-toxic, lightweight, and child-safe, making it ideal for frequent classroom handling. Its polished finish ensures resistance to wear and tear while maintaining a sleek, attractive appearance throughout multiple uses. The vibrant color scheme of black, orange, and green not only makes the model visually appealing but also helps students easily identify the different components such as the base, tower, and rotator blades. The motor is securely attached to provide steady operation, simulating the function of a real wind turbine when exposed to airflow or manually rotated, allowing students to experiment with different energy inputs and outputs.
This Windmill Working Model is also an excellent choice for science fairs and school exhibitions where students are expected to present practical projects that align with themes like renewable energy, environmental awareness, or mechanical systems. It can be used as a core part of an extended project presentation, where students can add electrical circuits, bulbs, or sensors to demonstrate the energy produced. The model encourages active learning, critical thinking, and innovation, making it a must-have teaching aid for science teachers looking to integrate experiential learning into their classroom activities.
On IndiaMART, this Windmill Working Model is a widely searched and highly rated educational product due to its practicality, design, and effective demonstration capability. Schools, coaching institutes, and individual learners frequently purchase this model for its versatility in explaining renewable energy concepts. It is also in demand by science project kit suppliers and educators seeking reliable and ready-to-use classroom resources. The compact size of 10 inches makes it easy to store and transport, while the robust plastic construction ensures long-lasting use even under frequent demonstrations.
This science working model is a popular choice for educators and students who aim to understand renewable energy systems in a simplified and interactive manner. It accurately demonstrates the functionality of wind turbines, including the basic mechanics of how wind rotation activates the blades, which in turn generates power through the motor. Ideal for middle school and high school levels, this model helps reinforce key curriculum topics like energy conversion, sustainability, environmental science, and electricity generation. The presence of a working motor makes it particularly impactful, offering real-time insights into the application of green technology in daily life and future energy solutions.
The plastic used in this windmill model is non-toxic, lightweight, and child-safe, making it ideal for frequent classroom handling. Its polished finish ensures resistance to wear and tear while maintaining a sleek, attractive appearance throughout multiple uses. The vibrant color scheme of black, orange, and green not only makes the model visually appealing but also helps students easily identify the different components such as the base, tower, and rotator blades. The motor is securely attached to provide steady operation, simulating the function of a real wind turbine when exposed to airflow or manually rotated, allowing students to experiment with different energy inputs and outputs.
This Windmill Working Model is also an excellent choice for science fairs and school exhibitions where students are expected to present practical projects that align with themes like renewable energy, environmental awareness, or mechanical systems. It can be used as a core part of an extended project presentation, where students can add electrical circuits, bulbs, or sensors to demonstrate the energy produced. The model encourages active learning, critical thinking, and innovation, making it a must-have teaching aid for science teachers looking to integrate experiential learning into their classroom activities.
On IndiaMART, this Windmill Working Model is a widely searched and highly rated educational product due to its practicality, design, and effective demonstration capability. Schools, coaching institutes, and individual learners frequently purchase this model for its versatility in explaining renewable energy concepts. It is also in demand by science project kit suppliers and educators seeking reliable and ready-to-use classroom resources. The compact size of 10 inches makes it easy to store and transport, while the robust plastic construction ensures long-lasting use even under frequent demonstrations.
Mutual Induction Model
Request Callback
₹ 2900 / Piece Get Latest Price
| Material | Plastic |
| Kit Required | Yes |
| Model Type | Working Model |
| Country of Origin | Made in India |
| Color | Beige |
| Thickness | 4mm |
Minimum order quantity: 1 Piece
The Mutual Induction Model is a highly effective educational tool designed to demonstrate the fundamental principle of electromagnetic induction between two coils—an essential concept in physics and electrical engineering. Constructed from durable plastic, the model has been thoughtfully developed to simplify the understanding of mutual induction, which occurs when a changing current in the primary coil induces a current in the secondary coil. This working model is an ideal addition to school laboratories, science exhibitions, and technical training institutes, especially for students in higher secondary and early undergraduate courses.
This mutual induction apparatus clearly showcases the interaction between a mains-powered primary coil and a secondary coil. The entire setup is mounted on a sturdy beige-colored plastic base with a 4mm thickness, ensuring both stability and longevity. The model is equipped with an LED indicator that lights up when a voltage is successfully induced in the secondary coil, providing instant visual feedback to help users understand the concept of energy transfer through electromagnetic fields. The inclusion of the LED output indicator enhances the learning experience by offering an interactive and demonstrative approach to a concept that is often considered abstract when taught purely through theory.
The Mutual Induction Model includes a plug wire integrated into the setup, allowing the system to be conveniently connected to a mains power supply. This feature simplifies the demonstration process and removes the need for separate power sources, making it highly accessible in a classroom environment. Once connected to power, current flows through the primary coil, generating a magnetic field. As the magnetic field varies, it induces a current in the nearby secondary coil, which is evidenced by the illumination of the LED. This simple yet effective visual cue enables students to grasp the principle of electromagnetic induction without the need for complex instrumentation or mathematical calculations.
Designed with user-friendly components, this model is both safe and easy to operate under supervised educational conditions. The layout of the components mimics a real-life transformer circuit, providing a practical perspective on how mutual induction is used in everyday electrical devices. This makes it an excellent hands-on teaching aid for explaining the functionality of transformers, which play a vital role in power transmission and voltage regulation. Furthermore, the kit required for this model includes all necessary components, ensuring seamless classroom integration without the need for additional purchases.
The model is highly suitable for curriculum-based demonstrations and helps students visualize how alternating current in one coil can induce electromotive force in another, even without direct contact. This reinforces the principle that electricity and magnetism are interrelated, forming the foundation of many modern electrical technologies. The presence of visible coils, labeled connections, and a clearly functioning LED light all contribute to making the learning process intuitive and engaging. Its lightweight, plastic build also ensures that the model is portable, allowing it to be easily transported for use in different classrooms or external educational events.
The Mutual Induction Model serves not only as a demonstrative device but also as a discussion starter, encouraging students to explore related concepts such as Faraday’s Law, Lenz’s Law, and real-world transformer design. It promotes experiential learning, helping students move beyond textbook definitions to experience how electromagnetic induction operates in practice.
This mutual induction apparatus clearly showcases the interaction between a mains-powered primary coil and a secondary coil. The entire setup is mounted on a sturdy beige-colored plastic base with a 4mm thickness, ensuring both stability and longevity. The model is equipped with an LED indicator that lights up when a voltage is successfully induced in the secondary coil, providing instant visual feedback to help users understand the concept of energy transfer through electromagnetic fields. The inclusion of the LED output indicator enhances the learning experience by offering an interactive and demonstrative approach to a concept that is often considered abstract when taught purely through theory.
The Mutual Induction Model includes a plug wire integrated into the setup, allowing the system to be conveniently connected to a mains power supply. This feature simplifies the demonstration process and removes the need for separate power sources, making it highly accessible in a classroom environment. Once connected to power, current flows through the primary coil, generating a magnetic field. As the magnetic field varies, it induces a current in the nearby secondary coil, which is evidenced by the illumination of the LED. This simple yet effective visual cue enables students to grasp the principle of electromagnetic induction without the need for complex instrumentation or mathematical calculations.
Designed with user-friendly components, this model is both safe and easy to operate under supervised educational conditions. The layout of the components mimics a real-life transformer circuit, providing a practical perspective on how mutual induction is used in everyday electrical devices. This makes it an excellent hands-on teaching aid for explaining the functionality of transformers, which play a vital role in power transmission and voltage regulation. Furthermore, the kit required for this model includes all necessary components, ensuring seamless classroom integration without the need for additional purchases.
The model is highly suitable for curriculum-based demonstrations and helps students visualize how alternating current in one coil can induce electromotive force in another, even without direct contact. This reinforces the principle that electricity and magnetism are interrelated, forming the foundation of many modern electrical technologies. The presence of visible coils, labeled connections, and a clearly functioning LED light all contribute to making the learning process intuitive and engaging. Its lightweight, plastic build also ensures that the model is portable, allowing it to be easily transported for use in different classrooms or external educational events.
The Mutual Induction Model serves not only as a demonstrative device but also as a discussion starter, encouraging students to explore related concepts such as Faraday’s Law, Lenz’s Law, and real-world transformer design. It promotes experiential learning, helping students move beyond textbook definitions to experience how electromagnetic induction operates in practice.
Oersted Law Apparatus Model
Request Callback
₹ 497 / Piece Get Latest Price
| Material | Stainless Steel |
| Project Subject | Physics |
| Model Type | Working Model |
| Recommended Class | 9-12 |
| Subject | Physics |
| Topic | Basic Principles of Electromagnetism, Magnetic fields, and Rotational motion |
| Usage | Educational & learning purpose |
Minimum order quantity: 1 Piece
The Physics Oersted Law Apparatus Model is a highly effective educational tool designed to demonstrate the fundamental principles of electromagnetism in a clear and interactive manner. Made from high-quality stainless steel, this working model offers durability, precision, and long-term usability, making it ideal for classrooms, laboratories, and educational institutions. It is specifically developed to illustrate Oersted’s Law, which shows the relationship between electricity and magnetism by revealing how an electric current passing through a conductor generates a magnetic field around it. This hands-on apparatus provides students from classes 9 to 12 with a visual and practical understanding of one of the most essential concepts in physics.
The apparatus typically includes a straight conducting wire connected to a battery or power source, positioned parallel to a freely suspended magnetic needle or compass. When the current flows through the conductor, the magnetic needle deflects, effectively demonstrating the magnetic field created around the conductor. This deflection offers tangible proof of Oersted’s discovery and serves as a foundational experiment for students to grasp the basic principles of electromagnetism and its real-world applications. Such a setup not only reinforces theoretical learning but also engages students by allowing them to observe the direct impact of electric current on magnetic orientation.
Constructed with a stainless steel frame, the apparatus is corrosion-resistant and easy to maintain. The non-reactive nature of the material ensures safety during experiments, especially when the equipment is used repeatedly in laboratory conditions. The build quality allows for precise measurements and consistent results, enabling accurate observations and experimental learning. The model is compact, portable, and suitable for individual as well as group demonstrations, making it a versatile teaching aid for educators and laboratory instructors.
Designed with both functionality and ease of use in mind, the Oersted Law Apparatus can be assembled and operated effortlessly by students under guided supervision. It allows learners to adjust the current, observe changes in magnetic field direction, and record varying degrees of deflection, helping them draw meaningful conclusions about electromagnetic behavior. The simplicity of the model makes it especially valuable for building conceptual clarity, as it eliminates the complexity often associated with theoretical models or simulations.
This working model also encourages scientific inquiry and promotes critical thinking among students. By engaging with a hands-on experiment, learners can better understand cause-and-effect relationships in physics and explore broader applications, such as the role of electromagnetism in electric motors, generators, and various communication systems. It can also be used as part of science exhibitions, classroom demonstrations, and laboratory assessments to support curriculum-based learning objectives in secondary and senior secondary education.
Furthermore, the model aligns with modern educational standards that emphasize experiential and activity-based learning. The model’s robust design, accurate functioning, and educational value make it an indispensable addition to any physics lab or science resource center focused on fostering curiosity and scientific literacy.
With its focus on demonstrating one of the cornerstones of electromagnetic theory, the Physics Oersted Law Apparatus Model plays a crucial role in simplifying complex concepts and inspiring the next generation of scientists and engineers. It is a perfect choice for practical education, offering an engaging and reliable platform for learning through observation and experimentation.
The apparatus typically includes a straight conducting wire connected to a battery or power source, positioned parallel to a freely suspended magnetic needle or compass. When the current flows through the conductor, the magnetic needle deflects, effectively demonstrating the magnetic field created around the conductor. This deflection offers tangible proof of Oersted’s discovery and serves as a foundational experiment for students to grasp the basic principles of electromagnetism and its real-world applications. Such a setup not only reinforces theoretical learning but also engages students by allowing them to observe the direct impact of electric current on magnetic orientation.
Constructed with a stainless steel frame, the apparatus is corrosion-resistant and easy to maintain. The non-reactive nature of the material ensures safety during experiments, especially when the equipment is used repeatedly in laboratory conditions. The build quality allows for precise measurements and consistent results, enabling accurate observations and experimental learning. The model is compact, portable, and suitable for individual as well as group demonstrations, making it a versatile teaching aid for educators and laboratory instructors.
Designed with both functionality and ease of use in mind, the Oersted Law Apparatus can be assembled and operated effortlessly by students under guided supervision. It allows learners to adjust the current, observe changes in magnetic field direction, and record varying degrees of deflection, helping them draw meaningful conclusions about electromagnetic behavior. The simplicity of the model makes it especially valuable for building conceptual clarity, as it eliminates the complexity often associated with theoretical models or simulations.
This working model also encourages scientific inquiry and promotes critical thinking among students. By engaging with a hands-on experiment, learners can better understand cause-and-effect relationships in physics and explore broader applications, such as the role of electromagnetism in electric motors, generators, and various communication systems. It can also be used as part of science exhibitions, classroom demonstrations, and laboratory assessments to support curriculum-based learning objectives in secondary and senior secondary education.
Furthermore, the model aligns with modern educational standards that emphasize experiential and activity-based learning. The model’s robust design, accurate functioning, and educational value make it an indispensable addition to any physics lab or science resource center focused on fostering curiosity and scientific literacy.
With its focus on demonstrating one of the cornerstones of electromagnetic theory, the Physics Oersted Law Apparatus Model plays a crucial role in simplifying complex concepts and inspiring the next generation of scientists and engineers. It is a perfect choice for practical education, offering an engaging and reliable platform for learning through observation and experimentation.
Dc Dc Power Supply
Request Callback
₹ 14000 / Piece Get Latest Price
| Output Voltage | 30V |
| Current | 10 A |
| Maximum Input Voltage | 1.1E+2 Volts (AC) |
| Country of Origin | Made in India |
| Connector type | AC input |
Minimum order quantity: 1 Piece
A DC power supply is an essential piece of educational equipment designed to provide a stable and adjustable source of direct current for a wide range of laboratory, training, and testing applications. Built with precision and durability, this device ensures reliable performance for students, educators, and professionals engaged in electronics, electrical engineering, and related fields. By converting alternating current into a consistent and controllable direct current output, the DC power supply allows users to conduct experiments, power electronic circuits, and test components with accuracy. Its versatility makes it a core instrument in laboratories, classrooms, workshops, and research facilities where understanding the principles of voltage, current, and resistance is critical. Whether used for basic circuit training, prototyping, or advanced research, a DC power supply offers a dependable solution to meet diverse educational and practical requirements.
Crafted with robust engineering, the DC power supply is designed to provide high precision with minimal fluctuation, ensuring stable output that supports consistent results during experiments. Most models feature adjustable voltage and current settings, allowing users to customize the power levels to match specific needs. This flexibility is especially valuable in academic environments where learners experiment with different electronic components and devices, gaining hands-on experience in circuit design and troubleshooting. The compact and ergonomic design of a DC power supply ensures ease of use, while safety mechanisms such as overload protection, short-circuit protection, and temperature control enhance reliability and protect both the user and connected equipment. Its clear digital or analog display allows accurate monitoring of voltage and current, helping learners develop a deeper understanding of electrical measurements and control.
The DC power supply also serves as an indispensable tool in technical training institutes and engineering laboratories, where it supports practical sessions in subjects like analog electronics, digital electronics, embedded systems, and communication circuits. It enables learners to power devices such as microcontrollers, sensors, LEDs, motors, and various electronic kits, making theoretical knowledge come alive through practical experimentation. Beyond academic use, it is also suitable for professional applications in research and development, repair workshops, and industrial testing environments. Its role in providing a consistent and adjustable power source ensures that projects and experiments run smoothly, minimizing interruptions caused by unstable or inconsistent current.
Built with high-quality materials, the DC power supply is designed for durability and long-term use. Its efficient design ensures minimal power loss and reliable performance under continuous operation. Many units feature powder-coated finishes or sturdy enclosures to withstand regular handling in busy laboratory environments. Its user-friendly interface and reliable performance make it an ideal choice for beginners as well as advanced learners. Furthermore, its ability to deliver accurate results fosters confidence among students as they learn fundamental and advanced concepts of electrical and electronic engineering.
With its combination of accuracy, reliability, and educational value, the DC power supply is more than just a laboratory tool; it is a gateway to practical learning and skill development. By offering a controlled environment for experimentation, it helps learners build confidence in handling circuits and understanding power management, making it a vital part of modern educational equipment designed for electronics and electrical training.
Crafted with robust engineering, the DC power supply is designed to provide high precision with minimal fluctuation, ensuring stable output that supports consistent results during experiments. Most models feature adjustable voltage and current settings, allowing users to customize the power levels to match specific needs. This flexibility is especially valuable in academic environments where learners experiment with different electronic components and devices, gaining hands-on experience in circuit design and troubleshooting. The compact and ergonomic design of a DC power supply ensures ease of use, while safety mechanisms such as overload protection, short-circuit protection, and temperature control enhance reliability and protect both the user and connected equipment. Its clear digital or analog display allows accurate monitoring of voltage and current, helping learners develop a deeper understanding of electrical measurements and control.
The DC power supply also serves as an indispensable tool in technical training institutes and engineering laboratories, where it supports practical sessions in subjects like analog electronics, digital electronics, embedded systems, and communication circuits. It enables learners to power devices such as microcontrollers, sensors, LEDs, motors, and various electronic kits, making theoretical knowledge come alive through practical experimentation. Beyond academic use, it is also suitable for professional applications in research and development, repair workshops, and industrial testing environments. Its role in providing a consistent and adjustable power source ensures that projects and experiments run smoothly, minimizing interruptions caused by unstable or inconsistent current.
Built with high-quality materials, the DC power supply is designed for durability and long-term use. Its efficient design ensures minimal power loss and reliable performance under continuous operation. Many units feature powder-coated finishes or sturdy enclosures to withstand regular handling in busy laboratory environments. Its user-friendly interface and reliable performance make it an ideal choice for beginners as well as advanced learners. Furthermore, its ability to deliver accurate results fosters confidence among students as they learn fundamental and advanced concepts of electrical and electronic engineering.
With its combination of accuracy, reliability, and educational value, the DC power supply is more than just a laboratory tool; it is a gateway to practical learning and skill development. By offering a controlled environment for experimentation, it helps learners build confidence in handling circuits and understanding power management, making it a vital part of modern educational equipment designed for electronics and electrical training.
Electronic Lab Trainer
Request Callback
₹ 4000 / Piece Get Latest Price
| Trainer Type | Electronics Lab Trainer |
| Usage/Application | Laboratory |
| Brand | A.S. Int'l |
| Country of Origin | Made in India |
| Voltage Requirement | 230V |
Minimum order quantity: 1 Piece
The Electronic Lab Trainer is a highly versatile and advanced educational training system designed to provide students, educators, and researchers with a comprehensive platform for studying and experimenting with digital electronics. Built with precision and durability, this trainer is widely used in laboratories, engineering colleges, polytechnic institutes, and technical training centers, where practical learning is emphasized alongside theoretical knowledge.
This trainer is powered through mains supply at 230V, 50Hz, ensuring compatibility with standard laboratory infrastructure. It incorporates regulated DC power supplies that offer flexibility and stability, including IC regulated 3V–15V and 3V–30V supplies at 500mA, along with fixed outputs of +5V/1A and -5V/500mA. Such a variety of power options allows users to work on multiple experiments without the need for additional external supplies, making it convenient for extended lab sessions. A built-in pulse generator with a range of 0–1 MHz provides precise signals compatible with both TTL and CMOS technologies, enabling learners to explore real-time testing of digital circuits and logic functions.
One of the most distinctive features of the Electronic Lab Trainer is its layout ensures that students can quickly connect, build, and analyze circuits without confusion. Connections are brought out through brass pins of 2mm dimension, ensuring reliability and durability during frequent use. The system includes a large solderless breadboard, consisting of 640 tie points on terminal strips and 200 tie points on distribution strips, totaling 840 tie points. This allows users to design and test complex circuits without the need for soldering, thereby saving time and ensuring reusability.
The trainer is further enhanced with built-in components such as logic inputs and outputs with 12-bit capacity, a buzzer for continuity testing, an inbuilt logic probe, low-frequency clock generator adjustable between 1Hz–10Hz, and a mono pulse generator for timing experiments. It also includes a 2-bit BCD to 7-segment indicator system for visual demonstration of binary inputs and outputs, making it especially valuable for learning number systems and code conversions. These integrated features make it a comprehensive platform for studying topics such as logic gates, Boolean algebra, combinational circuits, sequential circuits, counters, multiplexers, shift registers, encoders, and flip-flops.
Safety and durability are also well addressed, with a fuse provided for short-circuit protection, ensuring secure operation during experiments. The trainer is housed in a sturdy ABS plastic cabinet, designed for long-term institutional use. Its compact size of 12” x 10” makes it easy to handle and store, while still offering a large enough surface for comfortable circuit assembly. The kit is supplied with patch cords, an instruction manual, and optional accessories like CRO and additional IC components, further expanding its usability.
Optional plug-and-play modules extend the trainer’s capabilities even further, offering pre-configured modules for logic gates, binary adders, multiplexers, shift registers, counters, code converters, parity checkers, comparators, RAM, ALU, and more. These modules allow learners to directly plug into the trainer for guided experiments, saving setup time while ensuring accuracy.
The Electronic Lab Trainer is more than just a piece of equipment; it is a complete learning solution that bridges the gap between theory and practice in digital electronics. By offering a wide range of built-in features, high-quality design, and flexibility for expansion, it empowers students to develop hands-on expertise, making it an indispensable resource for laboratories focused on electronics education and training.
This trainer is powered through mains supply at 230V, 50Hz, ensuring compatibility with standard laboratory infrastructure. It incorporates regulated DC power supplies that offer flexibility and stability, including IC regulated 3V–15V and 3V–30V supplies at 500mA, along with fixed outputs of +5V/1A and -5V/500mA. Such a variety of power options allows users to work on multiple experiments without the need for additional external supplies, making it convenient for extended lab sessions. A built-in pulse generator with a range of 0–1 MHz provides precise signals compatible with both TTL and CMOS technologies, enabling learners to explore real-time testing of digital circuits and logic functions.
One of the most distinctive features of the Electronic Lab Trainer is its layout ensures that students can quickly connect, build, and analyze circuits without confusion. Connections are brought out through brass pins of 2mm dimension, ensuring reliability and durability during frequent use. The system includes a large solderless breadboard, consisting of 640 tie points on terminal strips and 200 tie points on distribution strips, totaling 840 tie points. This allows users to design and test complex circuits without the need for soldering, thereby saving time and ensuring reusability.
The trainer is further enhanced with built-in components such as logic inputs and outputs with 12-bit capacity, a buzzer for continuity testing, an inbuilt logic probe, low-frequency clock generator adjustable between 1Hz–10Hz, and a mono pulse generator for timing experiments. It also includes a 2-bit BCD to 7-segment indicator system for visual demonstration of binary inputs and outputs, making it especially valuable for learning number systems and code conversions. These integrated features make it a comprehensive platform for studying topics such as logic gates, Boolean algebra, combinational circuits, sequential circuits, counters, multiplexers, shift registers, encoders, and flip-flops.
Safety and durability are also well addressed, with a fuse provided for short-circuit protection, ensuring secure operation during experiments. The trainer is housed in a sturdy ABS plastic cabinet, designed for long-term institutional use. Its compact size of 12” x 10” makes it easy to handle and store, while still offering a large enough surface for comfortable circuit assembly. The kit is supplied with patch cords, an instruction manual, and optional accessories like CRO and additional IC components, further expanding its usability.
Optional plug-and-play modules extend the trainer’s capabilities even further, offering pre-configured modules for logic gates, binary adders, multiplexers, shift registers, counters, code converters, parity checkers, comparators, RAM, ALU, and more. These modules allow learners to directly plug into the trainer for guided experiments, saving setup time while ensuring accuracy.
The Electronic Lab Trainer is more than just a piece of equipment; it is a complete learning solution that bridges the gap between theory and practice in digital electronics. By offering a wide range of built-in features, high-quality design, and flexibility for expansion, it empowers students to develop hands-on expertise, making it an indispensable resource for laboratories focused on electronics education and training.
Student Compound Microscope
Request Callback
₹ 8500 / Piece Get Latest Price
| Magnification | 50x-600x |
| Brand | A.S.Int'L |
| Model Name / Number | AS01SM |
| Light Source | LED |
| Model Name/Number | AS01SM |
| Country of Origin | Made in India |
Minimum order quantity: 1 Piece
A student compound microscope is one of the most fundamental and essential pieces of educational equipment used in schools, colleges, and research institutions to study the microscopic world in detail. Designed with precision optics and advanced magnification capabilities, it allows students and researchers to explore the structure of cells, tissues, and microorganisms that cannot be observed with the naked eye. By combining multiple lenses to achieve high levels of magnification and clarity, the compound microscope transforms scientific learning into a hands-on experience, bridging the gap between theoretical concepts and practical observation. Its ability to reveal intricate details makes it indispensable for studies in biology, life sciences, medical education, and material sciences, providing learners with the opportunity to deepen their understanding of microscopic structures and biological processes.
The student compound microscope works by using an objective lens close to the specimen and an eyepiece lens that magnifies the image formed by the objective. This system of lenses produces a highly detailed and enlarged view of the sample, allowing students to study cellular structures, bacteria, plant tissues, and other specimens with precision. Most educational compound microscopes come equipped with multiple objective lenses of varying magnifications, usually ranging from low power to high power, enabling users to switch between magnifications based on the level of detail required. The addition of a fine and coarse focusing mechanism ensures that students can adjust the sharpness of the image, learning how to work with optical instruments effectively.
Illumination plays a critical role in the performance of a compound microscope, and modern designs often incorporate built-in LED or mirror-based light sources that provide consistent brightness. This ensures that even the most transparent specimens can be clearly observed. Some advanced versions also include adjustable diaphragms and condensers that allow control of light intensity and contrast, giving learners the ability to observe specimens with enhanced clarity. These features not only make the microscope suitable for academic labs but also for higher-level research training, ensuring versatility in its use.
Durability and reliability are key aspects of a compound microscope intended for educational use. Constructed with a sturdy body and high-quality optical glass lenses, it is designed to withstand frequent handling by students while maintaining precision over long-term use. The ergonomic design with a stable base ensures ease of use during extended observation sessions, making it comfortable for learners to engage in laboratory experiments. Its compact size also makes it easy to integrate into classroom environments without occupying excessive space, while still offering powerful magnification and clear visualization.
The educational value of a student compound microscope extends beyond biology classrooms. It is widely used in environmental science, forensic studies, material analysis, and medical training. Students gain hands-on experience in preparing slides, focusing the lenses, and analyzing minute details, which enhances their practical learning and strengthens their understanding of scientific methods. In research institutions and advanced laboratories, the compound microscope continues to serve as a foundational tool for examining structures at the cellular level, playing a vital role in discoveries and innovations.
Overall, the student compound microscope is an indispensable educational instrument that provides unmatched clarity, magnification, and usability. By allowing learners to explore the hidden world of microscopic structures, it not only enriches classroom teaching but also inspires curiosity, scientific thinking, and a deeper appreciation of the natural world.
The student compound microscope works by using an objective lens close to the specimen and an eyepiece lens that magnifies the image formed by the objective. This system of lenses produces a highly detailed and enlarged view of the sample, allowing students to study cellular structures, bacteria, plant tissues, and other specimens with precision. Most educational compound microscopes come equipped with multiple objective lenses of varying magnifications, usually ranging from low power to high power, enabling users to switch between magnifications based on the level of detail required. The addition of a fine and coarse focusing mechanism ensures that students can adjust the sharpness of the image, learning how to work with optical instruments effectively.
Illumination plays a critical role in the performance of a compound microscope, and modern designs often incorporate built-in LED or mirror-based light sources that provide consistent brightness. This ensures that even the most transparent specimens can be clearly observed. Some advanced versions also include adjustable diaphragms and condensers that allow control of light intensity and contrast, giving learners the ability to observe specimens with enhanced clarity. These features not only make the microscope suitable for academic labs but also for higher-level research training, ensuring versatility in its use.
Durability and reliability are key aspects of a compound microscope intended for educational use. Constructed with a sturdy body and high-quality optical glass lenses, it is designed to withstand frequent handling by students while maintaining precision over long-term use. The ergonomic design with a stable base ensures ease of use during extended observation sessions, making it comfortable for learners to engage in laboratory experiments. Its compact size also makes it easy to integrate into classroom environments without occupying excessive space, while still offering powerful magnification and clear visualization.
The educational value of a student compound microscope extends beyond biology classrooms. It is widely used in environmental science, forensic studies, material analysis, and medical training. Students gain hands-on experience in preparing slides, focusing the lenses, and analyzing minute details, which enhances their practical learning and strengthens their understanding of scientific methods. In research institutions and advanced laboratories, the compound microscope continues to serve as a foundational tool for examining structures at the cellular level, playing a vital role in discoveries and innovations.
Overall, the student compound microscope is an indispensable educational instrument that provides unmatched clarity, magnification, and usability. By allowing learners to explore the hidden world of microscopic structures, it not only enriches classroom teaching but also inspires curiosity, scientific thinking, and a deeper appreciation of the natural world.
Basic Logic Gates
Request Callback
₹ 1400 / Piece Get Latest Price
| Gate Type | NAND Gate |
| Supply Voltage | 5 V DC |
| Mounting Type | Trainer Board |
| Application | Trainer Use |
| Current | 150 mA |
Minimum order quantity: 1 Piece
The Basic Logic Gates using Discrete Components apparatus is an essential educational equipment designed to introduce students to the fundamental building blocks of digital electronics through hands-on experimentation and observation. Commonly used in electronics laboratories at engineering colleges, polytechnic institutes, and technical training centers, this trainer enables learners to study the operation of five basic logic gates constructed using individual discrete electronic components rather than integrated circuits. This approach allows students to develop a deeper understanding of how logic functions are physically realized at the component level, bridging the gap between abstract Boolean logic theory and real-world electronic implementation. By assembling and analyzing circuits composed of resistors, diodes, transistors, and other basic elements, students gain valuable insight into signal behavior, switching action, voltage levels, and current flow that form the foundation of digital systems.
The apparatus provides a clear and structured platform for experimenting with fundamental logic operations such as AND, OR, NOT, NAND, and NOR, enabling learners to verify truth tables and logical expressions through practical observation. Input combinations can be applied systematically, allowing students to observe corresponding output states and understand the logical relationships governing each gate. This hands-on interaction reinforces theoretical concepts taught in digital electronics courses and helps students build confidence in circuit analysis and logical reasoning. The use of discrete components makes the internal functioning of each logic gate visible and understandable, which is particularly beneficial for beginners who are transitioning from basic electronics to more advanced digital system studies.
Designed specifically for laboratory applications, the trainer is built to withstand regular handling and repeated experimentation in academic environments. The layout of the circuitry is organized and accessible, allowing students to easily identify individual components and trace signal paths without confusion. This clarity supports effective troubleshooting exercises, where learners can intentionally introduce faults or modify connections to observe their impact on circuit behavior. Such practical exposure enhances problem-solving skills and fosters a deeper appreciation of circuit reliability and design considerations in digital electronics.
The Basic Logic Gates using Discrete Components apparatus is especially valuable in reinforcing core topics such as binary logic, voltage level interpretation, noise margins, and switching characteristics. By working with discrete components, students can directly observe the effects of component tolerances and real-world non-idealities that are often hidden when using integrated logic devices. This experiential learning approach strengthens conceptual understanding and prepares learners for advanced subjects such as combinational logic design, sequential circuits, microprocessors, and embedded systems. The trainer also serves as a strong foundation for understanding how complex digital integrated circuits are constructed from simple logic building blocks.
Overall, this educational trainer plays a vital role in digital electronics laboratories by promoting active learning and conceptual clarity. It supports outcome-based education by encouraging experimentation, verification of theoretical principles, and independent analysis. Suitable for a wide range of academic programs, the Basic Logic Gates using Discrete Components apparatus helps students develop a solid and lasting understanding of digital logic fundamentals, making it an indispensable teaching and learning tool in electronics education.
The apparatus provides a clear and structured platform for experimenting with fundamental logic operations such as AND, OR, NOT, NAND, and NOR, enabling learners to verify truth tables and logical expressions through practical observation. Input combinations can be applied systematically, allowing students to observe corresponding output states and understand the logical relationships governing each gate. This hands-on interaction reinforces theoretical concepts taught in digital electronics courses and helps students build confidence in circuit analysis and logical reasoning. The use of discrete components makes the internal functioning of each logic gate visible and understandable, which is particularly beneficial for beginners who are transitioning from basic electronics to more advanced digital system studies.
Designed specifically for laboratory applications, the trainer is built to withstand regular handling and repeated experimentation in academic environments. The layout of the circuitry is organized and accessible, allowing students to easily identify individual components and trace signal paths without confusion. This clarity supports effective troubleshooting exercises, where learners can intentionally introduce faults or modify connections to observe their impact on circuit behavior. Such practical exposure enhances problem-solving skills and fosters a deeper appreciation of circuit reliability and design considerations in digital electronics.
The Basic Logic Gates using Discrete Components apparatus is especially valuable in reinforcing core topics such as binary logic, voltage level interpretation, noise margins, and switching characteristics. By working with discrete components, students can directly observe the effects of component tolerances and real-world non-idealities that are often hidden when using integrated logic devices. This experiential learning approach strengthens conceptual understanding and prepares learners for advanced subjects such as combinational logic design, sequential circuits, microprocessors, and embedded systems. The trainer also serves as a strong foundation for understanding how complex digital integrated circuits are constructed from simple logic building blocks.
Overall, this educational trainer plays a vital role in digital electronics laboratories by promoting active learning and conceptual clarity. It supports outcome-based education by encouraging experimentation, verification of theoretical principles, and independent analysis. Suitable for a wide range of academic programs, the Basic Logic Gates using Discrete Components apparatus helps students develop a solid and lasting understanding of digital logic fundamentals, making it an indispensable teaching and learning tool in electronics education.
Digital Electronic Circuit Trainer Bread Board Model
Request Callback
₹ 8000 / Piece Get Latest Price
| Training Level | Basic Digital |
| Logic Family | TTL |
| Number Of Experiments | 10–20 |
| Clock Frequency | 1 Hz–10 Hz |
| Input Switches | 8 Switches |
| Output Display | LEDs |
| Power Supply | 5 V DC |
Minimum order quantity: 1 Piece
The digital electronic circuit trainer breadboard model is a versatile and comprehensive educational tool designed to support hands-on learning in digital electronics for schools, colleges, and technical training institutes. This trainer is specifically developed to help students understand fundamental and advanced concepts of digital logic through practical circuit construction and experimentation. By combining a solderless breadboard with integrated power supplies, signal sources, logic controls, and visual indicators, it creates an ideal learning environment where theoretical knowledge can be directly translated into working electronic circuits. Its compact and classroom-friendly design makes it suitable for laboratory benches, electronics workshops, and instructional demonstrations.
At the core of this trainer is a high-quality breadboard layout featuring a total of 400 tie points, arranged with horizontally and vertically common strips for easy and systematic circuit building. This configuration allows learners to quickly assemble and modify digital circuits without soldering, encouraging experimentation and troubleshooting. The clearly defined common strips help students understand circuit connectivity, signal flow, and component placement, which are essential skills in digital electronics education. The breadboard supports repeated use and can accommodate a wide range of integrated circuits, discrete components, and interconnections required for digital logic experiments.
The trainer includes a stable low-voltage DC power supply suitable for logic-level circuits, ensuring safe operation during student use. With regulated output and sufficient current capacity, it can reliably power multiple digital ICs and display elements simultaneously. Logic input switches are provided on the front panel, allowing users to manually apply logic high and logic low states to their circuits. These switches make it easy to test logic gate operations, truth tables, and combinational logic designs without the need for external signal sources. The inclusion of multiple logic input options enhances flexibility and supports a wide variety of experiments.
For output visualization, the digital electronic circuit trainer breadboard model is equipped with multiple LED indicators and a seven-segment display. These visual outputs enable students to instantly observe the results of their circuit configurations, making abstract digital concepts more tangible. Whether verifying Boolean expressions, observing binary counting sequences, or studying data encoding and decoding, the clear visual feedback significantly improves comprehension and retention. The trainer also features an integrated clock generator with selectable frequencies, including low-frequency pulse options suitable for counters, flip-flops, and shift registers. A pulser switch allows for single-step clocking, which is especially useful when analyzing sequential logic behavior.
An integrated digital panel meter mounted on the front panel adds further educational value by allowing real-time monitoring of voltage levels during experiments. This helps students develop good measurement practices and understand the importance of electrical parameters in digital circuit performance. The trainer is designed to support a wide range of experiments, including logic gates, Boolean identities, adders and subtractors, flip-flops, counters, shift registers, multiplexers, demultiplexers, encoders, and decoders. Its all-in-one construction reduces setup time and minimizes the need for additional laboratory equipment..
At the core of this trainer is a high-quality breadboard layout featuring a total of 400 tie points, arranged with horizontally and vertically common strips for easy and systematic circuit building. This configuration allows learners to quickly assemble and modify digital circuits without soldering, encouraging experimentation and troubleshooting. The clearly defined common strips help students understand circuit connectivity, signal flow, and component placement, which are essential skills in digital electronics education. The breadboard supports repeated use and can accommodate a wide range of integrated circuits, discrete components, and interconnections required for digital logic experiments.
The trainer includes a stable low-voltage DC power supply suitable for logic-level circuits, ensuring safe operation during student use. With regulated output and sufficient current capacity, it can reliably power multiple digital ICs and display elements simultaneously. Logic input switches are provided on the front panel, allowing users to manually apply logic high and logic low states to their circuits. These switches make it easy to test logic gate operations, truth tables, and combinational logic designs without the need for external signal sources. The inclusion of multiple logic input options enhances flexibility and supports a wide variety of experiments.
For output visualization, the digital electronic circuit trainer breadboard model is equipped with multiple LED indicators and a seven-segment display. These visual outputs enable students to instantly observe the results of their circuit configurations, making abstract digital concepts more tangible. Whether verifying Boolean expressions, observing binary counting sequences, or studying data encoding and decoding, the clear visual feedback significantly improves comprehension and retention. The trainer also features an integrated clock generator with selectable frequencies, including low-frequency pulse options suitable for counters, flip-flops, and shift registers. A pulser switch allows for single-step clocking, which is especially useful when analyzing sequential logic behavior.
An integrated digital panel meter mounted on the front panel adds further educational value by allowing real-time monitoring of voltage levels during experiments. This helps students develop good measurement practices and understand the importance of electrical parameters in digital circuit performance. The trainer is designed to support a wide range of experiments, including logic gates, Boolean identities, adders and subtractors, flip-flops, counters, shift registers, multiplexers, demultiplexers, encoders, and decoders. Its all-in-one construction reduces setup time and minimizes the need for additional laboratory equipment..
Transformer Demonstration Unit
Request Callback
₹ 2000 / Piece Get Latest Price
| Trainer Type | Basic Electronics |
| Included Instruments | CRO |
| Number Of Experiments | 10–20 |
| Power Supply | ±12 V DC |
| Signal Generator | Sine |
| Display Type | Analog Meter |
| Trainer Configuration | Single Board |
| PC Interface | USB |
| Kit Level | Diploma Level |
A Transformer Demonstration Unit (TDU) is primarily an educational tool for teaching principles of electromagnetism, used in labs to show step-up/down voltage, turns ratio, efficiency, and induction, while also demonstrating practical applications like eddy current braking and induction furnaces, helping students understand real-world power systems and electronics.
Fluke Digital Multimeter
Request Callback
₹ 10000 / Piece Get Latest Price
| Model Series | 177 |
| Max Dc Voltage | 600 V |
| Max Ac Voltage | 600 V |
| Max Dc Current | 10 A |
| Max Ac Current | 10 A |
| Display Count | 2000 Count |
| Auto Ranging | Yes |
| Safety Rating | CAT II 600 V |
| Additional Functions | Temperature, Frequency |
The Fluke Digital Multimeter is a high-precision instrument designed for accurate electrical measurements. Ideal for professionals, it offers reliable readings for voltage, current, resistance, and continuity. With a durable build, backlit display, and advanced safety features, it ensures efficient troubleshooting in industrial, commercial, and residential electrical systems.
Newton Cradle Model
Request Callback
₹ 700 / Piece Get Latest Price
| Brand | A.S. Int'l |
| Usage/Application | Schools |
| Material | Stainless Steel |
| Phase | Single Phase |
| Country of Origin | Made in India |
| Ideal For | School |
| Color | Silver |
| Finish | Polished |
Minimum order quantity: 100 Piece
The Single Phase Stainless Steel Newton Cradle Model is a visually engaging and scientifically accurate educational apparatus designed to demonstrate the core principles of physics, particularly Newton’s Third Law of Motion and the conservation of momentum and energy. Crafted entirely from high-grade stainless steel, this polished model offers both aesthetic appeal and exceptional durability, making it ideal for use in school laboratories, science classrooms, and educational demonstrations. Its sleek silver finish not only enhances the appearance of the model but also provides resistance to corrosion, scratches, and general wear and tear, ensuring long-lasting use in educational settings.
Engineered with precision, the Newton Cradle features a series of identical stainless steel spheres suspended by durable wires that align perfectly along a linear frame. When one or more spheres at one end are lifted and released, they strike the stationary spheres, transferring kinetic energy through the row and causing the sphere(s) on the opposite end to swing out. This motion vividly illustrates the conservation of momentum and energy, concepts that are foundational in the study of classical mechanics. Students and observers can witness how energy travels through the aligned balls without any visible movement in the middle spheres, offering a clear and captivating demonstration of Newtonian physics.
The model operates efficiently on a single phase, ensuring safe and low-power usage, especially within classroom environments. This characteristic makes it suitable for continuous demonstration without the risk of overheating or electrical instability. Its simple mechanical design does not require any complex setup, allowing educators to integrate it seamlessly into lesson plans and practical demonstrations. The visual and tactile engagement of the Newton Cradle makes it especially effective for reinforcing theoretical knowledge through real-time observation, thus catering to various learning styles, including kinesthetic and visual learners.
The stainless steel construction ensures consistent performance and accuracy in demonstration. Unlike models made from plastic or lower-grade metals, this cradle resists deformation and maintains a uniform sphere size and weight, which is critical for achieving precise results in energy transfer demonstrations. The rigidity of the steel frame and the strength of the suspension wires ensure minimal energy loss, allowing for extended oscillation with reduced damping, giving students ample time to study and analyze the motion pattern.
This educational model is ideal for various academic levels, from elementary school through to college-level physics courses. It is frequently used to introduce students to fundamental physics concepts and is also employed in more advanced settings to discuss more intricate aspects of momentum and energy dynamics. The model also finds relevance in psychology and business studies to metaphorically illustrate ideas such as cause and effect, decision-making impact, and chain reactions.
Whether placed on a teacher's desk, in a physics laboratory, or used during a science exhibition, the Single Phase Stainless Steel Newton Cradle Model serves as an iconic representation of mechanical laws in motion. Its polished and modern design complements its educational utility, making it a perfect combination of form and function. It is also a popular choice among educators who value precision, durability, and clarity in teaching aids. With its sturdy build, polished finish, and flawless mechanical performance, this Newton Cradle stands as an exemplary tool for both educational enrichment and scientific exploration.
Engineered with precision, the Newton Cradle features a series of identical stainless steel spheres suspended by durable wires that align perfectly along a linear frame. When one or more spheres at one end are lifted and released, they strike the stationary spheres, transferring kinetic energy through the row and causing the sphere(s) on the opposite end to swing out. This motion vividly illustrates the conservation of momentum and energy, concepts that are foundational in the study of classical mechanics. Students and observers can witness how energy travels through the aligned balls without any visible movement in the middle spheres, offering a clear and captivating demonstration of Newtonian physics.
The model operates efficiently on a single phase, ensuring safe and low-power usage, especially within classroom environments. This characteristic makes it suitable for continuous demonstration without the risk of overheating or electrical instability. Its simple mechanical design does not require any complex setup, allowing educators to integrate it seamlessly into lesson plans and practical demonstrations. The visual and tactile engagement of the Newton Cradle makes it especially effective for reinforcing theoretical knowledge through real-time observation, thus catering to various learning styles, including kinesthetic and visual learners.
The stainless steel construction ensures consistent performance and accuracy in demonstration. Unlike models made from plastic or lower-grade metals, this cradle resists deformation and maintains a uniform sphere size and weight, which is critical for achieving precise results in energy transfer demonstrations. The rigidity of the steel frame and the strength of the suspension wires ensure minimal energy loss, allowing for extended oscillation with reduced damping, giving students ample time to study and analyze the motion pattern.
This educational model is ideal for various academic levels, from elementary school through to college-level physics courses. It is frequently used to introduce students to fundamental physics concepts and is also employed in more advanced settings to discuss more intricate aspects of momentum and energy dynamics. The model also finds relevance in psychology and business studies to metaphorically illustrate ideas such as cause and effect, decision-making impact, and chain reactions.
Whether placed on a teacher's desk, in a physics laboratory, or used during a science exhibition, the Single Phase Stainless Steel Newton Cradle Model serves as an iconic representation of mechanical laws in motion. Its polished and modern design complements its educational utility, making it a perfect combination of form and function. It is also a popular choice among educators who value precision, durability, and clarity in teaching aids. With its sturdy build, polished finish, and flawless mechanical performance, this Newton Cradle stands as an exemplary tool for both educational enrichment and scientific exploration.
5 V Battery Eliminator
Request Callback
₹ 700 / Piece Get Latest Price
| Output Voltage | 5 V |
| Usage/Application | Electronic Instruments |
| Design | Smps |
| Shape | Rectangular |
| Material | MS |
Minimum order quantity: 10 Piece
5 Volt Battery Eliminator for School Laboratories – Physics, Chemistry & Biology Experiments
The 5 Volt Battery Eliminator is an essential power supply device designed to replace conventional batteries in science experiments and educational demonstrations. Widely used in Physics, Chemistry, and Biology laboratories, this compact power source delivers a stable 5V DC output, making it highly suitable for operating circuit-based setups, low-voltage lab instruments, school-level science kits, and various experimental devices. It ensures long-lasting, cost-effective, and safe power delivery for continuous classroom and lab use.
✅ Technical Specifications:-
Product Name: Battery Eliminator – 5 Volt Output
-
Input Voltage: 220–240V AC, 50/60Hz (Standard Indian Power Supply)
-
Output Voltage: Regulated 5V DC
-
Output Current: 500mA to 2A (depending on model selection)
-
Output Terminals: 2 or 3 pairs of color-coded banana terminals (Red & Black)
-
Output Type: Constant DC supply with ripple-free voltage
-
Fuse Protection: Built-in safety fuse with quick-replace access
-
Body Material: Durable, shockproof, powder-coated metallic enclosure or ABS body
-
Cooling: Ventilated housing with optional fan (on heavy-duty model)
-
Indicator: LED power indicator
-
Dimensions: Compact desktop model – approx. 15 cm x 10 cm x 7 cm
-
Weight: Approx. 800 grams to 1.2 Kg (depending on model)
-
Compliance: ISO Certified, RoHS compliant
-
Usage: Laboratory experiments, student projects, electronic circuits, STEM education tools
-
Replaces conventional 5V batteries with continuous DC power
-
Ideal for school science labs, electronic kits, Arduino-based projects, and sensor circuits
-
Provides safe, regulated, ripple-free output to protect delicate components
-
Available in both single-output and multi-output terminal designs
-
Short circuit & overload protection ensures lab safety
-
Power indicator for easy monitoring
-
Long-life transformer and rectifier system
-
Compatible with resistors, diodes, transistors, LEDs, buzzers, motors, sensors, etc.
-
Energy-efficient and low maintenance
-
Custom branding for educational institutions and bulk buyers
150 mm Brass Vernier Caliper Round Jaw
Request Callback
₹ 200 / Piece Get Latest Price
| Measuring Range | 150 mm |
| Accuracy | 0.001 mm |
| Country of Origin | Made in India |
| Colour | Golden |
| Material | Brass |
| Usage | Used In Laboratory |
| Type | Vernier Caliper Round Jaw |
Minimum order quantity: 10 Piece
The 150 mm Brass Vernier Caliper with Round Jaw is a precision measuring instrument meticulously crafted to meet the demands of laboratory professionals and educational institutions. Designed with a measuring range of 150 mm and offering a remarkable accuracy of 0.001 mm, this vernier caliper ensures highly accurate readings that are essential for applications requiring minute measurement tolerances. The instrument features a distinctive round jaw design, making it especially suitable for measuring cylindrical and curved surfaces with enhanced stability and grip. Whether you are working in a physics lab, engineering workshop, or quality control setting, this caliper provides reliable and consistent measurements.
Constructed entirely from high-quality brass, the caliper not only exhibits superior durability but also offers excellent resistance to corrosion and environmental wear. The golden finish not only enhances its aesthetic appeal but also adds to its resilience in humid or chemically active laboratory environments. Brass is a preferred material for precision instruments due to its dimensional stability and reduced magnetic interference, ensuring that measurement results remain unaffected by surrounding electromagnetic fields—making this vernier caliper an ideal tool in sensitive experimental setups.
The sliding scale mechanism of the caliper is engineered for smooth operation and ease of adjustment, allowing the user to obtain readings quickly and efficiently without compromising precision. The clearly marked graduated scale enhances visibility and reduces the risk of parallax error, making it suitable for both novice learners and experienced technicians. The fine adjustment screw and locking mechanism allow for fixed positioning during critical measurements, further enhancing the usability of the tool during experiments and data recording.
This brass vernier caliper is widely used in laboratory settings for educational demonstrations, practical experiments, and technical training in schools, colleges, and engineering institutions. It plays a crucial role in teaching students the fundamentals of linear measurement, the concept of least count, and the importance of measurement accuracy in scientific investigations. It is also a trusted instrument in research facilities and workshops where dimensional accuracy is essential for quality assurance and prototype evaluation.
The round jaw configuration makes this caliper especially useful for measuring round objects such as rods, wires, tubes, and other cylindrical specimens. Its ergonomic design ensures a comfortable grip and ease of handling, which contributes to improved efficiency during repetitive tasks. The compact form factor and lightweight construction allow for convenient storage and portability, making it easy to transport between lab stations or carry in a tool kit.
In stock and ready for immediate dispatch, the 150 mm Brass Vernier Caliper with Round Jaw is a valuable addition to any precision tool collection. Its blend of traditional craftsmanship and modern measurement accuracy makes it a versatile instrument suitable for a variety of measurement tasks. Whether used for academic instruction, laboratory experiments, or professional measurement needs, this brass caliper delivers exceptional performance and reliability. Its precision, durability, and functionality make it a dependable tool for anyone requiring meticulous measurement in a laboratory or educational setting.
Constructed entirely from high-quality brass, the caliper not only exhibits superior durability but also offers excellent resistance to corrosion and environmental wear. The golden finish not only enhances its aesthetic appeal but also adds to its resilience in humid or chemically active laboratory environments. Brass is a preferred material for precision instruments due to its dimensional stability and reduced magnetic interference, ensuring that measurement results remain unaffected by surrounding electromagnetic fields—making this vernier caliper an ideal tool in sensitive experimental setups.
The sliding scale mechanism of the caliper is engineered for smooth operation and ease of adjustment, allowing the user to obtain readings quickly and efficiently without compromising precision. The clearly marked graduated scale enhances visibility and reduces the risk of parallax error, making it suitable for both novice learners and experienced technicians. The fine adjustment screw and locking mechanism allow for fixed positioning during critical measurements, further enhancing the usability of the tool during experiments and data recording.
This brass vernier caliper is widely used in laboratory settings for educational demonstrations, practical experiments, and technical training in schools, colleges, and engineering institutions. It plays a crucial role in teaching students the fundamentals of linear measurement, the concept of least count, and the importance of measurement accuracy in scientific investigations. It is also a trusted instrument in research facilities and workshops where dimensional accuracy is essential for quality assurance and prototype evaluation.
The round jaw configuration makes this caliper especially useful for measuring round objects such as rods, wires, tubes, and other cylindrical specimens. Its ergonomic design ensures a comfortable grip and ease of handling, which contributes to improved efficiency during repetitive tasks. The compact form factor and lightweight construction allow for convenient storage and portability, making it easy to transport between lab stations or carry in a tool kit.
In stock and ready for immediate dispatch, the 150 mm Brass Vernier Caliper with Round Jaw is a valuable addition to any precision tool collection. Its blend of traditional craftsmanship and modern measurement accuracy makes it a versatile instrument suitable for a variety of measurement tasks. Whether used for academic instruction, laboratory experiments, or professional measurement needs, this brass caliper delivers exceptional performance and reliability. Its precision, durability, and functionality make it a dependable tool for anyone requiring meticulous measurement in a laboratory or educational setting.
150 mm Brass IME Type Vernier Caliper
Request Callback
₹ 500 / Piece Get Latest Price
| Measuring Range | 150 mm |
| Accuracy | 0.001 mm |
| Country of Origin | Made in India |
| Material | Brass |
| Usage | Physics Laboratory |
| Manufactured By | A.S. INT'L |
| Colour | Golden |
Minimum order quantity: 100 Piece
The 150 mm Brass IME Type Vernier Caliper is a precision measuring instrument engineered for high-accuracy applications in laboratory environments, academic institutions, and industrial quality control setups. With an impressive accuracy of 0.001 mm, this caliper is specially designed for tasks that demand exact measurement readings and consistent repeatability. Crafted from premium-grade brass, it offers not only robust mechanical strength and durability but also excellent corrosion resistance, making it particularly suitable for use in environments where contact with reactive chemicals or moisture is frequent. The golden hue of the brass material adds a touch of elegance and ensures the tool remains oxidation-free over extended use.
Designed according to the Indian Measurement Engineering (IME) standard, this vernier caliper allows for highly detailed linear measurements up to 150 mm, making it ideal for measuring both external and internal dimensions, as well as depth and step measurements. The brass construction also eliminates the risk of magnetism or spark generation, which is especially beneficial in sensitive laboratory environments such as those involving volatile compounds or precision electronics. The scale is finely engraved with sharp graduations that remain legible even with prolonged use, supporting meticulous and confident measurement taking.
Manufactured by AS International, a trusted name in laboratory and technical instrumentation, the caliper reflects a commitment to quality and precision. The jaws of the caliper are perfectly aligned and smoothly glide over the main scale, providing minimal friction for seamless operation. Whether measuring metallic objects, plastic components, small mechanical parts, or other experimental specimens, the caliper provides accurate readings that help maintain consistency in research, inspection, or manufacturing processes.
Its ergonomic design ensures that the user can handle it comfortably for extended periods without experiencing fatigue, which is particularly advantageous in academic and research settings where repetitive measurements are common. Additionally, the IME-type design includes dual measurement scales, which cater to both metric and fractional readings, thereby increasing versatility across multiple disciplines and user preferences. This feature also makes the caliper a reliable educational tool for teaching precise measurement principles in mechanical engineering, physics, and applied sciences labs.
The smooth brass surface, combined with polished edges, ensures the device remains free from burrs or rough finishes that could hinder measurements or damage sensitive objects. It is also easy to clean and maintain, requiring minimal effort to keep it in pristine working condition. The caliper’s lightweight yet sturdy design makes it portable and convenient for field work, calibration procedures, and project-based tasks that require movement between locations.
For professionals, students, or technicians seeking an instrument that merges accuracy, elegance, and reliability, the 150 mm Brass IME Type Vernier Caliper is a smart investment. Its high-resolution measurement capability, combined with a corrosion-resistant brass body and precision engineering, ensures dependable performance across various scientific and industrial applications. Whether it is for quality assurance, component inspection, or academic experimentation, this caliper continues to be a trusted tool for obtaining exact dimensional readings with confidence and efficiency.
Designed according to the Indian Measurement Engineering (IME) standard, this vernier caliper allows for highly detailed linear measurements up to 150 mm, making it ideal for measuring both external and internal dimensions, as well as depth and step measurements. The brass construction also eliminates the risk of magnetism or spark generation, which is especially beneficial in sensitive laboratory environments such as those involving volatile compounds or precision electronics. The scale is finely engraved with sharp graduations that remain legible even with prolonged use, supporting meticulous and confident measurement taking.
Manufactured by AS International, a trusted name in laboratory and technical instrumentation, the caliper reflects a commitment to quality and precision. The jaws of the caliper are perfectly aligned and smoothly glide over the main scale, providing minimal friction for seamless operation. Whether measuring metallic objects, plastic components, small mechanical parts, or other experimental specimens, the caliper provides accurate readings that help maintain consistency in research, inspection, or manufacturing processes.
Its ergonomic design ensures that the user can handle it comfortably for extended periods without experiencing fatigue, which is particularly advantageous in academic and research settings where repetitive measurements are common. Additionally, the IME-type design includes dual measurement scales, which cater to both metric and fractional readings, thereby increasing versatility across multiple disciplines and user preferences. This feature also makes the caliper a reliable educational tool for teaching precise measurement principles in mechanical engineering, physics, and applied sciences labs.
The smooth brass surface, combined with polished edges, ensures the device remains free from burrs or rough finishes that could hinder measurements or damage sensitive objects. It is also easy to clean and maintain, requiring minimal effort to keep it in pristine working condition. The caliper’s lightweight yet sturdy design makes it portable and convenient for field work, calibration procedures, and project-based tasks that require movement between locations.
For professionals, students, or technicians seeking an instrument that merges accuracy, elegance, and reliability, the 150 mm Brass IME Type Vernier Caliper is a smart investment. Its high-resolution measurement capability, combined with a corrosion-resistant brass body and precision engineering, ensures dependable performance across various scientific and industrial applications. Whether it is for quality assurance, component inspection, or academic experimentation, this caliper continues to be a trusted tool for obtaining exact dimensional readings with confidence and efficiency.
Single Phase Electric Motor
Request Callback
₹ 1500 / Piece Get Latest Price
| Power | 0.12 KW |
| Horsepower | 0.5 HP |
| Speed | 960 rpm |
| No. of Poles | 4 |
| Voltage | 220 V |
| Mounting Type | Foot |
| Frequency | 50 Hz |
Minimum order quantity: 1 Piece
The 0.12 KW 0.5 HP Single Phase Electric Motor is a compact and efficient power solution, meticulously engineered for reliability, durability, and smooth performance in various light-duty applications. Built with precision, this electric motor operates at a standard voltage of 220 V and is perfectly suited for domestic, agricultural, and small industrial uses where low horsepower and consistent torque are required. With a power rating of 0.12 kilowatts and an output of 0.5 horsepower, it delivers optimal performance while maintaining energy efficiency. Its speed of 960 revolutions per minute ensures controlled and steady operation across different systems and equipment.
Designed with a four-pole configuration, the motor is capable of generating a balanced and smooth rotational output that makes it ideal for applications needing moderate speed and high torque stability. The motor features a robust foot mounting type, allowing it to be securely installed on a variety of base surfaces, thereby ensuring stability and minimal vibration during operation. This design contributes to long-term reliability and reduces wear and tear, even with continuous use. Its single-phase operation makes it extremely convenient for use in residential or low-load commercial environments where three-phase power supply is not available.
The build quality of this single phase electric motor is a highlight, with high-grade materials used throughout its construction to ensure longevity and resistance to environmental factors. The casing is engineered to provide effective heat dissipation, which prevents overheating and allows the motor to function efficiently under prolonged load conditions. Furthermore, its internal windings and insulation are crafted to handle variations in voltage, offering protection against short circuits and electrical faults. The 50 Hz frequency ensures compatibility with standard electric systems, making this motor easy to integrate into existing setups without the need for additional modifications.
One of the standout advantages of the 0.5 HP electric motor is its versatility. It can be effectively used in a wide range of applications such as small water pumps, fans, blowers, conveyors, compressors, and agricultural machinery. Its consistent 960 rpm speed is especially useful in systems where a slower and more controlled mechanical output is essential. The low noise operation and minimal maintenance requirements further make it an appealing choice for users looking for a practical and low-maintenance motor solution.
From an energy consumption perspective, the 0.12 KW motor is highly efficient, helping users cut down on electricity usage without compromising on output. This makes it an eco-friendly and cost-effective option for long-term operation. The single phase design simplifies wiring and installation, making it accessible for small workshops, home-based applications, and areas with limited technical infrastructure.
In conclusion, the 0.12 KW 0.5 HP Single Phase Electric Motor with 960 rpm is a highly dependable and energy-efficient solution for a variety of light-duty power needs. Its robust build, smooth operation, and user-friendly installation make it an excellent addition to any setup requiring moderate mechanical power. Whether used in home appliances, small-scale farming tools, or low-load industrial equipment, this electric motor delivers consistent and safe performance backed by solid engineering and design.
Designed with a four-pole configuration, the motor is capable of generating a balanced and smooth rotational output that makes it ideal for applications needing moderate speed and high torque stability. The motor features a robust foot mounting type, allowing it to be securely installed on a variety of base surfaces, thereby ensuring stability and minimal vibration during operation. This design contributes to long-term reliability and reduces wear and tear, even with continuous use. Its single-phase operation makes it extremely convenient for use in residential or low-load commercial environments where three-phase power supply is not available.
The build quality of this single phase electric motor is a highlight, with high-grade materials used throughout its construction to ensure longevity and resistance to environmental factors. The casing is engineered to provide effective heat dissipation, which prevents overheating and allows the motor to function efficiently under prolonged load conditions. Furthermore, its internal windings and insulation are crafted to handle variations in voltage, offering protection against short circuits and electrical faults. The 50 Hz frequency ensures compatibility with standard electric systems, making this motor easy to integrate into existing setups without the need for additional modifications.
One of the standout advantages of the 0.5 HP electric motor is its versatility. It can be effectively used in a wide range of applications such as small water pumps, fans, blowers, conveyors, compressors, and agricultural machinery. Its consistent 960 rpm speed is especially useful in systems where a slower and more controlled mechanical output is essential. The low noise operation and minimal maintenance requirements further make it an appealing choice for users looking for a practical and low-maintenance motor solution.
From an energy consumption perspective, the 0.12 KW motor is highly efficient, helping users cut down on electricity usage without compromising on output. This makes it an eco-friendly and cost-effective option for long-term operation. The single phase design simplifies wiring and installation, making it accessible for small workshops, home-based applications, and areas with limited technical infrastructure.
In conclusion, the 0.12 KW 0.5 HP Single Phase Electric Motor with 960 rpm is a highly dependable and energy-efficient solution for a variety of light-duty power needs. Its robust build, smooth operation, and user-friendly installation make it an excellent addition to any setup requiring moderate mechanical power. Whether used in home appliances, small-scale farming tools, or low-load industrial equipment, this electric motor delivers consistent and safe performance backed by solid engineering and design.
Racer Digital Stopwatch
Request Callback
₹ 2200 / Pack Get Latest Price
| Material | ABS |
| Brand | Racer |
| Model Name/Number | ASINTSTOPWAT |
| Product Type | Digital |
| Color | Black |
| Country of Origin | Made in India |
| Dial Shape | Round or polygon |
| Battery | 4 Cell Button Type |
| Usage/Application | Sports |
Minimum order quantity: 10 Pack
Racer Digital Stopwatch is a compact and precise handheld timing device used for accurate time measurement in sports, science labs, training, and classroom activities. It features a clear LCD screen, 1/100-second precision, and split timing functionality. Ideal for coaches, athletes, teachers, referees, and students, it supports essential functions like start, stop, reset, lap, and split time. Built from durable ABS plastic, it has a lightweight ergonomic body with a lanyard for wrist or neck use. The stopwatch supports extended timing up to 23 hours, 59 minutes, 59.99 seconds, depending on the model.
The bold digital display ensures clear visibility under varied lighting. Its large buttons offer smooth and reliable operation. The Racer Stopwatch is powered by a pre-installed button cell battery (LR44 or CR2032), which is long-lasting and easily replaceable. Most models come with beep alerts and some advanced variants feature memory recall and silent mode options.
It is widely used across fields like athletics, swimming, fitness, yoga, physical education, lab experiments, and competitive exams. In educational settings, it helps conduct science practicals and demonstrations in CBSE, ICSE, and state board schools. It fits perfectly into NCERT-based kits and supports activity-based learning under Jaadui Pitara and Samagra Shiksha programs. Its precise time-tracking ability makes it useful for physics and chemistry labs, quiz timers, classroom games, and student training.
Racer Stopwatch is highly recommended for schools, colleges, training centers, coaching academies, government projects, and educational kits. Its robust body and consistent performance make it ideal for everyday institutional use. It is available in assorted designs and colors based on availability. Bulk packaging and OEM branding are also offered for large orders.
The stopwatch is supplied with a user manual and lanyard. It is low maintenance and can be cleaned with a dry cloth. Store in a cool, dry place for long-term use. Racer Stopwatch combines accuracy, durability, and ease of use in a compact design for all your timing needs.
Racer Stopwatch Digital Stopwatch Stopwatch for Athletics Stopwatch for Science Lab Stopwatch for Chemistry Lab Stopwatch for Physics Practicals Stopwatch for School Use CBSE Stopwatch ICSE Stopwatch School Sports Stopwatch Sports Timer Racer Handheld Timer Stopwatch for Gym Stopwatch for PE Class Stopwatch for Quiz Timer Stopwatch for Lab Use Racer Brand Stopwatch Stopwatch with Lap Time Stopwatch with Split Time 1/100 Second Stopwatch Stopwatch for Yoga Timer for Physical Education School Lab Equipment Racer Stopwatch Supplier Racer Stopwatch Manufacturer Stopwatch for Samagra Shiksha Stopwatch for Jaadui Pitara Stopwatch for NCERT Kit Stopwatch for Science Kits Stopwatch for Sports Kits Stopwatch for Teachers Stopwatch for Students Stopwatch India Stopwatch Plastic Stopwatch Battery Stopwatch Stopwatch with Lanyard Stopwatch for Track and Field Digital Timer Stopwatch for Olympiads Stopwatch for Events Stopwatch for Experiments Stopwatch for Schools Educational Stopwatch Timer Stopwatch Stopwatch Racer Timer Racer Digital Stopwatch with Battery Stopwatch for Exams Racer Sports Timer Stopwatch for Competitions Stopwatch Exporter from India Educational Tools Stopwatch School Use Timer Racing Stopwatch Coach Stopwatch School Timer Handheld Stopwatch India Stop Watch Racer Stop Watch Digital Stop Watch for Schools
Newton force meter or spring scale
Request Callback
₹ 2200 / Piece Get Latest Price
| Weighing Capacity | 5 Kg |
| Material | Stainless Steel |
| Country of Origin | Made in India |
| Usage | Laboratory |
| Finish | Stainless Steel Polished Finish |
Minimum order quantity: 100 Piece
The Stainless Steel Newton Force Meter or Spring Scale with a 5 kg capacity is a precision-engineered mechanical device designed to measure force and weight in educational, industrial, and laboratory environments. Built with high-grade stainless steel, this instrument offers superior durability, resistance to corrosion, and long-lasting performance, even under frequent use. Its primary function is to measure force in Newtons or weight in kilograms, making it an essential tool for physics experiments, mechanical testing, and classroom demonstrations where an understanding of force, mass, and gravity is fundamental.
With a maximum weighing capacity of 5 kg, this Newton force meter provides accurate readings suitable for a wide range of applications, from simple educational setups to more advanced mechanical studies. It is calibrated to deliver consistent performance, ensuring that students and professionals alike can rely on it for precise and repeatable results. Whether used in a school lab for learning Newton’s Laws of Motion or in a workshop for testing the tension and resistance of materials, this spring scale serves its purpose with clarity and reliability.
The polished finish of the stainless steel body adds a professional aesthetic to the instrument, while also enhancing its resistance to environmental wear, chemicals, and moisture. This makes it particularly suitable for lab environments where exposure to varying conditions is common. Its robust construction ensures that the scale maintains its structural integrity even when subjected to repeated loading and unloading cycles. The metal components are securely assembled to prevent misalignment or measurement drift over time, which is crucial for maintaining accuracy.
This particular model, identified as Model No. 256, is designed with user experience in mind. It features a smooth operation mechanism that allows users to easily attach weights or objects to the hook for measurement without the need for complex setup or calibration. The internal spring system is engineered to provide a uniform force response, and the scale markings are clearly visible for easy reading. The blue-colored outer casing adds a visual appeal while also providing some visual differentiation in lab settings with multiple instruments.
One of the standout features of this Newton force meter is its versatility. It is not limited to just educational use but is equally effective in industrial or commercial scenarios where force measurement is required without the use of digital equipment. This makes it a valuable tool for technicians, researchers, educators, and students who prefer analog instrumentation or require a backup measurement method without dependency on batteries or power sources.
In classrooms, this spring scale is commonly used to teach the relationship between mass and gravitational force, showcasing how weight changes with varying gravitational pull. Its clear Newton calibration also helps students understand the concept of force as a vector quantity. It can also be used in science fairs, project exhibitions, and mechanical workshops for demonstrating basic principles of physics and mechanics in an interactive, tangible way.
Overall, the Stainless Steel Newton Force Meter or Spring Scale with a 5 kg capacity is a reliable, accurate, and durable instrument that stands out for its mechanical precision, build quality, and versatility. With its polished finish, corrosion-resistant stainless steel construction, and educational utility, it is an excellent addition to any lab, classroom, or industrial setting where accurate force measurement is essential. Its ease of use, long life, and consistent performance make it an indispensable tool in any setting that values mechanical precision and hands-on learning.
With a maximum weighing capacity of 5 kg, this Newton force meter provides accurate readings suitable for a wide range of applications, from simple educational setups to more advanced mechanical studies. It is calibrated to deliver consistent performance, ensuring that students and professionals alike can rely on it for precise and repeatable results. Whether used in a school lab for learning Newton’s Laws of Motion or in a workshop for testing the tension and resistance of materials, this spring scale serves its purpose with clarity and reliability.
The polished finish of the stainless steel body adds a professional aesthetic to the instrument, while also enhancing its resistance to environmental wear, chemicals, and moisture. This makes it particularly suitable for lab environments where exposure to varying conditions is common. Its robust construction ensures that the scale maintains its structural integrity even when subjected to repeated loading and unloading cycles. The metal components are securely assembled to prevent misalignment or measurement drift over time, which is crucial for maintaining accuracy.
This particular model, identified as Model No. 256, is designed with user experience in mind. It features a smooth operation mechanism that allows users to easily attach weights or objects to the hook for measurement without the need for complex setup or calibration. The internal spring system is engineered to provide a uniform force response, and the scale markings are clearly visible for easy reading. The blue-colored outer casing adds a visual appeal while also providing some visual differentiation in lab settings with multiple instruments.
One of the standout features of this Newton force meter is its versatility. It is not limited to just educational use but is equally effective in industrial or commercial scenarios where force measurement is required without the use of digital equipment. This makes it a valuable tool for technicians, researchers, educators, and students who prefer analog instrumentation or require a backup measurement method without dependency on batteries or power sources.
In classrooms, this spring scale is commonly used to teach the relationship between mass and gravitational force, showcasing how weight changes with varying gravitational pull. Its clear Newton calibration also helps students understand the concept of force as a vector quantity. It can also be used in science fairs, project exhibitions, and mechanical workshops for demonstrating basic principles of physics and mechanics in an interactive, tangible way.
Overall, the Stainless Steel Newton Force Meter or Spring Scale with a 5 kg capacity is a reliable, accurate, and durable instrument that stands out for its mechanical precision, build quality, and versatility. With its polished finish, corrosion-resistant stainless steel construction, and educational utility, it is an excellent addition to any lab, classroom, or industrial setting where accurate force measurement is essential. Its ease of use, long life, and consistent performance make it an indispensable tool in any setting that values mechanical precision and hands-on learning.
Digital Electro Convulsometer
Request Callback
₹ 20000 / Piece Get Latest Price
| Country of Origin | Made in India |
| Material | Mild Steel |
| Voltage | 220V |
| Frequency | 50Hz |
| Display | Digital |
| Usage/Application | Laboratory |
Minimum order quantity: 1 Piece
The Digital Electro Convulsometer is a sophisticated laboratory instrument designed to deliver precise, controlled electrical stimuli for neuropharmacological research and physiological experimentation. Constructed from high-quality mild steel, this device is engineered to provide durability, safety, and long-term performance in rigorous research environments. It is specifically used in laboratories focused on neurobiology, psychopharmacology, and behavioral science for evaluating the convulsive thresholds and the anticonvulsant efficacy of various pharmaceutical compounds using animal models. The electro convulsometer plays a critical role in generating reproducible seizures, which are essential for testing and validating the therapeutic effectiveness of antiepileptic and CNS-active drugs.
This digital model stands out due to its user-friendly interface and advanced digital display system that enables accurate control and monitoring of current, frequency, and duration parameters. The display offers real-time visibility of output values, making it easier for researchers to maintain consistency across trials and minimize experimental error. With its 220V input voltage and 50Hz operating frequency, the convulsometer integrates seamlessly into standard laboratory electrical systems, requiring no additional configurations or adaptations. The device’s precise calibration and adjustable output ensure safe application of stimuli, reducing the risk of data inconsistency and enhancing the reliability of experimental outcomes.
Designed with functionality and researcher safety in mind, the mild steel body of the Digital Electro Convulsometer offers robust protection for internal electronic components while also resisting corrosion and mechanical damage. The solid build ensures operational stability even in high-throughput laboratories, where equipment is frequently moved or subjected to varying environmental conditions. The material’s strength supports the device’s internal circuitry, ensuring smooth, uninterrupted performance during sensitive testing procedures. Additionally, the instrument features insulated connectors and securely fitted terminals to prevent accidental discharge and ensure the safety of both the user and the test subjects.
The primary application of the Digital Electro Convulsometer lies in the induction of controlled seizures in experimental animal models, such as rats or mice, for preclinical screening of antiepileptic drugs. Researchers can adjust the stimulus parameters to mimic various seizure intensities and durations, thereby allowing detailed evaluation of drug efficacy across a range of conditions. The compact footprint of the unit allows it to fit conveniently on any laboratory bench, saving valuable space while offering high functionality. Its intuitive controls and digital precision enable both experienced researchers and students to operate the system with confidence and ease. As research continues to evolve in neuroscience and drug development, the demand for reliable, accurate, and reproducible convulsion-inducing systems makes this digital electro convulsometer an indispensable piece of laboratory equipment.
The Digital Electro Convulsometer made from mild steel is a precision laboratory instrument designed for neuropharmacological testing and behavioral research. With its 220V power input, 50Hz operating frequency, digital display, and durable construction, it provides unparalleled reliability, user safety, and experimental accuracy. This device remains a critical tool for laboratories engaged in antiepileptic drug discovery, central nervous system research, and electrophysiological studies, offering consistent performance and valuable insights into neural function and pharmacological response.
This digital model stands out due to its user-friendly interface and advanced digital display system that enables accurate control and monitoring of current, frequency, and duration parameters. The display offers real-time visibility of output values, making it easier for researchers to maintain consistency across trials and minimize experimental error. With its 220V input voltage and 50Hz operating frequency, the convulsometer integrates seamlessly into standard laboratory electrical systems, requiring no additional configurations or adaptations. The device’s precise calibration and adjustable output ensure safe application of stimuli, reducing the risk of data inconsistency and enhancing the reliability of experimental outcomes.
Designed with functionality and researcher safety in mind, the mild steel body of the Digital Electro Convulsometer offers robust protection for internal electronic components while also resisting corrosion and mechanical damage. The solid build ensures operational stability even in high-throughput laboratories, where equipment is frequently moved or subjected to varying environmental conditions. The material’s strength supports the device’s internal circuitry, ensuring smooth, uninterrupted performance during sensitive testing procedures. Additionally, the instrument features insulated connectors and securely fitted terminals to prevent accidental discharge and ensure the safety of both the user and the test subjects.
The primary application of the Digital Electro Convulsometer lies in the induction of controlled seizures in experimental animal models, such as rats or mice, for preclinical screening of antiepileptic drugs. Researchers can adjust the stimulus parameters to mimic various seizure intensities and durations, thereby allowing detailed evaluation of drug efficacy across a range of conditions. The compact footprint of the unit allows it to fit conveniently on any laboratory bench, saving valuable space while offering high functionality. Its intuitive controls and digital precision enable both experienced researchers and students to operate the system with confidence and ease. As research continues to evolve in neuroscience and drug development, the demand for reliable, accurate, and reproducible convulsion-inducing systems makes this digital electro convulsometer an indispensable piece of laboratory equipment.
The Digital Electro Convulsometer made from mild steel is a precision laboratory instrument designed for neuropharmacological testing and behavioral research. With its 220V power input, 50Hz operating frequency, digital display, and durable construction, it provides unparalleled reliability, user safety, and experimental accuracy. This device remains a critical tool for laboratories engaged in antiepileptic drug discovery, central nervous system research, and electrophysiological studies, offering consistent performance and valuable insights into neural function and pharmacological response.
Antibiotic Zone Reader
Request Callback
₹ 6000 / Piece Get Latest Price
| Usage/Application | Laboratory |
| Brand | A.S.Int'L |
| Material | Mild Steel |
| Frequency | 50Hz |
| Phase | Three Phase |
| Power Source | electric |
| Country of Origin | Made in India |
Minimum order quantity: 1 Piece
The Antibiotic Zone Reader is a precision laboratory instrument designed to accurately measure the diameter of inhibition zones in petri dishes during antibiotic sensitivity testing. This essential device is widely used in microbiology, pharmaceutical, and clinical laboratories to evaluate the effectiveness of antibiotics against specific bacteria. Constructed from high-quality mild steel, the instrument offers long-lasting durability, structural stability, and resistance to corrosion, making it suitable for routine use in demanding laboratory environments. Its robust design ensures that it can withstand frequent handling and heavy-duty use without compromising measurement accuracy or operational efficiency.
This electric-powered device is designed to operate on a three-phase electrical system, with a frequency of 50Hz, ensuring compatibility with standard laboratory power configurations. Its energy-efficient performance and low maintenance requirements make it a reliable and cost-effective addition to any microbiological or pharmacological testing facility. The Antibiotic Zone Reader is engineered to deliver precise and reproducible measurements by magnifying the zone of inhibition and allowing technicians to read the diameter with utmost clarity and accuracy. This feature is particularly useful when conducting agar diffusion tests such as the Kirby-Bauer method, where exact zone measurement is critical to determining bacterial resistance or susceptibility to antibiotics.
The measuring platform of the device is designed to securely hold standard petri dishes while providing a clear and magnified view of the bacterial growth and the inhibition zone surrounding antibiotic discs. The built-in measurement scale, often in millimeters, allows for direct and precise reading of the inhibition diameter, eliminating the need for manual measurement using rulers or calipers, which can be subject to human error. This makes the Antibiotic Zone Reader a valuable tool for standardizing results across multiple tests and ensuring consistency in data reporting.
In laboratories where accurate antimicrobial susceptibility testing is essential, the Antibiotic Zone Reader enhances both efficiency and reliability. It is particularly indispensable in quality control labs, research institutions, educational settings, and hospital laboratories. By enabling accurate assessment of antibiotic effectiveness, this device plays a crucial role in guiding appropriate therapeutic decisions and monitoring emerging antibiotic resistance patterns.
The use of mild steel in the construction not only adds to the machine’s longevity but also gives it a solid, professional appearance suitable for any modern laboratory setting. The heavy-duty body resists wear and ensures the device remains stable during use, even when handling multiple samples. Its electric operation reduces operator fatigue and simplifies the measurement process, contributing to higher productivity in busy laboratory environments. Moreover, the three-phase power configuration offers consistent energy flow, reducing the chances of performance fluctuations during operation.
This device is designed with user convenience in mind, featuring intuitive controls and easy-to-read displays. Technicians can quickly operate the reader without extensive training, making it accessible to both experienced microbiologists and new lab personnel. The clear magnification lens and precise scale further enhance usability, ensuring that each reading is both quick and dependable.
Antibiotic Zone Reader is a high-performance, laboratory-grade instrument that combines robust construction, electrical efficiency, and exceptional measurement accuracy. Ideal for microbiological analysis and antimicrobial testing, it supports rigorous scientific research and clinical diagnostics by providing reliable and standardized data.
This electric-powered device is designed to operate on a three-phase electrical system, with a frequency of 50Hz, ensuring compatibility with standard laboratory power configurations. Its energy-efficient performance and low maintenance requirements make it a reliable and cost-effective addition to any microbiological or pharmacological testing facility. The Antibiotic Zone Reader is engineered to deliver precise and reproducible measurements by magnifying the zone of inhibition and allowing technicians to read the diameter with utmost clarity and accuracy. This feature is particularly useful when conducting agar diffusion tests such as the Kirby-Bauer method, where exact zone measurement is critical to determining bacterial resistance or susceptibility to antibiotics.
The measuring platform of the device is designed to securely hold standard petri dishes while providing a clear and magnified view of the bacterial growth and the inhibition zone surrounding antibiotic discs. The built-in measurement scale, often in millimeters, allows for direct and precise reading of the inhibition diameter, eliminating the need for manual measurement using rulers or calipers, which can be subject to human error. This makes the Antibiotic Zone Reader a valuable tool for standardizing results across multiple tests and ensuring consistency in data reporting.
In laboratories where accurate antimicrobial susceptibility testing is essential, the Antibiotic Zone Reader enhances both efficiency and reliability. It is particularly indispensable in quality control labs, research institutions, educational settings, and hospital laboratories. By enabling accurate assessment of antibiotic effectiveness, this device plays a crucial role in guiding appropriate therapeutic decisions and monitoring emerging antibiotic resistance patterns.
The use of mild steel in the construction not only adds to the machine’s longevity but also gives it a solid, professional appearance suitable for any modern laboratory setting. The heavy-duty body resists wear and ensures the device remains stable during use, even when handling multiple samples. Its electric operation reduces operator fatigue and simplifies the measurement process, contributing to higher productivity in busy laboratory environments. Moreover, the three-phase power configuration offers consistent energy flow, reducing the chances of performance fluctuations during operation.
This device is designed with user convenience in mind, featuring intuitive controls and easy-to-read displays. Technicians can quickly operate the reader without extensive training, making it accessible to both experienced microbiologists and new lab personnel. The clear magnification lens and precise scale further enhance usability, ensuring that each reading is both quick and dependable.
Antibiotic Zone Reader is a high-performance, laboratory-grade instrument that combines robust construction, electrical efficiency, and exceptional measurement accuracy. Ideal for microbiological analysis and antimicrobial testing, it supports rigorous scientific research and clinical diagnostics by providing reliable and standardized data.
Nuclear Chain Reaction Model
Request Callback
₹ 899 / Piece Get Latest Price
| Material | Wood |
| Size | 10 x 15 Inch |
| Color | White |
| Finish | Polished |
Minimum order quantity: 1 Piece
The Wood Nuclear Chain Reaction Model is an exceptional educational aid designed to visually demonstrate the complex process of nuclear fission in a clear, engaging, and simplified manner. Crafted from high-quality polished wood, this model measures approximately 10 x 15 inches, making it ideal for tabletop demonstrations in classrooms, laboratories, and science fairs. It is specifically designed to represent the breakdown of Uranium-235 (U-235) into Barium (Ba), Krypton (Kr), and additional neutrons, which trigger a self-sustaining chain reaction. The white-colored polished surface enhances the clarity of labels and pathways, allowing learners to easily follow the sequence of reactions and understand the fundamental principles of atomic energy and nuclear reactions.
This nuclear chain reaction model is a highly effective visual aid for educators teaching nuclear physics, atomic structure, or energy generation. It simplifies the concept of how a single neutron striking a U-235 nucleus can cause it to split into smaller nuclei like Barium and Krypton while releasing more neutrons and a significant amount of energy. These newly released neutrons continue to strike other U-235 atoms, perpetuating a chain reaction. This step-by-step breakdown is physically illustrated on the wooden panel, helping students visualize the abstract theory in a more concrete and memorable form. The model also helps emphasize the importance of nuclear reactions in energy generation, nuclear reactors, and atomic science, thereby making it an essential tool for science curriculum support.
In educational environments, the Wood Nuclear Chain Reaction Model encourages interactive learning by promoting student discussions, hands-on explanation, and teacher-guided analysis of nuclear reactions. The wooden construction ensures durability and long-term usability, making it suitable for repeated use in classrooms, workshops, and science outreach programs. The smooth polished finish and vibrant component labeling ensure high visibility and readability, while its lightweight and compact form make it easy to transport and display. Students can point out and trace the reaction path, reinforcing their understanding through active participation.
This model is particularly valuable in middle school, high school, and early college-level physics and chemistry classes, where students are first introduced to the concept of fission and chain reactions. By integrating visual and tactile elements, it makes a highly complex scientific phenomenon more accessible and less intimidating for learners. Furthermore, the inclusion of real scientific elements such as Uranium-235, Krypton, Barium, and neutrons aligns the model closely with actual nuclear science content, ensuring that students gain accurate and relevant knowledge.
On IndiaMART, the Wood Nuclear Chain Reaction Model is increasingly sought after by educators, science kit distributors, and institutional buyers looking for reliable and visually engaging teaching aids. It is well-suited for educational institutions seeking to upgrade their teaching materials with hands-on learning tools that support the NEP 2020's emphasis on experiential learning. The model also holds value for science hobbyists, museum demonstrators, and nuclear energy awareness campaigns aiming to educate the public about the benefits and risks of nuclear technology.
In summary, the Wood Nuclear Chain Reaction Model stands out as a highly informative and visually compelling educational product that simplifies the teaching of nuclear fission and chain reactions. With its durable wooden build, clear layout, and accurate scientific representation, this model provides a strong foundation for learners to explore one of the most powerful concepts in modern science.
This nuclear chain reaction model is a highly effective visual aid for educators teaching nuclear physics, atomic structure, or energy generation. It simplifies the concept of how a single neutron striking a U-235 nucleus can cause it to split into smaller nuclei like Barium and Krypton while releasing more neutrons and a significant amount of energy. These newly released neutrons continue to strike other U-235 atoms, perpetuating a chain reaction. This step-by-step breakdown is physically illustrated on the wooden panel, helping students visualize the abstract theory in a more concrete and memorable form. The model also helps emphasize the importance of nuclear reactions in energy generation, nuclear reactors, and atomic science, thereby making it an essential tool for science curriculum support.
In educational environments, the Wood Nuclear Chain Reaction Model encourages interactive learning by promoting student discussions, hands-on explanation, and teacher-guided analysis of nuclear reactions. The wooden construction ensures durability and long-term usability, making it suitable for repeated use in classrooms, workshops, and science outreach programs. The smooth polished finish and vibrant component labeling ensure high visibility and readability, while its lightweight and compact form make it easy to transport and display. Students can point out and trace the reaction path, reinforcing their understanding through active participation.
This model is particularly valuable in middle school, high school, and early college-level physics and chemistry classes, where students are first introduced to the concept of fission and chain reactions. By integrating visual and tactile elements, it makes a highly complex scientific phenomenon more accessible and less intimidating for learners. Furthermore, the inclusion of real scientific elements such as Uranium-235, Krypton, Barium, and neutrons aligns the model closely with actual nuclear science content, ensuring that students gain accurate and relevant knowledge.
On IndiaMART, the Wood Nuclear Chain Reaction Model is increasingly sought after by educators, science kit distributors, and institutional buyers looking for reliable and visually engaging teaching aids. It is well-suited for educational institutions seeking to upgrade their teaching materials with hands-on learning tools that support the NEP 2020's emphasis on experiential learning. The model also holds value for science hobbyists, museum demonstrators, and nuclear energy awareness campaigns aiming to educate the public about the benefits and risks of nuclear technology.
In summary, the Wood Nuclear Chain Reaction Model stands out as a highly informative and visually compelling educational product that simplifies the teaching of nuclear fission and chain reactions. With its durable wooden build, clear layout, and accurate scientific representation, this model provides a strong foundation for learners to explore one of the most powerful concepts in modern science.
Analogue Tensile Testing Machine
Request Callback
₹ 500000 / Piece Get Latest Price
| Display Type | Analogue |
| Body Material | Stainless Steel |
| Color | White |
| Size | 4 x 10 Inch |
| Thickness | 4mm |
- Reliable & Robust Mechanical Design: Engineered for durability, analogue machines often feature sturdy hydraulic or screw-driven mechanisms, providing consistent and reliable force application for accurate tensile testing.
- Direct & Clear Readouts: With large, easy-to-read dials, analogue machines offer direct display of load values, making it simple for operators to observe real-time testing progress and peak loads.
- Cost-Effective & Low Maintenance: Typically less complex than their digital counterparts, analogue tensile testers are often more budget-friendly and require minimal maintenance, offering long-term operational efficiency.
- Versatile for Diverse Material Testing: Equipped with various grips and fixtures, these machines can effectively test a wide range of materials including metals, plastics, rubber, and textiles, for properties like tensile strength and elongation.
Nuclear Fusion Model
Request Callback
₹ 450 / Piece Get Latest Price
| Function Type | Manual |
| Model Type | Non Working |
| Material | Plastic |
| Project Subject | Physics |
| Usage | Educational Use |
| Subject | Chemistry |
Minimum order quantity: 10 Piece
Acrylic Fusion Model with Plastic Beads – For Physics, Chemistry & Biology Lab Demonstrations
The Acrylic Fusion Model with Plastic Beads is a scientifically designed teaching aid ideal for Physics, Chemistry, and Biology laboratory demonstrations. Constructed from high-grade transparent acrylic, this model allows educators to visually demonstrate fundamental science concepts such as diffusion, fusion, particle motion, mixing, density separation, and kinetic molecular theory using colorful plastic beads. Perfect for STEM education, science exhibitions, and classroom experiments, it offers an engaging and interactive learning experience for students from middle school to senior secondary levels.
�� Product Specifications:-
Product Name: Acrylic Fusion Model with Plastic Beads
-
Body Material: High-impact transparent acrylic (PMMA) – 3 mm to 5 mm thickness
-
Overall Dimensions: 300 mm (L) × 200 mm (W) × 80 mm (H) – Custom sizes available
-
Beads Material: Colored plastic beads (HDPE / Acrylic / PP)
-
Bead Diameter: 5 mm to 10 mm – Assorted color pack
-
No. of Beads: 100–200 pieces included
-
Compartments: Single, Dual or Triple chambers (optional partitions)
-
Closure: Snap-lock lids or sliding top cover
-
Base: Stable rectangular base with anti-slip rubber feet
-
Weight: Approx. 1.2 Kg (including beads)
-
Usage: Demonstration of fusion, molecular motion, mixing, density, separation, fluid dynamics
-
Country of Origin: Made in India (Ambala)
-
Branding: Custom logo printing available for institutions
-
Made from crystal-clear acrylic for maximum visibility
-
Includes vibrant plastic beads that simulate particle motion
-
Ideal for showing fusion, kinetic energy, heat transfer, and density variation
-
Modular design with removable partitions for flexible usage
-
Shatter-resistant, lightweight, and easy to clean
-
Suitable for NEP 2020-based activity learning
-
Excellent for school demonstrations, science fairs, and practical sessions
-
Non-toxic, washable beads safe for classroom use
-
Works without electricity – perfect for manual lab setups
-
Designed and manufactured by trusted Indian suppliers in Ambala Science Market
-
Demonstrate particle movement under external force
-
Show energy distribution and molecular collisions
-
Simulate kinetic molecular theory and Brownian motion
-
Visualize Newtonian dynamics in particulate systems
-
Explain molecular diffusion between different zones
-
Simulate chemical mixing and solution concentration gradients
-
Visualize solid-liquid or gas interactions
-
Teach thermodynamics, entropy, and fluidic behavior
-
Represent cell transport phenomena and osmosis analogies
-
Illustrate membrane diffusion and cytoplasmic streaming
-
Simulate nutrient movement across compartments
-
Used as a passive analog model in inquiry-based learning
-
Enhance cognitive understanding of real-world systems
-
Applied in hands-on maker labs and school STEM corners
Laboratory Muffle Furnace
Request Callback
₹ 13000 / Piece Get Latest Price
| Temperature Range | 250 Degree C |
| Country of Origin | Made in India |
| Automation Grade | Automatic |
| Surface Finish | Stainless Steel |
| Rated Power | 2kW |
| Input Voltage | 240V |
| Usage | Laboratory |
Minimum order quantity: 1 Piece
The 250 Degree C Laboratory Muffle Furnace is a high-precision heating device engineered for consistent performance in laboratory environments requiring controlled high-temperature operations. Designed to meet the demanding requirements of modern scientific and industrial research, this muffle furnace is ideal for applications such as material testing, ash determination, heat treatment of samples, and thermal decomposition processes. Operating at a maximum temperature of 250 degrees Celsius, it offers reliable and uniform heat distribution, ensuring accurate and reproducible results across a wide range of laboratory functions. This makes it an essential piece of equipment in educational institutions, research labs, material science centers, and quality control departments.
Manufactured with an emphasis on durability and functionality, the outer surface of this laboratory muffle furnace is finished in premium-grade stainless steel, offering resistance to rust, chemical corrosion, and mechanical wear. Its sturdy construction ensures that it can endure the high-heat environments and constant use typical in lab settings. The internal heating chamber is well-insulated and designed to minimize heat loss while maintaining a stable and safe external surface temperature. With its compact footprint and efficient build, this furnace fits seamlessly on laboratory benches, optimizing space without compromising on performance.
This laboratory muffle furnace is fully automatic, allowing users to control and monitor temperature settings with ease and precision. The automation features significantly reduce manual intervention, making the furnace user-friendly and ideal for repetitive heating cycles. The digital interface and integrated controls ensure that temperature parameters can be set, monitored, and maintained with minimal fluctuation. This level of automation also contributes to energy efficiency, prolonging the life of the unit and reducing operational costs. Safety features are built into the system, offering thermal protection and overload safeguards to prevent any accidental damage or operational mishaps.
Powered by a rated 2kW energy input, the muffle furnace operates on a standard input voltage of 240V, ensuring compatibility with most laboratory power systems. Its energy-efficient design ensures optimal thermal output while keeping electricity consumption in check. This is particularly valuable for labs operating under energy constraints or aiming to implement green practices without compromising on functionality or precision. Whether used in educational labs for student training or in professional research facilities, the muffle furnace delivers consistent and reliable performance under varied experimental conditions.
In terms of usability, the muffle furnace provides quick heat-up times and uniform temperature control, making it suitable for a range of applications including ceramic sintering, metal annealing, ashing organic and inorganic samples, and conducting controlled material experiments. The ergonomic design ensures ease of access to the chamber while maintaining safety standards. Its robust stainless-steel body, combined with advanced heating technology, guarantees longevity and low maintenance, even with intensive daily use. With high demand in academic, pharmaceutical, metallurgy, and industrial testing labs, this furnace stands out as a dependable tool for high-accuracy thermal processing tasks.
In summary, this stainless steel, 250 Degree C muffle furnace is the ideal laboratory heating solution, offering robust construction, user-friendly automation, energy efficiency, and reliable thermal performance. Its precision design and functionality make it a valuable asset for any laboratory aiming for high-quality results in a safe and controlled heating environment.
Manufactured with an emphasis on durability and functionality, the outer surface of this laboratory muffle furnace is finished in premium-grade stainless steel, offering resistance to rust, chemical corrosion, and mechanical wear. Its sturdy construction ensures that it can endure the high-heat environments and constant use typical in lab settings. The internal heating chamber is well-insulated and designed to minimize heat loss while maintaining a stable and safe external surface temperature. With its compact footprint and efficient build, this furnace fits seamlessly on laboratory benches, optimizing space without compromising on performance.
This laboratory muffle furnace is fully automatic, allowing users to control and monitor temperature settings with ease and precision. The automation features significantly reduce manual intervention, making the furnace user-friendly and ideal for repetitive heating cycles. The digital interface and integrated controls ensure that temperature parameters can be set, monitored, and maintained with minimal fluctuation. This level of automation also contributes to energy efficiency, prolonging the life of the unit and reducing operational costs. Safety features are built into the system, offering thermal protection and overload safeguards to prevent any accidental damage or operational mishaps.
Powered by a rated 2kW energy input, the muffle furnace operates on a standard input voltage of 240V, ensuring compatibility with most laboratory power systems. Its energy-efficient design ensures optimal thermal output while keeping electricity consumption in check. This is particularly valuable for labs operating under energy constraints or aiming to implement green practices without compromising on functionality or precision. Whether used in educational labs for student training or in professional research facilities, the muffle furnace delivers consistent and reliable performance under varied experimental conditions.
In terms of usability, the muffle furnace provides quick heat-up times and uniform temperature control, making it suitable for a range of applications including ceramic sintering, metal annealing, ashing organic and inorganic samples, and conducting controlled material experiments. The ergonomic design ensures ease of access to the chamber while maintaining safety standards. Its robust stainless-steel body, combined with advanced heating technology, guarantees longevity and low maintenance, even with intensive daily use. With high demand in academic, pharmaceutical, metallurgy, and industrial testing labs, this furnace stands out as a dependable tool for high-accuracy thermal processing tasks.
In summary, this stainless steel, 250 Degree C muffle furnace is the ideal laboratory heating solution, offering robust construction, user-friendly automation, energy efficiency, and reliable thermal performance. Its precision design and functionality make it a valuable asset for any laboratory aiming for high-quality results in a safe and controlled heating environment.
Bicycle Dynamo Set
Request Callback
₹ 750 / Piece Get Latest Price
| Material | Aluminum Alloy |
| Voltage | 6 V |
| Output Power | 3 Watt |
| Mount Location | Front |
| Additional Features | Portable |
Minimum order quantity: 10 Piece
The Bicycle Dynamo Set Physics Model is an innovative and interactive educational tool specifically designed to demonstrate the practical application of electromagnetic induction and energy conversion principles in physics. Constructed from high-quality aluminum alloy, this physics model combines lightweight durability with high functionality, ensuring that it withstands repeated use in classroom or laboratory environments. Ideal for science demonstrations, this set enables students to visually grasp how mechanical energy from motion is transformed into electrical energy, offering a tangible representation of core scientific concepts.
Operating at a voltage of 6 volts with an output power of 3 watts, this bicycle dynamo set provides a real-world example of energy generation. It effectively illustrates the fundamental working of a dynamo system as used in bicycles, where mechanical motion—typically generated by pedaling—drives the dynamo to produce electricity. This electricity can then be used to power a small bulb or light, making the set not only educational but also functionally demonstrative. This hands-on experience helps students understand the dynamics of alternating current (AC) generation and the role of conductors and magnetic fields in electricity production.
This model is particularly effective in illustrating Faraday’s law of electromagnetic induction. As the aluminum alloy dynamo rotates, it exposes students to the interactions between magnetic fields and conductors, showcasing the creation of electric current through movement. With its compact and portable design, it is easy to transport and integrate into various classroom setups or science fair projects. Its mountable front location allows for versatile placement, either on a mock-up bicycle frame, demonstration board, or any custom setup used to simulate rotational motion.
The Bicycle Dynamo Set Physics Model encourages inquiry-based learning by allowing learners to observe cause-and-effect relationships in real time. Teachers can use it to explain key concepts such as the role of resistance in circuits, the conversion efficiency of mechanical to electrical energy, and the environmental benefits of human-powered energy solutions. As such, it supports curriculum objectives for classes studying electricity, motion, magnetism, and sustainable energy sources. Moreover, the low-voltage, safe operation of the model makes it suitable for secondary school and early college-level physics education without the need for complex or hazardous setups.
Designed with precision and ease of use in mind, this model requires minimal maintenance. The aluminum alloy body ensures rust resistance and long-lasting performance, even after extended use. Its streamlined design and functionality make it an ideal inclusion in school laboratories, teacher training institutes, and interactive science museums where demonstrating the relationship between mechanical movement and electricity is a learning priority.
Being readily available and in stock, the Bicycle Dynamo Set Physics Model is a reliable resource for enhancing STEM education. It supports a multidisciplinary learning experience by integrating principles of mechanics, electronics, and environmental science. With this model, educators can promote hands-on learning and spark students’ interest in real-world applications of physics. Its clear, visible results make abstract scientific theories accessible and exciting for students, thereby reinforcing theoretical knowledge through experiential practice. This model serves as a key educational asset for institutions aiming to deliver quality science education with engaging, functional tools.
Operating at a voltage of 6 volts with an output power of 3 watts, this bicycle dynamo set provides a real-world example of energy generation. It effectively illustrates the fundamental working of a dynamo system as used in bicycles, where mechanical motion—typically generated by pedaling—drives the dynamo to produce electricity. This electricity can then be used to power a small bulb or light, making the set not only educational but also functionally demonstrative. This hands-on experience helps students understand the dynamics of alternating current (AC) generation and the role of conductors and magnetic fields in electricity production.
This model is particularly effective in illustrating Faraday’s law of electromagnetic induction. As the aluminum alloy dynamo rotates, it exposes students to the interactions between magnetic fields and conductors, showcasing the creation of electric current through movement. With its compact and portable design, it is easy to transport and integrate into various classroom setups or science fair projects. Its mountable front location allows for versatile placement, either on a mock-up bicycle frame, demonstration board, or any custom setup used to simulate rotational motion.
The Bicycle Dynamo Set Physics Model encourages inquiry-based learning by allowing learners to observe cause-and-effect relationships in real time. Teachers can use it to explain key concepts such as the role of resistance in circuits, the conversion efficiency of mechanical to electrical energy, and the environmental benefits of human-powered energy solutions. As such, it supports curriculum objectives for classes studying electricity, motion, magnetism, and sustainable energy sources. Moreover, the low-voltage, safe operation of the model makes it suitable for secondary school and early college-level physics education without the need for complex or hazardous setups.
Designed with precision and ease of use in mind, this model requires minimal maintenance. The aluminum alloy body ensures rust resistance and long-lasting performance, even after extended use. Its streamlined design and functionality make it an ideal inclusion in school laboratories, teacher training institutes, and interactive science museums where demonstrating the relationship between mechanical movement and electricity is a learning priority.
Being readily available and in stock, the Bicycle Dynamo Set Physics Model is a reliable resource for enhancing STEM education. It supports a multidisciplinary learning experience by integrating principles of mechanics, electronics, and environmental science. With this model, educators can promote hands-on learning and spark students’ interest in real-world applications of physics. Its clear, visible results make abstract scientific theories accessible and exciting for students, thereby reinforcing theoretical knowledge through experiential practice. This model serves as a key educational asset for institutions aiming to deliver quality science education with engaging, functional tools.
Lab Burette Clamp
Request Callback
₹ 500 / Piece Get Latest Price
| Material | Mild Steel |
| Corrosion Resistance | Yes |
| Size | 1.5 Inch |
| Country of Origin | Made in India |
| Surface Treatment | Powder Coated |
| Color | Beige |
Minimum order quantity: 100 Piece
The Lab Burette Clamp in a 1.5-inch size is a highly functional and durable laboratory accessory designed to securely hold burettes during titration and other chemical experiments. Made from high-quality mild steel (MS), this clamp is built to withstand the rigorous demands of laboratory environments while providing a stable and precise grip on glassware. Its compact size of 1.5 inches makes it suitable for a variety of lab setups, allowing it to accommodate standard burette diameters with ease and ensuring that the equipment remains securely in place throughout experimental procedures. This makes it an essential component in chemistry laboratories across educational institutions, research centers, and industrial labs.
One of the key advantages of this burette clamp is its excellent corrosion resistance. Laboratories often expose their equipment to chemicals, moisture, and varying temperatures, all of which can compromise the integrity of metal components. To address this, the Lab Burette Clamp is specially treated with a painted surface finish that acts as a protective barrier against corrosive agents. This not only enhances the longevity of the clamp but also ensures consistent performance over time, even with frequent exposure to harsh conditions. The surface treatment also gives the clamp a smooth and clean finish, contributing to its aesthetic appeal and making it easier to clean and maintain.
The beige color of the clamp adds a professional and neutral tone to laboratory setups, blending seamlessly with various lab apparatus and furniture. Its ergonomic design ensures that the clamp can be easily attached to retort stands or other supporting structures, while the gripping arms are shaped to hold burettes firmly without causing damage or slippage. This is especially important during titration, where accuracy and precision are critical. The clamp’s secure hold prevents unnecessary movement or tipping, allowing for more accurate measurement and drop-by-drop control during chemical reactions.
Engineered with both functionality and safety in mind, this burette clamp provides laboratory users with the confidence that their glassware is held securely and stably. Its robust MS construction ensures structural integrity under stress, making it suitable for heavy-duty use in demanding lab conditions. The painted surface not only improves resistance to corrosion but also adds to the overall strength and durability of the clamp. Whether used in high school laboratories for educational demonstrations or in advanced research labs for precise titrations, this clamp offers reliable performance across a range of applications.
In addition to its technical capabilities, the 1.5-inch Lab Burette Clamp is designed for user convenience. It is easy to install, adjust, and remove, allowing for efficient lab workflows and minimizing setup time. The clamp’s design ensures compatibility with a wide range of lab stands and supports, making it a versatile tool that fits seamlessly into existing laboratory equipment. Its strong grip and corrosion-resistant properties make it an economical and long-term solution for securely holding delicate lab glassware.
Overall, the Lab Burette Clamp in beige color with a 1.5-inch size offers an ideal combination of durability, precision, and ease of use. Its mild steel construction, painted corrosion-resistant finish, and functional design make it an indispensable tool in any laboratory that requires reliable support for burettes and other glassware during critical scientific procedures.
One of the key advantages of this burette clamp is its excellent corrosion resistance. Laboratories often expose their equipment to chemicals, moisture, and varying temperatures, all of which can compromise the integrity of metal components. To address this, the Lab Burette Clamp is specially treated with a painted surface finish that acts as a protective barrier against corrosive agents. This not only enhances the longevity of the clamp but also ensures consistent performance over time, even with frequent exposure to harsh conditions. The surface treatment also gives the clamp a smooth and clean finish, contributing to its aesthetic appeal and making it easier to clean and maintain.
The beige color of the clamp adds a professional and neutral tone to laboratory setups, blending seamlessly with various lab apparatus and furniture. Its ergonomic design ensures that the clamp can be easily attached to retort stands or other supporting structures, while the gripping arms are shaped to hold burettes firmly without causing damage or slippage. This is especially important during titration, where accuracy and precision are critical. The clamp’s secure hold prevents unnecessary movement or tipping, allowing for more accurate measurement and drop-by-drop control during chemical reactions.
Engineered with both functionality and safety in mind, this burette clamp provides laboratory users with the confidence that their glassware is held securely and stably. Its robust MS construction ensures structural integrity under stress, making it suitable for heavy-duty use in demanding lab conditions. The painted surface not only improves resistance to corrosion but also adds to the overall strength and durability of the clamp. Whether used in high school laboratories for educational demonstrations or in advanced research labs for precise titrations, this clamp offers reliable performance across a range of applications.
In addition to its technical capabilities, the 1.5-inch Lab Burette Clamp is designed for user convenience. It is easy to install, adjust, and remove, allowing for efficient lab workflows and minimizing setup time. The clamp’s design ensures compatibility with a wide range of lab stands and supports, making it a versatile tool that fits seamlessly into existing laboratory equipment. Its strong grip and corrosion-resistant properties make it an economical and long-term solution for securely holding delicate lab glassware.
Overall, the Lab Burette Clamp in beige color with a 1.5-inch size offers an ideal combination of durability, precision, and ease of use. Its mild steel construction, painted corrosion-resistant finish, and functional design make it an indispensable tool in any laboratory that requires reliable support for burettes and other glassware during critical scientific procedures.
Hot Plate Magnetic Stirrer
Request Callback
₹ 4500 / Piece Get Latest Price
| Material | Cast Iron |
| Brand | A.S. Int'L |
| Hotplate Surface | with hotplate |
| Country of Origin | Made in India |
| Number of Plates | 1 Plate |
| Type | Electric Hot Plate |
| Voltage | 240V |
| Frequency | 50Hz |
| Phase | Single Phase |
Minimum order quantity: 10 Piece
The Cast Iron Hot Plate Magnetic Stirrer is a highly efficient and durable laboratory instrument designed for consistent heating and simultaneous stirring of solutions. Built with a robust cast iron body, this electric hot plate ensures long-term durability and uniform heat distribution, making it an essential tool in laboratories requiring reliable thermal and mixing performance. The solid cast iron construction not only provides mechanical strength and stability but also offers superior resistance to corrosion, chemical exposure, and wear from repeated laboratory use. Its rugged design supports a wide range of laboratory applications, from simple solution heating to complex chemical synthesis and sample preparation.
This magnetic stirrer features a single heating plate that provides uniform and controlled heat output, ensuring optimal temperature maintenance throughout the experiment. The hot plate operates on a standard 240V power supply and functions at a frequency of 50Hz, making it compatible with standard electrical systems used in laboratories across various regions. With a single-phase electrical configuration, the hot plate magnetic stirrer is energy-efficient and easy to operate, even in compact workspaces. Its electric design eliminates the need for external gas or flame sources, offering a safer and more controlled heating environment—ideal for sensitive chemical processes and temperature-dependent experiments.
Engineered to support magnetic stirring functions, this device is equipped with an integrated motor and magnetic mechanism that allows for efficient mixing of solutions during heating. This feature is particularly beneficial when working with viscous liquids or solutions that require constant agitation to prevent precipitation or separation. The magnetic stirrer enables smooth, silent, and splash-free stirring, maintaining sample homogeneity while minimizing manual intervention. Its performance contributes to consistent experimental outcomes and improved lab productivity.
Safety is a top priority in any laboratory setting, and the cast iron build of this magnetic stirrer adds an extra layer of safety and reliability. The device is designed to withstand high temperatures and extended operational hours without compromising functionality. The surface of the hot plate remains stable during use, ensuring secure placement of glassware and reaction vessels. The cast iron top also promotes even heat distribution, which helps prevent localized overheating and ensures accurate and reproducible results during thermal reactions or solution preparations.
This electric hot plate magnetic stirrer is ideally suited for use in research laboratories, academic institutions, industrial testing centers, and pharmaceutical labs. It supports a broad range of scientific applications including reagent heating, sample dilution, buffer preparation, and other temperature-sensitive processes. Its simple operation, combined with advanced performance features, makes it a valuable addition to any lab requiring precise heat and stirring capabilities.
In terms of design, the hot plate stirrer is compact and user-friendly, making it suitable for benchtop use without taking up excessive space. Its single-plate format allows focused and efficient energy use, especially useful when working with small to medium-sized volumes. The straightforward controls and stable power configuration ensure ease of use, even for individuals with limited technical experience.
In summary, the Cast Iron Hot Plate Magnetic Stirrer is a powerful, reliable, and versatile tool for modern laboratories. With its durable cast iron construction, precise electric heating, and effective magnetic stirring function, it delivers dependable performance and enhances experimental accuracy across various scientific and industrial applications.
This magnetic stirrer features a single heating plate that provides uniform and controlled heat output, ensuring optimal temperature maintenance throughout the experiment. The hot plate operates on a standard 240V power supply and functions at a frequency of 50Hz, making it compatible with standard electrical systems used in laboratories across various regions. With a single-phase electrical configuration, the hot plate magnetic stirrer is energy-efficient and easy to operate, even in compact workspaces. Its electric design eliminates the need for external gas or flame sources, offering a safer and more controlled heating environment—ideal for sensitive chemical processes and temperature-dependent experiments.
Engineered to support magnetic stirring functions, this device is equipped with an integrated motor and magnetic mechanism that allows for efficient mixing of solutions during heating. This feature is particularly beneficial when working with viscous liquids or solutions that require constant agitation to prevent precipitation or separation. The magnetic stirrer enables smooth, silent, and splash-free stirring, maintaining sample homogeneity while minimizing manual intervention. Its performance contributes to consistent experimental outcomes and improved lab productivity.
Safety is a top priority in any laboratory setting, and the cast iron build of this magnetic stirrer adds an extra layer of safety and reliability. The device is designed to withstand high temperatures and extended operational hours without compromising functionality. The surface of the hot plate remains stable during use, ensuring secure placement of glassware and reaction vessels. The cast iron top also promotes even heat distribution, which helps prevent localized overheating and ensures accurate and reproducible results during thermal reactions or solution preparations.
This electric hot plate magnetic stirrer is ideally suited for use in research laboratories, academic institutions, industrial testing centers, and pharmaceutical labs. It supports a broad range of scientific applications including reagent heating, sample dilution, buffer preparation, and other temperature-sensitive processes. Its simple operation, combined with advanced performance features, makes it a valuable addition to any lab requiring precise heat and stirring capabilities.
In terms of design, the hot plate stirrer is compact and user-friendly, making it suitable for benchtop use without taking up excessive space. Its single-plate format allows focused and efficient energy use, especially useful when working with small to medium-sized volumes. The straightforward controls and stable power configuration ensure ease of use, even for individuals with limited technical experience.
In summary, the Cast Iron Hot Plate Magnetic Stirrer is a powerful, reliable, and versatile tool for modern laboratories. With its durable cast iron construction, precise electric heating, and effective magnetic stirring function, it delivers dependable performance and enhances experimental accuracy across various scientific and industrial applications.
Newton 1st Law Model
Request Callback
₹ 2406 / Piece Get Latest Price
| Material | Stainless Steel |
| Project Subject | Physics |
| Recommended Class | 9-12 |
| Usage | Educational & learning purpose |
Minimum order quantity: 100 Piece
The Newton’s First Law Model is a meticulously designed educational apparatus crafted from durable stainless steel, intended to visually and practically demonstrate one of the fundamental principles of classical physics—Newton’s First Law of Motion. Also known as the Law of Inertia, this principle states that an object at rest stays at rest, and an object in motion continues in motion with the same speed and in the same direction unless acted upon by an unbalanced external force. This model is ideal for students in classes 9 through 12, offering a hands-on, engaging method for understanding a concept that underpins much of mechanical physics.
Made entirely from premium stainless steel, the model is built to withstand frequent classroom handling, ensuring long-term durability and safety during demonstrations. The polished surface and robust framework reflect a professional-grade build, which not only makes the model aesthetically appealing but also resistant to corrosion, wear, and damage. Stainless steel provides the strength and stability necessary to conduct accurate and repeatable experiments, making this model suitable for continuous use in both school laboratories and science exhibition settings.
The Newton’s First Law Model allows educators to illustrate how an object will maintain its current state—either at rest or in uniform motion—unless disturbed by an external force. This demonstration is particularly effective in helping students understand the practical implications of inertia, force, and motion. The setup typically includes a base, a track, and a movable object (such as a ball or slider) that can be used to demonstrate motion in a straight line. By removing friction or minimizing it through smooth surfaces and balanced design, students are able to observe nearly ideal inertial behavior, reinforcing their theoretical understanding with real-world visualization.
Recommended specifically for physics learning and science projects, this model aligns seamlessly with school curriculums and examination boards. It supports interactive learning and conceptual clarity by offering students a tangible way to experience Newton’s laws, rather than relying solely on textbook explanations. As students manipulate the components, they can observe how motion is sustained until a force—such as friction, impact, or resistance—is introduced, thereby altering the object's velocity or direction. Such real-time experimentation fosters critical thinking, curiosity, and a deeper grasp of physics principles.
The Newton’s First Law Model is not just a classroom tool but also an excellent resource for science fairs, laboratory assessments, and physics workshops. Its compact yet effective design makes it easy to set up and operate, requiring minimal maintenance while delivering consistent performance. The sturdy stainless steel construction ensures that the model retains its form and function across numerous demonstrations, making it a valuable addition to any physics teaching lab.
In summary, the Newton’s First Law Model made from stainless steel is a high-quality, curriculum-aligned educational resource for classes 9 to 12. It brings theoretical physics to life through practical demonstration, enabling students to witness firsthand the behavior of objects in rest and motion as described by Newton’s First Law. Ideal for academic institutions, this model fosters a deeper understanding of inertia, motion, and force while promoting interactive and experiential learning in physics education.
Made entirely from premium stainless steel, the model is built to withstand frequent classroom handling, ensuring long-term durability and safety during demonstrations. The polished surface and robust framework reflect a professional-grade build, which not only makes the model aesthetically appealing but also resistant to corrosion, wear, and damage. Stainless steel provides the strength and stability necessary to conduct accurate and repeatable experiments, making this model suitable for continuous use in both school laboratories and science exhibition settings.
The Newton’s First Law Model allows educators to illustrate how an object will maintain its current state—either at rest or in uniform motion—unless disturbed by an external force. This demonstration is particularly effective in helping students understand the practical implications of inertia, force, and motion. The setup typically includes a base, a track, and a movable object (such as a ball or slider) that can be used to demonstrate motion in a straight line. By removing friction or minimizing it through smooth surfaces and balanced design, students are able to observe nearly ideal inertial behavior, reinforcing their theoretical understanding with real-world visualization.
Recommended specifically for physics learning and science projects, this model aligns seamlessly with school curriculums and examination boards. It supports interactive learning and conceptual clarity by offering students a tangible way to experience Newton’s laws, rather than relying solely on textbook explanations. As students manipulate the components, they can observe how motion is sustained until a force—such as friction, impact, or resistance—is introduced, thereby altering the object's velocity or direction. Such real-time experimentation fosters critical thinking, curiosity, and a deeper grasp of physics principles.
The Newton’s First Law Model is not just a classroom tool but also an excellent resource for science fairs, laboratory assessments, and physics workshops. Its compact yet effective design makes it easy to set up and operate, requiring minimal maintenance while delivering consistent performance. The sturdy stainless steel construction ensures that the model retains its form and function across numerous demonstrations, making it a valuable addition to any physics teaching lab.
In summary, the Newton’s First Law Model made from stainless steel is a high-quality, curriculum-aligned educational resource for classes 9 to 12. It brings theoretical physics to life through practical demonstration, enabling students to witness firsthand the behavior of objects in rest and motion as described by Newton’s First Law. Ideal for academic institutions, this model fosters a deeper understanding of inertia, motion, and force while promoting interactive and experiential learning in physics education.
Small Cylindrical Magnets
Request Callback
₹ 100 / Piece Get Latest Price
| Dimensions | 16mm |
| Thickness | 25 mm |
| Shape | Rod (Cylinder) |
| Material | Ferrite |
| Colour | Red |
| Brand | A.S.Int'L |
Minimum order quantity: 10 Piece
A cylindrical magnet is a highly versatile and effective educational tool widely used in physics laboratories, classrooms, and research settings to demonstrate the core principles of magnetism. Characterized by its elongated cylindrical shape, this magnet offers a uniform structure that allows for an even distribution of magnetic force across its poles, making it suitable for a wide range of experiments and demonstrations. The smooth, symmetrical design makes it easy to handle, while its compact form ensures it can be incorporated into multiple setups with ease. It serves as a practical and engaging piece of educational equipment for exploring topics such as magnetic fields, polarity, attraction, repulsion, and the interaction between magnets and various materials. Its design not only supports simple classroom experiments but also helps students connect scientific theories to practical applications, enhancing their learning experience through visual and hands-on demonstrations.
Made from high-quality magnetic materials, the cylindrical magnet is designed to retain its magnetic strength over extended periods, ensuring reliable performance and durability even after frequent use. Its robust construction makes it resistant to chipping or breaking, while protective coatings are often applied to guard against corrosion and wear. This durability makes it a long-lasting resource for schools, colleges, and laboratories, where it can withstand repeated handling by both teachers and students. Its cylindrical shape is not only practical but also advantageous for specific experiments that require consistent magnetic fields or compact magnets that can fit into smaller apparatus, providing educators with flexibility in lesson planning and demonstration.
In educational settings, cylindrical magnets are commonly used to illustrate fundamental concepts of physics, including the mapping of magnetic field lines, the effect of distance on magnetic strength, and the distinction between magnetic and non-magnetic materials. They are also excellent for demonstrating how magnets interact with each other, offering clear visual evidence of attraction and repulsion. When combined with iron filings, a cylindrical magnet provides a vivid and accurate visualization of magnetic fields, making abstract concepts easier to understand for students. In addition, the magnet can be used to demonstrate principles of electromagnetism, induction, and magnetization, bridging the gap between theoretical physics and real-world applications.
Beyond the classroom, cylindrical magnets also help introduce students to practical applications of magnetism in technology and industry. They can be used to replicate the basic functionality of components in motors, generators, and sensors, allowing learners to explore how magnetic fields are harnessed in engineering and innovation. Their uniform structure and strong magnetic field make them useful for experiments involving rotating systems or for exploring how cylindrical magnets can be used in alignment or positioning tasks. By engaging with these types of experiments, students not only develop a strong foundation in scientific principles but also gain insight into the role of magnets in everyday devices and advanced technologies.
The cylindrical magnet is also a valuable tool for science projects, exhibitions, and hands-on learning activities. Its clear design, combined with its powerful magnetic properties, makes it a favorite among educators and learners alike for sparking curiosity and encouraging exploration. As a staple piece of physics laboratory equipment, it continues to play a crucial role in promoting interactive and practical learning, helping students develop problem-solving skills and a deeper appreciation for the importance of magnetism in both science and technology.
Made from high-quality magnetic materials, the cylindrical magnet is designed to retain its magnetic strength over extended periods, ensuring reliable performance and durability even after frequent use. Its robust construction makes it resistant to chipping or breaking, while protective coatings are often applied to guard against corrosion and wear. This durability makes it a long-lasting resource for schools, colleges, and laboratories, where it can withstand repeated handling by both teachers and students. Its cylindrical shape is not only practical but also advantageous for specific experiments that require consistent magnetic fields or compact magnets that can fit into smaller apparatus, providing educators with flexibility in lesson planning and demonstration.
In educational settings, cylindrical magnets are commonly used to illustrate fundamental concepts of physics, including the mapping of magnetic field lines, the effect of distance on magnetic strength, and the distinction between magnetic and non-magnetic materials. They are also excellent for demonstrating how magnets interact with each other, offering clear visual evidence of attraction and repulsion. When combined with iron filings, a cylindrical magnet provides a vivid and accurate visualization of magnetic fields, making abstract concepts easier to understand for students. In addition, the magnet can be used to demonstrate principles of electromagnetism, induction, and magnetization, bridging the gap between theoretical physics and real-world applications.
Beyond the classroom, cylindrical magnets also help introduce students to practical applications of magnetism in technology and industry. They can be used to replicate the basic functionality of components in motors, generators, and sensors, allowing learners to explore how magnetic fields are harnessed in engineering and innovation. Their uniform structure and strong magnetic field make them useful for experiments involving rotating systems or for exploring how cylindrical magnets can be used in alignment or positioning tasks. By engaging with these types of experiments, students not only develop a strong foundation in scientific principles but also gain insight into the role of magnets in everyday devices and advanced technologies.
The cylindrical magnet is also a valuable tool for science projects, exhibitions, and hands-on learning activities. Its clear design, combined with its powerful magnetic properties, makes it a favorite among educators and learners alike for sparking curiosity and encouraging exploration. As a staple piece of physics laboratory equipment, it continues to play a crucial role in promoting interactive and practical learning, helping students develop problem-solving skills and a deeper appreciation for the importance of magnetism in both science and technology.
Dip Circle With Needle
Request Callback
₹ 850 / Piece Get Latest Price
| Dip Circle Type | Laboratory |
| Scale Diameter | 150 mm |
| Scale Graduation | 1° |
| Material | Brass |
| Mount Type | Table Mount |
| Finish | Polished |
| Usage | Physics Lab, Education, Research |
| Needle Lock | Provided |
Minimum order quantity: 1 Piece
A magnetic dip circle is a precision scientific instrument designed for educational and laboratory environments where the measurement and study of the Earth’s magnetic field is essential. This device is widely used in physics laboratories, research settings, and academic institutions to demonstrate the concept of magnetic inclination or dip, which is the angle made by the Earth’s magnetic field lines with the horizontal plane. By allowing students to observe this natural phenomenon through direct measurement, the magnetic dip circle helps build a practical understanding of geomagnetism, vector fields, and magnetic forces in the Earth’s environment. Its intuitive design makes it an effective tool for both introductory demonstrations and advanced experimental applications.
The instrument typically consists of a lightweight yet durable frame that supports a highly sensitive magnetic needle mounted so that it can rotate freely in a vertical plane. This free rotation is crucial for accurately determining the dip angle. The needle is carefully balanced and magnetized to ensure a stable response to the Earth’s magnetic field. The structure is compact, usually measuring around 18 x 19 x 20 cm, making it easy to place on laboratory benches and transport between classrooms or demonstration areas. Despite its portable size, it delivers precise readings, which is critical for teaching accuracy and repeatability in scientific measurements. With a weight of approximately 200 grams, the device is easy to handle yet sturdy enough for regular educational use.
A calibrated circular scale surrounds the needle, allowing users to read measurements directly and clearly. This scale is typically marked in degrees to give students a straightforward way to interpret the dip angle. The simplicity of the scale promotes ease of learning, ensuring that students can quickly grasp how changes in the needle’s position relate to variations in magnetic inclination at different locations. The pivot mechanism at the center of the instrument is engineered for smooth and minimal-friction movement. This ensures that even small variations in magnetic forces can be detected, providing accurate and reliable results during classroom demonstrations or experimental sessions.
The magnetic dip circle is commonly used in earth science, physics, and geophysics courses to help students explore the relationship between horizontal and vertical components of the Earth’s magnetic field. By rotating the device about its axis, learners can align the needle with the magnetic meridian and then observe the resulting dip angle. This hands-on interaction deepens their understanding of geographic variation in magnetic fields and the factors that influence these variations. The device also supports experiments involving induced magnetism, field mapping, and comparisons between theoretical predictions and empirical measurements.
Built for long-term academic use, the magnetic dip circle is constructed with materials that resist wear and maintain calibration over time. Its compact design and stable base make it ideal for repeated classroom handling. Educators value this instrument for its ability to transform abstract geomagnetic concepts into clear, interactive learning experiences. As a result, it stands as an essential piece of educational equipment for schools, colleges, and technical institutes seeking to strengthen practical understanding of magnetic phenomena.
The instrument typically consists of a lightweight yet durable frame that supports a highly sensitive magnetic needle mounted so that it can rotate freely in a vertical plane. This free rotation is crucial for accurately determining the dip angle. The needle is carefully balanced and magnetized to ensure a stable response to the Earth’s magnetic field. The structure is compact, usually measuring around 18 x 19 x 20 cm, making it easy to place on laboratory benches and transport between classrooms or demonstration areas. Despite its portable size, it delivers precise readings, which is critical for teaching accuracy and repeatability in scientific measurements. With a weight of approximately 200 grams, the device is easy to handle yet sturdy enough for regular educational use.
A calibrated circular scale surrounds the needle, allowing users to read measurements directly and clearly. This scale is typically marked in degrees to give students a straightforward way to interpret the dip angle. The simplicity of the scale promotes ease of learning, ensuring that students can quickly grasp how changes in the needle’s position relate to variations in magnetic inclination at different locations. The pivot mechanism at the center of the instrument is engineered for smooth and minimal-friction movement. This ensures that even small variations in magnetic forces can be detected, providing accurate and reliable results during classroom demonstrations or experimental sessions.
The magnetic dip circle is commonly used in earth science, physics, and geophysics courses to help students explore the relationship between horizontal and vertical components of the Earth’s magnetic field. By rotating the device about its axis, learners can align the needle with the magnetic meridian and then observe the resulting dip angle. This hands-on interaction deepens their understanding of geographic variation in magnetic fields and the factors that influence these variations. The device also supports experiments involving induced magnetism, field mapping, and comparisons between theoretical predictions and empirical measurements.
Built for long-term academic use, the magnetic dip circle is constructed with materials that resist wear and maintain calibration over time. Its compact design and stable base make it ideal for repeated classroom handling. Educators value this instrument for its ability to transform abstract geomagnetic concepts into clear, interactive learning experiences. As a result, it stands as an essential piece of educational equipment for schools, colleges, and technical institutes seeking to strengthen practical understanding of magnetic phenomena.
Wooden Brown Cube
Request Callback
₹ 25 / Piece Get Latest Price
| Color | Brown |
| Surface Texture | Sanding |
| Size/Dimension | 20mm |
| Country of Origin | Made in India |
| Material | Pine Wood |
Minimum order quantity: 100 Piece
The Wooden Cube is a classic and highly effective educational tool designed for teaching and experimenting with concepts of density, volume, and material properties. Crafted with precision from durable wood, this cube is specifically tailored to provide students with a hands-on experience in understanding one of the most fundamental principles of physics and material science. With a size of 20mm, the cube is compact and easy to handle, making it perfectly suited for classroom demonstrations, laboratory experiments, and individual student investigations. Its simple yet purposeful design allows learners to focus on the properties of the material itself, encouraging observation, calculation, and practical application of theoretical knowledge.As an educational equipment piece, the Wooden Cube plays a vital role in experiments related to density determination. By providing a standardized size, it enables students to measure its mass and calculate density using the formula density equals mass divided by volume. This process helps learners understand how different materials, though similar in volume, can have varying densities. The use of a wooden cube is particularly effective in comparative studies where students can test multiple cubes made from different materials such as metal, plastic, or acrylic to observe contrasts in density values. This hands-on experimentation enhances critical thinking and problem-solving skills, as students are not only calculating values but also analyzing results in relation to real-world material applications.The cube’s wooden structure provides a safe and reliable material for classroom use. Wood is lightweight compared to metals, making it easy for students to handle without risk of injury, while still offering consistency in volume for accurate experiments. Its durability ensures repeated use without damage, which is essential for institutions looking to invest in long-lasting teaching aids. The cube’s natural texture and finish also add to its appeal, making it more engaging for younger learners who benefit from tactile experiences when learning abstract scientific concepts.Beyond density experiments, the Wooden Cube can be used to demonstrate volume calculations, buoyancy, and displacement experiments when combined with water and measuring cylinders. Teachers can illustrate Archimedes’ principle by showing how the cube displaces water equal to its volume, thereby connecting multiple scientific concepts through a single piece of equipment. This versatility makes the cube a valuable addition to any physics laboratory or science classroom. In mathematics education, it can also serve as a teaching model for three-dimensional geometry, helping students visualize and calculate surface area, volume, and dimensions in a practical manner.The compact 20mm size ensures that multiple cubes can be stored easily and distributed among students for group activities or individual experiments. This encourages collaborative learning, where students can compare their results and refine their understanding through discussion and shared observations. The wooden cube is also suitable for use in both basic and advanced studies, adapting seamlessly to different educational levels from primary science introductions to secondary and higher-level investigations of physical properties.In conclusion, the Wooden Cube is more than just a simple block of wood; it is a thoughtfully designed piece of educational equipment that bridges theoretical concepts with real-world application. Its role in density investigations, geometric studies, and physics demonstrations makes it an essential tool for any institution focused on hands-on learning. By providing accuracy, durability, and versatility, this cube enriches the teaching and learning process, ensuring students gain a deeper and more practical understanding of science and mathematics.
BH Curve Apparatus
Request Callback
₹ 2500 / Piece Get Latest Price
| Core Material | Mild Steel |
| Max Magnetizing Current | 500 mA |
| Power Supply | 10-30 V DC |
| Application | Teaching Lab |
| Measurement Type | Analog |
| Country of Origin | Made in India |
Minimum order quantity: 1 Piece
The BH Curve Apparatus is a specialized educational equipment designed for laboratory use to study and trace magnetic hysteresis curves, making it an important instrument for physics and electrical engineering education. This apparatus enables students to experimentally analyze the magnetic properties of ferromagnetic materials by observing the relationship between magnetic flux density and magnetizing force. Operated using a regulated DC power supply in the range of 10 to 30 volts with a current capacity of up to 500 mA, the system provides stable and controlled excitation necessary for accurate hysteresis loop formation. The apparatus is specifically designed to work in conjunction with a cathode ray oscilloscope, allowing learners to visualize BH curves directly on the screen and correlate theoretical magnetic concepts with real-time graphical representation. This direct visualization helps students develop a clear understanding of key magnetic parameters such as retentivity, coercivity, permeability, and hysteresis loss.
The unit allows tracing of hysteresis curves using resistance, capacitance, and inductance methods, offering flexibility in experimental approach and enabling comparison between different circuit configurations. An output selection band switch is provided on the front panel, allowing students to easily choose the required experimental mode without altering internal wiring. The complete circuit diagram for the BH curve experiment is clearly printed on the front panel, serving as a constant visual reference that aids comprehension and reduces setup errors during laboratory sessions. All essential components are securely mounted behind the front panel, ensuring electrical safety, mechanical protection, and long-term reliability in high-usage academic environments. Input and output connections are neatly brought out to labeled sockets, enabling quick and error-free connection to external instruments such as oscilloscopes and power supplies.
Constructed using a sturdy mild steel enclosure, the BH Curve Apparatus offers excellent durability and stability, making it suitable for repeated handling in teaching laboratories. The robust construction protects internal circuitry while also providing resistance to wear and accidental damage, which is critical in institutional settings where multiple students interact with the equipment daily. The compact and well-organized layout helps maintain a clean laboratory workspace and allows instructors to demonstrate experiments clearly to groups of students. Packaged securely in a box, the apparatus is easy to store and transport, supporting flexible laboratory arrangements and efficient equipment management.
From an educational perspective, this apparatus plays a vital role in bridging theoretical study and practical understanding of magnetic materials and electromagnetic principles. By tracing hysteresis loops on an oscilloscope, students gain hands-on experience in interpreting magnetic behavior, understanding energy loss in magnetic cycles, and analyzing the performance of materials used in transformers, motors, and electrical machines. The experiment reinforces foundational concepts taught in courses on electromagnetism, electrical machines, and material science. Overall, the BH Curve Apparatus is an indispensable laboratory training tool that supports experiential learning, promotes conceptual clarity, and enhances the quality of practical education in physics and electrical engineering laboratories.
The unit allows tracing of hysteresis curves using resistance, capacitance, and inductance methods, offering flexibility in experimental approach and enabling comparison between different circuit configurations. An output selection band switch is provided on the front panel, allowing students to easily choose the required experimental mode without altering internal wiring. The complete circuit diagram for the BH curve experiment is clearly printed on the front panel, serving as a constant visual reference that aids comprehension and reduces setup errors during laboratory sessions. All essential components are securely mounted behind the front panel, ensuring electrical safety, mechanical protection, and long-term reliability in high-usage academic environments. Input and output connections are neatly brought out to labeled sockets, enabling quick and error-free connection to external instruments such as oscilloscopes and power supplies.
Constructed using a sturdy mild steel enclosure, the BH Curve Apparatus offers excellent durability and stability, making it suitable for repeated handling in teaching laboratories. The robust construction protects internal circuitry while also providing resistance to wear and accidental damage, which is critical in institutional settings where multiple students interact with the equipment daily. The compact and well-organized layout helps maintain a clean laboratory workspace and allows instructors to demonstrate experiments clearly to groups of students. Packaged securely in a box, the apparatus is easy to store and transport, supporting flexible laboratory arrangements and efficient equipment management.
From an educational perspective, this apparatus plays a vital role in bridging theoretical study and practical understanding of magnetic materials and electromagnetic principles. By tracing hysteresis loops on an oscilloscope, students gain hands-on experience in interpreting magnetic behavior, understanding energy loss in magnetic cycles, and analyzing the performance of materials used in transformers, motors, and electrical machines. The experiment reinforces foundational concepts taught in courses on electromagnetism, electrical machines, and material science. Overall, the BH Curve Apparatus is an indispensable laboratory training tool that supports experiential learning, promotes conceptual clarity, and enhances the quality of practical education in physics and electrical engineering laboratories.
LCD Projection Microscope
Request Callback
₹ 35000 / Piece Get Latest Price
| Magnification | 100x |
| Illumination Type | LED |
| Viewing Method | Screen |
| Stage Type | Mechanical Stage |
| Application | Demonstration, Teaching, Pathology |
| Viewing Head | Binocular |
| Country of Origin | Made in India |
Minimum order quantity: 1 Piece
Product Detls: Minimum Order Quantity 1 Piece Magnification 100x Features 11.6" retina HD LCD Screen, high definition and high quality color reproduction. Digital Microscope with Digital Imaging System (LDM-01) LCD Screen : 11.1” LCD HD screen
Newton 2nd Law Model
Request Callback
₹ 1546 / Piece Get Latest Price
| Material | Stainless Steel |
| Project Subject | Physics |
| Recommended Class | 9-12 |
| Usage | Educational & learning purpose |
Minimum order quantity: 10 Piece
The Physics Newton’s Second Law Model is an essential educational apparatus designed to visually and practically demonstrate the principles of Newton’s Second Law of Motion. Crafted from high-quality stainless steel, this durable and precision-engineered model serves as an ideal teaching aid for students in classes 9 to 12, supporting interactive and hands-on learning in physics classrooms and laboratories. The model clearly illustrates the fundamental concept that the acceleration of an object is directly proportional to the net force acting upon it, occurs in the same direction as that force, and is inversely proportional to the object’s mass.
Constructed using stainless steel, the model offers excellent longevity, resistance to corrosion, and the ability to withstand repeated use in rigorous classroom environments. Its sturdy build ensures it remains reliable over time, making it suitable for regular demonstrations and student-led experiments. The polished metallic finish enhances its professional appearance while also ensuring ease of cleaning and maintenance. Because it is designed with educational use in mind, the components are assembled in a way that is intuitive and accessible for students, allowing them to easily manipulate parts and observe outcomes.
This Newton’s Second Law Model effectively helps learners understand the relationship between force, mass, and acceleration in a controlled and observable manner. Typically involving weights, pulleys, and a movable cart or platform, the model allows users to alter mass and apply varying forces to observe the corresponding changes in acceleration. This practical experience reinforces textbook concepts and brings the equation F = ma to life, bridging the gap between theoretical knowledge and real-world application.
Recommended specifically for physics education in secondary schools, the model supports science curricula focused on classical mechanics. It plays a crucial role in helping students develop a deeper understanding of motion, dynamics, and the behavior of objects under applied forces. Teachers can use this model during lessons on force and motion, experiment-based learning sessions, and science fairs, enhancing student engagement and retention of complex scientific ideas. The visual and kinesthetic learning experience it offers is particularly beneficial for students who learn best through hands-on activities and direct observation.
The model not only serves as an instructional tool but also fosters scientific inquiry and critical thinking. Students are encouraged to form hypotheses, conduct trials with varying parameters, measure results, and draw conclusions based on empirical data. Such investigative learning strengthens their problem-solving skills and lays a strong foundation for further studies in physics and engineering.
This model is also an invaluable resource for extracurricular science activities, physics workshops, and academic exhibitions. Its ability to clearly demonstrate one of the most important laws in classical physics makes it a must-have for any well-equipped science lab. The stainless steel material ensures it withstands wear and tear, while its precise design ensures accurate demonstration of Newton’s second law across multiple uses.
In conclusion, the Physics Newton’s Second Law Model made from stainless steel is an outstanding educational instrument tailored for students in grades 9 to 12. With its durable construction, intuitive design, and capability to effectively illustrate the principles of force, mass, and acceleration, it is an indispensable asset for science teachers aiming to deliver impactful, experiential physics education. This model ensures that students not only understand Newton's Second Law but can also see it in action, creating a strong conceptual foundation in motion and mechanics.
Constructed using stainless steel, the model offers excellent longevity, resistance to corrosion, and the ability to withstand repeated use in rigorous classroom environments. Its sturdy build ensures it remains reliable over time, making it suitable for regular demonstrations and student-led experiments. The polished metallic finish enhances its professional appearance while also ensuring ease of cleaning and maintenance. Because it is designed with educational use in mind, the components are assembled in a way that is intuitive and accessible for students, allowing them to easily manipulate parts and observe outcomes.
This Newton’s Second Law Model effectively helps learners understand the relationship between force, mass, and acceleration in a controlled and observable manner. Typically involving weights, pulleys, and a movable cart or platform, the model allows users to alter mass and apply varying forces to observe the corresponding changes in acceleration. This practical experience reinforces textbook concepts and brings the equation F = ma to life, bridging the gap between theoretical knowledge and real-world application.
Recommended specifically for physics education in secondary schools, the model supports science curricula focused on classical mechanics. It plays a crucial role in helping students develop a deeper understanding of motion, dynamics, and the behavior of objects under applied forces. Teachers can use this model during lessons on force and motion, experiment-based learning sessions, and science fairs, enhancing student engagement and retention of complex scientific ideas. The visual and kinesthetic learning experience it offers is particularly beneficial for students who learn best through hands-on activities and direct observation.
The model not only serves as an instructional tool but also fosters scientific inquiry and critical thinking. Students are encouraged to form hypotheses, conduct trials with varying parameters, measure results, and draw conclusions based on empirical data. Such investigative learning strengthens their problem-solving skills and lays a strong foundation for further studies in physics and engineering.
This model is also an invaluable resource for extracurricular science activities, physics workshops, and academic exhibitions. Its ability to clearly demonstrate one of the most important laws in classical physics makes it a must-have for any well-equipped science lab. The stainless steel material ensures it withstands wear and tear, while its precise design ensures accurate demonstration of Newton’s second law across multiple uses.
In conclusion, the Physics Newton’s Second Law Model made from stainless steel is an outstanding educational instrument tailored for students in grades 9 to 12. With its durable construction, intuitive design, and capability to effectively illustrate the principles of force, mass, and acceleration, it is an indispensable asset for science teachers aiming to deliver impactful, experiential physics education. This model ensures that students not only understand Newton's Second Law but can also see it in action, creating a strong conceptual foundation in motion and mechanics.
Induction Coil (Ruhmkorff Coil )
Request Callback
₹ 2999 / Piece Get Latest Price
| Application | Heating |
Minimum order quantity: 10 Piece
An induction coil, often referred to as a Ruhmkorff coil, is a highly effective educational instrument used to demonstrate the principles of electromagnetic induction and high-voltage generation. This device is a staple in physics laboratories, engineering classrooms, and science training centers where students explore how varying currents in a primary coil can produce high-voltage pulses in a secondary coil. Designed to transform low-voltage direct current into significantly higher voltages, the induction coil offers a clear, visual, and practical representation of core concepts in electromagnetism. Its construction typically features a primary coil, a secondary coil with a large number of turns, an interrupter, and a soft iron core, all integrated to create a working system that reliably produces strong electrical sparks, making lessons both engaging and informative.
The induction coil is particularly valuable in demonstrating the relationship between changing magnetic fields and induced electromotive force. When current flows through the primary coil, it creates a magnetic field in the iron core. As the interrupter repeatedly breaks and reconnects the circuit, it causes the magnetic field to collapse and rebuild rapidly. This change in magnetic flux induces a high-voltage pulse in the secondary coil, resulting in a visible spark that students can easily observe. These sparks provide a compelling visual cue that helps learners understand abstract concepts such as induction, flux variation, and the behavior of electric fields. Because these demonstrations are dynamic and interactive, they significantly enhance comprehension and retention of theoretical topics.
Educational environments benefit greatly from using an induction coil due to its versatility and the range of experiments it supports. Students can examine how the number of coil turns, core material, and interrupter speed affect the strength of the induced voltage. They can also explore applications of induction in modern technologies, such as transformers, ignition systems, and wireless energy transfer. This hands-on learning experience connects classroom theory to real-world applications, fostering curiosity and strengthening analytical thinking. The induction coil serves as an essential foundation for deeper studies in physics, electronics, and electrical engineering, preparing learners for more complex technological concepts.
The design of a quality induction coil emphasizes safety, stability, and durability, ensuring reliable performance in repeated classroom use. Insulated wiring, solid coil construction, and a secure interrupter mechanism allow the device to operate safely under supervised conditions. Sturdy materials prevent overheating and mechanical wear, ensuring that the coil can withstand continuous educational demonstrations. Its user-friendly design allows teachers and students to set up experiments quickly without requiring extensive technical knowledge, making it suitable for both introductory and advanced science instruction.
In addition to classroom demonstrations, the induction coil plays an important role in laboratory projects, science fairs, and extracurricular STEM activities where students experiment independently. Its ability to produce high-voltage sparks offers a fascinating platform for creative experiments while still reinforcing essential principles. As a piece of educational equipment, it delivers high value by combining practicality, scientific accuracy, and hands-on engagement. The induction coil remains a timeless and essential tool in physics education, enabling students to witness the power of electromagnetic induction firsthand while building a strong foundation for advanced scientific learning.
The induction coil is particularly valuable in demonstrating the relationship between changing magnetic fields and induced electromotive force. When current flows through the primary coil, it creates a magnetic field in the iron core. As the interrupter repeatedly breaks and reconnects the circuit, it causes the magnetic field to collapse and rebuild rapidly. This change in magnetic flux induces a high-voltage pulse in the secondary coil, resulting in a visible spark that students can easily observe. These sparks provide a compelling visual cue that helps learners understand abstract concepts such as induction, flux variation, and the behavior of electric fields. Because these demonstrations are dynamic and interactive, they significantly enhance comprehension and retention of theoretical topics.
Educational environments benefit greatly from using an induction coil due to its versatility and the range of experiments it supports. Students can examine how the number of coil turns, core material, and interrupter speed affect the strength of the induced voltage. They can also explore applications of induction in modern technologies, such as transformers, ignition systems, and wireless energy transfer. This hands-on learning experience connects classroom theory to real-world applications, fostering curiosity and strengthening analytical thinking. The induction coil serves as an essential foundation for deeper studies in physics, electronics, and electrical engineering, preparing learners for more complex technological concepts.
The design of a quality induction coil emphasizes safety, stability, and durability, ensuring reliable performance in repeated classroom use. Insulated wiring, solid coil construction, and a secure interrupter mechanism allow the device to operate safely under supervised conditions. Sturdy materials prevent overheating and mechanical wear, ensuring that the coil can withstand continuous educational demonstrations. Its user-friendly design allows teachers and students to set up experiments quickly without requiring extensive technical knowledge, making it suitable for both introductory and advanced science instruction.
In addition to classroom demonstrations, the induction coil plays an important role in laboratory projects, science fairs, and extracurricular STEM activities where students experiment independently. Its ability to produce high-voltage sparks offers a fascinating platform for creative experiments while still reinforcing essential principles. As a piece of educational equipment, it delivers high value by combining practicality, scientific accuracy, and hands-on engagement. The induction coil remains a timeless and essential tool in physics education, enabling students to witness the power of electromagnetic induction firsthand while building a strong foundation for advanced scientific learning.
DC Moving Coil Galvanometer
Request Callback
₹ 3500 / Piece Get Latest Price
| Current Range | 5A |
| Country of Origin | Made in India |
| Usage/Application | Laboratory |
| Power Source | DC |
| Display | Analog |
| Material | Plastic |
Minimum order quantity: 1 Piece
The DC Moving Coil Galvanometer with a current range of 5A is a high-precision analog instrument designed specifically for educational, experimental, and research-based laboratory applications. Built with a robust plastic body, this galvanometer is engineered for durability and consistent performance under standard lab conditions. It operates on a direct current (DC) power source and features a reliable analog display, which offers precise and instantaneous visual readings of electrical current. The device is ideal for demonstrating and measuring current in circuits, making it a crucial instrument for physics labs, electrical training workshops, and engineering institutions.
The galvanometer functions based on the moving coil principle, where a coil suspended in a magnetic field experiences a torque proportional to the current flowing through it. This torque causes a deflection of the pointer on the scale, which is carefully calibrated to measure up to 5 amperes. Its high sensitivity and accuracy allow users to detect even minute changes in current, ensuring that it meets the rigorous demands of both academic and industrial applications. The instrument is typically used in experiments involving Kirchhoff’s laws, Ohm’s law verification, bridge circuits, and other fundamental and advanced studies in electromagnetism and electronics.
One of the standout features of this DC galvanometer is its clear and easy-to-read analog dial. The scale is marked for precise readings and is enclosed under a transparent cover to protect the internal mechanism from dust and accidental damage. The dial’s ergonomic layout allows students and researchers to observe current fluctuations effortlessly during dynamic electrical experiments. Additionally, the lightweight yet sturdy plastic casing ensures safe handling and portability while maintaining structural integrity even after repeated usage.
Its 5A capacity makes this galvanometer particularly suitable for experiments involving relatively higher current values, which are often beyond the scope of standard microampere or milliampere galvanometers. This extended current range allows the instrument to be used across a wider variety of experimental setups, adding flexibility and value to laboratory equipment collections. Whether it is being used in a basic school lab setting or a more complex university or vocational training environment, this galvanometer proves itself as a dependable tool for accurate current measurement.
The construction of the instrument ensures minimal friction, offering smooth pointer movement and reducing the risk of mechanical lag, which could otherwise compromise measurement accuracy. Internally, the coil and magnets are made using high-grade materials that provide longevity and repeatable precision. Furthermore, the use of durable plastic for the housing adds to the galvanometer’s safety profile, especially when used by younger students or in high-traffic educational settings.
Designed for intuitive use, the galvanometer is equipped with standard terminal connections that allow quick and secure integration into any experimental circuit. This feature supports seamless switching between various setups without the need for specialized connectors, making it suitable for quick demonstrations as well as long-duration laboratory investigations. The overall form factor is compact, allowing it to fit conveniently on lab benches without occupying excessive space.
In conclusion, the DC Moving Coil Galvanometer rated for 5A is a reliable and essential tool for accurately measuring electric current in laboratory environments. Its sturdy plastic body, analog display, and robust internal components ensure long-lasting performance. Ideal for academic, research, and technical training purposes, this galvanometer delivers precise and efficient current measurement, making it a valuable addition to any electrical or physics laboratory setup.
The galvanometer functions based on the moving coil principle, where a coil suspended in a magnetic field experiences a torque proportional to the current flowing through it. This torque causes a deflection of the pointer on the scale, which is carefully calibrated to measure up to 5 amperes. Its high sensitivity and accuracy allow users to detect even minute changes in current, ensuring that it meets the rigorous demands of both academic and industrial applications. The instrument is typically used in experiments involving Kirchhoff’s laws, Ohm’s law verification, bridge circuits, and other fundamental and advanced studies in electromagnetism and electronics.
One of the standout features of this DC galvanometer is its clear and easy-to-read analog dial. The scale is marked for precise readings and is enclosed under a transparent cover to protect the internal mechanism from dust and accidental damage. The dial’s ergonomic layout allows students and researchers to observe current fluctuations effortlessly during dynamic electrical experiments. Additionally, the lightweight yet sturdy plastic casing ensures safe handling and portability while maintaining structural integrity even after repeated usage.
Its 5A capacity makes this galvanometer particularly suitable for experiments involving relatively higher current values, which are often beyond the scope of standard microampere or milliampere galvanometers. This extended current range allows the instrument to be used across a wider variety of experimental setups, adding flexibility and value to laboratory equipment collections. Whether it is being used in a basic school lab setting or a more complex university or vocational training environment, this galvanometer proves itself as a dependable tool for accurate current measurement.
The construction of the instrument ensures minimal friction, offering smooth pointer movement and reducing the risk of mechanical lag, which could otherwise compromise measurement accuracy. Internally, the coil and magnets are made using high-grade materials that provide longevity and repeatable precision. Furthermore, the use of durable plastic for the housing adds to the galvanometer’s safety profile, especially when used by younger students or in high-traffic educational settings.
Designed for intuitive use, the galvanometer is equipped with standard terminal connections that allow quick and secure integration into any experimental circuit. This feature supports seamless switching between various setups without the need for specialized connectors, making it suitable for quick demonstrations as well as long-duration laboratory investigations. The overall form factor is compact, allowing it to fit conveniently on lab benches without occupying excessive space.
In conclusion, the DC Moving Coil Galvanometer rated for 5A is a reliable and essential tool for accurately measuring electric current in laboratory environments. Its sturdy plastic body, analog display, and robust internal components ensure long-lasting performance. Ideal for academic, research, and technical training purposes, this galvanometer delivers precise and efficient current measurement, making it a valuable addition to any electrical or physics laboratory setup.
Magnet Alnico Cylindrical
Request Callback
₹ 20 / Piece Get Latest Price
| Shape | Rod |
| Diameter | 6 mm |
| Length | 25 mm |
| Manufacturing Method | Cast |
| Brand | Unisource |
| Magnet Grade | Alnico 5 |
| Maximum Working Temperature | 550 degree c |
Alnico cylindrical magnets are used for high-temperature stability, strong holding, and precise sensing in motors, generators, automotive systems, and aerospace, as well as in audio equipment like guitar pickups and loudspeakers, benefiting from their corrosion resistance and ability to maintain magnetism in harsh conditions. Their shape makes them ideal for sensors (Hall effect, reed switches), magnetic chucks in machining, and as educational tools for demonstrating magnetic fields, providing stable performance where rare earths might struggle.
Electronic Door Bells
Request Callback
₹ 200 / Piece Get Latest Price
| Bell Type | Electronic Buzzer |
| Operating Voltage | 220-240 V AC |
| Usage | School |
| Bell Size | 4 Inch |
| Mounting Type | Wall Mount |
| Current Rating | 0.2 A |
| Body Material | Mild Steel |
A wireless doorbell adds an extra dimension to your home security system. Always know when someone is at your door with immediate text or email alerts whenever the bell is rung. Connect the device to other home automation components for customized, controlled lighting for further security and convenience.
Planck Constant Apparatus
Request Callback
₹ 3500 / Piece Get Latest Price
| Apparatus Type | Photoelectric Effect |
| Power Supply | 230 V AC |
| Measurement Type | Direct Reading |
| Detector Type | Photo Diode |
| Light Source | Sodium Lamp |
| Usage Level | School Level |
| Accessories Included | Light Source |
| Body Material | MS Powder Coated |
A Planck's Constant Apparatus measures "h" by using LEDs or a phototube with filters to determine the energy of photons, plotting photon energy (E=hfcap E equals h f𝐸=ℎ𝑓) against frequency (ff𝑓) to find the slope, which reveals Planck's constant; the core process involves measuring the threshold voltage (stopping potential) where light starts causing current or light emission, correlating this voltage to photon energy, and graphing the data for analysis, often with an ammeter for precision.
X
Contact Us
Shubhra (Director)
A.S. International
Second Floor, 6262/10, Idgah Road, Sadar Bazar
Ambala - 133001, Haryana, India
Send Email