A.S. International

Bernoulli Principle Demonstrator – Engineering Lab Training System (AS-INT-TVET-DVET-013)The Bernoulli Principle Demonstrator is a vital educational apparatus designed to illustrate the application of Bernoulli’s theorem in fluid flow systems. This demonstrator is widely used in polytechnic and engineering colleges, especially those participating in international educational projects sponsored by the World Bank, Asian Development Bank (ADB), African Development Bank (AfDB), and UNESCO. It is crafted to align perfectly with the latest syllabi requirements of global technical and vocational education institutions.
The unit features a transparent venturi tube housed within a sturdy frame, incorporating multiple pressure measurement ports connected to sensitive manometers. The controlled water supply is integrated with a supporting hydraulic bench, offering students the chance to observe local pressure variations and velocity changes across the venturi constriction, thereby validating Bernoulli’s equation in real-time.
Key FeaturesTransparent venturi tube with six pressure measurement points for precise observation.
Pressure measurement via multiple manometers, including pitot and static pressure gauges.
Integrated with a Basic Hydraulics Bench providing steady water supply and flow control.
Clear and accessible panel design for easy monitoring and data collection.
Durable, corrosion-resistant materials ensuring longevity in academic labs.
Practical Educational BenefitsDemonstrates the fundamental principles of energy conservation in fluid flows.
Enables students to measure static, dynamic, and total pressure along a flow path.
Supports experiments on velocity distribution, pressure variation, and flow rate correlation.
Reinforces theoretical concepts with practical, hands-on experience and data analysis.
Prepares engineering students for real-world fluid dynamics applications in diverse industries.
Tender and Curriculum ComplianceMeets tender specifications of donor agencies including World Bank, ADB, and AfDB projects.
Equipped with comprehensive instructional materials aligned to modern curricula.
Facilitates incorporation of digital data acquisition for enhanced learning outcomes.
Manufactured to withstand frequent use in rigorous academic environments.
ApplicationsPolytechnic and engineering colleges offering courses on fluid mechanics and hydraulics.
Vocational training centers emphasizing practical applications of fluid dynamics.
Research labs studying flow measurement and pressure distribution in fluids.
Development projects aimed at improving technical education infrastructure worldwide.

Pressure Distribution In A Venturi Nozzle – Engineering Training System (AS-INT-TVET-DVET-014)The Pressure Distribution In A Venturi Nozzle apparatus is designed to study the pressure variations along a converging-diverging channel representing a venturi nozzle, a key component in fluid mechanics and hydraulic engineering curricula. This equipment is widely used in polytechnic and engineering colleges worldwide and complies with specifications set by major international funding bodies like the World Bank, Asian Development Bank (ADB), and African Development Bank (AfDB).
The unit comprises a variable cross-section flow channel equipped with a transparent viewing window and connected inlet and outlet tanks to maintain steady pressure conditions. The device allows injection of dye for visualizing flow patterns and uses a twelve-tube manometer distributed along the nozzle to measure static pressure changes at regular intervals, enabling detailed investigation of pressure distributions and velocity changes.
Key FeaturesTransparent flow channel with variable cross-section for observing fluid behavior.
Twelve-tube manometer system providing detailed static pressure readings along the nozzle length.
Connected inlet and outlet tanks guaranteeing constant pressure boundary conditions.
Inclusion of dye injection ports to visualize flow trajectories and streamline patterns.
Robust frame and durable materials suitable for intensive use in educational labs.
Educational BenefitsFacilitates in-depth understanding of pressure and velocity distribution in nozzles.
Demonstrates fundamental principles of fluid acceleration and pressure drop in varying cross-sectional areas.
Supports curriculum requirements for fluid mechanics, hydraulics, and energy conversion courses.
Enhances student skills in data collection and analysis through precise instrumentation.
Complements theoretical and simulation studies with empirical observations.
Tender and Compliance FeaturesBuilt following international educational standards and tender requirements for development projects.
Designed for longevity and frequent use in diverse academic environments.
Delivered with comprehensive instructional manuals and experimental guides.
Compatible with digital sensors and data logging systems for modern lab integration.
ApplicationsEngineering universities and polytechnic colleges teaching fluid dynamics.
TVET and vocational training centers focusing on fundamental hydraulics.
Research institutes analyzing flow phenomena and pressure variations.
Donor-funded projects aiming to upgrade technical education infrastructure globally.

An electronics training kit is a comprehensive educational equipment designed to provide students, educators, and trainees with practical experience in understanding the fundamental principles of electronics and circuit design. These kits serve as a valuable resource in laboratories, technical institutes, vocational training centers, and engineering colleges where hands-on learning is considered essential to build a strong foundation in the field of electronics. With the rapid advancement of technology, the importance of practical exposure has grown significantly, and an electronics training kit plays a vital role in bridging the gap between theoretical knowledge and real-world applications. It allows learners to visualize, construct, and test various electronic circuits, giving them the opportunity to develop essential technical skills that are highly relevant in both academic and professional environments.
An electronics training kit is equipped with a wide range of components and modules that help demonstrate key concepts in analog and digital electronics. Typical kits include regulated power supplies, function generators, breadboards, logic probes, switches, resistors, capacitors, transistors, diodes, LEDs, and connectors that enable the construction of different types of circuits. Many kits also come with built-in modules for logic gates, flip-flops, counters, registers, encoders, decoders, and arithmetic units, making them suitable for the study of digital electronics and Boolean algebra. For analog electronics, learners can explore amplifier circuits, oscillators, filters, rectifiers, and various signal-processing modules. The inclusion of solderless breadboards allows quick and easy circuit assembly without the need for permanent connections, encouraging experimentation and repeated practice.
These training kits are designed with user-friendly layouts and clearly marked circuit symbols to make the learning process intuitive and engaging. Students can perform structured experiments aligned with their course curriculum while also gaining the freedom to design and test their own circuits. By using an electronics training kit, learners become familiar with the process of troubleshooting, understanding circuit faults, and improving their problem-solving abilities. The ability to test and measure voltage, current, and signal outputs in real time using the provided tools ensures that students not only acquire technical knowledge but also build confidence in their practical skills.
In addition to academic use, electronics training kits are widely utilized in industrial training and research projects, where they serve as an ideal platform for developing prototypes and testing new ideas. Their versatility and modular nature allow them to adapt to different levels of learning, from beginners studying basic electronic components to advanced learners working with microcontrollers, programmable logic, and embedded systems. Many modern training kits also integrate digital displays, microprocessor-based controls, and connectivity options, keeping them aligned with the requirements of today’s electronic industries.
The durability, precision, and versatility of an electronics training kit make it an indispensable part of any educational setup focused on electronics. By combining theoretical lessons with practical experiments, these kits inspire innovation, enhance technical competence, and prepare learners for careers in engineering, research, and technology development. With their ability to simplify complex concepts and encourage creativity, electronics training kits remain a cornerstone in the effective teaching and training of electronics.

A PLC trainer kit is an essential educational equipment designed to provide students, trainees, and professionals with hands-on learning experience in the field of industrial automation and control systems. Built with precision and durability, this trainer serves as a practical tool to understand the working principles, programming, and applications of programmable logic controllers in real-world scenarios. The trainer kit is constructed from high-quality powder-coated metal, ensuring a sturdy and long-lasting frame that can withstand repeated use in classroom and laboratory environments. Its appealing blue and white finish not only enhances the professional look of the equipment but also ensures resistance to wear and corrosion, making it suitable for extensive educational usage over time.
Measuring 30 cm in length, 43 cm in width, and 22 cm in height, this PLC trainer kit is compact and well-structured, making it easy to place on laboratory benches without occupying excessive space. Despite its compact dimensions, it incorporates all the essential features required for effective training sessions, allowing learners to experiment and understand automation concepts thoroughly. Designed for academic use, it is widely employed in engineering colleges, polytechnic institutes, and technical training centers where students are introduced to automation technology and industrial applications.
Operating at a frequency of 50 Hz and a voltage of 230 volts AC, the trainer is perfectly suited for standard laboratory power supplies, ensuring safe and reliable operation. It provides the ideal platform for students to simulate industrial processes, develop programming logic, and troubleshoot control circuits. By offering exposure to real-time applications, the trainer kit helps bridge the gap between theoretical knowledge and practical implementation, giving learners the confidence to handle PLC systems in industrial environments.
The PLC trainer kit is not just a piece of equipment but a comprehensive learning tool. It enables students to practice wiring, input-output configuration, ladder logic programming, and process control, all of which are crucial for understanding automation systems. Through this, learners can grasp how PLCs are used in industries to control machinery, manufacturing processes, and robotic systems. Its well-designed layout ensures that beginners can easily follow the functions while advanced learners can use it to practice complex applications, making it versatile for different levels of training.
Durability and safety have been prioritized in the design of this trainer. The powder-coated metal body provides protection against scratches, rust, and laboratory wear, while the secure design minimizes risks during operation. The equipment is engineered to meet educational standards, ensuring that students can learn in a safe and controlled environment. Teachers and instructors find it particularly useful because it allows them to demonstrate industrial automation concepts effectively and provide students with hands-on exposure that is crucial for skill development.
Overall, the PLC trainer kit is an indispensable educational resource for institutions aiming to provide quality technical training in industrial automation. With its sturdy construction, compact design, and reliable performance, it offers a perfect balance between functionality and durability. It prepares students to meet industry demands by equipping them with the practical knowledge and technical skills needed to work with PLCs, making it an ideal addition to any laboratory dedicated to engineering and technical education.

A flip flop trainer is a highly valuable educational equipment designed to help students, engineers, and beginners in electronics understand the working principles and applications of various types of flip flops used in digital electronics. This trainer kit provides a practical and interactive platform for learning the fundamentals of sequential logic circuits, making it an indispensable tool in laboratories, training institutes, and academic environments where digital electronics and logic design are taught. By using a flip flop trainer, learners can explore the behavior of different flip flops such as SR, JK, D, and T flip flops, observe their input-output relationships, and gain hands-on experience in constructing and analyzing sequential circuits that form the foundation of digital systems.
The trainer is carefully designed with a durable body, often made from powder-coated metal or high-quality materials to ensure long-term use in educational setups. It comes with clearly labeled components, switches, and terminals that allow students to easily perform experiments without confusion. With a built-in regulated power supply, the kit ensures safe and reliable operation during practical sessions. The circuits are pre-assembled and neatly laid out, reducing the chances of wiring errors and helping learners focus on the functionality of the flip flops themselves rather than troubleshooting unnecessary connection problems. This makes it especially suitable for beginners who are just starting their journey into digital electronics.
One of the most significant advantages of the flip flop trainer is its ability to demonstrate the fundamental principles of sequential logic, which is the basis of memory storage, counters, registers, and many other digital devices. Students can apply different inputs, toggle clock pulses, and observe how the outputs change depending on the type of flip flop being used. This practical exposure enhances theoretical learning by bridging the gap between classroom knowledge and real-world application. By experimenting with different flip flops, learners develop a clear understanding of concepts such as edge triggering, clock dependency, and metastability, which are essential for advanced studies in digital design and computer architecture.
The flip flop trainer is not only limited to demonstrating individual flip flops but also allows for experimentation with combinations of circuits to form counters, shift registers, and frequency dividers. This versatility makes it an ideal piece of equipment for engineering students, diploma learners, and vocational training programs where practical exposure is as important as theoretical knowledge. The trainer is lightweight, portable, and designed for ease of use, making it convenient for laboratory sessions as well as project-based learning activities.
In addition to its educational value, the flip flop trainer is also a reliable tool for instructors, as it simplifies teaching complex concepts by providing clear, observable demonstrations. Students can engage in self-learning, repeat experiments, and analyze circuit behavior at their own pace, encouraging critical thinking and problem-solving abilities. With its robust construction, user-friendly interface, and wide range of applications in teaching digital electronics, the flip flop trainer serves as an essential piece of equipment that enhances learning outcomes and equips students with the knowledge and skills required to excel in the field of electronics and digital technology.

The Digital IC Trainer is an advanced educational equipment designed to provide students with practical exposure to digital and TTL electronics in a comprehensive and structured manner. This trainer is particularly useful in laboratory environments where learners can bridge the gap between theoretical concepts and real-world applications. Constructed with durable fiber and metal materials, it ensures long-lasting use and reliability, making it suitable for continuous practice sessions in engineering colleges, polytechnic institutes, and science colleges. The trainer is semi-automatic in operation and comes equipped with a reliable power supply of +5V and ±12V, providing consistent and regulated outputs to support a wide range of experiments. With less than 1mV ripple and less than 0.1% regulation, the system ensures stability and precision, which are critical when working with digital circuits.
One of the standout features of this educational trainer is its 2-digit BCD to decimal display, which allows students to clearly visualize circuit outputs in real time. The trainer is designed with high-intensity LEDs for indication of outputs, available in single and dual color, making it easier for learners to track circuit responses during experimentation. It also features TTL clocks ranging from 1Hz to 1MHz, providing flexibility for different types of digital experiments and ensuring that students gain exposure to both low and high-frequency operations. The inclusion of monopulse high and low functionality further enhances the scope of experiments that can be conducted, allowing learners to deepen their understanding of logic transitions and pulse responses.
The Digital IC Trainer is highly practical, with physical parameters carefully designed to support convenient usage. It features four 16-pin ZIF sockets and a 680-pin breadboard, allowing for multiple circuit setups simultaneously. With 12 logic input and output terminals and 2mm socket dimensions, it provides ample flexibility for wiring and connecting various digital components. The sturdy unit measures 320mm x 320mm x 110mm and weighs approximately 5 kgs, making it compact enough for laboratory setups while still offering robust functionality.
Safety has also been prioritized in the design, with inbuilt protection against load and short circuit conditions, ensuring that both students and equipment remain secure during experiments. The trainer comes with essential accessories such as patch chords for connections, a fuse for added protection, and a comprehensive manual to guide learners through various practical exercises. These inclusions make the kit complete and ready to use, saving time and ensuring smooth integration into laboratory sessions.
By offering hands-on experience, the Digital IC Trainer enables students to explore digital electronics concepts in depth, from basic logic gate operations to complex sequential circuits. It supports effective learning of TTL integrated circuits and CMOS integrated circuits, which are fundamental building blocks in the field of electronics. This tool not only enhances practical knowledge but also builds confidence in students, preparing them for advanced studies and careers in electronics and engineering. With its combination of durability, precision, and comprehensive functionality, the Digital IC Trainer stands out as an essential piece of educational equipment for practical learning in modern laboratories.

An analog trainer kit is an essential educational equipment designed to provide students with practical exposure to the fundamental principles of analog electronics. It serves as a versatile training platform that allows learners to understand, analyze, and implement basic and advanced analog circuits through hands-on experimentation. Widely used in electronics laboratories, engineering colleges, technical institutes, and research facilities, this trainer kit plays a crucial role in bridging the gap between theoretical knowledge and practical application. By offering a complete set of built-in components, circuit modules, and measuring facilities, the analog trainer kit enables students to explore the behavior of resistors, capacitors, diodes, transistors, and operational amplifiers in various analog circuits. This makes it a highly effective teaching tool for subjects like analog electronics, circuit analysis, communication systems, and instrumentation.
The analog trainer kit is typically designed with a user-friendly layout that integrates power supplies, function generators, breadboard areas, and measuring instruments into a single compact unit. This eliminates the need for separate laboratory equipment and simplifies the experimental process. With clearly marked test points and modular connections, students can easily assemble, modify, and test circuits without the complexity of external wiring. Experiments that can be performed on the trainer kit often include rectifiers, filters, voltage regulators, amplifiers, oscillators, and waveform analysis. The ability to directly observe input and output signals using built-in measuring tools, or by connecting external devices such as oscilloscopes, helps students gain a clear understanding of how analog circuits function in real-world applications.
One of the key benefits of using an analog trainer kit in educational settings is its ability to develop problem-solving skills and enhance practical knowledge. Students not only learn the theoretical aspects of analog electronics but also gain the experience of troubleshooting and optimizing circuits. This exposure is invaluable as it prepares learners for working with electronic systems in industries where analog technology still plays a significant role. From audio systems and communication equipment to instrumentation and control devices, analog circuits form the foundation of many modern technologies. By practicing on an analog trainer kit, students can relate their classroom knowledge to practical applications, making the learning process more engaging and impactful.
Constructed with durability and precision in mind, the analog trainer kit is built using high-quality components that ensure accurate results and long-lasting performance. Its robust design makes it suitable for repeated use in laboratory environments, while the safe and reliable circuitry allows students to perform experiments without the risk of damaging components. The portability and compact size of the kit also make it convenient for use in classrooms, workshops, and training sessions, providing flexibility for both teachers and students.
Instructors find the analog trainer kit extremely useful as it simplifies the teaching process by providing a ready-to-use experimental platform. Instead of setting up multiple devices, they can demonstrate important analog concepts quickly and effectively, saving time and effort while maintaining clarity. Students, on the other hand, benefit from the hands-on learning experience, which enhances their confidence and prepares them for advanced studies and practical work in electronics. Overall, the analog trainer kit is an indispensable tool for modern education, offering a comprehensive and interactive approach to learning analog electronics and laying a strong foundation for future studies in electrical and electronic engineering.

A power electronics trainer kit is a specialized educational tool designed to provide students, researchers, and professionals with a practical understanding of power electronics and its applications in modern electrical engineering. This trainer kit is widely used in engineering colleges, polytechnic institutes, and technical training centers to teach the fundamentals of power electronics through hands-on experiments. Built with precision and durability, the power electronics trainer kit helps learners explore the principles of controlling and converting electrical power using semiconductor devices such as diodes, thyristors, MOSFETs, and IGBTs. It provides a safe and organized platform to study power conversion techniques, circuit behavior, and the operation of power electronic devices under different conditions, making it an indispensable part of laboratory equipment for electrical and electronics engineering education.
The trainer kit is equipped with pre-assembled circuit modules that allow students to conduct experiments on rectifiers, inverters, choppers, and AC voltage controllers. With its structured design, learners can easily build and analyze various power electronic circuits without requiring extensive external wiring, thus reducing errors and enhancing safety. The kit usually includes an inbuilt regulated power supply, digital or analog meters for accurate measurements, and test points for monitoring waveforms using oscilloscopes. This enables detailed analysis of voltage and current behavior at different stages of a circuit, helping learners develop a deep conceptual and practical understanding. By simulating real-world applications of power electronics, the trainer bridges the gap between theoretical learning and industrial practices.
One of the major advantages of a power electronics trainer kit is its ability to demonstrate the fundamental characteristics of semiconductor switching devices. Students can observe the switching behavior, efficiency, and limitations of various devices and understand how they are used in designing power control circuits. For example, by experimenting with rectifier modules, learners can study how alternating current is converted into direct current, while inverter experiments help them analyze the conversion of DC back into AC for applications such as motor drives and renewable energy systems. Similarly, chopper and AC voltage controller experiments provide insights into how power can be efficiently regulated for industrial applications.
The kit also supports the study of pulse-width modulation (PWM) techniques, which are essential in modern power electronic applications such as motor speed control, power supplies, and renewable energy integration. By adjusting switching pulses, students can directly observe how circuit performance and output characteristics are influenced. These practical sessions not only reinforce classroom theory but also improve critical thinking, problem-solving, and circuit troubleshooting skills. Many trainer kits are also designed to interface with computers and digital controllers, allowing advanced learners to explore microcontroller-based power electronic systems and programmable logic applications.
Constructed with high-quality materials, the power electronics trainer kit ensures reliability, safety, and long service life even under regular laboratory use. Its modular and user-friendly design makes it suitable for both beginners and advanced learners, allowing progressive learning from basic concepts to complex applications. Educators benefit from its ease of demonstration, while students gain hands-on experience that prepares them for careers in industries such as renewable energy, power distribution, motor drives, electric vehicles, and automation.

A PN junction diode apparatus is an essential educational equipment designed to provide students and learners with a clear understanding of the working principles and characteristics of a PN junction diode. Widely used in physics and electronics laboratories, this apparatus helps in studying the electrical behavior of a semiconductor diode under various conditions. Built with accuracy and reliability, it allows students to visualize and analyze the concept of forward and reverse bias, current-voltage characteristics, and the rectifying nature of a diode. This apparatus is a fundamental tool in electronics education, as the PN junction diode is considered the building block of modern semiconductor devices. By offering a practical platform for experimentation, it bridges the gap between theoretical concepts taught in textbooks and real-world electronic applications, ensuring effective learning outcomes for students in schools, colleges, and technical institutes.
The PN junction diode apparatus is designed with precision to facilitate safe and straightforward experimentation. It generally consists of a mounted PN junction diode, terminals for connections, and a regulated power supply, along with meters for measuring voltage and current. With this setup, learners can easily apply forward bias and reverse bias conditions to the diode and observe its response. Through this, they gain practical insights into concepts such as threshold voltage, knee voltage, leakage current, and reverse breakdown. The apparatus also allows the plotting of V-I characteristics, which is a crucial experiment in basic electronics courses, enabling students to interpret the diode’s behavior graphically. By performing these experiments, learners develop a deeper comprehension of how diodes function as rectifiers, switches, and protective components in electronic circuits.
This apparatus is not only useful for understanding diode fundamentals but also for exploring real-world applications of semiconductors. For instance, students can relate the operation of a PN junction diode to its role in power supplies where it converts AC to DC, or in communication systems where it is used in modulation and demodulation circuits. It also introduces them to advanced concepts like clipping and clamping circuits, Zener regulation, and transistor operations, which are all based on the foundational principles of PN junction behavior. The use of such practical equipment enhances critical thinking, analytical skills, and hands-on circuit-building capabilities, which are vital for any student pursuing studies in electronics or electrical engineering.
The apparatus is manufactured using high-quality, durable components to ensure accuracy and long-term use in laboratory environments. Its user-friendly design makes it suitable for both beginners and advanced learners, allowing them to carry out experiments safely and efficiently. Teachers and instructors find it particularly effective for classroom demonstrations, as it provides a visual and measurable way to explain abstract semiconductor theories. Furthermore, its compact and portable design ensures ease of storage and setup, making it a versatile addition to any educational laboratory.
By providing a practical, hands-on experience with one of the most fundamental semiconductor devices, the PN junction diode apparatus plays a crucial role in building a strong foundation in electronics. It prepares students to progress confidently into more complex experiments involving transistors, integrated circuits, and power electronics. In this way, the apparatus not only supports academic learning but also equips learners with the technical knowledge and practical skills necessary for future careers in electronics, telecommunications, renewable energy, and modern technology fields.

The microcontroller training kit is an advanced educational equipment designed to provide students, researchers, and professionals with a hands-on platform for learning, experimenting, and developing applications using microcontroller technology. Built with precision and durability, this training kit serves as a comprehensive tool for understanding embedded systems, programming techniques, interfacing, and real-time applications in electronics and computer science. The kit is constructed with high-quality components that ensure reliable performance, making it an ideal choice for use in laboratories, engineering colleges, technical institutes, and training centers. By offering practical exposure, it bridges the gap between theoretical knowledge and real-world application, making it one of the most essential tools for those pursuing studies in electronics, communication, and computer engineering.
This microcontroller training kit comes equipped with a robust microcontroller board, programmable modules, and input-output interfaces that enable learners to perform a wide variety of experiments. Students can work with digital and analog input-output operations, timers, interrupts, communication protocols, and peripheral interfacing such as LCD displays, keypads, sensors, and motors. By simulating real-world control systems, the kit allows learners to develop practical skills in automation, robotics, industrial control, and embedded software development. The design of the kit ensures that users can easily connect and disconnect components, making it simple to carry out different configurations and experiments without risk of damage.
One of the strongest features of the microcontroller training kit is its versatility in supporting multiple programming environments. Learners can program the microcontroller using assembly language, embedded C, or other high-level languages, depending on the curriculum or training requirements.  With this integrated learning approach, the training kit helps students build problem-solving skills, logical thinking, and technical competence that are crucial in modern-day engineering and technology fields.
In addition to its role in academic learning, the microcontroller training kit is also widely used for project development and innovation. Engineering students often use the kit to design final-year projects or prototypes that involve automation, communication, and control applications. Its modular design and adaptability make it suitable for building real-time systems such as traffic control models, robotics mechanisms, data acquisition systems, and home automation devices. The kit provides a safe and controlled environment for experimentation, ensuring that learners can innovate and test their ideas with confidence.
The durability and reliability of the kit make it a long-term investment for educational institutions. Made with a strong and compact design, it can withstand frequent handling and rigorous use in busy laboratory sessions. The components are designed for easy maintenance and replacement, ensuring continuous functionality. Its ability to demonstrate core concepts such as memory organization, peripheral interfacing, and communication standards makes it an indispensable teaching aid for electronics and computer science courses.
By providing a complete, hands-on platform for embedded systems education, it enables students to transition from theoretical study to practical implementation with ease. This kit empowers learners to gain confidence, develop technical skills, and prepare for careers in automation, robotics, and embedded systems design. It is a versatile, durable, and reliable resource that supports innovation, experimentation, and knowledge building in the rapidly growing field of microcontroller-based technologies.

Product Detls: Packaging Type Box Display Type Digital Usage/Application Laboratory Model Name/Number BFW10 Current 150 mA Power Supply 3-15 V DC Body Material Mild Steel

Product Detls: Usage/Application Laboratory Type Analog Material Metal Power Supply 5 V DC Current 150 mA Temperature Rang 20 to 60 Deg C Using Discrete Components (5 in 1) for logic 1 & logic 0. Circuit diagram for or and & not gates has been printed & components mounted on front panel to demonstrate the working of DTL gates. NAND & NOR gates can be assembled using different combinations of Gates.