- Mix and Match Source/Load Modules
- 8 Channels in 1U Rack
- Single unit output max 2kW
- High Precision and Stability
- Arbitrary Waveform Generation
- Adjustable voltage and current slope
- List sequencing
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Home / Test & Measurement Solutions / Power Supplies & Electronic Loads
With advanced technology and innovative designs, these electronic loads and power supplies meet the rigorous demands of modern industries, making them ideal for professionals seeking dependable energy solutions.
Genetron’s electronic loads and power supplies are engineered to deliver unparalleled precision and reliability, ensuring accurate testing results across various industries. Whether you’re exploring options like programmable DC power supplies, regenerative power supplies, or electronic loads, Genetron’s solutions are built to meet the demands of advanced testing environments.
All key products are designed with efficiency, versatility, and stable output to accommodate a wide array of applications. From automotive to telecommunications and aerospace industries, our power supplies provide the robust performance needed for modern testing challenges.
Power supplies come in various types, each designed to meet specific application requirements. Whether for industrial testing, research laboratories, or high-precision electronics, selecting the right power supply is essential for efficiency and reliability.
An AC power supply converts mains power into controlled voltage and frequency outputs, making it ideal for industrial equipment, appliances, and motor testing.
A DC power supply converts alternating current (AC) from the mains into direct current (DC) with regulated voltage and current outputs. Used extensively in electronics testing, automotive applications, and telecommunications, it ensures stable power delivery for sensitive components.
A programmable power supply offers dynamic control over voltage, current, and power settings, enabling automated testing and precision in industries like aerospace and semiconductor manufacturing.
A regenerative power supply not only delivers power but also feeds excess energy back to the grid, reducing waste and operational costs. Ideal for battery testing and sustainable energy applications. This energy-efficient solution is particularly useful in applications requiring bidirectional power flow, such as battery testing and renewable energy simulations.
Choosing the right power supply, whether a DC power supply or an advanced programmable power supply, ensures optimal performance, efficiency, and reliability across industries in Singapore.
• Up to 21 kVA at 3U
• Voltage can reach 350V L-N
• Highly efficient power regeneration + AC E-Load
• Master and slave equal flow, parallelmachines up to 1MVA
• Working mode: single-phase, three-phase, reversed phase and multi-channel, Voltage extension to 200% of rated voltage in reversed mode
Genetron's power supplies and electronic loads are engineered for precise voltage and current output, ensuring consistent and accurate results for your testing needs across various applications.
Built with high-quality materials and advanced technology, Genetron products are designed to withstand demanding environments, providing reliable performance that you can depend on for critical operations.
Our power supplies are suitable for a wide range of uses, from laboratory experiments to industrial testing, making them the ideal choice for professionals seeking flexible solutions in the test and measurement industry.
Programmable power supplies come in two main types—linear and switched—each suited to different applications based on performance requirements and design considerations.
Linear power supplies offer a simple design that produces a clean and stable output. These are ideal for applications requiring low noise and minimal electromagnetic interference (EMI). Their drawback is lower efficiency and a bulkier form factor due to larger components.
Switched power supplies, in contrast, use advanced switching techniques to convert power efficiently, resulting in a compact and lightweight design. While they provide higher efficiency and flexibility, their output may have higher noise levels, making them less suited for noise-sensitive tasks.
Understanding these differences allows engineers to select the appropriate power supply for specific requirements, ensuring both performance and cost-effectiveness.
Choosing the right power supply is essential for achieving stable performance, energy efficiency, and accurate test results. Whether selecting a programmable power supply for automated testing or a DC power supply for industrial use, considering the following factors will ensure you get the best fit for your needs.
Determine the required voltage, current, and power capacity. A DC power supply is ideal for applications needing stable direct current, such as circuit testing and device development. If your application requires dynamic voltage changes, a programmable power supply allows precise adjustments for greater flexibility.
Energy efficiency is a key factor when selecting a power supply. A regenerative power supply reduces energy waste by recycling excess power back into the grid. Additionally, features like remote programmability, overvoltage protection, and current-limiting functions improve safety and ease of operation.
Compact power supplies are best suited for laboratory and R&D environments where space is limited. For large-scale industrial applications, modular and scalable systems allow for power expansion to meet growing demands.
By assessing these factors, businesses can select the ideal high-efficiency programmable power supply or DC power supply in Singapore that aligns with their specific requirements, ensuring performance, reliability, and cost-effectiveness.
A DC power supply converts alternating current (AC) from the mains into direct current (DC), providing a stable voltage output. It regulates power to ensure a steady supply for electronic circuits, industrial equipment, and research applications, making it essential for reliable and efficient energy delivery.
A DC power supply provides stable and consistent power to devices requiring direct current. It is used in electronics manufacturing, automotive testing, and telecommunications to ensure precision in power delivery, allowing accurate testing, efficient operations, and reduced risk of power fluctuations.
Yes, a DC power supply is suitable for both prototyping and production. In prototyping, it provides adjustable voltage for testing circuit designs. In production, it ensures stable and repeatable power conditions for manufacturing, quality control, and device validation in industries like aerospace, medical devices, and consumer electronics.
A programmable power supply allows users to control and adjust voltage, current, and power settings digitally. It enables automation, remote control, and customised test sequences, making it ideal for R&D, testing labs, and industrial applications that require variable power outputs and precise regulation.
A programmable power supply offers flexibility, automation, and precision. It allows engineers to simulate different power conditions, automate testing processes, and ensure accurate voltage and current regulation. These features are crucial in industries such as telecommunications, automotive, and semiconductor testing.
A programmable power supply is needed when precise voltage and current adjustments are required for testing, automation, or research. It is commonly used in electronics design, automotive battery testing, and semiconductor validation, where repeatable and controlled power conditions are essential.
Yes, programmable power supplies come in various types, including linear, switched-mode, and regenerative models. Linear power supplies offer low noise and high precision, while switched-mode supplies provide efficiency and compact design. Regenerative power supplies recycle excess energy, making them ideal for applications requiring energy recovery.
Battery simulators replicate various battery conditions, enabling accurate testing of devices like electric vehicles and portable electronics without relying on physical batteries. This saves time and resources while ensuring consistency.
