RESOURCES
Green Hydrogen Production Through Electrolysis
Power Solutions and EMI/EMC Filters for Green Hydrogen Production Process
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Overview of Green Hydrogen Generation Process:
Green Hydrogen, also referred to as GH2 represents a sustainable and eco-friendly solution in the realm of energy production. Its creation involves the innovative process of Electrolysis, which harnesses the power of renewable energy sources like solar and wind power. Through the utilization of PEM Electrolyzers, this advanced technology enables the seamless conversion of DC electricity into hydrogen gas by splitting water molecules. This groundbreaking method not only ensures efficiency but also emphasizes the crucial role of clean energy in shaping a greener future for generations to come.
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What are the various applications of hydrogen in different industries and sectors?
Hydrogen, often hailed as the fuel of the future, has a wide range of applications across various industries and sectors. One significant comparison lies in the use of alternative power sources like Solar+H2 versus traditional options such as Diesel or Natural Gas for backup generators. The Chemical Industry benefits from hydrogen in the production of essential products like Ammonia, Fertilizers, and Petroleum, showcasing its versatility and importance. Moreover, hydrogen's role in Material processing for industries dealing with Petroleum, Crystals, Glass, and Steel highlights its significance in manufacturing processes. In the realm of transportation, hydrogen powers Fuel Cell Electric Vehicles (FCEVs), offering a cleaner and more sustainable option for mobility. This widespread utilization of hydrogen underscores its potential to revolutionize various sectors and pave the way for a greener and more environmentally friendly future.Energy Needs for Producing Green Hydrogen!
In addition to the unique voltage levels and high reliability required for the production of Green Hydrogen, it is essential to utilize constant current (CC) to ensure a consistent and efficient electrolysis process. To maintain optimal performance and prevent overheating, liquid cooling systems are implemented, not only for space-saving purposes but also to operate in polluted environments without compromising the equipment. Furthermore, the very high power levels ranging from tens to thousands of kilowatts demand robust power supplies and EMI/EMC filters to support the demanding energy needs of producing Green Hydrogen. This combination of advanced technology and sustainable practices is crucial in driving the transition towards a cleaner and greener energy future.
Astrodyne TDI Power Solutions for Hydrogen Generation
|
Model |
|
|
|
Input |
90-176 or 176-260VAC auto range (1Ø) 342VAC – 528VAC 3-Phase 4 wire (3Ø) |
342-528VAC, three-phase |
|
Cooling |
Air-cooled programmable power supply |
Liquid-cooled programmable power supply |
|
Output Power |
Up to 3.8KW power per module |
16.5 kW Maximum (see derating chart) |
|
Programmable Outputs |
3V -28V, 5V -56V, 10V -125V, 10V -180V, 10V-250V, 15V-450V |
0-60V, 0-120V, 0-180V, 0-500V |
|
Power Density |
Up to 15.2kW power in a 2U |
Up to 16.5kW power in a 1U |
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Power Factor |
>.97 (1Ø) or >.90 (3Ø) |
>0.93 at full power |
|
Max Efficiency |
>91% |
>93% |
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Height |
2U |
1U |
|
Rack fitment |
4 Across |
1 Across |
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