Indoor Green Hydrogen Generators Water Electrolysis 3ph 10KVAC

Green Hydrogen, Water Electrolysis,  Hydrogen Generator

Hydrogen Importance and Background

Hydrogen can be used much more widely. Today, hydrogen is used mostly in oil refining and for the production of fertilizers. For it to make a significant contribution to clean energy transitions, it also needs to be adopted in sectors where it is almost completely absent at the moment, such as transport, buildings, and power generation.
The Future of Hydrogen provides an extensive and independent survey of hydrogen that lays out where things stand now; how hydrogen can help to achieve a clean, secure, and affordable energy future; and how we can go about realizing its potential.

Hydrogen can be extracted from fossil fuels and biomass, from water, or a mix of both. Natural gas is currently the primary source of hydrogen production, accounting for around three-quarters of the annual global dedicated hydrogen production of around 70 million tonnes. This accounts for about 6% of global natural gas use. Gas is followed by coal, due to its dominant role in China, and a small fraction is produced from the use of oil and electricity.
The production cost of hydrogen from natural gas is influenced by a range of technical and economic factors, with gas prices and capital expenditures being the two most important.

Fuel costs are the largest cost component, accounting for between 45% and 75% of production costs. Low gas prices in the Middle East, Russia, and North America give rise to some of the lowest hydrogen production costs. Gas importers like Japan, Korea, China, and India have to contend with higher gas import prices, and that makes for higher hydrogen production costs.

While less than 0.1% of global dedicated hydrogen production today comes from water electrolysis, with declining costs for renewable electricity, in particular from solar PV and wind, there is growing interest in electrolytic hydrogen.

With declining costs for renewable electricity, in particular from solar PV and wind, interest is growing in electrolytic hydrogen and there have been several demonstration projects in recent years. Producing all of today’s dedicated hydrogen output from electricity would result in an electricity demand of 3 600 TWh, more than the total annual electricity generation of the European Union.

Under the background of the "3060 carbon peak and carbon neutrality" policy, the installed capacity of clean energy such as wind power will continue to grow rapidly, and green hydrogen may usher in a period of rapid development. According to the forecast of China Hydrogen Energy Alliance, by 2050, the proportion of hydrogen production from renewable energy electrolysis will reach 70%.
In 2020, China announced its ambition to be carbon neutral by 2060. The use of hydrogen will be important, especially in China's huge industrial sector which accounts for 60% of the final energy demand. The use of hydrogen as an alternative to fossil fuels received attention even before China's net-zero commitment, as it was seen as a means to address urban air quality problems.

Description of existing technology

Hydrogen production technology from water electrolysis includes:
Alkaline Electrolyzed Water for Hydrogen Production (AWE)
Proton exchange membrane electrolysis of water for hydrogen production (PEM)
Anion exchange membrane electrolysis of water for hydrogen production (AEM)
Solid oxide electrolysis of water for hydrogen production (SOE)

Product Introduction

The water electrolysis hydrogen (Oxygen) plant is equipment that electrolyzes water to produce hydrogen and oxygen by using lye as an electrolyte.

Water H2O + Power = Hydrogen H2 (+ Oxygen O2)

Product advantage:

Mature and advanced technology, lower power consumption and cost, high pressure, and purity, no pollution, and zero emission.

World-leading technology
High Efficiency/Low Consumption
Reliable Performance
Solid Quality & Performance
Less footprint

Technical Details:

Condition: New

Place of origin: Suzhou, China

H2 output flow: 5~1300Nm3/h

O2 output flow: 2.5~ 650Nm3/h

H2 output pressure: 1.5~2Mpa(G)

H2 purify after purification: 99.9995%

Impurities: O2: 3ppm(max), N2: 5ppm(max)

Dew Point: -70 deg. C

Guaranteed Performance