HYDROGEN PRODUCTION

Hydrogen is one of the most abundant elements on Earth. However, most of it is in a bound state. In the form of compounds with carbon, hydrogen is part of oil, combustible hydrocarbon gases, and all living organisms. Hydrogen is universal because it is both a combustible and a chemical raw material. It has a wide range of traditional applications in the chemical industry, used for large-scale production of ammonia, methanol, petrochemical, pharmaceutical, and microbiological industries. Hydrogen, as a versatile, highly efficient, and environmentally friendly energy source, has undeniable advantages over other energy sources.
Firstly, any energy release using hydrogen (fuel cell, conventional hydrogen heating, hydrogen internal combustion engine) produces a very favorable energy / mass ratio – that is, hydrogen is an unusually energy-intensive carrier..

Secondly, when hydrogen is burned, there are no emissions of such harmful substances as carbon dioxide and methane. The formation of CO2 during the implementation of hydrogen energy will largely depend on the technology of hydrogen production.
Thirdly, hydrogen solves the problem of energy storage and transportation complexity. Hydrogen allows energy to be stored and transmitted over distances. When hydrogen interacts with oxygen, 120.7 GJ / t is released, which is the highest amount of energy released per unit mass. This is one of the reasons why liquid hydrogen is used as fuel for rockets and spacecraft power. Indeed, these advantages are indisputable, which opens up great prospects for the use of hydrogen in many areas: transport, energy, and industry.

Our specialist have implemented a completely new principle of converting associated petroleum gas or natural gas into synthesis gas (and then into hydrogen).
The advantages of this process do not require external heat sources, is technologically simple, and does not require complex processes for the production and regeneration of hydrogen. This process requires a cheap catalytic treatment, and the costs of gas purification and treatment are dramatically reduced.
Moreover, it allows you to convert hydrocarbon gases of almost any composition into synthesis gas (and then into hydrogen), including associated petroleum gases and even liquid hydrocarbons. But most importantly, the process has a very high specific volumetric productivity, orders of magnitude higher than, for example, the specific volumetric productivity of steam reforming.
This makes it possible to create incomparably simpler, less metal-consuming, and cheaper facilities than existing processes. That is, it becomes possible to reduce the cost of producing synthesis gas (and then into hydrogen) and consequently, all gas-chemical processes based on its production.