THE FINAL SOLUTION TO THE CO2 PROBLEM. The Advantages of Chemical Technology in Green Hydrogen Production.

The Basics of Chemical Engineering

Final Solution to the CO2 Challenge

- CO2 is often viewed as a major contributor to global warming, but it should be seen as a valuable resource. By Allan Otto Head of Development and Commercialization

- The key to addressing the CO2 challenge lies in harnessing it as an energy resource. Through the process of CO2 utilization, to turn it into a viable energy source.

Through the process of "hydrogenation", a process in which carbon dioxide (CO2) reacts with water (H2O) and a chemical mixture to generate hydrogen (H2) at an extremely low price level per KG/H2 under 0,50 EUR.

This process is crucial in power-to-gas (PtG) technology and the production of natural green hydrogen gas (GHG). It makes any country independent from fossil fuels and imports.

Additionally, natural green hydrogen gas can confidently be utilized to produce "green fuels" of any type of liquid useful green fuel or electricity.

- The governments must commit to this approach if they are seriously aiming to convert 90% of CO2 emissions into green, natural, harmless hydrogen by 2050.

Chemical engineering is often underestimated. At its essence, it involves converting raw materials into valuable products through chemical processes. This field holds remarkable potential, promising significant savings for businesses and the environment. Hydrogenerous chemical technology can lower production costs by 90% while minimizing waste to zero, making it a win-win solution, especially in green hydrogen production.

The Danish Energy Agency illustrates that trees and forests naturally absorb carbon dioxide from the atmosphere.

Similarly, chemical engineering employs techniques such as absorption to capture CO2 emissions for direct use in green hydrogen production, akin to how trees and forests absorb carbon.

Subterranean concrete and steel reactors have been developed to ensure minimal emissions, highlighting the importance of chemical engineering in environmental protection.

Has Hydrogenerous made the process significantly more efficient? Our new methodologies in chemical engineering streamline hydrogen production, reducing costs to a very affordable level, while lessening the environmental impact typically linked to traditional methods.

The Advantages of Chemical Technology in Green Hydrogen Production

Chemical technology offers several advantages that distinguish it from conventional methods, including:

1. Simplicity and Efficiency: Modern chemical engineering approaches enable the use of various feedstocks, including waste materials. The chemical reaction also utilizes resources that would otherwise go to waste.

   
   

2. Environmental Impact: Emphasizing the absorption of harmful emissions, these techniques result in clean production processes. Not only does this make green hydrogen production more sustainable, but it also positively contributes to environmental recovery by absorbing CO2.

   
   

3. Cost-effectiveness: By maximizing existing resources and harnessing innovative processes, chemical engineering can lower hydrogen production costs. This reduction can benefit consumers and stimulate economic growth. According to recent estimates, advanced chemical methods could decrease hydrogen production costs by nearly 80 to 90% compared to traditional methods like electrolysis.

   
   

Chemical engineering is simple, green, cheap, and harmless to the environment and nature.

When a concept is straightforward, it can often be challenging to comprehend, particularly when innovative chemical engineering serves as the foundation for substantial savings and significant growth.

CO2 absorption refers to the process by which forests or trees capture carbon dioxide from the atmosphere. In discussions with professors from leading universities in chemical engineering, this process is also referred to as absorption or absorbing CO2 within scientific frameworks. Some may use the term "consumption." The distinction lies in the chemical production process of green hydrogen, where CO2 is prevented from entering the atmosphere by being absorbed within the reaction itself inside the steel tank, which is why it is termed a reactor.

To ensure a comprehensive understanding, particularly regarding the political impact on the green transition, it is crucial to be informed about chemical technology. I will endeavor to explain the process of producing green hydrogen through chemical means in a clear and accessible manner, highlighting the benefits of this advantageous method.

Hydrogen can be produced through various methods when water and combustible materials or iron are present. These methods have been understood for centuries, so I will not delve into the specifics.

The commonly recognized and utilized method for producing green hydrogen is the PtX electrolysis process, which has been in use for 200 years and is notably costly. This method necessitates a substantial amount of green energy derived from wind turbines, whether offshore or onshore, or from large solar installations, as well as using distilled water. However, both solar and wind energies, despite being classified as renewable, can negatively impact local communities and the natural environment in certain areas. Additionally, their effectiveness is limited by their dependence on weather conditions, making them unsuitable as long-term solutions.

What factors should be considered for change? What benefits can be achieved through the use of Chemical Technology in green hydrogen production?

1. The chemical technology employed by Hydrogenerous for green hydrogen production offers significant advantages over traditional electrolysis methods.

2. This chemical technology can utilize all forms of water, including seawater.

3. Additionally, it can process all forms of CO2, even those with low concentrations.

4. The only continuous inputs to the reactor's chemical elements and materials, referred to as chemical mixtures, are a flow system that introduces water and CO2.

5. The process includes CO2 capture, effectively preventing carbon emissions from entering the atmosphere.

6. The combustion of green hydrogen results in the formation of clean water, making it a zero-emission fuel or energy carrier.

7. It is crucial to note that this innovative method of producing Green Chemical Hydrogen does not rely on electricity from renewable sources like solar or wind energy, nor does it require external energy. Instead, it is a straightforward chemical reaction that efficiently produces green hydrogen.

   
   

What is the significance of the seven announcements mentioned above?

1. There is no requirement for wind turbines in the production of green hydrogen.

2. Solar installations are not necessary for the production of green hydrogen.

3. Distilled water is not needed in this process.

4. Long-term storage of CO2 (CCS) is not required.

5. CO2 can be directly utilized for the production of green hydrogen.

6. CO2 capture can be temporarily stored and used to promote growth.

7. The most CO2-intensive industries can benefit from subsidies and improved economics by ceasing fossil fuel consumption, thereby largely avoiding CO2 taxes and generating positive economic outcomes from their carbon emissions, effectively profiting from utilization.

8. The cost of producing green hydrogen will not exceed 14 EUR, but will be reduced to only 0,5 EUR with the new method.

9. There is no need for complex, uncertain infrastructure solutions that lack financial viability.

   
   

What modifications are necessary?

Currently, substantial subsidies ranging from 80 to 120 EUR per ton are provided for storing CO2 in abandoned oil rigs. This arrangement allows fossil fuel companies, who are responsible for pollution and atmospheric imbalance, to benefit financially, which is inequitable.

There is no subsidy available for the direct utilization of CO2 in hydrogen production. Consequently, CO2 must first be stored to qualify for subsidies before it can be used for hydrogen. This approach enables us to access funding that would otherwise be directed solely to fossil fuel companies.

It is essential to consider modern legislation and significantly higher subsidies for the direct utilization of CO2, known as Carbon Capture Utilization (CCU), or as we refer to it, Direct Carbon Utilization (DCU) for green hydrogen production.

Due to current subsidies, valuable CO2 is being sequestered, resulting in considerable expense for EU and world citizens.

Green hydrogen serves as an ideal complement to wind and solar energy, which can now independently supply electricity to the grid and for export. As fossil fuels become obsolete, this represents an innovative and groundbreaking solution.

Establishment of Efficient CO2 Absorption and Recovery Technology. We have successfully initiated a strong dialogue and are preparing partnerships with corporations specializing in low-cost and straightforward CO2 capture and recovery technology. Working closely with universities and applying direct carbon utilization to low-cost facilities to further reduce expenses.

To generate 30.03 kg of green hydrogen equivalent to 1 MWh, the Hydrogenerous chemical production facility confidently utilizes a 3 by 6-meter container operating 24/7. Solar installations require 3 to 5 hectares of land to deliver 1 MWh, contingent on the daily sunlight hours.

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