ELECTROCHEMICAL CELL EXHAUST MANAGEMENT SYSTEM

Organization Name

robert bosch gmbh

Inventor(s)

Mordechai Kornbluth of Brighton MA (US)

Daniil Kitchaev of Brookline MA (US)

Tilman Miehle of Waiblingen (DE)

Andrea Di Benedetto of Löchgau (DE)

Thorsten Stahl of Waiblingen (DE)

Charles Tuffile of Swansea MA (US)

Christoph Osemann of Karlsruhe (DE)

ELECTROCHEMICAL CELL EXHAUST MANAGEMENT SYSTEM - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240178426 titled 'ELECTROCHEMICAL CELL EXHAUST MANAGEMENT SYSTEM

Simplified Explanation

The high temperature electrochemical cell component described in the patent application includes a surface portion containing alkaline earth metal-containing, cobalt-free, and nickel-free oxides that react with chromium hydroxide. The most stable reaction between the oxides and chromium hydroxide has a reaction energy of about -0.1 to -0.35 eV/at, and the oxides are non-reactive with water. The high temperature electrochemical cell operates at temperatures ranging from 600-1000°C.

• Alkaline earth metal-containing, cobalt-free, and nickel-free oxides are used in the surface portion of the high temperature electrochemical cell component.
• The oxides react with chromium hydroxide with a reaction energy of about -0.1 to -0.35 eV/at.
• The oxides are non-reactive with water.
• The high temperature electrochemical cell operates at temperatures of about 600-1000°C.

Potential Applications

The technology described in the patent application could be applied in:

• High temperature electrochemical cells
• Energy storage systems
• Fuel cells

Problems Solved

The technology addresses the following issues:

• Compatibility with high temperatures
• Resistance to reactions with water
• Elimination of cobalt and nickel in the cell component

Benefits

The benefits of this technology include:

• Enhanced stability at high temperatures
• Improved efficiency in electrochemical processes
• Reduced risk of corrosion

Potential Commercial Applications

The technology could find commercial applications in:

• Energy storage for renewable energy systems
• Industrial electrochemical processes
• Aerospace applications

Possible Prior Art

One possible prior art could be the use of cobalt and nickel-containing oxides in high temperature electrochemical cell components. However, the innovation in this patent application lies in the use of alkaline earth metal-containing, cobalt-free, and nickel-free oxides that react with chromium hydroxide.

Unanswered Questions

How does the use of alkaline earth metal-containing oxides improve the performance of the high temperature electrochemical cell component?

The patent application mentions that the oxides are reactive with chromium hydroxide, but it does not delve into the specific mechanisms by which this reaction enhances the cell component's performance.

What are the potential challenges in scaling up the production of high temperature electrochemical cells using this technology?

While the patent application highlights the benefits of the technology, it does not address the potential obstacles or limitations that may arise when implementing this innovation on a larger scale.

Original Abstract Submitted

a high temperature electrochemical cell component includes a bulk portion and a surface portion including one or more alkaline earth metal-containing, cobalt free and nickel free, oxides reactive with cr(ho)such that a most stable reaction between each one of the oxides and the cr(ho)has a reaction energy of about −0.1 to −0.35 ev/at, the oxide(s) being non-reactive with water, the high temperature electrochemical cell having an operating temperature of about 600-1000�c.