DEHYDROGENATION REACTION DEVICE AND SYSTEM HAVING THE SAME

Organization Name

HYUNDAI MOTOR COMPANY

Inventor(s)

Yongwoo Kim of Gunpo-si (KR)

Jin Woo Choung of Suwon-si (KR)

Jihui Seo of Ulsan (KR)

Jaeyong Lee of Seongnam-si (KR)

Pyung Soon Kim of Suwon-si (KR)

Minkyu Kim of Seoul (KR)

Yoondo Kim of Seoul (KR)

Yu-Jin Lee of Seoul (KR)

Jaewon Kirk of Seoul (KR)

Suk Woo Nam of Seoul (KR)

Yongmin Kim of Seoul (KR)

Hyangsoo Jeong of Seoul (KR)

DEHYDROGENATION REACTION DEVICE AND SYSTEM HAVING THE SAME - A simplified explanation of the abstract

This abstract first appeared for US patent application 17863997 titled 'DEHYDROGENATION REACTION DEVICE AND SYSTEM HAVING THE SAME

Simplified Explanation

The abstract describes a dehydrogenation reaction device that includes an acid aqueous solution storage unit, a water storage unit, and a dehydrogenation reaction unit. The dehydrogenation reaction unit receives a mixture of a first aqueous acid solution and water, and reacts with a chemical hydride to produce hydrogen.

• Acid aqueous solution storage unit: Contains a first aqueous acid solution.
• Water storage unit: Stores water.
• Dehydrogenation reaction unit: Reacts a chemical hydride with a second aqueous acid solution (a mixture of the first aqueous acid solution and water) to generate hydrogen.

Potential Applications

• Hydrogen production for fuel cells and other applications.
• Energy storage and conversion systems.
• Chemical processes requiring hydrogen as a reactant.

Problems Solved

• Efficient and controlled generation of hydrogen.
• Simplified and compact device design.
• Utilization of acid aqueous solutions and chemical hydrides for hydrogen production.

Benefits

• Improved hydrogen production efficiency.
• Cost-effective and scalable device design.
• Versatile application in various industries.
• Environmentally friendly alternative to traditional hydrogen production methods.

Original Abstract Submitted

A dehydrogenation reaction device includes: an acid aqueous solution storage unit including a first aqueous acid solution; a water storage unit including water; and a dehydrogenation reaction unit including a chemical hydride. The dehydrogenation reaction unit receives a second aqueous acid solution in which the first aqueous acid solution and water are mixed, and further reacts the chemical hydride and the second aqueous acid solution to generate hydrogen.