18511234. WATER ELECTROLYSIS APPARATUS simplified abstract (TOYOTA JIDOSHA KABUSHIKI KAISHA)
WATER ELECTROLYSIS APPARATUS
Organization Name
TOYOTA JIDOSHA KABUSHIKI KAISHA
Inventor(s)
Yasuhiro Izawa of Mishima-shi (JP)
WATER ELECTROLYSIS APPARATUS - A simplified explanation of the abstract
This abstract first appeared for US patent application 18511234 titled 'WATER ELECTROLYSIS APPARATUS
The abstract describes a water electrolysis stack that includes a water electrolysis cell, a water supply side path for supplying water, and a hydrogen side path for recovering hydrogen.
- Water supply side path features:
- Pump as power source for supplying water - Ion exchanger between pump and electrolysis stack - Bypass for water flow without passing through ion exchanger - Valve for adjusting water flow to bypass - Controller for valve adjustment
Key Features and Innovation: - Integration of pump, ion exchanger, bypass, valve, and controller in water supply path for efficient water electrolysis process
Potential Applications: - Industrial hydrogen production - Renewable energy storage - Fuel cell technology
Problems Solved: - Efficient water supply management in electrolysis process - Enhanced hydrogen recovery from electrolysis stack
Benefits: - Increased efficiency in hydrogen production - Reduced energy consumption - Improved control over water flow in electrolysis process
Commercial Applications: - Hydrogen production plants - Renewable energy facilities - Fuel cell technology companies
Prior Art: - Prior research on water electrolysis efficiency and hydrogen recovery methods
Frequently Updated Research: - Ongoing studies on water electrolysis stack optimization and performance improvements
Questions about Water Electrolysis Stack: 1. How does the integration of a pump and ion exchanger improve the efficiency of the water electrolysis process? 2. What are the potential environmental benefits of using a water electrolysis stack for hydrogen production?
Original Abstract Submitted
A water electrolysis stack in which a water electrolysis cell is laminated, a water supply side path for supplying water to the water electrolysis stack, and a hydrogen side path for recovering hydrogen generated from the water electrolysis stack are provided, and the water supply side path includes a pump which is a power source for supplying water to the water electrolysis stack, an ion exchanger arranged between the pump and the water electrolysis stack, a bypass which is a path for flowing water from the pump to the water electrolysis stack without passing through the ion exchanger, a valve for adjusting an amount of water flowing to the bypass, and a controller for adjusting a valve.