Honda motor co., ltd. (20240332604). SOLID ELECTROLYTE COMPOSITE simplified abstract
Contents
- 1 SOLID ELECTROLYTE COMPOSITE
- 1.1 Organization Name
- 1.2 Inventor(s)
- 1.3 SOLID ELECTROLYTE COMPOSITE - A simplified explanation of the abstract
- 1.4 Potential Applications
- 1.5 Problems Solved
- 1.6 Benefits
- 1.7 Commercial Applications
- 1.8 Prior Art
- 1.9 Frequently Updated Research
- 1.10 Questions about Solid Electrolyte Compositions
- 1.11 Original Abstract Submitted
SOLID ELECTROLYTE COMPOSITE
Organization Name
Inventor(s)
Kizashi Iwakiri of Saitama (JP)
Takuya Taniuchi of Saitama (JP)
Toshimitsu Tanaka of Saitama (JP)
SOLID ELECTROLYTE COMPOSITE - A simplified explanation of the abstract
This abstract first appeared for US patent application 20240332604 titled 'SOLID ELECTROLYTE COMPOSITE
The present disclosure pertains to a solid electrolyte composition that aims to achieve a balance between energy density and strength in a solid-state battery. The composition includes a solid electrolyte composite positioned between a positive electrode layer and a negative electrode layer in a solid-state battery. This composite consists of a positive electrode side solid electrolyte layer near the positive electrode layer and a negative electrode side solid electrolyte layer near the negative electrode layer, with a stepped shape between them. The negative electrode side solid electrolyte layer contains a higher content of filler and/or porous substrate compared to the positive electrode side solid electrolyte layer.
- Solid electrolyte composition for solid-state batteries
- Composite structure with positive and negative electrode side layers
- Stepped shape design for enhanced compatibility
- Higher filler and/or porous substrate content in the negative electrode side layer
- Balancing energy density and strength in solid-state batteries
Potential Applications
The solid electrolyte composition can be utilized in various solid-state battery applications, including electric vehicles, portable electronics, and grid energy storage systems.
Problems Solved
This innovation addresses the challenge of achieving compatibility between energy density and strength in solid-state batteries, which is crucial for enhancing battery performance and longevity.
Benefits
- Improved energy density in solid-state batteries - Enhanced strength and durability - Better overall performance and efficiency
Commercial Applications
The solid electrolyte composition can revolutionize the battery industry by enabling the development of more efficient and reliable solid-state batteries for a wide range of applications, leading to advancements in electric vehicles, consumer electronics, and renewable energy storage systems.
Prior Art
Readers interested in exploring prior art related to solid electrolyte compositions for solid-state batteries can start by researching existing patents and scientific literature in the field of battery technology and materials science.
Frequently Updated Research
Stay updated on the latest research and developments in solid electrolyte compositions for solid-state batteries by following reputable scientific journals and conferences in the field of energy storage technologies.
Questions about Solid Electrolyte Compositions
What are the key advantages of using solid electrolyte compositions in solid-state batteries?
Solid electrolyte compositions offer advantages such as improved safety, higher energy density, and longer cycle life compared to traditional liquid electrolytes.
How does the stepped shape design in the solid electrolyte composite contribute to the performance of solid-state batteries?
The stepped shape design helps optimize the interface between the positive and negative electrode side layers, enhancing the overall efficiency and stability of the battery system.
Original Abstract Submitted
the present disclosure relates to a solid electrolyte composition that can achieve compatibility between energy density and strength of a solid-state battery. provided is a solid electrolyte composite disposed between a positive electrode layer and a negative electrode layer in a solid-state battery, comprising a positive electrode side solid electrolyte layer disposed in a side closer to the positive electrode layer and a negative electrode side solid electrolyte layer disposed in a side closer to the negative electrode layer, the solid electrolyte composite having a stepped shape having a step between the positive electrode side solid electrolyte layer and the negative electrode side solid electrolyte layer, at least the negative electrode side solid electrolyte layer comprising a filler and/or a porous substrate, the negative electrode side solid electrolyte layer having a higher content of the filler and/or the porous substrate than the positive electrode side solid electrolyte layer.
