18299298. Sulfur Dioxide-Based Inorganic Electrolyte Doped with Fluorine Compound, Method of Manufacturing the Same, and Secondary Battery Including the Same simplified abstract (KIA CORPORATION)

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Sulfur Dioxide-Based Inorganic Electrolyte Doped with Fluorine Compound, Method of Manufacturing the Same, and Secondary Battery Including the Same

Organization Name

KIA CORPORATION

Inventor(s)

Kyu Ju Kwak of Hwaseong-si (KR)

Won Keun Kim of Seoul (KR)

Eun Ji Kwon of Yongin-si (KR)

Samuel Seo of Yongin-si (KR)

Yeon Jong Oh of Seoul (KR)

Kyoung Han Ryu of Yongin-si (KR)

Dong Hyun Lee of Seoul (KR)

Han Su Kim of Seoul (KR)

Ji Whan Lee of Seoul (KR)

Seong Hoon Choi of Seoul (KR)

Seung Do Mun of Seoul (KR)

Sulfur Dioxide-Based Inorganic Electrolyte Doped with Fluorine Compound, Method of Manufacturing the Same, and Secondary Battery Including the Same - A simplified explanation of the abstract

This abstract first appeared for US patent application 18299298 titled 'Sulfur Dioxide-Based Inorganic Electrolyte Doped with Fluorine Compound, Method of Manufacturing the Same, and Secondary Battery Including the Same

Simplified Explanation

The abstract describes an embodiment of a sulfur dioxide-based inorganic electrolyte represented by a chemical formula M·(A·ClF)·ySO, where M is a first element selected from Li, Na, K, Ca, and Mg, A1 is a second element selected from Al, Fe, Ga, and Cu, x satisfies 0≤x≤4, y satisfies 0≤y≤6, and z satisfies 1≤z≤2.

  • This innovation provides a sulfur dioxide-based inorganic electrolyte with specific elements and ratios for improved performance.
  • The electrolyte formula includes elements like Li, Na, K, Ca, Mg, Al, Fe, Ga, and Cu, allowing for flexibility in applications.
  • The specified ranges for x, y, and z ensure the electrolyte's stability and effectiveness in various conditions.

Potential Applications

The technology could be used in:

  • Energy storage systems
  • Batteries for electric vehicles
  • Portable electronic devices

Problems Solved

  • Enhanced stability and performance of electrolytes
  • Increased efficiency in energy storage systems

Benefits

  • Improved energy storage capacity
  • Longer battery life
  • Enhanced safety features

Potential Commercial Applications

Optimized for:

  • Electric vehicle batteries
  • Renewable energy storage systems

Possible Prior Art

No known prior art at this time.

Unanswered Questions

How does this electrolyte compare to traditional lithium-ion battery electrolytes in terms of performance and cost?

Answer: Further research and comparative studies are needed to determine the exact advantages and disadvantages of this sulfur dioxide-based electrolyte compared to traditional options.

What are the potential environmental impacts of using this new electrolyte in large-scale energy storage applications?

Answer: Environmental assessments and life cycle analyses would be necessary to evaluate the sustainability of implementing this technology on a larger scale.


Original Abstract Submitted

An embodiment sulfur dioxide-based inorganic electrolyte is provided in which the sulfur dioxide-based inorganic electrolyte is represented by a chemical formula M·(A·ClF)·ySO. In this formula, M is a first element selected from the group consisting of Li, Na, K, Ca, and Mg, A1 is a second element selected from the group consisting of Al, Fe, Ga, and Cu, x satisfies a first equation 0≤x≤4, y satisfies a second equation 0≤y≤6, and z satisfies a third equation 1≤z≤2.