Conductive Composite Material, Method of Preparing Same, and Lithium Secondary Battery Comprising Same

Organization Name

Kia Corporation

Inventor(s)

Seung Min Oh of Incheon (KR)

Sung Ho Ban of Hwaseong-Si (KR)

Sang Hun Lee of Paju-Si (KR)

Ko Eun Kim of Cheongju-Si (KR)

Yoon Sung Lee of Suwon-Si (KR)

Chang Hoon Song of Seoul (KR)

Hyeong Jun Choi of Suwon-Si (KR)

Jun Myoung Sheem of Suwon-Si (KR)

Jin Kyo Koo of Suwon-si (KR)

Young Jun Kim of Seongnam-si (KR)

Conductive Composite Material, Method of Preparing Same, and Lithium Secondary Battery Comprising Same - A simplified explanation of the abstract

This abstract first appeared for US patent application 18371275 titled 'Conductive Composite Material, Method of Preparing Same, and Lithium Secondary Battery Comprising Same

Simplified Explanation

The abstract describes a conductive composite material and a method of preparing it, as well as a secondary battery including the material. The conductive composite material increases the proportion of an active material in an electrode by chemically bonding a conductive material and a binder together. The method involves ionizing carbon-based particles and PTFE particles in different polarities, then chemically bonding them to each other.

• Conductive composite material with increased active material proportion
• Method involves ionizing carbon-based and PTFE particles in different polarities
• Chemical bonding of ionized particles to form the composite material

Potential Applications

The conductive composite material can be used in various applications such as:

• Lithium-ion batteries
• Fuel cells
• Capacitors

Problems Solved

This technology addresses the following issues:

• Low proportion of active material in electrodes
• Inefficient energy storage in batteries
• Poor conductivity in composite materials

Benefits

The benefits of this technology include:

• Improved energy storage capacity
• Enhanced conductivity
• Longer battery life

Potential Commercial Applications

The conductive composite material can be commercially applied in:

• Electric vehicles
• Portable electronic devices
• Renewable energy storage systems

Possible Prior Art

One possible prior art could be the use of conductive additives in composite materials for electrodes in batteries. However, the specific method of ionizing carbon-based and PTFE particles in different polarities to chemically bond them may be a novel approach.

Unanswered Questions

How does this technology compare to existing conductive composite materials in terms of performance and cost?

This article does not provide a direct comparison with existing materials in the market. Further research or testing may be needed to evaluate the performance and cost-effectiveness of this technology compared to others.

What are the potential environmental impacts of using this conductive composite material in batteries?

The environmental implications of using this material, such as the recyclability of the components or the energy efficiency of the batteries, are not discussed in the article. Additional studies could explore the sustainability aspects of this technology.

Original Abstract Submitted

A conductive composite material, a method of preparing the same, and a secondary battery including the same. The conductive composite material may increase the proportion of an active material when forming an electrode by chemically bonding a conductive material and a binder to each other. A method of preparing the conductive composite material comprises ionizing carbon-based particles in a predetermined polarity, ionizing PTFE particles in a polarity different from that of the carbon-based particles, and chemically bonding the ionized carbon-based particles and the ionized PTFE particles, which are ionized in different polarities, to each other.