Graphite Flakes can be used as carbon additives in various metallurgical processes to increase the carbon content in steel and ferroalloys. It can enhance the hardness, strength, plasticity and toughness of the material. By adding graphite, the composition of the alloy can also be adjusted to meet specific requirements, thereby improving the performance of the final product.
Because the graphite squama of the graphite Flakes has a layered structure that allows them to slide against each other, the graphite flake is an excellent dry lubricant. Different from the high temperature and high pressure environment that cannot be achieved with traditional lubricants, It has high temperature resistance characteristics. Graphite Flakes lubricants are used in machinery, gears and bearings to reduce friction and wear.
Graphite Flakes can be added to rubber, plastics and other composite materials to improve their mechanical and electrical properties. Moreover, in rubber, graphite enhances electrical conductivity and wear resistance. In plastics, it can confer electrical conductivity and thermal stability, making the material suitable for a range of industrial applications.
Apple uses graphite Flakes as a cooling material in many of its products, taking advantage of their high thermal conductivity to effectively manage heat.
Tesla incorporated graphite material into its electric vehicle battery management system to regulate the temperature of the battery pack. This plays a crucial role in maintaining the efficiency and safety of the system.
Both Boeing and Airbus have incorporated graphite composites into their commercial aircraft programs, benefiting from the material’s strength-to-weight ratio and thermal properties.
Graphite Flakes are a key component of lithium-ion batteries and you can use it as negative electrode materials. Its ability to embed lithium ions makes it an indispensable material in energy storage solutions.
Graphite Flakes are extremely chemically stable and can protect metals from corrosion by acting as a barrier to corrosive agents. This feature is useful in Marine and offshore applications where corrosion resistance is critical.
In the field of metallurgy, especially in the production of grey cast iron, graphite flakes play a vital role. In the solidification process of hot metal, as the carbon content is precipitated from the liquid phase, the graphite flakes will naturally form. These flakes alter the microstructure of the metal, helping to form 흑연 nodules rather than cementite. This change enhances the mechanical properties of cast iron, giving it greater toughness and wear resistance, which is critical for applications that require durability and strength.
The Graphite Flakes is mainly made of Thermal Flexible Graphite sheet, whose chemical composition is mainly a single carbon (C) element, which is a natural element mineral. Among them, the formation of “sheet” is to obtain a graphitized film under high temperature and high pressure of thin-film polymer compounds, because the carbon element is a non-metallic element, but it has the conductivity and thermal conductivity of metal materials.
Graphite can conduct electricity because each carbon atom in graphite and other carbon atoms only forms 3 covalent bonds, and each carbon atom is still reserved 1 free electron to transmit charge. It also has the same plasticity as organic plastics, and has special thermal properties and chemical stability. It is widely used in many fields such as electronics, communications, lighting, aviation and national defense and military industry.