Carbon strips are thin strips of carbon or graphite that find wide applications across diverse industries due to their unique properties. Made from highly compressed carbon or petroleum coke, these strips exhibit high thermal and electrical conductivity, corrosion resistance, and tremendous strength. Owing to these qualities, carbon strips have emerged as a preferred alternative to metals in applications requiring heat dissipation, sparking, electrical contacts and more.
CoherentMI delves deeper into carbon strips, their manufacturing process, properties, and key areas of usage in Carbon Strips Market.
Manufacturing of Carbon Strips
Carbon strips are manufactured through a process known as graphitization. In the initial step, select grades of coke or carbonaceous materials are crushed into a fine powder. This powder is compacted under high pressure to form blocks. The blocks are then baked at temperatures over 2000 °C in limited oxygen or inert environments. During this baking phase, the carbon atoms within the blocks rearrange and align themselves in crystalline graphitic patterns. The well-baked blocks are then processed through precision cutting machines to get long strips or ribbons of highly oriented pyrolytic graphite or carbon. Proper quality checks ensure the strips meet industry specifications.
Key Properties
Some of the notable properties of carbon strips that make them widely applicable include:
- High Thermal Conductivity: Carbon strips can conduct heat up to 4-5 times better than copper. This allows for efficient heat dissipation.
- Electrical Conductivity: Depending on production methods, carbon strips can be conductive or non-conductive. Conductive grades find usage as electrodes, brushes, etc.
- Strength: Carbon strips have a tensile strength ranging from 3000-5000 psi, greater than steel.
- Chemical Resistance: Being inert in nature, carbon strips don’t corrode or react with acids, bases or organic solvents.
- Self-Lubricating: The graphitic layers within carbon strips help reduce friction and wear during sliding motion.
Areas of Application
Given their unique feature profile, carbon strips have emerged as the material of choice across various industries:
- Brakes: As brake pads or shoes, carbon composite formulas with strips provide better stopping power and longer lifespan than conventional materials. The self-lubricating property reduces brake fade.
- Electronics: Used as brushes or contacts in motors, generators, switches etc. due to high conductivity and wear resistance.
- Heat Sinks: Carbon strip based heat sinks efficiently pull heat away from electronics components, protecting them from overheating.
- Energy Storage: Graphene derived carbon strips show potential as anode materials in lithium-ion batteries due to fast charging ability.
- Industrial Equipment: Found in machines dealing with molten metals to dissipate heat, in kilns for heat distribution, and as linings enduring thermal stresses.
- Automotive: From glow plugs and spark plugs to seals and gaskets, carbon components enhance engine efficiency and lifespan.
- Aerospace: Carbon-carbon composites using coated carbon fiber or siliconized strips withstand high temperatures in spacecraft and jet engine parts.
Market Outlook
The carbon strip market has been growing steadily over the past few years. Technological advancements across various industries coupled with rising demand for products like electronics, automobiles, etc. have driven greater consumption of carbon strips. Asia Pacific currently dominates the carbon strip market driven by countries like China, Japan and India. However, North America and Europe are also lucrative regions. Recent trends indicate graphene infused carbon strips could gain prominence over the coming years. For more detailed analysis on the carbon strip market opportunity size, segmental forecasts, regional shares and demand driving factors, refer the market research report published by CoherentMI.