2025年12月16日

1. The raw materials for carbon fiber mainly come from polymer organic compounds and petroleum extracts. In the production process, only 1 ton of carbon fiber can be burned from 2-2.2 tons of raw silk, with a cost of about 40000 to 60000 tons, which is 4-5 times that of steel. 2. High electricity costs: The processing technology of carbon fiber mainly involves heat treatment, which requires a large amount of electricity. Electricity accounts for 25% -30% of the production cost of carbon fiber, making it a major electricity consumer. 3. The process is complex and costly: the research and production of carbon fiber involves interdisciplinary research, and the entire

For decades, carbon fiber and its composite materials have solidified their position as staples in the advanced materials sector. Renowned for their exceptional strength, robust durability, and lightweight properties, these materials have become the preferred choice for applications where performance and efficiency are paramount. The primary breakthrough direction in the technological evolution of carbon fiber and its composites lies in enhancing their strength and toughness while preserving their inherent lightweight characteristics and other favorable properties. This focus has driven the development of next-generation carbon fiber materials that boast unprecedented levels of strength and long-term reliability. One sector witnessing remarkable strides in the adoption and advancement of carbon fiber composites is

Sports cars are renowned for their potent performance engines, streamlined aesthetics, and remarkable velocity. Yet another defining trait that distinguishes them from regular passenger vehicles lies in the adoption of carbon fiber composites during their manufacturing process. Carbon fiber is a high-tensile, low-weight composite material produced by interlacing carbon filaments into a fabric, which is subsequently bonded with a specialized resin. This unique composition renders it an optimal choice for sports cars, where even marginal weight savings can exert a substantial impact on both speed and maneuverability. Beyond its weight-reduction benefits, carbon fiber also boasts exceptional sturdiness and longevity. This enables sports cars constructed with carbon fiber to endure high-speed

Carbon fiber-reinforced polymers (CFRPs) have found widespread adoption across diverse industrial sectors, thanks to their inherent properties of being lightweight, high-strength, and long-lasting. In recent years, the medical device industry has also embarked on exploring the integration of CFRPs into the design and manufacturing of medical equipment—encompassing prosthetics, implants, and surgical instruments. A key benefit of CFRPs in medical applications lies in their biocompatibility. These composite materials can be surface-treated with biocompatible coatings to boost their compatibility with human tissues, positioning them as a preferred choice for implants and prosthetic components. Additionally, CFRPs exhibit exceptional fatigue resistance, rendering them a robust and long-service-life material for medical devices that are subjected