fibrous braiding

简明释义

纤维编包

英英释义

例句

1.In the construction of the boat, fibrous braiding was essential for enhancing the durability of the hull.

在船只的建造中，纤维编织对于增强船体的耐用性至关重要。

2.The artist used fibrous braiding to create intricate patterns in her textile work.

艺术家使用纤维编织在她的纺织作品中创造复杂的图案。

3.Many modern backpacks utilize fibrous braiding for added strength and flexibility.

许多现代背包利用纤维编织来增加强度和灵活性。

4.The new yoga mats feature fibrous braiding to improve grip and stability during practice.

新的瑜伽垫采用纤维编织来提高练习时的抓地力和稳定性。

5.The engineering team experimented with fibrous braiding to create lighter and stronger composite materials.

工程团队尝试使用纤维编织来创造更轻且更强的复合材料。

作文

In the realm of materials science and engineering, the concept of fibrous braiding plays a crucial role in the development of advanced composite materials. Fibrous braiding refers to a technique where multiple strands of fiber are intertwined in a specific pattern to create a strong, flexible, and lightweight structure. This method is particularly significant in industries such as aerospace, automotive, and sports equipment manufacturing, where high performance and durability are essential.The process of fibrous braiding involves the use of various types of fibers, including carbon, glass, and aramid fibers. Each type of fiber has its unique properties, such as strength, weight, and resistance to heat and chemicals. By carefully selecting and combining these fibers, engineers can tailor the mechanical properties of the final product to meet specific requirements. For instance, carbon fibers are known for their exceptional strength-to-weight ratio, making them ideal for applications in aircraft components and high-performance vehicles.One of the key advantages of fibrous braiding is its ability to produce complex geometries that would be challenging to achieve with traditional manufacturing methods. The braiding process allows for the creation of intricate shapes and designs, which can enhance the performance of the final product. For example, in the production of bicycle frames, fibrous braiding can be used to create tubes that are not only lightweight but also possess superior impact resistance.Moreover, fibrous braiding contributes to the overall sustainability of manufacturing processes. As the demand for eco-friendly materials rises, the use of natural fibers in braiding techniques has gained popularity. Natural fibers, such as hemp, flax, and jute, offer an environmentally friendly alternative to synthetic fibers. By integrating these materials into the braiding process, manufacturers can reduce their carbon footprint while still delivering high-performance products.In addition to its applications in consumer goods, fibrous braiding is also making waves in the medical field. Researchers are exploring the use of braided structures for creating scaffolds in tissue engineering. These scaffolds can support cell growth and tissue regeneration, potentially leading to breakthroughs in regenerative medicine. The versatility of fibrous braiding allows for customization in terms of pore size, fiber orientation, and mechanical properties, all of which are critical factors in successful tissue engineering.As technology continues to advance, the future of fibrous braiding looks promising. Innovations in automated braiding machines and computer-aided design are enabling manufacturers to produce braided structures more efficiently and with greater precision. This progress will likely lead to even more applications across various industries, further highlighting the importance of fibrous braiding in modern engineering.In conclusion, fibrous braiding is a vital technique that enhances the performance and sustainability of composite materials. Its ability to create strong, lightweight, and complex structures opens up new possibilities in multiple fields, from aerospace to medicine. As we continue to explore the potential of this innovative approach, it is clear that fibrous braiding will remain at the forefront of material development for years to come.

在材料科学和工程领域，纤维编织的概念在先进复合材料的发展中起着至关重要的作用。纤维编织指的是一种技术，其中多根纤维按照特定的模式交织在一起，以创建一种强大、灵活且轻便的结构。这种方法在航空航天、汽车和运动器材制造等行业尤为重要，因为这些领域对高性能和耐用性有着严格的要求。纤维编织的过程涉及使用各种类型的纤维，包括碳纤维、玻璃纤维和芳纶纤维。每种纤维都有其独特的属性，例如强度、重量以及对热和化学品的抵抗力。通过仔细选择和组合这些纤维，工程师可以根据具体要求定制最终产品的机械性能。例如，碳纤维以其卓越的强度与重量比而闻名，使其成为飞机部件和高性能车辆应用的理想选择。纤维编织的一个关键优势是它能够生产复杂的几何形状，而这些形状通过传统制造方法难以实现。编织过程允许创建复杂的形状和设计，这可以增强最终产品的性能。例如，在自行车框架的生产中，纤维编织可以用于创建不仅轻便而且具有优越抗冲击性的管道。此外，纤维编织还促进了制造过程的整体可持续性。随着对环保材料需求的上升，天然纤维在编织技术中的应用越来越受到欢迎。天然纤维，如麻、亚麻和黄麻，提供了一种环保的替代合成纤维的方法。通过将这些材料整合到编织过程中，制造商可以减少其碳足迹，同时仍然提供高性能产品。除了在消费品中的应用，纤维编织在医疗领域也引起了关注。研究人员正在探索使用编织结构来创建组织工程中的支架。这些支架可以支持细胞生长和组织再生，可能导致再生医学的突破。纤维编织的多功能性使得在孔径、纤维方向和机械性能等方面的定制成为可能，这些都是成功的组织工程中的关键因素。随着技术的不断进步，纤维编织的未来看起来充满希望。自动化编织机和计算机辅助设计的创新使制造商能够更高效、更精确地生产编织结构。这一进展可能会导致各行业的更多应用，进一步凸显了纤维编织在现代工程中的重要性。总之，纤维编织是一种重要的技术，它增强了复合材料的性能和可持续性。其创造强大、轻便和复杂结构的能力为多个领域开辟了新可能，从航空航天到医学。随着我们继续探索这种创新方法的潜力，显然纤维编织将在未来几年继续处于材料发展的前沿。