fiber-reinforced metal

简明释义

纤维增强金属

英英释义

例句

1.Manufacturers are investing in fiber-reinforced metal 纤维增强金属 technology to enhance product performance.

制造商正在投资于纤维增强金属 fiber-reinforced metal 技术，以提高产品性能。

2.Engineers are exploring the benefits of fiber-reinforced metal 纤维增强金属 in automotive applications.

工程师正在探索纤维增强金属 fiber-reinforced metal 在汽车应用中的好处。

3.The aerospace industry is increasingly using fiber-reinforced metal 纤维增强金属 for lightweight components.

航空航天工业越来越多地使用纤维增强金属 fiber-reinforced metal 来制造轻型部件。

4.Research shows that fiber-reinforced metal 纤维增强金属 can withstand higher temperatures than traditional metals.

研究表明，纤维增强金属 fiber-reinforced metal 能够承受比传统金属更高的温度。

5.The use of fiber-reinforced metal 纤维增强金属 can significantly improve the strength-to-weight ratio of structures.

使用纤维增强金属 fiber-reinforced metal 可以显著提高结构的强度重量比。

作文

In recent years, the field of materials science has witnessed significant advancements, particularly in the development of composite materials. One of the most promising innovations in this area is the use of fiber-reinforced metal, which combines the best properties of metals and fibers to create a new class of materials with enhanced performance characteristics. The concept of fiber-reinforced metal (纤维增强金属) involves embedding fibers, typically made from materials like carbon or glass, into a metal matrix. This integration results in a material that exhibits improved strength, stiffness, and resistance to wear and corrosion compared to traditional metals.The applications of fiber-reinforced metal are vast and varied, spanning industries such as aerospace, automotive, and construction. For instance, in the aerospace sector, engineers are constantly seeking ways to reduce the weight of aircraft while maintaining structural integrity. By utilizing fiber-reinforced metal components, manufacturers can produce lighter yet stronger parts, leading to increased fuel efficiency and lower emissions.In the automotive industry, the introduction of fiber-reinforced metal has revolutionized the design of vehicles. Components such as chassis and body panels can now be made from these advanced materials, resulting in cars that are not only lighter but also safer and more efficient. The high strength-to-weight ratio of fiber-reinforced metal allows for better performance and handling, making it an attractive option for high-performance vehicles.Moreover, fiber-reinforced metal offers excellent fatigue resistance, which is crucial for parts that undergo repeated stress cycles. For example, in machinery and heavy equipment, components made from fiber-reinforced metal can withstand the rigors of operation without succumbing to failure. This durability translates to lower maintenance costs and longer service life, providing significant economic benefits to manufacturers and consumers alike.The manufacturing processes for fiber-reinforced metal are also evolving. Techniques such as additive manufacturing and advanced casting methods are being explored to optimize the production of these materials. As technology continues to advance, we can expect to see even more innovative applications and improvements in the performance of fiber-reinforced metal.However, despite the many advantages of fiber-reinforced metal, there are challenges that need to be addressed. The cost of production can be higher than that of conventional metals, which may limit its widespread adoption. Additionally, the recycling of fiber-reinforced metal poses questions, as the separation of fibers from the metal matrix can be complex.In conclusion, fiber-reinforced metal represents a significant leap forward in materials technology, offering numerous benefits across various industries. As research and development continue to progress, it is likely that we will see an increase in the use of fiber-reinforced metal in everyday applications, ultimately leading to more efficient, durable, and sustainable products. The future of materials science looks promising with the integration of fiber-reinforced metal, paving the way for innovations that can transform our world.

近年来，材料科学领域经历了显著的进步，特别是在复合材料的发展方面。其中最有前景的创新之一是使用纤维增强金属，它将金属和纤维的最佳性能结合在一起，创造出一种具有增强性能特征的新型材料。纤维增强金属（fiber-reinforced metal）的概念涉及将纤维（通常由碳或玻璃等材料制成）嵌入金属基体中。这种整合产生了一种材料，其强度、刚度以及耐磨损和腐蚀的能力均优于传统金属。纤维增强金属的应用范围广泛，涉及航空航天、汽车和建筑等行业。例如，在航空航天领域，工程师们不断寻求在保持结构完整性的同时减轻飞机重量的方法。通过利用纤维增强金属组件，制造商可以生产出更轻但更强的部件，从而提高燃油效率并减少排放。在汽车工业中，纤维增强金属的引入彻底改变了车辆的设计。底盘和车身面板等组件现在可以由这些先进材料制成，从而使汽车不仅更轻，而且更安全、更高效。纤维增强金属的高强度重量比使其能够实现更好的性能和操控性，这使其成为高性能车辆的理想选择。此外，纤维增强金属还提供了优异的疲劳抗性，这对于经历重复应力循环的部件至关重要。例如，在机械和重型设备中，由纤维增强金属制成的组件能够承受操作的严酷条件，而不会失效。这种耐用性转化为更低的维护成本和更长的服务寿命，为制造商和消费者带来了显著的经济利益。纤维增强金属的制造工艺也在不断演变。增材制造和先进铸造方法等技术正在被探索，以优化这些材料的生产。随着技术的持续进步，我们可以期待看到更多创新的应用和纤维增强金属性能的提升。然而，尽管纤维增强金属有许多优点，但仍然存在一些需要解决的挑战。生产成本可能高于传统金属，这可能限制其广泛采用。此外，纤维增强金属的回收利用也提出了问题，因为分离纤维与金属基体可能相对复杂。总之，纤维增强金属代表了材料技术的重大飞跃，在各个行业提供了众多好处。随着研究和开发的继续推进，我们很可能会看到纤维增强金属在日常应用中的使用增加，最终导致更高效、更耐用和更可持续的产品。随着纤维增强金属的整合，材料科学的未来看起来充满希望，为能够改变我们世界的创新铺平了道路。