metallic matrix

简明释义

金属基体

英英释义

例句

1.Researchers are exploring the use of a metallic matrix 金属基体 to improve the thermal conductivity of ceramics.

研究人员正在探索使用金属基体 metallic matrix来提高陶瓷的热导率。

2.The metallic matrix 金属基体 in this alloy provides excellent wear resistance for industrial tools.

这种合金中的金属基体 metallic matrix为工业工具提供了优异的耐磨性。

3.In aerospace applications, a lightweight metallic matrix 金属基体 can significantly reduce the overall weight of components.

在航空航天应用中，轻质的金属基体 metallic matrix可以显著减少组件的整体重量。

4.Innovative methods are being developed to fabricate metallic matrix 金属基体 composites with improved mechanical properties.

正在开发创新方法来制造具有改进机械性能的金属基体 metallic matrix复合材料。

5.The new composite material features a strong metallic matrix 金属基体 that enhances its durability.

这种新型复合材料具有强大的金属基体 metallic matrix，增强了其耐用性。

作文

The development of advanced materials has significantly transformed various industries, particularly in aerospace and automotive engineering. One of the most promising innovations in this field is the use of a metallic matrix (金属基体) composite. This type of composite material combines the properties of metals with other reinforcing materials, leading to enhanced performance characteristics that are essential for high-stress applications.A metallic matrix (金属基体) composite typically consists of a metal matrix, which serves as the primary structural component, and a secondary phase that can be either a ceramic or another metal. The incorporation of these additional materials allows for improved mechanical properties, such as increased strength, stiffness, and wear resistance. For instance, aluminum reinforced with ceramic particles can exhibit remarkable improvements in hardness and thermal stability, making it an ideal choice for components subjected to extreme conditions.One of the key advantages of using a metallic matrix (金属基体) composite is its ability to withstand high temperatures without losing structural integrity. This property is particularly beneficial in aerospace applications, where materials must endure significant thermal stresses during flight. By utilizing a metallic matrix (金属基体), engineers can design lighter and more efficient aircraft that consume less fuel while maintaining safety and performance standards.In the automotive sector, the demand for lightweight materials has led to the increased adoption of metallic matrix (金属基体) composites. These materials contribute to weight reduction in vehicles, which directly translates to improved fuel efficiency and reduced emissions. Additionally, the enhanced wear resistance of metallic matrix (金属基体) composites makes them suitable for high-performance engine components, such as pistons and cylinder heads, that require durability under extreme conditions.Another area where metallic matrix (金属基体) composites are making an impact is in the field of sports equipment. Manufacturers are increasingly incorporating these advanced materials into products like bicycles, golf clubs, and tennis rackets. The combination of lightweight and strong properties allows athletes to achieve better performance while reducing the risk of injury due to equipment failure.Despite the numerous benefits of metallic matrix (金属基体) composites, there are challenges associated with their production and processing. The manufacturing methods for these materials often require specialized techniques, such as powder metallurgy or casting, which can increase production costs. Additionally, ensuring a uniform distribution of the reinforcing phase within the metallic matrix (金属基体) is crucial for achieving optimal performance, and this can be difficult to control during fabrication.In conclusion, the use of metallic matrix (金属基体) composites represents a significant advancement in material science, offering numerous advantages across various industries. Their unique properties make them ideal for applications requiring high strength, low weight, and excellent thermal stability. As research and technology continue to evolve, we can expect to see even more innovative uses of metallic matrix (金属基体) composites, paving the way for a new era of advanced materials that will shape the future of engineering and manufacturing.

先进材料的发展显著改变了各个行业，特别是在航空航天和汽车工程领域。在这个领域中，最有前途的创新之一是使用金属基体复合材料。这种复合材料结合了金属与其他增强材料的特性，从而提高了在高应力应用中所需的性能特征。金属基体复合材料通常由金属基体组成，作为主要结构成分，以及可以是陶瓷或另一种金属的次相。加入这些附加材料使得机械性能得到改善，例如强度、刚度和耐磨性的增加。例如，添加陶瓷颗粒的铝可以表现出硬度和热稳定性的显著提升，使其成为在极端条件下使用的理想选择。使用金属基体复合材料的一个关键优势是其能够承受高温而不失去结构完整性。这一特性在航空航天应用中尤为重要，因为材料必须在飞行过程中承受显著的热应力。通过利用金属基体，工程师可以设计出更轻、更高效的飞机，这些飞机在保持安全和性能标准的同时，消耗更少的燃料。在汽车行业，对轻质材料的需求导致了金属基体复合材料的广泛采用。这些材料有助于减少车辆重量，直接转化为改善的燃油效率和减少的排放。此外，金属基体复合材料的耐磨性增强使其适合用于高性能发动机部件，如活塞和缸头，这些部件需要在极端条件下保持耐用性。金属基体复合材料影响的另一个领域是在体育设备方面。制造商越来越多地将这些先进材料融入到自行车、高尔夫球杆和网球拍等产品中。轻便且强大的特性使运动员能够在减少设备故障风险的同时实现更好的表现。尽管金属基体复合材料具有众多优点，但其生产和加工也面临挑战。这些材料的制造方法通常需要特殊技术，例如粉末冶金或铸造，这可能会增加生产成本。此外，确保在金属基体中均匀分布增强相对于实现最佳性能至关重要，而这在制造过程中可能很难控制。总之，使用金属基体复合材料代表了材料科学的重要进步，为各个行业提供了众多优势。它们独特的特性使其在需要高强度、低重量和优良热稳定性的应用中理想。随着研究和技术的不断发展，我们可以期待看到更多创新的金属基体复合材料的应用，为塑造工程和制造的未来铺平道路。