high temperature strength

简明释义

高温强度

英英释义

例句

1.Developing a composite material with improved high temperature strength 高温强度 could lead to more efficient electric vehicles.

开发一种具有改进的高温强度 高温强度的复合材料可能会导致更高效的电动汽车。

2.The new alloy exhibits excellent high temperature strength 高温强度, making it suitable for aerospace applications.

这种新合金表现出优异的高温强度 高温强度，使其适用于航空航天应用。

3.In the manufacturing of turbine blades, materials with high temperature strength 高温强度 are essential to withstand extreme conditions.

在涡轮叶片的制造中，具有高温强度 高温强度的材料对于承受极端条件至关重要。

4.The research focused on enhancing the high temperature strength 高温强度 of steel for better performance in construction.

研究集中在增强钢材的高温强度 高温强度以提高建筑性能。

5.Ceramics used in engines must have a high high temperature strength 高温强度 to prevent failure during operation.

用于发动机的陶瓷必须具有高高温强度 高温强度以防止在操作过程中失效。

作文

High temperature strength is a critical property of materials used in various industrial applications, especially in the fields of aerospace, automotive, and energy generation. When materials are exposed to elevated temperatures, their mechanical properties can change significantly. Therefore, understanding and optimizing high temperature strength (高温强度) is essential for ensuring the reliability and performance of components under extreme conditions.In aerospace engineering, for instance, aircraft engines operate at very high temperatures due to the combustion of fuel. Materials used in these engines must not only withstand high temperatures but also maintain their structural integrity over time. This is where high temperature strength (高温强度) comes into play. Superalloys, which are often used in turbine blades, are designed to retain their strength and resist deformation even when subjected to intense heat.Similarly, in the automotive industry, the development of high-performance engines requires materials that can endure high thermal stresses. Components such as exhaust valves and pistons are exposed to extreme temperatures and pressures during operation. Engineers must select materials with excellent high temperature strength (高温强度) to prevent failure and ensure longevity. The ability to withstand thermal fatigue is crucial for maintaining engine efficiency and performance.In the energy sector, particularly in power plants, materials must endure high temperatures in processes such as steam generation. Boilers and turbines operate at elevated temperatures, necessitating materials that exhibit superior high temperature strength (高温强度). The choice of material can significantly impact the efficiency and safety of the energy generation process. For example, stainless steels and nickel-based alloys are commonly used due to their ability to maintain strength and resist oxidation at high temperatures.Research and development efforts continue to focus on improving high temperature strength (高温强度) through advanced material science techniques. Innovations such as composite materials and coatings can enhance the performance of traditional metals and alloys. By combining different materials, engineers can create composites that offer both lightweight properties and exceptional thermal resistance. This is particularly important in industries where weight reduction is critical, such as aerospace and automotive.Furthermore, the characterization of high temperature strength (高温强度) involves rigorous testing methods. Techniques such as creep testing, where materials are subjected to constant stress at elevated temperatures for extended periods, help determine how materials behave under real-world conditions. Understanding the limits of high temperature strength (高温强度) allows engineers to design safer and more efficient systems.In conclusion, high temperature strength (高温强度) is an essential property for materials used in high-temperature applications across various industries. Its importance cannot be overstated, as it directly impacts the performance, safety, and reliability of critical components. As technology advances, the pursuit of materials with superior high temperature strength (高温强度) will continue to drive innovation and progress in engineering and manufacturing. By investing in research and development, we can enhance our understanding of material behavior at high temperatures and develop solutions that meet the demands of modern applications.

高温强度是各种工业应用中材料的一个关键特性，尤其是在航空航天、汽车和能源发电领域。当材料暴露在高温环境中时，其机械性能可能会发生显著变化。因此，理解和优化高温强度（high temperature strength）对于确保在极端条件下组件的可靠性和性能至关重要。例如，在航空航天工程中，飞机发动机由于燃料的燃烧而在非常高的温度下运行。用于这些发动机的材料不仅必须能够承受高温，还必须在长时间内保持其结构完整性。这就是高温强度（high temperature strength）发挥作用的地方。超合金常用于涡轮叶片，设计目的是在受到强烈热量时仍能保持强度并抵抗变形。同样，在汽车工业中，高性能发动机的开发需要能够承受高热应力的材料。排气阀和活塞等组件在运行过程中暴露于极端温度和压力下。工程师必须选择具有优异高温强度（high temperature strength）的材料，以防止故障并确保耐久性。承受热疲劳的能力对于维持发动机效率和性能至关重要。在能源部门，特别是在发电厂，材料必须在蒸汽生成等过程中承受高温。锅炉和涡轮在高温下运行，这需要表现出优越高温强度（high temperature strength）的材料。材料的选择可以显著影响能源生成过程的效率和安全性。例如，不锈钢和镍基合金因其在高温下保持强度和抗氧化的能力而被广泛使用。研究与开发工作继续专注于通过先进的材料科学技术来改善高温强度（high temperature strength）。复合材料和涂层等创新可以增强传统金属和合金的性能。通过结合不同的材料，工程师可以创造出既轻便又具有卓越热阻的复合材料。这在航空航天和汽车等对重量减轻要求严格的行业尤为重要。此外，高温强度（high temperature strength）的表征涉及严格的测试方法。像蠕变测试这样的技术，通过在高温下对材料施加恒定的应力并持续较长时间，可以帮助确定材料在实际条件下的表现。了解高温强度（high temperature strength）的极限使工程师能够设计更安全、更高效的系统。总之，高温强度（high temperature strength）是高温应用中材料的重要特性，涉及多个行业。其重要性不容小觑，因为它直接影响到关键组件的性能、安全性和可靠性。随着技术的进步，对具有优越高温强度（high temperature strength）的材料的追求将继续推动工程和制造业的创新与进步。通过投资于研究与开发，我们可以增强对高温下材料行为的理解，并开发满足现代应用需求的解决方案。