yield temperature

简明释义

屈服温度

英英释义

例句

1.The yield temperature 屈服温度 of the polymer affects its processing and final properties.

聚合物的yield temperature屈服温度影响其加工和最终性能。

2.The material's yield temperature 屈服温度 is crucial for determining its suitability in high-temperature applications.

材料的yield temperature屈服温度对于确定其在高温应用中的适用性至关重要。

3.Engineers must consider the yield temperature 屈服温度 when designing components that will operate in extreme conditions.

工程师在设计将在极端条件下运行的部件时，必须考虑yield temperature屈服温度。

4.During testing, we found that the yield temperature 屈服温度 of the alloy was significantly higher than expected.

在测试过程中，我们发现合金的yield temperature屈服温度明显高于预期。

5.To ensure safety, the yield temperature 屈服温度 must be well understood in the context of thermal cycling.

为了确保安全，必须在热循环的背景下充分理解yield temperature屈服温度。

作文

The concept of yield temperature is essential in various scientific fields, particularly in material science and engineering. It refers to the temperature at which a material begins to deform plastically. Understanding this temperature is crucial for engineers and scientists when designing materials that will be subjected to heat and stress. For instance, metals have specific yield temperatures that determine their usability in high-temperature environments. When a metal reaches its yield temperature, it can no longer return to its original shape once the stress is removed, leading to permanent deformation. This property is vital in applications such as construction, automotive design, and aerospace engineering.In the context of manufacturing, knowing the yield temperature of a material allows for better decision-making when selecting materials for specific applications. For example, if a manufacturer is producing components that will experience high temperatures, they must choose materials with a high yield temperature to ensure durability and performance. This knowledge helps prevent failures that could arise from using materials that cannot withstand the operational conditions.Moreover, the yield temperature can vary significantly among different materials. For instance, polymers typically have lower yield temperatures compared to metals. This difference necessitates careful consideration when designing products that incorporate multiple materials. Engineers must account for the lowest yield temperature in a composite material to avoid compromising the integrity of the entire structure.In addition to its importance in material selection, the yield temperature also plays a role in the processing of materials. During processes like welding or casting, understanding the yield temperature helps in determining the appropriate temperatures to use. If the temperature exceeds the yield temperature, the material may become too malleable, leading to defects in the final product. Therefore, precise control of temperature during manufacturing is crucial to ensure quality and performance.Furthermore, the yield temperature is not a fixed value; it can change based on various factors such as alloy composition, impurities, and the presence of stress. For instance, certain treatments can enhance a material's yield temperature, making it more suitable for demanding applications. This adaptability makes it necessary for researchers to continuously study and understand how different factors influence the yield temperature of materials.In conclusion, the yield temperature is a fundamental property of materials that has significant implications in engineering and manufacturing. It determines how materials behave under stress and temperature, guiding the selection and processing of materials for various applications. As industries continue to evolve and demand higher performance from materials, the understanding of yield temperature will remain a critical area of study. By mastering this concept, engineers and scientists can innovate and create safer, more reliable products that meet the challenges of modern technology.

“屈服温度”的概念在各个科学领域中至关重要，特别是在材料科学和工程学中。它指的是材料开始发生塑性变形的温度。理解这个温度对于工程师和科学家在设计将承受热量和应力的材料时至关重要。例如，金属具有特定的“屈服温度”，决定了它们在高温环境中的可用性。当金属达到其“屈服温度”时，一旦去除应力，它就无法恢复到原来的形状，从而导致永久变形。这一特性在建筑、汽车设计和航空航天工程等应用中至关重要。在制造的背景下，了解材料的“屈服温度”可以在选择特定应用材料时做出更好的决策。例如，如果制造商正在生产会经历高温的组件，他们必须选择具有高“屈服温度”的材料，以确保耐用性和性能。这种知识有助于防止因使用无法承受操作条件的材料而导致的故障。此外，不同材料之间的“屈服温度”可能会显著不同。例如，聚合物的“屈服温度”通常低于金属。这种差异使得在设计包含多种材料的产品时必须谨慎考虑。工程师必须考虑复合材料中最低的“屈服温度”，以避免妨碍整个结构的完整性。除了在材料选择中的重要性外，“屈服温度”在材料加工过程中也发挥着作用。在焊接或铸造等过程中，了解“屈服温度”有助于确定使用的适当温度。如果温度超过“屈服温度”，材料可能变得过于柔软，从而导致最终产品的缺陷。因此，在制造过程中精确控制温度对于确保质量和性能至关重要。此外，“屈服温度”并不是一个固定值；它可以根据合金成分、杂质和应力的存在等各种因素而变化。例如，某些处理可以提高材料的“屈服温度”，使其更适合于苛刻的应用。这种适应性使得研究人员必须不断研究和理解不同因素如何影响材料的“屈服温度”。总之，“屈服温度”是材料的一个基本特性，对工程和制造具有重要影响。它决定了材料在应力和温度下的行为，指导着各种应用中材料的选择和加工。随着工业的不断发展，对材料性能的要求越来越高，对“屈服温度”的理解将始终是一个关键的研究领域。通过掌握这一概念，工程师和科学家能够创新并创造出满足现代技术挑战的更安全、更可靠的产品。