creep resisting

简明释义

抗蠕变的

英英释义

例句

1.The new polymer is known for its creep resisting capabilities, making it ideal for high-stress applications.

这种新型聚合物以其抗蠕变能力而闻名，非常适合高应力应用。

2.The research team published a study on the effects of temperature on creep resisting alloys.

研究小组发表了一项关于温度对抗蠕变合金影响的研究。

3.The engineers designed a new material with creep resisting properties to enhance its durability.

工程师们设计了一种具有抗蠕变特性的材料，以增强其耐用性。

4.Manufacturers are increasingly focusing on creep resisting materials for automotive parts.

制造商越来越关注汽车零部件的抗蠕变材料。

5.In construction, using creep resisting concrete can prevent structural failure over time.

在建筑中，使用抗蠕变混凝土可以防止结构随时间而失效。

作文

In the field of materials science and engineering, the term creep resisting refers to the ability of a material to withstand deformation over time when subjected to constant stress and elevated temperatures. This phenomenon is especially critical in applications where materials are exposed to high levels of stress for extended periods. For instance, in the aerospace and automotive industries, components must maintain their structural integrity under conditions that may lead to creep. The study of creep resisting materials involves understanding the mechanisms that contribute to this behavior, such as grain boundary sliding, dislocation movement, and phase transformations.One of the most common examples of creep resisting materials is superalloys, which are often used in turbine blades for jet engines. These alloys are designed to perform at high temperatures and resist deformation. The development of creep resisting materials has led to significant advancements in engine efficiency and performance. Engineers conduct extensive testing to evaluate the creep properties of these materials, using methods such as tensile tests and creep tests at various temperatures and loads.Another important aspect of creep resisting materials is their application in civil engineering. Structures like bridges, buildings, and dams are subject to constant loads over their lifespan, making it essential to select materials that can resist creep deformation. Concrete, for example, exhibits creep behavior, which can lead to long-term deflection if not properly accounted for in design. Therefore, engineers must consider the creep resisting characteristics of concrete mixtures and incorporate reinforcement techniques to mitigate potential issues.The importance of creep resisting materials extends beyond just mechanical performance; it also impacts safety and reliability. In nuclear power plants, for example, the integrity of reactor components is crucial. Any failure due to creep could have catastrophic consequences. As a result, research into new creep resisting materials continues to be a priority, with scientists exploring innovative compositions and treatments to enhance performance.In conclusion, the concept of creep resisting is vital in various engineering fields. Understanding how different materials behave under stress and temperature over time allows engineers to design safer and more efficient structures and components. As technology advances, the development of new creep resisting materials will undoubtedly play a key role in the future of engineering, ensuring that our infrastructure and machinery can withstand the test of time.

在材料科学和工程领域，术语抗蠕变指的是材料在持续应力和高温条件下抵御变形的能力。这种现象在材料长时间承受高水平应力的应用中尤为重要。例如，在航空航天和汽车工业中，组件必须在可能导致蠕变的条件下保持其结构完整性。对抗蠕变材料的研究涉及理解促成这种行为的机制，如晶界滑移、位错运动和相变。最常见的抗蠕变材料之一是超合金，这些合金通常用于喷气发动机的涡轮叶片。这些合金旨在高温下工作并抵抗变形。抗蠕变材料的发展已导致发动机效率和性能的显著提升。工程师进行广泛的测试以评估这些材料的蠕变特性，使用拉伸试验和不同温度和负荷下的蠕变试验等方法。抗蠕变材料的另一个重要方面是它们在土木工程中的应用。桥梁、建筑物和水坝等结构在其生命周期中受到持续负载，因此选择能够抵抗蠕变变形的材料至关重要。例如，混凝土表现出蠕变行为，如果在设计中没有正确考虑，可能会导致长期挠曲。因此，工程师必须考虑混凝土混合物的抗蠕变特性，并采用加固技术来减轻潜在问题。抗蠕变材料的重要性不仅仅影响机械性能；它还影响安全性和可靠性。在核电站中，反应堆组件的完整性至关重要。由于蠕变导致的任何故障都可能具有灾难性后果。因此，对新型抗蠕变材料的研究仍然是优先事项，科学家们正在探索创新的成分和处理方法，以增强性能。总之，抗蠕变的概念在各个工程领域至关重要。理解不同材料在应力和温度下随时间的表现使工程师能够设计出更安全、更高效的结构和组件。随着技术的进步，新型抗蠕变材料的发展无疑将在未来的工程中发挥关键作用，确保我们的基础设施和机械能够经受住时间的考验。