heat erosion

简明释义

热侵蚀

英英释义

例句

1.To prevent heat erosion, engineers applied a special coating to the furnace walls.

为了防止热侵蚀，工程师在炉壁上涂覆了一种特殊涂层。

2.The researchers studied the effects of heat erosion on various materials used in aerospace applications.

研究人员研究了在航空航天应用中使用的各种材料上热侵蚀的影响。

3.In industrial settings, heat erosion can cause equipment failures if not monitored regularly.

在工业环境中，如果不定期监测，热侵蚀可能导致设备故障。

4.The constant exposure to high temperatures led to significant heat erosion in the metal components of the engine.

持续暴露在高温下导致引擎金属部件出现显著的热侵蚀。

5.The report highlighted the risks associated with heat erosion in power generation facilities.

报告强调了发电设施中与热侵蚀相关的风险。

作文

Heat erosion is a phenomenon that occurs when materials are subjected to high temperatures, leading to their gradual degradation over time. This process is particularly significant in various engineering fields, especially in aerospace and mechanical engineering, where components are often exposed to extreme heat during operation. Understanding heat erosion (热侵蚀) is crucial for designing durable materials that can withstand such conditions without failing. One of the most common examples of heat erosion (热侵蚀) can be observed in jet engines. These engines operate at incredibly high temperatures, which can exceed 1,500 degrees Celsius. The materials used in jet engine components must not only be strong but also resistant to thermal degradation. Engineers often use superalloys, which are specially designed to retain their strength and stability at elevated temperatures. However, even these advanced materials can suffer from heat erosion (热侵蚀) over time, necessitating regular maintenance and replacement to ensure safety and efficiency. Another area where heat erosion (热侵蚀) is a concern is in nuclear reactors. The reactor core generates immense heat, which can lead to the erosion of structural materials if not properly managed. Engineers must carefully monitor the temperature levels and use materials that can resist heat erosion (热侵蚀) to prevent catastrophic failures. In this context, the study of heat erosion (热侵蚀) is not only about material science but also involves thermodynamics and fluid mechanics to ensure that cooling systems are effective and reliable. Moreover, heat erosion (热侵蚀) is not limited to industrial applications; it can also be observed in everyday life. For instance, cooking utensils made from metal can experience heat erosion (热侵蚀) when exposed to high temperatures repeatedly. Over time, the surface of these utensils may become pitted or discolored due to the effects of heat. This highlights the importance of understanding heat erosion (热侵蚀) in consumer products as well, ensuring that they are safe and effective for daily use. To mitigate the effects of heat erosion (热侵蚀), researchers are continually developing new materials and coatings that can better withstand high temperatures. For example, ceramic coatings are being explored for their ability to provide thermal protection while maintaining structural integrity. These innovations are essential for advancing technology and improving the longevity of critical components in various industries. In conclusion, heat erosion (热侵蚀) is a vital concept in both engineering and everyday life. Its implications stretch across multiple disciplines, from aerospace to domestic cooking. By gaining a deeper understanding of heat erosion (热侵蚀), we can develop better materials and practices that enhance safety, efficiency, and durability in our technological advancements. As we continue to push the boundaries of what is possible, recognizing and addressing the challenges posed by heat erosion (热侵蚀) will be key to our success in future innovations.

热侵蚀是指材料在高温条件下逐渐退化的现象。这个过程在各个工程领域中尤为重要，尤其是在航空航天和机械工程中，因为组件在操作过程中经常会暴露于极端高温下。理解热侵蚀对设计能够承受这种条件而不失效的耐用材料至关重要。热侵蚀的一个常见例子可以在喷气发动机中观察到。这些发动机在工作时的温度可超过1500摄氏度。用于喷气发动机组件的材料不仅必须强韧，还要抵抗热降解。工程师们通常使用超合金，这些合金专门设计用于在高温下保持其强度和稳定性。然而，即使是这些先进材料也可能随着时间的推移受到热侵蚀的影响，因此需要定期维护和更换，以确保安全和效率。另一个热侵蚀成为关注点的领域是核反应堆。反应堆核心产生巨大的热量，如果不加以妥善管理，会导致结构材料的侵蚀。工程师必须仔细监测温度水平，并使用能够抵抗热侵蚀的材料，以防止灾难性故障。在这个背景下，研究热侵蚀不仅涉及材料科学，还包括热力学和流体力学，以确保冷却系统的有效性和可靠性。此外，热侵蚀并不限于工业应用；在日常生活中也可以观察到。例如，金属制成的烹饪器具在反复暴露于高温下时可能会经历热侵蚀。随着时间的推移，这些器具的表面可能因热的影响而变得凹凸不平或变色。这突显了理解热侵蚀在消费产品中的重要性，确保它们在日常使用中安全有效。为了减轻热侵蚀的影响，研究人员不断开发新的材料和涂层，以更好地承受高温。例如，陶瓷涂层因其能够提供热保护而被探索，同时保持结构完整性。这些创新对于推动技术进步和提高各行业关键组件的耐用性至关重要。总之，热侵蚀是工程和日常生活中一个重要的概念。它的影响跨越多个学科，从航空航天到家庭烹饪。通过深入理解热侵蚀，我们可以开发出更好的材料和实践，增强我们技术进步中的安全性、效率和耐用性。随着我们继续突破可能的界限，认识并解决热侵蚀带来的挑战将是我们未来创新成功的关键。