heat resisting material
简明释义
耐热材料
英英释义
A type of material that can withstand high temperatures without undergoing significant degradation or deformation. | 一种能够承受高温而不发生显著降解或变形的材料。 |
例句
1.In cooking, using a pan made from heat resisting material 耐热材料 ensures that it can handle high temperatures without warping.
在烹饪中,使用由耐热材料 heat resisting material制成的平底锅可以确保其在高温下不会变形。
2.Ceramic tiles are often used as heat resisting material 耐热材料 in high-temperature applications like jet engines.
陶瓷瓷砖常被用作高温应用(如喷气发动机)中的耐热材料 heat resisting material。
3.The construction of furnaces requires heat resisting material 耐热材料 to prevent damage from the intense heat generated inside.
炉子的建造需要耐热材料 heat resisting material以防止内部产生的强烈热量造成损坏。
4.When designing a rocket, engineers must choose the right heat resisting material 耐热材料 to protect sensitive components from heat.
在设计火箭时,工程师必须选择合适的耐热材料 heat resisting material来保护敏感组件免受热量影响。
5.The aerospace industry relies heavily on heat resisting material 耐热材料 to withstand the extreme temperatures during re-entry into the Earth's atmosphere.
航空航天工业在进入地球大气层时,严重依赖于耐热材料 heat resisting material以承受极端温度。
作文
In today's rapidly advancing technological world, the importance of heat resisting material (耐热材料) cannot be overstated. These materials play a crucial role in various industries, including aerospace, automotive, and construction. As the demand for more efficient and durable products increases, the significance of heat resisting material (耐热材料) grows even more. One of the primary applications of heat resisting material (耐热材料) is in the aerospace industry. Aircraft are subjected to extreme temperatures during flight, especially during takeoff and re-entry into the atmosphere. Engineers rely on heat resisting material (耐热材料) to ensure that critical components, such as engine parts and thermal protection systems, can withstand these harsh conditions without failing. For instance, materials like ceramic matrix composites and superalloys are commonly used due to their excellent thermal stability and strength at elevated temperatures. Similarly, in the automotive sector, heat resisting material (耐热材料) is essential for the performance and safety of vehicles. High-performance engines generate significant heat, and components such as exhaust systems, turbochargers, and brake systems must be made from materials that can endure high temperatures without degrading. The use of heat resisting material (耐热材料) in these applications not only enhances the longevity of the components but also improves the overall efficiency of the vehicle. Moreover, the construction industry also benefits from the properties of heat resisting material (耐热材料). Buildings and structures require materials that can resist fire and high temperatures to ensure the safety of occupants. Fire-resistant insulation, coatings, and structural elements are critical in preventing the spread of flames and protecting the integrity of buildings during a fire. By incorporating heat resisting material (耐热材料) into building designs, architects and engineers can create safer environments. The development of new heat resisting material (耐热材料) continues to evolve as researchers explore innovative solutions to meet the demands of modern technology. Advances in nanotechnology and materials science have led to the creation of lighter, stronger, and more efficient heat-resistant materials. These innovations not only improve performance but also contribute to sustainability by reducing energy consumption and waste. In conclusion, heat resisting material (耐热材料) is an indispensable part of many industries, providing safety, efficiency, and durability. As technology progresses, the demand for advanced heat resisting material (耐热材料) will only increase, making it a vital area of research and development. Understanding the properties and applications of heat resisting material (耐热材料) is essential for anyone looking to work in fields related to engineering, manufacturing, or construction. The future of technology relies heavily on these materials, and their continued innovation will shape the advancements of tomorrow.
在当今快速发展的技术世界中,耐热材料的重要性不容小觑。这些材料在航空航天、汽车和建筑等各个行业中发挥着至关重要的作用。随着对更高效、更耐用产品的需求增加,耐热材料的重要性也愈加凸显。耐热材料的主要应用之一是在航空航天行业。飞机在飞行过程中,特别是在起飞和重新进入大气层时,会遭受极端温度的影响。工程师依赖于耐热材料来确保关键组件,如发动机部件和热保护系统,能够在这些恶劣条件下承受而不失效。例如,陶瓷基复合材料和超级合金因其优异的热稳定性和高温下的强度而被广泛使用。同样,在汽车行业,耐热材料对于车辆的性能和安全至关重要。高性能发动机会产生大量热量,排气系统、涡轮增压器和制动系统等组件必须由能够承受高温而不会降解的材料制成。在这些应用中使用耐热材料不仅增强了组件的使用寿命,还提高了整车的效率。此外,建筑行业也从耐热材料的特性中受益。建筑物和结构需要能够抵抗火灾和高温的材料,以确保居住者的安全。防火绝缘材料、涂层和结构元素在防止火焰蔓延和保护建筑物在火灾期间的完整性方面至关重要。通过将耐热材料纳入建筑设计,建筑师和工程师可以创造更安全的环境。新型耐热材料的开发仍在不断演进,研究人员正在探索创新解决方案以满足现代技术的需求。纳米技术和材料科学的进展促成了更轻、更强、更高效的耐热材料的诞生。这些创新不仅提高了性能,还通过减少能源消耗和废物贡献了可持续性。总之,耐热材料是许多行业不可或缺的一部分,提供安全性、效率和耐用性。随着技术的进步,对先进耐热材料的需求只会增加,使其成为一个至关重要的研究和开发领域。了解耐热材料的特性和应用对于任何希望在与工程、制造或建筑相关领域工作的人来说都是必不可少的。技术的未来在很大程度上依赖于这些材料,而它们的持续创新将塑造明天的进步。
相关单词
