thermal plasticity

简明释义

热塑性

英英释义

例句

1.Engineers often consider thermal plasticity 热塑性 when designing components that will be exposed to fluctuating heat levels.

工程师在设计将暴露于波动热量的组件时，通常会考虑热塑性。

2.The thermal plasticity 热塑性 of certain ceramics makes them ideal for use in high-temperature applications.

某些陶瓷的热塑性使它们非常适合用于高温应用。

3.The thermal plasticity 热塑性 of certain metals allows them to be reshaped without losing their structural integrity.

某些金属的热塑性使它们可以在不失去结构完整性的情况下被重新塑形。

4.The study of thermal plasticity 热塑性 in polymers is crucial for developing materials that can withstand high temperatures.

聚合物中热塑性的研究对于开发能够承受高温的材料至关重要。

5.Understanding thermal plasticity 热塑性 helps scientists create better insulation materials for buildings.

理解热塑性有助于科学家为建筑创造更好的绝缘材料。

作文

Thermal plasticity is a fascinating concept that plays a crucial role in the field of materials science and engineering. It refers to the ability of a material to undergo significant deformation when subjected to heat, allowing it to be reshaped without breaking. This property is particularly important for polymers, metals, and ceramics, which can exhibit varying degrees of thermal plasticity (热塑性) depending on their composition and structure.Understanding thermal plasticity (热塑性) is essential for engineers and designers who work with materials that need to withstand high temperatures or undergo processing at elevated temperatures. For instance, in the manufacturing of plastic products, heat is often applied to make the material malleable. This allows for intricate shapes to be formed, which would otherwise be impossible in their rigid state. The key to successful manufacturing lies in knowing how much heat to apply and for how long, as this influences the final properties of the product.Moreover, thermal plasticity (热塑性) is not only relevant in manufacturing processes but also in everyday applications. For example, thermoplastics such as polyethylene and polypropylene are widely used in packaging, containers, and automotive parts. These materials can be heated and reshaped multiple times without losing their integrity, making them highly versatile and cost-effective.Another critical aspect of thermal plasticity (热塑性) is its impact on the performance of materials under thermal stress. When materials are exposed to varying temperatures, they can expand or contract, leading to potential failures if they cannot accommodate these changes. Engineers must consider thermal plasticity (热塑性) when designing structures and components that will experience temperature fluctuations during their service life. For instance, in aerospace engineering, components must be able to endure extreme temperatures while maintaining their structural integrity and performance.In recent years, research has focused on enhancing the thermal plasticity (热塑性) of materials to improve their performance. This includes developing new alloys and composites that can better withstand heat without compromising their mechanical properties. Innovations in material science have led to the creation of heat-resistant polymers and metals that are more durable and reliable in high-temperature applications.Furthermore, understanding the mechanisms behind thermal plasticity (热塑性) can lead to more sustainable practices in manufacturing. By optimizing the heating and cooling processes, companies can reduce energy consumption and minimize waste. This not only benefits the environment but also lowers production costs, making it an attractive option for manufacturers.In conclusion, thermal plasticity (热塑性) is a vital property that influences how materials behave under heat. Its significance spans across various industries, from manufacturing to aerospace, and understanding it is crucial for innovation and sustainability. As research continues to advance, the potential for new materials with enhanced thermal plasticity (热塑性) will likely lead to exciting developments that can revolutionize the way we use and interact with materials in our daily lives.

热塑性是一个迷人的概念，在材料科学和工程领域中发挥着至关重要的作用。它指的是材料在受热时能够经历显著变形的能力，使其可以在不破裂的情况下被重新塑造。这种特性对于聚合物、金属和陶瓷尤为重要，这些材料根据其成分和结构可以表现出不同程度的热塑性。理解热塑性对从事需要承受高温或在高温下进行加工的材料的工程师和设计师来说至关重要。例如，在塑料产品的制造过程中，通常会施加热量使材料变得可塑。这使得形成复杂形状成为可能，而这些形状在其刚性状态下是不可能实现的。成功制造的关键在于知道施加多少热量以及持续多长时间，因为这会影响最终产品的性质。此外，热塑性不仅与制造过程相关，还与日常应用密切相关。例如，聚乙烯和聚丙烯等热塑性塑料广泛用于包装、容器和汽车零部件。这些材料可以在不失去完整性的情况下反复加热和重新塑造，使其具有高度的多功能性和成本效益。热塑性的另一个关键方面是其对材料在热应力下性能的影响。当材料暴露于不同温度时，它们可能会膨胀或收缩，如果无法适应这些变化，则可能导致潜在的故障。工程师在设计在服务生命周期中会经历温度波动的结构和组件时，必须考虑热塑性。近年来，研究集中于增强材料的热塑性，以改善其性能。这包括开发新的合金和复合材料，以更好地承受热量而不妥协其机械性能。材料科学的创新导致了耐热聚合物和金属的产生，这些材料在高温应用中更加耐用和可靠。此外，理解热塑性背后的机制可以促进制造中的可持续实践。通过优化加热和冷却过程，公司可以减少能源消耗并最小化废物。这不仅有利于环境，还有助于降低生产成本，使其成为制造商的有吸引力的选择。总之，热塑性是影响材料在热作用下行为的重要特性。它的重要性跨越多个行业，从制造到航空航天，理解它对于创新和可持续性至关重要。随着研究的不断推进，具有增强热塑性的材料的新潜力可能会引领激动人心的发展，彻底改变我们在日常生活中使用和与材料互动的方式。