resistance material

简明释义

电阻材料

英英释义

Material that opposes the flow of electric current, heat, or other forms of energy, often used in electrical and thermal applications.

阻碍电流、热量或其他形式能量流动的材料,通常用于电气和热应用中。

A substance designed to withstand stress, strain, or adverse conditions without failing.

一种旨在承受压力、应变或不利条件而不失效的物质。

例句

1.We need to test the durability of the resistance material under extreme conditions.

我们需要测试在极端条件下阻力材料的耐用性。

2.In electronics, the choice of resistance material can significantly affect performance.

在电子学中,阻力材料的选择会显著影响性能。

3.The engineers selected the best resistance material for the high-temperature application.

工程师为高温应用选择了最佳的阻力材料

4.The resistance material used in this circuit is designed to minimize energy loss.

这个电路中使用的阻力材料旨在最小化能量损失。

5.This resistance material is ideal for use in thermal insulation.

这种阻力材料非常适合用于热绝缘。

作文

In the field of engineering and materials science, the term resistance material refers to substances that are designed to withstand various forms of stress, heat, and electrical currents. These materials play a crucial role in ensuring the safety and efficiency of numerous applications, ranging from electronics to construction. Understanding the properties and applications of resistance material is essential for both engineers and manufacturers, as it directly impacts the performance and longevity of products.One of the most common types of resistance material is used in electrical components, where materials must resist the flow of electricity to prevent overheating and potential failures. For instance, resistors, which are fundamental components in electronic circuits, utilize materials with specific resistance values to control the current flow. The choice of resistance material in these components can significantly affect the overall functionality of electronic devices. High-quality resistors made from durable resistance material ensure that devices operate efficiently without risking damage due to excessive heat.In addition to electronics, resistance material is also vital in construction and manufacturing processes. For example, building materials such as steel and concrete must possess high resistance to environmental factors like corrosion, temperature fluctuations, and mechanical stress. Engineers often select specific alloys or composite materials that provide enhanced durability and resistance to wear and tear. This careful selection process ensures that structures can withstand the test of time and remain safe for use.Moreover, the development of new resistance material is an ongoing area of research. Scientists are continually exploring innovative materials that can offer improved resistance characteristics while being lightweight and cost-effective. For instance, the emergence of nanomaterials has opened new avenues for creating advanced resistance material with exceptional strength-to-weight ratios. These advancements not only enhance the performance of existing products but also pave the way for new technologies and applications.Another critical aspect of resistance material is its role in thermal management. In many industrial processes, materials that can resist high temperatures are necessary to maintain operational efficiency. For example, in aerospace engineering, components exposed to extreme heat must be made from specialized resistance material that can endure high thermal loads without degrading. This requirement highlights the importance of selecting the right materials to ensure safety and performance in high-stakes environments.In conclusion, resistance material encompasses a wide range of substances that are essential for modern technology and infrastructure. From electronics to construction and beyond, the properties of these materials dictate their suitability for various applications. As research continues to advance, the future of resistance material holds exciting possibilities for enhanced performance and innovation. Understanding these materials is crucial for anyone involved in design, engineering, or manufacturing, as they form the backbone of many critical systems and structures. By investing in research and development of new resistance material, we can look forward to a future filled with safer, more efficient technologies that improve our quality of life.

在工程和材料科学领域,术语resistance material指的是旨在承受各种形式的压力、热量和电流的物质。这些材料在确保众多应用的安全性和效率方面发挥着至关重要的作用,从电子产品到建筑。理解resistance material的特性和应用对工程师和制造商来说至关重要,因为这直接影响到产品的性能和使用寿命。最常见的resistance material之一是在电子元件中使用的,其中材料必须抵抗电流的流动,以防止过热和潜在故障。例如,电阻器是电子电路中的基本组件,利用具有特定电阻值的材料来控制电流流动。在这些组件中选择resistance material可以显著影响电子设备的整体功能。由耐用resistance material制成的高质量电阻器确保设备高效运行,而不会因过热而面临损坏的风险。除了电子产品,resistance material在建筑和制造过程中也至关重要。例如,建筑材料如钢铁和混凝土必须具备对环境因素(如腐蚀、温度波动和机械应力)的高抵抗力。工程师通常会选择特定的合金或复合材料,以提供增强的耐久性和抗磨损能力。这种仔细选择的过程确保结构能够经受住时间的考验,并保持安全可用。此外,新resistance material的开发也是一个持续的研究领域。科学家们不断探索创新材料,这些材料能够在轻巧且经济有效的情况下提供改善的抗性特征。例如,纳米材料的出现为创造具有卓越强度与重量比的先进resistance material开辟了新途径。这些进展不仅增强了现有产品的性能,也为新技术和应用铺平了道路。resistance material的另一个关键方面是其在热管理中的作用。在许多工业过程中,需要能够抵抗高温的材料以维持操作效率。例如,在航空航天工程中,暴露于极端热量的组件必须由专门的resistance material制成,以承受高热负荷而不降解。这一要求突显了选择合适材料的重要性,以确保在高风险环境中的安全性和性能。总之,resistance material包括广泛的物质,对于现代技术和基础设施至关重要。从电子产品到建筑及其他领域,这些材料的特性决定了它们在各种应用中的适用性。随着研究的不断推进,resistance material的未来充满了增强性能和创新的激动人心的可能性。理解这些材料对于任何参与设计、工程或制造的人来说都是至关重要的,因为它们构成了许多关键系统和结构的基础。通过投资于新resistance material的研究和开发,我们可以期待一个充满更安全、更高效技术的未来,从而改善我们的生活质量。