nonconductor

简明释义

英[ˌnɑn.kənˈdʌk.tɚ]美[ˌnɑn.kənˈdʌk.tɚ]

n. [物] 绝缘体；[物] 非导体

英英释义

单词用法

同义词

反义词

例句

1.AFM may be the most effective instrument to satisfy the demand of ITRS to improve the measurement precision constantly since its observed objects are not limited in nonconductor only.

由于不要求被测样本为非绝缘体，原子力显微镜将可能成为边缘粗糙度测量精度要求不断提高的最有效工具。

2.AFM may be the most effective instrument to satisfy the demand of ITRS to improve the measurement precision constantly since its observed objects are not limited in nonconductor only.

由于不要求被测样本为非绝缘体，原子力显微镜将可能成为边缘粗糙度测量精度要求不断提高的最有效工具。

3.The application of GDMS was reviewed in the aspects of the bulk metal, semiconductor, nonconductor, solution, gas and depth analysis.

对辉光放电质谱在块状金属、半导体、非导体、溶液、气体和深度分析方面的应用进行了综述。

4.The transparency of organic glass is good, but it is nonconductor and has no shielded efficiency.

有机玻璃透明性好，但为绝缘体因而不具有屏蔽效能。

5.The modified electrode change from conductor to nonconductor with number of circle increased.

随着扫描圈数的增加，聚合膜的厚度也增加，同时电极由导体向绝缘体转变。

6.Rubber is a common nonconductor 绝缘体 used in electrical applications.

橡胶是电气应用中常用的非导体 绝缘体。

7.In high-voltage environments, using a nonconductor 绝缘材料 is essential to prevent accidents.

在高压环境中，使用非导体 绝缘材料是防止事故的关键。

8.Plastic is often chosen as a nonconductor 绝缘体 for wires and cables.

塑料通常被选为电线和电缆的非导体 绝缘体。

9.A good nonconductor 绝缘体 will help maintain the efficiency of electrical systems.

一个好的非导体 绝缘体将有助于维持电气系统的效率。

10.When designing circuits, engineers must consider materials that act as nonconductors 绝缘体.

在设计电路时，工程师必须考虑作为非导体 绝缘体的材料。

作文

In the world of physics and electrical engineering, the term nonconductor refers to a material that does not allow the flow of electric current. This property makes nonconductors essential in various applications, especially in insulating materials used in electrical devices. Understanding the role of nonconductors can help us appreciate the intricacies of electrical systems and their safe operation. To illustrate the significance of nonconductors, consider the common example of rubber. Rubber is widely recognized as a nonconductor of electricity, which is why it is often used to insulate wires and electrical components. Without such nonconductors, the risk of electrical shocks and short circuits would be substantially higher. For instance, if a live wire were to come into contact with a conductive material, it could lead to dangerous situations, including fires or electrocution. Moreover, the use of nonconductors extends beyond just electrical safety. In electronic devices, materials like plastic and glass serve as nonconductors that protect sensitive components from external electrical interference. This ensures that devices operate smoothly without unexpected interruptions. The presence of nonconductors in these devices allows for the efficient functioning of electronics, which has become an integral part of our daily lives. The classification of materials into conductors, semiconductors, and nonconductors also plays a crucial role in the development of new technologies. Researchers are continuously exploring various materials to enhance their properties. For example, the search for better nonconductors can lead to advancements in energy storage and transmission. By improving the insulation properties of nonconductors, we can create more efficient systems that minimize energy loss during transmission. Furthermore, understanding the concept of nonconductors is vital for students studying physics and engineering. It helps them grasp fundamental principles related to electricity and magnetism. Through experiments, students can observe how different materials behave when subjected to electrical currents, reinforcing their knowledge of nonconductors and their applications. In summary, the term nonconductor signifies a material's inability to conduct electricity, making it a crucial component in ensuring safety and efficiency in electrical systems. From rubber to glass, nonconductors play a pivotal role in protecting both users and devices from electrical hazards. As technology continues to evolve, the importance of nonconductors will undoubtedly grow, paving the way for innovations that rely on their insulating properties. By understanding and utilizing nonconductors, we can enhance the functionality and safety of our electrical devices, ultimately leading to a more advanced technological future.

在物理和电气工程的世界中，术语非导体指的是一种不允许电流流动的材料。这种特性使得非导体在各种应用中至关重要，特别是在用于电气设备的绝缘材料中。理解非导体的作用可以帮助我们欣赏电气系统的复杂性及其安全操作。 为了说明非导体的重要性，可以考虑一个常见的例子：橡胶。橡胶被广泛认为是电的非导体，这就是为什么它常常用于绝缘电线和电气组件。如果没有这样的非导体，电击和短路的风险将大大增加。例如，如果一根带电的电线与导电材料接触，可能会导致危险情况，包括火灾或触电。 此外，非导体的使用不仅限于电气安全。在电子设备中，塑料和玻璃等材料充当非导体，保护敏感组件免受外部电干扰。这保证了设备平稳运行而不会出现意外中断。这些设备中非导体的存在使电子产品高效运作，而这些产品已成为我们日常生活中不可或缺的一部分。 将材料分类为导体、半导体和非导体也在新技术的发展中发挥着关键作用。研究人员不断探索各种材料以增强其性能。例如，寻找更好的非导体可以推动能源存储和传输的进步。通过改善非导体的绝缘性能，我们可以创建更高效的系统，减少在传输过程中的能量损失。 此外，理解非导体的概念对学习物理和工程的学生至关重要。它帮助他们掌握与电力和磁力相关的基本原理。通过实验，学生可以观察不同材料在施加电流时的表现，从而巩固他们对非导体及其应用的知识。 总之，术语非导体表示材料无法导电，使其成为确保电气系统安全和效率的关键组成部分。从橡胶到玻璃，非导体在保护用户和设备免受电气危害方面发挥着重要作用。随着技术的不断发展，非导体的重要性无疑会增加，为依赖其绝缘特性的创新铺平道路。通过理解和利用非导体，我们可以增强电气设备的功能和安全性，最终引领我们迈向更先进的技术未来。