reentrant winding

简明释义

双线线圈

英英释义

例句

1.One advantage of reentrant winding is its ability to reduce electromagnetic interference.

再入绕组的一个优点是它能够减少电磁干扰。

2.The reentrant winding configuration allows for better heat dissipation in high-power applications.

在高功率应用中，再入绕组配置允许更好的散热。

3.We tested several prototypes, and the one with the reentrant winding performed best.

我们测试了几个原型，其中带有再入绕组的那个表现最好。

4.The motor's efficiency can be enhanced by using a reentrant winding.

通过使用再入绕组，可以提高电机的效率。

5.In our design, we incorporated a reentrant winding to improve torque output.

在我们的设计中，我们采用了再入绕组以提高扭矩输出。

作文

Understanding the concept of reentrant winding is crucial for engineers and designers working in the field of electrical engineering, particularly in the design of motors and transformers. The term refers to a specific type of winding configuration that allows for efficient magnetic flux linkage and minimizes losses. In essence, reentrant winding involves a winding that makes a return path, effectively creating a loop or a reentrant path that enhances the performance of the device.The importance of reentrant winding can be seen in various applications, including electric motors, generators, and inductors. When designing these devices, engineers must consider how the winding layout affects overall efficiency, power output, and thermal management. A well-designed reentrant winding can significantly improve the electromagnetic characteristics of a device, leading to better performance and longevity.One of the primary advantages of using reentrant winding is its ability to reduce the amount of copper required for winding. By allowing the wire to loop back on itself, designers can achieve the same level of magnetic flux with less material. This not only lowers costs but also reduces the weight of the device, which is particularly important in applications where space and weight are critical factors, such as in aerospace and automotive industries.Additionally, reentrant winding helps in minimizing the stray losses that occur in traditional winding configurations. Stray losses are unwanted energy losses that can occur due to leakage inductance and other factors. By optimizing the winding layout with a reentrant design, engineers can enhance the efficiency of the device, leading to lower operational costs and improved reliability.In practical applications, the implementation of reentrant winding can be observed in various types of motors, such as synchronous and asynchronous motors. These motors utilize the reentrant configuration to create a more uniform magnetic field, which contributes to smoother operation and higher torque output. Moreover, transformers designed with reentrant winding can achieve better voltage regulation and reduced core losses, making them more efficient in power distribution systems.It is essential for engineers to have a deep understanding of the principles behind reentrant winding when developing new technologies. As the demand for more efficient and compact electrical devices continues to grow, mastery of this winding technique will become increasingly important. Engineers must stay updated with the latest advancements in materials and design methodologies to fully leverage the benefits of reentrant winding.In conclusion, reentrant winding is a vital concept in electrical engineering that plays a significant role in enhancing the performance and efficiency of various electrical devices. By understanding and applying this winding technique, engineers can contribute to the development of more effective and sustainable technologies. As we move towards a future that prioritizes energy efficiency and innovation, the mastery of concepts like reentrant winding will undoubtedly be a key factor in driving progress in the field of electrical engineering.

理解重入绕组的概念对于在电气工程领域工作的工程师和设计师至关重要，特别是在电动机和变压器的设计中。该术语指的是一种特定的绕组配置，能够有效地链接磁通并最小化损失。简单来说，重入绕组涉及一个返回路径的绕组，有效地创建一个环路或重入路径，从而增强设备的性能。重入绕组的重要性可以在各种应用中看到，包括电动机、发电机和电感器。在设计这些设备时，工程师必须考虑绕组布局如何影响整体效率、功率输出和热管理。一个设计良好的重入绕组能够显著改善设备的电磁特性，从而提高性能和寿命。使用重入绕组的主要优点之一是它能够减少绕组所需的铜量。通过允许导线回环，设计师可以用更少的材料实现相同的磁通水平。这不仅降低了成本，还减少了设备的重量，这在空间和重量至关重要的应用中尤为重要，例如航空航天和汽车工业。此外，重入绕组有助于最小化在传统绕组配置中发生的漏损。漏损是由于漏感和其他因素造成的能量损失。通过优化带有重入设计的绕组布局，工程师可以提高设备的效率，从而降低运营成本并提高可靠性。在实际应用中，重入绕组的实施可以在各种类型的电动机中观察到，例如同步电动机和异步电动机。这些电动机利用重入配置来创建更均匀的磁场，从而有助于更平稳的运行和更高的扭矩输出。此外，采用重入绕组设计的变压器可以实现更好的电压调节和减少核心损耗，使其在电力分配系统中更高效。工程师需要深入理解重入绕组背后的原理，以便开发新技术。随着对更高效和紧凑的电气设备需求的不断增长，掌握这一绕组技术将变得越来越重要。工程师必须及时更新材料和设计方法的最新进展，以充分利用重入绕组的优势。总之，重入绕组是电气工程中的一个重要概念，在提升各种电气设备的性能和效率方面发挥着重要作用。通过理解和应用这一绕组技术，工程师可以为开发更有效和可持续的技术做出贡献。随着我们向一个优先考虑能源效率和创新的未来迈进，掌握像重入绕组这样的概念无疑将成为推动电气工程领域进步的关键因素。