toroidal winding

简明释义

环形绕组

英英释义

例句

1.Using a toroidal winding can significantly reduce the size of the inductor.

使用环形绕组可以显著减小电感器的体积。

2.The audio amplifier features a high-quality toroidal winding for better sound clarity.

这款音频放大器配备了高品质的环形绕组，以获得更好的声音清晰度。

3.The transformer utilizes a toroidal winding to minimize electromagnetic interference.

变压器利用环形绕组来最小化电磁干扰。

4.We chose a toroidal winding for its compact design and improved performance.

我们选择了环形绕组，因为它的紧凑设计和更好的性能。

5.In this circuit, the toroidal winding enhances efficiency by reducing losses.

在这个电路中，环形绕组通过减少损耗来提高效率。

作文

In the field of electrical engineering, the design and efficiency of inductors and transformers play a crucial role in various applications. One of the most effective designs for achieving high performance in these components is the use of toroidal winding. A toroidal winding refers to a specific type of wire winding that is wrapped around a doughnut-shaped core. This configuration offers several advantages over traditional winding methods. First and foremost, the toroidal winding minimizes electromagnetic interference (EMI). The closed-loop structure of the toroid helps contain the magnetic fields within the core, thereby reducing the radiation of stray fields into the surrounding environment. This characteristic is particularly beneficial in sensitive electronic circuits where EMI can lead to performance degradation or malfunctions. Additionally, toroidal winding provides enhanced magnetic efficiency. The continuous path of the magnetic flux in a toroidal shape ensures that the magnetic field lines are tightly concentrated within the core material. This results in a higher inductance value per unit of volume compared to other winding configurations, such as solenoids or rectangular coils. Consequently, designers can achieve the desired inductive properties with less material, which is a significant advantage in compact electronic devices. Another important aspect of toroidal winding is its thermal performance. The design allows for better heat dissipation due to the uniform distribution of the winding around the core. This property is crucial in applications where the components may experience high currents and generate substantial heat. By effectively managing heat, toroidal winding enhances the reliability and longevity of inductors and transformers. Moreover, the aesthetic appeal of toroidal winding cannot be overlooked. The neat and compact nature of toroidal coils makes them visually appealing, which is an essential consideration in consumer electronics where design plays a critical role. The smooth surface of the toroid also facilitates easier integration into various systems without compromising the overall look of the product. However, it is worth noting that the manufacturing process of toroidal winding can be more complex and costly compared to traditional winding methods. The need for specialized equipment and precise handling adds to the production time and expenses. Nonetheless, for many applications, the benefits far outweigh these challenges. Engineers often opt for toroidal winding when designing high-performance power supplies, audio equipment, and RF applications, where efficiency and compactness are paramount. In conclusion, the use of toroidal winding in electrical engineering represents a significant advancement in inductor and transformer design. Its ability to minimize EMI, enhance magnetic efficiency, improve thermal performance, and offer aesthetic benefits makes it a preferred choice for many applications. As technology continues to evolve, the demand for efficient and compact components will likely lead to an increase in the adoption of toroidal winding in various fields, further solidifying its importance in modern engineering practices.

在电气工程领域，电感器和变压器的设计与效率在各种应用中发挥着至关重要的作用。实现这些组件高性能的有效设计之一是采用环形绕组。环形绕组是指一种特定类型的线圈绕组，它绕在一个类似甜甜圈形状的核心上。这种配置相较于传统的绕组方法提供了几个优势。首先，环形绕组最小化了电磁干扰（EMI）。环形的闭合结构有助于将磁场限制在核心内部，从而减少了杂散场辐射到周围环境中的情况。这一特性在敏感电子电路中尤为重要，因为电磁干扰可能导致性能下降或故障。此外，环形绕组提供了增强的磁效率。环形形状中磁通量的连续路径确保磁场线紧密集中在核心材料内。这导致单位体积的感抗值相比其他绕组配置（如螺线管或矩形线圈）更高。因此，设计师可以用更少的材料实现所需的电感特性，这在紧凑的电子设备中是一个显著优势。环形绕组的另一个重要方面是其热性能。该设计由于绕组在核心周围均匀分布，允许更好的散热。这一属性在可能经历高电流并产生大量热量的应用中至关重要。通过有效管理热量，环形绕组增强了电感器和变压器的可靠性和使用寿命。此外，环形绕组的美观性也不能被忽视。环形线圈的整齐紧凑使其在视觉上具有吸引力，这在消费者电子产品中是一个重要考虑因素，因为设计在其中起着关键作用。环形的光滑表面也便于更容易地集成到各种系统中，而不会影响产品的整体外观。然而，值得注意的是，环形绕组的制造过程可能比传统的绕组方法更复杂且成本更高。对专业设备和精确处理的需求增加了生产时间和费用。尽管如此，对于许多应用来说，收益远大于这些挑战。在设计高性能电源、音频设备和射频应用时，工程师们通常选择环形绕组，因为效率和紧凑性至关重要。总之，环形绕组在电气工程中的使用代表了电感器和变压器设计的重要进步。其能够最小化电磁干扰、增强磁效率、改善热性能以及提供美学优势，使其成为许多应用的首选。随着技术的不断发展，对高效紧凑组件的需求可能会导致在各个领域中越来越多地采用环形绕组，进一步巩固其在现代工程实践中的重要性。