toroidal system with internal winding

简明释义

内部线圈环形装置

英英释义

例句

1.The engineer designed a toroidal system with internal winding to improve the efficiency of the power transformer.

工程师设计了一个带有内部绕组的环形系统以提高变压器的效率。

2.In our lab, we are testing a new toroidal system with internal winding for wireless energy transfer applications.

在我们的实验室中，我们正在测试一种新的带有内部绕组的环形系统用于无线能量传输应用。

3.The toroidal system with internal winding allows for better thermal management in high-power applications.

该带有内部绕组的环形系统在高功率应用中允许更好的热管理。

4.The toroidal system with internal winding minimizes electromagnetic interference in sensitive electronic devices.

该带有内部绕组的环形系统最小化了敏感电子设备中的电磁干扰。

5.For our project, we chose a toroidal system with internal winding due to its compact design and high performance.

对于我们的项目，我们选择了一个带有内部绕组的环形系统，因为它的紧凑设计和高性能。

作文

The concept of a toroidal system with internal winding is essential in various fields, particularly in electrical engineering and physics. A toroidal system refers to a structure that is shaped like a doughnut or a ring. This unique geometry allows for specific electromagnetic properties that are not found in linear systems. The internal winding aspect refers to the coils of wire that are wound around the toroidal core. These windings create a magnetic field when an electric current passes through them, which is fundamental in the operation of devices such as transformers and inductors.In practical applications, a toroidal system with internal winding can be observed in power supplies and audio equipment. For instance, in a toroidal transformer, the winding is arranged in a circular pattern around a magnetic core. This design minimizes electromagnetic interference and improves efficiency compared to traditional rectangular transformers. The compact nature of the toroidal shape also contributes to space-saving designs in electronic devices.Moreover, the magnetic field produced by a toroidal system with internal winding is highly concentrated within the core, which reduces the stray magnetic fields that can affect nearby components. This characteristic is particularly advantageous in sensitive applications where precision is crucial, such as in medical devices or high-fidelity audio systems. Engineers and designers often prefer toroidal systems due to their superior performance and reduced size.The mathematical modeling of a toroidal system with internal winding involves complex equations related to electromagnetism. The Biot-Savart law and Ampere's law are frequently used to analyze the magnetic fields generated by the current flowing through the windings. Understanding these principles is vital for optimizing the design and functionality of toroidal devices.Furthermore, advancements in materials science have led to the development of high-performance magnetic cores used in toroidal systems with internal winding. Ferrite and laminated steel are commonly used materials that enhance the magnetic properties and efficiency of these systems. As technology progresses, researchers continue to explore new materials and designs that could further improve the performance of toroidal systems.In conclusion, the toroidal system with internal winding is a fundamental concept in modern engineering. Its unique shape and efficient design provide numerous advantages in various applications, from power distribution to audio processing. As technology evolves, the importance of understanding and utilizing this system will only grow, making it a critical area of study for future engineers and scientists. The ongoing research and development in this field promise exciting innovations that will enhance the performance and capabilities of electronic devices, ultimately benefiting society as a whole.

“带内部绕组的环形系统”这一概念在多个领域中至关重要，特别是在电气工程和物理学中。环形系统是指形状类似于甜甜圈或环的结构。这种独特的几何形状使得其具备一些线性系统所不具备的特定电磁特性。内部绕组则是指绕在环形核心上的电线圈。当电流通过这些绕组时，会产生磁场，这是变压器和电感等设备正常运作的基础。在实际应用中，可以在电源和音频设备中观察到“带内部绕组的环形系统”。例如，在环形变压器中，绕组以圆形模式围绕磁芯排列。这种设计最小化了电磁干扰，并提高了效率，相较于传统的矩形变压器而言，环形变压器具有更高的性能。环形形状的紧凑性也有助于电子设备的节省空间设计。此外，“带内部绕组的环形系统”所产生的磁场高度集中在核心内，这减少了可能影响附近组件的漏磁场。这一特性在需要精确的敏感应用中尤为有利，例如在医疗设备或高保真音频系统中。工程师和设计师通常偏爱环形系统，因为它们的卓越性能和减小的体积。对“带内部绕组的环形系统”的数学建模涉及与电磁学相关的复杂方程。Biot-Savart定律和安培定律常用于分析流经绕组的电流所产生的磁场。理解这些原理对于优化环形设备的设计和功能至关重要。此外，材料科学的进步导致了用于“带内部绕组的环形系统”的高性能磁芯的发展。铁氧体和层压钢是常用的材料，可以增强这些系统的磁性和效率。随着技术的发展，研究人员继续探索新的材料和设计，以进一步提高环形系统的性能。总之，“带内部绕组的环形系统”是现代工程中的一个基本概念。其独特的形状和高效的设计在多个应用中提供了众多优势，从电力分配到音频处理。随着技术的进步，理解和利用这一系统的重要性只会增加，使其成为未来工程师和科学家的关键研究领域。该领域持续的研究和开发承诺将带来令人兴奋的创新，提升电子设备的性能和能力，最终惠及整个社会。