toroidal system with external winding

简明释义

外部线圈环形装置

英英释义

例句

1.We implemented a toroidal system with external winding for our new audio amplifier to enhance sound quality.

我们为新的音频放大器实施了一个带外部绕组的环形系统以增强音质。

2.The toroidal system with external winding is widely used in high-frequency applications due to its compact design.

带外部绕组的环形系统因其紧凑的设计而广泛应用于高频应用中。

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

工程师设计了一个带外部绕组的环形系统以提高变压器的效率。

4.The toroidal system with external winding allows for better thermal management in electronic devices.

带外部绕组的环形系统允许在电子设备中实现更好的热管理。

5.In our research, we found that the toroidal system with external winding significantly reduces electromagnetic interference.

在我们的研究中，我们发现带外部绕组的环形系统显著减少了电磁干扰。

作文

In the realm of electrical engineering and physics, the term toroidal system with external winding refers to a specific configuration of electromagnetic systems that utilize a toroidal shape. A toroidal shape is essentially a doughnut-like form that allows for the efficient containment and manipulation of magnetic fields. This design is particularly advantageous in various applications such as transformers, inductors, and magnetic coils, where the control of magnetic flux is crucial. The toroidal system with external winding incorporates an external coil wound around the toroidal core, enhancing its functionality by allowing for greater flexibility in design and increased efficiency in energy transfer.One of the primary benefits of using a toroidal system with external winding is its ability to minimize electromagnetic interference. In conventional coil designs, stray magnetic fields can lead to unwanted noise and interference, which can affect the performance of nearby electronic devices. However, the closed-loop nature of a toroidal system helps to contain these fields within the core, significantly reducing their escape into the surrounding environment. This characteristic makes toroidal systems particularly appealing in sensitive applications such as audio equipment and communication devices, where clarity and fidelity are paramount.Moreover, the toroidal system with external winding is known for its high efficiency in energy conversion processes. Traditional transformer designs often suffer from losses due to heat and leakage flux. In contrast, the toroidal structure allows for a more uniform distribution of the magnetic field, which results in lower losses and improved performance. As a result, engineers and designers frequently opt for toroidal transformers in applications where efficiency is a critical factor, such as renewable energy systems and electric vehicles.The versatility of the toroidal system with external winding extends beyond just electrical applications. In recent years, researchers have begun exploring its potential in fields such as plasma physics and fusion energy. The unique geometry of the toroidal design lends itself well to containing plasma, making it an ideal candidate for experimental fusion reactors. By applying external windings to manipulate magnetic fields, scientists aim to achieve stable plasma confinement, a crucial step towards harnessing fusion energy as a viable power source.In conclusion, the toroidal system with external winding represents a significant advancement in the field of electromagnetic engineering. Its unique shape and configuration offer numerous advantages, including reduced electromagnetic interference, enhanced efficiency, and versatility across various applications. As technology continues to evolve, the importance of such innovative systems will undoubtedly grow, paving the way for new discoveries and advancements in both electrical engineering and related fields. Understanding the principles behind the toroidal system with external winding is essential for those looking to push the boundaries of modern technology, ensuring that they remain at the forefront of innovation and development.

在电气工程和物理学领域，短语带外部绕组的环形系统指的是一种特定的电磁系统配置，它利用环形形状。环形形状本质上是一种类似于甜甜圈的形式，允许有效地包含和操控磁场。这种设计在变压器、电感器和磁线圈等各种应用中尤为有利，因为控制磁通量至关重要。带外部绕组的环形系统包括绕在环形核心周围的外部线圈，通过允许更大的设计灵活性和提高能量传输效率来增强其功能。使用带外部绕组的环形系统的主要好处之一是其能够最小化电磁干扰。在传统的线圈设计中，散逸的磁场可能导致不必要的噪声和干扰，这会影响附近电子设备的性能。然而，环形系统的闭合环路特性有助于将这些场限制在核心内，从而显著减少它们逃逸到周围环境中的可能性。这一特性使得环形系统在音频设备和通信设备等敏感应用中特别受欢迎，因为在这些领域中清晰度和保真度至关重要。此外，带外部绕组的环形系统在能量转换过程中以高效率而闻名。传统变压器设计往往由于热损失和泄漏磁通而遭受损失。相比之下，环形结构允许磁场的更均匀分布，从而导致更低的损失和更好的性能。因此，工程师和设计师经常选择在效率至关重要的应用中使用环形变压器，例如可再生能源系统和电动车辆。带外部绕组的环形系统的多样性不仅限于电气应用。近年来，研究人员开始探索其在等离子体物理和聚变能源等领域的潜力。环形设计的独特几何形状非常适合于包含等离子体，使其成为实验聚变反应堆的理想候选者。通过施加外部绕组来操控磁场，科学家们旨在实现稳定的等离子体约束，这是利用聚变能源作为可行的电源的关键步骤。总之，带外部绕组的环形系统代表了电磁工程领域的重要进展。其独特的形状和配置提供了许多优点，包括减少电磁干扰、提高效率以及在各种应用中的多样性。随着技术的不断发展，这种创新系统的重要性无疑会增加，为电气工程及相关领域的新发现和进步铺平道路。理解带外部绕组的环形系统背后的原理对于那些希望推动现代技术边界的人来说至关重要，确保他们始终处于创新和发展的前沿。