multiple winding

简明释义

复绕组复绕法

英英释义

例句

1.Using multiple winding in inductors helps to manage the inductance levels effectively.

在电感器中使用多个绕组有助于有效管理电感水平。

2.In electric motors, multiple winding configurations can lead to better torque performance.

在电动机中，多个绕组配置可以带来更好的扭矩性能。

3.The design of the coil includes multiple winding to achieve a higher voltage output.

线圈的设计包括多个绕组以实现更高的电压输出。

4.For this circuit, we need to implement multiple winding to ensure proper current distribution.

对于这个电路，我们需要实施多个绕组以确保适当的电流分配。

5.The transformer is designed with multiple winding to increase its efficiency.

该变压器设计有多个绕组以提高其效率。

作文

In the world of electrical engineering, the term multiple winding refers to a configuration where a single coil is wound around a core in several layers or sections. This design is commonly found in transformers and inductors, where the purpose is to increase the voltage or current capacity by utilizing more than one winding. The concept of multiple winding is crucial for understanding how electrical energy can be efficiently transformed and distributed. Transformers, for instance, are devices that rely heavily on the principle of multiple winding. A transformer typically consists of two or more windings: the primary winding, which receives the input voltage, and the secondary winding, which delivers the output voltage. By varying the number of turns in each winding, engineers can control the voltage levels. If the primary winding has more turns than the secondary winding, the transformer steps down the voltage; conversely, if the secondary has more turns, it steps up the voltage. This ability to manipulate voltage through multiple winding is essential for power distribution systems, ensuring that electricity can be transmitted over long distances with minimal loss.Moreover, multiple winding configurations are not limited to transformers alone. Inductors, which are used in various electronic circuits, also employ this method. An inductor with multiple winding can store more energy in its magnetic field, making it more efficient for applications like filtering signals or managing power supply in electronic devices. The increased inductance provided by multiple winding allows for better performance in circuits that require stable and reliable operation.The advantages of using multiple winding are numerous. For one, it allows for greater flexibility in circuit design. Engineers can create devices that meet specific voltage and current requirements without needing multiple separate components. This not only saves space but also reduces costs associated with manufacturing and assembly.However, there are challenges associated with multiple winding designs. One of the main concerns is the potential for electromagnetic interference (EMI). When multiple windings are placed close together, the magnetic fields generated can interact, leading to unwanted noise and reduced efficiency. Engineers must carefully design the layout of the windings to minimize these effects, often employing techniques such as shielding or spacing to mitigate interference.In conclusion, the concept of multiple winding is fundamental in the field of electrical engineering. It plays a vital role in the design and functionality of transformers and inductors, enabling the efficient transformation and management of electrical energy. As technology continues to advance, the importance of multiple winding configurations will only grow, paving the way for more innovative solutions in energy distribution and electronic circuit design.

在电气工程的世界中，术语multiple winding指的是一种配置，其中单个线圈在核心周围以多个层或部分缠绕。这种设计通常出现在变压器和电感器中，其目的是通过利用多个绕组来增加电压或电流容量。理解multiple winding的概念对于理解如何有效地转换和分配电能至关重要。例如，变压器是高度依赖于multiple winding原理的设备。变压器通常由两个或多个绕组组成：接收输入电压的初级绕组和提供输出电压的次级绕组。通过改变每个绕组中的匝数，工程师可以控制电压水平。如果初级绕组的匝数多于次级绕组，变压器就会降低电压；反之，如果次级绕组的匝数更多，则会提高电压。通过multiple winding操控电压的能力对电力分配系统至关重要，确保电力能够以最小的损耗在长距离内传输。此外，multiple winding配置不仅限于变压器。电感器也在各种电子电路中采用这种方法。具有multiple winding的电感器可以在其磁场中储存更多的能量，使其在过滤信号或管理电子设备中的电源方面更高效。multiple winding所提供的增加电感使电路在需要稳定和可靠操作时表现得更好。使用multiple winding的优点有很多。首先，它允许电路设计的更大灵活性。工程师可以创建满足特定电压和电流要求的设备，而无需多个独立组件。这不仅节省了空间，还减少了与制造和组装相关的成本。然而，multiple winding设计也面临挑战。主要问题之一是电磁干扰（EMI）的潜在风险。当多个绕组靠近放置时，产生的磁场可能会相互作用，导致不必要的噪声和效率降低。工程师必须仔细设计绕组的布局，以最小化这些影响，通常采用屏蔽或间距等技术来减轻干扰。总之，multiple winding的概念在电气工程领域中是基础性的。它在变压器和电感器的设计和功能中发挥着至关重要的作用，使电能的高效转换和管理成为可能。随着技术的不断进步，multiple winding配置的重要性只会增加，为能源分配和电子电路设计中的更多创新解决方案铺平道路。