leakage transformer

简明释义

漏磁变压器

英英释义

例句

1.When designing a circuit, it's crucial to consider the leakage transformer 漏泄变压器 to minimize energy loss.

在设计电路时，考虑漏泄变压器以最小化能量损失是至关重要的。

2.The leakage transformer 漏泄变压器 must be properly shielded to prevent electromagnetic interference.

漏泄变压器必须正确屏蔽，以防止电磁干扰。

3.The performance of the leakage transformer 漏泄变压器 can significantly affect the efficiency of the electrical system.

漏泄变压器的性能可以显著影响电气系统的效率。

4.Testing the leakage transformer 漏泄变压器 under various loads helps determine its reliability.

在不同负载下测试漏泄变压器有助于确定其可靠性。

5.High leakage current in the leakage transformer 漏泄变压器 can lead to safety hazards.

漏泄变压器中的高漏电流可能导致安全隐患。

作文

In the field of electrical engineering, transformers play a crucial role in the transmission and distribution of electrical energy. One specific type of transformer that has garnered attention is the leakage transformer, which refers to a transformer that exhibits some degree of energy loss due to leakage currents. Understanding the concept of a leakage transformer is essential for engineers and technicians who work with electrical systems, as it can significantly impact the efficiency and performance of power systems.The primary function of a transformer is to change the voltage level of alternating current (AC) electricity. This is achieved through electromagnetic induction, where the primary winding generates a magnetic field that induces a voltage in the secondary winding. However, not all the magnetic flux generated in the primary winding couples perfectly with the secondary winding. Some of this magnetic flux 'leaks' into the surrounding environment instead of being used effectively, leading to what we call leakage.Leakage can occur due to various factors, including the physical design of the transformer, the materials used in its construction, and the distance between the windings. As a result, a leakage transformer may have a lower efficiency compared to an ideal transformer, where all the magnetic flux is utilized. The energy lost in the form of leakage currents can translate into heat, which can further affect the overall performance of the transformer and the system it is part of.To mitigate the effects of leakage, engineers often employ several strategies during the design and manufacturing of transformers. For instance, they may use high-quality insulating materials to reduce the risk of leakage currents. Additionally, optimizing the geometry of the windings and the core can help minimize the leakage flux. These design considerations are particularly important in applications where efficiency is paramount, such as in power generation and distribution networks.Another critical aspect of understanding leakage transformers is their impact on the overall system stability. In power systems, transformers are often connected in parallel to ensure reliability and redundancy. If one transformer experiences significant leakage, it can lead to imbalances in the system, potentially causing issues such as voltage fluctuations and increased losses. Therefore, monitoring and managing the performance of transformers, including assessing leakage, is vital for maintaining the stability of electrical grids.In summary, the leakage transformer is a fundamental concept within electrical engineering that highlights the importance of efficiency in transformer design and operation. By recognizing the factors that contribute to leakage and implementing effective design strategies, engineers can enhance the performance of transformers and ensure the reliable delivery of electrical energy. This understanding is not only crucial for individual components but also for the broader context of power systems, where every element must work harmoniously to achieve optimal performance and efficiency.

在电气工程领域，变压器在电能的传输和分配中发挥着至关重要的作用。其中一种特定类型的变压器引起了人们的关注，即漏电变压器，指的是由于漏电流而表现出一定能量损失的变压器。理解漏电变压器的概念对于从事电气系统工作的工程师和技术人员至关重要，因为这会显著影响电力系统的效率和性能。变压器的主要功能是改变交流电（AC）电力的电压水平。这是通过电磁感应实现的，初级绕组产生的磁场在次级绕组中感应出电压。然而，并不是所有在初级绕组中产生的磁通都与次级绕组完美耦合。一部分磁通会“泄漏”到周围环境，而不是被有效利用，这就是我们所称的漏电现象。漏电可能由于多种因素而发生，包括变压器的物理设计、其构造中使用的材料以及绕组之间的距离。因此，漏电变压器的效率可能低于理想变压器，在理想变压器中，所有的磁通都被利用。以漏电流形式损失的能量可能转化为热量，进一步影响变压器及其所在系统的整体性能。为了减轻漏电的影响，工程师在变压器的设计和制造过程中通常会采取多种策略。例如，他们可能会使用高质量的绝缘材料，以减少漏电流的风险。此外，优化绕组和铁心的几何形状可以帮助最小化漏电磁通。这些设计考虑在效率至关重要的应用中尤为重要，例如在发电和配电网络中。理解漏电变压器的另一个关键方面是它们对整体系统稳定性的影响。在电力系统中，变压器通常并联连接，以确保可靠性和冗余。如果一个变压器经历了显著的漏电，可能导致系统不平衡，从而引发电压波动和损耗增加等问题。因此，监测和管理变压器的性能，包括评估漏电，对于维持电网的稳定至关重要。总之，漏电变压器是电气工程中的一个基本概念，强调了变压器设计和操作中效率的重要性。通过认识导致漏电的因素并实施有效的设计策略，工程师可以提高变压器的性能，确保电能的可靠传输。这种理解不仅对单个组件至关重要，而且对电力系统的更广泛背景也同样重要，在这个系统中，每个元素都必须和谐工作，以实现最佳性能和效率。