coefficient of magnetic leakage

简明释义

磁漏系数

英英释义

例句

1.The engineer calculated the coefficient of magnetic leakage to determine how much magnetic flux was escaping from the transformer.

工程师计算了磁泄漏系数以确定有多少磁通从变压器中泄漏。

2.A low coefficient of magnetic leakage indicates that the magnetic circuit is efficient and minimizes energy loss.

低磁泄漏系数表明磁路高效，最小化能量损失。

3.In designing inductors, it is crucial to minimize the coefficient of magnetic leakage for better performance.

在设计电感器时，降低磁泄漏系数对提高性能至关重要。

4.Manufacturers often test the coefficient of magnetic leakage to ensure their products meet industry standards.

制造商通常测试磁泄漏系数以确保其产品符合行业标准。

5.The coefficient of magnetic leakage can vary significantly between different materials used in magnetic circuits.

不同材料在磁路中的磁泄漏系数可能会有显著差异。

作文

The study of magnetism is a fundamental aspect of physics that has numerous applications in our daily lives. One important concept within this field is the coefficient of magnetic leakage, which plays a critical role in understanding how magnetic fields behave in various materials and systems. In essence, the coefficient of magnetic leakage (磁漏系数) quantifies the amount of magnetic flux that does not follow the intended path within a magnetic circuit. This phenomenon occurs due to imperfections in the materials used, geometric configurations, and other environmental factors. To grasp the significance of the coefficient of magnetic leakage, we must first understand what magnetic leakage is. Magnetic leakage refers to the stray magnetic fields that occur when the magnetic flux deviates from its desired pathway. These stray fields can lead to energy losses, reduced efficiency, and unintended interactions with nearby components. For instance, in electrical transformers, high levels of magnetic leakage can result in significant energy losses, which ultimately affect the performance and operational costs of the device.When designing magnetic circuits, engineers must take the coefficient of magnetic leakage into consideration to optimize performance. A lower leakage coefficient indicates that more of the magnetic flux is contained within the intended path, resulting in higher efficiency. On the contrary, a high leakage coefficient signifies that a greater portion of the magnetic field is leaking away, leading to potential losses and inefficiencies. Therefore, understanding and minimizing the coefficient of magnetic leakage is crucial for enhancing the functionality of devices such as transformers, inductors, and magnetic sensors.The determination of the coefficient of magnetic leakage can be achieved through various experimental methods. One common approach involves measuring the magnetic flux density in different parts of the magnetic circuit while applying known input currents. By analyzing these measurements, engineers can calculate the leakage coefficient and make informed decisions about material selection, design modifications, and overall system improvements.Moreover, advancements in technology have enabled the development of new materials and designs that can significantly reduce the coefficient of magnetic leakage. For example, the use of laminated cores in transformers helps to minimize eddy currents, which are a major source of magnetic leakage. Additionally, innovative geometrical configurations can guide the magnetic flux more effectively, further reducing leakage effects.In conclusion, the coefficient of magnetic leakage (磁漏系数) is a vital parameter in the field of magnetism and plays an essential role in the design and efficiency of magnetic circuits. By understanding and managing this coefficient, engineers can enhance the performance of various electrical devices, reduce energy losses, and improve overall system reliability. As technology continues to evolve, ongoing research will undoubtedly yield new insights and methodologies for addressing magnetic leakage, ensuring that we harness the full potential of magnetic materials and designs in our ever-advancing technological landscape.

磁漏系数是物理学中磁性研究的一个重要概念，在我们日常生活中有着广泛的应用。简单来说，磁漏系数（coefficient of magnetic leakage）量化了在磁路中，未按照预期路径流动的磁通量的多少。由于使用材料的缺陷、几何配置和其他环境因素，这种现象会发生。为了理解磁漏系数的重要性，我们首先需要了解什么是磁漏。磁漏是指当磁通量偏离其预定路径时所产生的杂散磁场。这些杂散场可能导致能量损失、效率降低以及与附近组件的意外相互作用。例如，在电力变压器中，高水平的磁漏可能导致显著的能量损失，最终影响设备的性能和运营成本。在设计磁路时，工程师必须考虑磁漏系数，以优化性能。较低的漏磁系数表明更多的磁通量被限制在预定路径内，从而提高效率。相反，高漏磁系数则意味着更大部分的磁场正在泄漏，导致潜在损失和低效。因此，理解和最小化磁漏系数对于提升变压器、电感器和磁传感器等设备的功能至关重要。磁漏系数的确定可以通过多种实验方法实现。一种常见的方法是，在施加已知输入电流的情况下，测量磁路不同部分的磁通密度。通过分析这些测量结果，工程师可以计算出漏磁系数，并就材料选择、设计修改和整体系统改进做出明智的决策。此外，技术的进步使得开发新材料和设计成为可能，这些新材料和设计能够显著降低磁漏系数。例如，在变压器中使用层压核心有助于最小化涡流，这是磁漏的主要来源。此外，创新的几何配置可以更有效地引导磁通，进一步减少泄漏效应。总之，磁漏系数（coefficient of magnetic leakage）是磁学领域中的一个重要参数，在磁路的设计和效率中起着至关重要的作用。通过理解和管理这一系数，工程师可以增强各种电气设备的性能，减少能量损失，提高整体系统的可靠性。随着技术的不断发展，持续的研究无疑会为解决磁漏问题提供新的见解和方法，确保我们在不断发展的技术环境中充分利用磁性材料和设计的潜力。