magneticflux linkage

简明释义

磁链

英英释义

例句

1.In generators, magnetic flux linkage 磁通联结 plays a significant role in converting mechanical energy into electrical energy.

在发电机中，磁通联结 magnetic flux linkage在将机械能转换为电能方面起着重要作用。

2.The concept of magnetic flux linkage 磁通联结 is crucial in understanding how electromagnetic fields interact with circuits.

理解电磁场如何与电路相互作用的关键在于磁通联结 magnetic flux linkage的概念。

3.In a transformer, the efficiency depends on the amount of magnetic flux linkage 磁通联结 between the primary and secondary coils.

在变压器中，效率取决于初级和次级线圈之间的磁通联结 magnetic flux linkage的数量。

4.The design of electric motors often focuses on maximizing magnetic flux linkage 磁通联结 to improve performance.

电动机的设计通常侧重于最大化磁通联结 magnetic flux linkage以提高性能。

5.When analyzing inductors, engineers must consider the magnetic flux linkage 磁通联结 to calculate energy storage.

在分析电感器时，工程师必须考虑磁通联结 magnetic flux linkage以计算能量存储。

作文

Understanding the concept of magnetic flux linkage is crucial in the field of electromagnetism and electrical engineering. It refers to the way magnetic fields interact with electric circuits, forming a fundamental principle that underlies many technologies we use today. The concept can be broken down into two key components: magnetic flux and linkage. Magnetic flux, denoted by the Greek letter 'Phi' (Φ), represents the total magnetic field passing through a given area. It is measured in webers (Wb) and is influenced by the strength of the magnetic field and the area it penetrates. On the other hand, magnetic flux linkage involves the interaction between the magnetic flux and a coil or loop of wire. When a magnetic field passes through a coil, it induces an electromotive force (EMF) due to Faraday's law of electromagnetic induction. This induced EMF is directly proportional to the rate of change of magnetic flux linkage in the coil. Therefore, understanding how these magnetic fields link with electrical circuits is essential for designing efficient electrical devices.In practical applications, magnetic flux linkage plays a vital role in transformers, electric motors, and generators. For instance, in a transformer, the primary coil generates a magnetic field that links with the secondary coil. The efficiency of energy transfer between these coils heavily relies on the degree of magnetic flux linkage. If the magnetic flux does not effectively link the two coils, energy loss occurs, leading to inefficiencies. Similarly, in electric motors, the rotation of the motor’s rotor within a magnetic field creates a continuous change in magnetic flux linkage, which is responsible for converting electrical energy into mechanical energy.Moreover, the concept of magnetic flux linkage is not only limited to traditional electrical devices but also extends to renewable energy systems. In wind turbines, the blades rotate in the wind, causing a change in magnetic flux linkage within the generator, thus producing electricity. The efficiency of this process is contingent upon how well the magnetic fields are linked to the coils within the generator.To further illustrate the importance of magnetic flux linkage, consider the advancements in wireless power transfer technologies. These technologies rely on the principles of electromagnetic induction, where the magnetic flux linkage between the transmitter and receiver coils enables the transfer of power without physical connections. This innovation highlights how a deep understanding of magnetic flux linkage can lead to groundbreaking developments in modern technology.In conclusion, magnetic flux linkage is a fundamental concept that bridges the gap between magnetic fields and electrical circuits. Its significance spans various applications, from traditional electrical devices to cutting-edge technologies in renewable energy and wireless power transfer. As we continue to innovate and develop new technologies, the principles behind magnetic flux linkage will remain at the forefront of electrical engineering, shaping the future of how we harness and utilize energy.

理解磁通链的概念在电磁学和电气工程领域至关重要。它指的是磁场与电路之间的相互作用，形成了我们今天使用的许多技术的基本原理。这个概念可以分为两个关键组成部分：磁通和链。磁通用希腊字母“Phi”（Φ）表示，代表通过给定面积的总磁场。它以韦伯（Wb）为单位进行测量，并受到磁场强度和穿透面积的影响。另一方面，磁通链涉及磁通与一圈或一条导线之间的相互作用。当磁场穿过一个线圈时，由于法拉第电磁感应定律，它会在其中诱导出电动势（EMF）。这种诱导的电动势与线圈中磁通链的变化率成正比。因此，理解这些磁场如何与电路链接对于设计高效的电气设备至关重要。在实际应用中，磁通链在变压器、电动机和发电机中发挥着重要作用。例如，在变压器中，初级线圈产生的磁场与次级线圈链接。这些线圈之间能量转移的效率在很大程度上依赖于磁通链的程度。如果磁通没有有效地链接这两个线圈，就会发生能量损失，导致效率降低。同样，在电动机中，转子在磁场中的旋转会导致磁通链的持续变化，这负责将电能转换为机械能。此外，磁通链的概念不仅限于传统电气设备，还扩展到可再生能源系统。在风力涡轮机中，叶片在风中旋转，导致发电机内部的磁通链发生变化，从而产生电力。这一过程的效率取决于磁场与发电机内部线圈的链接效果。为了进一步说明磁通链的重要性，可以考虑无线电力传输技术的进步。这些技术依赖于电磁感应原理，其中发射器和接收器线圈之间的磁通链使得在没有物理连接的情况下进行能量传输。这一创新突显了对磁通链深入理解如何引领现代技术的突破性发展。总之，磁通链是一个基本概念，架起了磁场与电路之间的桥梁。它的重要性跨越了各种应用，从传统电气设备到可再生能源和无线电力传输的前沿技术。随着我们继续创新和开发新技术，磁通链背后的原理将始终处于电气工程的最前沿，塑造我们利用和利用能源的未来。