magnetic linkage

简明释义

磁链

英英释义

例句

1.In this experiment, we will observe the effects of magnetic linkage 磁耦合 between two coils.

在这个实验中，我们将观察两个线圈之间的magnetic linkage 磁耦合的效果。

2.The magnetic linkage 磁耦合 between the magnets creates a strong attraction.

磁铁之间的magnetic linkage 磁耦合产生了强大的吸引力。

3.The design of this motor relies on magnetic linkage 磁耦合 to enhance efficiency.

这个电机的设计依赖于magnetic linkage 磁耦合来提高效率。

4.The magnetic linkage 磁耦合 in this system allows for wireless energy transfer.

这个系统中的magnetic linkage 磁耦合允许无线能量传输。

5.Understanding magnetic linkage 磁耦合 is crucial for developing more efficient transformers.

理解magnetic linkage 磁耦合对于开发更高效的变压器至关重要。

作文

In the realm of physics and engineering, the concept of magnetic linkage plays a crucial role in understanding how magnetic fields interact with various materials. Magnetic linkage refers to the connection or relationship between magnetic fields and the objects that they influence. This phenomenon can be observed in numerous applications, from electric motors to transformers, and even in everyday items like refrigerator magnets. To delve deeper into magnetic linkage, one must first grasp the fundamentals of magnetism. Magnetism is a force that arises from the motion of electric charges, and it manifests in various forms. When we speak of magnetic linkage, we are often referring to how the magnetic field generated by one magnet can affect another magnet or a conductive material nearby. This interaction is essential for the functioning of many devices that rely on magnetic forces. For instance, in electric motors, magnetic linkage is responsible for converting electrical energy into mechanical energy. The motor consists of a rotor and a stator, where the stator generates a magnetic field that interacts with the rotor. This interaction creates a force that causes the rotor to spin, thus producing motion. Here, the efficiency of the motor heavily depends on the strength of the magnetic linkage between the components. Another significant application of magnetic linkage can be found in transformers, which are crucial for the transmission of electrical energy over long distances. A transformer works by utilizing magnetic linkage between two coils of wire. When an alternating current flows through the primary coil, it generates a changing magnetic field. This magnetic field induces a voltage in the secondary coil through magnetic linkage, allowing for the transfer of energy without direct electrical contact. This principle is fundamental to the operation of power grids worldwide. Moreover, magnetic linkage also has implications in the field of data storage. Hard drives and other magnetic storage devices utilize the principles of magnetism to read and write data. The alignment of magnetic particles on a disk surface represents binary data, and the magnetic linkage between the read/write head and the disk is vital for accurate data retrieval. In conclusion, the concept of magnetic linkage is integral to various technological advancements and everyday applications. By understanding how magnetic fields interact with materials, we can harness these forces to create efficient machines and systems that power our modern world. As technology continues to evolve, the study of magnetic linkage will undoubtedly lead to new innovations and improvements in various fields, including electronics, energy, and even medicine. Therefore, a deeper comprehension of this phenomenon is essential for anyone interested in pursuing a career in science and engineering. In summary, magnetic linkage (磁联结) is not only a fascinating subject within physics but also a practical concept that underpins many aspects of our daily lives. Understanding its principles can open doors to a multitude of opportunities in the ever-evolving landscape of technology and innovation.

在物理和工程领域，magnetic linkage（磁联结）的概念在理解磁场如何与各种材料相互作用方面起着至关重要的作用。Magnetic linkage指的是磁场与其影响的物体之间的连接或关系。这个现象可以在许多应用中观察到，从电动机到变压器，甚至在日常物品如冰箱磁铁中。要深入了解magnetic linkage，首先必须掌握磁性的基本原理。磁性是由电荷运动引发的力，以各种形式表现出来。当我们谈论magnetic linkage时，通常是指一个磁体所产生的磁场如何影响另一个磁体或附近的导电材料。这种相互作用对依赖磁力的许多设备的功能至关重要。例如，在电动机中，magnetic linkage负责将电能转化为机械能。电动机由转子和定子组成，其中定子产生的磁场与转子相互作用。这种相互作用产生一种力，使转子旋转，从而产生运动。在这里，电动机的效率在很大程度上取决于组件之间magnetic linkage的强度。Magnetic linkage的另一个重要应用可以在变压器中找到，变压器对于长距离电能传输至关重要。变压器通过利用两个线圈之间的magnetic linkage而工作。当交流电流流过初级线圈时，它会产生一个变化的磁场。这个磁场通过magnetic linkage在次级线圈中感应出电压，从而实现能量的传输，而无需直接电气接触。这个原理是全球电网运行的基础。此外，magnetic linkage在数据存储领域也有影响。硬盘驱动器和其他磁性存储设备利用磁性的原理来读取和写入数据。磁盘表面上磁性粒子的排列表示二进制数据，而读/写头与磁盘之间的magnetic linkage对于准确的数据检索至关重要。总之，magnetic linkage的概念对于各种技术进步和日常应用至关重要。通过理解磁场如何与材料相互作用，我们可以利用这些力量创造出高效的机器和系统，以推动我们现代世界的发展。随着技术的不断发展，对magnetic linkage的研究无疑会导致各个领域的新创新和改进，包括电子、能源，甚至医学。因此，对这一现象的深入理解对于任何有意在科学和工程领域追求职业的人来说都是必不可少的。总之，magnetic linkage（磁联结）不仅是物理学中的一个迷人主题，也是一个实际概念，支撑着我们日常生活的许多方面。理解其原理可以为我们在不断发展的技术和创新领域打开多种机会。