magnetic yoke

简明释义

磁偏角系统

英英释义

例句

1.By adjusting the magnetic yoke, we can control the strength of the magnetic field.

通过调整磁性架，我们可以控制磁场的强度。

2.The engineer explained how the magnetic yoke works in conjunction with sensors to detect flaws.

工程师解释了磁性架是如何与传感器配合工作以检测缺陷的。

3.In the lab, we employed a magnetic yoke to create a uniform magnetic field for our experiments.

在实验室中，我们使用磁性架为我们的实验创造均匀的磁场。

4.The magnetic yoke is essential for ensuring accurate measurements in magnetic testing.

在磁性测试中，磁性架对于确保准确测量至关重要。

5.The technician used a magnetic yoke to hold the metal sheet in place while welding.

技术员使用磁性架在焊接时将金属板固定到位。

作文

In the world of electromagnetism, various components play crucial roles in the functioning of devices and systems. One such component is the magnetic yoke, which serves as an essential part of many electromagnetic applications. A magnetic yoke is essentially a magnetic circuit that helps to direct magnetic flux and enhance the efficiency of magnetic fields generated by coils or other magnetic sources. It is commonly made of ferromagnetic materials, which possess high magnetic permeability, allowing them to effectively channel magnetic lines of force. This characteristic makes the magnetic yoke invaluable in devices such as transformers, relays, and magnetic sensors.The primary function of a magnetic yoke is to provide a path for magnetic flux, thereby reducing losses associated with stray magnetic fields. In a transformer, for instance, the magnetic yoke connects the primary and secondary windings, ensuring that the magnetic field generated by the primary winding efficiently induces a voltage in the secondary winding. Without a well-designed magnetic yoke, a significant amount of magnetic energy could be lost, resulting in lower efficiency and increased operational costs.Moreover, the design of a magnetic yoke can significantly influence the performance of the entire electromagnetic system. Engineers must consider factors such as shape, size, and material properties when designing a magnetic yoke. For example, a yoke with a larger cross-sectional area can carry more magnetic flux, which is particularly important in high-power applications. Additionally, the geometry of the magnetic yoke can affect how uniformly the magnetic field is distributed, impacting the overall effectiveness of the device.In industrial applications, magnetic yokes are often used in conjunction with sensors and actuators. For example, in magnetic levitation systems, a magnetic yoke can help stabilize the levitating object by providing a controlled magnetic field that counteracts gravitational forces. Similarly, in magnetic separation processes, the magnetic yoke plays a pivotal role in attracting and holding ferrous materials, thereby enhancing the efficiency of the separation process.Furthermore, advancements in material science have led to the development of new types of magnetic yokes that offer improved performance. For instance, the use of laminated silicon steel in the construction of magnetic yokes minimizes eddy current losses, allowing for higher efficiency in transformers and other devices. The integration of advanced computational techniques also enables engineers to simulate and optimize the design of magnetic yokes, leading to better performance and reduced manufacturing costs.In conclusion, the magnetic yoke is a fundamental component in the realm of electromagnetism, playing a vital role in directing magnetic flux and enhancing the efficiency of various devices. Its importance cannot be overstated, as it directly affects the performance and reliability of electromagnetic systems. As technology continues to advance, the role of magnetic yokes will likely evolve, paving the way for more efficient and innovative applications in the future.

在电磁学的世界中，各种组件在设备和系统的功能中扮演着至关重要的角色。其中一个组件是磁轭，它在许多电磁应用中作为基本部分。磁轭本质上是一个磁路，有助于引导磁通并提高线圈或其他磁源产生的磁场的效率。它通常由铁磁材料制成，这些材料具有高磁导率，使其能够有效地引导磁力线。这一特性使得磁轭在变压器、继电器和磁传感器等设备中不可或缺。磁轭的主要功能是为磁通提供路径，从而减少与杂散磁场相关的损失。例如，在变压器中，磁轭连接了初级和次级绕组，确保初级绕组产生的磁场有效地在次级绕组中感应出电压。如果没有设计良好的磁轭，大量的磁能可能会丧失，导致效率降低和运营成本增加。此外，磁轭的设计可以显著影响整个电磁系统的性能。工程师在设计磁轭时必须考虑形状、大小和材料特性等因素。例如，具有较大横截面积的磁轭能够承载更多的磁通，这在高功率应用中特别重要。此外，磁轭的几何形状可能影响磁场的均匀分布，从而影响设备的整体有效性。在工业应用中，磁轭通常与传感器和执行器一起使用。例如，在磁悬浮系统中，磁轭可以通过提供控制的磁场来稳定悬浮物体，从而抵消重力。同样，在磁分离过程中，磁轭在吸引和保持铁磁材料方面发挥着关键作用，从而提高分离过程的效率。此外，材料科学的进步导致了新型磁轭的发展，提供了更好的性能。例如，在磁轭的构造中使用层压硅钢可以最小化涡流损耗，从而提高变压器和其他设备的效率。先进的计算技术的整合也使工程师能够模拟和优化磁轭的设计，从而提高性能并降低制造成本。总之，磁轭是电磁领域中的基本组件，在引导磁通和提高各种设备的效率方面发挥着至关重要的作用。它的重要性不容低估，因为它直接影响电磁系统的性能和可靠性。随着技术的不断进步，磁轭的角色可能会演变，为未来更高效和创新的应用铺平道路。