yoke flux

简明释义

轭磁通

英英释义

例句

1.In this experiment, we measured the yoke flux to analyze the performance of the coil.

在这个实验中，我们测量了耦合通量以分析线圈的性能。

2.To enhance the sensor's accuracy, we need to minimize the yoke flux interference.

为了提高传感器的准确性，我们需要最小化耦合通量的干扰。

3.The engineer calculated the yoke flux to optimize the magnetic field in the motor design.

工程师计算了耦合通量以优化电机设计中的磁场。

4.Understanding the yoke flux is crucial for improving the efficiency of transformers.

理解耦合通量对于提高变压器的效率至关重要。

5.The research focused on the effects of yoke flux on electromagnetic induction.

研究集中在耦合通量对电磁感应的影响上。

作文

In the realm of physics and engineering, the concept of yoke flux plays a crucial role in understanding magnetic circuits and their applications. The term 'yoke' generally refers to a frame or structure that supports or connects various components, while 'flux' denotes the flow of energy or force through a given area. When combined, yoke flux specifically pertains to the magnetic flux that is linked with the yoke of a magnetic circuit, such as in transformers or inductors. Understanding this concept is essential for anyone involved in electrical engineering or related fields, as it directly influences the efficiency and performance of electromagnetic devices.The significance of yoke flux can be observed in its impact on the design and operation of transformers. In a transformer, the yoke serves as a path for the magnetic flux generated by the primary winding. This flux then induces an electromotive force (EMF) in the secondary winding, allowing for the transfer of electrical energy between two circuits. If the yoke flux is not properly managed, it can lead to energy losses due to leakage or saturation, ultimately affecting the transformer's efficiency.Moreover, the calculation of yoke flux is vital for engineers when designing magnetic circuits. It involves analyzing the geometry of the yoke, the material properties, and the operational conditions under which the device will function. By accurately calculating the yoke flux, engineers can optimize the design to minimize losses and enhance performance. For instance, selecting materials with high magnetic permeability can significantly increase the amount of flux that the yoke can carry, thus improving the overall efficiency of the device.In addition to transformers, yoke flux also finds relevance in other applications such as electric motors and generators. In these devices, the yoke contributes to the creation of a magnetic field that is necessary for their operation. Understanding how yoke flux interacts with different components helps engineers to troubleshoot issues and improve the design of these machines.Furthermore, the study of yoke flux extends beyond just theoretical calculations. Practical experiments and simulations are often conducted to observe how changes in the yoke's design or material affect the magnetic flux. These experiments provide valuable insights that can lead to innovative designs and improvements in technology.In conclusion, the term yoke flux encapsulates a fundamental aspect of magnetic circuits in electrical engineering. Its understanding is pivotal for designing efficient transformers, motors, and generators. By mastering the principles surrounding yoke flux, engineers can contribute to advancements in technology that harness electrical energy more effectively and sustainably. As the demand for efficient energy solutions continues to grow, the importance of concepts like yoke flux will undoubtedly remain at the forefront of engineering innovation.

在物理和工程领域，yoke flux的概念在理解磁性电路及其应用中发挥着至关重要的作用。术语'yoke'通常指的是支撑或连接各种组件的框架或结构，而'flux'则表示通过给定区域的能量或力的流动。当两者结合时，yoke flux特指与磁性电路的yoke相关的磁通量，例如变压器或电感器。理解这一概念对于任何参与电气工程或相关领域的人来说都是必不可少的，因为它直接影响到电磁设备的效率和性能。yoke flux的重要性可以通过其对变压器设计和操作的影响来观察。在变压器中，yoke作为由初级绕组产生的磁通量的路径。这种磁通量随后在次级绕组中感应出电动势（EMF），允许电能在两个电路之间转移。如果yoke flux管理不当，可能会导致由于泄漏或饱和而造成的能量损失，从而最终影响变压器的效率。此外，计算yoke flux对于工程师在设计磁性电路时至关重要。它涉及分析yoke的几何形状、材料属性以及设备运行时的条件。通过准确计算yoke flux，工程师可以优化设计以最小化损失并增强性能。例如，选择具有高磁导率的材料可以显著增加yoke能够承载的磁通量，从而提高设备的整体效率。除了变压器，yoke flux还在电动机和发电机等其他应用中具有相关性。在这些设备中，yoke有助于创造其操作所需的磁场。理解yoke flux与不同组件的相互作用有助于工程师排除故障并改善这些机器的设计。此外，yoke flux的研究不仅限于理论计算。通常会进行实际实验和模拟，以观察yoke的设计或材料变化如何影响磁通量。这些实验提供了宝贵的见解，可以导致创新设计和技术改进。总之，术语yoke flux概括了电气工程中磁性电路的一个基本方面。掌握这一原则对于设计高效的变压器、电动机和发电机至关重要。通过掌握与yoke flux相关的原理，工程师可以为开发更有效和可持续利用电能的技术做出贡献。随着对高效能源解决方案的需求不断增长，像yoke flux这样的概念的重要性无疑将继续处于工程创新的前沿。