polarized armature

简明释义

极化衔铁

英英释义

例句

1.The design of the motor includes a polarized armature to enhance efficiency.

该电机的设计包含一个极化电枢以提高效率。

2.The polarized armature in this generator helps reduce energy loss.

这个发电机中的极化电枢有助于减少能量损失。

3.The technician explained how the polarized armature works in conjunction with the magnetic field.

技术员解释了极化电枢如何与磁场协同工作。

4.In our latest project, we utilized a polarized armature for better torque control.

在我们最新的项目中，我们使用了一个极化电枢以更好地控制扭矩。

5.By adjusting the polarized armature, we can improve the performance of the device.

通过调整极化电枢，我们可以改善设备的性能。

作文

In the field of electrical engineering, many concepts and components are critical for understanding how devices operate. One such concept is the polarized armature, which plays a significant role in various types of electromagnetic devices, particularly in motors and generators. To fully appreciate the function and importance of a polarized armature, it is essential to explore its definition, operation, and applications.A polarized armature refers to an armature that possesses a specific magnetic orientation. This orientation is achieved by using permanent magnets or by arranging the windings in such a way that they create a distinct magnetic field. The polarization allows the armature to interact effectively with the magnetic field generated by the stator, enhancing the efficiency and performance of the device. In motors, for instance, the polarized armature ensures that the torque produced is maximized, leading to smoother and more powerful operation.The operation of a polarized armature is based on the principles of electromagnetism. When electric current flows through the windings of the armature, it generates a magnetic field that interacts with the external magnetic field from the stator. This interaction produces a force that causes the armature to rotate. The polarization of the armature is crucial because it determines the direction of the magnetic field and, subsequently, the direction of rotation. If the armature were not polarized correctly, the motor could stall or operate inefficiently.Applications of polarized armature technology can be found in various devices, from small household appliances to large industrial machines. For example, in toy motors, a polarized armature allows for efficient power conversion, making the toys run faster and longer. In larger applications, such as electric vehicles, the use of a polarized armature can significantly increase the overall efficiency of the vehicle's propulsion system, thereby extending battery life and improving performance.Moreover, the concept of polarized armature is not limited to just motors; it also applies to generators. In generators, the armature is rotated within a magnetic field, inducing an electric current. The polarization of the armature ensures that the generated current is stable and efficient. This is particularly important in renewable energy applications, where maximizing energy output is essential for sustainability.Understanding the significance of a polarized armature extends beyond just its mechanical and electrical properties. It also highlights the intricate relationship between physics and engineering. Engineers must consider factors such as material selection, design, and operational conditions when implementing a polarized armature in their designs. The challenges of creating a highly efficient polarized armature push the boundaries of innovation in the field, leading to advancements in technology that benefit society as a whole.In conclusion, the polarized armature is a fundamental component in many electromagnetic devices, providing essential functionality that enhances performance and efficiency. Its application in various fields, from small toys to electric vehicles, demonstrates its versatility and importance. As technology continues to evolve, the study and development of polarized armature systems will undoubtedly play a crucial role in shaping the future of electrical engineering and sustainable energy solutions.

在电气工程领域，许多概念和组件对于理解设备的运作至关重要。其中一个重要概念是极化电枢，它在各种电磁设备中发挥着重要作用，尤其是在电动机和发电机中。要充分理解极化电枢的功能和重要性，有必要探讨其定义、操作和应用。极化电枢指的是具有特定磁方向的电枢。这种方向是通过使用永久磁铁或以特定方式排列绕组来实现的，从而产生明显的磁场。极化使得电枢能够有效地与由定子产生的磁场相互作用，增强设备的效率和性能。例如，在电动机中，极化电枢确保产生的扭矩最大化，从而实现更平稳、更强大的操作。极化电枢的操作基于电磁学原理。当电流流经电枢的绕组时，它会产生一个磁场，与来自定子的外部磁场相互作用。这种相互作用产生了一个力，使电枢旋转。电枢的极化至关重要，因为它决定了磁场的方向，进而影响旋转的方向。如果电枢没有正确极化，电动机可能会停滞或效率低下。极化电枢技术的应用可以在各种设备中找到，从小型家用电器到大型工业机器。例如，在玩具电动机中，极化电枢允许高效的能量转换，使玩具运行得更快、更久。在更大应用中，例如电动汽车，使用极化电枢可以显著提高车辆推进系统的整体效率，从而延长电池寿命并改善性能。此外，极化电枢的概念不仅限于电动机；它也适用于发电机。在发电机中，电枢在磁场中旋转，诱导出电流。电枢的极化确保产生的电流稳定且高效。这在可再生能源应用中尤为重要，因为最大化能量输出对可持续性至关重要。理解极化电枢的重要性不仅仅涉及其机械和电气特性。它还突显了物理学与工程学之间复杂的关系。工程师在设计中实施极化电枢时，必须考虑材料选择、设计和操作条件等因素。创造高效的极化电枢的挑战推动了该领域的创新，导致了造福整个社会的技术进步。总之，极化电枢是许多电磁设备中的基本组件，提供了增强性能和效率所需的基本功能。它在从小玩具到电动汽车等各个领域的应用展示了其多功能性和重要性。随着技术的不断发展，对极化电枢系统的研究和开发无疑将在塑造电气工程和可持续能源解决方案的未来中发挥关键作用。