amortisseur winding

简明释义

阻尼绕组

英英释义

例句

1.By adjusting the parameters of the amortisseur winding 阻尼绕组, we can optimize the performance of the machine.

通过调整 amortisseur winding 阻尼绕组 的参数，我们可以优化机器的性能。

2.In our latest design, we incorporated an amortisseur winding 阻尼绕组 to enhance stability during operation.

在我们最新的设计中，我们加入了一个 amortisseur winding 阻尼绕组 以增强操作过程中的稳定性。

3.The engineer explained how the amortisseur winding 阻尼绕组 helps in reducing vibrations in the motor.

工程师解释了如何通过 amortisseur winding 阻尼绕组 来减少电机中的振动。

4.The amortisseur winding 阻尼绕组 plays a crucial role in minimizing noise levels in transformers.

在变压器中，amortisseur winding 阻尼绕组 在降低噪音水平方面起着至关重要的作用。

5.The maintenance team checked the integrity of the amortisseur winding 阻尼绕组 during their routine inspection.

维护团队在例行检查中检查了 amortisseur winding 阻尼绕组 的完整性。

作文

The field of electrical engineering encompasses a vast array of concepts and components essential for the design and operation of electrical machines. One such component that plays a crucial role in enhancing the performance of synchronous machines is the amortisseur winding. This term refers to a specific type of winding used in the rotor of synchronous motors and generators, primarily designed to improve the machine's stability and efficiency during operation. Understanding the function and significance of the amortisseur winding is vital for anyone involved in the field of electrical engineering, especially those focusing on rotating machinery.To begin with, the amortisseur winding serves as a damping mechanism within synchronous machines. When these machines operate, they can experience oscillations or transient disturbances due to changes in load or system conditions. The amortisseur winding, typically made of conductive material, is strategically placed in the rotor and connected to the rotor's magnetic circuit. Its primary function is to dissipate the energy from these oscillations, thereby stabilizing the rotor's motion and preventing excessive vibrations that could lead to mechanical failure.Moreover, the amortisseur winding enhances the starting characteristics of synchronous machines. Unlike induction motors, synchronous motors require an external means to bring them up to synchronous speed. The presence of the amortisseur winding allows the rotor to develop a magnetic field quickly, facilitating a smoother transition to synchronous operation. This characteristic is especially beneficial in applications where rapid acceleration and deceleration are required.Additionally, the design of the amortisseur winding can vary based on the specific requirements of the machine. In some cases, it may consist of short-circuited coils that are placed along the rotor's surface. In other designs, the winding may be more complex, integrating multiple phases to enhance performance further. Regardless of the design, the fundamental purpose remains the same: to provide damping and improve operational stability.In practical applications, the benefits of incorporating amortisseur winding are evident in various industries. For instance, in hydroelectric power plants, synchronous generators equipped with amortisseur winding can maintain stable output despite fluctuations in water flow. Similarly, in industrial settings, synchronous motors with amortisseur winding can handle variable loads effectively, ensuring consistent performance without the risk of stalling.Furthermore, understanding the principles behind amortisseur winding contributes to advancements in electrical engineering research and development. As engineers continue to innovate and seek ways to enhance machine performance, the knowledge of how amortisseur winding functions will undoubtedly play a significant role in the evolution of electrical machinery.In conclusion, the amortisseur winding is a fundamental aspect of synchronous machines that significantly influences their performance and reliability. By providing damping, enhancing starting characteristics, and stabilizing operation, this winding type is essential for the effective functioning of various electrical machines. A comprehensive understanding of the amortisseur winding not only aids engineers in designing better machines but also ensures the longevity and efficiency of these critical components in the broader context of electrical engineering.

电气工程领域涵盖了众多概念和组件，这些概念和组件对于电动机和发电机的设计和运行至关重要。其中一个在提高同步机器性能方面发挥关键作用的组件是阻尼绕组。这个术语指的是一种特定类型的绕组，通常用于同步电动机和发电机的转子，主要旨在改善机器在运行过程中的稳定性和效率。理解阻尼绕组的功能和重要性，对于任何参与电气工程领域的人，尤其是专注于旋转机械的人来说都是至关重要的。首先，阻尼绕组作为同步机器中的一种阻尼机制。当这些机器运行时，由于负载或系统条件的变化，它们可能会经历振荡或瞬态干扰。阻尼绕组通常由导电材料制成，巧妙地放置在转子中并连接到转子的磁路。它的主要功能是消散这些振荡所产生的能量，从而稳定转子的运动，防止过度振动导致机械故障。此外，阻尼绕组增强了同步机器的起动特性。与感应电动机不同，同步电动机需要外部手段将其提升至同步速度。阻尼绕组的存在使得转子能够快速发展出磁场，促进平稳过渡到同步运行。这一特性在需要快速加速和减速的应用中尤为有益。此外，阻尼绕组的设计可以根据机器的具体要求而有所不同。在某些情况下，它可能由短路线圈组成，这些线圈沿着转子的表面放置。在其他设计中，绕组可能更复杂，集成多个相位以进一步增强性能。无论设计如何，其基本目的保持不变：提供阻尼并改善操作稳定性。在实际应用中，采用阻尼绕组的好处在各个行业中都显而易见。例如，在水电站中，配备阻尼绕组的同步发电机能够在水流波动的情况下保持稳定的输出。同样，在工业环境中，具有阻尼绕组的同步电动机能够有效处理可变负载，确保一致的性能，而不会面临停转的风险。此外，理解阻尼绕组背后的原理有助于电气工程研究和开发的进步。随着工程师不断创新，寻求提高机器性能的方法，对阻尼绕组功能的了解无疑将在电气机械的演变中发挥重要作用。总之，阻尼绕组是同步机器的一个基本方面，对其性能和可靠性有显著影响。通过提供阻尼、增强起动特性和稳定运行，这种绕组类型对于各种电气机器的有效运行至关重要。全面理解阻尼绕组不仅有助于工程师设计更好的机器，还确保了这些关键组件在电气工程更广泛背景下的长期使用和效率。