stator

简明释义

英[ˈsteɪtə]美[ˈsteɪtər]

n. 固定片，定子

英英释义

单词用法

同义词

反义词

例句

1.VPI of stator , androtor dynamic balance .

定子真空浸漆，转子动平衡。

2.The function of voltage vectors on the stator flux and torque is investigated.

并且具体分析了电压矢量对转矩和磁链的作用。

3.The main products are: rotor blades, the stator, leaves and other parts.

主要产品有：叶片泵转子、定子、叶片及其它零件。

4.The synchronous hysteresis motor consists of a polyphase-wound stator and a magnetically hard rotor .

同步迟滞电动机由一个多相缠绕的定子和一个硬磁转子所组成。

5.Thus it is necessary to identify stator resistance on-line.

因此，非常有必要对定子电阻进行在线辨识。

6.Then how USM works and how the ellipse trace of particle on the surface of stator forms are analyzed.

接着分析了超声波电动机的工作原理和定子表面质点椭圆运动的形成机理。

7.Adjust the clearance between the stator and the rotor which should be equal everywhere.

调整定子与转子间的间隙，该间隙应处处相等。

8.Through the detection of the stator current, the control can confine the starting current within the allowable range.

控制器通过监测电机定子电流的大小，将其起动电流控制在允许的范围内。

9.Based on the analysis on cooling process of stator, basic assumption and boundary condition are presented.

通过对定子冷却的分析，提出了计算的基本假设和边界条件。

10.The design of the stator affects the overall efficiency of the motor.

定子的设计影响电动机的整体效率。

11.In a generator, the stator converts mechanical energy into electrical energy.

在发电机中，定子将机械能转换为电能。

12.The stator is the stationary part of an electric motor that generates a magnetic field.

电动机的定子是产生磁场的静止部分。

13.The coils in the stator create a rotating magnetic field.

定子中的线圈产生旋转磁场。

14.When troubleshooting, check the stator for signs of wear and tear.

在故障排除时，检查定子是否有磨损迹象。

作文

In the world of electrical engineering, the term stator refers to a crucial component found in electric motors and generators. The stator is the stationary part of these machines, playing a vital role in their operation. Understanding the function and importance of the stator can significantly enhance our knowledge of how electric machines work. To begin with, the stator consists of a series of coils or windings that are arranged around a central core. When an electric current is passed through these windings, it creates a magnetic field. This magnetic field interacts with the rotor, which is the rotating part of the machine, leading to motion. The design and configuration of the stator are critical as they determine the efficiency and performance of the motor or generator. One of the most common applications of the stator is in induction motors. In these motors, the stator generates a rotating magnetic field that induces current in the rotor, causing it to turn. The efficiency of this process largely depends on the design of the stator. For instance, a well-designed stator can minimize energy losses, leading to better performance and lower operational costs. Moreover, the stator is not only limited to motors but is also essential in generators. In generators, the stator converts mechanical energy into electrical energy. As the rotor spins inside the stator, it cuts through the magnetic lines of force created by the stator, inducing an electromotive force (EMF) and generating electricity. This principle is fundamental to many power generation systems used today. The materials used in the construction of the stator are also significant. Typically, the stator is made from laminated silicon steel to reduce eddy current losses. The lamination allows the stator to maintain its magnetic properties while minimizing energy loss due to heat. Additionally, the insulation materials used in the stator must withstand high temperatures and electrical stress to ensure longevity and reliability. Furthermore, advancements in technology have led to the development of smart stators equipped with sensors that monitor performance and detect potential issues before they become serious problems. These smart stators can provide valuable data that helps engineers optimize the performance of electric machines, ensuring they operate at peak efficiency. In conclusion, the stator is a fundamental component in the field of electrical engineering, with applications in both motors and generators. Its design, materials, and technological advancements play a significant role in the efficiency and performance of these machines. A deeper understanding of the stator allows us to appreciate the intricate workings of electric machines and their impact on modern technology. As we continue to innovate and improve these systems, the importance of the stator will undoubtedly remain a key focus in the pursuit of more efficient and sustainable energy solutions.

在电气工程的世界中，术语stator指的是电动机和发电机中的一个关键组件。stator是这些机器的固定部分，在其操作中起着至关重要的作用。理解stator的功能和重要性可以显著增强我们对电动机工作原理的认识。首先，stator由一系列线圈或绕组组成，这些线圈围绕着一个中心核心排列。当电流通过这些绕组时，它会产生一个磁场。这个磁场与转子相互作用，转子是机器的旋转部分，从而引发运动。stator的设计和配置至关重要，因为它们决定了电动机或发电机的效率和性能。stator最常见的应用之一是在感应电动机中。在这些电动机中，stator产生一个旋转磁场，诱导转子中产生电流，导致其旋转。这个过程的效率在很大程度上取决于stator的设计。例如，一个设计良好的stator可以最小化能量损失，从而提高性能并降低运营成本。此外，stator不仅限于电动机，还在发电机中至关重要。在发电机中，stator将机械能转换为电能。当转子在stator内部旋转时，它切割通过stator产生的磁力线，诱导出电动势（EMF），从而产生电力。这一原理是当今许多发电系统的基础。构成stator的材料也非常重要。通常，stator由层压硅钢制成，以减少涡流损失。层压使得stator能够保持其磁性，同时最小化由于热量造成的能量损失。此外，stator中使用的绝缘材料必须能够承受高温和电气压力，以确保其耐久性和可靠性。此外，技术的进步导致了智能stators的开发，这些stators配备了传感器，可以监测性能并在潜在问题变得严重之前检测到它们。这些智能stators可以提供有价值的数据，帮助工程师优化电动机的性能，确保它们在最佳效率下运行。总之，stator是电气工程领域的一个基本组件，在电动机和发电机中都有应用。其设计、材料和技术进步在这些机器的效率和性能中发挥着重要作用。对stator的深入理解使我们能够欣赏电动机的复杂工作原理及其对现代技术的影响。随着我们继续创新和改进这些系统，stator的重要性无疑将继续成为追求更高效和可持续能源解决方案的关键焦点。