armature winding

简明释义

1. 电枢绕组; 2. 电枢绕法;

英英释义

例句

1.The technician inspected the armature winding to ensure it was properly insulated.

技术人员检查了电枢绕组以确保其绝缘良好。

2.During maintenance, the engineer found that the armature winding was worn out.

在维护期间，工程师发现电枢绕组磨损严重。

3.To improve efficiency, we need to optimize the design of the armature winding.

为了提高效率，我们需要优化电枢绕组的设计。

4.A fault in the armature winding can lead to a significant drop in motor performance.

电枢绕组的故障可能导致电动机性能显著下降。

5.The armature winding must be connected correctly to avoid short circuits.

必须正确连接电枢绕组以避免短路。

作文

In the realm of electrical engineering, the concept of armature winding plays a crucial role in the functioning of various types of motors and generators. The armature winding refers to the component of an electric machine that carries the current and produces the magnetic field necessary for operation. This winding is typically made of insulated copper wire and is wound around a core, which can be made from various materials such as iron or steel. The design and configuration of the armature winding significantly affect the efficiency and performance of the machine.The primary function of the armature winding is to convert electrical energy into mechanical energy in motors, or vice versa in generators. In a motor, when electric current flows through the armature winding, it generates a magnetic field that interacts with the magnetic field produced by the stator, leading to motion. Conversely, in a generator, mechanical energy is converted back into electrical energy as the armature rotates within a magnetic field, inducing a current in the winding.One of the key aspects of armature winding is its arrangement. There are different types of windings, including lap winding and wave winding. Lap winding allows for a greater number of parallel paths for current, which can enhance the output current but may also lead to increased losses. On the other hand, wave winding provides a more uniform distribution of the magnetic field and can improve the overall efficiency of the machine.The choice of winding type depends on the specific application and requirements of the motor or generator. For instance, in high-power applications, lap winding might be preferred due to its ability to handle larger currents. In contrast, wave winding might be used in applications where efficiency and smooth operation are paramount.Moreover, the quality of the armature winding is essential for the longevity and reliability of the machine. Poorly executed windings can lead to issues such as overheating, short circuits, and reduced performance. Therefore, engineers must pay close attention to the materials used and the winding techniques employed during the manufacturing process.In addition to the technical aspects, understanding the armature winding also involves recognizing its importance in the broader context of electrical systems. As industries continue to evolve and demand more efficient and powerful machines, the design and implementation of armature winding will remain a critical area of research and development. Innovations in materials science and engineering techniques can lead to better-performing windings that contribute to the overall effectiveness of electric machines.In conclusion, the armature winding is a fundamental component in the operation of motors and generators, serving as the medium through which electrical energy is transformed into mechanical energy and vice versa. Its design, quality, and arrangement are vital for the performance and efficiency of electrical machines. As technology advances, the role of armature winding will continue to be a significant focus in the field of electrical engineering, driving innovations that enhance our energy systems and machinery.

在电气工程领域，绕组的概念在各种类型的电动机和发电机的运作中发挥着至关重要的作用。绕组指的是电机的组成部分，它携带电流并产生操作所需的磁场。这种绕组通常由绝缘铜线制成，并缠绕在一个核心上，该核心可以由铁或钢等多种材料制成。绕组的设计和配置显著影响机器的效率和性能。绕组的主要功能是将电能转换为电动机中的机械能，或在发电机中反之亦然。在电动机中，当电流通过绕组流动时，它会产生一个磁场，该磁场与定子产生的磁场相互作用，从而导致运动。相反，在发电机中，机械能在磁场中旋转时被转换回电能，从而在绕组中感应出电流。绕组的一个关键方面是其排列。有不同类型的绕组，包括交叉绕组和波形绕组。交叉绕组允许更多的电流并行路径，这可以增强输出电流，但也可能导致损耗增加。另一方面，波形绕组提供更均匀的磁场分布，可以提高机器的整体效率。绕组类型的选择取决于电动机或发电机的具体应用和要求。例如，在高功率应用中，可能更倾向于使用交叉绕组，因为它能够处理更大的电流。相比之下，在效率和顺畅运行至关重要的应用中，可能会使用波形绕组。此外，绕组的质量对机器的耐用性和可靠性至关重要。执行不当的绕组可能导致过热、短路和性能下降等问题。因此，工程师在制造过程中必须密切关注所使用的材料和采用的绕组技术。除了技术方面，理解绕组还涉及到认识到它在电气系统更广泛背景下的重要性。随着工业的不断发展，对更高效、更强大机器的需求不断增加，绕组的设计和实施将继续成为研究和开发的关键领域。材料科学和工程技术的创新可以导致更高性能的绕组，从而有助于电动机器的整体有效性。总之，绕组是电动机和发电机运作的基本组成部分，作为电能转化为机械能及其反向过程的媒介。其设计、质量和排列对电气机器的性能和效率至关重要。随着技术的进步，绕组的作用将继续在电气工程领域成为重要的关注点，推动提升我们能源系统和机械的创新。