armature coil

简明释义

1. 电枢绕组; 2. 电枢线圈;

英英释义

例句

1.An efficient armature coil (电枢线圈) design can significantly improve the performance of an electric vehicle.

高效的armature coil（电枢线圈）设计可以显著提高电动车的性能。

2.During maintenance, always check the armature coil (电枢线圈) for signs of wear and tear.

在维护过程中，始终检查armature coil（电枢线圈）是否有磨损迹象。

3.In a generator, the armature coil (电枢线圈) converts mechanical energy into electrical energy.

在发电机中，armature coil（电枢线圈）将机械能转换为电能。

4.The technician replaced the damaged armature coil (电枢线圈) in the electric motor to restore its functionality.

技术人员更换了电动机中损坏的armature coil（电枢线圈），以恢复其功能。

5.The resistance of the armature coil (电枢线圈) affects the overall efficiency of the motor.

电动机中的armature coil（电枢线圈）的电阻会影响整体效率。

作文

The concept of the armature coil is fundamental in the field of electrical engineering, particularly in the design and function of electric motors and generators. An armature coil can be defined as a wire coil that is wound around a core, which plays a crucial role in the generation of electromagnetic fields. This coil is typically situated within a magnetic field, and when an electric current passes through it, the interaction between the magnetic field and the current produces motion. This principle is the cornerstone of how many electrical devices operate today.In electric motors, the armature coil is responsible for converting electrical energy into mechanical energy. When the motor is powered, the current flows through the armature coil, creating a magnetic field around it. This magnetic field interacts with the permanent magnets or electromagnets in the motor, resulting in rotational motion. The efficiency and performance of the motor heavily depend on the design and quality of the armature coil. A well-designed coil will minimize energy loss and maximize torque output, making the motor more effective.Similarly, in generators, the armature coil serves a different yet equally important function. Instead of converting electrical energy into mechanical energy, generators work to convert mechanical energy into electrical energy. As the rotor spins, the armature coil moves through a magnetic field, inducing an electric current within the coil according to Faraday's law of electromagnetic induction. The number of turns in the armature coil, the strength of the magnetic field, and the speed at which the coil moves all influence the amount of electricity generated.Understanding the properties of the armature coil is vital for engineers who design these systems. Factors such as wire gauge, number of turns, and the type of core material can significantly impact the performance of both motors and generators. For instance, using a thicker wire may allow for more current to flow, but it also adds weight and reduces flexibility. Conversely, a higher number of turns in the coil can increase the voltage produced but may also lead to increased resistance and heat generation.Moreover, advancements in materials science have led to the development of better insulation and conductive materials, which further enhance the performance of the armature coil. Innovations such as superconductors are being explored to eliminate resistance altogether, potentially revolutionizing how we generate and use electrical energy.In conclusion, the armature coil is a critical component in both electric motors and generators, serving as the bridge between electrical energy and mechanical energy. Its design and functionality are paramount to the efficiency of these machines. As technology continues to evolve, understanding and optimizing the armature coil will remain essential for future developments in electrical engineering. Engineers and designers must continue to innovate and refine their approaches to harness the full potential of this vital component, ensuring that our reliance on electric power remains sustainable and efficient.

“电枢线圈”这一概念在电气工程领域中至关重要，尤其是在电动机和发电机的设计和功能方面。电枢线圈可以定义为绕在核心上的线圈，它在电磁场的生成中起着关键作用。该线圈通常位于磁场内，当电流通过它时，磁场与电流之间的相互作用产生运动。这一原理是许多电气设备今天运作的基石。在电动机中，电枢线圈负责将电能转换为机械能。当电动机通电时，电流流过电枢线圈，在线圈周围产生一个磁场。这个磁场与电动机中的永久磁铁或电磁铁相互作用，导致旋转运动。电动机的效率和性能在很大程度上取决于电枢线圈的设计和质量。设计良好的线圈将最小化能量损失并最大化扭矩输出，使电动机更有效。同样，在发电机中，电枢线圈也发挥着不同但同样重要的功能。发电机不是将电能转换为机械能，而是将机械能转换为电能。当转子旋转时，电枢线圈在磁场中移动，根据法拉第电磁感应定律在线圈内感应出电流。电枢线圈中的匝数、磁场的强度以及线圈移动的速度都会影响所产生的电量。理解电枢线圈的特性对设计这些系统的工程师至关重要。线径、匝数和核心材料的类型等因素都可能显著影响电动机和发电机的性能。例如，使用较粗的导线可能允许更多电流流动，但同时也增加了重量并降低了灵活性。相反，线圈中的匝数增加可以提高产生的电压，但也可能导致电阻和热量增加。此外，材料科学的进步导致更好的绝缘和导电材料的发展，进一步增强了电枢线圈的性能。诸如超导体等创新正在被探索，以消除电阻，可能会彻底改变我们生成和使用电能的方式。总之，电枢线圈是电动机和发电机中的关键组件，它在电能与机械能之间架起了桥梁。其设计和功能对于这些机器的效率至关重要。随着技术的不断发展，理解和优化电枢线圈将继续对电气工程的未来发展至关重要。工程师和设计师必须继续创新和完善他们的方法，以充分利用这一重要组件，以确保我们对电力的依赖保持可持续和高效。