armature-controlled motor
简明释义
电枢可控电动机
英英释义
例句
1.The technician explained how the armature-controlled motor 电枢控制电机 operates in various applications.
技术员解释了电枢控制电机 armature-controlled motor在各种应用中的工作原理。
2.The efficiency of an armature-controlled motor 电枢控制电机 makes it ideal for electric vehicles.
电枢控制电机 armature-controlled motor的高效率使其非常适合电动汽车。
3.In robotics, an armature-controlled motor 电枢控制电机 is often used for precise movements.
在机器人技术中,电枢控制电机 armature-controlled motor通常用于精确运动。
4.An armature-controlled motor 电枢控制电机 can be found in many household appliances like washing machines.
电枢控制电机 armature-controlled motor可以在许多家用电器中找到,比如洗衣机。
5.The design of the armature-controlled motor 电枢控制电机 allows for high torque at low speeds.
电枢控制电机 armature-controlled motor的设计允许在低速下产生高扭矩。
作文
In the realm of electrical engineering, various types of motors are utilized for different applications. One such motor that has gained prominence is the armature-controlled motor. This type of motor is particularly interesting because it operates based on the principle of controlling the armature's current to regulate the speed and torque of the motor. Understanding how an armature-controlled motor functions can provide insights into its advantages and applications in modern technology.The fundamental concept behind an armature-controlled motor lies in its construction. The motor consists of two main parts: the stator and the armature. The stator is the stationary part of the motor, while the armature is the rotating component that generates mechanical power. In this design, the armature winding is connected to a power source, allowing current to flow through it. By varying the voltage applied to the armature, engineers can control the speed of the motor.One of the primary benefits of using an armature-controlled motor is its ability to provide precise control over speed and torque. This feature makes it ideal for applications where accurate positioning is crucial, such as in robotics and automation. For instance, in robotic arms, an armature-controlled motor can adjust its speed to handle delicate tasks or increase torque when lifting heavy objects. This adaptability is essential for ensuring efficiency and safety in operations.Moreover, armature-controlled motors are known for their smooth operation. Unlike other motor types that may exhibit jerky movements, these motors can achieve gradual acceleration and deceleration. This characteristic is vital in applications like conveyor systems, where sudden changes in speed can lead to product damage or operational inefficiencies. The smooth operation of an armature-controlled motor contributes to the overall reliability of the system.Another significant advantage of armature-controlled motors is their compact size. Due to their design, they can be manufactured in smaller dimensions without compromising performance. This compactness allows for greater flexibility in design and installation, making them suitable for applications with limited space. For example, in electric vehicles, armature-controlled motors can be integrated into the vehicle's design without adding excessive weight or bulk.Despite their many advantages, armature-controlled motors do have some limitations. One notable drawback is their susceptibility to overheating. Since the armature carries the current, excessive load can cause it to heat up quickly, leading to potential damage. Therefore, engineers must carefully monitor the operating conditions to prevent overheating and ensure the longevity of the motor.In conclusion, the armature-controlled motor represents a significant advancement in motor technology. Its ability to provide precise control over speed and torque, coupled with its smooth operation and compact size, makes it a valuable asset in various industries. As technology continues to evolve, the demand for efficient and reliable motors like the armature-controlled motor will undoubtedly increase. Understanding the principles and applications of this motor type is essential for engineers and technicians working in the field of electrical engineering. With ongoing research and development, we can expect even more innovative uses for armature-controlled motors in the future.
在电气工程领域,各种类型的电动机被用于不同的应用。其中一种逐渐受到重视的电动机是电枢控制电动机。这种类型的电动机特别有趣,因为它的工作原理是通过控制电枢的电流来调节电动机的速度和扭矩。理解电枢控制电动机的工作方式可以为我们提供对其优势和现代技术应用的深入了解。电枢控制电动机的基本概念在于其结构。电动机主要由两个部分组成:定子和电枢。定子是电动机的静止部分,而电枢是旋转组件,负责产生机械动力。在这种设计中,电枢绕组连接到电源,使电流能够通过。通过改变施加到电枢上的电压,工程师可以控制电动机的速度。使用电枢控制电动机的主要好处之一是它能够精确控制速度和扭矩。这一特性使其成为在机器人技术和自动化等需要准确定位的应用中的理想选择。例如,在机器人手臂中,电枢控制电动机可以调整速度,以处理精细任务或在提升重物时增加扭矩。这种适应性对确保操作的效率和安全至关重要。此外,电枢控制电动机以其平稳的运行而闻名。与其他可能出现抖动运动的电动机类型不同,这些电动机能够实现逐渐加速和减速。这一特性在输送系统等应用中至关重要,因为速度的突然变化可能导致产品损坏或操作效率低下。电枢控制电动机的平稳运行有助于提高系统的整体可靠性。电枢控制电动机的另一个显著优势是其紧凑的尺寸。由于其设计,它们可以在不影响性能的情况下制造得更小。这种紧凑性允许在设计和安装中具有更大的灵活性,使其适合空间有限的应用。例如,在电动汽车中,电枢控制电动机可以无缝集成到车辆的设计中,而不会增加过多的重量或体积。尽管有许多优点,电枢控制电动机也存在一些局限性。其中一个显著的缺点是它们容易过热。由于电枢承载电流,过大的负载可能导致其迅速升温,从而导致潜在的损坏。因此,工程师必须仔细监测操作条件,以防止过热并确保电动机的使用寿命。总之,电枢控制电动机代表了电动机技术的重大进步。它能够精确控制速度和扭矩,加上平稳的运行和紧凑的尺寸,使其在各个行业中都成为有价值的资产。随着技术的不断发展,对高效、可靠的电动机(如电枢控制电动机)的需求无疑会增加。了解这种电动机类型的原理和应用对于在电气工程领域工作的工程师和技术人员至关重要。随着持续的研究和开发,我们可以期待在未来看到电枢控制电动机更具创新性的应用。
