servomotor

简明释义

英[ˈsɜːvəʊˌməʊtə]美[ˈsɜːrvoˈmotər]

n. 伺服电动机；继动器

英英释义

单词用法

同义词

反义词

例句

1.EH system oil servomotor is the most important part of EH control system.

EH系统油动机是EH控制系统的重要组成部分。

2.The control of azimuth Angle of electrohydraulic servomotor system, and the on-line and real-time test of the system performance were realized.

实现了用于方位角跟踪的电液伺服马达系统的控制，以及系统性能的在线实时测试。

3.The movement of the turning pairs and the swinging pairs of the joints and the worm of the clamping hand are respectively driven by one servomotor.

各关节的回转副和摆动副、以及夹持手的蜗杆的运动分别由一台伺服电机驱动。

4.A design method of a robust rotational velocity controller of water hydraulic servomotor was presented for the uncertain parameters and the load fluctuation.

针对液压伺服马达的参数不确定性以及负载转矩脉动等问题，提出了一种鲁棒转速控制器的设计方法。

5.Relating to the phenomenon of hydraulic servomotor swing with high magnitude during the operation of the turbine unit, the causes of swing were analysed.

针对机组运行中油动机发生大幅度摆动的现象，分析了产生摆动的原因。

6.A brush-less DC servomotor is used to drive the belt that drives the positive yarn feeders accurately.

采用一种无电刷的直流伺服电机来传动用于精确传动积极式喂纱器的皮带。

7.Rot of the work piece is assured by a SIEMENS brushless Digitally Controlled servomotor with infinitely variable speed.

工件的旋转，由西门子无刷数控伺服马达控制，它可以用不同速度运行。

8.The connecting rods between the guide vane servomotor piston rods and guide vane operating ring shall be of steel, with grease lubricated bearings.

导叶操作圆环将被设计接受导叶辅助电动机连接杆和别针在圆环的相反点。

9.The robot arm uses a servomotor to achieve precise movements.

机器人手臂使用伺服电机来实现精确的动作。

10.In CNC machines, a servomotor controls the position of the cutting tool.

在数控机床中，伺服电机控制切削工具的位置。

11.The drone's flight stability is enhanced by a high-performance servomotor.

无人机的飞行稳定性通过高性能的伺服电机得以增强。

12.A servomotor is essential for the accurate positioning of solar panels.

伺服电机对于太阳能电池板的精确定位至关重要。

13.The automation system relies on a servomotor for efficient operation.

自动化系统依赖于伺服电机来实现高效操作。

作文

In the world of automation and robotics, the term servomotor plays a crucial role in enhancing precision and control. A servomotor is a type of motor that is designed to provide precise control of angular or linear position, velocity, and acceleration. It is commonly used in various applications, including robotics, CNC machinery, and automated manufacturing systems. The functionality of a servomotor is based on the feedback mechanism, which allows it to adjust its performance based on the desired output. This capability makes it an essential component in modern engineering and technology. The operation of a servomotor typically involves a closed-loop system that includes a controller, a motor, and a feedback device, such as an encoder. The controller sends a command signal to the servomotor, which then moves to the specified position. The feedback device continuously monitors the position of the motor and sends this information back to the controller. If there is any discrepancy between the desired position and the actual position, the controller adjusts the input signal accordingly. This real-time adjustment ensures that the servomotor maintains high accuracy and responsiveness, making it ideal for applications where precision is paramount. One of the most significant advantages of using a servomotor is its ability to deliver high torque at low speeds. This characteristic is particularly beneficial in applications that require quick starts and stops, as well as smooth acceleration and deceleration. For instance, in robotic arms used in assembly lines, a servomotor can move the arm with great precision, allowing it to pick up and place components accurately without damaging them. Additionally, servomotors are available in various types, including AC and DC versions. Each type has its unique features and applications. AC servomotors are often preferred for applications requiring high speed and efficiency, while DC servomotors are favored for their simplicity and ease of control. Regardless of the type, the core principle remains the same: to provide precise control over movement. In conclusion, the significance of the servomotor in modern technology cannot be overstated. Its ability to perform with high accuracy and reliability makes it an indispensable tool in fields ranging from manufacturing to aerospace. As industries continue to evolve and demand greater levels of automation, the role of servomotors will only become more prominent. Understanding how a servomotor works and its applications can provide valuable insights into the future of engineering and technology. With ongoing advancements in electronics and control systems, we can expect servomotors to become even more sophisticated, further pushing the boundaries of what is possible in automation and robotics.

在自动化和机器人技术的世界中，术语伺服电机在提高精度和控制方面发挥着至关重要的作用。伺服电机是一种旨在提供角度或线性位置、速度和加速度的精确控制的电动机。它通常用于各种应用，包括机器人、数控机械和自动化制造系统。伺服电机的功能基于反馈机制，使其能够根据所需输出调整其性能。这种能力使其成为现代工程和技术中的重要组成部分。 伺服电机的操作通常涉及一个闭环系统，包括控制器、电动机和反馈装置，如编码器。控制器向伺服电机发送命令信号，后者移动到指定位置。反馈装置持续监测电动机的位置，并将此信息反馈给控制器。如果期望位置与实际位置之间存在任何差异，控制器会相应地调整输入信号。这种实时调整确保了伺服电机保持高精度和响应性，使其非常适合对精度要求极高的应用。 使用伺服电机的一个显著优势是它能够在低速下提供高扭矩。这一特性在需要快速启动和停止以及平稳加速和减速的应用中尤为有利。例如，在组装线中使用的机器人手臂中，伺服电机可以非常精确地移动手臂，使其能够准确地拾取和放置组件，而不会损坏它们。 此外，伺服电机可分为多种类型，包括交流和直流版本。每种类型都有其独特的特点和应用。交流伺服电机通常更适合需要高速度和效率的应用，而直流伺服电机因其简单性和易于控制而受到青睐。无论类型如何，其核心原理始终相同：提供对运动的精确控制。 总之，伺服电机在现代技术中的重要性不容低估。它以高精度和可靠性运作的能力使其成为制造业到航空航天等领域不可或缺的工具。随着工业的不断发展，对更高水平自动化的需求不断增加，伺服电机的作用只会变得更加突出。了解伺服电机的工作原理及其应用，可以为我们提供关于工程和技术未来的宝贵见解。随着电子和控制系统的持续进步，我们可以期待伺服电机变得更加复杂，进一步推动自动化和机器人技术的可能性。