servo

简明释义

英[ˈsɜːvəʊ]美[ˈsɜːrvoʊ]

n. 伺服；伺服系统；随动系统

n. （Servo）人名；（意、芬、葡）塞尔沃

复 数 s e r v o s

英英释义

单词用法

同义词

反义词

例句

1.The robot has 7-axis arms, each with a servo gripper for small-part handling.

该款机器人具有7轴手臂，每一个手臂都有一个用于操作细小部件的伺服爪。

2.One such means, which is very effective, is the geared or servo tab .

这类方法中的一种非常有效的方法是随动调整片或伺服调整片。

3.Remove longitudinal interlock servo motor.

拆下纵向互锁伺服电机。

4.Ac servo system in many performance is better than the stepping motor.

交流伺服系统在许多性能方面都优于步进电机。

5.And that parallel mode requires the servo system to have good speed stability to ensure invariable output of speed.

平行式要求伺服系统具有良好的速度稳定性，保证恒定的速度输出。

6.He is now working on novel servo mechanisms, the basic building blocks for robots.

他现在用的是新型伺服机械装置——机器人的基本组成部分。

7.Servo motor has small start frequency, can quickly from the lowest revolution accelerated to the rated speed.

伺服电机有很小的启动频率，能很快从最低转速加速到额定转速。

8.A dynamic design method of robust sliding mode controller in AC servo system is proposed in the paper.

文章提出了一种适用于交流伺服系统的鲁棒滑模控制器的动态设计方法。

9.The robot uses a servo to control its arm movements.

这个机器人使用一个伺服器来控制它的手臂运动。

10.In our drone, the servo adjusts the angle of the camera.

在我们的无人机中，伺服器调整摄像头的角度。

11.He replaced the faulty servo in his RC car.

他更换了遥控车中故障的伺服器。

12.The servo motor is essential for precise control in CNC machines.

伺服器电机在数控机床中对精确控制至关重要。

13.We need to calibrate the servo for better performance.

我们需要校准伺服器以获得更好的性能。

作文

In the world of engineering and robotics, the term servo refers to a type of motor that is used to provide precise control of angular or linear position, velocity, and acceleration. The servo system typically consists of a motor, a sensor for feedback, and a controller that adjusts the motor's output based on the sensor's input. This combination allows for highly accurate movements, which are crucial in applications such as robotics, aerospace, and manufacturing. For instance, when designing a robotic arm, engineers often rely on servo motors to achieve the desired range of motion and precision. Each joint of the robotic arm may be equipped with a servo motor that can rotate to specific angles, allowing the arm to perform complex tasks such as assembly, painting, or welding. The feedback from the sensors ensures that the arm moves exactly as intended, without overshooting or undershooting its target position. Moreover, servo systems are not limited to robotics; they are also widely used in remote-controlled vehicles. In these applications, servo motors control the steering mechanism, throttle, and other critical functions. The responsiveness of a servo motor can significantly enhance the performance of the vehicle, providing smoother and more accurate handling. The versatility of servo motors extends to consumer electronics as well. Many modern cameras use servo technology for autofocus systems, allowing the camera to quickly adjust the lens position to achieve sharp images. Similarly, drones utilize servo motors to control their flight surfaces, enabling stable and agile flight patterns. Understanding how servo systems work is essential for anyone interested in pursuing a career in engineering or technology. The principles of feedback control, which are fundamental to servo systems, can be applied to various fields beyond robotics, including automotive engineering, aerospace, and even home automation. For example, smart home devices may use servo motors to control blinds, doors, or other mechanical components, enhancing convenience and energy efficiency. In conclusion, the significance of servo technology cannot be overstated. Its applications are vast and varied, offering solutions that require precision and reliability. As technology continues to evolve, the demand for servo systems will likely increase, making it an important area of study for future engineers. Whether in robotics, automotive design, or consumer electronics, mastering the principles behind servo mechanisms will undoubtedly open up numerous opportunities for innovation and advancement in the field of engineering.

在工程和机器人领域，术语servo指的是一种电机，用于精确控制角度或线性位置、速度和加速度。servo系统通常由电机、反馈传感器和根据传感器输入调整电机输出的控制器组成。这种组合允许进行高度准确的运动，这在机器人技术、航空航天和制造等应用中至关重要。 例如，在设计机器人手臂时，工程师通常依靠servo电机来实现所需的运动范围和精度。机器手臂的每个关节可能配备一个servo电机，可以旋转到特定角度，使手臂能够执行复杂的任务，如组装、喷漆或焊接。传感器的反馈确保手臂按预期移动，不会超过或低于目标位置。 此外，servo系统不仅限于机器人；它们在遥控车辆中也被广泛使用。在这些应用中，servo电机控制转向机制、油门和其他关键功能。servo电机的响应能力可以显著提高车辆的性能，提供更平稳和更准确的操控。 servo电机的多功能性还扩展到消费电子产品。许多现代相机使用servo技术进行自动对焦系统，使相机能够快速调整镜头位置以获得清晰的图像。同样，无人机利用servo电机控制其飞行表面，实现稳定和敏捷的飞行模式。 理解servo系统的工作原理对于任何有兴趣从事工程或技术职业的人来说都是至关重要的。反馈控制的原则是servo系统的基础，可以应用于机器人技术以外的各种领域，包括汽车工程、航空航天，甚至家庭自动化。例如，智能家居设备可能使用servo电机来控制百叶窗、门或其他机械部件，提高便利性和能效。 总之，servo技术的重要性不容小觑。它的应用广泛而多样，提供需要精度和可靠性的解决方案。随着技术的不断发展，对servo系统的需求可能会增加，这使其成为未来工程师学习的重要领域。无论是在机器人、汽车设计还是消费电子产品中，掌握servo机制背后的原理无疑将为工程领域的创新和进步开辟众多机会。