actuating arm

简明释义

驱动杆

英英释义

例句

1.The drone's actuating arm allows it to carry and deliver packages effectively.

无人机的驱动臂使其能够有效地携带和投递包裹。

2.In the assembly line, each machine is equipped with an actuating arm for handling components.

在装配线上，每台机器都配备有一个驱动臂来处理组件。

3.The robotic arm uses an actuating arm to pick up and place objects accurately.

机器人手臂使用一个驱动臂来准确地拾取和放置物体。

4.The actuating arm in the automated system helps in precise movements during the manufacturing process.

自动化系统中的驱动臂在制造过程中帮助实现精确的移动。

5.Engineers designed a new actuating arm that can extend and retract quickly.

工程师设计了一种新的驱动臂，可以快速伸缩。

作文

In the world of engineering and robotics, the term actuating arm refers to a mechanical component that plays a crucial role in the movement and operation of machines. An actuating arm is typically designed to convert energy into motion, allowing various devices to perform tasks that would otherwise be impossible or too labor-intensive for human operators. Understanding the function and significance of the actuating arm can enhance our appreciation of modern technology and its applications in daily life.The actuating arm is often found in robotic systems, where it serves as the limb that carries out specific actions. For instance, in an industrial robot, the actuating arm may be responsible for picking up objects, assembling parts, or performing intricate tasks with precision. The design of these arms can vary significantly, depending on the requirements of the task at hand. Some actuating arms are equipped with sensors and advanced control systems that enable them to adapt to their environment and execute complex movements.One of the key features of an actuating arm is its ability to provide force and motion through various methods, including hydraulic, pneumatic, or electric actuators. Hydraulic actuating arms utilize pressurized fluid to create movement, making them powerful and suitable for heavy-duty applications. On the other hand, pneumatic actuating arms use compressed air, which allows for faster movements but may not support as much weight. Electric actuating arms, often found in smaller robots, rely on electric motors to generate motion, offering precision and control.The integration of actuating arms into everyday devices is becoming increasingly common. For example, in the automotive industry, actuating arms are used in assembly lines to automate the manufacturing process. They help improve efficiency and reduce the risk of human error. Additionally, actuating arms are essential components in medical devices, such as robotic surgical systems, where they assist surgeons in performing delicate procedures with enhanced accuracy.Moreover, the concept of the actuating arm extends beyond industrial applications. In consumer electronics, we see actuating arms in devices such as drones and robotic vacuum cleaners. These products utilize the principles of actuating arms to navigate their environments, perform tasks autonomously, and respond to user commands. As technology continues to advance, the capabilities of actuating arms will likely expand, leading to even more innovative applications.Understanding the mechanics behind actuating arms also opens the door to exploring their potential future developments. Researchers are continually working on improving the efficiency, speed, and precision of these devices. Innovations in materials science, artificial intelligence, and machine learning are playing a significant role in enhancing the functionality of actuating arms. For instance, smart actuating arms that can learn from their environment and adjust their operations accordingly are already being developed, paving the way for more autonomous robotic systems.In conclusion, the actuating arm is a fundamental component in the realm of robotics and automation. Its ability to convert energy into motion allows machines to perform a wide range of tasks, from industrial applications to consumer products. As we continue to embrace technological advancements, the importance of understanding and optimizing actuating arms will only grow, shaping the future of how we interact with machines and the world around us.

在工程和机器人技术的世界中，术语actuating arm指的是一个机械组件，它在机器的运动和操作中扮演着至关重要的角色。actuating arm通常被设计为将能量转化为运动，使各种设备能够执行否则不可能或对人类操作员来说过于繁重的任务。理解actuating arm的功能和重要性可以增强我们对现代技术及其在日常生活中应用的欣赏。actuating arm通常出现在机器人系统中，它作为执行特定动作的肢体。例如，在工业机器人中，actuating arm可能负责拾取物体、组装零件或以精确的方式执行复杂的任务。这些臂的设计可能会根据手头任务的要求而有很大的不同。有些actuating arm配备传感器和先进的控制系统，使它们能够适应环境并执行复杂的运动。actuating arm的一个关键特征是它通过各种方法提供力量和运动，包括液压、气动或电动执行器。液压actuating arm利用加压流体产生运动，使其强大且适合重型应用。另一方面，气动actuating arm使用压缩空气，这使得运动更快，但可能无法承受太多重量。电动actuating arm，通常出现在较小的机器人中，依靠电动机产生运动，提供精度和控制。actuating arm的整合到日常设备中变得越来越普遍。例如，在汽车工业中，actuating arm用于自动化制造过程的装配线。它们帮助提高效率并减少人为错误的风险。此外，actuating arm是医疗设备的重要组成部分，例如机器人手术系统，在这些系统中，它们帮助外科医生以增强的准确性执行精细的手术。此外，actuating arm的概念超出了工业应用。在消费电子产品中，我们看到actuating arm出现在无人机和机器人吸尘器等设备中。这些产品利用actuating arm的原理来导航其环境、自动执行任务并响应用户命令。随着技术的不断进步，actuating arm的能力可能会扩展，导致更多创新的应用。理解actuating arm背后的机制也为探索其未来发展潜力打开了大门。研究人员正在不断努力提高这些设备的效率、速度和精度。材料科学、人工智能和机器学习的创新在增强actuating arm的功能方面发挥了重要作用。例如，能够从环境中学习并相应调整操作的智能actuating arm已经开始开发，为更自主的机器人系统铺平了道路。总之，actuating arm是机器人和自动化领域的基本组成部分。它将能量转化为运动的能力使机器能够执行广泛的任务，从工业应用到消费产品。随着我们继续接受技术进步，理解和优化actuating arm的重要性只会增加，塑造我们与机器及周围世界互动的未来。