actuating mechanism

简明释义

执行机构

英英释义

例句

1.A hydraulic actuating mechanism is used in heavy machinery to lift and lower loads.

重型机械中使用液压执行机构来提升和降低负载。

2.In this engineering project, we need to design an actuating mechanism for the automated door system.

在这个工程项目中，我们需要为自动门系统设计一个执行机构。

3.The robot's movement is controlled by an actuating mechanism that translates electrical signals into physical motion.

机器人的运动由一个执行机构控制，该机构将电信号转换为物理运动。

4.The actuating mechanism of the valve is crucial for controlling fluid flow in the system.

阀门的执行机构对于控制系统中的流体流动至关重要。

5.The actuating mechanism in the printer allows it to move the print head accurately across the paper.

打印机中的执行机构使其能够准确地在纸张上移动打印头。

作文

The concept of an actuating mechanism is pivotal in the realm of engineering and automation. An actuating mechanism refers to a device that converts energy into motion, enabling systems to perform specific tasks. This mechanism can be found in various applications, from simple household appliances to complex industrial machines. Understanding how these mechanisms function is essential for anyone interested in mechanics or robotics.In everyday life, we encounter numerous examples of actuating mechanisms. For instance, consider the common electric fan. When you switch it on, electrical energy is converted into rotational motion through a motor, which acts as the actuating mechanism. This rotation causes the blades to spin, creating airflow that cools the surrounding environment. Similarly, in vehicles, the engine serves as an actuating mechanism that transforms fuel into kinetic energy, propelling the car forward.In industrial settings, actuating mechanisms are crucial for automation processes. Robotic arms, for example, utilize various types of actuating mechanisms to perform precise movements. These mechanisms can be hydraulic, pneumatic, or electric, each offering distinct advantages depending on the application. Hydraulic systems provide immense power and are often used in heavy machinery, while pneumatic systems are lighter and faster, making them suitable for tasks requiring quick responses. Electric actuators, on the other hand, are known for their accuracy and ease of control, making them ideal for applications like 3D printing.The design and selection of an appropriate actuating mechanism are critical for the efficiency and reliability of any system. Engineers must consider factors such as the required speed, load capacity, and energy consumption when choosing the right mechanism. A poorly chosen actuating mechanism can lead to inefficiencies, increased wear and tear, and ultimately, system failure.Moreover, advancements in technology have led to the development of smart actuating mechanisms. These mechanisms can be controlled remotely and can adapt to changing conditions in real-time. For instance, modern HVAC systems use smart actuators to regulate temperature based on occupancy and weather conditions, leading to significant energy savings.In conclusion, the actuating mechanism is an integral component of many systems we rely on daily. Its ability to convert energy into motion makes it indispensable in various fields, including engineering, manufacturing, and robotics. As technology continues to evolve, the role of actuating mechanisms will only become more prominent, paving the way for innovations that enhance efficiency and functionality across multiple industries. Understanding the principles behind these mechanisms not only enriches our knowledge but also empowers us to contribute to future advancements in technology.

“驱动机制”的概念在工程和自动化领域中至关重要。“驱动机制”是指将能量转化为运动的装置，使系统能够执行特定任务。这个机制可以在各种应用中找到，从简单的家用电器到复杂的工业机器。理解这些机制是如何运作的，对于任何对机械或机器人感兴趣的人来说都是必不可少的。在日常生活中，我们遇到许多“驱动机制”的例子。例如，考虑常见的电风扇。当你打开它时，电能通过电动机转化为旋转运动，这就是“驱动机制”。这种旋转使叶片旋转，创造出空气流动，冷却周围环境。类似地，在车辆中，发动机作为“驱动机制”，将燃料转化为动能，推动汽车前进。在工业环境中，“驱动机制”对自动化过程至关重要。例如，机器人手臂利用各种类型的“驱动机制”来执行精确的运动。这些机制可以是液压的、气动的或电动的，每种机制在不同应用中都有其独特的优势。液压系统提供巨大的动力，通常用于重型机械，而气动系统较轻且速度更快，适合需要快速响应的任务。另一方面，电动驱动器以其准确性和易于控制而闻名，非常适合3D打印等应用。选择合适的“驱动机制”的设计和选择对于任何系统的效率和可靠性至关重要。工程师在选择合适的机制时，必须考虑所需的速度、负载能力和能耗。不当选择的“驱动机制”可能导致效率低下、磨损加剧，最终导致系统故障。此外，技术的进步导致智能“驱动机制”的发展。这些机制可以远程控制，并能够实时适应变化的条件。例如，现代HVAC系统使用智能执行器根据占用情况和天气条件调节温度，从而显著节省能源。总之，“驱动机制”是我们日常生活中许多系统的重要组成部分。它将能量转化为运动的能力使其在工程、制造和机器人等多个领域不可或缺。随着技术的不断发展，“驱动机制”的角色将变得更加突出，为提高各个行业的效率和功能铺平道路。理解这些机制背后的原理不仅丰富了我们的知识，也使我们能够为未来技术的进步做出贡献。