actuating mechanism
简明释义
收张机构;
英英释义
An actuating mechanism is a device or system that converts a control signal into a physical motion or action, often used to operate machinery or equipment. | 驱动机制是一种装置或系统,它将控制信号转换为物理运动或动作,通常用于操作机械或设备。 |
例句
1.The actuating mechanism 驱动机制 in this machine is responsible for its rapid movements.
这台机器中的actuating mechanism 驱动机制负责其快速运动。
2.The robot's actuating mechanism 驱动机制 allows it to move its arms with precision.
机器人的actuating mechanism 驱动机制使其能够精确地移动手臂。
3.Engineers are testing the actuating mechanism 驱动机制 of the robotic arm for better functionality.
工程师们正在测试机器人手臂的actuating mechanism 驱动机制以提高其功能性。
4.In the new car design, the actuating mechanism 驱动机制 for the convertible roof is more efficient.
在新车设计中,敞篷车顶的actuating mechanism 驱动机制更加高效。
5.The actuating mechanism 驱动机制 in this elevator ensures smooth and quiet operation.
这部电梯中的actuating mechanism 驱动机制确保了平稳和安静的运行。
作文
In the realm of engineering and mechanics, the term actuating mechanism refers to a system or device that converts energy into motion. This concept is fundamental in various applications, from simple household appliances to complex industrial machinery. Understanding how an actuating mechanism operates is crucial for engineers and technicians alike, as it plays a pivotal role in ensuring the functionality and efficiency of mechanical systems.An actuating mechanism typically consists of several components: a power source, a control system, and the actuator itself. The power source can be electrical, hydraulic, or pneumatic, depending on the application. For instance, in electric motors, electrical energy is converted into mechanical energy, which then drives the actuator. The control system dictates when and how the actuator should move, allowing for precise operations.One common example of an actuating mechanism is found in robotics. Robots often rely on these mechanisms to perform tasks such as lifting, moving, or manipulating objects. The actuators in robots can be servos, stepper motors, or hydraulic cylinders, each providing different levels of precision and power. The choice of an actuating mechanism greatly influences the robot's capabilities and performance.In automotive engineering, actuating mechanisms are also vital. For example, the braking system of a car uses hydraulic actuators to apply force to the brake pads, slowing down the vehicle. This demonstrates how critical actuating mechanisms are for safety and control in everyday vehicles. The efficiency of these systems directly impacts the overall performance of the vehicle, making it essential for engineers to design effective actuating mechanisms.Moreover, the aerospace industry heavily relies on actuating mechanisms for controlling aircraft systems. Flaps, slats, and landing gear all utilize these mechanisms to function correctly. For instance, the deployment of landing gear during landing involves a complex actuating mechanism that must operate flawlessly under various conditions. Any failure in this system could lead to catastrophic results, highlighting the importance of reliability in actuating mechanisms.As technology advances, the development of more sophisticated actuating mechanisms continues to evolve. Innovations such as smart actuators, which incorporate sensors and feedback systems, allow for enhanced control and adaptability in various applications. These advancements not only improve performance but also contribute to energy efficiency, which is increasingly important in today’s environmentally conscious world.In conclusion, the concept of actuating mechanism is integral to numerous fields, including robotics, automotive, and aerospace engineering. By converting energy into controlled motion, these mechanisms enable machines and systems to perform a wide array of functions. As we continue to innovate and improve these systems, understanding the principles behind actuating mechanisms will remain essential for engineers and designers striving to create efficient, reliable, and advanced technologies.
在工程和机械领域,术语actuating mechanism指的是将能量转化为运动的系统或装置。这个概念在各种应用中都是基础,从简单的家用电器到复杂的工业机械。理解actuating mechanism的工作原理对工程师和技术人员来说至关重要,因为它在确保机械系统的功能性和效率方面发挥着关键作用。一个actuating mechanism通常由几个组件组成:动力源、控制系统和执行器本身。动力源可以是电动的、液压的或气动的,具体取决于应用。例如,在电动机中,电能转化为机械能,驱动执行器。控制系统决定了执行器何时以及如何移动,从而实现精确操作。一个常见的actuating mechanism例子可以在机器人技术中找到。机器人通常依赖这些机制来执行诸如提升、移动或操纵物体等任务。机器人的执行器可以是伺服电机、步进电机或液压缸,每种提供不同水平的精度和动力。actuating mechanism的选择极大地影响了机器人的能力和性能。在汽车工程中,actuating mechanisms同样至关重要。例如,一辆车的制动系统使用液压执行器将力量施加到刹车片上,从而减缓车辆的速度。这表明actuating mechanisms对于日常车辆的安全性和控制有多么重要。这些系统的效率直接影响车辆的整体性能,因此工程师设计有效的actuating mechanisms是必不可少的。此外,航空航天工业也在重度依赖actuating mechanisms来控制飞机系统。襟翼、缝翼和起落架都利用这些机制正常运作。例如,着陆时起落架的展开涉及一个复杂的actuating mechanism,必须在各种条件下完美运行。该系统的任何故障都可能导致灾难性的后果,这突显了actuating mechanisms可靠性的重要性。随着技术的进步,更复杂的actuating mechanisms的发展也在不断演变。诸如智能执行器等创新,结合了传感器和反馈系统,允许在各种应用中增强控制和适应性。这些进步不仅提高了性能,还促进了能源效率,这在当今环保意识日益增强的世界中变得越来越重要。总之,actuating mechanism的概念在机器人技术、汽车和航空航天工程等多个领域都是不可或缺的。通过将能量转化为受控运动,这些机制使机器和系统能够执行各种功能。随着我们不断创新和改进这些系统,理解actuating mechanisms背后的原理将继续对努力创造高效、可靠和先进技术的工程师和设计师至关重要。
相关单词
