actuating mechanism

简明释义

传动机构

英英释义

例句

1.An efficient actuating mechanism can significantly improve the performance of the system.

高效的驱动机制可以显著提高系统的性能。

2.The engineers tested the actuating mechanism under various conditions to assess its reliability.

工程师们在不同条件下测试了驱动机制以评估其可靠性。

3.The actuating mechanism for the valve must be regularly maintained to ensure proper function.

阀门的驱动机制必须定期维护以确保正常功能。

4.In this design, the actuating mechanism is powered by a small electric motor.

在这个设计中，驱动机制由一个小电动机提供动力。

5.The robot's actuating mechanism allows it to move its arms with precision.

机器人的驱动机制使它能够精确地移动手臂。

作文

In the realm of engineering and automation, the concept of an actuating mechanism plays a crucial role in the functionality of various systems. An actuating mechanism refers to a device or component that converts energy into motion, enabling machines to perform specific tasks. This mechanism is essential in numerous applications, from simple household appliances to complex industrial machinery.To illustrate the importance of an actuating mechanism, consider the example of a robotic arm used in manufacturing. The robotic arm is equipped with several actuating mechanisms that allow it to move with precision and accuracy. These mechanisms may include electric motors, pneumatic cylinders, or hydraulic systems, each designed to provide the necessary force to manipulate objects. Without these actuating mechanisms, the robotic arm would be unable to perform its intended functions, such as assembling parts or packaging products.Moreover, actuating mechanisms are not limited to industrial applications; they are also found in everyday devices. For instance, the automatic door opener in a supermarket utilizes an actuating mechanism that detects the presence of a customer and activates the door to open. This simple yet effective use of technology enhances convenience for shoppers while ensuring smooth operation.The design and selection of an actuating mechanism depend on various factors, including the required speed, force, and type of motion. Engineers must carefully evaluate these parameters to choose the most suitable mechanism for the task at hand. For example, in applications where rapid movement is essential, electric motors might be preferred due to their quick response times. In contrast, for tasks requiring substantial lifting capacity, hydraulic systems could be the better choice due to their ability to generate high forces.Additionally, the integration of advanced technologies has led to the development of smarter actuating mechanisms. With the rise of automation and robotics, many modern systems now incorporate sensors and control algorithms that enhance the performance of these mechanisms. For instance, a robotic system may employ feedback loops to adjust the operation of its actuating mechanisms in real-time, allowing for greater accuracy and efficiency in completing tasks.In conclusion, the significance of actuating mechanisms cannot be overstated. They are vital components that enable machines and systems to operate effectively across various industries. Whether in manufacturing, transportation, or everyday life, actuating mechanisms facilitate movement and interaction with the environment. As technology continues to advance, the evolution of these mechanisms will undoubtedly lead to even more innovative applications and improvements in efficiency, ultimately shaping the future of automation and engineering.

在工程和自动化领域，驱动机制的概念在各种系统的功能中发挥着至关重要的作用。驱动机制是指将能量转化为运动的装置或组件，使机器能够执行特定任务。这种机制在许多应用中都是必不可少的，从简单的家用电器到复杂的工业机械。为了说明驱动机制的重要性，考虑制造业中使用的机器人手臂的例子。机器人手臂配备了多个驱动机制，使其能够精确而准确地移动。这些机制可能包括电动机、气动缸或液压系统，每种机制都旨在提供必要的力量以操作物体。如果没有这些驱动机制，机器人手臂将无法执行其预期功能，例如组装零件或包装产品。此外，驱动机制并不仅限于工业应用；它们也出现在日常设备中。例如，超市中的自动门开启器利用一种驱动机制，该机制检测到顾客的存在并激活门打开。这种简单而有效的技术使用提高了购物者的便利性，同时确保了顺畅的操作。驱动机制的设计和选择取决于多种因素，包括所需的速度、力量和运动类型。工程师必须仔细评估这些参数，以选择最适合当前任务的机制。例如，在快速运动至关重要的应用中，电动机可能更受青睐，因为其响应时间快。相比之下，对于需要大量提升能力的任务，液压系统可能是更好的选择，因为其能够产生高力量。此外，先进技术的融合导致了更智能的驱动机制的发展。随着自动化和机器人技术的兴起，许多现代系统现在集成了传感器和控制算法，以增强这些机制的性能。例如，机器人系统可能采用反馈回路实时调整其驱动机制的操作，从而在完成任务时实现更高的准确性和效率。总之，驱动机制的重要性不容小觑。它们是使机器和系统在各个行业有效运行的关键组件。无论是在制造、运输还是日常生活中，驱动机制都促进了与环境的运动和互动。随着技术的不断进步，这些机制的演变无疑将导致更具创新性的应用和效率提升，最终塑造自动化和工程的未来。