discontinuous action servo-mechanism

简明释义

断续动作的伺服机构

英英释义

例句

1.By incorporating a discontinuous action servo-mechanism, the drone can execute complex maneuvers in tight spaces.

通过加入不连续动作伺服机制，无人机可以在狭小空间内执行复杂的机动。

2.The discontinuous action servo-mechanism is crucial for applications that require rapid changes in direction without losing precision.

不连续动作伺服机制对于需要快速改变方向而不失去精度的应用至关重要。

3.The engineers tested the discontinuous action servo-mechanism to ensure it could handle the stress of repeated use in high-speed environments.

工程师们测试了不连续动作伺服机制，以确保它能够承受高速度环境中重复使用的压力。

4.In our latest design, the discontinuous action servo-mechanism improves the speed of the assembly line by enabling quick start-stop operations.

在我们最新的设计中，不连续动作伺服机制通过实现快速的启停操作，提高了生产线的速度。

5.The robotic arm uses a discontinuous action servo-mechanism to perform precise movements, allowing it to pick and place objects efficiently.

这只机器人臂使用不连续动作伺服机制进行精确移动，使其能够高效地拾取和放置物体。

作文

In modern engineering, the concept of a discontinuous action servo-mechanism has gained significant attention due to its unique capabilities in controlling motion. Unlike continuous systems that operate in a smooth and steady manner, a discontinuous action servo-mechanism functions by executing movements in distinct steps or phases. This characteristic makes it particularly useful in applications where precise positioning is crucial, such as robotics, CNC machinery, and automated assembly lines.The fundamental principle behind a discontinuous action servo-mechanism lies in its feedback control system. This system continuously monitors the position and velocity of the mechanism's components and adjusts their movement accordingly. When the desired position is reached, the mechanism stops, creating a 'discontinuous' effect. This contrasts sharply with traditional servo mechanisms that maintain a continuous flow of motion.One of the primary advantages of using a discontinuous action servo-mechanism is its ability to enhance accuracy and repeatability in tasks. For instance, in robotic arms used for assembly, the precision of each movement can significantly impact the overall quality of the product being assembled. By employing a discontinuous action servo-mechanism, manufacturers can ensure that each component is placed exactly where it needs to be, reducing errors and increasing efficiency.Moreover, the energy consumption of a discontinuous action servo-mechanism can be lower than that of continuous systems. Since the mechanism only engages fully during specific actions, it can conserve energy during idle periods. This aspect is particularly beneficial in industries striving for sustainability and reduced operational costs.However, implementing a discontinuous action servo-mechanism does come with its challenges. Designing such systems requires careful consideration of the control algorithms and hardware components involved. Engineers must ensure that the transition between different states is smooth enough to avoid mechanical stress and potential failures. Additionally, the complexity of programming these systems can lead to longer development times compared to simpler continuous mechanisms.In conclusion, the discontinuous action servo-mechanism represents a fascinating area of study within the field of automation and robotics. Its ability to perform precise, stepwise movements opens up new possibilities for innovation in various industries. As technology continues to advance, the integration of discontinuous action servo-mechanisms into everyday applications will likely become more prevalent, paving the way for smarter and more efficient systems. The ongoing research and development in this area promise to unlock even greater potential, making it an exciting field for engineers and technologists alike.

在现代工程中，离散动作伺服机制的概念因其在控制运动方面的独特能力而受到广泛关注。与以平滑和稳定的方式操作的连续系统不同，离散动作伺服机制通过以明确的步骤或阶段执行运动来工作。这一特性使其在精确定位至关重要的应用中尤为有用，例如机器人技术、CNC机械和自动化装配线。离散动作伺服机制的基本原理在于其反馈控制系统。该系统不断监测机制组件的位置和速度，并相应地调整其运动。当达到所需位置时，机制停止，从而产生“离散”的效果。这与维持连续运动的传统伺服机制形成了鲜明对比。使用离散动作伺服机制的主要优点之一是它能够提高任务的准确性和重复性。例如，在用于装配的机器人手臂中，每个动作的精确度会显著影响所组装产品的整体质量。通过采用离散动作伺服机制，制造商可以确保每个组件放置在所需位置，从而减少错误并提高效率。此外，离散动作伺服机制的能耗可能低于连续系统。由于机制仅在特定动作期间完全参与，因此在空闲期间可以节省能源。这一方面对于追求可持续发展和降低运营成本的行业尤其有益。然而，实施离散动作伺服机制确实存在一些挑战。设计此类系统需要仔细考虑涉及的控制算法和硬件组件。工程师必须确保不同状态之间的过渡足够平滑，以避免机械应力和潜在故障。此外，编程这些系统的复杂性可能导致与简单连续机制相比更长的开发时间。总之，离散动作伺服机制代表了自动化和机器人领域内一个引人入胜的研究领域。其执行精确逐步运动的能力为各行各业的创新开辟了新的可能性。随着技术的不断进步，离散动作伺服机制在日常应用中的集成可能会变得更加普遍，为更智能、更高效的系统铺平道路。在这一领域的持续研究和开发承诺将解锁更大的潜力，使其成为工程师和技术人员都感到兴奋的领域。