dynamic compensating device

简明释义

动态补偿装置

英英释义

例句

1.The engineer designed a new dynamic compensating device to improve the stability of the aircraft during turbulence.

工程师设计了一种新的动态补偿装置，以提高飞机在颠簸中的稳定性。

2.In robotics, a dynamic compensating device is essential for maintaining balance while walking.

在机器人技术中，动态补偿装置对于在行走时保持平衡至关重要。

3.The dynamic compensating device helps to offset the vibrations produced by the machinery in the factory.

该动态补偿装置有助于抵消工厂内机器产生的振动。

4.The research team tested a dynamic compensating device that adjusts in real-time to environmental changes.

研究小组测试了一种能够实时适应环境变化的动态补偿装置。

5.To enhance the performance of the vehicle, a dynamic compensating device was integrated into the suspension system.

为了提升车辆性能，在悬挂系统中集成了一个动态补偿装置。

作文

In the realm of engineering and technology, the term dynamic compensating device refers to a sophisticated mechanism designed to adjust and balance various forces in real-time. These devices are crucial in applications where stability and precision are paramount, such as in aerospace, robotics, and automotive engineering. The primary function of a dynamic compensating device is to counteract any unwanted movements or disturbances that may affect the performance of a system. For instance, in an aircraft, the wings must remain stable despite turbulence; a dynamic compensating device can help maintain this stability by adjusting the wing's position in response to external forces.The concept of dynamic compensation is rooted in the principles of feedback control systems. These systems continuously monitor the output of a process and make necessary adjustments to ensure that the desired outcome is achieved. A dynamic compensating device employs sensors and actuators to detect deviations from the intended path and correct them instantaneously. This capability is essential in high-speed applications where even the slightest error can lead to catastrophic failures.One of the most notable examples of a dynamic compensating device can be found in modern robotic arms used in manufacturing. These arms must perform intricate tasks with high precision, often in environments where they encounter unexpected obstacles. By utilizing dynamic compensating devices, these robotic systems can adjust their movements on-the-fly, ensuring that they do not collide with other objects and can complete their tasks efficiently.Moreover, the importance of dynamic compensating devices extends beyond industrial applications. In the field of civil engineering, structures such as bridges and skyscrapers are increasingly equipped with these devices to enhance their resilience against environmental forces like wind and earthquakes. For example, base isolation systems are a type of dynamic compensating device that allows a building to move independently of ground motion during seismic events, significantly reducing the risk of damage.The development of dynamic compensating devices has been greatly influenced by advances in materials science and computer technology. Innovations in lightweight materials allow for the creation of more efficient devices that can respond faster and with greater accuracy. Additionally, the integration of artificial intelligence into these systems enables them to learn from past experiences and improve their performance over time.In conclusion, the role of dynamic compensating devices in modern engineering cannot be overstated. They provide essential support in maintaining stability and precision across various applications, from aerospace to civil engineering. As technology continues to evolve, we can expect to see even more sophisticated dynamic compensating devices that will push the boundaries of what is possible in engineering design. Understanding the functionality and significance of these devices is crucial for anyone involved in technical fields, as they represent the intersection of innovation and practical application, ultimately leading to safer and more efficient systems.

在工程和技术领域，术语动态补偿装置指的是一种复杂的机制，旨在实时调整和平衡各种力量。这些装置在航空航天、机器人和汽车工程等需要稳定性和精确性的应用中至关重要。动态补偿装置的主要功能是抵消可能影响系统性能的任何不必要的运动或干扰。例如，在飞机中，机翼必须在气流不稳定时保持稳定；动态补偿装置可以通过根据外部力量调整机翼的位置来帮助维持这种稳定性。动态补偿的概念根植于反馈控制系统的原理。这些系统持续监测过程的输出，并进行必要的调整，以确保实现所需的结果。动态补偿装置利用传感器和执行器来检测偏离预期路径的情况，并即时进行修正。这种能力在高速应用中至关重要，因为即使是最微小的错误也可能导致灾难性的故障。一个显著的例子是现代制造业中使用的机器人手臂。这些手臂必须以高精度执行复杂任务，通常在遇到意外障碍物的环境中。通过利用动态补偿装置，这些机器人系统可以随时调整其运动，确保它们不会与其他物体碰撞，并能够高效地完成任务。此外，动态补偿装置的重要性不仅限于工业应用。在土木工程领域，桥梁和摩天大楼等结构越来越多地配备这些装置，以增强它们对风和地震等环境力量的抗御能力。例如，基础隔离系统是一种动态补偿装置，允许建筑物在地震事件中独立于地面运动，从而显著降低受损风险。动态补偿装置的发展受到材料科学和计算机技术进步的极大影响。轻质材料的创新使得创建更高效的装置成为可能，这些装置能够更快、更准确地响应。此外，将人工智能集成到这些系统中，使它们能够从过去的经验中学习并随着时间的推移提高性能。总之，动态补偿装置在现代工程中的作用不可低估。它们为维护各类应用的稳定性和精确性提供了必要的支持，从航空航天到土木工程。随着技术的不断进步，我们可以期待看到更复杂的动态补偿装置，它们将推动工程设计的可能性界限。理解这些装置的功能和意义对任何从事技术领域的人来说都是至关重要的，因为它们代表了创新与实际应用的交汇，最终导致更安全和更高效的系统。