vibration control

简明释义

振动控制

英英释义

例句

1.For better performance, the machinery was equipped with advanced vibration control systems.

为了更好的性能，机械设备配备了先进的振动控制系统。

2.Our team developed a new algorithm for vibration control in robotic arms.

我们的团队开发了一种新的算法用于机器臂的振动控制。

3.In seismic design, vibration control is crucial for the safety of tall buildings.

在抗震设计中，振动控制对高层建筑的安全至关重要。

4.The engineers implemented vibration control to reduce noise in the new building.

工程师们实施了振动控制以减少新建筑中的噪音。

5.The research focused on the effectiveness of vibration control in reducing structural damage.

研究集中于振动控制在减少结构损坏方面的有效性。

作文

In today's fast-paced world, the importance of technology cannot be overstated. One significant aspect of engineering that has gained attention is vibration control. This term refers to the techniques and methods used to reduce or eliminate unwanted vibrations in structures and mechanical systems. Vibration control is crucial in various fields, including civil engineering, aerospace, automotive, and manufacturing. Understanding this concept can lead to improved safety, comfort, and durability in many applications.Vibrations occur naturally in many systems due to external forces, such as wind, earthquakes, or machinery operation. These vibrations can lead to structural damage, discomfort for occupants, and reduced performance of mechanical systems. Therefore, implementing effective vibration control strategies is essential to mitigate these issues.One common method of vibration control is the use of dampers. Dampers are devices designed to absorb and dissipate vibrational energy. For example, in buildings, tuned mass dampers can be installed at the top of skyscrapers to counteract wind-induced vibrations. By adjusting the mass and stiffness of the damper, engineers can tune it to the specific frequency of the building's sway, effectively reducing the amplitude of the vibrations.Another approach to vibration control involves isolating the source of the vibrations. Vibration isolation systems can be employed to separate sensitive equipment from the ground or other vibrating structures. For instance, in laboratories where precision instruments are used, isolation pads or mounts can prevent vibrations from affecting the measurements, ensuring accurate results.Moreover, active vibration control systems have emerged as advanced solutions. These systems utilize sensors and actuators to detect and counteract vibrations in real-time. By continuously monitoring the vibrational behavior, active systems can apply forces to negate the unwanted movements. This technology is particularly beneficial in aerospace applications, where maintaining stability is critical during flight.The significance of vibration control extends beyond engineering; it also impacts everyday life. In vehicles, for instance, effective vibration control enhances ride comfort and reduces wear on components. Automotive engineers design suspension systems that absorb road imperfections, providing a smoother driving experience. Similarly, in consumer electronics, vibration control is employed to ensure that devices like smartphones and gaming consoles function optimally without interference from vibrations.As technology advances, the field of vibration control continues to evolve. Researchers are exploring new materials and innovative designs to enhance the effectiveness of vibration control systems. For example, metamaterials—engineered materials with unique properties—show promise in creating highly efficient vibration absorbers.In conclusion, vibration control is a vital aspect of modern engineering that plays a crucial role in ensuring safety, comfort, and efficiency across various industries. By employing techniques such as damping, isolation, and active control, engineers can effectively manage vibrations and enhance the performance of structures and systems. As we continue to innovate and develop new technologies, the importance of vibration control will only grow, making it an essential area of study for future engineers and researchers.

在当今快节奏的世界中，科技的重要性不容小觑。工程学中一个重要的方面是振动控制。这个术语指的是用于减少或消除结构和机械系统中不必要振动的技术和方法。振动控制在土木工程、航空航天、汽车和制造等多个领域都至关重要。理解这一概念可以提高许多应用的安全性、舒适性和耐用性。振动在许多系统中自然发生，原因包括外力，如风、地震或机械操作。这些振动可能导致结构损坏、居住者不适以及机械系统性能下降。因此，实施有效的振动控制策略对减轻这些问题至关重要。一种常见的振动控制方法是使用阻尼器。阻尼器是设计用于吸收和耗散振动能量的装置。例如，在建筑物中，可以在摩天大楼顶部安装调谐质量阻尼器，以抵消风引起的振动。通过调整阻尼器的质量和刚度，工程师可以将其调谐到建筑物摇摆的特定频率，从而有效降低振动幅度。另一种振动控制的方法是隔离振动源。振动隔离系统可以用于将敏感设备与地面或其他振动结构分开。例如，在使用精密仪器的实验室中，隔离垫或支架可以防止振动影响测量，确保结果准确。此外，主动振动控制系统作为先进解决方案应运而生。这些系统利用传感器和执行器实时检测和对抗振动。通过持续监测振动行为，主动系统可以施加力量以抵消不必要的运动。这项技术在航空航天应用中尤为重要，因为在飞行过程中保持稳定至关重要。振动控制的重要性不仅限于工程，它也影响着日常生活。例如，在车辆中，有效的振动控制提高了乘坐舒适性并减少了组件磨损。汽车工程师设计悬挂系统以吸收路面的不平整，提供更平稳的驾驶体验。同样，在消费电子产品中，振动控制被用于确保智能手机和游戏机等设备在不受振动干扰的情况下正常工作。随着技术的进步，振动控制领域不断发展。研究人员正在探索新材料和创新设计，以增强振动控制系统的有效性。例如，超材料——具有独特属性的工程材料——在创建高效的振动吸收器方面显示出前景。总之，振动控制是现代工程中的一个重要方面，在确保各个行业的安全、舒适和效率方面发挥着关键作用。通过采用阻尼、隔离和主动控制等技术，工程师能够有效管理振动，提升结构和系统的性能。随着我们继续创新和开发新技术，振动控制的重要性只会增加，使其成为未来工程师和研究人员研究的关键领域。