damp vibration

简明释义

阻尼振动

英英释义

例句

1.To reduce noise and damp vibration, the studio installed special soundproofing materials on the walls.

为了减少噪音和抑制振动，录音室在墙上安装了特殊的隔音材料。

2.The rubber feet on the table help to damp vibration from the nearby machinery.

桌子上的橡胶脚有助于抑制振动，防止附近机器的影响。

3.The engineers designed the new suspension system to effectively damp vibration in the vehicle, ensuring a smoother ride.

工程师们设计了新的悬挂系统，以有效地抑制振动，确保更平稳的驾驶体验。

4.In order to damp vibration during operation, the manufacturer added shock absorbers to the equipment.

为了在操作期间抑制振动，制造商在设备中添加了减震器。

5.The use of advanced materials can significantly damp vibration in aerospace applications.

在航空航天应用中，使用先进材料可以显著抑制振动。

作文

In the field of engineering and physics, the concept of vibration is crucial for understanding how structures respond to various forces. One important aspect of vibration analysis is the phenomenon known as damp vibration, which refers to the reduction of amplitude in oscillations due to energy dissipation. This energy dissipation can occur through various mechanisms such as friction, material properties, or external damping devices. Understanding damp vibration is essential for designing stable structures that can withstand dynamic loads, such as those caused by earthquakes or wind. When a structure vibrates, it often does so at specific frequencies known as natural frequencies. If the frequency of an external force matches one of these natural frequencies, resonance can occur, leading to excessive vibrations that may cause structural failure. Therefore, engineers must consider how to effectively manage damp vibration to enhance the longevity and safety of a structure. One common method to achieve this is through the use of damping materials, which are incorporated into the design of buildings and bridges. These materials absorb some of the energy from vibrations, thereby reducing the amplitude of oscillations. For example, rubber bearings are often used in bridge construction to allow for movement while simultaneously dampening vibrations caused by traffic or environmental factors. By implementing such solutions, engineers can significantly mitigate the effects of damp vibration on a structure's integrity. Moreover, the study of damp vibration extends beyond civil engineering; it is also relevant in mechanical systems, automotive engineering, and aerospace applications. In vehicles, for instance, engineers design suspension systems that not only support the weight of the car but also dampen vibrations from the road. This enhances passenger comfort and improves vehicle handling. Similarly, in aerospace applications, reducing damp vibration is critical for ensuring the stability of aircraft during flight, particularly in turbulent conditions. In conclusion, damp vibration plays a vital role in various engineering disciplines. By understanding and controlling this phenomenon, engineers can design safer and more efficient structures and systems. The ability to predict how different materials and designs will respond to vibrations allows for innovation in technology and infrastructure. Ultimately, effective management of damp vibration contributes to the resilience of our built environment, ensuring that it can withstand the challenges posed by nature and human activity. As we continue to advance in engineering practices, the importance of studying and applying the principles of damp vibration will only grow, paving the way for more robust and sustainable designs.

在工程和物理学领域，振动的概念对于理解结构如何响应各种力至关重要。振动分析中的一个重要方面是被称为damp vibration的现象，它指的是由于能量耗散而导致的振荡幅度的减少。这种能量耗散可以通过各种机制发生，例如摩擦、材料特性或外部阻尼装置。理解damp vibration对于设计能够承受动态载荷（例如地震或风引起的载荷）的稳定结构至关重要。当一个结构振动时，它通常以特定频率振动，这些频率被称为自然频率。如果外部力的频率与这些自然频率之一相匹配，就会发生共振，导致过度振动，这可能导致结构失败。因此，工程师必须考虑如何有效管理damp vibration以增强结构的耐久性和安全性。实现这一目标的一种常见方法是使用阻尼材料，这些材料被纳入建筑物和桥梁的设计中。这些材料吸收部分振动的能量，从而减少振荡的幅度。例如，橡胶支座通常用于桥梁建设，以允许运动，同时减弱由交通或环境因素引起的振动。通过实施这样的解决方案，工程师可以显著减轻damp vibration对结构完整性的影响。此外，damp vibration的研究不仅限于土木工程；它在机械系统、汽车工程和航空航天应用中也具有相关性。例如，在车辆中，工程师设计悬挂系统，不仅支持汽车的重量，还能减弱来自道路的振动。这增强了乘客的舒适度并改善了车辆的操控性。同样，在航空航天应用中，减少damp vibration对于确保飞机在飞行中的稳定性至关重要，特别是在湍流条件下。总之，damp vibration在各个工程学科中扮演着重要角色。通过理解和控制这一现象，工程师可以设计出更安全、更高效的结构和系统。预测不同材料和设计如何响应振动的能力为技术和基础设施的创新铺平了道路。最终，有效管理damp vibration有助于我们建成环境的韧性，确保其能够承受自然和人类活动带来的挑战。随着我们在工程实践中的不断进步，研究和应用damp vibration原理的重要性只会增加，为更强大和可持续的设计铺平道路。