deformation vibration

简明释义

形变振动

英英释义

例句

1.In mechanical systems, deformation vibration 变形振动 can lead to premature failure of components.

在机械系统中，变形振动 deformation vibration可能导致组件的过早失效。

2.The team used advanced sensors to monitor deformation vibration 变形振动 during the construction phase.

团队使用先进的传感器监测施工阶段的< span>变形振动 deformation vibration。

3.The research focused on how deformation vibration 变形振动 affects the performance of high-speed trains.

研究集中于< span>变形振动 deformation vibration如何影响高速列车的性能。

4.The engineer conducted tests to measure the effects of deformation vibration 变形振动 on the structural integrity of the bridge.

工程师进行了测试，以测量< span>变形振动 deformation vibration对桥梁结构完整性的影响。

5.To minimize deformation vibration 变形振动, engineers designed a new damping system for the machinery.

为了最小化< span>变形振动 deformation vibration，工程师为机器设计了一个新的阻尼系统。

作文

Deformation is a term that refers to the alteration of the shape or size of an object due to applied forces. In engineering and physics, understanding how materials deform under stress is crucial for ensuring the integrity and safety of structures. One important aspect of deformation is the phenomenon known as deformation vibration, which describes the oscillations that occur in a material when it undergoes deformation. These vibrations can significantly affect the performance and longevity of mechanical systems. When a structure is subjected to external loads, it may not only deform but also vibrate. This deformation vibration can result from a variety of factors, including the material properties, the geometry of the structure, and the nature of the applied forces. For instance, in bridges, the load from vehicles can induce both bending and vibrational modes, leading to complex interactions that engineers must account for in their designs.The study of deformation vibration is particularly important in fields such as aerospace, automotive, and civil engineering. In aircraft design, for example, engineers must consider how the wings will deform and vibrate during flight. If these vibrations exceed certain thresholds, they can lead to structural failure or reduced performance. Therefore, advanced modeling techniques and materials are employed to predict and mitigate the effects of deformation vibration.Similarly, in the automotive industry, the vibrations caused by the engine and road conditions can lead to wear and tear on various components. Engineers conduct extensive tests to measure deformation vibration and develop solutions that enhance the durability and reliability of vehicles. This includes using dampers and isolators to minimize the impact of vibrations on sensitive parts.In civil engineering, buildings and bridges are designed to withstand not just static loads but also dynamic forces such as wind and earthquakes. The deformation vibration of these structures during seismic events can be catastrophic if not properly managed. Engineers use sophisticated simulations to analyze how buildings will respond under different conditions, with the goal of minimizing damage and ensuring occupant safety.To effectively manage deformation vibration, researchers are continuously exploring new materials and technologies. For instance, smart materials that can adapt their properties in response to stress are being developed. These materials can potentially reduce vibrations and improve the overall performance of structures.In conclusion, the concept of deformation vibration is a critical consideration in various engineering disciplines. Understanding how materials behave under stress and how they vibrate is essential for designing safe and efficient structures. As technology advances, the ability to predict and control deformation vibration will continue to enhance the safety and performance of engineered systems, ultimately benefiting society as a whole.

变形是指物体因施加的力而改变形状或大小的术语。在工程和物理学中，理解材料在应力下如何变形对于确保结构的完整性和安全性至关重要。变形的一个重要方面是称为变形振动的现象，它描述了材料在发生变形时所产生的振荡。这些振动可能会显著影响机械系统的性能和寿命。当结构受到外部载荷时，它不仅可能变形，还可能振动。这种变形振动可以由多种因素引起，包括材料特性、结构几何形状和施加力量的性质。例如，在桥梁中，车辆的载荷可以引起弯曲和振动模式，从而导致复杂的相互作用，工程师必须在设计中考虑这些因素。变形振动的研究在航空航天、汽车和土木工程等领域尤为重要。例如，在飞机设计中，工程师必须考虑机翼在飞行过程中如何变形和振动。如果这些振动超过某个阈值，可能导致结构失效或性能下降。因此，采用先进的建模技术和材料来预测和减轻变形振动的影响。同样，在汽车工业中，发动机和道路条件引起的振动可能会导致各种组件的磨损。工程师进行广泛的测试以测量变形振动，并开发解决方案以增强汽车的耐用性和可靠性。这包括使用减震器和隔离器来最小化振动对敏感部件的影响。在土木工程中，建筑物和桥梁的设计不仅要承受静态载荷，还要承受风和地震等动态力。地震事件中这些结构的变形振动如果管理不当，可能会造成灾难性的后果。工程师使用复杂的模拟来分析建筑在不同条件下的响应，旨在最大限度地减少损坏，确保居住者的安全。为了有效管理变形振动，研究人员不断探索新材料和新技术。例如，正在开发能够根据应力调整其特性的智能材料。这些材料有可能减少振动并改善结构的整体性能。总之，变形振动的概念在各个工程学科中都是一个关键考虑因素。理解材料在应力下的行为及其振动方式对于设计安全高效的结构至关重要。随着技术的进步，预测和控制变形振动的能力将继续增强工程系统的安全性和性能，最终造福整个社会。