elastic mounting of superstructures

简明释义

上层建筑弹性安装

英英释义

例句

1.With the elastic mounting of superstructures, the building was able to withstand strong winds without significant damage.

通过超构件的弹性安装，这座建筑能够在强风中保持结构完整而没有明显损坏。

2.The engineers discussed the benefits of elastic mounting of superstructures in reducing vibrations in tall buildings.

工程师们讨论了在高层建筑中采用超构件的弹性安装来减少振动的好处。

3.The design team implemented elastic mounting of superstructures to enhance the overall stability of the bridge.

设计团队实施了超构件的弹性安装以增强桥梁的整体稳定性。

4.In seismic zones, the elastic mounting of superstructures can help protect structures during an earthquake.

在地震带，超构件的弹性安装可以帮助保护建筑物在地震期间的安全。

5.The research focused on the effectiveness of elastic mounting of superstructures in modern construction.

该研究集中于超构件的弹性安装在现代建筑中的有效性。

作文

The concept of elastic mounting of superstructures is crucial in the field of civil engineering and architecture. This term refers to the method of supporting large structures, such as buildings and bridges, using flexible materials or systems that can absorb and dissipate energy. The importance of this technique cannot be overstated, especially in areas prone to seismic activity or extreme weather conditions. By allowing for some degree of movement, elastic mounting of superstructures helps to prevent catastrophic failures that could lead to significant loss of life and property.One of the primary advantages of the elastic mounting of superstructures is its ability to enhance the overall stability of a structure. Traditional methods often rely on rigid supports, which can become compromised during events like earthquakes. However, with elastic mounting, the flexibility of the materials allows the structure to sway and adapt to the forces acting upon it. This adaptability is essential in maintaining the structural integrity and safety of buildings, particularly high-rises that are more susceptible to lateral forces.In addition to seismic resilience, the elastic mounting of superstructures also plays a significant role in reducing vibrations caused by wind or traffic. For instance, tall buildings located in windy areas can experience oscillations that may lead to discomfort for occupants or even structural damage over time. By implementing elastic mounting techniques, engineers can mitigate these vibrations, ensuring a more comfortable and safer environment for everyone within the structure.Moreover, the application of elastic mounting of superstructures extends beyond just buildings. Bridges, for example, benefit greatly from this technology. The constant movement of vehicles and the dynamic loads imposed on bridges necessitate a design that can accommodate these changes without compromising safety. Elastic mounting systems can absorb shocks and distribute loads more evenly, prolonging the lifespan of the bridge and reducing maintenance costs.It is also worth noting that the materials used in the elastic mounting of superstructures have evolved significantly over the years. Modern engineering has introduced advanced polymers and composite materials that offer superior elasticity and durability compared to traditional options. These innovations not only improve performance but also contribute to sustainability efforts by reducing the need for frequent repairs and replacements.In conclusion, the elastic mounting of superstructures is an essential aspect of modern engineering that enhances the safety and durability of various structures. Its ability to absorb energy, reduce vibrations, and adapt to changing conditions makes it a vital consideration in the design and construction of buildings and bridges. As we continue to face challenges posed by natural disasters and environmental factors, the implementation of elastic mounting techniques will undoubtedly play a pivotal role in shaping resilient infrastructures for the future.

“超结构的弹性支撑”这一概念在土木工程和建筑领域至关重要。该术语指的是采用柔性材料或系统支撑大型结构（如建筑物和桥梁）的方法，这些材料或系统能够吸收和消散能量。这种技术的重要性不言而喻，特别是在地震活动频繁或极端天气条件下。通过允许一定程度的运动，“超结构的弹性支撑”有助于防止可能导致重大生命和财产损失的灾难性故障。“超结构的弹性支撑”的主要优点之一是增强结构的整体稳定性。传统方法通常依赖于刚性支撑，而在地震等事件中，这些支撑可能会受到损害。然而，通过弹性支撑，材料的灵活性使结构能够摇摆并适应作用于其上的力量。这种适应性对于维护建筑物的结构完整性和安全性至关重要，尤其是高层建筑更容易受到横向力的影响。除了抗震能力外，“超结构的弹性支撑”在减少因风或交通造成的振动方面也发挥着重要作用。例如，位于多风地区的高楼可能会经历摆动，这可能导致居住者的不适，甚至随时间推移导致结构损坏。通过实施弹性支撑技术，工程师可以减轻这些振动，确保为所有人提供更加舒适和安全的环境。此外，“超结构的弹性支撑”的应用不仅限于建筑物。桥梁，例如，极大地受益于这一技术。车辆的持续移动和施加在桥梁上的动态载荷需要一种能够适应这些变化而不妨碍安全的设计。弹性支撑系统能够吸收冲击并更均匀地分配载荷，从而延长桥梁的使用寿命并降低维护成本。还值得注意的是，近年来“超结构的弹性支撑”所使用的材料发生了显著变化。现代工程引入了先进的聚合物和复合材料，这些材料相比传统选项提供了更优越的弹性和耐久性。这些创新不仅提高了性能，还有助于可持续发展努力，减少了频繁维修和更换的需求。总之，“超结构的弹性支撑”是现代工程的一个基本方面，它增强了各种结构的安全性和耐久性。其吸收能量、减少振动和适应变化条件的能力使其成为建筑物和桥梁设计与施工中的重要考虑因素。随着我们继续面临自然灾害和环境因素带来的挑战，弹性支撑技术的实施无疑将在未来塑造具有韧性的基础设施方面发挥关键作用。