suspension structural system

简明释义

悬浮结构系

英英释义

例句

1.The iconic Sydney Harbour Bridge utilizes a suspension structural system to connect both sides of the harbor.

标志性的悉尼港大桥利用悬索结构系统连接港口两侧。

2.The Golden Gate Bridge is a prime example of a suspension structural system that allows for long spans over water.

金门大桥是一个典型的悬索结构系统，可以跨越水域形成长跨度。

3.A well-designed suspension structural system can significantly reduce the sway of tall structures during strong winds.

设计良好的悬索结构系统可以显著减少高层建筑在强风中的摇摆。

4.Engineers often choose a suspension structural system for bridges because it can support heavy loads while minimizing material use.

工程师通常选择悬索结构系统用于桥梁，因为它可以在最小化材料使用的同时支持重载。

5.The suspension structural system in this building allows for large open spaces without the need for internal columns.

这栋建筑中的悬索结构系统允许大型开放空间，无需内部柱子。

作文

The concept of a suspension structural system is one of the most innovative and widely used designs in modern engineering. This system primarily relies on cables or ropes to support structures, allowing for longer spans and more flexible designs compared to traditional methods. The use of a suspension structural system can be seen in various applications, from bridges to large roofs and even in some high-rise buildings. One of the most iconic examples of a suspension structural system is the Golden Gate Bridge in San Francisco. This bridge uses massive cables to suspend the roadway, which allows it to stretch across the wide bay without the need for numerous supporting pillars. The ability to span such distances without interruptions is one of the key advantages of this system. It not only enhances the aesthetic appeal but also minimizes the impact on the environment below.In addition to its aesthetic benefits, a suspension structural system provides significant structural advantages. For instance, the tension in the cables allows the structure to distribute loads effectively. This means that forces acting on the structure, such as wind or earthquakes, are managed in a way that reduces stress on any single point. This characteristic makes suspension structural systems particularly suitable for areas prone to seismic activity.Moreover, the flexibility of a suspension structural system enables it to adapt to various environmental conditions. Unlike rigid structures that may suffer damage during extreme weather, suspension systems can sway and move, absorbing some of the energy generated by external forces. This adaptability is crucial for maintaining the integrity and longevity of the structure.However, designing a suspension structural system is not without its challenges. Engineers must carefully calculate the tension in the cables, the weight of the materials used, and the overall stability of the structure. Any miscalculation can lead to catastrophic failures, as seen in historical incidents where poorly designed suspension bridges collapsed under pressure. Therefore, rigorous testing and simulations are essential parts of the design process.In conclusion, the suspension structural system represents a remarkable achievement in engineering innovation. Its ability to create long spans with minimal supports while providing flexibility and strength makes it an ideal choice for various applications. As technology continues to advance, we can expect to see even more sophisticated designs and uses for suspension structural systems, pushing the boundaries of what is possible in structural engineering. Understanding the principles and applications of this system is essential for anyone interested in the field of architecture and civil engineering. The future of construction is undoubtedly linked to the continued evolution of suspension structural systems.

“悬索结构系统”的概念是现代工程中最具创新性和广泛应用的设计之一。该系统主要依靠电缆或绳索来支撑结构，与传统方法相比，允许更长的跨度和更灵活的设计。在各种应用中都可以看到“悬索结构系统”，从桥梁到大型屋顶，甚至一些高层建筑。“悬索结构系统”的一个标志性例子是旧金山的金门大桥。这座桥使用巨大的电缆悬挂路面，使其能够跨越宽阔的海湾，而无需多个支撑柱。没有中断地跨越如此大的距离是该系统的关键优势之一。它不仅增强了美学吸引力，还最小化了对下面环境的影响。除了美学优势外，“悬索结构系统”还提供了显著的结构优势。例如，电缆中的张力使结构能够有效分配负载。这意味着作用于结构的力量，例如风或地震，以一种减少任何单一点压力的方式进行管理。这一特性使得“悬索结构系统”特别适合于地震活动频繁的地区。此外，“悬索结构系统”的灵活性使其能够适应各种环境条件。与可能在极端天气下受损的刚性结构不同，悬索系统可以摇摆和移动，吸收外部力量产生的一部分能量。这种适应性对于保持结构的完整性和耐久性至关重要。然而，设计“悬索结构系统”并非没有挑战。工程师必须仔细计算电缆的张力、所用材料的重量以及结构的整体稳定性。任何错误计算都可能导致灾难性故障，正如历史上一些设计不良的悬索桥在压力下倒塌的事件。因此，严格的测试和模拟是设计过程的重要组成部分。总之，“悬索结构系统”代表了工程创新的卓越成就。其能够以最小的支撑创造长跨度，同时提供灵活性和强度，使其成为各种应用的理想选择。随着技术的不断进步，我们可以期待看到更复杂的设计和“悬索结构系统”的使用，推动结构工程可能性的边界。理解这一系统的原理和应用对于任何对建筑和土木工程领域感兴趣的人来说都是必不可少的。建筑的未来无疑与“悬索结构系统”的持续演变息息相关。