anchored tension cable

简明释义

1. 锚定拉张钢缆; 2. 锚定张力钢缆;

英英释义

例句

1.Engineers inspected the anchored tension cable system to prevent any structural failures.

工程师检查了锚固拉索系统，以防止任何结构性故障。

2.The anchored tension cable played a crucial role in maintaining the integrity of the tower.

这根锚固拉索在维持塔的完整性方面发挥了关键作用。

3.In mountainous areas, anchored tension cables are often used to secure slopes against landslides.

在山区，锚固拉索常用于固定斜坡以防止滑坡。

4.During the construction, workers installed the anchored tension cable to support the framework.

在施工过程中，工人们安装了锚固拉索以支撑框架。

5.The bridge was designed with an anchored tension cable to ensure stability during high winds.

这座桥的设计中使用了锚固拉索以确保在强风中保持稳定。

作文

In modern engineering, the concept of stability and support is crucial, especially in the construction of bridges and tall structures. One of the key components that provide this stability is the use of an anchored tension cable. An anchored tension cable is a type of cable that is secured at both ends to resist tensile forces. This design allows it to support heavy loads while maintaining structural integrity. The principle behind an anchored tension cable is relatively simple. When a load is applied to the cable, it experiences tension, which pulls on the anchors located at either end. These anchors are typically embedded in solid structures like concrete or rock, ensuring that the force exerted by the cable is effectively transferred to the ground. This method of anchoring is essential in applications such as suspension bridges, where the weight of the bridge deck and the dynamic forces from traffic must be managed. One of the most notable examples of the use of anchored tension cables can be seen in the Golden Gate Bridge in San Francisco. The bridge employs a series of cables that are anchored into massive concrete blocks at each end. These cables not only support the weight of the bridge but also help to stabilize it against strong winds and seismic activity. The engineering behind the Golden Gate Bridge showcases how anchored tension cables can be used to create structures that are both functional and aesthetically pleasing.In addition to bridges, anchored tension cables are also utilized in various other applications such as telecommunications towers, high-rise buildings, and even in the construction of large tents and canopies. In each of these cases, the cables play a vital role in maintaining the overall stability of the structure. For instance, in a tall building, anchored tension cables can be used to counteract the lateral forces caused by wind, ensuring that the building remains upright and secure.Moreover, the materials used for anchored tension cables have evolved significantly over the years. Traditionally, steel cables were the standard choice due to their high tensile strength and durability. However, advancements in material science have introduced synthetic fibers and composite materials that offer similar strength with reduced weight. This innovation has led to lighter and more efficient designs, making it easier to construct larger and more complex structures.Understanding the role of anchored tension cables in engineering not only highlights their importance in structural design but also illustrates the principles of physics at play. Tension, compression, and the transfer of forces are fundamental concepts that engineers must consider when designing safe and effective structures. As we continue to push the boundaries of architectural design and construction techniques, the use of anchored tension cables will undoubtedly remain a critical element in ensuring the safety and longevity of our built environment.In conclusion, the anchored tension cable is a vital component in modern engineering, providing the necessary support and stability for a variety of structures. Its application in iconic constructions like the Golden Gate Bridge serves as a testament to its effectiveness and versatility. As technology advances, the future of anchored tension cables looks promising, paving the way for even more innovative designs in architecture and engineering.

在现代工程中，稳定性和支撑的概念至关重要，尤其是在桥梁和高层建筑的建设中。提供这种稳定性的关键组件之一是使用锚固拉索。锚固拉索是一种在两端固定以抵抗拉力的电缆。这种设计使其能够在保持结构完整性的同时支持重载。锚固拉索背后的原理相对简单。当施加负载到电缆时，它会经历拉力，这会拉动位于两端的锚。这些锚通常嵌入坚固的结构中，如混凝土或岩石，确保电缆施加的力量有效地传递到地面。这种锚固方法在悬索桥等应用中至关重要，因为桥面和交通产生的动态力量必须得到管理。一个著名的例子是旧金山的金门大桥，它使用一系列锚固在每一端的大型混凝土块中的电缆。这些电缆不仅支持桥的重量，还帮助在强风和地震活动下稳定桥梁。金门大桥的工程展示了如何使用锚固拉索来创建既实用又美观的结构。除了桥梁，锚固拉索还被广泛应用于各种其他领域，如电信塔、高层建筑，甚至大型帐篷和遮阳篷的建造。在每一种情况下，这些电缆在维持结构的整体稳定性方面发挥着至关重要的作用。例如，在一栋高楼中，锚固拉索可以用来抵消风造成的横向力量，确保建筑保持直立和安全。此外，随着时间的推移，使用的锚固拉索材料也发生了显著变化。传统上，钢缆是标准选择，因为它们具有高拉伸强度和耐用性。然而，材料科学的进步引入了合成纤维和复合材料，这些材料在减轻重量的同时提供了类似的强度。这一创新使得更轻、更高效的设计成为可能，使得构建更大、更复杂的结构变得更容易。了解锚固拉索在工程中的作用不仅强调了它们在结构设计中的重要性，还说明了物理学原理的运作。拉力、压缩和力的传递是工程师在设计安全有效的结构时必须考虑的基本概念。随着我们不断突破建筑设计和施工技术的界限，锚固拉索的使用无疑将继续作为确保我们建筑环境安全和持久的重要元素。总之，锚固拉索是现代工程中的重要组成部分，为各种结构提供必要的支撑和稳定性。它在金门大桥等标志性建筑中的应用证明了其有效性和多功能性。随着技术的进步，锚固拉索的未来看起来充满希望，为建筑和工程领域的更多创新设计铺平了道路。