tug arch

简明释义

拖缆承梁

英英释义

例句

1.In bridge construction, a tug arch 拉弓 can provide additional stability during high winds.

在桥梁建设中，tug arch 拉弓可以在强风中提供额外的稳定性。

2.The architect chose a tug arch 拉弓 style for the new building to enhance its aesthetic appeal.

建筑师选择了新的建筑采用tug arch 拉弓风格，以增强其美观性。

3.The engineer explained how the tug arch 拉弓 design helps distribute weight evenly across the structure.

工程师解释了如何通过tug arch 拉弓设计均匀分配结构的重量。

4.During the presentation, the team highlighted the benefits of using a tug arch 拉弓 in modern architecture.

在演示中，团队强调了在现代建筑中使用tug arch 拉弓的好处。

5.The tug arch 拉弓 technique is often used in large stadiums to support the roof structure.

在大型体育场中，通常使用tug arch 拉弓技术来支撑屋顶结构。

作文

In the world of engineering and architecture, various structures are designed to withstand different types of forces. One such concept is the tug arch, which plays a crucial role in the stability and strength of certain constructions. A tug arch can be defined as an arch structure that is primarily subjected to tensile forces, pulling it apart rather than compressing it. This unique characteristic allows it to distribute loads effectively, making it a preferred choice in specific architectural designs. The significance of the tug arch becomes evident when we consider its application in modern bridges and large buildings. In traditional arch designs, the weight of the structure is borne downwards, relying on compression to maintain stability. However, the tug arch utilizes tension, which can often lead to lighter and more efficient designs. By employing materials that can withstand tensile stress, engineers can create structures that are not only aesthetically pleasing but also functionally superior.Take, for example, the famous Sydney Harbour Bridge in Australia. While it is primarily known for its steel arch design, the principles behind the tug arch can be observed in how the bridge distributes the load across its structure. The cables that hold the bridge in place are under constant tension, showcasing the effectiveness of a tug arch system. This method of construction allows for longer spans without the need for excessive support columns, enabling a more open and inviting space beneath the bridge.Moreover, the use of tug arch designs extends beyond just bridges. In the field of sports architecture, stadiums often incorporate this principle to create expansive roof structures that can cover large areas without obstructing views. The tensioned fabric or cables used in these designs provide the necessary support while allowing light to filter through, enhancing the spectator experience.Despite its advantages, the tug arch also comes with challenges. Engineers must carefully calculate the forces at play to ensure that the materials used can handle the tension without failure. This requires advanced knowledge of material science and structural engineering principles. Additionally, because the tug arch relies heavily on tension, any failure in the supporting cables or materials can lead to catastrophic results, making safety a top priority during the design and construction phases.In conclusion, the tug arch represents a fascinating intersection of art and science in the field of architecture and engineering. Its ability to utilize tensile forces offers innovative solutions for creating strong, durable, and visually striking structures. As technology continues to advance, we can expect to see even more creative applications of the tug arch in future architectural marvels, pushing the boundaries of what is possible in construction. Understanding the principles behind the tug arch not only enriches our knowledge of engineering but also inspires us to appreciate the beauty and complexity of the structures that surround us.

在工程和建筑的世界中，各种结构被设计用来承受不同类型的力量。其中一个概念是拉拱，它在某些建筑物的稳定性和强度中发挥着至关重要的作用。拉拱可以定义为一种主要受到拉力作用的拱形结构，这种拉力使其向外拉伸，而不是压缩。这一独特特性使其能够有效地分配负载，使其成为特定建筑设计中的首选。 当我们考虑拉拱在现代桥梁和大型建筑中的应用时，其重要性变得显而易见。在传统的拱形设计中，结构的重量向下施加，依靠压缩来维持稳定。然而，拉拱利用张力，这通常会导致更轻便和高效的设计。通过使用能够承受拉应力的材料，工程师可以创建不仅美观而且功能优越的结构。 例如，澳大利亚著名的悉尼海港大桥就是一个很好的例子。虽然它以钢拱设计而闻名，但拉拱背后的原理可以在桥梁如何分配负载的方式中观察到。支撑桥梁的电缆始终处于张力之中，展示了拉拱系统的有效性。这种建筑方法允许更长的跨度，而无需过多的支撑柱，从而使桥下的空间更加开放和宜人。 此外，拉拱设计的应用超越了桥梁。在体育建筑领域，体育场通常采用这一原理来创建覆盖大面积而不阻碍视线的屋顶结构。这些设计中使用的张拉面料或电缆提供了必要的支撑，同时让光线透过，增强了观众的体验。 尽管有其优势，拉拱也伴随着挑战。工程师必须仔细计算所施加的力量，以确保所用材料能够承受张力而不发生故障。这需要对材料科学和结构工程原理有深入的了解。此外，由于拉拱在很大程度上依赖于张力，因此任何支撑电缆或材料的失效都可能导致灾难性的后果，这使得在设计和施工阶段安全成为重中之重。 总之，拉拱代表了建筑和工程领域艺术与科学的迷人交汇。它利用张力的能力为创建强大、耐用和视觉上引人注目的结构提供了创新的解决方案。随着技术的不断进步，我们可以期待在未来的建筑奇迹中看到更多创造性的拉拱应用，推动建筑可能性的边界。理解拉拱背后的原理不仅丰富了我们对工程的知识，还激励我们欣赏周围结构的美丽和复杂性。