wind bracing

简明释义

抗风支撑

英英释义

例句

1.In coastal areas, buildings often require wind bracing due to the risk of hurricanes.

在沿海地区，建筑物通常需要抗风支撑以应对飓风的风险。

2.The architect recommended wind bracing for the tall tower to prevent swaying during high winds.

建筑师建议为高塔设计抗风支撑以防止在强风中摇摆。

3.The engineers designed the building with wind bracing to ensure it could withstand strong storms.

工程师们设计了这座建筑，加入了抗风支撑以确保它能够承受强风暴。

4.During the construction, we installed wind bracing to enhance the structure's stability.

在施工过程中，我们安装了抗风支撑以增强结构的稳定性。

5.The contractor explained that wind bracing is crucial for the safety of the structure in windy conditions.

承包商解释说，在风大的条件下，抗风支撑对结构的安全至关重要。

作文

In the realm of architecture and engineering, structural integrity is paramount. One of the key concepts that ensures the stability of buildings and bridges is the technique known as wind bracing. This method involves the use of diagonal supports to counteract lateral forces caused by wind. When strong gusts blow against a structure, the force can create significant stress on its walls and foundations. Without adequate support, buildings may sway or even collapse under extreme conditions. Thus, understanding wind bracing is essential for architects and engineers alike.To illustrate the importance of wind bracing, let us consider a tall skyscraper in a bustling city. These towering structures are often designed with sleek glass facades that are aesthetically pleasing but can be vulnerable to wind forces. Engineers must incorporate wind bracing into their designs to ensure that the building can withstand the powerful winds that sweep through urban environments. The diagonal braces provide a counterforce, enabling the structure to remain upright and stable, ensuring the safety of its occupants.Moreover, wind bracing is not limited to tall buildings; it is also crucial in the construction of bridges. For example, suspension bridges rely heavily on wind bracing to maintain their shape and stability. The cables that hold up the bridge must be supported by diagonal braces to prevent swaying or twisting during high winds. Without these reinforcements, the structural integrity of the bridge could be compromised, leading to catastrophic failures.The implementation of wind bracing varies depending on the type of structure and the environmental conditions it faces. In regions prone to hurricanes or tornadoes, engineers may opt for more robust bracing systems to withstand the extreme forces of nature. Conversely, in areas with milder weather, lighter bracing may suffice. This adaptability highlights the importance of a thorough analysis of local conditions when designing structures.In addition to its practical applications, wind bracing also plays a role in sustainability. By ensuring that buildings and bridges can withstand high winds, engineers can reduce the need for extensive repairs and reconstruction after severe weather events. This not only saves resources but also minimizes the environmental impact associated with construction activities.In conclusion, wind bracing is a critical aspect of modern engineering that enhances the safety and durability of structures. Its ability to counteract lateral forces from wind makes it indispensable in the design of skyscrapers and bridges. As we continue to build taller and more complex structures, the significance of wind bracing will only grow. Understanding this concept is vital for anyone involved in the fields of architecture and engineering, as it directly influences the resilience of our built environment against the forces of nature.

在建筑和工程领域，结构完整性至关重要。确保建筑物和桥梁稳定性的关键概念之一是被称为风支撑的技术。这种方法涉及使用对角支撑来抵消由风造成的横向力。当强风吹袭建筑物时，这种力量可能会对其墙壁和基础施加显著压力。如果没有足够的支撑，建筑物可能会在极端条件下摇晃甚至倒塌。因此，理解风支撑对于建筑师和工程师来说都是至关重要的。为了说明风支撑的重要性，让我们考虑一座繁忙城市中的高层摩天大楼。这些高耸的建筑通常设计有光滑的玻璃外立面，虽然美观，但在风力下可能会变得脆弱。工程师必须将风支撑纳入设计中，以确保建筑能够承受席卷城市环境的强风。对角支撑提供了一种反作用力，使结构保持直立和稳定，确保居住者的安全。此外，风支撑不仅限于高层建筑；它在桥梁的建设中也至关重要。例如，悬索桥在维持其形状和稳定性方面严重依赖于风支撑。支撑桥梁的电缆必须通过对角支撑来防止在强风中摇摆或扭曲。如果没有这些加固，桥梁的结构完整性可能会受到损害，导致灾难性的失败。风支撑的实施因结构类型和面临的环境条件而异。在容易遭受飓风或龙卷风的地区，工程师可能会选择更坚固的支撑系统，以承受自然界的极端力量。相反，在气候较温和的地区，较轻的支撑可能就足够了。这种适应性突显了在设计结构时对当地条件进行彻底分析的重要性。除了其实际应用，风支撑在可持续性方面也发挥着作用。通过确保建筑和桥梁能够承受强风，工程师可以减少在严重天气事件后进行大量维修和重建的需要。这不仅节省资源，还最小化与建筑活动相关的环境影响。总之，风支撑是现代工程中一个关键的方面，增强了结构的安全性和耐用性。它抵消风的横向力量的能力使其在摩天大楼和桥梁设计中不可或缺。随着我们继续建造更高和更复杂的结构，风支撑的重要性只会增加。理解这一概念对于任何参与建筑和工程领域的人来说都是至关重要的，因为它直接影响到我们建成环境对自然力量的韧性。