moment resulting from sidesway

简明释义

侧倾力矩

英英释义

例句

1.To design a safer building, we must account for the moment resulting from sidesway during high winds.

为了设计更安全的建筑，我们必须考虑在强风下侧移产生的力矩。

2.The architect presented a model that showed the effects of moment resulting from sidesway on the overall design.

建筑师展示了一个模型，显示了侧移产生的力矩对整体设计的影响。

3.The engineer calculated the moment resulting from sidesway to ensure the structure's stability under lateral loads.

工程师计算了侧移产生的力矩以确保结构在侧向荷载下的稳定性。

4.During the simulation, the team observed the moment resulting from sidesway and its impact on the building's integrity.

在模拟过程中，团队观察到侧移产生的力矩及其对建筑完整性的影响。

5.Understanding the moment resulting from sidesway is crucial for earthquake-resistant design.

理解侧移产生的力矩对于抗震设计至关重要。

作文

In the field of structural engineering, understanding the forces and moments acting on a structure is crucial for its design and safety. One particular concept that often arises in discussions about stability is the moment resulting from sidesway (侧向摆动引起的力矩). This phenomenon occurs when a lateral force, such as wind or seismic activity, causes a building or structure to sway sideways. The analysis of this moment is essential for ensuring that structures can withstand unexpected lateral loads without collapsing.When engineers design tall buildings, they must consider various factors that contribute to the overall stability of the structure. One of these factors is the moment resulting from sidesway (侧向摆动引起的力矩). For instance, during an earthquake, buildings experience lateral forces that can lead to significant sway. If the structure is not designed to accommodate these forces, it may suffer from excessive deformation or even failure.To illustrate this point, let’s consider a tall skyscraper. As the wind blows against the building, it creates a lateral force that pushes the structure sideways. The response of the building to this force generates a moment resulting from sidesway (侧向摆动引起的力矩), which is calculated based on the height of the building, the magnitude of the wind force, and the stiffness of the structure. Engineers use this information to design bracing systems or dampers that can counteract the sway, thereby reducing the moment and ensuring the building remains stable.The importance of addressing the moment resulting from sidesway (侧向摆动引起的力矩) cannot be overstated. Inadequate consideration of this factor can lead to severe consequences. Historical examples, such as the collapse of the Tacoma Narrows Bridge in 1940, highlight the dangers of ignoring lateral forces. The bridge’s design did not account for aerodynamic forces, leading to an uncontrollable sway that ultimately resulted in its destruction. This incident serves as a reminder for engineers to thoroughly analyze all potential forces acting on a structure.In modern engineering practice, sophisticated software tools allow for detailed simulations of how structures respond to lateral forces. These tools help engineers visualize the moment resulting from sidesway (侧向摆动引起的力矩) and make informed decisions about design modifications. By integrating these advanced technologies into the design process, engineers can create safer and more resilient structures.In conclusion, the moment resulting from sidesway (侧向摆动引起的力矩) is a critical aspect of structural engineering that must be carefully considered during the design phase. As our cities continue to grow taller and more complex, the need for robust engineering solutions becomes increasingly vital. By understanding and addressing the challenges posed by lateral forces, engineers can ensure that our structures remain safe and functional, even in the face of natural disasters. The study of moments and forces will continue to evolve, but the fundamental principles surrounding the moment resulting from sidesway (侧向摆动引起的力矩) will always remain relevant in the pursuit of architectural integrity and safety.

在结构工程领域，理解作用于结构上的力和力矩对于其设计和安全至关重要。一个经常在稳定性讨论中出现的概念是侧向摆动引起的力矩。这种现象发生在横向力（如风或地震活动）导致建筑物或结构侧向摆动时。分析这一力矩对于确保结构能够承受意外的横向载荷而不倒塌是必不可少的。当工程师设计高层建筑时，必须考虑影响结构整体稳定性的各种因素。其中一个因素就是侧向摆动引起的力矩。例如，在地震期间，建筑物会受到横向力的影响，从而产生显著的摆动。如果结构没有设计成能够适应这些力，就可能会遭受过度变形甚至失败。为了说明这一点，让我们考虑一座高耸的摩天大楼。随着风吹向建筑物，会产生一种横向力，将结构向侧面推。建筑物对这一力的反应产生了侧向摆动引起的力矩，该力矩根据建筑物的高度、风力的大小和结构的刚度进行计算。工程师利用这些信息设计支撑系统或阻尼器，以抵消摆动，从而降低力矩，确保建筑物保持稳定。解决侧向摆动引起的力矩的重要性不容小觑。对这一因素的考虑不足可能会导致严重后果。历史上的例子，如1940年塔科马海峡大桥的倒塌，突显了忽视横向力的危险。这座桥的设计未能考虑空气动力学力，导致无法控制的摆动，最终导致其毁坏。这一事件提醒工程师必须全面分析作用于结构的所有潜在力。在现代工程实践中，复杂的软件工具允许对结构如何响应横向力进行详细模拟。这些工具帮助工程师可视化侧向摆动引起的力矩并就设计修改做出明智的决策。通过将这些先进技术整合到设计过程中，工程师可以创建更安全、更具韧性的结构。总之，侧向摆动引起的力矩是结构工程中的一个关键方面，必须在设计阶段仔细考虑。随着城市不断向更高和更复杂的方向发展，对强大工程解决方案的需求变得越来越重要。通过理解和应对横向力带来的挑战，工程师可以确保我们的结构在自然灾害面前仍然安全和功能正常。对力矩和力的研究将继续发展，但围绕侧向摆动引起的力矩的基本原则在追求建筑完整性和安全性时始终具有相关性。