cantilever beam

简明释义

挑梁

英英释义

例句

1.The design of the cantilever beam (悬臂梁) allows for greater flexibility in architectural layouts.

cantilever beam（悬臂梁）的设计允许建筑布局有更大的灵活性。

2.The roof of the modern pavilion was constructed with a cantilever beam (悬臂梁) that extends outwards.

现代展馆的屋顶采用了一个向外延伸的cantilever beam（悬臂梁）建造。

3.The architect designed a stunning balcony using a cantilever beam (悬臂梁) to create an illusion of floating.

建筑师设计了一个令人惊叹的阳台，使用了一个cantilever beam（悬臂梁）来创造悬浮的错觉。

4.During the inspection, the engineer noted that the cantilever beam (悬臂梁) showed signs of stress.

在检查过程中，工程师注意到cantilever beam（悬臂梁）出现了应力迹象。

5.In civil engineering, a cantilever beam (悬臂梁) is often used in bridges to support the deck without additional supports.

在土木工程中，cantilever beam（悬臂梁）常用于桥梁，以支撑桥面而不需要额外的支撑。

作文

The concept of a cantilever beam is fundamental in the field of engineering and architecture. A cantilever beam is a beam that is fixed at one end and free at the other. This unique structure allows it to extend horizontally into space without any support at its free end. The design of a cantilever beam is crucial in various applications, from bridges to buildings, where overhanging structures are required. One of the most famous examples of a cantilever beam is the Frank Lloyd Wright-designed Fallingwater house, which dramatically extends over a waterfall. The engineering behind such structures involves understanding the forces acting on the cantilever beam. The weight of the beam itself, along with any additional loads, creates bending moments that must be calculated to ensure stability and safety. In civil engineering, the application of cantilever beams can be seen in the construction of balconies, bridges, and even large roofs. When designing a cantilever beam, engineers must consider several factors, including material strength, load capacity, and environmental conditions. Common materials used for cantilever beams include steel, concrete, and wood, each offering different advantages depending on the specific requirements of the project. The analysis of a cantilever beam involves applying principles of mechanics and physics. Engineers often use equations derived from static equilibrium to determine the reactions at the fixed support and the internal forces within the beam. Understanding how a cantilever beam behaves under load is essential for ensuring that structures remain safe and functional over time. In addition, the aesthetic appeal of cantilever beams cannot be overlooked. They allow architects to create visually striking designs that challenge traditional building forms. The combination of functionality and beauty makes the cantilever beam a popular choice in modern architecture. As technology advances, new materials and construction techniques are being developed, further enhancing the capabilities of cantilever beams. Innovations such as composite materials and advanced computational methods enable engineers to push the limits of what is possible with these structures. In conclusion, the cantilever beam is an essential component in both engineering and architecture, providing support and aesthetic value to a wide range of structures. Its ability to extend without support opens up new possibilities for design and functionality. As we continue to explore and innovate in this field, the importance of understanding the principles behind cantilever beams will only grow. Whether in the construction of bridges, homes, or commercial buildings, the cantilever beam remains a vital element that shapes our built environment.

悬臂梁的概念在工程和建筑领域中是基础性的。悬臂梁是一种一端固定而另一端自由的梁。这种独特的结构使其能够在没有任何支撑的情况下水平延伸到空间中。悬臂梁的设计在各种应用中至关重要，从桥梁到建筑物，都是需要悬挑结构的地方。最著名的一个例子是弗兰克·劳埃德·赖特设计的瀑布住宅，它戏剧性地延伸在瀑布上方。这种结构背后的工程涉及理解作用于悬臂梁上的力。梁自身的重量以及任何额外负载都会产生必须计算的弯矩，以确保其稳定性和安全性。在土木工程中，悬臂梁的应用可以在阳台、桥梁甚至大型屋顶的建造中看到。在设计悬臂梁时，工程师必须考虑多个因素，包括材料强度、承载能力和环境条件。常用的悬臂梁材料包括钢、混凝土和木材，每种材料根据项目的具体要求提供不同的优势。对悬臂梁的分析涉及应用力学和物理学的原理。工程师通常使用静力平衡推导出的方程来确定固定支撑处的反应和梁内的内部力。理解悬臂梁在负载下的行为对于确保结构在时间上保持安全和功能至关重要。此外，悬臂梁的美学吸引力也不容忽视。它们使建筑师能够创造视觉上引人注目的设计，挑战传统的建筑形式。功能与美的结合使得悬臂梁成为现代建筑中流行的选择。随着技术的进步，新材料和施工技术正在不断发展，进一步增强了悬臂梁的能力。复合材料和先进的计算方法等创新使工程师能够突破这些结构的可能性极限。总之，悬臂梁是工程和建筑中不可或缺的组成部分，为各种结构提供支持和美学价值。它能够在没有支撑的情况下延伸，为设计和功能开辟了新的可能性。随着我们继续探索和创新这一领域，理解悬臂梁背后的原理的重要性只会增加。无论是在桥梁、住宅还是商业建筑的建造中，悬臂梁始终是塑造我们建筑环境的重要元素。