cantilever

简明释义

英[ˈkæntɪliːvə(r)]美[ˈkæntɪliːvər]

n. 悬臂

复 数 c a n t i l e v e r s

第 三 人 称 单 数 c a n t i l e v e r s

现 在 分 词 c a n t i l e v e r i n g

过 去 式 c a n t i l e v e r e d

过 去 分 词 c a n t i l e v e r e d

英英释义

单词用法

同义词

反义词

例句

1.Large green roofs cantilever to create sun animated shadows that help generate this oasis feel.

巨大绿色悬臂屋顶创造了活泼的太阳影子，产生了舒服的感觉。

2.This article introduces a cantilever rotary drum resistance furnace, including its structure, effectiveness and prospects in application.

本文介绍了悬臂滚筒式电阻炉的结构特点，使用效果，以及应用前景。

3.The cantilever of the amphitheater clearly designates a protected entry.

露天剧场的悬梁明显地指定为一个受保护的入口。

4.Wrinkling characteristics of a conical inflated cantilever beam under bending is analyzed based upon the membrane theory.

该文基于薄膜理论分析了受弯充气锥台的褶皱特性。

5.For its first aircraft Beriev chose a scheme of the single-cantilever monoplane with two-step boat, which had a large cross-deadrise.

别里耶夫为它的这个首个作品选择了悬臂式上单翼和双阶船身的结构，后者具有较大的横截面。

6.Gradually, as cantilever monoplanes proved their efficiency, less economical designs were discarded, and aircraft took on a more stereotyped look.

随着悬臂单翼机的效率被证实，不经济的设计逐渐被淘汰，飞机呈现出一种陈规的外型。

7.You can see the series of arches that are supporting this cantilever.

你可以看到支撑这个悬臂的一系列拱廊。

8.The heavy build of the EXE cantilever-bed lathe is evident from this picture.

沉重的EXE文件建立悬臂梁床车床于此可见图片。

9.To construct as or in the manner of a cantilever.

作为一条悬臂或以悬臂的方式建造。

10.The architect designed a stunning balcony that extends out from the building using a cantilever.

建筑师设计了一个令人惊叹的阳台，使用了一个悬臂结构从建筑物向外延伸。

11.In civil engineering, a cantilever bridge can span long distances without needing support in the middle.

在土木工程中，悬臂桥可以跨越长距离而不需要中间支撑。

12.The cantilever shelf was perfect for displaying my collection of books without any visible supports.

这个悬臂架非常适合展示我的书籍收藏，没有任何可见的支撑。

13.Engineers often use cantilevers to create overhangs in modern buildings.

工程师们经常使用悬臂结构来创建现代建筑中的悬挑部分。

14.The design of the cantilever pier allows boats to dock easily without obstruction.

这个悬臂码头的设计使得船只可以轻松靠泊而不受阻碍。

作文

The concept of a cantilever is fascinating and plays a crucial role in modern engineering and architecture. A cantilever is a beam or structure that is anchored at one end and extends horizontally into space without any support on the other end. This innovative design allows for remarkable architectural feats, enabling the construction of bridges, balconies, and even entire buildings that seem to defy gravity. The principles behind a cantilever are grounded in physics, particularly in understanding how forces are distributed and balanced. One of the most famous examples of a cantilever structure is the Frank Lloyd Wright-designed Fallingwater house. Built over a waterfall in Pennsylvania, this house exemplifies how a cantilever can create a stunning visual impact while also harmonizing with its natural surroundings. The extended terraces of Fallingwater appear to float above the water, showcasing the beauty and elegance that a well-executed cantilever can achieve. In bridge construction, cantilevers are often used to create long spans without the need for extensive support structures in the water below. The Forth Bridge in Scotland is a prime example of a cantilever bridge. Its iconic red steel structure stretches across the Firth of Forth, utilizing cantilever technology to support its massive weight while allowing ships to pass beneath. This bridge not only serves a practical purpose but has also become a symbol of engineering excellence. The advantages of using cantilevers in construction are numerous. They allow architects and engineers to design lighter structures, reduce material costs, and create open spaces that enhance usability and aesthetics. However, designing a cantilever is not without its challenges. Engineers must carefully calculate the load and stress points to ensure stability and safety. For instance, the longer the cantilever extends, the more significant the bending moments and shearing forces become. Therefore, understanding the materials used and their properties is essential in creating a successful cantilever design. In addition to traditional construction, cantilever designs have found their way into furniture and product design. Many modern furniture pieces feature cantilever elements, providing both style and functionality. For example, a cantilever chair uses the principle of balance and support to create a comfortable seating option without the need for traditional legs, offering a sleek and contemporary look. As we look to the future, the application of cantilever technology is likely to expand further. With advancements in materials science, such as carbon fiber and high-strength concrete, the potential for more daring and innovative cantilever designs is limitless. Architects and engineers are continually pushing the boundaries of what is possible, and the cantilever will undoubtedly remain a vital component of this exploration. In conclusion, the cantilever is more than just a structural element; it represents creativity, innovation, and the ability to overcome physical limitations. From breathtaking homes perched over waterfalls to monumental bridges connecting distant shores, the cantilever stands as a testament to human ingenuity and our desire to create remarkable spaces that inspire and endure.

‘悬臂’的概念令人着迷，并在现代工程和建筑中发挥着至关重要的作用。‘悬臂’是一种结构或梁，一端固定，另一端在没有支撑的情况下水平延伸。这种创新设计使得建筑师能够实现非凡的建筑成就，使桥梁、阳台甚至整栋建筑似乎违背了重力。‘悬臂’背后的原理源于物理学，特别是在理解力如何分布和平衡方面。 最著名的‘悬臂’结构之一是弗兰克·劳埃德·赖特设计的福林水房。这座位于宾夕法尼亚州的房子展示了‘悬臂’如何创造出惊人的视觉效果，同时与自然环境和谐共生。福林水房的延伸露台似乎漂浮在水面上，展示了一个精心执行的‘悬臂’所能达到的美丽和优雅。 在桥梁建设中，‘悬臂’常用于创建长跨度，而无需在水下建立大量支撑结构。苏格兰的福斯大桥就是一个典型的悬臂桥。它标志性的红色钢结构跨越福斯湾，利用‘悬臂’技术支撑其巨大的重量，同时允许船只在下方通过。这座桥不仅具有实用功能，还成为了工程卓越的象征。 使用‘悬臂’进行建设的优点有很多。它们允许建筑师和工程师设计更轻的结构，降低材料成本，并创造出增强可用性和美感的开放空间。然而，设计一个‘悬臂’并非没有挑战。工程师必须仔细计算负载和应力点，以确保稳定性和安全性。例如，‘悬臂’延伸得越长，弯矩和剪切力就越大。因此，理解所用材料及其特性对于创建成功的‘悬臂’设计至关重要。 除了传统建筑，‘悬臂’设计还进入了家具和产品设计的领域。许多现代家具作品都采用了‘悬臂’元素，提供了风格和功能。例如，一个‘悬臂’椅子利用平衡和支撑的原理，创造出一种舒适的座椅选项，而不需要传统的腿部，提供了一种时尚和现代的外观。 展望未来，‘悬臂’技术的应用可能会进一步扩展。随着材料科学的进步，如碳纤维和高强度混凝土，更大胆和创新的‘悬臂’设计潜力无限。建筑师和工程师不断突破可能性的界限，而‘悬臂’无疑将继续成为这一探索的重要组成部分。 总之，‘悬臂’不仅仅是一个结构元素；它代表了创造力、创新和克服物理限制的能力。从悬在瀑布上的惊人住宅到连接遥远海岸的宏伟桥梁，‘悬臂’都是人类智慧的见证，体现了我们创造出激励和持久的非凡空间的愿望。