cambering

简明释义

英[ˈkæmbərɪŋ]美[ˈkæmbərɪŋ]

n. 辊型设计；中凹度磨削；弧线，弧形化

v. 成弧形；起拱（camber 的 ing 形式）

英英释义

单词用法

同义词

反义词

例句

1.This paper discusses the question of crane main girder camber and the pre-cambering curve, introducing camber values stipulated in related crane standards in China and abroad.

本文论述起重机主梁的上拱度及预拱曲线的基本原理，介绍了国内外起重机技术标准中规定的上拱度值。

2.This paper discusses the question of crane main girder camber and the pre-cambering curve, introducing camber values stipulated in related crane standards in China and abroad.

本文论述起重机主梁的上拱度及预拱曲线的基本原理，介绍了国内外起重机技术标准中规定的上拱度值。

3.According to real tested data, it builds up CVC cambering curve equation by polynomial regression. This paper discusses practical significance of the equation.

根据实测数据，采用多项式回归方法，建立CVC辊形曲线方程，并探讨了该方程的重要实际意义。

4.The engineer is focused on the process of cambering to ensure the road has proper drainage.

工程师专注于倾斜处理的过程，以确保道路有适当的排水。

5.During the construction, the team discussed the importance of cambering in the design of the bridge.

在施工过程中，团队讨论了在桥梁设计中倾斜处理的重要性。

6.The cambering of the aircraft wings improves its aerodynamic efficiency.

飞机机翼的倾斜处理提高了其空气动力效率。

7.Proper cambering can extend the lifespan of the pavement on highways.

适当的倾斜处理可以延长高速公路上路面的使用寿命。

8.The architect specified a certain degree of cambering for the roof to prevent water accumulation.

建筑师指定了屋顶的某个倾斜度，以防止水积聚。

作文

The concept of cambering is often discussed in the context of engineering and design, particularly when it comes to the construction of roads and bridges. Cambering refers to the slight arch or curvature that is intentionally built into a surface, such as a road or a bridge deck. This curvature is designed to facilitate proper drainage of water and to enhance the structural integrity of the construction. When engineers design a road, they take into account various factors including the type of traffic, the climate, and the materials used. The cambering is an essential aspect of this design process. It ensures that rainwater does not accumulate on the surface, which could lead to hydroplaning or other dangerous driving conditions. In addition to its practical applications, cambering also plays a significant role in aesthetics. A well-cambered road or bridge can create a visually appealing profile that complements the surrounding landscape. For instance, when driving along a scenic route, the gentle curves created by cambering can enhance the overall experience by providing a sense of flow and harmony with nature. Engineers and architects often collaborate to ensure that the cambering not only serves functional purposes but also contributes to the beauty of the structure. Moreover, cambering is not limited to civil engineering; it can also be observed in the design of aircraft wings and automotive components. In aviation, the wings of an airplane are cambered to optimize lift during flight. This means that the upper surface of the wing is curved while the lower surface is relatively flat. This design allows for better airflow and helps the aircraft achieve the necessary lift to become airborne. Similarly, in automotive engineering, the cambering of wheels can affect vehicle handling and stability. By adjusting the angle of the wheels, engineers can enhance traction and improve cornering performance. Understanding cambering is crucial for anyone involved in design and engineering fields. It requires a deep knowledge of physics, materials science, and environmental considerations. Designers must carefully calculate the degree of cambering needed for a specific project, ensuring that it meets safety standards while also fulfilling aesthetic goals. Failure to properly implement cambering can result in structural failures or unsafe conditions for users. In conclusion, cambering is a vital component in various engineering disciplines, from civil infrastructure to aerospace and automotive design. Its importance cannot be overstated, as it impacts both functionality and aesthetics. As technology continues to evolve, the principles of cambering will remain integral to creating safe, efficient, and beautiful structures that enhance our daily lives. Whether we are driving on a well-designed road or flying in a plane, the effects of cambering are all around us, quietly supporting our journeys and experiences.

“cambering”这个概念通常在工程和设计的背景下进行讨论，尤其是在道路和桥梁的建设中。“cambering”指的是故意在表面上构建的轻微拱形或曲率，例如在道路或桥面上。这种曲率旨在促进水的适当排水，并增强结构的完整性。当工程师设计一条道路时，他们会考虑各种因素，包括交通类型、气候和所用材料。“cambering”是这一设计过程中的一个重要方面。它确保雨水不会在表面上积聚，从而导致水滑或其他危险的驾驶条件。 除了其实际应用外，“cambering”在美学方面也发挥着重要作用。一个设计良好的拱形道路或桥梁可以创造出与周围景观相辅相成的视觉吸引力。例如，当沿着风景优美的路行驶时，由“cambering”所形成的柔和曲线可以通过提供流动感和与自然的和谐感来增强整体体验。工程师和建筑师常常合作，以确保“cambering”不仅服务于功能目的，还能为结构的美观做出贡献。 此外，“cambering”并不限于土木工程；它也可以在飞机机翼和汽车组件的设计中观察到。在航空领域，飞机的机翼被设计成弯曲，以优化飞行中的升力。这意味着机翼的上表面是弯曲的，而下表面则相对平坦。这种设计允许更好的气流，并帮助飞机获得起飞所需的升力。同样，在汽车工程中，车轮的“cambering”可以影响车辆的操控性和稳定性。通过调整车轮的角度，工程师可以增强牵引力并改善转弯性能。 理解“cambering”对于任何参与设计和工程领域的人来说都是至关重要的。这需要对物理学、材料科学和环境考虑有深入的了解。设计师必须仔细计算特定项目所需的“cambering”程度，确保其符合安全标准，同时也满足美学目标。如果未能正确实施“cambering”，可能会导致结构失效或用户的安全隐患。 总之，“cambering”是各个工程学科中的一个重要组成部分，从土木基础设施到航空和汽车设计。它的重要性不容小觑，因为它影响着功能性和美学。随着技术的不断发展，“cambering”的原则将继续成为创建安全、高效和美观的结构的核心，这些结构提升了我们的日常生活。无论我们是在一条设计良好的道路上驾驶，还是在飞机上飞行，“cambering”的影响无处不在，默默支持着我们的旅程和体验。