cambered

简明释义

英[ˈkæmbəd]美[ˈkæmbər]

adj. 曲面的；拱形的；弧形的

v. 成弓形；反挠（camber 的过去分词）

英英释义

单词用法

同义词

反义词

例句

1.The effects of flapping frequency, wind velocity, Angle of attack, plane shape of wing and cambered aerofoil are investigated.

试验中进行了扑动频率、风速、迎角、机翼平面形状、翼型弯度对机翼气动特性影响的研究。

2.Its new product renovates fast by extending the plane direction system to consummate the cambered direction system. It can provide various problem solutions to satisfied different clients.

从平面指示系统的推广到弧面标识系统的完善到媒体传播，提供多种解决方案以满足不同客户的需求。

3.Formula to evaluate translation of the tooth-surface and the equation to describe the generatrix of the negatively cambered sooth-surface were derived respectively.

分别推导得到齿面平移距离和内凹齿面母线方程的计算公式。

4.The unit's lateral sectors permit selective air pressure adjustment across its entire width, allowing the Air Turn to compensate for cambered webs and uneven tensions.

可通过设备的侧面部分有选择性地进行空气压力调节，使无接触气垫转向器能够补偿翘曲的卷筒纸和不均匀的张力。

5.The appearance of each square elbow presents a smooth cambered surface.

所述的直角弯头外表呈光滑的弧面。

6.The street is quite steeply cambered at this point.

这条街的这个地方拱起很高。

7.The road was designed with a slight slope to allow water to drain off, making it more effective for rainwater management. The surface was intentionally cambered.

这条路设计成轻微的倾斜，以便让雨水排走，使其在雨水管理上更有效。表面是故意倾斜的。

8.In automotive engineering, a cambered wheel can improve traction during cornering.

在汽车工程中，倾斜的车轮可以在转弯时提高牵引力。

9.The architect incorporated a cambered roof design to enhance the building's aesthetic appeal and structural integrity.

建筑师采用了拱形屋顶设计，以增强建筑的美观性和结构完整性。

10.A cambered skateboard deck allows for better control and maneuverability.

一块倾斜的滑板甲板能提供更好的控制和灵活性。

11.The bridge was constructed with a cambered profile to distribute weight evenly across its span.

这座桥以拱形的轮廓建造，以便均匀分配其跨越的重量。

作文

In the world of engineering and design, the term cambered refers to a specific curvature or arching of a surface. This concept is particularly significant in the fields of automotive engineering, architecture, and even aerodynamics. When we talk about a cambered surface, we are usually referring to a structure that is not flat but instead has a slight upward or downward curve. This design feature can enhance performance, stability, and aesthetics, depending on the application. For instance, in the context of a vehicle's suspension system, a cambered wheel can improve traction and handling by allowing the tire to maintain better contact with the road surface during turns. The importance of cambered designs can be seen in various applications. In automotive racing, for example, cars often have cambered wheels to optimize their cornering capabilities. By tilting the wheels slightly inward at the top, engineers can ensure that the tires grip the road more effectively during high-speed maneuvers. This adjustment can significantly reduce the risk of losing control, making it a crucial aspect of race car design. Similarly, in architecture, a cambered beam can help distribute weight more evenly and prevent sagging over time. Architects may choose to implement a cambered design to enhance the longevity and durability of a structure. This technique is especially useful in large buildings or bridges, where the load-bearing elements must withstand significant forces. Aerodynamics also benefits from the principles of cambered surfaces. Aircraft wings are often designed with a cambered shape to create lift. The curvature allows air to move faster over the top surface of the wing, resulting in lower pressure above the wing compared to the higher pressure below it. This pressure difference generates lift, which is essential for flight. Engineers meticulously calculate the degree of cambered necessary to achieve optimal performance, balancing factors such as speed, weight, and altitude. In summary, the concept of cambered surfaces plays a vital role across various fields. From enhancing vehicle performance to ensuring structural integrity in buildings and optimizing flight dynamics in aviation, the application of cambered designs is both practical and innovative. Understanding the implications of this term allows engineers and designers to create solutions that are not only functional but also efficient and aesthetically pleasing. As technology continues to advance, the importance of cambered designs will likely grow, leading to new innovations and improvements in many industries. Ultimately, the study of cambered surfaces exemplifies how a simple curvature can have far-reaching effects on performance and safety in our everyday lives.

在工程和设计的世界中，术语cambered指的是表面的特定曲率或弯曲。这个概念在汽车工程、建筑甚至空气动力学等领域尤为重要。当我们谈论cambered表面时，通常指的是一个不是平坦而是略微向上或向下弯曲的结构。这种设计特征可以根据应用的不同，提高性能、稳定性和美观性。例如，在车辆悬挂系统的背景下，cambered轮胎可以通过使轮胎在转弯时保持更好的路面接触来改善牵引力和操控性。 cambered设计的重要性可以在各种应用中看到。例如，在汽车赛车中，赛车通常具有cambered轮胎，以优化其过弯能力。通过将轮胎顶部稍微向内倾斜，工程师可以确保轮胎在高速机动时更有效地抓住路面。这种调整可以显著降低失控的风险，使其成为赛车设计的关键方面。 同样，在建筑中，cambered梁可以帮助更均匀地分配重量，并防止随时间的推移而下沉。建筑师可能选择实施cambered设计，以增强结构的耐久性和持久性。这种技术在大型建筑或桥梁中特别有用，因为承重元件必须承受重大力量。 空气动力学也受益于cambered表面的原理。飞机的机翼通常设计成cambered形状以产生升力。曲率使空气在机翼顶部表面上流动得更快，从而导致机翼上方的压力低于下方的压力。这种压力差产生升力，这是飞行所必需的。工程师们细致计算所需的cambered程度，以实现最佳性能，平衡速度、重量和高度等因素。 总之，cambered表面的概念在各个领域中发挥着至关重要的作用。从提高车辆性能到确保建筑物的结构完整性，再到优化航空动力学中的飞行，cambered设计的应用既实用又创新。理解这个术语的含义使工程师和设计师能够创造出不仅功能性强，而且高效、美观的解决方案。随着技术的不断进步，cambered设计的重要性可能会进一步增加，导致许多行业的新创新和改进。最终，对cambered表面的研究展示了简单的曲率如何对我们日常生活中的性能和安全产生深远的影响。