maximum camber

简明释义

最大弯度

英英释义

例句

1.During the design phase, we need to determine the maximum camber for optimal aerodynamics.

在设计阶段，我们需要确定最大弯曲度以达到最佳气动性能。

2.In civil engineering, the maximum camber is crucial for road safety and drainage.

在土木工程中，最大弯曲度对道路安全和排水至关重要。

3.The pilot was trained to understand the effects of maximum camber on aircraft stability.

飞行员接受了了解最大弯曲度对飞机稳定性影响的培训。

4.The engineer calculated the maximum camber to ensure the bridge could handle heavy loads.

工程师计算了最大弯曲度以确保桥梁能够承受重载。

5.The car's performance improved significantly after adjusting the maximum camber of the wheels.

调整了车轮的最大弯曲度后，汽车的性能显著提高。

作文

In the world of aerodynamics and engineering, the term maximum camber refers to the greatest curvature of an airfoil or wing section. This concept is crucial for understanding how lift is generated in aircraft and how vehicles, such as cars, perform at high speeds. The maximum camber point on a wing is where the airfoil's shape is most pronounced, allowing for optimal airflow over the surface. When designing an aircraft, engineers must carefully consider the position and magnitude of the maximum camber to ensure that the aircraft can achieve sufficient lift while maintaining stability and control.The importance of maximum camber can be illustrated through the principles of lift generation. As air flows over a wing, it travels faster over the curved upper surface than the flatter lower surface. According to Bernoulli's principle, this difference in velocity creates a pressure difference, resulting in lift. Therefore, the design of the airfoil, including its maximum camber, directly influences the efficiency and effectiveness of lift production.In automotive engineering, the concept of maximum camber also plays a significant role, particularly in the design of tires and suspension systems. In this context, maximum camber refers to the angle at which the wheels are tilted relative to the vertical axis. Adjusting the maximum camber can enhance a vehicle's cornering ability, providing better grip during turns. However, too much camber can lead to uneven tire wear and reduced straight-line stability.Understanding maximum camber in both aviation and automotive contexts highlights its significance in performance optimization. For instance, in racing, teams often adjust the maximum camber of their cars to gain a competitive edge. By fine-tuning the suspension geometry, they can improve tire contact with the road during high-speed maneuvers, ultimately leading to faster lap times.Moreover, the effects of maximum camber extend beyond performance; they also influence safety. In aviation, wings designed with an inappropriate maximum camber may stall at lower speeds, compromising the aircraft's safety during takeoff and landing. Similarly, in automobiles, improper camber settings can lead to loss of traction, increasing the risk of accidents.In conclusion, the concept of maximum camber is integral to the fields of aerodynamics and automotive engineering. It affects lift generation in aircraft and handling characteristics in cars. A thorough understanding of maximum camber enables engineers and designers to create more efficient, safer, and higher-performing vehicles and aircraft. As technology advances, the exploration of maximum camber will continue to evolve, leading to innovations that enhance both performance and safety in transportation.

在空气动力学和工程学的世界中，术语最大弯曲度指的是机翼或翼型截面的最大曲率。这个概念对于理解飞机如何产生升力以及汽车在高速下的表现至关重要。机翼上的最大弯曲度点是翼型形状最明显的地方，允许最佳气流通过表面。当设计飞机时，工程师必须仔细考虑最大弯曲度的位置和大小，以确保飞机能够在保持稳定性和控制性的同时获得足够的升力。最大弯曲度的重要性可以通过升力产生的原理来说明。当空气流过机翼时，它在弯曲的上表面上流动得比较平坦的下表面快。根据伯努利原理，这种速度差异会造成压力差，从而产生升力。因此，翼型的设计，包括其最大弯曲度，直接影响升力产生的效率和效果。在汽车工程中，最大弯曲度的概念也发挥着重要作用，特别是在轮胎和悬挂系统的设计中。在这个上下文中，最大弯曲度指的是车轮相对于垂直轴的倾斜角度。调整最大弯曲度可以增强车辆的转弯能力，在转弯时提供更好的抓地力。然而，过大的弯曲度可能导致轮胎磨损不均和直线稳定性降低。理解航空和汽车领域的最大弯曲度突显了其在性能优化中的重要性。例如，在赛车中，车队经常调整他们汽车的最大弯曲度以获得竞争优势。通过微调悬挂几何形状，他们可以在高速操控过程中改善轮胎与路面的接触，从而最终导致更快的圈速。此外，最大弯曲度的影响不仅限于性能；它们还影响安全性。在航空中，设计不当的机翼可能在较低速度下失速，从而危及飞机在起飞和着陆时的安全。同样，在汽车中，不当的弯曲度设置可能导致失去牵引力，增加事故风险。总之，最大弯曲度的概念对于空气动力学和汽车工程领域至关重要。它影响飞机的升力生成和汽车的操控特性。对最大弯曲度的透彻理解使工程师和设计师能够创建更高效、更安全和性能更高的车辆和飞机。随着技术的进步，对最大弯曲度的探索将继续发展，导致增强交通运输性能和安全性的创新。