windage resistance

简明释义

风阻力

英英释义

例句

1.The design of the drone was optimized to minimize windage resistance 风阻, allowing for better flight performance.

无人机的设计经过优化，以最小化风阻，从而提高飞行性能。

2.In aerial photography, minimizing windage resistance 风阻 is crucial for capturing stable images.

在航空摄影中，最小化风阻对于捕捉稳定图像至关重要。

3.Sailboats often adjust their sails to reduce windage resistance 风阻 and increase speed.

帆船通常会调整帆以减少风阻并提高速度。

4.Engineers conducted tests to assess the windage resistance 风阻 of the new vehicle model in wind tunnel experiments.

工程师通过风洞实验对新车型的风阻进行了评估测试。

5.The athlete wore a specially designed suit that reduced windage resistance 风阻 during the race.

运动员穿着一种专门设计的服装，以减少比赛中的风阻。

作文

In the realm of physics and engineering, understanding various forces acting on objects is crucial for designing efficient systems. One such concept is windage resistance, which refers to the drag force experienced by an object moving through the air. This phenomenon is particularly significant in fields such as aerodynamics, automotive design, and even in sports like cycling or sailing. The importance of windage resistance cannot be overstated, as it directly impacts the performance and efficiency of vehicles and equipment. To delve deeper into this topic, let us consider a scenario involving a cyclist racing against the clock. As the cyclist speeds along the road, they encounter air resistance that affects their speed and energy expenditure. The faster they go, the more pronounced the windage resistance becomes. Cyclists often adopt aerodynamic postures and wear specialized clothing to minimize this resistance, allowing them to maintain higher speeds with less effort. Similarly, in the automotive industry, engineers strive to design cars that are sleek and streamlined. A vehicle with a high windage resistance will consume more fuel and produce more emissions, making it less desirable from both an economic and environmental standpoint. By optimizing the shape of a car, manufacturers can reduce drag and improve fuel efficiency, ultimately benefiting both the consumer and the planet. In aviation, windage resistance plays a critical role in aircraft design. Engineers must carefully calculate the aerodynamic properties of an airplane to ensure that it can achieve optimal lift while minimizing drag. A well-designed aircraft will glide through the air with minimal resistance, allowing it to travel further and faster with less fuel. This is why modern airplanes often feature sleek wings and fuselages that are specifically shaped to reduce windage resistance. Even in everyday life, we experience windage resistance in our daily activities. For instance, when walking or running outside on a windy day, we may feel the force of the wind pushing against us, making our movements more strenuous. Understanding this concept can help individuals prepare better for outdoor activities, whether it’s choosing the right clothing or timing their workouts to avoid strong winds. In conclusion, windage resistance is a fundamental concept that affects various aspects of our lives, from sports and transportation to environmental considerations. By recognizing and mitigating the effects of windage resistance, we can enhance performance, improve efficiency, and contribute to a more sustainable future. Whether you are a cyclist looking to shave seconds off your time or an engineer designing the next generation of vehicles, understanding this force is essential for success. As technology continues to advance, the principles of windage resistance will remain at the forefront of innovation, guiding us toward a more efficient and effective world.

在物理和工程领域，理解作用于物体的各种力对于设计高效的系统至关重要。其中一个概念是风阻，它指的是物体在空气中移动时所经历的阻力。这种现象在空气动力学、汽车设计以及自行车或帆船等运动中尤为重要。风阻的重要性不容小觑，因为它直接影响到车辆和设备的性能和效率。为了更深入地探讨这个话题，让我们考虑一个涉及骑自行车的场景。在骑自行车的人与时间赛跑时，他们会遇到空气阻力，这会影响他们的速度和能量消耗。骑得越快，风阻就越明显。骑自行车的人通常会采取空气动力学姿势，并穿着专门的服装来最小化这种阻力，从而使他们能够以更少的努力保持更高的速度。同样，在汽车工业中，工程师们努力设计出流线型的汽车。具有高风阻的车辆将消耗更多的燃料并产生更多的排放，从经济和环境的角度来看都不太理想。通过优化汽车的形状，制造商可以减少阻力，提高燃油效率，最终使消费者和地球受益。在航空领域，风阻在飞机设计中发挥着关键作用。工程师必须仔细计算飞机的气动特性，以确保它能够在最小化阻力的同时实现最佳升力。设计良好的飞机将在空气中滑行，阻力最小，使其能够以更少的燃料飞得更远、更快。这就是为什么现代飞机通常具有流线型的机翼和机身，专门设计用于减少风阻。即使在日常生活中，我们也会在日常活动中体验到风阻。例如，当我们在风大的日子里走路或跑步时，可能会感受到风对我们的推动力，使我们的动作更加费力。理解这一概念可以帮助个人更好地为户外活动做准备，无论是选择合适的服装还是选择合适的时间进行锻炼以避免强风。总之，风阻是一个基本概念，影响着我们生活的各个方面，从运动和交通到环境考虑。通过认识和减轻风阻的影响，我们可以提高性能、改善效率，并为更可持续的未来做出贡献。无论你是想缩短时间的骑自行车的人，还是正在设计下一代车辆的工程师，理解这一力量对成功至关重要。随着技术的不断进步，风阻的原理将继续处于创新的前沿，引导我们走向一个更高效和有效的世界。