aerodynamically

简明释义

英[ˌeərəʊdaɪˈnæmɪkli]美[ˌeroʊdaɪˈnæmɪkli]

adv. 空气动力学地

英英释义

单词用法

同义词

反义词

例句

1.RB: We had some parts on it and we were hotter than we thought we would have been, so aerodynamically we were not as strong as in testing.

我们搞清楚了一些，我们比预期中热了点，所以空气动力没有测试中强大。

2.The tailless delta-canard configuration is inherently aerodynamically unstable, which provides a high level of agility, particularly at supersonic speeds.

鸭式无尾翼布局具有高度机动性和优越的超音速性能，但亦具有先天空气动力上之不稳定性。

3.Aim To study the effect of aerodynamically stabilized seeker dynamics on guided bomb system analysis.

目的研究风标头的动力学在制导航弹系统分析中的作用。

4.There was a lot of effort and a lot of things behind that, so we knew aerodynamically that the car had all the potential to be strong, so today is only a good proof of that.

之后还有很多的项目，我们知道空气动力套件拥有的巨大潜力，所以今天只是个很好的证明。

5.The HISAC is an aerodynamically configured cargo container which will be transported and delivered as an external store by high performance tactical aircraft.

HISAC是一种通过航空动力学方式构造的货箱，它由高性能的战术飞机作为货物的外体进行运输和交付。

6.The modern airplane design works well, but from a fuel efficiency standpoint, could planes be designed more aerodynamically — to lower drag and increase lift?

现代的飞机设计做得很好，但立足于燃料效率来看，飞机是否能设计得更符合空气动力学——降低阻力还是增加动力？

7.By all reckoning, the bumblebee is aerodynamically unsound and shouldn't be able to fly.

无论怎么考量，大黄蜂从空气动力学上讲是不健全、不应该会飞的。

8.The new car model is designed to be more aerodynamically efficient, reducing drag on the highway.

新款汽车模型的设计更加空气动力学上高效，减少了高速公路上的阻力。

9.For maximum speed, the cyclist adjusted their position to be more aerodynamically streamlined.

为了达到最佳速度，骑自行车的人调整了自己的姿势，使其更加空气动力学上流线型。

10.The airplane's wings are shaped aerodynamically to enhance lift and performance.

飞机的机翼形状是空气动力学上优化的，以增强升力和性能。

11.The design team focused on making the product aerodynamically stable during testing.

设计团队在测试中专注于使产品在空气动力学上保持稳定。

12.Buildings can also be designed aerodynamically to withstand strong winds.

建筑物也可以设计得更加空气动力学上，以抵御强风。

作文

The concept of aerodynamics is crucial in various fields, especially in aviation and automotive engineering. When designing vehicles that move through air, it is essential to consider how their shapes affect their performance. For instance, a car that is designed to be more streamlined will perform better at high speeds than one with a boxy shape. This is because the streamlined design allows air to flow more smoothly around the vehicle, reducing drag. In this context, we often use the term aerodynamically (空气动力学地) to describe how well an object can move through the air. In aviation, the importance of being aerodynamically (空气动力学地) efficient cannot be overstated. Aircraft are meticulously designed to minimize air resistance and maximize lift. The wings of an airplane, for example, are shaped in a way that allows them to generate lift while minimizing drag. This careful consideration of shape and design ensures that planes can fly efficiently and safely. Engineers use wind tunnels to test models of aircraft, observing how changes in design affect their aerodynamic properties. Similarly, in the world of sports cars, manufacturers invest heavily in research and development to create vehicles that are not only visually appealing but also aerodynamically (空气动力学地) optimized. A well-designed sports car can achieve higher speeds and better fuel efficiency due to its aerodynamic features. Elements such as spoilers, diffusers, and even the overall body shape play significant roles in enhancing a car’s performance. Moreover, the principles of aerodynamics extend beyond just vehicles. In architecture, buildings can be designed to be more aerodynamically (空气动力学地) efficient to withstand strong winds. Structures that are too flat or have sharp edges can experience increased wind resistance, which may lead to structural issues. By considering aerodynamic principles, architects can create safer and more resilient buildings. In nature, we can observe how aerodynamic shapes play a role in the survival of certain species. Birds, for example, have evolved to have bodies that are highly aerodynamically (空气动力学地) efficient, enabling them to fly long distances with minimal energy expenditure. Their wings are designed to create lift while reducing drag, showcasing the beauty of aerodynamic evolution. In conclusion, understanding the concept of being aerodynamically (空气动力学地) efficient is vital across various domains. Whether it is in the design of airplanes, cars, buildings, or even in the study of nature, the principles of aerodynamics play a significant role in enhancing performance and efficiency. As technology continues to advance, the application of aerodynamic principles will likely become even more sophisticated, leading to innovations that could transform our approach to design and engineering.

空气动力学的概念在多个领域中至关重要，尤其是在航空和汽车工程中。当设计穿越空气的车辆时，考虑其形状如何影响性能是至关重要的。例如，设计得更流线型的汽车在高速行驶时表现会比外形方方正正的汽车更好。这是因为流线型设计使空气能够更平滑地流过车辆，从而减少阻力。在这个背景下，我们常用术语空气动力学地来描述一个物体在空气中移动的效率。在航空领域，空气动力学地高效的重要性不容小觑。飞机的设计需要精确到位，以最小化空气阻力并最大化升力。例如，飞机的机翼形状经过精心设计，以便在最小化阻力的同时产生升力。这种对形状和设计的仔细考虑确保了飞机能够高效且安全地飞行。工程师们使用风洞测试飞机模型，观察设计变化如何影响其空气动力学特性。同样，在跑车的世界里，制造商在研发上投入巨资，以创造不仅视觉吸引人，而且在空气动力学地方面经过优化的车辆。一辆设计良好的跑车可以由于其空气动力学特征而实现更高的速度和更好的燃油效率。尾翼、扩散器甚至整体车身形状等元素在提升汽车性能方面发挥着重要作用。此外，空气动力学原理不仅限于车辆。在建筑领域，建筑物可以被设计得更空气动力学地高效，以抵御强风。过于平坦或有尖锐边缘的结构可能会遭受更大的风阻，这可能导致结构问题。通过考虑空气动力学原理，建筑师可以创造出更加安全和坚固的建筑。在自然界中，我们可以观察到空气动力学形状在某些物种生存中的作用。例如，鸟类已经进化出具有高度空气动力学地效率的身体，使它们能够以最低的能量消耗飞行长距离。它们的翅膀设计用于创造升力，同时减少阻力，展示了空气动力学进化的美丽。总之，理解空气动力学地高效的概念在各个领域都是至关重要的。无论是在飞机、汽车、建筑还是自然研究的设计中，空气动力学原理在提高性能和效率方面都发挥着重要作用。随着技术的不断进步，空气动力学原理的应用可能会变得更加复杂，从而导致可能改变我们设计和工程方式的创新。