aerodyne

简明释义

英[ˈeərəʊˌdaɪn]美[ˈerəˌdaɪn]

n. 重航空器

英英释义

单词用法

同义词

反义词

例句

1.May be an aerodyne to scramble.

可能是飞车抢夺。

2.May be an aerodyne to scramble.

可能是飞车抢夺。

3.The design of the new aerodyne 空气动力学飞行器 focuses on reducing drag.

新型aerodyne 空气动力学飞行器的设计重点在于减少阻力。

4.The aerodyne 空气动力学飞行器 achieved unprecedented speeds during the recent flight tests.

在最近的飞行测试中，这款aerodyne 空气动力学飞行器达到了前所未有的速度。

5.Engineers are testing a prototype of an aerodyne 空气动力学飞行器 that can operate in both air and water.

工程师正在测试一种可以在空气和水中运行的aerodyne 空气动力学飞行器原型。

6.Researchers are exploring how different shapes affect the performance of an aerodyne 空气动力学飞行器.

研究人员正在探索不同形状如何影响aerodyne 空气动力学飞行器的性能。

7.The military is investing in advanced aerodyne 空气动力学飞行器 technology for reconnaissance missions.

军方正在投资先进的aerodyne 空气动力学飞行器技术用于侦察任务。

作文

The term aerodyne refers to any heavier-than-air aircraft that derives its lift from aerodynamic forces. This concept is crucial in the field of aeronautics, as it encompasses a wide range of flying vehicles, including airplanes and helicopters. Understanding the principles behind aerodyne technology not only enhances our knowledge of flight but also contributes significantly to advancements in transportation and engineering.In the early days of aviation, pioneers like the Wright brothers experimented with various designs to achieve controlled flight. Their successful invention of the first powered aerodyne marked a pivotal moment in human history, allowing for the exploration of the skies and the development of modern air travel. The fundamental principles governing aerodyne flight involve lift, weight, thrust, and drag. Lift is generated by the wings as air flows over them, creating a difference in pressure that allows the aircraft to ascend.The evolution of aerodyne technology has led to remarkable innovations. For instance, jet engines have revolutionized air travel, enabling faster speeds and greater efficiency. Additionally, advancements in materials science have resulted in lighter and stronger structures, enhancing the performance of aerodyne vehicles. As we continue to push the boundaries of what is possible in aviation, it is essential to understand the underlying physics that make aerodyne flight feasible.Moreover, the study of aerodyne dynamics plays a critical role in ensuring safety and reliability in air travel. Engineers and scientists analyze various factors such as turbulence, wind patterns, and weather conditions to design aircraft that can withstand challenging environments. This research not only improves the performance of aerodyne vehicles but also minimizes the risks associated with flying.In recent years, the focus on sustainable aviation has brought new challenges and opportunities for the aerodyne industry. With growing concerns about climate change and environmental impact, researchers are exploring alternative fuels and electric propulsion systems. These innovations aim to reduce carbon emissions and make aerodyne travel more eco-friendly. By investing in cleaner technologies, the aviation sector can contribute to a more sustainable future while maintaining the benefits of global connectivity.Furthermore, the advent of unmanned aerial vehicles (UAVs) has expanded the definition of aerodyne. Drones are now used in various applications, from delivery services to agricultural monitoring. As technology continues to evolve, the potential uses for aerodyne vehicles will likely expand, opening new avenues for research and development.In conclusion, the concept of aerodyne represents a fascinating intersection of science, technology, and innovation. As we delve deeper into the mechanics of flight, we gain valuable insights that not only enhance our understanding of aviation but also drive progress in related fields. The ongoing exploration of aerodyne technology promises to shape the future of transportation, making it more efficient and sustainable. Whether through traditional aircraft or innovative drones, the journey of aerodyne development is an exciting frontier that continues to inspire generations of engineers and dreamers alike.

术语aerodyne指的是任何比空气重的飞机，它的升力来源于气动力。这个概念在航空学领域至关重要，因为它涵盖了包括飞机和直升机在内的各种飞行器。理解aerodyne技术背后的原理不仅增强了我们对飞行的认识，还对交通和工程的进步做出了重大贡献。在航空的早期，像怀特兄弟这样的先驱者们实验了各种设计，以实现受控飞行。他们成功发明的第一架动力aerodyne标志着人类历史的一个关键时刻，使人类能够探索天空并发展现代航空旅行。支配aerodyne飞行的基本原理涉及升力、重力、推力和阻力。升力是通过机翼产生的，当空气流过机翼时，形成压力差，使飞机能够上升。aerodyne技术的演变带来了显著的创新。例如，喷气发动机彻底改变了航空旅行，使得速度更快、效率更高。此外，材料科学的进步导致结构更轻且更强，从而增强了aerodyne飞行器的性能。随着我们不断推动航空领域的可能性，理解使aerodyne飞行可行的基础物理原理至关重要。此外，研究aerodyne动力学在确保航空旅行的安全性和可靠性方面起着关键作用。工程师和科学家分析各种因素，如湍流、风向和天气条件，以设计能够承受挑战性环境的飞机。这项研究不仅改善了aerodyne飞行器的性能，还减少了与飞行相关的风险。近年来，关注可持续航空为aerodyne行业带来了新的挑战和机遇。随着对气候变化和环境影响的关注日益加剧，研究人员正在探索替代燃料和电动推进系统。这些创新旨在减少碳排放，使aerodyne旅行更加环保。通过投资清洁技术，航空部门可以为更可持续的未来做出贡献，同时保持全球连通性的好处。此外，无人驾驶飞行器（UAV）的出现扩展了aerodyne的定义。无人机现在被用于各种应用，从快递服务到农业监测。随着技术的不断发展，aerodyne飞行器的潜在用途可能会扩大，为研究和开发开辟新的途径。总之，aerodyne的概念代表了科学、技术和创新的迷人交汇点。当我们深入研究飞行的机制时，我们获得了宝贵的见解，这不仅增强了我们对航空的理解，也推动了相关领域的进步。对aerodyne技术的持续探索有望塑造交通的未来，使其更加高效和可持续。无论是通过传统飞机还是创新无人机，aerodyne发展的旅程都是一个令人兴奋的前沿，继续激励着一代又一代的工程师和梦想家。