wing-in-ground-effect machine

简明释义

冲翼艇

英英释义

例句

1.The wing-in-ground-effect machine can fly at lower altitudes, making it ideal for search and rescue operations.

由于能够在较低的高度飞行，翼地效应机器非常适合用于搜救行动。

2.The new model of the wing-in-ground-effect machine has significantly improved fuel efficiency.

新型号的翼地效应机器显著提高了燃油效率。

3.The design of the wing-in-ground-effect machine allows it to skim over water surfaces with minimal drag.

该翼地效应机器的设计使其能够在水面上滑行，阻力最小。

4.Many researchers are exploring the aerodynamic properties of the wing-in-ground-effect machine.

许多研究人员正在探索翼地效应机器的空气动力学特性。

5.Engineers are testing the wing-in-ground-effect machine for potential use in coastal patrols.

工程师正在测试翼地效应机器，以便在沿海巡逻中使用。

作文

The concept of a wing-in-ground-effect machine is fascinating and represents one of the most innovative advancements in aviation technology. This term refers to a type of aircraft that takes advantage of the aerodynamic phenomenon known as ground effect, which occurs when an aircraft is flying close to the surface of the Earth or water. In essence, the wing-in-ground-effect machine utilizes the increased lift and decreased drag that occur when the wings are within a certain distance from the ground. This unique feature allows these machines to achieve greater efficiency compared to traditional aircraft.Ground effect is particularly significant for vehicles like hovercraft and certain types of amphibious craft, which operate just above the surface. These machines can glide over water or land with minimal resistance, making them incredibly fuel-efficient. The wing-in-ground-effect machine is designed to capitalize on this principle, allowing it to travel at higher speeds while consuming less energy.One of the most well-known examples of a wing-in-ground-effect machine is the Ekranoplan, a Soviet-era vehicle that resembled a hybrid between an airplane and a boat. It was capable of flying just above the surface of the water, utilizing ground effect to achieve remarkable speeds while maintaining stability. The design of the Ekranoplan showcased the potential of wing-in-ground-effect machines to revolutionize transportation across bodies of water.The advantages of wing-in-ground-effect machines extend beyond speed and efficiency; they also offer operational benefits in certain environments. For instance, in regions where traditional runways are scarce or non-existent, these machines can take off and land on water or flat terrain, providing vital connectivity for remote communities. This capability makes them ideal for search and rescue missions, cargo transport, and even tourism in areas that are otherwise difficult to access.However, the development and implementation of wing-in-ground-effect machines are not without challenges. Regulatory frameworks governing aviation and maritime operations often do not adequately address the unique characteristics of these vehicles. As a result, manufacturers and operators may face hurdles in gaining the necessary approvals to operate these innovative machines. Additionally, there are technical challenges related to stability and control, particularly during adverse weather conditions.Despite these challenges, the future of wing-in-ground-effect machines looks promising. Advances in materials science and aerodynamics continue to enhance the performance and safety of these vehicles. Furthermore, as global demand for sustainable transportation solutions grows, the efficiency of wing-in-ground-effect machines positions them as viable alternatives to conventional aircraft and boats.In conclusion, the wing-in-ground-effect machine represents a unique intersection of aviation and maritime technology, offering numerous advantages in terms of efficiency, speed, and operational flexibility. As we continue to explore the potential of these machines, it is essential to address the regulatory and technical challenges they face. With proper support and innovation, wing-in-ground-effect machines could play a crucial role in the future of transportation, especially in areas where traditional methods fall short.

“翼地效应机器”的概念令人着迷，代表了航空技术中最具创新性的进展之一。这个术语指的是一种利用称为地面效应的空气动力学现象的飞行器，当飞行器接近地球或水面的表面时，就会发生这种现象。实质上，“翼地效应机器”利用了当机翼在离地面一定距离内时所产生的升力增加和阻力减少。这一独特特性使这些机器能够比传统飞机实现更高的效率。地面效应对于像气垫船和某些类型的两栖船只等车辆尤为重要，这些车辆就在表面上方运行。这些机器可以在水面或陆地上滑行，阻力最小，从而实现极高的燃油效率。“翼地效应机器”旨在利用这一原理，使其能够以更高的速度旅行，同时消耗更少的能源。最著名的“翼地效应机器”之一是Ekranoplan，这是一种苏联时代的飞行器，外形类似于飞机和船的混合体。它能够在水面上方飞行，利用地面效应达到显著的速度，同时保持稳定。Ekranoplan的设计展示了“翼地效应机器”革命性改变水上交通的潜力。“翼地效应机器”的优势不仅限于速度和效率；在某些环境中，它们还提供了操作上的好处。例如，在传统跑道稀缺或不存在的地区，这些机器可以在水面或平坦地形上起飞和着陆，为偏远社区提供重要的连接。这种能力使它们成为搜救任务、货物运输甚至在难以到达的地区进行旅游的理想选择。然而，“翼地效应机器”的开发和实施并非没有挑战。管理航空和海事运营的监管框架往往无法充分解决这些车辆的独特特性。因此，制造商和运营商在获得必要的批准以操作这些创新机器时可能面临障碍。此外，与稳定性和控制相关的技术挑战，尤其是在恶劣天气条件下，也需要克服。尽管面临这些挑战，“翼地效应机器”的未来看起来前景广阔。材料科学和空气动力学的进步不断提高这些车辆的性能和安全性。此外，随着全球对可持续交通解决方案的需求不断增长，“翼地效应机器”的效率使其成为传统飞机和船只的可行替代方案。总之，“翼地效应机器”代表了航空和海事技术的独特交汇点，在效率、速度和操作灵活性方面提供了众多优势。在我们继续探索这些机器的潜力时，解决它们面临的监管和技术挑战至关重要。在适当的支持和创新下，“翼地效应机器”可能在未来的交通中发挥关键作用，特别是在传统方法无法满足需求的领域。