surface-piercing air-cushion
简明释义
侧壁式气垫船
英英释义
例句
1.The surface-piercing air-cushion technology has revolutionized marine transportation by reducing drag.
这种表面穿透气垫技术通过减少阻力,彻底改变了海洋运输。
2.The new design of the boat features a surface-piercing air-cushion, which allows it to glide smoothly over the water.
这艘新设计的船采用了表面穿透气垫,使其能在水面上平稳滑行。
3.The military is exploring the use of surface-piercing air-cushion crafts for rapid deployment in coastal areas.
军方正在探索在沿海地区快速部署使用表面穿透气垫船只。
4.During the demonstration, the surface-piercing air-cushion enabled the vehicle to travel at high speeds over rough waters.
在演示中,表面穿透气垫使得该车辆能够在波涛汹涌的水面上高速行驶。
5.Engineers are testing a surface-piercing air-cushion system to improve the efficiency of hovercraft.
工程师们正在测试一种表面穿透气垫系统,以提高气垫船的效率。
作文
The concept of a surface-piercing air-cushion is fascinating and plays a significant role in modern engineering, particularly in the design of high-speed vessels. This innovative technology utilizes the principles of buoyancy and aerodynamics to create a cushion of air beneath a craft, allowing it to glide over water surfaces with minimal drag. Understanding how a surface-piercing air-cushion operates can provide insights into its advantages and applications in various fields.A surface-piercing air-cushion works by generating a layer of compressed air that supports the weight of the vessel. When a boat or vehicle equipped with this technology moves across the water, it creates a high-pressure zone beneath it, which lifts the hull partially out of the water. This results in reduced water resistance, enabling the craft to achieve higher speeds than traditional boats. The efficiency of this system is particularly beneficial in military and commercial applications where speed and maneuverability are crucial.One of the most notable applications of the surface-piercing air-cushion technology is in the design of hovercraft. Hovercraft utilize large fans to push air underneath the vessel, creating a substantial air cushion that allows them to traverse various terrains, including water, mud, and ice. The ability to operate on multiple surfaces makes hovercraft an invaluable asset in search and rescue operations, as well as in transporting goods to remote areas where conventional vehicles cannot reach.In addition to hovercraft, the surface-piercing air-cushion principle is also being explored in the development of advanced marine vehicles such as air-cushion ships and amphibious vehicles. These designs aim to combine the best features of both ships and land vehicles, offering unparalleled versatility for transportation and logistics. The potential for these vehicles to operate efficiently in shallow waters or on uneven terrain opens up new possibilities for exploration and commerce.However, the implementation of surface-piercing air-cushion technology is not without challenges. Engineers must consider factors such as stability, control, and environmental impact when designing vessels that utilize this system. For instance, maintaining balance while the craft is partially airborne requires sophisticated control systems and skilled operators. Additionally, the noise generated by the fans and the potential disruption to aquatic ecosystems are concerns that need to be addressed.Despite these challenges, the future of surface-piercing air-cushion technology looks promising. Ongoing research and advancements in materials science, aerodynamics, and propulsion systems are likely to enhance the performance and sustainability of these vessels. As we continue to explore the possibilities of this innovative technology, it is essential to strike a balance between efficiency and environmental responsibility.In conclusion, the surface-piercing air-cushion represents a remarkable advancement in maritime technology, offering numerous benefits in terms of speed, versatility, and operational capability. Its applications in hovercraft and other marine vehicles highlight its potential to revolutionize transportation across various terrains. As we move forward, embracing innovation while addressing environmental concerns will be key to the successful integration of this technology into our transportation systems.
“表面穿透气垫”的概念令人着迷,并在现代工程中发挥着重要作用,特别是在高速船只的设计中。这项创新技术利用浮力和空气动力学原理,在船只下方创造一个空气垫,使其能够以最小的阻力滑行于水面。理解“表面穿透气垫”的运作方式,可以深入了解它在各个领域中的优势和应用。“表面穿透气垫”通过产生一层压缩空气来支撑船只的重量。当配备这项技术的船只或车辆在水面上移动时,会在其下方形成一个高压区,从而将船体部分抬出水面。这导致水阻力的减少,使船只能够比传统船只达到更高的速度。这种系统的高效性在军事和商业应用中尤为重要,因为速度和机动性至关重要。“表面穿透气垫”技术最显著的应用之一是在气垫船的设计中。气垫船利用大型风扇将空气推送到船只下方,形成一个巨大的气垫,使其能够跨越水域、泥土和冰面等多种地形。在搜救行动中,气垫船的多地形作业能力使其成为一项不可或缺的资产,同时也可以将货物运输到传统车辆无法到达的偏远地区。除了气垫船,“表面穿透气垫”原理还在先进海洋车辆的开发中受到关注,例如气垫船和两栖车辆。这些设计旨在结合船只和陆地车辆的最佳特性,为运输和物流提供无与伦比的灵活性。这些车辆在浅水或不平坦地形中高效作业的潜力,开辟了探索和商业的新可能性。然而,实施“表面穿透气垫”技术并非没有挑战。工程师在设计利用该系统的船只时,必须考虑稳定性、控制和环境影响等因素。例如,保持船只在部分悬空状态下的平衡需要复杂的控制系统和熟练的操作员。此外,风扇产生的噪音和对水生生态系统的潜在干扰是需要解决的问题。尽管面临这些挑战,“表面穿透气垫”技术的未来仍然充满希望。材料科学、空气动力学和推进系统的持续研究和进步,可能会增强这些船只的性能和可持续性。随着我们继续探索这项创新技术的可能性,寻求效率与环境责任之间的平衡将是成功将其整合到我们的交通系统中的关键。总之,“表面穿透气垫”代表了海洋技术的一项显著进步,在速度、多功能性和操作能力方面提供了众多好处。它在气垫船和其他海洋车辆中的应用突显了其革命化各种地形交通的潜力。随着我们向前发展,拥抱创新的同时解决环境问题,将是成功整合这项技术的关键。
