wavemaking resistance
简明释义
兴波阻力
英英释义
例句
1.In order to achieve higher speeds, the team focused on reducing wavemaking resistance 造波阻力 during testing.
为了实现更高的速度,团队在测试中专注于减少wavemaking resistance 造波阻力。
2.The engineers designed the boat to minimize wavemaking resistance 造波阻力 for better fuel efficiency.
工程师们设计了这艘船以最小化wavemaking resistance 造波阻力,以提高燃油效率。
3.By optimizing the design, we were able to significantly lower wavemaking resistance 造波阻力 and improve overall performance.
通过优化设计,我们能够显著降低wavemaking resistance 造波阻力,并提高整体性能。
4.The research focused on how different materials affect wavemaking resistance 造波阻力 in shipbuilding.
研究集中在不同材料如何影响船舶建造中的wavemaking resistance 造波阻力。
5.Sailboats are often designed with hull shapes that create less wavemaking resistance 造波阻力 in the water.
帆船通常设计成具有较少的wavemaking resistance 造波阻力的船体形状。
作文
In the world of fluid dynamics, the term wavemaking resistance refers to the resistance encountered by a vessel moving through water, which generates waves. This phenomenon is particularly significant for ships and boats, as it affects their efficiency and speed. When a vessel travels through water, it displaces the liquid, creating waves that propagate outward. The energy required to generate these waves contributes to the overall resistance faced by the vessel, making it crucial to understand and minimize this effect for better performance.The concept of wavemaking resistance can be broken down into several components. Firstly, the shape and design of the hull play a vital role in determining how much resistance a vessel will face. A streamlined hull can reduce the intensity of wave formation, thereby decreasing the wavemaking resistance. Engineers and designers often conduct extensive research and testing to create hull designs that optimize performance by minimizing this form of resistance.Secondly, the speed of the vessel also influences wavemaking resistance. As a ship increases its speed, the amplitude and frequency of the waves it creates change. At certain speeds, known as the 'hull speed,' the resistance due to wave-making becomes particularly pronounced. Understanding this relationship helps operators choose optimal speeds for fuel efficiency and speed, ensuring that they do not waste energy battling against unnecessary resistance.Moreover, the environmental conditions, such as wind and current, can also impact wavemaking resistance. For instance, a headwind can exacerbate the waves created by a vessel, leading to increased resistance. Conversely, following winds can help reduce the overall resistance experienced. Thus, navigators must consider these factors when planning routes and speeds to enhance operational efficiency.In addition to practical applications, the study of wavemaking resistance also has implications for environmental sustainability. By designing vessels that minimize this resistance, we can reduce fuel consumption and emissions, contributing to greener maritime practices. Innovations in technology, such as the use of advanced materials and hull shapes, are paving the way for more environmentally friendly shipping options.In conclusion, understanding wavemaking resistance is essential for anyone involved in maritime activities. It encompasses various elements, including hull design, vessel speed, and environmental conditions. By addressing these factors, we can improve the efficiency of vessels, reduce operational costs, and promote sustainable practices in the shipping industry. As we continue to advance in engineering and technology, the importance of minimizing wavemaking resistance will only grow, making it a critical area of focus for future developments in marine transportation.
在流体动力学的世界中,术语wavemaking resistance指的是船只在水中移动时遇到的阻力,这种移动会产生波浪。这种现象对于船舶和小艇尤其重要,因为它影响着它们的效率和速度。当船只在水中行驶时,它会排开液体,形成向外传播的波浪。产生这些波浪所需的能量会增加船只面临的总阻力,因此理解和最小化这种影响对提高性能至关重要。wavemaking resistance的概念可以分为几个组成部分。首先,船体的形状和设计在决定船只面临的阻力大小方面起着至关重要的作用。流线型的船体可以减少波浪形成的强度,从而降低wavemaking resistance。工程师和设计师通常会进行广泛的研究和测试,以创造出优化性能的船体设计,尽量减少这种阻力。其次,船只的速度也会影响wavemaking resistance。随着船速的增加,它所产生的波浪的幅度和频率也会发生变化。在某些特定的速度下,即“船体速度”,波浪产生的阻力变得尤为明显。理解这种关系有助于操作人员选择最佳速度,以实现燃油效率和速度,确保他们不会因对抗不必要的阻力而浪费能源。此外,环境条件,如风和水流,也会影响wavemaking resistance。例如,逆风可能会加剧船只产生的波浪,从而导致阻力增加。相反,顺风则可以帮助减少总体阻力。因此,航海者在规划航线和速度时必须考虑这些因素,以提高操作效率。除了实际应用之外,对wavemaking resistance的研究还对环境可持续性具有重要意义。通过设计能够最小化这种阻力的船只,我们可以减少燃料消耗和排放,从而促进更环保的海事实践。技术上的创新,如使用先进材料和船体形状,正在为更环保的航运选择铺平道路。总之,理解wavemaking resistance对任何参与海事活动的人来说都是至关重要的。它涵盖了多个元素,包括船体设计、船速和环境条件。通过解决这些因素,我们可以提高船只的效率,降低运营成本,并促进航运业的可持续实践。随着我们在工程和技术方面的不断进步,最小化wavemaking resistance的重要性只会增加,使其成为未来海洋运输发展中的一个关键关注点。
