hydroelastic
简明释义
英[haɪdrəʊɪˈlæstɪk]美[haɪdroʊˈɛləsˌtɪk]
水力弹性的
英英释义
Relating to the interaction between fluid dynamics and elastic materials, particularly in contexts such as structural engineering or marine engineering. | 与流体动力学和弹性材料之间的相互作用有关,特别是在结构工程或海洋工程等背景下。 |
单词用法
水弹性模型 | |
水弹性效应 | |
水弹性相互作用 | |
水弹性结构 | |
水弹性理论 | |
水弹性仿真 |
同义词
反义词
| 刚性 | The structure was designed to be rigid to withstand heavy loads. | 该结构设计为刚性以承受重载。 | |
| 坚硬 | Stiff materials are often used in construction for their strength. | 坚硬的材料通常用于建筑,因为它们的强度。 |
例句
1.The hydroelastic effect can be negligible in most cases except for the longer ships and the lower sea state.
除较长船和较低海况外,一般可以忽略水弹性效应。
2.Efficient and accurate estimation of mat-like VLFS s hydroelastic responses in waves is very important for the design.
如何快速而精确地估计箱式超大型浮体在波浪中的水弹性响应是设计中需要解决的一个重要问题。
3.The paper predicts dynamic response of the aft-part vibration of an "A type ship", using the hydroelastic theory, by the means of the set of computational programs designed by the authors.
采用水弹性分析方法,利用自行开发的软件对某型船尾部振动响应进行了预报。对建模、附连水质量计算、激振力的确定等问题进行了探讨。
4.Hydroelastic model simulating flow, structure and their coupling system requires especial model material.
模拟水流、结构及其相互耦合系统的水弹性模型,对模型材料具有特殊要求。
5.Both the three-dimensional potential theories and thin-walled beam theories are applied to the hydroelastic analysis of container ships with large deck openings in this paper.
本文提出利用三维势流理论和薄壁梁理论计算大开口集装箱船的水弹性问题。
6.The nonlinear hydroelastic theory of high speed vessels in time domain is established.
建立了单体或多体高速船舶的非线性时域水弹性理论。
7.This paper presents a nonlinear hydroelastic differential analysis method of wave-induced vertical motions and structural responses of ships.
本文给出了一个预报波浪诱导的船舶垂向运动和结构总体动响应的非线性时域水弹性力学微分分析法。
8.The coupling action between sloshing liquid and flexible structure is also analyzed associated with the hydroelasticity theory and corresponding hydroelastic equations are established.
运用水弹性力学理论论述了液体晃荡与弹性液舱耦合作用的分析方法,建立了相应的水弹性力学方程。
9.According to the dynamic analysis of the responsive skirt-air cushion system, the flexible skirt of the hovercraft can be simplified to a aeroelastic and hydroelastic dynamic feedback system.
根据响应围裙-气垫系统的动力学分析,气垫船柔性围裙可简化为一个气弹和水弹动力反馈系统。
10.According to the dynamic analysis of the responsive skirt-air cushion system, the flexible skirt of the hovercraft can be simplified to a aeroelastic and hydroelastic dynamic feedback system.
根据响应围裙-气垫系统的动力学分析,气垫船柔性围裙可简化为一个气弹和水弹动力反馈系统。
11.Engineers must consider hydroelastic 水弹性 effects when designing ships to ensure they can handle rough seas.
工程师在设计船只时必须考虑水弹性效应,以确保它们能够应对恶劣海况。
12.The design of the bridge incorporates hydroelastic 水弹性 principles to ensure stability during high winds.
这座桥的设计采用了水弹性原理,以确保在强风中保持稳定。
13.Researchers are studying hydroelastic 水弹性 behavior in marine structures to improve their resilience against waves.
研究人员正在研究海洋结构中的水弹性行为,以提高其抵御波浪的韧性。
14.The study focuses on the hydroelastic 水弹性 interaction between water waves and underwater structures.
该研究集中于水波与水下结构之间的水弹性相互作用。
15.The hydroelastic 水弹性 response of the floating platform was analyzed using advanced simulation techniques.
浮动平台的水弹性响应使用先进的模拟技术进行了分析。
作文
In recent years, the field of engineering has seen significant advancements, particularly in the study of structures that interact with fluids. One such area of research is the concept of hydroelastic (水弹性), which refers to the behavior of elastic structures subjected to fluid forces. This phenomenon is critical in various applications, including marine engineering, where ships and offshore structures must withstand the forces exerted by water. Understanding hydroelastic (水弹性) effects is essential for designing safer and more efficient vessels.The term hydroelastic (水弹性) combines two fundamental concepts: hydro, meaning related to water, and elastic, referring to the ability of materials to deform and return to their original shape. When a structure is immersed in a fluid, it experiences dynamic interactions that can lead to complex responses, including vibrations and deformations. Engineers must consider these factors when designing structures that operate in aquatic environments.One of the primary challenges in hydroelastic analysis is predicting how a structure will respond to varying fluid conditions. For example, a ship moving through waves experiences different forces depending on the wave height, frequency, and direction. The hydroelastic (水弹性) response of the ship's hull can significantly impact its performance, stability, and safety. Researchers use advanced computational models to simulate these interactions, allowing for better predictions and designs.Furthermore, the hydroelastic (水弹性) behavior is not limited to marine vessels. It also applies to bridges, dams, and offshore wind turbines, where water flow can influence structural integrity. For instance, a bridge over a river must account for the forces exerted by flowing water, especially during floods. Engineers employ hydroelastic (水弹性) principles to ensure that these structures can endure such forces without compromising safety.Another important aspect of hydroelastic (水弹性) studies is the material selection. Different materials exhibit varying degrees of elasticity and strength when exposed to fluid forces. For example, composite materials may offer better performance in hydroelastic applications due to their lightweight and high-strength properties. Engineers must carefully choose materials that can withstand the dynamic loads associated with hydroelastic (水弹性) phenomena while maintaining structural integrity.Moreover, the implications of hydroelastic (水弹性) analysis extend beyond engineering. As climate change continues to affect sea levels and weather patterns, understanding how structures behave in fluid environments becomes increasingly important. Coastal cities must prepare for rising waters and stronger storms, necessitating the application of hydroelastic (水弹性) principles in urban planning and infrastructure development.In conclusion, the study of hydroelastic (水弹性) phenomena is vital for engineers working in fluid-structure interaction fields. By understanding how elastic structures respond to fluid forces, we can design safer, more efficient, and resilient systems. As we face challenges posed by climate change and increasing maritime activities, the importance of hydroelastic (水弹性) research will only continue to grow, shaping the future of engineering and environmental sustainability.
近年来,工程领域取得了显著的进展,特别是在研究与流体相互作用的结构方面。其中一个研究领域是hydroelastic(水弹性)的概念,指的是在流体力作用下弹性结构的行为。这一现象在各种应用中至关重要,包括海洋工程,其中船舶和海上结构必须承受水所施加的力量。理解hydroelastic(水弹性)效应对于设计更安全、更高效的船只至关重要。hydroelastic(水弹性)这个术语结合了两个基本概念:hydro,意为与水相关,elastic,指材料变形并恢复到其原始形状的能力。当一个结构浸入流体中时,它会经历动态相互作用,这可能导致复杂的反应,包括振动和变形。在设计在水环境中运行的结构时,工程师必须考虑这些因素。hydroelastic(水弹性)分析中的主要挑战之一是预测结构如何响应不同的流体条件。例如,一艘穿越波浪的船只根据波高、频率和方向的不同,会经历不同的力量。船体的hydroelastic(水弹性)反应会显著影响其性能、稳定性和安全性。研究人员使用先进的计算模型来模拟这些相互作用,从而允许更好的预测和设计。此外,hydroelastic(水弹性)行为不仅限于海洋船只。它还适用于桥梁、坝和海上风电涡轮机,在这些情况下,水流可能会影响结构的完整性。例如,一座跨越河流的桥梁必须考虑流动水施加的力量,尤其是在洪水期间。工程师利用hydroelastic(水弹性)原理确保这些结构能够承受此类力量,而不影响安全性。hydroelastic(水弹性)研究的另一个重要方面是材料选择。不同的材料在暴露于流体力量时表现出不同程度的弹性和强度。例如,复合材料由于其轻质和高强度特性,在hydroelastic(水弹性)应用中可能提供更好的性能。工程师必须仔细选择能够承受与hydroelastic(水弹性)现象相关的动态载荷的材料,同时保持结构的完整性。此外,hydroelastic(水弹性)分析的影响不仅限于工程。随着气候变化持续影响海平面和天气模式,理解结构在流体环境中的行为变得愈加重要。沿海城市必须为海水上升和更强的风暴做好准备,这需要在城市规划和基础设施开发中应用hydroelastic(水弹性)原理。总之,hydroelastic(水弹性)现象的研究对于从事流体-结构相互作用领域的工程师至关重要。通过理解弹性结构如何响应流体力量,我们可以设计出更安全、更高效且更具韧性的系统。随着我们面临气候变化和日益增加的海洋活动带来的挑战,hydroelastic(水弹性)研究的重要性只会继续增长,塑造工程和环境可持续发展的未来。
