hydromechanics
简明释义
英[ˌhaɪdrəʊmɪˈkænɪks]美[ˌhaɪdroʊməˈkænɪks]
n. [流] 流体力学
英英释义
Hydromechanics is the branch of science that deals with the behavior of fluids (liquids and gases) in motion and at rest, and the forces acting on them. | 水力学是研究流体(液体和气体)在运动和静止状态下的行为以及作用于它们的力的科学分支。 |
单词用法
流体力学原理 | |
流体力学应用 | |
流体力学分析 | |
流体力学建模 |
同义词
反义词
| 热力学 | Thermodynamics is essential for understanding heat transfer in engines. | 热力学对于理解发动机中的热传递至关重要。 | |
| 空气动力学 | Aerodynamics plays a crucial role in the design of aircraft. | 空气动力学在飞机设计中起着至关重要的作用。 |
例句
1.Therefore they also has the characteristic which many linear polymers do not have: good hydromechanics performance, unique viscosity behavior, multi-purpose and good solubility.
因此它也就拥有许多线型聚合物所不具备的性能特点:良好的流体力学性能、独特的粘度行为、多功能性、较好的溶解性等。
2.The impact pressure on the surface of product and the flowing velocity were calculated by hydromechanics theory, and the calculatio.
同时,运用流体力学原理,对冷却管路系统进行了理论计算,得到了喷嘴出口处的水流速度以及作用于钢板表面的冲击压力。
3.In this paper the mechanical behaviour of the fluid at the exit of a slit die has been analysed theoretically based on the basic law of hydromechanics.
本文从流体力学的基本定律出发,从理论上分析了流体在狭缝出口处的力学行为。
4.In order to overcome this weak link in the dregs thick liquid expulsion system, we have designed and made a simple wear-resisting bend, using hydromechanics knowledge, to solve this problem.
为了克服渣浆输送系统中这一薄弱环节,运用流体力学中的伯奴利方程及其他知识而设计和制造的简易耐磨弯头解决了这一问题。
5.The tension of liquid surface is studied in several industrial areas, such as flotation technology and liquid technology, and in the teaching of hydromechanics and other subjects.
液体的表面张力,在工业上的浮选技术和液体输送技术;在教学中的流体力学等都要对它进行研究。
6.Involves the project geology, the hydrology geology, Rock mechanics, mine pressure, hydromechanics, crag body water subject and so on multi-gates discipline theory and practice.
涉及工程地质、水文地质、岩体力学、矿山压力、流体力学、岩体水力学等多门学科的理论和实践。
7.The study of hydromechanics 流体力学 is essential for designing efficient water transport systems.
研究流体力学对于设计高效的水运输系统至关重要。
8.The principles of hydromechanics 流体力学 are applied in the design of dams and reservoirs.
在大坝和水库的设计中应用了流体力学的原理。
9.Research in hydromechanics 流体力学 contributes to better flood management strategies.
在流体力学方面的研究有助于更好的洪水管理策略。
10.Engineers apply principles of hydromechanics 流体力学 to improve the performance of hydraulic machines.
工程师应用流体力学的原理来提高液压机器的性能。
11.In coastal engineering, hydromechanics 流体力学 helps predict wave behavior and erosion patterns.
在海岸工程中,流体力学有助于预测波浪行为和侵蚀模式。
作文
Hydromechanics is a branch of physics that deals with the behavior of fluids at rest and in motion. It is an essential field of study that combines principles from both fluid mechanics and hydraulics. Understanding hydromechanics (水力学) is crucial for engineers, scientists, and researchers who work in various industries, including civil engineering, mechanical engineering, and environmental science.The study of hydromechanics (水力学) allows us to analyze the forces exerted by fluids on structures, predict fluid behavior under different conditions, and design systems that effectively manage water resources. For example, when designing a dam, engineers must consider the pressure exerted by the water on the dam walls, as well as the flow patterns of the water behind the dam. This requires a deep understanding of hydromechanics (水力学) to ensure the safety and efficiency of the structure.In addition to engineering applications, hydromechanics (水力学) plays a vital role in environmental studies. For instance, understanding how pollutants spread in rivers and lakes can help scientists develop strategies to mitigate environmental damage. By applying the principles of hydromechanics (水力学), researchers can model the movement of contaminants and predict their impact on aquatic ecosystems.One of the fundamental concepts in hydromechanics (水力学) is the principle of buoyancy, which explains why objects float or sink in a fluid. This principle is based on Archimedes' principle, which states that the upward buoyant force experienced by an object submerged in a fluid is equal to the weight of the fluid displaced by the object. This concept has practical applications in various fields, such as naval architecture and the design of underwater vehicles.Another important aspect of hydromechanics (水力学) is the study of fluid dynamics, which focuses on the behavior of fluids in motion. Fluid dynamics is essential for understanding phenomena such as turbulence, laminar flow, and the effects of viscosity. Engineers use these principles to design efficient pipelines, optimize the performance of pumps, and improve the aerodynamics of vehicles.Moreover, the advancements in computational fluid dynamics (CFD) have revolutionized the field of hydromechanics (水力学). CFD allows for the simulation of fluid flow using numerical methods, enabling engineers to visualize and analyze complex fluid behavior in a virtual environment. This technology has become indispensable in various industries, from aerospace to automotive engineering, where optimizing fluid flow can lead to significant improvements in performance and energy efficiency.In conclusion, hydromechanics (水力学) is a multifaceted field that encompasses various principles and applications related to fluids. Its importance cannot be overstated, as it affects numerous aspects of our daily lives, from the water we drink to the vehicles we drive. As technology continues to advance, the study of hydromechanics (水力学) will remain a critical area of research, driving innovation and helping us address the challenges posed by fluid systems in our world.
