hydraulics computation

简明释义

水力学计算;

英英释义

例句

1.The team relied on hydraulics computation to ensure the dam's structural integrity under varying water levels.

团队依靠液压计算确保大坝在不同水位下的结构完整性。

2.Accurate hydraulics computation is essential for designing effective drainage systems.

准确的液压计算对于设计有效的排水系统至关重要。

3.The engineer performed hydraulics computation to determine the flow rate of water in the pipeline.

工程师进行了液压计算以确定管道中水的流速。

4.In our project, we used hydraulics computation to analyze the pressure distribution in the reservoir.

在我们的项目中，我们使用液压计算分析水库中的压力分布。

5.Using advanced software for hydraulics computation can significantly improve design accuracy.

使用先进的软件进行液压计算可以显著提高设计的准确性。

作文

Hydraulics is a branch of engineering that deals with the mechanical properties of liquids. One of the critical aspects of hydraulics is the process of hydraulics computation, which involves the calculation and analysis of fluid behavior in various systems. This field is essential for designing and optimizing systems that rely on fluid movement, such as dams, pipelines, and hydraulic machinery. Understanding hydraulics computation is vital for engineers who aim to create efficient and effective designs that can withstand various environmental conditions.The importance of hydraulics computation cannot be overstated. It provides engineers with the tools necessary to predict how fluids will behave under different circumstances. For instance, when designing a dam, engineers must calculate the forces exerted by water on the structure. This requires an understanding of fluid dynamics, pressure distribution, and flow rates. By performing hydraulics computation, engineers can ensure that the dam will hold up against potential flooding or other stressors.Moreover, hydraulics computation plays a crucial role in the design of pipelines. Engineers must consider factors such as the viscosity of the fluid, the diameter of the pipe, and the elevation changes along the pipeline's route. By applying hydraulics computation, they can determine the optimal pipe size and material to minimize energy loss due to friction and turbulence. This not only saves costs but also enhances the overall efficiency of the system.In addition to these applications, hydraulics computation is also fundamental in the development of hydraulic machinery. Equipment such as excavators, forklifts, and hydraulic presses rely on the principles of hydraulics to function effectively. Engineers use hydraulics computation to analyze the forces at play within these machines, ensuring that they operate safely and efficiently. By accurately calculating the hydraulic forces, engineers can design machinery that maximizes performance while minimizing the risk of failure.As technology advances, the methods used in hydraulics computation have also evolved. Modern engineers often utilize computer simulations and software tools to model fluid behavior more accurately. These tools allow for complex calculations that would be impractical to perform manually. With the help of computational fluid dynamics (CFD), engineers can visualize how fluids interact within a system, leading to better-informed design decisions.In conclusion, hydraulics computation is a fundamental aspect of hydraulic engineering that enables professionals to design systems involving fluid dynamics. Its applications range from constructing safe and efficient dams to optimizing pipeline designs and developing hydraulic machinery. As the field continues to grow, the importance of mastering hydraulics computation will only increase, highlighting the need for engineers to stay updated with the latest techniques and technologies in this area. By doing so, they can contribute to creating innovative solutions that address the challenges of fluid dynamics in various engineering projects.

液压学是工程学的一个分支，涉及液体的机械特性。其中一个关键方面是液压计算，它涉及对各种系统中流体行为的计算和分析。这个领域对于设计和优化依赖于流体运动的系统（如水坝、管道和液压机械）至关重要。理解液压计算对那些旨在创造高效有效设计的工程师来说是至关重要的，这些设计能够承受各种环境条件。液压计算的重要性不容小觑。它为工程师提供了预测流体在不同情况下如何行为所需的工具。例如，在设计水坝时，工程师必须计算水对结构施加的力量。这需要对流体动力学、压力分布和流量进行理解。通过进行液压计算，工程师可以确保水坝能够抵御潜在的洪水或其他压力。此外，液压计算在管道设计中也起着至关重要的作用。工程师必须考虑流体的粘度、管道的直径以及沿管道路线的高差变化。通过应用液压计算，他们可以确定最佳的管道尺寸和材料，以最小化由于摩擦和湍流造成的能量损失。这不仅节省了成本，还提高了系统的整体效率。除了这些应用外，液压计算在液压机械的开发中也至关重要。挖掘机、叉车和液压压机等设备依赖于液压原理有效运作。工程师使用液压计算来分析这些机器内部的力，确保它们安全高效地运行。通过准确计算液压力，工程师可以设计出最大化性能并最小化故障风险的机械。随着技术的进步，用于液压计算的方法也在不断发展。现代工程师通常利用计算机模拟和软件工具更准确地建模流体行为。这些工具允许进行复杂的计算，而手动执行是不切实际的。在计算流体动力学（CFD）的帮助下，工程师可以可视化流体在系统内的相互作用，从而做出更明智的设计决策。总之，液压计算是液压工程的基本方面，使专业人士能够设计涉及流体动力学的系统。其应用范围从构建安全高效的水坝到优化管道设计和开发液压机械。随着这一领域的不断发展，掌握液压计算的重要性只会增加，这突显了工程师需要跟上该领域最新技术和技术的必要性。这样，他们才能为应对各种工程项目中流体动力学的挑战做出创新的解决方案。