experimental model basin

简明释义

船模试验池

英英释义

例句

1.The researchers conducted tests in the experimental model basin 实验模型水池 to study wave patterns.

研究人员在实验模型水池 experimental model basin中进行测试，以研究波浪模式。

2.The experimental model basin 实验模型水池 was designed to replicate real-world ocean currents.

该实验模型水池 experimental model basin旨在复制现实世界中的海洋洋流。

3.Using an experimental model basin 实验模型水池, engineers can simulate various hydrodynamic conditions.

工程师可以使用实验模型水池 experimental model basin模拟各种水动力条件。

4.The results from the experimental model basin 实验模型水池 will inform our design decisions.

来自实验模型水池 experimental model basin的结果将为我们的设计决策提供信息。

5.We observed how different shapes affected resistance in the experimental model basin 实验模型水池.

我们观察了不同形状如何影响在实验模型水池 experimental model basin中的阻力。

作文

The study of fluid dynamics is essential in various fields, including engineering, environmental science, and oceanography. One of the crucial tools utilized in this field is the experimental model basin, which plays a significant role in understanding how fluids behave under different conditions. An experimental model basin is essentially a controlled environment where researchers can simulate and analyze the effects of water flow, waves, and other hydrodynamic phenomena on structures, objects, or ecosystems. By creating scaled-down models of real-world scenarios, scientists can gather valuable data that would be difficult to obtain through theoretical calculations alone.In an experimental model basin, various parameters can be manipulated, such as the depth of water, the speed of currents, and the shape of the basin itself. This flexibility allows researchers to replicate specific conditions that might occur in nature, such as tidal flows, storm surges, or the impact of human activities on aquatic environments. For instance, engineers designing coastal structures can use an experimental model basin to test how their designs will hold up against powerful waves or erosion, ultimately leading to safer and more effective solutions.Moreover, the experimental model basin serves as an educational tool. Students and professionals alike can observe firsthand the principles of fluid dynamics in action. By conducting experiments in these basins, learners can visualize complex concepts such as turbulence, buoyancy, and drag forces. This hands-on experience is invaluable in fostering a deeper understanding of the subject matter.The applications of experimental model basins extend beyond engineering. Environmental scientists utilize these facilities to study the effects of pollutants in water bodies or to assess the health of marine ecosystems. By simulating different scenarios, they can predict how changes in water quality or temperature might impact aquatic life. This research is critical for developing effective conservation strategies and ensuring the sustainability of our natural resources.In recent years, advancements in technology have further enhanced the capabilities of experimental model basins. With the integration of computer simulations and high-speed cameras, researchers can analyze data with greater precision and efficiency. This combination of physical experimentation and digital modeling allows for a more comprehensive understanding of fluid dynamics, pushing the boundaries of what we can achieve in this field.In conclusion, the experimental model basin is an indispensable asset in the study of fluid dynamics. Its ability to replicate real-world conditions enables researchers to conduct thorough investigations and develop innovative solutions across various disciplines. As we continue to face challenges related to climate change, pollution, and infrastructure development, the importance of experimental model basins will only grow. They not only provide a platform for scientific inquiry but also contribute to the education and training of future generations of scientists and engineers. Through ongoing research and experimentation in experimental model basins, we can better understand our environment and work towards a more sustainable future.

流体动力学的研究在工程、环境科学和海洋学等多个领域至关重要。其中一个关键工具就是实验模型水槽，它在理解流体在不同条件下的行为方面发挥着重要作用。实验模型水槽本质上是一个受控环境，研究人员可以在其中模拟和分析水流、波浪以及其他水动力现象对结构、物体或生态系统的影响。通过创建现实场景的缩小模型，科学家可以收集到通过理论计算难以获得的宝贵数据。在实验模型水槽中，可以操控各种参数，例如水深、水流速度和水槽的形状。这种灵活性使研究人员能够复制自然界可能发生的特定条件，例如潮流、风暴潮或人类活动对水域环境的影响。例如，设计沿海结构的工程师可以利用实验模型水槽测试他们的设计在强大波浪或侵蚀下的表现，从而最终导致更安全、更有效的解决方案。此外，实验模型水槽还作为一种教育工具。学生和专业人士都可以亲眼观察流体动力学原理的实际应用。通过在这些水槽中进行实验，学习者可以直观地理解复杂的概念，如湍流、浮力和阻力。这种实践经验对于加深对学科内容的理解是无价的。实验模型水槽的应用不仅限于工程。环境科学家利用这些设施研究污染物在水体中的影响，或评估海洋生态系统的健康状况。通过模拟不同的场景，他们可以预测水质或温度变化对水生生物的影响。这项研究对于制定有效的保护策略和确保我们自然资源的可持续性至关重要。近年来，技术的进步进一步增强了实验模型水槽的能力。随着计算机模拟和高速摄像机的结合，研究人员可以更精确高效地分析数据。这种物理实验与数字建模的结合，使我们对流体动力学有了更全面的理解，推动了这一领域的边界。总之，实验模型水槽是流体动力学研究中不可或缺的资产。它复制现实条件的能力使研究人员能够进行全面的调查，并在各个学科中开发创新解决方案。随着我们继续面临与气候变化、污染和基础设施发展相关的挑战，实验模型水槽的重要性只会增加。它们不仅为科学探究提供了平台，还为未来一代科学家和工程师的教育和培训做出了贡献。通过在实验模型水槽中不断进行研究和实验，我们可以更好地理解我们的环境，并朝着更可持续的未来努力。