towing basin

简明释义

拖曳试验水池

英英释义

例句

1.During the experiment, the model was towed through the towing basin at various speeds.

在实验过程中，模型以不同速度在拖曳水池中被拖动。

2.The research vessel was tested in the towing basin to evaluate its hydrodynamic performance.

研究船在拖曳水池中进行测试，以评估其水动力性能。

3.The new yacht design showed promising results after testing in the towing basin.

新的游艇设计在拖曳水池测试后显示出良好的结果。

4.Engineers often use a towing basin to simulate real-world conditions for ship models.

工程师们常常使用拖曳水池来模拟船舶模型的实际条件。

5.The university's towing basin is one of the largest in the country.

该大学的拖曳水池是全国最大的之一。

作文

The concept of a towing basin is crucial in the field of naval architecture and marine engineering. A towing basin is a specialized facility designed for testing the hydrodynamic performance of ships and other floating structures. It is essentially a large, controlled water tank where models or full-scale vessels can be towed through the water to measure various performance metrics such as resistance, propulsion, and maneuverability. The significance of a towing basin lies in its ability to provide accurate data that can inform the design and optimization of marine vessels.In a typical towing basin, a model of the vessel is placed in the water, and a towing carriage moves the model at varying speeds. This allows engineers to observe how the model interacts with the water, including the effects of waves, currents, and other environmental factors. By analyzing the data collected during these tests, engineers can make informed decisions about the hull design, propulsion systems, and overall efficiency of the vessel.One of the primary advantages of using a towing basin is the ability to conduct experiments in a controlled environment. Unlike real-world testing, which can be influenced by unpredictable weather conditions and sea states, a towing basin provides a stable setting for experimentation. This control enables researchers to isolate specific variables and obtain more reliable results.Moreover, the use of a towing basin can significantly reduce the time and costs associated with the ship design process. By identifying potential issues early in the design phase, engineers can make adjustments before constructing a full-sized vessel, thereby saving resources and minimizing risks. This proactive approach not only enhances the performance of the final product but also contributes to the safety and sustainability of marine operations.In addition to traditional shipbuilding, towing basins are also used in the development of various marine technologies, such as underwater vehicles, offshore structures, and renewable energy devices like tidal turbines. As the maritime industry continues to evolve, the role of towing basins becomes increasingly important in ensuring that new designs meet the rigorous demands of modern marine environments.Furthermore, advancements in technology have allowed for the integration of computer simulations and modeling alongside physical tests conducted in a towing basin. Computational fluid dynamics (CFD) can complement the data obtained from physical tests, providing a more comprehensive understanding of a vessel's performance. This combination of experimental and computational methods leads to more efficient design processes and improved performance predictions.In conclusion, the towing basin is an indispensable tool in the marine engineering field. Its ability to simulate real-world conditions in a controlled environment allows for the thorough testing and optimization of marine vessels. As the industry moves towards more innovative and sustainable designs, the importance of towing basins will only continue to grow, ensuring that future vessels are not only efficient but also safe and environmentally friendly.

拖曳水池的概念在船舶设计和海洋工程领域至关重要。拖曳水池是一个专门的设施，旨在测试船舶和其他浮动结构的水动力性能。它本质上是一个大型的、受控的水槽，在这里可以将模型或全尺度的船舶在水中拖曳，以测量各种性能指标，如阻力、推进和操纵性。拖曳水池的重要性在于它能够提供准确的数据，这些数据可以为船舶的设计和优化提供信息。在一个典型的拖曳水池中，船舶的模型被放置在水中，拖曳小车以不同的速度移动模型。这使得工程师能够观察模型与水的相互作用，包括波浪、潮流和其他环境因素的影响。通过分析在这些测试过程中收集的数据，工程师可以对船体设计、推进系统和整体效率做出明智的决策。使用拖曳水池的主要优点之一是能够在受控环境中进行实验。与真实世界的测试不同，真实世界的测试可能受到不可预测的天气条件和海洋状态的影响，而拖曳水池则提供了一个稳定的实验环境。这种控制使研究人员能够隔离特定变量并获得更可靠的结果。此外，使用拖曳水池可以显著减少船舶设计过程中的时间和成本。通过在设计阶段早期识别潜在问题，工程师可以在建造全尺寸船舶之前进行调整，从而节省资源并降低风险。这种主动的方法不仅提高了最终产品的性能，还促进了海洋作业的安全性和可持续性。除了传统的造船，拖曳水池还用于各种海洋技术的发展，例如水下车辆、海洋结构和潮汐涡轮等可再生能源设备。随着海事行业的不断发展，拖曳水池在确保新设计满足现代海洋环境的严格要求方面变得越来越重要。此外，技术的进步使得计算机模拟和建模可以与在拖曳水池中进行的物理测试相结合。计算流体动力学（CFD）可以补充从物理测试中获得的数据，提供对船舶性能的更全面理解。这种实验和计算方法的结合导致了更高效的设计过程和改进的性能预测。总之，拖曳水池是海洋工程领域不可或缺的工具。它能够在受控环境中模拟真实世界条件，使得对海洋船舶进行彻底的测试和优化成为可能。随着行业朝着更具创新性和可持续性的设计发展，拖曳水池的重要性只会继续增长，确保未来的船舶不仅高效，而且安全和环保。