hydrodynamic load

简明释义

水动力载荷

英英释义

例句

1.During the simulations, the team observed how the hydrodynamic load 水动力荷载 influenced the design of the dam.

在模拟过程中，团队观察到水动力荷载如何影响大坝的设计。

2.The hydrodynamic load 水动力荷载 affects the performance of ships, especially in rough seas.

在恶劣海况下，水动力荷载会影响船只的性能。

3.The research focused on the impact of hydrodynamic load 水动力荷载 on marine turbines.

研究集中在水动力荷载对海洋涡轮机的影响上。

4.The bridge was designed to withstand the hydrodynamic load 水动力荷载 caused by strong river currents during floods.

这座桥梁的设计考虑了在洪水期间强河流所造成的水动力荷载。

5.Engineers must calculate the hydrodynamic load 水动力荷载 on offshore structures to ensure their stability.

工程师必须计算海上结构的水动力荷载以确保其稳定性。

作文

Understanding the concept of hydrodynamic load is essential for engineers and scientists working in fields related to fluid dynamics and structural engineering. The term hydrodynamic load refers to the forces exerted by a fluid in motion on a solid structure. This can include a variety of scenarios, such as ships navigating through water, bridges subjected to wind and rain, or offshore platforms experiencing waves and currents. The analysis of hydrodynamic load is crucial for ensuring the safety and stability of these structures under various environmental conditions.When designing structures that interact with fluids, engineers must consider the impact of hydrodynamic load on the materials and overall design. For instance, in naval architecture, the hull of a ship must be designed to withstand the forces generated by waves and water currents. If these loads are not accurately calculated, it could lead to catastrophic failures, such as capsizing or structural damage.In addition to ships, other structures such as dams and bridges also face hydrodynamic load. Dams must be engineered to handle the pressure exerted by large volumes of water, especially during heavy rainfall or flooding. Engineers must perform detailed calculations and simulations to predict how these loads will affect the integrity of the dam over time.Bridges, particularly those located near bodies of water, must also account for hydrodynamic load. Water flow can create significant forces on bridge supports, especially during floods or storms. By understanding these forces, engineers can design more resilient structures that can better withstand extreme weather conditions.The study of hydrodynamic load is not limited to large structures; it also applies to smaller systems, such as pipelines and underwater cables. These systems must be designed to resist the forces exerted by moving water, which can cause wear and tear over time. Engineers use computational fluid dynamics (CFD) to simulate how fluids interact with these structures, allowing them to optimize designs and prevent failures.Moreover, the concept of hydrodynamic load extends beyond just physical structures. It also plays a role in environmental science, where researchers study how these loads affect ecosystems. For example, the movement of water can influence sediment transport, which in turn affects habitats for aquatic life. Understanding the hydrodynamic load in these contexts can help in developing strategies for conservation and management of natural resources.In conclusion, the term hydrodynamic load encompasses a wide range of applications and implications across various fields. From ensuring the safety of maritime vessels to protecting critical infrastructure like bridges and dams, understanding this concept is vital for engineers and scientists alike. As technology continues to advance, the methods for analyzing and predicting hydrodynamic load will become even more sophisticated, leading to safer and more efficient designs in our ever-changing environment.

理解水动力载荷的概念对于从事流体动力学和结构工程领域的工程师和科学家至关重要。术语水动力载荷指的是流动中的流体对固体结构施加的力。这可以包括多种场景，例如船只在水中航行、桥梁受到风雨影响或海上平台经历波浪和水流。分析水动力载荷对于确保这些结构在各种环境条件下的安全性和稳定性至关重要。在设计与流体相互作用的结构时，工程师必须考虑水动力载荷对材料和整体设计的影响。例如，在船舶设计中，船体必须设计得能够承受波浪和水流产生的力。如果这些载荷没有被准确计算，可能会导致灾难性的失败，例如翻船或结构损坏。除了船只，其他结构如大坝和桥梁也面临水动力载荷。大坝必须设计得能够应对大量水体施加的压力，特别是在暴雨或洪水期间。工程师必须进行详细的计算和模拟，以预测这些载荷如何随着时间的推移影响大坝的完整性。尤其是位于水体附近的桥梁，也必须考虑水动力载荷。水流可以对桥梁支撑产生显著的力，尤其是在洪水或风暴期间。通过理解这些力，工程师可以设计出更有韧性的结构，更好地抵御极端天气条件。水动力载荷的研究并不局限于大型结构；它同样适用于小型系统，如管道和水下电缆。这些系统必须设计得能够抵抗流动水施加的力量，这可能会随着时间的推移造成磨损。工程师使用计算流体动力学（CFD）来模拟流体与这些结构的相互作用，从而优化设计并防止故障。此外，水动力载荷的概念不仅限于物理结构。它还在环境科学中发挥作用，研究人员研究这些载荷如何影响生态系统。例如，水的运动可以影响沉积物运输，进而影响水生生物的栖息地。在这些背景下理解水动力载荷可以帮助制定自然资源保护和管理的策略。总之，术语水动力载荷涵盖了各个领域广泛的应用和含义。从确保海洋船舶的安全到保护桥梁和大坝等关键基础设施，理解这一概念对于工程师和科学家来说都是至关重要的。随着技术的不断进步，分析和预测水动力载荷的方法将变得更加复杂，从而在我们不断变化的环境中实现更安全、更高效的设计。