wave pressure

简明释义

波浪压力

英英释义

例句

1.Understanding wave pressure 波浪压力 is crucial for designing coastal structures.

理解wave pressure 波浪压力对设计海岸结构至关重要。

2.The research focused on how wave pressure 波浪压力 affects underwater pipelines.

研究集中于wave pressure 波浪压力如何影响水下管道。

3.The team used sensors to measure wave pressure 波浪压力 in real-time.

团队使用传感器实时测量wave pressure 波浪压力。

4.During the simulation, we observed the wave pressure 波浪压力 on the seawall.

在模拟过程中，我们观察到了海堤上的wave pressure 波浪压力。

5.The engineer calculated the wave pressure 波浪压力 exerted on the bridge during a storm.

工程师计算了暴风雨期间施加在桥上的wave pressure 波浪压力。

作文

In the realm of fluid dynamics and marine engineering, understanding the concept of wave pressure is crucial. wave pressure refers to the force exerted by waves on structures such as piers, ships, and coastal defenses. This phenomenon occurs due to the movement of water particles in waves, which creates dynamic forces that can significantly impact the integrity of marine structures. As waves approach the shore, they gain energy and height, leading to increased wave pressure on any object in their path. Engineers must take this into account when designing structures to withstand the forces generated by waves. One of the primary factors influencing wave pressure is wave height. Taller waves exert greater pressure on structures because they carry more energy. When a wave breaks, it can create an even more intense surge of wave pressure, resulting in potential damage to coastal infrastructure. For instance, during storms or extreme weather events, the combination of high winds and large waves can lead to catastrophic conditions, where the wave pressure exceeds the design limits of protective barriers. Moreover, the frequency and period of waves also play a significant role in determining wave pressure. Waves that arrive more frequently can cause a cumulative effect of pressure on structures, leading to fatigue over time. Engineers often use complex mathematical models to predict wave pressure based on historical wave data, allowing them to design more resilient structures. The implications of wave pressure extend beyond just structural integrity; they also affect navigation and safety at sea. Ships must be designed to handle the varying wave pressure encountered in different sea states. The hull shape, weight distribution, and overall stability of a vessel are critical factors in ensuring that it can safely navigate through turbulent waters. If a ship is not adequately designed to withstand wave pressure, it risks capsizing or sustaining damage during rough seas. In addition to engineering applications, wave pressure has environmental implications as well. Coastal erosion is often exacerbated by the forces of waves, where consistent wave pressure against the shoreline can lead to the gradual wearing away of land. Understanding this relationship helps in developing effective coastal management strategies aimed at protecting vulnerable areas from erosion and flooding. In conclusion, wave pressure is a fundamental concept in both marine engineering and environmental science. Its effects are far-reaching, influencing the design of structures, the safety of maritime navigation, and the health of coastal ecosystems. As climate change continues to impact wave patterns and sea levels, the study of wave pressure becomes increasingly important. Engineers and scientists must collaborate to develop innovative solutions that address the challenges posed by wave pressure, ensuring the safety and sustainability of our coastal environments for future generations.

在流体动力学和海洋工程领域，理解wave pressure的概念至关重要。wave pressure是指波浪对码头、船只和海岸防护结构等建筑物施加的力量。这种现象是由于波浪中水粒子的运动造成的，产生的动态力量可能会对海洋结构的完整性产生重大影响。当波浪接近海岸时，它们会获得能量和高度，从而导致任何在其路径上的物体上施加更大的wave pressure。工程师必须考虑这一点，在设计能够承受波浪所产生的力量的结构时。影响wave pressure的主要因素之一是波高。较高的波浪对结构施加更大的压力，因为它们携带更多的能量。当波浪破裂时，它可能会产生更强烈的wave pressure冲击，导致对沿海基础设施的潜在损害。例如，在风暴或极端天气事件期间，强风和大浪的结合可能会导致灾难性的情况，其中wave pressure超过了保护屏障的设计极限。此外，波浪的频率和周期也在确定wave pressure方面发挥着重要作用。到达频率较高的波浪可能会对结构造成累积的压力效应，导致随时间推移的疲劳。工程师通常使用复杂的数学模型来预测基于历史波浪数据的wave pressure，从而使他们能够设计出更具韧性的结构。wave pressure的影响不仅限于结构完整性；它们还影响海上的航行和安全。船只必须设计成能够应对不同海况下的变化wave pressure。船体形状、重量分布和整体稳定性是确保船只能够安全通过动荡水域的关键因素。如果船只没有得到充分设计以承受wave pressure，它就有翻覆或在恶劣海况下受损的风险。除了工程应用外，wave pressure还有环境影响。海岸侵蚀通常因波浪的力量而加剧，持续的wave pressure对海岸线施加压力可能导致土地的逐渐磨损。理解这种关系有助于制定有效的海岸管理策略，旨在保护易受侵蚀和洪水影响的脆弱区域。总之，wave pressure是海洋工程和环境科学中的一个基本概念。其影响深远，影响着结构设计、海上航行安全和沿海生态系统的健康。随着气候变化继续影响波浪模式和海平面，对wave pressure的研究变得越来越重要。工程师和科学家必须合作开发创新解决方案，以应对wave pressure带来的挑战，确保我们沿海环境的安全和可持续发展，为未来几代人服务。