wave impact load

简明释义

波浪冲击载荷

英英释义

例句

1.The research focused on how the wave impact load 波浪冲击载荷 affects the integrity of breakwaters.

研究集中在wave impact load 波浪冲击载荷如何影响防波堤的完整性。

2.Engineers conducted simulations to evaluate the wave impact load 波浪冲击载荷 on the coastal structures.

工程师进行了模拟，以评估海岸结构上的wave impact load 波浪冲击载荷。

3.The design of the offshore platform must account for the potential wave impact load 波浪冲击载荷 during extreme weather conditions.

离岸平台的设计必须考虑在极端天气条件下可能出现的wave impact load 波浪冲击载荷。

4.Understanding the wave impact load 波浪冲击载荷 is crucial for ensuring the safety of marine vessels.

理解wave impact load 波浪冲击载荷对于确保海洋船舶的安全至关重要。

5.A detailed analysis of the wave impact load 波浪冲击载荷 was necessary to improve the design of the harbor.

对wave impact load 波浪冲击载荷的详细分析是改善港口设计所必需的。

作文

The phenomenon of waves crashing against structures is a common occurrence in coastal areas and offshore installations. Engineers and architects must consider various forces when designing these structures to ensure their safety and durability. One critical factor that needs to be accounted for is the wave impact load, which refers to the forces exerted by waves when they strike a surface. Understanding this concept is essential for preventing structural failures and ensuring the longevity of marine constructions.When a wave approaches a structure, it carries a significant amount of energy. As the wave breaks, this energy is transferred to the structure, resulting in a force that can be quite substantial. The wave impact load is not only influenced by the height of the wave but also by its speed, direction, and the angle at which it hits the structure. Engineers must analyze these factors carefully to predict the potential impact on the structure accurately.In designing coastal defenses, such as seawalls and breakwaters, understanding the wave impact load is crucial. These structures are specifically built to withstand the forces generated by waves. For instance, if the design does not adequately account for the maximum expected wave impact load, the structure may suffer from severe damage or even collapse during extreme weather conditions. This could lead to catastrophic consequences, including loss of life and property.Furthermore, the wave impact load is also relevant in the context of offshore platforms and wind turbines. These structures are often located in harsh marine environments where they are subjected to continuous wave action. Engineers must conduct thorough assessments to determine the maximum possible wave impact load that these structures will experience over their lifespan. This information is vital for ensuring that the materials used can withstand such forces without compromising the integrity of the structure.In addition to physical forces, the wave impact load can also have implications for the environmental impact of marine constructions. For example, if a structure fails due to inadequate design against wave forces, it could lead to debris being released into the ocean, harming marine life and disrupting local ecosystems. Therefore, understanding and incorporating wave impact load considerations in the design phase is not only an engineering necessity but also an environmental responsibility.To effectively manage and mitigate the risks associated with wave impact load, engineers often employ various modeling techniques. Computational fluid dynamics (CFD) simulations allow them to visualize how waves interact with structures under different conditions. By analyzing these simulations, engineers can optimize designs to better withstand the forces of waves, thereby enhancing the resilience of coastal and offshore structures.In conclusion, the concept of wave impact load is integral to the field of civil and marine engineering. By understanding the forces exerted by waves and incorporating this knowledge into design practices, engineers can create safer and more durable structures. This not only protects human life and property but also preserves the delicate balance of marine ecosystems. As climate change continues to affect wave patterns and sea levels, the importance of considering wave impact load in engineering will only grow, underscoring the need for innovative solutions in the face of evolving challenges.

波浪撞击结构的现象在沿海地区和海上设施中是常见的。工程师和建筑师在设计这些结构时，必须考虑各种力，以确保它们的安全性和耐久性。其中一个关键因素是波浪冲击载荷，指的是波浪撞击表面时施加的力量。理解这一概念对于防止结构失效和确保海洋建筑的耐用性至关重要。当波浪接近结构时，它携带着大量的能量。随着波浪的破裂，这种能量被传递到结构上，导致产生相当可观的力量。波浪冲击载荷不仅受波高的影响，还受到波速、方向以及撞击角度等因素的影响。工程师必须仔细分析这些因素，以准确预测对结构的潜在影响。在设计海岸防御设施，如海堤和防波堤时，了解波浪冲击载荷至关重要。这些结构专门建造以承受波浪产生的力量。例如，如果设计没有充分考虑最大预期的波浪冲击载荷，则结构可能会在极端天气条件下遭受严重损坏甚至倒塌。这可能导致灾难性的后果，包括生命和财产的损失。此外，波浪冲击载荷在海上平台和风力涡轮机的背景下也很相关。这些结构通常位于恶劣的海洋环境中，面临持续的波浪作用。工程师必须进行彻底评估，以确定这些结构在其生命周期内将经历的最大可能波浪冲击载荷。这一信息对确保所使用的材料能够承受这些力量而不妨碍结构的完整性至关重要。除了物理力量外，波浪冲击载荷还可能对海洋建筑的环境影响产生影响。例如，如果由于设计不足未能考虑波浪力量而导致结构失败，可能会导致碎片释放到海洋中，危害海洋生物并扰乱当地生态系统。因此，在设计阶段理解并纳入波浪冲击载荷的考虑不仅是工程上的必要性，也是环保的责任。为了有效管理和减轻与波浪冲击载荷相关的风险，工程师通常采用各种建模技术。计算流体动力学（CFD）模拟使他们能够可视化波浪在不同条件下与结构的相互作用。通过分析这些模拟，工程师可以优化设计，以更好地承受波浪的力量，从而增强海岸和海上结构的韧性。总之，波浪冲击载荷的概念是土木工程和海洋工程领域的重要组成部分。通过理解波浪施加的力量并将这些知识纳入设计实践，工程师可以创建更安全、更耐用的结构。这不仅保护人类生命和财产，还有助于维护海洋生态系统的微妙平衡。随着气候变化继续影响波浪模式和海平面，考虑波浪冲击载荷在工程中的重要性只会增加，强调了在面对不断变化的挑战时创新解决方案的必要性。