design wave height

简明释义

计算波高

英英释义

例句

1.The design wave height 设计波高 for the new harbor was set based on the maximum recorded waves in the past decade.

新港口的设计波高 设计波高是根据过去十年记录的最大波浪设定的。

2.During the project planning phase, we need to establish the design wave height 设计波高 for accurate cost estimation.

在项目规划阶段，我们需要确定设计波高 设计波高以便准确估算成本。

3.In coastal construction, determining the design wave height 设计波高 is crucial for the safety of the structures.

在沿海建筑中，确定设计波高 设计波高对结构的安全至关重要。

4.The design wave height 设计波高 is influenced by historical weather data and local sea conditions.

设计波高 设计波高受历史气象数据和当地海洋条件的影响。

5.The engineers calculated the design wave height 设计波高 for the offshore platform to ensure its stability during storms.

工程师计算了海上平台的设计波高 设计波高，以确保其在风暴期间的稳定性。

作文

In the field of coastal engineering and offshore construction, understanding the concept of design wave height is crucial for ensuring the safety and stability of structures. The term design wave height refers to the maximum wave height that a structure is designed to withstand during its operational life. This parameter is essential in the design process because it helps engineers anticipate and mitigate the risks associated with extreme weather conditions and oceanic forces.Coastal areas and offshore environments are subject to various natural phenomena, including storms, hurricanes, and tsunamis, which can generate significant waves. These waves can pose a serious threat to marine structures such as oil rigs, wind turbines, and coastal defenses. Therefore, accurately determining the design wave height is vital for the structural integrity and longevity of these constructions.To establish the design wave height, engineers often rely on historical data, statistical analyses, and predictive models. They examine past wave patterns and meteorological conditions to estimate the maximum wave heights that could occur in a given location. This information is then used to calculate a conservative value for the design wave height, which incorporates safety factors to account for uncertainties in predictions and variations in environmental conditions.Moreover, the design wave height can vary significantly depending on the geographical location and type of structure being built. For instance, a coastal bridge may have a different design wave height compared to an offshore wind farm due to their distinct exposure to wave action. Engineers must consider local topography, bathymetry, and prevailing weather patterns when determining the appropriate design wave height for each project.In addition to structural safety, the design wave height also plays a role in economic considerations. Structures that are over-engineered to withstand excessive wave heights may incur higher construction costs, while underestimating the design wave height could lead to catastrophic failures and costly repairs. Thus, achieving a balance between safety and cost-effectiveness is a critical aspect of the design process.Furthermore, advancements in technology and modeling techniques continue to enhance our understanding of wave dynamics. Computational fluid dynamics (CFD) and other simulation tools allow engineers to visualize and predict wave behavior more accurately. As a result, the determination of design wave height is becoming increasingly sophisticated, enabling more resilient and efficient designs.In conclusion, the concept of design wave height is fundamental in coastal and offshore engineering. It serves as a key parameter in the design and construction of structures that must endure the challenges posed by the marine environment. By carefully analyzing historical data, utilizing advanced modeling techniques, and considering local conditions, engineers can establish a reliable design wave height that ensures both safety and economic viability. As we continue to face the impacts of climate change and rising sea levels, understanding and applying the principles related to design wave height will be increasingly important in safeguarding our coastal infrastructure and communities.

在海岸工程和离岸建筑领域，理解设计波高的概念对于确保结构的安全性和稳定性至关重要。术语设计波高指的是一个结构在其运营生命周期内被设计为承受的最大波高。这个参数在设计过程中是必不可少的，因为它帮助工程师预见并减轻与极端天气条件和海洋力量相关的风险。沿海地区和离岸环境受到各种自然现象的影响，包括风暴、飓风和海啸，这些现象可以产生显著的波浪。这些波浪可能对海洋结构如石油钻井平台、风力涡轮机和海岸防御设施构成严重威胁。因此，准确确定设计波高对于这些建设的结构完整性和耐久性至关重要。为了建立设计波高，工程师通常依赖历史数据、统计分析和预测模型。他们检查过去的波浪模式和气象条件，以估计在给定地点可能发生的最大波高。这些信息随后用于计算一个保守值的设计波高，该值包含安全系数，以应对预测中的不确定性和环境条件的变化。此外，设计波高可能因地理位置和所建结构类型而有显著差异。例如，沿海桥梁的设计波高可能与离岸风电场的设计波高不同，因为它们对波浪作用的暴露程度各异。工程师必须考虑当地的地形、海底地形和主导天气模式，以确定每个项目适当的设计波高。除了结构安全之外，设计波高在经济考虑中也发挥着作用。为了承受过高的波高而过度设计的结构可能会导致更高的建设成本，而低估设计波高可能会导致灾难性的故障和昂贵的修复。因此，在安全性和成本效益之间达到平衡是设计过程中的关键方面。此外，技术和建模技术的进步不断增强我们对波浪动力学的理解。计算流体动力学（CFD）和其他模拟工具使工程师能够更准确地可视化和预测波浪行为。因此，设计波高的确定变得越来越复杂，使得设计更加坚韧和高效。总之，设计波高的概念在海岸和离岸工程中是基础性的。它作为一个关键参数，用于设计和建造必须承受海洋环境挑战的结构。通过仔细分析历史数据、利用先进的建模技术以及考虑当地条件，工程师可以建立一个可靠的设计波高，以确保安全性和经济可行性。随着我们继续面临气候变化和海平面上升的影响，理解和应用与设计波高相关的原则将对保护我们的沿海基础设施和社区变得越来越重要。