wind-resistance model
简明释义
测定风阻模型
英英释义
例句
1.In our latest study, we tested the wind-resistance model 抗风模型 for various types of bridges.
在我们最新的研究中,我们测试了不同类型桥梁的wind-resistance model 抗风模型。
2.The wind-resistance model 抗风模型 was crucial in designing the new sports stadium.
该wind-resistance model 抗风模型在新体育场的设计中至关重要。
3.The wind-resistance model 抗风模型 helps predict how wind will affect the performance of wind turbines.
该wind-resistance model 抗风模型有助于预测风对风力涡轮机性能的影响。
4.Architects use a wind-resistance model 抗风模型 to ensure that their designs can withstand severe weather conditions.
建筑师使用wind-resistance model 抗风模型来确保他们的设计能够承受恶劣天气条件。
5.The engineers developed a new wind-resistance model 抗风模型 to improve the stability of high-rise buildings.
工程师们开发了一个新的wind-resistance model 抗风模型以提高高层建筑的稳定性。
作文
In the realm of engineering and architecture, understanding how structures interact with environmental forces is crucial. One of the key concepts in this area is the wind-resistance model (风阻模型), which helps engineers predict how buildings and other structures will respond to wind loads. This model is essential for ensuring the safety and durability of constructions, especially in areas prone to high winds or severe weather conditions.The wind-resistance model (风阻模型) is a mathematical representation that takes into account various factors such as wind speed, direction, and the physical characteristics of the structure itself. By analyzing these variables, engineers can determine the forces exerted by the wind on different parts of a building. For instance, tall skyscrapers must be designed to withstand lateral forces caused by strong winds, which can lead to swaying or even structural failure if not properly accounted for.To create an effective wind-resistance model (风阻模型), engineers often use computational fluid dynamics (CFD) simulations. These advanced simulations allow them to visualize how air flows around a structure and identify potential weak points. By running different scenarios, engineers can optimize designs to enhance stability and reduce the risk of damage during extreme weather events.Moreover, the wind-resistance model (风阻模型) is not only applicable to buildings but also to bridges, towers, and other large structures. For example, the design of suspension bridges heavily relies on these models to ensure that they can handle the dynamic forces imposed by wind. Engineers must consider how the bridge will behave under varying wind conditions, including gusts and sustained winds, to maintain safety and functionality.In addition to structural design, the wind-resistance model (风阻模型) plays a significant role in urban planning. City planners use these models to assess how wind patterns are affected by the arrangement of buildings and other infrastructure. By understanding the local wind environment, planners can make informed decisions about where to place new developments, ensuring that they do not create wind tunnels or exacerbate wind-related issues in the surrounding areas.Furthermore, advancements in technology have improved the accuracy and efficiency of wind-resistance models (风阻模型). With the integration of artificial intelligence and machine learning, engineers can analyze vast amounts of data and refine their models more quickly than ever before. This innovation allows for more resilient designs that can adapt to changing climate conditions and extreme weather patterns.In conclusion, the wind-resistance model (风阻模型) is a vital tool in the fields of engineering and architecture. It enables professionals to design structures that can withstand the forces of nature, ultimately protecting lives and investments. As technology continues to evolve, the importance of these models will only grow, making them an essential component of modern construction practices. By prioritizing wind resistance in design, we can create safer, more sustainable environments for future generations.
在工程和建筑领域,理解结构与环境力相互作用的方式至关重要。一个关键概念是风阻模型(wind-resistance model),它帮助工程师预测建筑物和其他结构如何应对风载荷。这个模型对于确保建筑物的安全性和耐久性尤其重要,特别是在容易遭受强风或恶劣天气的地区。风阻模型(wind-resistance model)是一个数学表示,考虑了各种因素,如风速、风向以及结构本身的物理特性。通过分析这些变量,工程师可以确定风对建筑物不同部分施加的力。例如,高耸的摩天大楼必须设计成能够承受强风引起的横向力,如果没有妥善考虑,这可能导致摇晃甚至结构失效。为了创建有效的风阻模型(wind-resistance model),工程师通常使用计算流体动力学(CFD)模拟。这些先进的模拟使他们能够可视化空气如何在结构周围流动,并识别潜在的薄弱点。通过运行不同的场景,工程师可以优化设计以增强稳定性,减少在极端天气事件中损坏的风险。此外,风阻模型(wind-resistance model)不仅适用于建筑物,还适用于桥梁、塔楼和其他大型结构。例如,悬索桥的设计在很大程度上依赖于这些模型,以确保它们能够承受风施加的动态力。工程师必须考虑桥梁在不同风况下的表现,包括阵风和持续风,以保持安全性和功能性。除了结构设计,风阻模型(wind-resistance model)在城市规划中也发挥着重要作用。城市规划者使用这些模型来评估建筑物和其他基础设施的排列如何影响风的模式。通过理解当地的风环境,规划者可以就新开发项目的放置做出明智的决策,确保它们不会造成风道或加剧周围地区的风相关问题。此外,技术的进步提高了风阻模型(wind-resistance model)的准确性和效率。随着人工智能和机器学习的结合,工程师可以分析大量数据并比以往更快地完善他们的模型。这一创新使得设计更具韧性,能够适应不断变化的气候条件和极端天气模式。总之,风阻模型(wind-resistance model)是工程和建筑领域的重要工具。它使专业人士能够设计能够抵御自然力量的结构,从而最终保护生命和投资。随着技术的不断发展,这些模型的重要性只会增加,使其成为现代建筑实践的基本组成部分。通过在设计中优先考虑风阻,我们可以为未来几代人创造更安全、更可持续的环境。
