transverse frame system

简明释义

横框结构式

英英释义

例句

1.The engineer proposed a new design incorporating a transverse frame system to enhance the stability of the structure.

工程师提出了一种新设计，采用了横向框架系统以增强结构的稳定性。

2.In the construction of bridges, a transverse frame system is often used to distribute loads evenly.

在桥梁的建设中，通常使用横向框架系统来均匀分配荷载。

3.Implementing a transverse frame system can significantly reduce the risk of structural failure.

实施横向框架系统可以显著降低结构失效的风险。

4.Our team analyzed the performance of the transverse frame system under various environmental conditions.

我们的团队分析了横向框架系统在不同环境条件下的性能。

5.The transverse frame system allows for better resistance against lateral forces in high-rise buildings.

在高层建筑中，横向框架系统能更好地抵抗侧向力。

作文

In the field of structural engineering, the design and analysis of various frameworks are crucial for ensuring stability and safety. One such framework is the transverse frame system, which plays a significant role in distributing loads and resisting lateral forces. This system is particularly important in tall buildings and bridges, where wind and seismic activities can impose considerable stress on structures. Understanding how a transverse frame system functions is essential for engineers to create resilient designs that can withstand these forces.A transverse frame system consists of a series of interconnected beams and columns arranged perpendicular to the main load-bearing elements of a structure. This configuration allows for effective load transfer across the frame, enhancing the overall rigidity and stability of the building. When lateral forces, such as those caused by strong winds or earthquakes, act on a structure, the transverse frame system helps to distribute these forces evenly throughout the framework, preventing localized failure.One of the key advantages of a transverse frame system is its ability to provide lateral stability without compromising vertical load-bearing capacity. In essence, while the primary purpose of beams and columns is to support vertical loads, the transverse frame system introduces additional support that counters horizontal forces. This dual functionality makes it an invaluable component in modern architectural designs, especially in urban environments where buildings are often subjected to unpredictable weather patterns and seismic events.Moreover, the design of a transverse frame system can vary significantly based on the specific requirements of a project. Engineers must consider factors such as material selection, frame geometry, and connection details to optimize performance. For instance, using high-strength materials can enhance the durability of the frame, while innovative connection techniques can improve the overall flexibility of the system, allowing it to absorb and dissipate energy during an earthquake.In addition to its structural benefits, the transverse frame system also contributes to the aesthetic appeal of a building. Many architects incorporate exposed frames into their designs, showcasing the intricate interplay of beams and columns. This not only highlights the engineering prowess involved but also creates visually striking spaces that resonate with occupants and visitors alike.However, implementing a transverse frame system is not without challenges. Engineers must conduct thorough analyses to ensure that the system can adequately handle the expected loads and forces. Advanced simulation tools and modeling techniques are often employed to predict the behavior of the frame under various conditions, allowing for informed decision-making during the design process.Ultimately, the transverse frame system represents a critical aspect of modern structural engineering. Its ability to enhance stability, distribute loads, and contribute to aesthetic design makes it a preferred choice for many construction projects. As cities continue to grow taller and more complex, understanding and mastering the principles behind the transverse frame system will be essential for engineers striving to create safe and resilient structures that stand the test of time.

在结构工程领域，设计和分析各种框架对于确保稳定性和安全性至关重要。其中一个框架是横向框架系统，它在分配负载和抵抗侧向力方面发挥着重要作用。这个系统在高层建筑和桥梁中尤为重要，因为风和地震活动会对结构施加相当大的压力。理解横向框架系统的功能对于工程师创造能够承受这些力量的坚固设计至关重要。横向框架系统由一系列互相连接的梁和柱组成，这些梁和柱与结构的主要承重元素垂直排列。这种配置允许有效的负载传递，从而增强建筑物的整体刚度和稳定性。当强风或地震等侧向力作用于结构时，横向框架系统有助于将这些力量均匀分布到整个框架中，防止局部失效。横向框架系统的一个主要优点是它能够提供侧向稳定性，而不影响垂直承载能力。实际上，梁和柱的主要目的是支撑垂直负载，而横向框架系统引入了额外的支持，以抵消水平力量。这种双重功能使其成为现代建筑设计中不可或缺的组成部分，尤其是在城市环境中，建筑物往往会受到不可预测的天气模式和地震事件的影响。此外，横向框架系统的设计可以根据项目的具体要求有很大不同。工程师必须考虑材料选择、框架几何形状和连接细节等因素，以优化性能。例如，使用高强度材料可以增强框架的耐久性，而创新的连接技术可以改善系统的整体灵活性，使其能够在地震中吸收和耗散能量。除了结构上的好处，横向框架系统还为建筑的美学吸引力做出了贡献。许多建筑师将裸露的框架融入他们的设计中，展示梁和柱之间复杂的相互作用。这不仅突显了涉及的工程技术，还创造出视觉上引人注目的空间，使居住者和访客都能共鸣。然而，实施横向框架系统并非没有挑战。工程师必须进行彻底的分析，以确保该系统能够充分应对预期的负载和力量。通常采用先进的仿真工具和建模技术来预测框架在各种条件下的行为，从而在设计过程中做出明智的决策。最终，横向框架系统代表了现代结构工程的一个关键方面。它增强稳定性、分配负载并有助于美学设计的能力，使其成为许多建筑项目的首选。随着城市继续变得更高、更复杂，理解和掌握横向框架系统背后的原理将对努力创造安全和韧性结构的工程师至关重要，这些结构经得起时间的考验。