plate—like space truss

简明释义

平板型网架

英英释义

例句

1.The use of a plate—like space truss allowed for larger open spaces in the community center.

使用板状空间桁架使社区中心能够拥有更大的开放空间。

2.In the design of the sports arena, a plate—like space truss was essential for supporting the expansive roof.

在体育场的设计中，板状空间桁架对于支撑宽阔的屋顶至关重要。

3.The new bridge design incorporates a plate—like space truss to enhance its structural integrity.

新桥的设计采用了板状空间桁架以增强其结构完整性。

4.The architectural firm specializes in buildings that feature a plate—like space truss for aesthetic and functional purposes.

这家建筑公司专注于具有美观和功能目的的建筑，这些建筑采用了板状空间桁架。

5.Engineers often use a plate—like space truss in large roof constructions to distribute weight evenly.

工程师们在大型屋顶建筑中常常使用板状空间桁架来均匀分配重量。

作文

In the field of structural engineering, the design and analysis of complex structures have evolved significantly over the years. One fascinating concept that has gained attention is the plate—like space truss (平面状空间桁架). This innovative structure combines the principles of plate theory with the advantages of trusses, resulting in a highly efficient and versatile system for supporting loads. Understanding the characteristics and applications of plate—like space truss is essential for engineers and architects alike.A plate—like space truss can be visualized as a three-dimensional framework that resembles a flat plate but is composed of interconnected members that form a truss. The primary advantage of this configuration is its ability to distribute loads evenly across the structure while maintaining a lightweight design. This efficiency is particularly beneficial in large-scale constructions, such as bridges, roofs, and towers, where weight reduction is critical without compromising strength.The construction of a plate—like space truss typically involves using materials such as steel or aluminum, which provide high tensile strength and durability. The arrangement of the members is crucial; they are strategically placed to ensure that forces are transferred effectively through the structure. By utilizing geometric shapes like triangles, engineers can create a stable framework that resists bending and buckling under load.One of the most significant applications of plate—like space truss systems is in the design of modern bridges. Engineers often face the challenge of spanning long distances while minimizing material use. The truss design allows for longer spans with fewer supports, resulting in a more aesthetically pleasing and functional bridge. Additionally, the lightweight nature of these structures reduces the overall load on foundations, making them ideal for various terrains and environments.Another area where plate—like space truss structures shine is in roofing systems. Large commercial buildings and sports arenas often require expansive roofs that can withstand heavy snow loads or strong winds. The use of a plate—like space truss enables architects to create open spaces free from interior columns, allowing for flexible usage of the area below. This versatility is a key reason why many contemporary buildings adopt this design approach.Moreover, the adaptability of plate—like space truss systems extends to modular construction. With the rise of prefabricated components, these trusses can be manufactured off-site and assembled on location, significantly reducing construction time and costs. This method also minimizes waste and enhances sustainability, aligning with modern engineering practices focused on environmental responsibility.In conclusion, the plate—like space truss (平面状空间桁架) represents a remarkable advancement in structural engineering. Its unique combination of strength, efficiency, and versatility makes it an ideal choice for various applications, from bridges to roofing systems. As technology continues to progress, the understanding and implementation of such innovative designs will play a crucial role in shaping the future of construction. Engineers and architects must embrace these concepts to create sustainable and resilient structures that meet the demands of our evolving world.

在结构工程领域，复杂结构的设计和分析近年来发生了显著变化。一个引人注目的概念是平面状空间桁架（plate—like space truss）。这种创新结构结合了板理论的原理与桁架的优势，形成了一种高效且多功能的承载系统。理解平面状空间桁架的特性和应用对工程师和建筑师来说至关重要。平面状空间桁架可以被视为一个三维框架，类似于一个平面，但由相互连接的构件组成，形成一个桁架。这种配置的主要优点是能够均匀地分配负载，同时保持轻量化设计。这种效率在大型建筑中尤为重要，例如桥梁、屋顶和塔楼，在这些结构中，减轻重量是关键，而不妨碍强度。平面状空间桁架的构造通常使用钢或铝等材料，这些材料提供高抗拉强度和耐久性。构件的排列至关重要；它们被战略性地放置，以确保力量有效地通过结构传递。通过利用三角形等几何形状，工程师可以创建一个稳定的框架，抵抗负载下的弯曲和屈曲。平面状空间桁架系统最重要的应用之一是在现代桥梁的设计中。工程师常常面临跨越长距离的挑战，同时最小化材料使用。桁架设计允许更长的跨度，减少支撑，从而形成一个更美观和实用的桥梁。此外，这些结构的轻量特性减少了对基础的整体负担，使它们非常适合各种地形和环境。平面状空间桁架结构在屋顶系统中也表现出色。大型商业建筑和体育场馆通常需要能够承受重雪负荷或强风的宽阔屋顶。使用平面状空间桁架使建筑师能够创建没有内部柱子的开放空间，从而灵活利用下面的区域。这种多功能性是许多当代建筑采用这种设计方法的关键原因。此外，平面状空间桁架系统的适应性扩展到模块化建筑。随着预制组件的兴起，这些桁架可以在工厂制造，然后在现场组装，大大减少了施工时间和成本。这种方法还最小化了浪费，增强了可持续性，与现代工程实践的环境责任目标一致。总之，平面状空间桁架（plate—like space truss）代表了结构工程的显著进步。其独特的强度、效率和多功能性的结合使其成为各种应用的理想选择，从桥梁到屋顶系统。随着技术的不断进步，对这些创新设计的理解和实施将在塑造未来建筑方面发挥关键作用。工程师和建筑师必须接受这些概念，以创造出满足我们不断发展的世界需求的可持续和韧性的结构。