plane trussed lattice grids

简明释义

平面桁架系网架

英英释义

例句

1.The engineers designed a series of plane trussed lattice grids to support the weight of the new bridge.

工程师们设计了一系列平面桁架格栅来支撑新桥的重量。

2.The construction team utilized plane trussed lattice grids to create a lightweight yet sturdy roof structure.

施工团队利用平面桁架格栅构建了一个轻质而坚固的屋顶结构。

3.The use of plane trussed lattice grids in the design reduced material costs significantly.

在设计中使用平面桁架格栅显著降低了材料成本。

4.During the project, we had to analyze the load distribution on the plane trussed lattice grids to ensure safety.

在项目期间，我们必须分析平面桁架格栅上的载荷分布以确保安全。

5.In architectural design, plane trussed lattice grids can provide both strength and aesthetic appeal.

在建筑设计中，平面桁架格栅既能提供强度又能增加美感。

作文

In the field of engineering and architecture, the concept of structural design plays a crucial role in ensuring the stability and durability of buildings and other infrastructures. One of the innovative approaches to structural design is the use of plane trussed lattice grids, which are characterized by their lightweight yet robust framework that can efficiently distribute loads across various points. The term plane trussed lattice grids refers to a two-dimensional grid structure composed of interconnected members, typically arranged in a triangular or polygonal pattern. This configuration not only enhances the strength of the structure but also minimizes the amount of material required, making it an environmentally friendly option in construction. The application of plane trussed lattice grids can be seen in various architectural marvels around the world. For instance, the design of modern bridges often incorporates these grids to ensure that they can withstand heavy traffic and environmental stresses while maintaining a sleek appearance. Similarly, large-span roofs in sports arenas and exhibition centers frequently utilize plane trussed lattice grids to create open spaces without the need for numerous supporting columns. This design freedom allows architects to explore creative possibilities while ensuring safety and functionality. From a technical perspective, the advantages of plane trussed lattice grids extend beyond their aesthetic appeal. The triangular shapes formed within the grid provide inherent stability, meaning that the structure can effectively resist bending and twisting forces. Additionally, because the load is distributed evenly across the grid, individual members experience less stress, which can prolong the lifespan of the materials used. Engineers often use advanced software to simulate and analyze the behavior of plane trussed lattice grids under different conditions, ensuring that the final design meets all safety standards. Moreover, the versatility of plane trussed lattice grids allows them to be employed in various contexts, from temporary structures like exhibition pavilions to permanent installations such as skyscrapers. As the demand for sustainable building practices grows, the efficiency of these grids makes them an attractive option for minimizing waste and reducing carbon footprints. By optimizing material usage, plane trussed lattice grids contribute to a more sustainable future in construction. In conclusion, the integration of plane trussed lattice grids into modern architecture and engineering represents a significant advancement in structural design. Their ability to combine strength, efficiency, and aesthetic appeal makes them a preferred choice for many architects and engineers. As technology continues to evolve, we can expect to see even more innovative uses of plane trussed lattice grids in the construction industry, paving the way for a new era of sustainable and resilient infrastructure. Understanding the principles behind plane trussed lattice grids is essential for anyone interested in the future of building design and engineering, as they embody the intersection of creativity, functionality, and sustainability.

在工程和建筑领域，结构设计的概念在确保建筑物和其他基础设施的稳定性和耐久性方面发挥着至关重要的作用。结构设计的一种创新方法是使用平面桁架格栅，其特点是轻巧而坚固的框架，可以有效地将荷载分布到各个点。术语平面桁架格栅指的是一种由相互连接的构件组成的二维网格结构，通常以三角形或多边形的形式排列。这种配置不仅增强了结构的强度，还最小化了所需材料的数量，使其成为建筑中环保的选择。平面桁架格栅的应用可以在世界各地的各种建筑奇迹中看到。例如，现代桥梁的设计通常采用这些格栅，以确保它们能够承受重型交通和环境压力，同时保持流线型外观。同样，体育场馆和展览中心的大跨度屋顶经常利用平面桁架格栅来创造开放空间，而不需要众多支撑柱。这种设计自由使建筑师能够探索创造性的可能性，同时确保安全和功能性。从技术角度来看，平面桁架格栅的优点不仅限于其美学吸引力。网格中形成的三角形提供了固有的稳定性，这意味着结构可以有效抵抗弯曲和扭转力。此外，由于荷载均匀分布在网格上，单个构件承受的应力较小，这可以延长所用材料的使用寿命。工程师通常使用先进的软件来模拟和分析平面桁架格栅在不同条件下的行为，确保最终设计符合所有安全标准。此外，平面桁架格栅的多功能性使其可以在各种环境中使用，从临时结构如展览亭到永久性安装如摩天大楼。随着对可持续建筑实践的需求不断增长，这些格栅的效率使其成为最小化浪费和减少碳足迹的有吸引力的选择。通过优化材料使用，平面桁架格栅为建筑的可持续未来做出贡献。总之，将平面桁架格栅融入现代建筑和工程中，代表了结构设计的重要进步。它们结合强度、效率和美学吸引力的能力，使其成为许多建筑师和工程师的首选。随着技术的不断发展，我们可以期待在建筑行业看到更多对平面桁架格栅的创新使用，为可持续和韧性基础设施的新纪元铺平道路。理解平面桁架格栅背后的原理对于任何对建筑设计和工程未来感兴趣的人来说都是至关重要的，因为它们体现了创造力、功能性和可持续性的交汇点。