web longitudinal stringer

简明释义

纵桁

英英释义

例句

1.The construction team installed the web longitudinal stringer 网纵向支撑梁 before proceeding with the decking.

施工团队在铺设甲板之前安装了网纵向支撑梁。

2.The engineer explained how the web longitudinal stringer 网纵向支撑梁 contributes to the overall stability of the bridge.

工程师解释了如何通过网纵向支撑梁来增强桥梁的整体稳定性。

3.The architect specified the dimensions of the web longitudinal stringer 网纵向支撑梁 to meet safety standards.

建筑师指定了网纵向支撑梁的尺寸，以符合安全标准。

4.A failure in the web longitudinal stringer 网纵向支撑梁 could lead to serious structural issues.

如果网纵向支撑梁发生故障，可能会导致严重的结构问题。

5.In the design phase, we need to ensure that the web longitudinal stringer 网纵向支撑梁 is adequately reinforced.

在设计阶段，我们需要确保网纵向支撑梁得到充分加固。

作文

In the field of engineering and architecture, various components play crucial roles in ensuring the stability and functionality of structures. One such component is the web longitudinal stringer, which is essential in the design of beams and trusses. Understanding the significance of a web longitudinal stringer can greatly enhance our appreciation of structural integrity and load distribution in constructions.The term web longitudinal stringer refers to a structural element that runs parallel to the length of a beam or truss. It is typically situated within the web of the structure, which is the part that connects the top and bottom chords of a truss. The primary function of a web longitudinal stringer is to provide additional support and enhance the load-carrying capacity of the overall structure. By distributing loads more evenly across the framework, stringers help prevent excessive bending or buckling, which can lead to structural failure.When considering the design of large structures, such as bridges or high-rise buildings, engineers must take into account various factors, including material strength, load requirements, and environmental conditions. The incorporation of web longitudinal stringers into the design process allows for a more efficient use of materials, ultimately leading to cost savings and increased safety. For instance, in a bridge design, the presence of web longitudinal stringers can significantly reduce the weight of the structure while maintaining its integrity under heavy traffic loads.Moreover, the configuration of web longitudinal stringers can vary depending on the specific requirements of a project. They may be made from steel, aluminum, or composite materials, each offering different benefits in terms of weight, strength, and durability. Engineers often conduct detailed analyses to determine the optimal arrangement and material selection for web longitudinal stringers to ensure they meet the necessary safety standards and performance expectations.In addition to their structural importance, web longitudinal stringers also play a role in the aesthetic aspect of architectural design. When incorporated thoughtfully, they can contribute to the overall visual appeal of a building or structure. For example, exposed stringers in a modern architectural design can create an industrial look, while also serving a functional purpose.Furthermore, advancements in technology have led to innovative approaches in the design and manufacturing of web longitudinal stringers. Computer-aided design (CAD) software and finite element analysis (FEA) allow engineers to simulate and optimize the performance of stringers before they are constructed. This not only improves efficiency but also enhances safety by identifying potential issues early in the design phase.In conclusion, the web longitudinal stringer is a vital component in modern engineering and architecture that contributes to the strength, stability, and aesthetics of structures. By understanding the role and significance of a web longitudinal stringer, we can better appreciate the complexities involved in creating safe and durable buildings and bridges. As technology continues to evolve, the design and implementation of web longitudinal stringers will undoubtedly advance, paving the way for even more innovative and resilient structures in the future.

在工程和建筑领域，各种组件在确保结构的稳定性和功能性方面发挥着至关重要的作用。其中一个重要组件是网状纵向支撑件，它在梁和桁架的设计中至关重要。理解网状纵向支撑件的重要性可以大大增强我们对建筑物结构完整性和负载分布的欣赏。术语网状纵向支撑件指的是沿着梁或桁架长度方向平行延伸的结构元件。它通常位于结构的网状部分，该部分连接桁架的顶部和底部弦。网状纵向支撑件的主要功能是提供额外的支持，并增强整体结构的承载能力。通过更均匀地分配负载，支撑件有助于防止过度弯曲或屈曲，这可能导致结构失效。在考虑大型结构的设计时，例如桥梁或高层建筑，工程师必须考虑多种因素，包括材料强度、负载要求和环境条件。在设计过程中加入网状纵向支撑件可以更有效地利用材料，最终实现成本节约和安全性提高。例如，在桥梁设计中，网状纵向支撑件的存在可以显著减轻结构的重量，同时在重型交通负载下保持其完整性。此外，网状纵向支撑件的配置可以根据项目的具体要求而有所不同。它们可以由钢、铝或复合材料制成，每种材料在重量、强度和耐久性方面都提供不同的优势。工程师通常会进行详细分析，以确定网状纵向支撑件的最佳布置和材料选择，以确保它们符合必要的安全标准和性能预期。除了结构重要性外，网状纵向支撑件在建筑设计的美学方面也发挥着作用。当巧妙地融入设计中时，它们可以为建筑或结构的整体视觉吸引力做出贡献。例如，现代建筑设计中的暴露支撑件可以创造一种工业外观，同时也发挥功能作用。此外，技术的进步使得在网状纵向支撑件的设计和制造中采用创新方法成为可能。计算机辅助设计（CAD）软件和有限元分析（FEA）使工程师能够在构建之前模拟和优化支撑件的性能。这不仅提高了效率，还通过在设计阶段早期识别潜在问题来增强安全性。总之，网状纵向支撑件是现代工程和建筑中一个至关重要的组件，促进了结构的强度、稳定性和美学。通过理解网状纵向支撑件的作用和重要性，我们可以更好地欣赏创建安全和耐用建筑物和桥梁所涉及的复杂性。随着技术的不断发展，网状纵向支撑件的设计和实施无疑会不断进步，为未来更具创新性和韧性的结构铺平道路。