tubular construction

简明释义

筒体结构

英英释义

例句

1.Engineers prefer tubular construction for its ability to withstand high winds.

工程师们喜欢管状结构，因为它能抵御强风。

2.The bike frame features a tubular construction that improves overall performance.

这款自行车的车架采用了管状结构，提升了整体性能。

3.In modern architecture, tubular construction is often used to create open spaces.

在现代建筑中，管状结构常用于创造开放空间。

4.The scaffolding was made from tubular construction materials for enhanced stability.

脚手架是由管状结构材料制成，以增强稳定性。

5.The bridge was designed using tubular construction, which allows for a lightweight yet strong structure.

这座桥采用了管状结构的设计，使其既轻便又坚固。

作文

The concept of tubular construction has gained significant attention in the field of architecture and engineering over the past few decades. This innovative approach involves the use of tubular structures, which are typically made from materials such as steel or reinforced concrete. The design is characterized by its hollow, cylindrical shape that provides strength and stability while minimizing the amount of material used. One of the primary advantages of tubular construction is its ability to withstand high levels of stress and load, making it an ideal choice for skyscrapers, bridges, and other large-scale structures.Historically, tubular designs can be traced back to ancient civilizations, where similar principles were applied in the construction of various structures. However, with advancements in technology and materials science, modern tubular construction has evolved to include more sophisticated techniques and applications. For instance, architects can now utilize computer-aided design (CAD) software to create intricate tubular frameworks that enhance both aesthetic appeal and structural integrity.Another significant benefit of tubular construction is its efficiency in terms of space utilization. Tubular structures often allow for larger open spaces within buildings, as the load-bearing elements can be strategically placed to support the overall design without the need for excessive columns or walls. This feature is particularly advantageous in urban environments where space is limited and maximizing usable area is crucial.Moreover, tubular construction is also recognized for its sustainability. By using less material, these structures not only reduce costs but also lower the environmental impact associated with construction. Furthermore, the durability of tubular designs means that they require less maintenance over time, contributing to a longer lifespan and reduced resource consumption in the long run.In recent years, we have witnessed a surge in the popularity of tubular construction in various projects around the world. Iconic structures such as the Willis Tower in Chicago and the Tokyo Skytree are prime examples of how this construction method can be employed to create landmark buildings that are both functional and visually striking. These structures often become symbols of innovation and progress, showcasing the potential of modern engineering.However, it is essential to recognize the challenges that come with tubular construction. While the benefits are substantial, the design and implementation process can be complex. Engineers must carefully consider factors such as wind resistance, seismic activity, and material properties to ensure the safety and longevity of the structure. Additionally, the initial costs of tubular construction can be higher than traditional methods, which may deter some developers from pursuing this innovative approach.In conclusion, tubular construction represents a fascinating intersection of technology, design, and sustainability in the modern architectural landscape. As we continue to push the boundaries of what is possible in construction, embracing methods like tubular construction will be vital in creating efficient, durable, and aesthetically pleasing structures. The future of architecture lies in our ability to adapt and innovate, and tubular construction is undoubtedly a key player in that evolution.

“管状结构”的概念在过去几十年里在建筑和工程领域引起了显著关注。这种创新的方法涉及使用管状结构，这些结构通常由钢或钢筋混凝土等材料制成。其设计特点是中空的圆柱形，既提供强度和稳定性，又最大限度地减少所用材料的数量。“管状结构”的主要优点之一是它能够承受高水平的应力和负载，使其成为摩天大楼、桥梁和其他大型结构的理想选择。历史上，管状设计可以追溯到古代文明，当时在各种结构的建造中应用了类似的原理。然而，随着技术和材料科学的进步，现代“管状结构”已经发展出更复杂的技术和应用。例如，建筑师现在可以利用计算机辅助设计（CAD）软件创建复杂的管状框架，从而增强美学吸引力和结构完整性。“管状结构”的另一个显著好处是其在空间利用方面的效率。管状结构通常允许建筑内部有更大的开放空间，因为承重元素可以被战略性地放置，以支持整体设计，而无需过多的柱子或墙壁。这一特性在城市环境中尤为重要，在这些地方，空间有限，最大化可用面积至关重要。此外，“管状结构”还因其可持续性而受到认可。通过使用更少的材料，这些结构不仅降低了成本，还减少了与建筑相关的环境影响。此外，管状设计的耐久性意味着它们在长期内需要更少的维护，从而贡献于更长的使用寿命和减少资源消耗。近年来，我们见证了全球各地对“管状结构”在各种项目中日益增长的热情。芝加哥的威利斯塔和东京天空树等标志性结构就是这种施工方法如何应用于创造既实用又视觉上引人注目的地标建筑的典范。这些结构往往成为创新和进步的象征，展示了现代工程的潜力。然而，必须认识到“管状结构”所带来的挑战。尽管好处很大，但设计和实施过程可能很复杂。工程师必须仔细考虑风阻、地震活动和材料特性等因素，以确保结构的安全性和耐久性。此外，管状结构的初始成本可能高于传统方法，这可能会阻止一些开发商追求这种创新的方法。总之，“管状结构”代表了现代建筑领域技术、设计和可持续性的迷人交汇点。随着我们继续推动建筑可能性的边界，采用像“管状结构”这样的方式将对创造高效、耐用和美观的结构至关重要。建筑的未来在于我们适应和创新的能力，而“管状结构”无疑是这一演变中的关键角色。