thin shell construction

简明释义

薄壳结构

英英释义

例句

1.The use of thin shell construction can significantly reduce material costs while maintaining structural integrity.

使用薄壳结构可以显著降低材料成本，同时保持结构完整性。

2.Due to its efficiency, thin shell construction is often used in modern sports arenas.

由于其高效性，薄壳结构常被用于现代体育场馆中。

3.The architect decided to use thin shell construction for the new pavilion, as it allows for a lightweight yet strong structure.

建筑师决定为新展馆采用薄壳结构，因为它能够提供轻便而坚固的结构。

4.Engineers are exploring new materials to enhance the performance of thin shell construction in extreme weather conditions.

工程师们正在探索新材料，以增强薄壳结构在极端天气条件下的性能。

5.One of the key advantages of thin shell construction is its ability to span large distances without the need for internal supports.

薄壳结构的一个主要优点是能够在不需要内部支撑的情况下跨越大距离。

作文

In the realm of architecture and engineering, the concept of thin shell construction has gained significant attention for its innovative approach to structural design. This technique involves the use of thin, curved surfaces that are capable of bearing loads efficiently while minimizing the amount of material used. The beauty of thin shell construction lies not only in its aesthetic appeal but also in its ability to create strong, lightweight structures that can withstand various forces such as wind, snow, and seismic activity.Historically, the application of thin shell construction can be traced back to the early 20th century when architects and engineers began experimenting with concrete and other materials to create forms that were both functional and visually striking. One of the most notable examples is the work of architect Felix Candela, who pioneered the use of hyperbolic paraboloids in his designs. His structures demonstrated that thin shell construction could achieve remarkable strength and stability while using minimal resources.The principles behind thin shell construction are rooted in geometry and physics. The curvature of the shell distributes loads evenly across its surface, allowing it to resist bending and buckling. This characteristic makes thin shell construction particularly suitable for large-span roofs and other applications where traditional construction methods may require excessive material and result in heavier structures.One of the key advantages of thin shell construction is its sustainability. By utilizing less material, these structures not only reduce the environmental impact associated with resource extraction and processing but also lower the overall carbon footprint of the building. In an era where sustainable practices are becoming increasingly important, thin shell construction offers a viable solution for architects and builders looking to create eco-friendly designs.Moreover, thin shell construction allows for greater design flexibility. Architects can explore a range of shapes and forms that would be difficult or impossible to achieve with conventional building techniques. The fluidity and elegance of these structures often lead to iconic buildings that capture the imagination of the public. Examples include the Sydney Opera House and the TWA Flight Center at JFK Airport, both of which showcase the artistic potential of thin shell construction.However, despite its many benefits, thin shell construction does come with challenges. The construction process requires a high level of precision and expertise, as any errors in the design or execution can compromise the structural integrity of the shell. Additionally, the materials used in thin shell construction, such as reinforced concrete or fiberglass, can be more expensive than traditional options, which may deter some builders from adopting this technique.In conclusion, thin shell construction represents a fascinating intersection of art and science in the field of architecture. Its ability to create lightweight, durable, and aesthetically pleasing structures makes it a valuable approach in modern design. As we continue to seek innovative solutions to the challenges of sustainable construction, thin shell construction will undoubtedly play a crucial role in shaping the future of our built environment. By embracing this technique, architects and engineers can push the boundaries of what is possible, creating spaces that are not only functional but also inspiring.

在建筑和工程领域，薄壳结构的概念因其对结构设计的创新方法而备受关注。这种技术涉及使用薄而弯曲的表面，这些表面能够有效承载负荷，同时最小化所用材料的数量。薄壳结构的美不仅在于其美学吸引力，还在于其能够创造出强大且轻便的结构，能够承受风、雪和地震等各种力量。历史上，薄壳结构的应用可以追溯到20世纪初，当时建筑师和工程师开始尝试使用混凝土和其他材料来创建既功能性又视觉上引人注目的形式。其中一个最著名的例子是建筑师费利克斯·坎德拉的作品，他在设计中开创了使用双曲抛物面的先河。他的结构证明了薄壳结构可以以最小的资源实现显著的强度和稳定性。薄壳结构背后的原理根植于几何和物理学。壳体的曲率均匀分布负荷，使其能够抵抗弯曲和屈曲。这一特性使得薄壳结构特别适合用于大跨度屋顶和其他传统建筑方法可能需要过多材料并导致结构较重的应用。薄壳结构的一个关键优势是其可持续性。通过利用更少的材料，这些结构不仅减少了与资源开采和加工相关的环境影响，还降低了建筑的整体碳足迹。在可持续实践日益重要的时代，薄壳结构为希望创造环保设计的建筑师和施工者提供了一种可行的解决方案。此外，薄壳结构还允许更大的设计灵活性。建筑师可以探索一系列形状和形式，这在传统建筑技术中可能难以或不可能实现。这些结构的流动性和优雅性常常导致标志性建筑的出现，吸引公众的想象力。例如悉尼歌剧院和肯尼迪机场的TWA航站楼，它们都展示了薄壳结构的艺术潜力。然而，尽管有许多好处，薄壳结构也面临挑战。施工过程需要高度的精确性和专业知识，因为设计或执行中的任何错误都可能危及壳体的结构完整性。此外，薄壳结构中使用的材料，如钢筋混凝土或玻璃纤维，可能比传统选项更昂贵，这可能会阻止一些建筑商采用这种技术。总之，薄壳结构代表了建筑领域艺术与科学的迷人交汇。它创造轻便、耐用且美观的结构的能力使其成为现代设计中一种有价值的方法。随着我们继续寻求创新解决方案来应对可持续建筑的挑战，薄壳结构无疑将在塑造我们建筑环境的未来中发挥至关重要的作用。通过接受这一技术，建筑师和工程师可以突破可能性的界限，创造出既实用又鼓舞人心的空间。