shell construction

简明释义

壳形结构

英英释义

例句

1.The architect presented the plans for the new building, emphasizing the importance of the shell construction in achieving energy efficiency.

建筑师展示了新建筑的计划，强调了外壳结构在实现能源效率方面的重要性。

2.The team focused on improving the shell construction to reduce maintenance costs over time.

团队专注于改善外壳结构以减少长期维护成本。

3.The shell construction of the house was designed to withstand extreme weather conditions.

这座房子的外壳结构被设计成能够抵御极端天气条件。

4.In marine engineering, shell construction is crucial for ensuring the integrity of vessels.

在海洋工程中，外壳结构对于确保船只的完整性至关重要。

5.During the workshop, we learned how to create a durable shell construction for outdoor sculptures.

在研讨会上，我们学习了如何为户外雕塑创建耐用的外壳结构。

作文

In the field of architecture and construction, the term shell construction refers to a building method that utilizes a thin, curved surface to create a structure's exterior. This technique is notable for its efficiency and aesthetic appeal, allowing architects to design buildings that are not only functional but also visually striking. The concept of shell construction can be traced back to various historical examples, such as the use of domes in ancient Roman architecture and the innovative designs of modern structures like sports arenas and exhibition halls.One of the primary advantages of shell construction is its ability to distribute loads evenly across the structure. This results in reduced material usage compared to traditional construction methods, where walls and beams are required to bear significant weight. By using a shell form, architects can create large open spaces without the need for extensive support systems. This is particularly beneficial in public buildings, where open areas are often desired for gatherings and events.Moreover, shell construction can significantly enhance the energy efficiency of a building. The aerodynamic shapes often seen in shell structures reduce wind resistance, which can lower heating and cooling costs. Additionally, the design allows for better natural lighting, as the curvature can facilitate the entry of sunlight into the interior spaces. This not only creates a pleasant environment for occupants but also contributes to sustainability by reducing reliance on artificial lighting.The versatility of shell construction is evident in its application across various building types. From the iconic Sydney Opera House to the sleek designs of modern sports complexes, this construction method has proven effective in creating diverse architectural forms. Each project showcases the unique potential of shells, whether they are made from concrete, steel, or other materials. The use of advanced technologies, such as computer-aided design (CAD) and 3D modeling, has further expanded the possibilities for architects to explore complex geometries and innovative forms using shell construction.Despite its many benefits, shell construction does come with challenges. The initial design and engineering phases can be more complex than traditional methods, requiring specialized knowledge and skills. Additionally, the construction process may demand careful planning and execution to ensure that the shell maintains its structural integrity throughout its lifespan. However, with advancements in technology and materials, these challenges are becoming increasingly manageable.In conclusion, shell construction represents a fascinating intersection of art and engineering in the built environment. Its ability to create visually stunning, efficient, and sustainable structures makes it a valuable approach in contemporary architecture. As architects continue to push the boundaries of design, we can expect to see even more innovative applications of shell construction in the future. Embracing this method not only enhances our urban landscapes but also contributes to a more sustainable and functional built environment for generations to come.

在建筑和施工领域，术语壳体结构指的是一种利用薄而弯曲的表面来创建建筑外部的建造方法。这种技术因其效率和美学吸引力而受到关注，使建筑师能够设计出既功能性又视觉上引人注目的建筑。壳体结构的概念可以追溯到各种历史实例，例如古罗马建筑中圆顶的使用，以及现代结构如体育场和展览馆的创新设计。壳体结构的主要优势之一是它能够均匀分配负荷。这导致与传统建造方法相比，材料使用量减少，因为墙壁和梁需要承受相当大的重量。通过使用壳体形式，建筑师可以创建大开间而无需广泛的支撑系统。这在公共建筑中特别有利，因为通常希望为聚会和活动提供开放的空间。此外，壳体结构可以显著提高建筑的能效。壳体结构中常见的流线型形状减少了风阻，从而降低了供暖和制冷成本。此外，该设计允许更好的自然采光，因为曲面可以促进阳光进入室内空间。这不仅为居住者创造了愉快的环境，还通过减少对人工照明的依赖，有助于可持续发展。壳体结构的多样性在其在各种建筑类型中的应用中得到了体现。从标志性的悉尼歌剧院到现代体育综合体的流线型设计，这种建造方法在创造多样化的建筑形式方面已被证明是有效的。每个项目都展示了壳体的独特潜力，无论它们是由混凝土、钢材或其他材料制成的。先进技术的使用，例如计算机辅助设计（CAD）和三维建模，进一步扩展了建筑师使用壳体结构探索复杂几何形状和创新形式的可能性。尽管有许多好处，但壳体结构也面临挑战。初始设计和工程阶段可能比传统方法更为复杂，需要专业知识和技能。此外，施工过程可能需要仔细计划和执行，以确保壳体在其生命周期内保持结构完整性。然而，随着技术和材料的进步，这些挑战正变得越来越容易管理。总之，壳体结构代表了建筑环境中艺术与工程的迷人交汇点。其创造视觉惊艳、高效且可持续结构的能力使其成为当代建筑中一种有价值的方法。随着建筑师继续推动设计的边界，我们可以期待在未来看到更多对壳体结构的创新应用。接受这种方法不仅增强了我们的城市景观，还为后代创造了一个更可持续和功能性的建筑环境。