shell type construction

简明释义

薄壳结构

英英释义

例句

1.The museum's exhibit on modern architecture highlighted the benefits of shell type construction for large public spaces.

博物馆关于现代建筑的展览强调了壳体结构在大型公共空间中的优势。

2.The architect proposed a new design featuring a shell type construction that would enhance the building's energy efficiency.

建筑师提出了一种新设计，采用了壳体结构，以提高建筑的能效。

3.In marine engineering, shell type construction is often used for designing ships and submarines due to its strength.

在海洋工程中，壳体结构常用于设计船只和潜艇，因为它具有强度。

4.Using shell type construction, the engineers were able to create a lightweight yet durable structure for the pavilion.

通过使用壳体结构，工程师能够为展馆创建一个轻便而耐用的结构。

5.The shell type construction of the dome allowed for natural light to flood the interior, creating a bright atmosphere.

圆顶的壳体结构使自然光能够照射到室内，营造出明亮的氛围。

作文

In the world of architecture and engineering, the term shell type construction refers to a method of building that utilizes thin, curved surfaces to create structures that are both lightweight and strong. This innovative approach has gained popularity due to its aesthetic appeal and structural efficiency. The concept is derived from natural forms, such as seashells and animal bones, which demonstrate how minimal material can support significant loads. One of the most notable examples of shell type construction is the Sydney Opera House in Australia. Designed by architect Jørn Utzon, this iconic structure features a series of large, shell-like roofs that not only serve as a visual centerpiece but also effectively distribute weight and withstand environmental forces. The use of reinforced concrete in the construction of the shells allows for greater flexibility in design while maintaining strength and durability.The advantages of shell type construction extend beyond aesthetics. These structures often require less material than traditional building methods, making them more cost-effective and environmentally friendly. By optimizing the use of materials, architects can reduce waste and lower the carbon footprint of their projects. Additionally, the aerodynamic shape of shell structures can enhance energy efficiency by minimizing wind resistance and improving natural ventilation.However, implementing shell type construction is not without its challenges. The design and engineering processes can be complex, requiring specialized knowledge and skills. Engineers must carefully calculate the load distribution and structural integrity of the shells to ensure safety and longevity. Moreover, the construction process may involve advanced techniques and equipment, which can increase project timelines and costs.Despite these challenges, the future of shell type construction looks promising. As technology advances, new materials and construction methods are being developed that make it easier to create these unique structures. Innovations in computer-aided design (CAD) and 3D printing are allowing architects to explore more intricate and ambitious designs than ever before.In conclusion, shell type construction represents a fascinating intersection of art and engineering. Its ability to create visually stunning and structurally sound buildings makes it a valuable approach in modern architecture. As we continue to face challenges related to sustainability and resource management, the principles of shell type construction will likely play an increasingly important role in shaping the built environment of the future.

在建筑和工程领域，术语壳体结构指的是一种利用薄而弯曲的表面来创建既轻便又坚固的结构的建造方法。这种创新的方法因其美学吸引力和结构效率而受到欢迎。该概念源于自然形态，如贝壳和动物骨骼，这些自然形式展示了最小材料如何支撑重载。壳体结构的一个显著例子是澳大利亚的悉尼歌剧院。由建筑师约恩·乌松设计，这一标志性建筑具有一系列大型的壳状屋顶，不仅作为视觉中心，还有效地分配重量并承受环境力量。壳体的混凝土加固使用使得设计更加灵活，同时保持强度和耐用性。壳体结构的优势不仅限于美学。这些结构通常比传统建筑方法所需的材料更少，使其更加经济和环保。通过优化材料的使用，建筑师可以减少浪费并降低项目的碳足迹。此外，壳体结构的空气动力学形状可以通过最小化风阻和改善自然通风来增强能效。然而，实施壳体结构并非没有挑战。设计和工程过程可能非常复杂，需要专业的知识和技能。工程师必须仔细计算壳体的负载分布和结构完整性，以确保安全和耐用。此外，建设过程可能涉及先进的技术和设备，这可能会增加项目的时间表和成本。尽管面临这些挑战，壳体结构的未来看起来仍然充满希望。随着技术的进步，新材料和建筑方法正在被开发，使得创建这些独特结构变得更加容易。计算机辅助设计（CAD）和3D打印等创新正在使建筑师能够探索比以往更复杂和雄心勃勃的设计。总之，壳体结构代表了艺术和工程的迷人交汇点。它创造出视觉上令人惊叹且结构稳固的建筑的能力，使其成为现代建筑中一种有价值的方法。随着我们继续面临与可持续性和资源管理相关的挑战，壳体结构的原则在塑造未来建筑环境方面可能会发挥越来越重要的作用。