shell structure

简明释义

壳层结构

英英释义

例句

1.In marine engineering, a shell structure is often used for underwater vehicles.

在海洋工程中，壳体结构通常用于水下车辆。

2.Researchers are studying the aerodynamic properties of a new shell structure for aircraft.

研究人员正在研究一种新的壳体结构在飞机上的空气动力学特性。

3.The shell structure of the egg provides protection while being lightweight.

蛋的壳体结构提供保护，同时又轻便。

4.The shell structure of the dome allows it to withstand heavy loads without additional support.

圆顶的壳体结构使其能够承受重载而无需额外支撑。

5.The architect designed a stunning building with a unique shell structure that maximizes natural light.

建筑师设计了一座独特的建筑，采用了独特的壳体结构，最大限度地利用自然光。

作文

In the realm of architecture and engineering, the term shell structure refers to a thin, curved plate or surface that is designed to support loads while minimizing the amount of material used. This innovative design approach has been utilized for centuries, showcasing its versatility and effectiveness in various applications. The concept of shell structure can be traced back to ancient civilizations, where builders employed arches and domes to create strong yet lightweight structures. Modern advancements have further refined these techniques, allowing for more complex and aesthetically pleasing designs.One of the most notable examples of shell structure in contemporary architecture is the Sydney Opera House in Australia. Its iconic sail-like roofs are not only visually stunning but also demonstrate the principles of shell structure by distributing weight evenly across the surface. This allows for large open spaces within the building without the need for excessive columns or supports, creating a seamless flow of movement and light.The benefits of utilizing a shell structure extend beyond aesthetics. These structures often exhibit remarkable strength-to-weight ratios, making them ideal for a variety of applications, from sports arenas to bridges. Engineers can design shell structures to withstand environmental forces such as wind and earthquakes, ensuring safety and durability.Moreover, the use of shell structure can lead to significant cost savings in construction. By reducing the amount of material required, builders can minimize expenses while still achieving robust and functional designs. This efficiency is particularly important in today’s world, where sustainability is a growing concern. The lightweight nature of shell structures means that they require less energy to transport and assemble, contributing to a lower overall carbon footprint.In addition to their practical advantages, shell structures also offer creative opportunities for architects and designers. The fluid forms and organic shapes made possible by this construction method can inspire innovative solutions that challenge traditional architectural norms. For instance, the Eden Project in the UK features geodesic domes made of shell structures, housing diverse ecosystems and serving as a testament to the harmony between nature and human design.As we move forward into an era of rapid technological advancement, the potential for shell structure continues to expand. With the advent of new materials such as advanced composites and 3D printing technologies, architects are now able to push the boundaries of what is possible. These innovations allow for even more intricate and efficient shell structures, paving the way for future designs that were once thought to be unattainable.In conclusion, the concept of shell structure represents a fascinating intersection of art and science within the fields of architecture and engineering. Its ability to combine beauty, functionality, and sustainability makes it a valuable approach in modern design. As we continue to explore and innovate within this realm, the legacy of shell structures will undoubtedly shape the skylines of tomorrow, inspiring future generations to create even more extraordinary spaces.

在建筑和工程领域，术语壳体结构指的是一种薄而弯曲的板或表面，旨在支撑负载，同时最小化所用材料的数量。这种创新的设计方法已经被利用了几个世纪，展示了其在各种应用中的多功能性和有效性。壳体结构的概念可以追溯到古代文明，建筑师们利用拱门和圆顶来创造强大而轻便的结构。现代技术的进步进一步完善了这些技术，使得更复杂和美观的设计成为可能。当代建筑中最显著的壳体结构例子之一是澳大利亚的悉尼歌剧院。其标志性的帆状屋顶不仅在视觉上令人惊叹，而且通过均匀分配重量来展示壳体结构的原理。这使得建筑内部能够有大面积的开放空间，而不需要过多的柱子或支撑，从而创造出流畅的运动和光线流动。利用壳体结构的好处不仅限于美学。这些结构通常表现出卓越的强度与重量比，使其非常适合用于各种应用，从体育场到桥梁。工程师可以设计壳体结构以抵御风和地震等环境力量，确保安全和耐用性。此外，使用壳体结构还可以在施工中带来显著的成本节约。通过减少所需材料的数量，建筑商可以在实现稳固和功能性设计的同时降低费用。这种效率在当今世界尤为重要，因为可持续性正日益受到关注。壳体结构的轻巧特性意味着它们在运输和组装时需要更少的能源，从而有助于降低整体碳足迹。除了其实用优势外，壳体结构还为建筑师和设计师提供了创造性的机会。这种建筑方法所能实现的流畅形状和有机造型，可以激发创新解决方案，挑战传统建筑规范。例如，英国的伊登项目拥有由壳体结构制成的几何穹顶，容纳着多样的生态系统，并作为自然与人类设计之间和谐的证明。随着我们进入一个快速技术进步的时代，壳体结构的潜力仍在不断扩大。随着先进复合材料和3D打印技术等新材料的出现，建筑师现在能够突破可能性的界限。这些创新使得更加复杂和高效的壳体结构成为可能，为未来曾被认为无法实现的设计铺平了道路。总之，壳体结构的概念代表了建筑和工程领域艺术与科学的迷人交汇。它将美、功能和可持续性结合在一起，使其成为现代设计中一种宝贵的方法。随着我们继续在这一领域探索和创新，壳体结构的遗产无疑将塑造明天的天际线，激励未来几代人创造出更加非凡的空间。