stressed skin construction

简明释义

蒙皮受力式结构

英英释义

例句

1.The use of stressed skin construction allowed for lighter and more efficient building materials.

使用应力皮肤结构使得建筑材料更轻，更高效。

2.The architect proposed a design that utilized stressed skin construction to enhance the building's structural integrity.

建筑师提出了一种设计，采用了应力皮肤结构来增强建筑的结构完整性。

3.Many modern bridges employ stressed skin construction techniques to withstand heavy loads.

许多现代桥梁采用应力皮肤结构技术以承受重载。

4.The designer explained how stressed skin construction can reduce the overall weight of a structure.

设计师解释了如何通过应力皮肤结构减少结构的整体重量。

5.In aerospace engineering, stressed skin construction is crucial for maintaining the durability of aircraft wings.

在航空航天工程中，应力皮肤结构对于保持飞机机翼的耐用性至关重要。

作文

In modern architecture and engineering, the concept of stressed skin construction has gained significant attention for its innovative approach to building design. This method involves the use of thin, lightweight materials that are capable of bearing loads through tension and compression. The idea is that the skin of the structure itself contributes to its overall strength, allowing for more efficient use of materials and creating aesthetically pleasing designs. Structures utilizing stressed skin construction often exhibit a unique combination of beauty and functionality, making them popular choices for various applications ranging from residential homes to large commercial buildings.One of the key advantages of stressed skin construction is its ability to reduce the weight of a building without compromising its structural integrity. Traditional construction methods often rely on heavy materials, which can lead to increased costs and longer construction times. In contrast, stressed skin construction allows architects and engineers to create lighter structures that are easier to transport and assemble. This not only saves time and money but also minimizes the environmental impact associated with heavy construction materials.Moreover, stressed skin construction offers enhanced energy efficiency. The use of insulated panels in the building's skin can significantly reduce heat loss in colder climates and keep interiors cool in warmer regions. This results in lower energy consumption for heating and cooling, ultimately leading to reduced utility bills for occupants. Additionally, the streamlined design of stressed skin construction can contribute to improved airflow and natural lighting within the building, further enhancing the living or working environment.The versatility of stressed skin construction also makes it suitable for various architectural styles. From sleek, modern designs to more traditional aesthetics, this construction method can be adapted to meet the specific needs and preferences of different projects. For instance, the iconic Sydney Opera House is an example of how stressed skin construction can be used to create a visually stunning structure that stands out in its environment while maintaining structural efficiency.However, it is important to note that stressed skin construction does come with its own set of challenges. Proper engineering and design are crucial to ensure that the materials used can withstand the forces they will encounter. This requires a deep understanding of material properties and load distribution, which can complicate the design process. Furthermore, maintenance of stressed skin construction buildings may require specialized knowledge and techniques to address potential issues such as wear and tear or environmental damage.In conclusion, stressed skin construction represents a remarkable advancement in the field of architecture and engineering. Its ability to combine lightweight materials with structural strength offers numerous benefits, including cost savings, energy efficiency, and aesthetic appeal. As the demand for sustainable and innovative building solutions continues to grow, it is likely that stressed skin construction will play an increasingly important role in shaping the future of our built environment. By embracing this approach, we can create structures that not only meet the needs of today but also pave the way for a more sustainable future.

在现代建筑和工程中，应力皮肤结构的概念因其创新的建筑设计方法而受到广泛关注。这种方法涉及使用薄而轻的材料，这些材料能够通过拉伸和压缩承载负荷。这个理念是，结构的外壳本身有助于其整体强度，从而更有效地利用材料，并创造出美观的设计。利用应力皮肤结构的结构通常展现出美丽与功能性的独特结合，使其成为从住宅到大型商业建筑等各种应用的热门选择。应力皮肤结构的一大优势是它能够在不妨碍结构完整性的情况下减轻建筑物的重量。传统的建筑方法往往依赖于重型材料，这可能导致成本增加和施工时间延长。相比之下，应力皮肤结构使建筑师和工程师能够创建更轻的结构，这些结构更易于运输和组装。这不仅节省了时间和金钱，而且最小化了与重型建筑材料相关的环境影响。此外，应力皮肤结构还提供了更高的能效。在建筑外壳中使用绝缘面板可以显著减少寒冷气候中的热量损失，并在温暖地区保持室内凉爽。这导致了供暖和制冷的能耗降低，最终使居住者的水电费减少。此外，应力皮肤结构的流线型设计可以促进建筑内部的空气流通和自然采光，进一步改善生活或工作环境。应力皮肤结构的多样性也使其适用于各种建筑风格。从时尚的现代设计到更传统的美学，这种建筑方法可以根据不同项目的具体需求和偏好进行调整。例如，悉尼歌剧院就是一个例子，展示了如何利用应力皮肤结构创造出一座在环境中脱颖而出的视觉惊艳的建筑，同时保持结构的效率。然而，重要的是要注意，应力皮肤结构确实存在着自身的一系列挑战。确保所用材料能够承受它们将遇到的力量需要适当的工程和设计。这需要对材料特性和负载分布有深入的理解，这可能会使设计过程变得复杂。此外，维护应力皮肤结构建筑可能需要专业知识和技术，以解决潜在的问题，例如磨损或环境损害。总之，应力皮肤结构代表了建筑和工程领域的显著进步。它将轻质材料与结构强度相结合，带来了许多好处，包括成本节约、能效和美观。随着对可持续和创新建筑解决方案的需求不断增长，应力皮肤结构在塑造我们未来的建筑环境方面将发挥越来越重要的作用。通过拥抱这种方法，我们可以创建出不仅满足今天需求的结构，也为更可持续的未来铺平道路。