sandwich construction

简明释义

夹层结构

英英释义

例句

1.Due to its insulation properties, sandwich construction is popular in cold climates.

由于其绝缘特性，夹层结构在寒冷气候中很受欢迎。

2.The new factory was built using sandwich construction to reduce energy costs.

新工厂采用夹层结构建造，以降低能源成本。

3.The lightweight nature of sandwich construction makes it ideal for prefabricated homes.

由于夹层结构的轻质特性，它非常适合用于预制房屋。

4.In the seminar, we discussed the various materials used in sandwich construction.

在研讨会上，我们讨论了用于夹层结构的各种材料。

5.The architect explained the benefits of using sandwich construction in modern buildings.

建筑师解释了在现代建筑中使用夹层结构的好处。

作文

In the realm of architecture and engineering, one often encounters various construction techniques that enhance both the functionality and aesthetic appeal of structures. Among these methods, sandwich construction stands out as a particularly innovative approach. This technique involves creating a composite structure made up of two outer layers and a core material in between. The outer layers are typically made from strong materials such as steel or concrete, while the core can be composed of lighter materials like foam or honeycomb structures. The result is a lightweight yet robust building element that offers excellent thermal insulation and soundproofing properties.The concept of sandwich construction is not only applicable in the field of architecture but also finds its relevance in various industries, including aerospace and automotive engineering. For instance, in the manufacturing of aircraft, sandwich construction is utilized to create wings and fuselage components that require high strength-to-weight ratios. This method allows engineers to design parts that are both lightweight and capable of withstanding significant stress during flight.One of the primary advantages of sandwich construction is its efficiency in terms of material usage. By strategically selecting materials for the outer layers and core, builders can minimize waste while maximizing structural integrity. This characteristic is particularly important in today’s environmentally conscious society, where sustainable practices are becoming increasingly vital. Moreover, the thermal insulation properties of sandwich construction contribute to energy efficiency in buildings, reducing the need for heating and cooling systems and ultimately lowering energy costs.Additionally, the versatility of sandwich construction allows for a wide range of applications. It can be used in the construction of walls, roofs, and even flooring systems. The design flexibility provided by this technique enables architects to create unique and aesthetically pleasing structures that meet the specific needs of their clients. For example, a modern office building might incorporate sandwich construction to achieve a sleek, contemporary look while ensuring that the interior spaces remain comfortable and quiet.Despite its many benefits, there are challenges associated with sandwich construction. One of the primary concerns is ensuring the bond between the outer layers and the core remains strong over time. If this bond weakens, it can compromise the structural integrity of the entire system. Therefore, careful attention must be paid during the design and construction phases to select appropriate adhesives and ensure proper installation techniques are followed.In conclusion, sandwich construction is a remarkable technique that has revolutionized the way we approach building design and construction. Its ability to combine strength, lightweight properties, and excellent insulation makes it an ideal choice for various applications across multiple industries. As technology continues to advance, it is likely that we will see even more innovative uses for sandwich construction in the future, paving the way for more sustainable and efficient building practices. Ultimately, understanding and mastering this construction method will be essential for architects and engineers looking to push the boundaries of what is possible in modern design.

在建筑和工程领域，人们常常会遇到各种施工技术，这些技术不仅增强了结构的功能性，还提高了美学吸引力。在这些方法中，夹心结构作为一种特别创新的方法脱颖而出。这种技术涉及创建一个复合结构，由两层外层和中间的核心材料组成。外层通常由钢或混凝土等坚固材料制成，而核心可以由泡沫或蜂窝结构等轻质材料组成。最终的结果是一个轻巧但坚固的建筑元素，提供优良的热绝缘和隔音性能。夹心结构的概念不仅适用于建筑领域，还在航空航天和汽车工程等多个行业中具有相关性。例如，在飞机制造中，夹心结构用于制造需要高强度与重量比的机翼和机身组件。这种方法使工程师能够设计出既轻巧又能承受飞行过程中重大压力的部件。夹心结构的主要优势之一是其在材料使用方面的效率。通过战略性地选择外层和核心材料，建筑商可以减少浪费，同时最大限度地提高结构的完整性。这一特性在当今环境意识日益增强的社会中尤为重要，环保实践变得越来越关键。此外，夹心结构的热绝缘特性有助于建筑的能效，减少对供暖和制冷系统的需求，从而降低能源成本。此外，夹心结构的多样性使其适用于广泛的应用。它可以用于墙壁、屋顶甚至地板系统的建造。这种技术提供的设计灵活性使建筑师能够创建独特且美观的结构，以满足客户的具体需求。例如，一座现代办公大楼可能会采用夹心结构来实现流线型的现代外观，同时确保内部空间保持舒适和安静。尽管有许多好处，但夹心结构也面临着挑战。其中一个主要问题是确保外层和核心之间的粘合在时间上保持强度。如果这种粘合减弱，可能会危及整个系统的结构完整性。因此，在设计和施工阶段必须格外注意选择合适的胶粘剂，并确保遵循正确的安装技术。总之，夹心结构是一种了不起的技术，彻底改变了我们对建筑设计和施工的看法。它结合了强度、轻量化特性和优良的绝缘性能，使其成为多个行业各种应用的理想选择。随着技术的不断进步，我们很可能会在未来看到夹心结构的更多创新用途，为更可持续和高效的建筑实践铺平道路。最终，理解和掌握这种施工方法对于希望推动现代设计可能性的建筑师和工程师来说，将是至关重要的。