fabricated structure

简明释义

装配式结构

英英释义

例句

1.The artist created an impressive fabricated structure for the outdoor exhibition.

艺术家为户外展览创造了一个令人印象深刻的制造结构。

2.The engineer designed a new fabricated structure to withstand extreme weather conditions.

工程师设计了一种新的制造结构以承受极端天气条件。

3.In the construction industry, a fabricated structure can significantly reduce assembly time on site.

在建筑行业中，制造结构可以显著减少现场的装配时间。

4.Architects often use fabricated structures to achieve innovative designs.

建筑师经常使用制造结构来实现创新设计。

5.This fabricated structure is made from recycled materials, promoting sustainability.

这个制造结构是由再生材料制成的，促进了可持续发展。

作文

In the modern world, engineering and architecture have evolved dramatically, leading to the creation of various innovative designs and constructions. One of the most significant advancements in this field is the use of fabricated structure, which refers to a construction that is assembled from prefabricated components rather than being built entirely on-site. This approach not only enhances efficiency but also ensures higher quality control during the construction process. The concept of fabricated structure has gained popularity due to its numerous benefits, including reduced construction time, cost-effectiveness, and the ability to create complex shapes and designs that would be challenging to achieve with traditional building methods.The process of creating a fabricated structure typically begins in a factory setting, where various materials such as steel, concrete, and wood are processed and shaped into specific components. These components are then transported to the construction site, where they are assembled to form the final structure. This method allows for better management of resources and minimizes waste, as materials can be cut and shaped with precision before reaching the site.One of the primary advantages of using fabricated structure is the significant reduction in construction time. Traditional construction methods often involve lengthy processes, including site preparation, material procurement, and on-site assembly. In contrast, prefabrication allows multiple components to be manufactured simultaneously, leading to faster completion times. For instance, commercial buildings that typically take months or even years to construct can be completed in a matter of weeks when utilizing fabricated structure techniques.Moreover, fabricated structure contributes to cost savings. By reducing labor costs and minimizing on-site delays, builders can significantly lower the overall expenses associated with a project. Additionally, the precision of prefabrication reduces the likelihood of costly errors that may arise during traditional construction methods. As a result, many developers and contractors are increasingly opting for fabricated structure solutions to stay within budget and meet tight deadlines.Another important aspect of fabricated structure is its versatility. Architects and designers can push the boundaries of creativity by utilizing prefabricated components that can be easily customized to fit specific design requirements. This flexibility allows for the creation of unique and aesthetically pleasing structures that stand out in their environments. For example, contemporary homes and commercial spaces often feature intricate designs and shapes that are made possible through the use of fabricated structure technology.However, it is essential to consider some challenges associated with fabricated structure. While the benefits are substantial, the initial design and planning phases require careful consideration to ensure that all components fit together seamlessly. Additionally, transportation logistics must be well-coordinated to prevent delays and damage to the prefabricated parts. Despite these challenges, the advantages of fabricated structure far outweigh the drawbacks, making it a preferred choice for many modern construction projects.In conclusion, the rise of fabricated structure in the construction industry represents a significant shift towards more efficient, cost-effective, and innovative building practices. As technology continues to advance, we can expect to see even more remarkable developments in the realm of prefabrication, further revolutionizing how we approach construction and design. The future of architecture will undoubtedly be shaped by the principles of fabricated structure, paving the way for a new era of sustainable and creative building solutions.

在现代世界中，工程和建筑发生了剧烈的变化，导致各种创新设计和建筑的产生。在这个领域最重要的进步之一是使用制造结构，它指的是由预制组件组装而成的建筑，而不是完全在现场建造。这种方法不仅提高了效率，还确保了在施工过程中更高的质量控制。由于其众多的好处，制造结构的概念越来越受到欢迎，包括缩短施工时间、成本效益以及能够创造复杂形状和设计，这在传统建筑方法中是具有挑战性的。创建制造结构的过程通常始于工厂环境，在这里，各种材料如钢、混凝土和木材被加工并塑造成特定的组件。这些组件然后被运输到施工现场，在那里进行组装以形成最终结构。这种方法允许更好地管理资源，并最大限度地减少浪费，因为材料可以在到达现场之前精确切割和成型。使用制造结构的主要优点之一是显著缩短施工时间。传统的建筑方法通常涉及漫长的过程，包括场地准备、材料采购和现场组装。相比之下，预制允许多个组件同时制造，从而加快完成时间。例如，通常需要数月甚至数年才能建造的商业建筑，利用制造结构技术可以在几周内完成。此外，制造结构有助于节省成本。通过降低劳动力成本和最小化现场延误，建筑商可以显著降低项目的整体费用。此外，预制的精确性减少了传统建筑方法中可能出现的昂贵错误的可能性。因此，许多开发商和承包商越来越倾向于选择制造结构解决方案，以保持预算并满足紧迫的截止日期。制造结构的另一个重要方面是其多功能性。建筑师和设计师可以通过利用易于定制的预制组件来推动创造力的边界，以适应特定的设计要求。这种灵活性使得创造独特且美观的结构成为可能，这些结构在其环境中脱颖而出。例如，当代住宅和商业空间通常具有复杂的设计和形状，这些都是通过使用制造结构技术实现的。然而，考虑与制造结构相关的一些挑战是至关重要的。虽然好处是巨大的，但初始设计和规划阶段需要仔细考虑，以确保所有组件无缝契合。此外，运输物流必须协调良好，以防止延误和对预制部件的损坏。尽管存在这些挑战，制造结构的优点远远超过缺点，使其成为许多现代建筑项目的首选。总之，制造结构在建筑行业的崛起代表着朝着更高效、经济实惠和创新建筑实践的重要转变。随着技术的不断进步，我们可以期待在预制领域看到更多显著的发展，进一步革新我们对建筑和设计的看法。建筑的未来无疑将受到制造结构原则的影响，为可持续和创造性的建筑解决方案开辟新的时代。