rigid construction

简明释义

刚性结构

英英释义

例句

1.The furniture's rigid construction (刚性结构) makes it durable and long-lasting.

家具的rigid construction（刚性结构）使其耐用且持久。

2.The rigid construction (刚性结构) of the vehicle ensures safety during collisions.

车辆的rigid construction（刚性结构）在碰撞中确保了安全。

3.Due to its rigid construction (刚性结构), the building is highly resistant to earthquakes.

由于其rigid construction（刚性结构），这座建筑对地震具有很高的抵抗力。

4.The engineer explained that the bridge's rigid construction (刚性结构) allows it to withstand heavy loads.

工程师解释说，桥梁的rigid construction（刚性结构）使其能够承受重载。

5.In robotics, a rigid construction (刚性结构) is often necessary for precise movements.

在机器人技术中，rigid construction（刚性结构）通常是精确运动所必需的。

作文

In the realm of architecture and engineering, the term rigid construction refers to a method of building that emphasizes strength and stability through the use of solid materials and fixed structural components. This approach is often utilized in designing buildings, bridges, and other infrastructures where safety and durability are paramount. The principles of rigid construction can be traced back to ancient civilizations, where structures were built to withstand the test of time and natural forces such as earthquakes and strong winds.One of the key advantages of rigid construction is its ability to provide a high level of structural integrity. By utilizing materials such as steel, concrete, and reinforced masonry, engineers can create frameworks that resist deformation under load. This is particularly important in areas prone to seismic activity, where flexible structures may fail during an earthquake. In contrast, a rigid construction design can absorb and distribute the forces exerted on it, ensuring that the building remains intact and safe for its occupants.Moreover, rigid construction allows for precise architectural designs and aesthetics. Architects can create intricate shapes and forms that are not only visually appealing but also functionally sound. For instance, the use of cantilevers and overhangs in a rigid construction framework enables the creation of unique rooflines and expansive open spaces within buildings. This versatility makes it a popular choice among modern architects who seek to push the boundaries of conventional design.However, there are also challenges associated with rigid construction. One significant drawback is the potential for higher costs due to the materials and labor required to achieve the desired strength and stability. Additionally, the inflexibility of rigid construction can lead to issues in regions where soil conditions are unstable or where the ground may shift over time. Engineers must carefully assess the site and consider factors such as soil composition and moisture content to ensure that the rigid construction will remain viable throughout its lifespan.In contrast to rigid construction, there are more flexible building methods that allow structures to adapt to environmental changes. These methods, such as post-and-beam construction or modular systems, can offer benefits in terms of cost-effectiveness and ease of assembly. However, they may not provide the same level of security and longevity as rigid construction.Ultimately, the choice between rigid construction and other building methods depends on various factors, including the intended use of the structure, the environmental conditions, and budget constraints. As urban areas continue to grow and evolve, the importance of choosing the right construction method becomes increasingly critical. With advancements in materials science and engineering techniques, the future of rigid construction looks promising, offering innovative solutions that combine strength, safety, and aesthetic appeal.In conclusion, rigid construction plays a vital role in the field of architecture and engineering, providing a robust framework for creating safe and enduring structures. While it presents certain challenges, the benefits of strength, stability, and design flexibility make it a preferred choice for many projects. As we move forward, understanding the nuances of rigid construction will be essential for architects and engineers alike, ensuring that our built environment can withstand the challenges of the future.

在建筑和工程领域，术语rigid construction指的是一种强调通过使用坚固材料和固定结构组件来增强强度和稳定性的方法。这种方法通常用于设计建筑、桥梁和其他基础设施，在这些地方，安全性和耐久性至关重要。rigid construction的原则可以追溯到古代文明，当时的结构被建造以抵御时间和自然力量的考验，例如地震和强风。rigid construction的一个主要优点是其提供高水平的结构完整性。通过利用钢、混凝土和加固砖石等材料，工程师可以创建在负载下抵抗变形的框架。这在地震活动频繁的地区尤为重要，因为灵活的结构在地震中可能会失败。相比之下，rigid construction设计能够吸收并分配施加在其上的力量，确保建筑物保持完好并对其居住者安全。此外，rigid construction允许精确的建筑设计和美学。建筑师可以创建复杂的形状和形式，这些形状不仅在视觉上吸引人，而且在功能上也合理。例如，rigid construction框架中悬臂和突出部分的使用，使建筑物能够创造独特的屋顶线和宽敞的开放空间。这种多样性使其成为现代建筑师的热门选择，他们希望突破传统设计的界限。然而，rigid construction也面临一些挑战。一个显著的缺点是由于实现所需的强度和稳定性的材料和劳动力，可能导致更高的成本。此外，rigid construction的刚性可能会导致在土壤条件不稳定或地面可能随时间变化的地区出现问题。工程师必须仔细评估现场，并考虑土壤成分和湿度等因素，以确保rigid construction在其生命周期内仍然可行。与rigid construction相反，还有一些更灵活的建筑方法，允许结构适应环境变化。这些方法，如柱梁结构或模块化系统，可以在成本效益和组装便利性方面提供好处。然而，它们可能无法提供与rigid construction相同的安全性和耐久性。最终，选择rigid construction和其他建筑方法取决于各种因素，包括结构的预期用途、环境条件和预算限制。随着城市地区的不断增长和发展，选择正确的建筑方法的重要性变得越来越关键。随着材料科学和工程技术的进步，rigid construction的未来看起来充满希望，提供结合强度、安全性和美学吸引力的创新解决方案。总之，rigid construction在建筑和工程领域发挥着至关重要的作用，为创建安全和持久的结构提供了坚实的框架。尽管它带来了一些挑战，但强度、稳定性和设计灵活性的好处使其成为许多项目的首选。随着我们向前发展，理解rigid construction的细微差别对建筑师和工程师而言至关重要，确保我们的建筑环境能够抵御未来的挑战。