stiffness of structure

简明释义

结构的劲度

英英释义

例句

1.The engineer analyzed the stiffness of structure to ensure it could withstand heavy loads.

工程师分析了结构的刚度以确保其能承受重载。

2.Increasing the stiffness of structure can help reduce vibrations during an earthquake.

增加结构的刚度可以帮助减少地震期间的震动。

3.The architect specified materials that would enhance the stiffness of structure.

建筑师指定了能够增强结构的刚度的材料。

4.To improve safety, we must evaluate the stiffness of structure in our designs.

为了提高安全性，我们必须评估我们设计中的结构的刚度。

5.The stiffness of structure directly affects the performance of bridges.

结构的刚度直接影响桥梁的性能。

作文

In the field of engineering and architecture, understanding the stiffness of structure is crucial for ensuring the stability and safety of buildings and other constructions. The term stiffness of structure refers to the ability of a structure to resist deformation under applied loads. This characteristic is fundamental when designing structures that must withstand various forces, such as wind, earthquakes, and the weight of the materials themselves.When engineers design a building, they must consider how different materials contribute to the overall stiffness of structure. For instance, steel beams are known for their high stiffness, which makes them ideal for supporting heavy loads in skyscrapers. On the other hand, materials like wood may have lower stiffness, but they can still be effectively used in certain types of structures, especially when combined with other materials to enhance overall performance.The stiffness of structure is not only important for load-bearing capacity but also plays a significant role in the comfort and safety of occupants. A structure with inadequate stiffness may sway excessively during strong winds or seismic activity, leading to discomfort for those inside and potentially causing damage to the building. Therefore, engineers use various methods and calculations to ensure that the stiffness of structure meets the required standards for safety and performance.One common approach to enhancing the stiffness of structure is through the use of bracing systems. These systems, which can include diagonal braces or shear walls, are strategically placed within a structure to provide additional support and stability. By distributing loads more evenly and preventing excessive movement, these bracing systems significantly improve the overall stiffness of the structure.Moreover, advancements in technology and materials science have led to innovative solutions for increasing the stiffness of structure. For example, the use of composite materials, which combine different substances to achieve superior properties, has become increasingly popular in modern construction. These materials can offer higher stiffness-to-weight ratios, allowing for lighter structures that maintain strength and stability.In conclusion, the stiffness of structure is a vital concept in the realms of engineering and architecture. It determines how well a building can withstand various forces while ensuring the safety and comfort of its occupants. As technology continues to evolve, the methods for enhancing the stiffness of structure will also advance, leading to more resilient and efficient buildings. Understanding this concept is essential for anyone involved in the design and construction of structures, as it directly impacts the longevity and safety of our built environment.

在工程和建筑领域，理解结构的刚度对确保建筑物和其他建筑物的稳定性和安全性至关重要。术语刚度指的是结构在施加负载下抵抗变形的能力。这一特性在设计必须承受各种力量（如风、地震和材料自身重量）的结构时是基础。当工程师设计建筑时，必须考虑不同材料如何影响整体刚度。例如，钢梁以其高刚度而闻名，使其成为支持摩天大楼重负荷的理想选择。另一方面，木材的刚度可能较低，但在某些类型的结构中仍然可以有效使用，尤其是与其他材料结合以增强整体性能时。刚度不仅对承载能力重要，还在居住者的舒适和安全中发挥着重要作用。刚度不足的结构在强风或地震活动期间可能会过度摇摆，从而导致内部人员的不适，并可能对建筑物造成损害。因此，工程师使用各种方法和计算来确保刚度符合安全和性能的要求。增强刚度的常见方法之一是使用支撑系统。这些系统可以包括对角支撑或剪切墙，战略性地放置在结构内，以提供额外的支持和稳定性。通过更均匀地分配负载并防止过度移动，这些支撑系统显著提高了结构的整体刚度。此外，技术和材料科学的进步使得增强刚度的创新解决方案成为可能。例如，复合材料的使用将不同物质结合起来以达到优越的性能，在现代建筑中越来越受欢迎。这些材料可以提供更高的刚度与重量比，使得更轻的结构能够保持强度和稳定性。总之，刚度是工程和建筑领域的重要概念。它决定了一座建筑在承受各种力量时的表现，同时确保居住者的安全和舒适。随着技术的不断发展，增强刚度的方法也将不断进步，从而导致更具韧性和效率的建筑。理解这一概念对于任何参与结构设计和建造的人来说都是至关重要的，因为它直接影响到我们建成环境的耐久性和安全性。