allowable value of deformation of steel member

简明释义

钢构件变形容许值

英英释义

例句

1.The design team used software to simulate the allowable value of deformation of steel member 钢构件变形的允许值 under various load conditions.

设计团队使用软件模拟了在各种载荷条件下的钢构件变形的允许值 allowable value of deformation of steel member。

2.During the inspection, we found that the actual deformation exceeded the allowable value of deformation of steel member 钢构件变形的允许值.

在检查过程中，我们发现实际变形超过了钢构件变形的允许值 allowable value of deformation of steel member。

3.To comply with building codes, the project must adhere to the allowable value of deformation of steel member 钢构件变形的允许值 specified in the regulations.

为了遵守建筑规范，项目必须遵循法规中规定的钢构件变形的允许值 allowable value of deformation of steel member。

4.The engineer calculated the allowable value of deformation of steel member 钢构件变形的允许值 to ensure the structure's safety.

工程师计算了钢构件变形的允许值 allowable value of deformation of steel member以确保结构的安全性。

5.It is crucial to monitor the allowable value of deformation of steel member 钢构件变形的允许值 during heavy winds.

在强风期间，监测钢构件变形的允许值 allowable value of deformation of steel member是至关重要的。

作文

The construction industry relies heavily on the properties and behavior of different materials, particularly steel. One crucial aspect that engineers must consider when designing steel structures is the allowable value of deformation of steel member. This term refers to the maximum amount of deformation or deflection that a steel member can undergo under load without compromising its structural integrity or functionality. Understanding this concept is vital for ensuring safety, stability, and longevity in construction projects.When engineers design steel structures, they must adhere to various codes and standards that dictate the allowable value of deformation of steel member. These standards take into account factors such as the type of load (static or dynamic), the duration of the load, and the environmental conditions the structure will face. For example, a bridge exposed to heavy traffic and wind forces will have different deformation allowances compared to a residential building.The allowable value of deformation of steel member is typically expressed in terms of deflection per unit length. For instance, a common rule of thumb is that the deflection should not exceed 1/360th of the span length for beams subjected to live loads. This ensures that the structure remains comfortable and safe for occupants while also preventing damage to non-structural elements such as drywall or ceilings.In addition to deflection, engineers must also consider other forms of deformation, such as buckling and yielding. The allowable value of deformation of steel member encompasses these potential failure modes, guiding engineers in selecting appropriate steel grades and member sizes. By carefully calculating these values, engineers can optimize material usage and minimize costs while maintaining safety standards.Moreover, the allowable value of deformation of steel member is influenced by the connection details between members. If connections are rigid, the overall deformation may be less than if they are flexible. Therefore, understanding how different connection types affect deformation is essential for achieving the desired structural performance.In recent years, advancements in technology and materials science have led to the development of high-strength steels and innovative design methodologies. These advancements allow for more efficient designs that can accommodate larger spans and heavier loads while still respecting the allowable value of deformation of steel member. However, with these new materials and methods come additional challenges in accurately predicting deformation behavior, making it imperative for engineers to stay current with research and best practices.In conclusion, the allowable value of deformation of steel member is a fundamental concept in structural engineering that ensures the safety and functionality of steel structures. By understanding and applying this principle, engineers can design buildings and bridges that not only meet regulatory requirements but also serve their intended purpose effectively. As the construction industry continues to evolve, so too will the methods and materials used to ensure that the allowable value of deformation of steel member is appropriately addressed in all designs.

建筑行业在很大程度上依赖于不同材料的特性和行为，特别是钢材。当工程师在设计钢结构时，必须考虑的一个关键方面是钢构件的允许变形值。这个术语指的是钢构件在承载下可以经历的最大变形或挠度，而不会影响其结构完整性或功能。理解这一概念对于确保建筑项目的安全、稳定和耐久性至关重要。当工程师设计钢结构时，必须遵循各种规范和标准，这些规定规定了钢构件的允许变形值。这些标准考虑了负载类型（静态或动态）、负载持续时间以及结构将面临的环境条件。例如，暴露于重交通和风力的桥梁，其变形允许值与住宅建筑会有所不同。钢构件的允许变形值通常以单位长度的挠度表示。例如，一个常见的经验法则是，对于承受活荷载的梁，挠度不得超过跨度长度的1/360。这确保了结构对居住者保持舒适和安全，同时防止对非结构元素如干墙或天花板造成损害。除了挠度外，工程师还必须考虑其他形式的变形，例如屈曲和屈服。钢构件的允许变形值涵盖了这些潜在的失效模式，指导工程师选择适当的钢材等级和构件尺寸。通过仔细计算这些值，工程师可以优化材料使用，降低成本，同时保持安全标准。此外，钢构件的允许变形值还受到构件之间连接细节的影响。如果连接是刚性的，则整体变形可能小于如果它们是柔性的。因此，理解不同连接类型如何影响变形对于实现所需的结构性能至关重要。近年来，材料科学和技术的进步导致高强度钢材和创新设计方法的发展。这些进展使得能够进行更有效的设计，能够容纳更大的跨度和更重的负载，同时仍然尊重钢构件的允许变形值。然而，随着这些新材料和方法的出现，在准确预测变形行为方面也面临额外挑战，因此工程师必须时刻关注研究和最佳实践。总之，钢构件的允许变形值是结构工程中的一个基本概念，确保钢结构的安全性和功能性。通过理解和应用这一原则，工程师可以设计出不仅符合监管要求而且能有效发挥预期用途的建筑和桥梁。随着建筑行业的不断发展，用于确保钢构件的允许变形值在所有设计中得到适当考虑的方法和材料也将不断演变。