erection stress

简明释义

装配应力

英英释义

例句

1.Excessive erection stress can lead to significant damage in large structures like skyscrapers.

过度的安装应力可能导致摩天大楼等大型结构的重大损坏。

2.The engineers conducted a study to analyze the impact of erection stress on the structural integrity of the bridge.

工程师们进行了研究，以分析安装应力对桥梁结构完整性的影响。

3.The project manager emphasized the importance of controlling erection stress during the lifting operations.

项目经理强调在吊装作业中控制安装应力的重要性。

4.During the construction process, it is crucial to monitor erection stress to prevent any potential failures.

在施工过程中，监测安装应力至关重要，以防止任何潜在的故障。

5.The team used advanced software to simulate erection stress conditions before the actual assembly.

团队使用先进的软件在实际组装之前模拟安装应力条件。

作文

In the field of engineering, particularly in construction and structural design, understanding various types of stresses is crucial for ensuring safety and stability. One specific type of stress that engineers must consider during the construction phase is known as erection stress. This term refers to the stresses that occur when a structure is being assembled or erected. It is essential to analyze these stresses to prevent potential failures during the building process.When a structure is being erected, various forces are at play. These forces can include weight from materials, environmental factors like wind or seismic activity, and the dynamic loads imposed by workers and machinery. The combination of these forces leads to the development of erection stress, which can affect the integrity of the structure if not managed properly.For instance, during the erection of a steel frame building, the individual steel beams and columns must be lifted and positioned accurately. As these components are hoisted into place, they experience significant loads and forces. If the erection stress exceeds the material's yield strength, it can lead to deformation or even catastrophic failure.To mitigate the risks associated with erection stress, engineers employ several strategies. First, they conduct thorough calculations and simulations to predict how the structure will behave during erection. This includes analyzing load distributions and identifying critical points where stress concentrations may occur. By understanding these factors, engineers can design temporary supports or bracing systems that help distribute loads evenly and reduce the risk of failure.Moreover, monitoring the erection process in real-time is vital. Engineers often use sensors and other monitoring technologies to track the stresses experienced by the structure as it is being built. This data allows them to make immediate adjustments if any unexpected stresses arise, thus ensuring the safety of both the workers and the structure itself.Additionally, training and experience play a significant role in managing erection stress. Workers involved in the erection process must be well-trained to recognize potential hazards and understand the importance of following safety protocols. A skilled workforce can significantly reduce the likelihood of accidents and ensure that the structure is erected safely and efficiently.In conclusion, erection stress is a critical concept in the field of construction and structural engineering. Understanding the nature of these stresses and implementing effective management strategies is essential for ensuring the safety and longevity of structures. By conducting thorough analyses, employing monitoring technologies, and relying on skilled workers, engineers can successfully navigate the challenges posed by erection stress and contribute to the creation of safe and durable buildings. As the construction industry continues to evolve, the importance of addressing erection stress will remain a fundamental aspect of engineering practice, highlighting the need for ongoing education and innovation in this vital field.

在工程领域，特别是在建筑和结构设计中，理解各种类型的应力对于确保安全和稳定至关重要。工程师在施工阶段必须考虑的一种特定应力类型被称为安装应力。这个术语指的是在结构组装或竖立时发生的应力。分析这些应力是防止在建筑过程中潜在故障的重要措施。当一个结构正在被竖立时，各种力量正在发挥作用。这些力量可以包括材料的重量、环境因素如风或地震活动，以及工人和机械施加的动态载荷。这些力量的组合导致了安装应力的产生，如果不加以管理，可能会影响结构的完整性。例如，在钢框架建筑的竖立过程中，单个钢梁和柱必须被准确地提升和定位。当这些组件被提升到位时，它们会经历显著的载荷和力量。如果安装应力超过材料的屈服强度，就可能导致变形甚至灾难性故障。为了减轻与安装应力相关的风险，工程师采用几种策略。首先，他们进行全面的计算和模拟，以预测结构在竖立过程中的行为。这包括分析载荷分布并识别可能发生应力集中关键点。通过理解这些因素，工程师可以设计临时支撑或支撑系统，帮助均匀分配载荷，减少故障风险。此外，实时监测竖立过程至关重要。工程师通常使用传感器和其他监测技术来跟踪结构在建造过程中所经历的应力。这些数据使他们能够在出现任何意外应力时立即进行调整，从而确保工人和结构本身的安全。此外，培训和经验在管理安装应力方面也起着重要作用。参与竖立过程的工人必须经过良好的培训，以识别潜在危险并理解遵循安全协议的重要性。一支技术熟练的劳动力可以显著降低事故发生的可能性，并确保结构的安全和高效竖立。总之，安装应力是建筑和结构工程领域的一个关键概念。理解这些应力的性质并实施有效的管理策略对于确保结构的安全性和耐久性至关重要。通过进行全面的分析、采用监测技术和依靠熟练的工人，工程师可以成功应对安装应力带来的挑战，为创建安全和耐用的建筑物做出贡献。随着建筑行业的不断发展，解决安装应力的重要性将继续成为工程实践的基本方面，突显出在这一重要领域持续教育和创新的必要性。