dynamic slope deflection

简明释义

动态角变位移

英英释义

例句

1.During the seismic analysis, the dynamic slope deflection was critical in assessing the building's resilience.

在地震分析中，动态斜率偏移对于评估建筑物的抗震能力至关重要。

2.The team monitored the dynamic slope deflection of the dam to ensure its structural integrity over time.

团队监测了大坝的动态斜率偏移以确保其结构完整性。

3.To prevent landslides, the geotechnical report included measurements of dynamic slope deflection in the area.

为了防止滑坡，岩土工程报告中包含了该地区的动态斜率偏移测量。

4.The engineers calculated the dynamic slope deflection to ensure the bridge could withstand heavy traffic loads.

工程师计算了动态斜率偏移以确保桥梁能够承受重型交通负荷。

5.The software model simulated the dynamic slope deflection of the road under various weather conditions.

该软件模型模拟了道路在各种天气条件下的动态斜率偏移。

作文

In the field of structural engineering, understanding the behavior of materials and structures under various loads is crucial. One important concept in this area is dynamic slope deflection, which refers to the change in angle or displacement of a slope when subjected to dynamic forces, such as vibrations or moving loads. This phenomenon is particularly significant in the design and analysis of slopes in civil engineering projects, such as highways, embankments, and earth-retaining structures. The term dynamic slope deflection can be broken down into two components: 'dynamic' and 'slope deflection.' The word 'dynamic' implies that the conditions are changing over time, often due to external influences like seismic activity or traffic loads. On the other hand, 'slope deflection' pertains to the deviation of a slope from its original position. When these two concepts are combined, they provide insight into how slopes behave under varying conditions.One of the key reasons why understanding dynamic slope deflection is vital is that it helps engineers predict potential failures in slope stability. For instance, during an earthquake, the forces acting on a slope can cause it to shift or deform significantly. If not properly accounted for in the design phase, this could lead to catastrophic landslides or structural failures. Therefore, engineers must utilize mathematical models and simulations to analyze the effects of dynamic forces on slopes and ensure their safety and stability.Moreover, the study of dynamic slope deflection extends beyond just theoretical analysis. In practice, engineers often employ various techniques to monitor and measure slope movements. These methods include the use of inclinometers, which can detect changes in the angle of a slope, and accelerometers, which measure vibrations. By collecting data on how a slope responds to dynamic forces, engineers can make informed decisions about necessary reinforcements or modifications to existing structures.Another aspect to consider is the impact of environmental factors on dynamic slope deflection. For example, heavy rainfall can saturate soil, reducing its cohesion and making slopes more susceptible to movement under dynamic loads. Similarly, freeze-thaw cycles can weaken the integrity of slopes, leading to increased deflection during dynamic events. Thus, engineers must take these environmental considerations into account when designing and assessing slope stability.In conclusion, the concept of dynamic slope deflection plays a critical role in ensuring the safety and functionality of civil engineering projects. By understanding how slopes react to dynamic forces, engineers can better predict potential failures and implement effective monitoring strategies. As we continue to advance our knowledge and technology in this field, the importance of studying dynamic slope deflection will only grow, paving the way for safer infrastructure and improved risk management in engineering practices.

在结构工程领域，理解材料和结构在各种载荷下的行为至关重要。一个重要的概念是动态坡度偏移，它指的是在动态力（如振动或移动载荷）作用下坡度的角度或位移变化。这个现象在土木工程项目的设计和分析中尤为重要，例如高速公路、堤坝和土体支护结构。术语动态坡度偏移可以分解为两个组成部分：“动态”和“坡度偏移”。“动态”一词意味着条件随着时间的推移而变化，通常是由于外部影响，如地震活动或交通载荷。另一方面，“坡度偏移”涉及坡度从其原始位置的偏离。当这两个概念结合在一起时，它们提供了对坡度在不同条件下行为的洞察。理解动态坡度偏移的重要原因之一是它帮助工程师预测坡度稳定性潜在的失败。例如，在地震期间，作用于坡度的力可能会导致其显著移动或变形。如果在设计阶段没有正确考虑这一点，可能会导致灾难性的滑坡或结构失败。因此，工程师必须利用数学模型和模拟来分析动态力对坡度的影响，以确保其安全性和稳定性。此外，动态坡度偏移的研究不仅限于理论分析。在实践中，工程师通常采用各种技术来监测和测量坡度运动。这些方法包括使用倾斜仪，可以检测坡度角度的变化，以及加速度计，可以测量振动。通过收集坡度对动态力反应的数据，工程师可以就必要的加固或对现有结构的修改做出明智的决定。另一个需要考虑的方面是环境因素对动态坡度偏移的影响。例如，强降雨可能会使土壤饱和，降低其内聚力，使坡度在动态载荷下更容易发生移动。同样，冻融循环可能会削弱坡度的完整性，导致在动态事件中增加偏移。因此，工程师在设计和评估坡度稳定性时必须考虑这些环境因素。总之，动态坡度偏移的概念在确保土木工程项目的安全性和功能性方面起着关键作用。通过了解坡度如何对动态力作出反应，工程师可以更好地预测潜在的失败并实施有效的监测策略。随着我们在这个领域知识和技术的不断进步，研究动态坡度偏移的重要性将只会增加，为更安全的基础设施和改进的工程实践风险管理铺平道路。