calculating overturning point

简明释义

计算倾覆点

英英释义

例句

1.The engineering team used software for calculating overturning point to improve accuracy.

工程团队使用软件来计算翻转点以提高准确性。

2.For bridges, calculating overturning point is essential to avoid collapse during earthquakes.

对于桥梁来说，计算翻转点 是避免在地震中倒塌的关键。

3.In civil engineering, calculating overturning point is crucial for ensuring the stability of structures under load.

在土木工程中，计算翻转点 对于确保结构在负载下的稳定性至关重要。

4.During the design phase, calculating overturning point helps prevent potential failures in high-rise buildings.

在设计阶段，计算翻转点 有助于防止高层建筑中的潜在故障。

5.The architect spent hours calculating overturning point to ensure the building could withstand strong winds.

建筑师花了几个小时计算翻转点以确保建筑能够承受强风。

作文

In the field of engineering and physics, understanding the concept of stability is crucial for the design and analysis of structures. One of the key aspects of stability is determining when a structure will fail or overturn under certain conditions. This brings us to the term calculating overturning point, which refers to the process of identifying the specific conditions under which a structure loses its stability and begins to tip over. The calculating overturning point involves various factors such as the weight distribution of the structure, the forces acting upon it, and the support conditions that are present.For instance, consider a tall building subjected to strong winds. Engineers must perform a calculating overturning point analysis to ensure that the building can withstand these forces without toppling over. They analyze the center of gravity of the building and the wind loads to determine the maximum force that can be applied before the structure reaches its calculating overturning point. If the wind force exceeds this limit, the building could potentially overturn, leading to catastrophic consequences.Similarly, in the case of bridges, the calculating overturning point is essential for ensuring safety. When vehicles pass over a bridge, they exert dynamic loads that can change the center of gravity of the structure. Engineers must calculate the calculating overturning point to prevent any scenarios where the bridge could become unstable and collapse. This requires precise calculations and simulations to account for various load scenarios, including those caused by natural disasters like earthquakes.Moreover, the calculating overturning point is not limited to large structures; it also applies to everyday objects. For example, when stacking boxes, one must consider the calculating overturning point to avoid having the stack topple over. If the center of mass of the stacked boxes extends beyond the base of the stack, the entire structure is at risk of overturning. This principle is fundamental in various fields, including logistics and storage management, where stability is paramount.To effectively perform a calculating overturning point analysis, engineers often use mathematical models and software tools. These tools allow them to simulate different scenarios and visualize how changes in weight distribution or external forces can affect stability. The use of technology enhances the accuracy of the calculating overturning point and helps in making informed decisions during the design phase.In conclusion, the process of calculating overturning point is vital for ensuring the safety and stability of structures in engineering. By understanding the factors that contribute to stability and utilizing advanced tools for analysis, engineers can prevent failures and enhance the resilience of buildings, bridges, and other structures. As we continue to innovate and push the boundaries of design, the importance of accurately calculating overturning point will only grow, making it an essential skill for future engineers and architects.

在工程和物理学领域，理解稳定性概念对于结构的设计和分析至关重要。稳定性的一个关键方面是确定在特定条件下结构何时会失败或翻倒。这就引出了“计算翻转点”这个术语，它指的是识别结构失去稳定性并开始倾斜的特定条件的过程。“计算翻转点”涉及多个因素，例如结构的重量分布、施加在其上的力以及存在的支撑条件。例如，考虑一座受到强风影响的高楼。工程师必须进行“计算翻转点”分析，以确保建筑能够承受这些力量而不倾覆。他们分析建筑的重心和风载荷，以确定在结构达到“计算翻转点”之前可以施加的最大力。如果风力超过这个限制，建筑可能会翻倒，从而导致灾难性的后果。同样，在桥梁的情况下，“计算翻转点”对于确保安全至关重要。当车辆通过桥梁时，它们施加的动态载荷会改变结构的重心。工程师必须计算“计算翻转点”，以防止桥梁在任何情况下变得不稳定并坍塌。这需要精确的计算和模拟，以考虑各种载荷场景，包括自然灾害（如地震）造成的载荷。此外，“计算翻转点”不仅限于大型结构；它也适用于日常物品。例如，在堆放箱子时，必须考虑“计算翻转点”，以避免堆叠倾倒。如果堆叠箱子的质心超出堆叠的基础，整个结构就有翻倒的风险。这一原理在物流和存储管理等各个领域都是基础，因为稳定性至关重要。为了有效地进行“计算翻转点”分析，工程师通常使用数学模型和软件工具。这些工具使他们能够模拟不同的场景，并可视化重量分布或外部力量变化如何影响稳定性。技术的使用提高了“计算翻转点”的准确性，并有助于在设计阶段做出明智的决策。总之，“计算翻转点”的过程对于确保工程中结构的安全性和稳定性至关重要。通过理解影响稳定性的因素并利用先进的分析工具，工程师可以防止故障并增强建筑、桥梁和其他结构的韧性。随着我们不断创新并推动设计的边界，准确“计算翻转点”的重要性只会增加，使其成为未来工程师和建筑师必备的技能。