inclining moment

简明释义

倾侧力矩

英英释义

例句

1.To avoid failure, the architect monitored the inclining moment throughout the construction process.

为了避免失败，建筑师在整个施工过程中监测了倾斜力矩。

2.The engineer calculated the inclining moment to determine how much force would be needed to stabilize the structure.

工程师计算了倾斜力矩以确定需要多少力量来稳定结构。

3.The inclining moment of the beam was critical in ensuring the safety of the bridge.

梁的倾斜力矩对于确保桥梁的安全至关重要。

4.An excessive inclining moment can lead to structural deformation over time.

过大的倾斜力矩可能会导致结构随时间变形。

5.During the design phase, the team had to account for the inclining moment caused by lateral winds.

在设计阶段，团队必须考虑由侧风引起的倾斜力矩。

作文

The concept of an inclining moment is often discussed in the fields of physics and engineering, particularly when analyzing the behavior of structures under various forces. An inclining moment refers to the rotational effect produced by a force acting at a distance from a pivot point. This moment can cause an object to rotate or tilt, which is crucial for understanding stability and balance in physical systems.To illustrate this concept, consider a simple seesaw. When one side is pushed down, it creates an inclining moment around the pivot in the center. The force applied at the end of the seesaw generates a torque that causes the other side to rise. This example highlights how an inclining moment can lead to movement and change in position based on the forces applied.In engineering, calculating the inclining moment is essential for ensuring that structures can withstand loads without collapsing or failing. For instance, when designing a bridge, engineers must consider the weight of vehicles and pedestrians, as well as environmental factors like wind. By calculating the inclining moment at various points along the bridge, they can determine whether the structure will remain stable under different conditions.Furthermore, the inclining moment is not only relevant to static structures but also to dynamic systems. In the case of a spinning top, the forces acting upon it create an inclining moment that keeps it upright while it spins. If the forces change, such as through external interference or friction, the inclining moment can cause the top to wobble and eventually fall over. Understanding these moments allows scientists and engineers to predict the behavior of objects in motion, leading to better designs and safer products.In everyday life, we encounter inclining moments in various scenarios. For example, when we lean back in a chair, our body exerts a force that creates an inclining moment around the chair's legs. If the angle is too extreme, the chair may tip over. This simple act demonstrates how the principles of inclining moments apply to our daily experiences, influencing our interactions with the world around us.In conclusion, the inclining moment is a fundamental concept that plays a significant role in both theoretical and practical applications. From engineering structures to understanding everyday movements, recognizing the impact of inclining moments helps us grasp the dynamics of forces and their effects on stability and motion. As we continue to explore the physical world, the significance of inclining moments will undoubtedly remain a key focus in both scientific inquiry and practical engineering solutions.

“倾斜力矩”的概念常常在物理和工程领域中讨论，特别是在分析结构在各种力作用下的行为时。“倾斜力矩”是指作用在距离支点的力所产生的旋转效应。这个力矩可以导致物体旋转或倾斜，这对于理解物理系统中的稳定性和平衡至关重要。为了说明这个概念，可以考虑一个简单的跷跷板。当一侧被向下推时，它会在中心的支点周围产生一个“倾斜力矩”。作用在跷跷板末端的力产生一个扭矩，使另一侧上升。这个例子突显了“倾斜力矩”如何根据施加的力导致运动和位置变化。在工程学中，计算“倾斜力矩”对于确保结构能够承受负载而不倒塌或失效至关重要。例如，在设计桥梁时，工程师必须考虑车辆和行人的重量，以及风等环境因素。通过计算桥梁沿不同点的“倾斜力矩”，他们可以确定结构在不同条件下是否保持稳定。此外，“倾斜力矩”不仅与静态结构相关，也与动态系统有关。在陀螺旋转的情况下，作用于它的力会产生一个“倾斜力矩”，使其在旋转时保持直立。如果力量发生变化，例如通过外部干扰或摩擦，“倾斜力矩”可能导致陀螺摆动并最终倒下。理解这些力矩使科学家和工程师能够预测运动物体的行为，从而实现更好的设计和更安全的产品。在日常生活中，我们在各种场景中都会遇到“倾斜力矩”。例如，当我们向后靠在椅子上时，我们的身体施加的力会在椅子腿周围产生一个“倾斜力矩”。如果角度过于极端，椅子可能会翻倒。这个简单的动作展示了“倾斜力矩”的原理如何应用于我们的日常体验，影响我们与周围世界的互动。总之，“倾斜力矩”是一个基本概念，在理论和实际应用中都发挥着重要作用。从工程结构到理解日常运动，认识“倾斜力矩”的影响帮助我们掌握力的动态及其对稳定性和运动的影响。随着我们继续探索物理世界，“倾斜力矩”的重要性无疑将继续成为科学研究和实际工程解决方案的关键焦点。