twisting load

简明释义

扭力负荷

英英释义

例句

1.Proper support is essential to prevent failure from a twisting load in this design.

在这个设计中，适当的支撑对于防止因扭转载荷而导致的失效至关重要。

2.In mechanical systems, the twisting load can lead to fatigue failure over time.

在机械系统中，扭转载荷可能会随着时间的推移导致疲劳失效。

3.The engineer calculated the effects of the twisting load on the bridge's structural integrity.

工程师计算了扭转载荷对桥梁结构完整性的影响。

4.The twisting load caused significant deformation in the metal rod.

该扭转载荷导致金属杆发生显著变形。

5.During the test, the beam failed under the twisting load applied to its ends.

在测试过程中，梁在施加于其两端的扭转载荷下失效。

作文

In engineering and physics, the concept of a twisting load refers to a force that causes an object to rotate or twist around its axis. This phenomenon is crucial in various applications, such as the design of bridges, buildings, and machinery. Understanding how twisting load affects materials helps engineers create safer and more efficient structures. For instance, when a beam is subjected to a twisting load, it experiences shear stress, which can lead to deformation or failure if the material's limits are exceeded. The effects of a twisting load can be observed in everyday life. Consider the simple act of twisting a towel to wring out water. The towel experiences a twisting load as you apply force at both ends, causing it to rotate around its central axis. This example illustrates how twisting load can lead to changes in shape and structure. In engineering terms, this can be analyzed using torsion formulas, which help predict how much a material will twist under a given load.In mechanical systems, components like shafts and axles are often subjected to twisting load. When a motor turns a shaft, it generates a torque that creates a twisting load on the shaft. Engineers must ensure that these components can withstand the forces without failing. This involves selecting appropriate materials and designing for the expected loads.Moreover, understanding twisting load is vital in the context of safety. For example, in the automotive industry, the chassis of a vehicle must endure various loads, including twisting load, during operation. If the chassis is not designed to handle these forces, it could lead to structural failure, endangering passengers' lives. Therefore, engineers perform rigorous testing and simulations to ensure that vehicles can withstand twisting load under different conditions.The implications of twisting load extend beyond engineering. In sports, athletes often encounter twisting load in their movements. For instance, a gymnast performing a twist in the air experiences a twisting load that requires strength and control to execute safely. Coaches and trainers study these forces to help athletes improve their performance while minimizing the risk of injury.In conclusion, the concept of twisting load plays a critical role in various fields, from engineering to sports. By understanding how twisting load affects materials and structures, we can design safer and more efficient systems. As technology advances, the study of twisting load will continue to evolve, leading to innovative solutions and improved safety in our daily lives.

在工程和物理学中，“twisting load”的概念是指一种使物体围绕其轴线旋转或扭曲的力。这种现象在桥梁、建筑和机械的设计中至关重要。理解“twisting load”如何影响材料有助于工程师创造更安全、更高效的结构。例如，当一根梁受到“twisting load”时，它会经历剪切应力，如果超过材料的极限，就可能导致变形或失效。“twisting load”的影响可以在日常生活中观察到。考虑扭动毛巾以挤出水分的简单行为。当你在两端施加力量时，毛巾会经历“twisting load”，导致它围绕中心轴旋转。这个例子说明了“twisting load”如何导致形状和结构的变化。在工程术语中，这可以通过扭转公式进行分析，以帮助预测材料在给定负载下会扭转多少。在机械系统中，像轴和轮轴这样的组件通常会受到“twisting load”。当电动机转动一个轴时，它会产生扭矩，从而在轴上产生“twisting load”。工程师必须确保这些组件能够承受这些力而不会失效。这涉及选择适当的材料并根据预期的负载进行设计。此外，理解“twisting load”在安全方面至关重要。比如在汽车工业中，车辆的底盘必须承受各种负载，包括“twisting load”，在操作过程中。如果底盘没有设计成能够处理这些力量，可能会导致结构失效，从而危及乘客的生命。因此，工程师会进行严格的测试和模拟，以确保车辆能够在不同条件下承受“twisting load”。“twisting load”的含义超越了工程领域。在运动中，运动员在动作中经常遇到“twisting load”。例如，体操运动员在空中做扭转时，会经历“twisting load”，这需要力量和控制才能安全地执行。教练和训练师研究这些力量，以帮助运动员提高表现，同时尽量减少受伤风险。总之，“twisting load”的概念在各个领域中发挥着关键作用，从工程到运动。通过理解“twisting load”如何影响材料和结构，我们可以设计出更安全、更高效的系统。随着技术的进步，对“twisting load”的研究将继续发展，带来创新解决方案和改善我们日常生活中的安全性。