torsion strength

简明释义

抗扭强度

英英释义

例句

1.The new alloy was developed to enhance the torsion strength 扭转强度 of automotive parts.

新合金的开发旨在增强汽车零件的torsion strength扭转强度。

2.During the manufacturing process, we must ensure that the torsion strength 扭转强度 meets industry standards.

在制造过程中，我们必须确保torsion strength扭转强度符合行业标准。

3.The engineers tested the material to determine its torsion strength 扭转强度 before using it in the bridge design.

工程师在桥梁设计中使用材料之前，测试了其torsion strength扭转强度。

4.The testing lab specializes in measuring the torsion strength 扭转强度 of various materials.

该测试实验室专门测量各种材料的torsion strength扭转强度。

5.A higher torsion strength 扭转强度 is crucial for components that will undergo twisting forces.

对于会承受扭转力的部件来说，更高的torsion strength扭转强度至关重要。

作文

Torsion is a fundamental concept in mechanics that refers to the twisting of an object due to an applied torque. When a force is applied to an object, it can cause the object to rotate around its axis, leading to internal stresses. One of the critical properties that determine how well a material can withstand these twisting forces is its torsion strength. The torsion strength (扭转强度) of a material is defined as the maximum amount of torque that a material can endure before it begins to deform or fail. This property is particularly important in engineering and design, where components are often subjected to twisting forces during operation.Understanding torsion strength is essential for engineers when selecting materials for various applications. For example, in the design of shafts, beams, and other structural elements, it is crucial to ensure that the selected material can handle the expected loads without failing. If a material has a low torsion strength (扭转强度), it may twist and break under stress, leading to catastrophic failures in machinery or structures.The torsion strength (扭转强度) of a material is influenced by several factors, including its composition, microstructure, and temperature. Different materials exhibit varying levels of torsion strength. For instance, metals such as steel typically have high torsion strength (扭转强度) compared to plastics or wood. This is why steel is often used in applications where high strength and durability are required.In practical terms, engineers often conduct tests to determine the torsion strength (扭转强度) of materials. One common method is the torsion test, where a sample is twisted until it fails. The results of this test provide valuable data that can be used to predict how a material will behave under real-world conditions. By analyzing the results, engineers can make informed decisions about which materials to use in their designs.Moreover, the concept of torsion strength (扭转强度) extends beyond just static loads. In many applications, components are subjected to dynamic loading conditions, where they experience fluctuating torques over time. Understanding how materials respond to such conditions is vital for ensuring longevity and reliability in engineering designs.In conclusion, torsion strength (扭转强度) is a critical property that engineers must consider when designing components that will be subjected to twisting forces. It is a measure of a material's ability to resist deformation and failure under torque. By understanding the factors that influence torsion strength (扭转强度) and employing appropriate testing methods, engineers can select the right materials for their applications, ensuring safety and performance in their designs. As technology advances, the exploration of new materials with enhanced torsion strength (扭转强度) will continue to play a significant role in the development of innovative engineering solutions.

扭转是力学中的一个基本概念，指的是由于施加的扭矩而导致物体的扭曲。当对物体施加力时，会导致物体围绕其轴旋转，从而产生内部应力。决定材料抵抗这些扭转力能力的一个关键属性是其扭转强度。扭转强度（torsion strength）是指材料在开始变形或失效之前能够承受的最大扭矩。这一特性在工程和设计中尤为重要，因为组件在使用过程中常常会受到扭转力的影响。理解扭转强度对工程师在选择各种应用材料时至关重要。例如，在轴、梁和其他结构元件的设计中，确保所选材料能够承受预期负载而不发生失效是至关重要的。如果材料的扭转强度（torsion strength）较低，则可能在应力下扭曲并断裂，导致机械或结构的灾难性故障。材料的扭转强度（torsion strength）受多种因素的影响，包括其成分、微观结构和温度。不同材料表现出不同水平的扭转强度。例如，钢等金属通常具有比塑料或木材更高的扭转强度（torsion strength）。这就是为什么在需要高强度和耐用性的应用中，通常使用钢的原因。在实际操作中，工程师通常进行测试以确定材料的扭转强度（torsion strength）。一种常见的方法是扭转测试，其中样本被扭转直到失效。该测试的结果提供了有价值的数据，可以用于预测材料在现实条件下的行为。通过分析结果，工程师可以在设计中做出明智的材料选择。此外，扭转强度（torsion strength）的概念不仅限于静态负载。在许多应用中，组件会受到动态加载条件的影响，即它们经历随时间变化的扭矩。了解材料如何响应这些条件对于确保工程设计的耐久性和可靠性至关重要。总之，扭转强度（torsion strength）是工程师在设计将受到扭转力的组件时必须考虑的一个关键属性。它是衡量材料抵抗变形和失效能力的指标。通过理解影响扭转强度（torsion strength）的因素并采用适当的测试方法，工程师可以选择适合其应用的正确材料，从而确保设计的安全性和性能。随着技术的进步，探索具有增强扭转强度（torsion strength）的新材料将继续在创新工程解决方案的发展中发挥重要作用。