torsion

简明释义

英[ˈtɔːʃn]美[ˈtɔːrʃn]

n. 扭转，扭曲；转矩，[力] 扭力

英英释义

单词用法

同义词

反义词

例句

1.In a study published earlier this year, Poplawski said when the density of matter reaches epic proportions, torsion counters gravity.

在今年早些时候发表的一篇论文中波普拉·瓦斯基提到，当一个事物的密度达到一定的比例时，它的扭曲变化便会脱离重力的控制。

2.Main Outcome Measures: Torsion, bending, and axial stiffness and axial failure force after cyclic loading.

主要测量指标：扭转、弯曲和轴向刚度，以及循环载荷下轴向失效力。

3.Light lateral and axis and torsion vibrations do not affect the normal work, but the resonance state has severity effect to drill string.

轻微的横向、轴向及扭转振动不影响钻井的正常作业，而钻柱的共振状态会对钻井产生严重的影响。

4.Tool marks for the torsion tool are found on the edges of the padlock.

在锁体的边缘发现扭力工具留下的印迹。

5.The discovery well was drilled in 1927 on the basis of magnetic and torsion-balance surveys.

其发现井是1927年根据磁力和扭称测量结果而钻探的。

6.How they let the beast tore torsion even Shiyao in themselves do not leave scars of the?

他们是怎样让野兽的撕挠甚至噬咬在自己身上不留疤痕的呢？

7.Polarization configuration recognition based on analysis of torsion and curvature.

极化识别配置的基础上扭转和曲率分析。

8.APEX pin, a pin for joining the two sections of the torsion link on the landing gear.

顶销，用于连接起落架扭力臂两部份的销子。

9.The effect of the vertical force on the pier stiffness and the interaction among the level, bending and torsion displacement is also studied.

文中考虑了竖向力对群桩刚度的影响以及桩基承台水平位移与弯曲、扭转位移的耦合作用。

10.The torsion 扭转 test is commonly used to determine the material properties of metals.

扭转 扭转测试通常用于确定金属的材料特性。

11.Excessive torsion 扭转 can lead to structural failure in bridges.

过度的扭转 扭转可能导致桥梁的结构失效。

12.The engineer calculated the amount of torsion 扭转 that the beam would experience under load.

工程师计算了梁在载荷下将经历的扭转 扭转量。

13.In mechanics, torsion 扭转 refers to the twisting of an object due to an applied torque.

在力学中，扭转 扭转指的是由于施加的扭矩而导致物体的扭曲。

14.A twisted shaft can cause significant torsion 扭转 in machinery, leading to inefficiency.

扭曲的轴可能会导致机械中的显著扭转 扭转，从而导致效率低下。

作文

Torsion is a fundamental concept in the field of mechanics and engineering, referring to the twisting of an object due to an applied torque. This phenomenon can be observed in various materials, from metals to plastics, and is crucial when designing structures that must withstand rotational forces. Understanding torsion (扭转) is essential for engineers who work with beams, shafts, and other load-bearing components. In engineering, torsion (扭转) affects the performance and safety of structures. For example, when a metal rod is twisted at one end while the other end is fixed, the rod experiences shear stress. This stress can lead to deformation, which may ultimately result in failure if the material's yield strength is exceeded. Therefore, engineers must calculate the torsion (扭转) that components will experience under different loading conditions to ensure they are designed properly. One practical application of torsion (扭转) is in the design of drive shafts in vehicles. These shafts must transmit power from the engine to the wheels while enduring significant twisting forces. Engineers must consider factors such as material properties, shaft diameter, and length to minimize the risk of failure due to excessive torsion (扭转). A well-designed drive shaft can enhance vehicle performance and longevity, making it a critical aspect of automotive engineering. Moreover, the study of torsion (扭转) extends beyond engineering into physics, where it is used to analyze the behavior of materials under stress. The mathematical representation of torsion (扭转) involves complex equations that describe how materials respond to twisting forces. For instance, the torsional rigidity of a material is a measure of its resistance to torsion (扭转), and this property is vital for predicting how structures will behave under load. In the realm of architecture, understanding torsion (扭转) is equally important. Architects must consider the effects of twisting forces on buildings, especially in areas prone to earthquakes or high winds. By incorporating knowledge of torsion (扭转) into their designs, architects can create safer and more resilient structures. For example, modern skyscrapers often feature reinforced cores that help them withstand the torsion (扭转) caused by lateral forces. In conclusion, torsion (扭转) is a key concept in both engineering and physics, influencing the design and functionality of various structures and materials. Its implications are vast, affecting everything from everyday objects to large-scale constructions. As technology advances, the understanding of torsion (扭转) will continue to evolve, leading to innovative solutions and improved safety standards across multiple disciplines. Engineers and architects alike must prioritize the study of torsion (扭转) to ensure the integrity and durability of their designs, ultimately benefiting society as a whole.

扭转是力学和工程领域的一个基本概念，指的是由于施加的扭矩而导致物体的扭曲。这种现象可以在各种材料中观察到，从金属到塑料，并且在设计必须承受旋转力的结构时至关重要。理解torsion（扭转）对从事梁、轴和其他承载构件的工程师来说是必不可少的。在工程中，torsion（扭转）影响着结构的性能和安全性。例如，当一根金属杆的一端被扭动而另一端固定时，杆会经历剪切应力。这种应力可能导致变形，如果超出了材料的屈服强度，最终可能导致失效。因此，工程师必须计算构件在不同载荷条件下将经历的torsion（扭转），以确保它们的设计是恰当的。torsion（扭转）的一个实际应用是在车辆的传动轴设计中。这些轴必须在承受显著扭转力的情况下，将动力从发动机传递到车轮。工程师必须考虑材料特性、轴直径和长度等因素，以最小化因过度torsion（扭转）而导致失效的风险。设计良好的传动轴可以增强车辆的性能和寿命，使其成为汽车工程的关键方面。此外，torsion（扭转）的研究不仅限于工程，还扩展到物理学，在这里它用于分析材料在应力下的行为。torsion（扭转）的数学表示涉及复杂的方程，这些方程描述了材料如何响应扭转力。例如，材料的扭转刚度是其抵抗torsion（扭转）的能力的度量，而这一特性对于预测结构在负载下的表现至关重要。在建筑领域，理解torsion（扭转）同样重要。建筑师必须考虑扭转力对建筑物的影响，尤其是在地震或强风频发的地区。通过将torsion（扭转）的知识融入设计中，建筑师可以创造出更安全、更具韧性的结构。例如，现代摩天大楼通常具有加固的核心，有助于它们承受由侧向力引起的torsion（扭转）。总之，torsion（扭转）是工程和物理学中的一个关键概念，影响着各种结构和材料的设计和功能。它的影响广泛，涉及从日常物品到大型建筑的方方面面。随着技术的进步，对torsion（扭转）的理解将继续发展，带来创新的解决方案和跨多个学科的安全标准的提高。工程师和建筑师必须优先研究torsion（扭转），以确保其设计的完整性和耐久性，最终造福整个社会。