torsionally

简明释义

[tɔːˈʃənəli][tɔrˈʃənəli]

扭力地

扭转地

产生扭转地

英英释义

In a manner relating to or caused by torsion; involving twisting or rotational forces.

以与扭转相关或由扭转引起的方式;涉及扭曲或旋转力。

单词用法

torsionally rigid

扭转刚性

torsionally flexible

扭转灵活

torsionally loaded

承受扭转负荷

torsionally balanced

扭转平衡

torsionally sensitive

对扭转敏感

同义词

twisting

扭转

The shaft experienced significant twisting under load.

在负载下,轴经历了显著的扭转。

spiral

螺旋

The cable has a spiral structure to enhance its strength.

这根电缆具有螺旋结构,以增强其强度。

rotational

旋转的

Rotational motion is crucial in many mechanical systems.

旋转运动在许多机械系统中至关重要。

反义词

non-torsional

非扭转的

The structure was designed to be non-torsional to withstand lateral forces.

该结构被设计为非扭转的,以承受横向力。

straight

直的

A straight beam is less likely to experience torsional stress.

直梁不太可能经历扭转应力。

例句

1.The effect of systematic parameters on the structural equivalent damping ratio in translational and torsional direction is studied for torsionally coupled vibration.

对结构扭转耦联的振动问题进行研究,分析了控制系统各参数对结构平移等效阻尼比和扭转等效阻尼比的影响。

2.The effect of systematic parameters on the structural equivalent damping ratio in translational and torsional direction is studied for torsionally coupled vibration.

对结构扭转耦联的振动问题进行研究,分析了控制系统各参数对结构平移等效阻尼比和扭转等效阻尼比的影响。

3.The torsionally 扭转地 rigid components help to improve overall stability.

这些扭转地刚性的组件有助于提高整体稳定性。

4.In the analysis, we found that the structure was torsionally 扭转地 weak at certain points.

在分析中,我们发现结构在某些点上是扭转地薄弱的。

5.The beam was designed to be torsionally 扭转地 stable under heavy loads.

该梁的设计旨在在重载下保持扭转地稳定。

6.The design included torsionally 扭转地 reinforced joints to enhance durability.

设计中包含了扭转地加固的接头以增强耐用性。

7.Engineers must consider how torsionally 扭转地 flexible materials will perform under stress.

工程师必须考虑扭转地柔性材料在应力下的表现。

作文

In the field of engineering, particularly in mechanical and structural design, understanding the behavior of materials under different types of stress is crucial. One of the key concepts that engineers must grasp is the idea of torsion. Torsion refers to the twisting of an object due to an applied torque. When a shaft or beam is subjected to torsional forces, it experiences a deformation known as torsional deformation. This phenomenon can lead to various mechanical failures if not properly accounted for during the design process. Therefore, it is essential to analyze components torsionally (扭转上) to ensure their integrity and functionality.For example, consider a cylindrical shaft that is used to transmit power in a machine. When the shaft rotates, it encounters resistance, which generates a torque that causes it to twist. Engineers must calculate the maximum allowable torque that the shaft can withstand without failing. This involves determining the material properties, such as the shear modulus, which describes how a material deforms under shear stress. If the shaft is not designed to handle the expected torsional loads, it may fail, leading to costly repairs and potential safety hazards.Moreover, the concept of torsionally (扭转上) analyzing components extends beyond simple shafts. In structural engineering, beams and frames are often subjected to complex loading conditions, including bending and torsion. When a beam is loaded torsionally (扭转上), it twists along its length, which can affect its overall stability and load-carrying capacity. Engineers use various methods, such as finite element analysis, to simulate these conditions and predict how structures will behave under real-world loads.Another important aspect of torsional (扭转的) analysis is the impact of geometry on performance. The shape and dimensions of a component significantly influence its ability to resist torsional forces. For instance, a hollow shaft is often more efficient in resisting torsion than a solid shaft of the same weight. This is because the material is distributed further from the center of rotation, increasing the polar moment of inertia, which is a measure of an object's resistance to torsion. By optimizing the geometry of components torsionally (扭转上), engineers can create lighter and more efficient designs without sacrificing strength.In conclusion, the term torsionally (扭转上) encompasses a critical aspect of engineering design that deals with the twisting of materials under applied forces. Understanding how to analyze and design components to withstand torsional loads is essential for ensuring the reliability and safety of mechanical and structural systems. As technology advances, engineers continue to develop new materials and design methodologies that enhance our ability to manage torsional stresses effectively. By prioritizing torsional (扭转的) analysis in their work, engineers contribute to the creation of safer, more efficient, and innovative solutions across various industries.

在工程领域,尤其是在机械和结构设计中,理解材料在不同类型应力下的行为至关重要。工程师必须掌握的一个关键概念是扭转的概念。扭转是指由于施加的扭矩而导致物体扭曲。当轴或梁受到扭转力时,会发生一种称为扭转变形的变形现象。如果在设计过程中没有适当考虑这种现象,可能会导致各种机械故障。因此,分析组件的扭转行为是确保其完整性和功能的关键。例如,考虑一个用于传递机器动力的圆柱形轴。当轴旋转时,它会遇到阻力,从而产生扭矩,导致其扭曲。工程师必须计算出轴可以承受的最大允许扭矩,而不会发生故障。这涉及确定材料属性,例如剪切模量,该模量描述材料在剪切应力下的变形。如果轴的设计未能承受预期的扭转负载,则可能会发生故障,导致昂贵的维修和潜在的安全隐患。此外,torsionally(扭转上)分析组件的概念不仅限于简单的轴。在结构工程中,梁和框架经常受到包括弯曲和扭转在内的复杂加载条件。当梁被扭转负载作用时,它沿其长度扭曲,这可能影响其整体稳定性和承载能力。工程师使用各种方法,例如有限元分析,来模拟这些条件并预测结构在实际负载下的行为。另一个重要的扭转分析方面是几何形状对性能的影响。组件的形状和尺寸显著影响其抵抗扭转力的能力。例如,空心轴通常比相同重量的实心轴在抵抗扭转方面更有效。这是因为材料分布在离旋转中心更远的地方,从而增加了极惯性矩,这是衡量物体抵抗扭转的能力的指标。通过优化组件的几何形状,工程师可以在不牺牲强度的情况下,创造出更轻、更高效的设计。总之,术语torsionally(扭转上)涵盖了与材料在施加力下扭曲相关的工程设计的关键方面。理解如何分析和设计组件以承受扭转负载,对于确保机械和结构系统的可靠性和安全性至关重要。随着技术的进步,工程师继续开发新材料和设计方法,提高我们有效管理扭转应力的能力。通过在工作中优先考虑torsional(扭转的)分析,工程师为各个行业的安全、更高效和创新解决方案的创造做出了贡献。