torsion couple

简明释义

扭力偶

英英释义

例句

1.The engineer calculated the torsion couple 扭矩偶 acting on the beam to ensure it would not fail under load.

工程师计算了作用在梁上的torsion couple 扭矩偶，以确保它在载荷下不会失效。

2.To analyze the stability of the structure, we need to consider the effect of the torsion couple 扭矩偶 on the joints.

为了分析结构的稳定性，我们需要考虑torsion couple 扭矩偶对接头的影响。

3.In mechanical systems, the torsion couple 扭矩偶 is crucial for understanding how forces interact.

在机械系统中，torsion couple 扭矩偶 对于理解力的相互作用至关重要。

4.The design of the new vehicle incorporates a torsion couple 扭矩偶 system to improve handling.

新车型的设计中融入了一个torsion couple 扭矩偶系统，以改善操控性。

5.The torsion couple 扭矩偶 generated by the rotating shaft was measured using a specialized torque sensor.

旋转轴产生的torsion couple 扭矩偶通过专用的扭矩传感器进行测量。

作文

In the study of mechanics, understanding the concept of a torsion couple is essential for analyzing the behavior of materials and structures under twisting forces. A torsion couple refers to a pair of equal and opposite forces that create a rotational effect around an axis. This phenomenon is crucial in various engineering applications, from the design of bridges to the construction of vehicles. When a torsion couple is applied to an object, it induces shear stresses within the material, which can lead to deformation or failure if the material's limits are exceeded.To illustrate the significance of a torsion couple, consider the example of a cylindrical shaft subjected to twisting. When torque is applied to one end of the shaft while the other end is held stationary, a torsion couple is generated. This twisting action causes the shaft to rotate, and the amount of rotation depends on the magnitude of the applied torque and the material properties of the shaft. Engineers must carefully calculate the maximum torque that can be applied without causing permanent deformation, ensuring the safety and reliability of the design.Moreover, the effects of a torsion couple can also be observed in everyday objects. For instance, when using a wrench to tighten a bolt, the force applied creates a torsion couple that turns the bolt. The effectiveness of the wrench relies on the user's ability to apply the right amount of torque, demonstrating how important it is to understand this concept in practical scenarios.Additionally, in the field of structural engineering, the analysis of torsion couples is vital for ensuring the stability of structures. Buildings and bridges must be designed to withstand not only vertical loads but also lateral forces that can cause twisting. By understanding how torsion couples affect structural elements, engineers can create designs that distribute these forces effectively, reducing the risk of failure.Furthermore, the study of torsion couples leads to advancements in materials science. Researchers explore new materials that can better resist torsional forces, enhancing the performance of mechanical systems. Innovations such as composite materials and advanced alloys are often developed with the understanding of how torsion couples interact with different substances, leading to stronger and more resilient products.In conclusion, the concept of a torsion couple plays a pivotal role in mechanics and engineering. From the design of everyday tools to complex structures, understanding how these forces work is crucial for ensuring safety and functionality. As technology advances, the importance of mastering the principles of torsion couples will continue to grow, making it a fundamental topic in the study of engineering and physics. Therefore, both students and professionals in these fields must prioritize learning about torsion couples to enhance their understanding and application of mechanical principles.

在力学研究中，理解“扭转偶”的概念对于分析材料和结构在扭转力下的行为至关重要。“扭转偶”是指一对相等且方向相反的力，它们在轴周围产生旋转效应。这一现象在各种工程应用中至关重要，从桥梁设计到车辆构造。当施加“扭转偶”于物体时，会在材料内部引发剪切应力，如果超过材料的极限，可能导致变形或破坏。为了说明“扭转偶”的重要性，可以考虑一个受到扭转的圆柱形轴的例子。当在轴的一端施加扭矩，而另一端保持静止时，就会产生“扭转偶”。这种扭转作用使轴旋转，旋转的程度取决于施加的扭矩大小和轴的材料特性。工程师必须仔细计算可以施加的最大扭矩，以确保不会造成永久变形，从而保证设计的安全性和可靠性。此外，“扭转偶”的影响也可以在日常物品中观察到。例如，当使用扳手拧紧螺栓时，施加的力会产生“扭转偶”，使螺栓转动。扳手的有效性依赖于用户施加适当扭矩的能力，这表明在实际场景中理解这一概念是多么重要。此外，在结构工程领域，对“扭转偶”的分析对于确保结构的稳定性至关重要。建筑物和桥梁必须设计成能够承受不仅是垂直载荷，还有可能导致扭转的侧向力。通过理解“扭转偶”如何影响结构元素，工程师可以创建有效分配这些力的设计，从而降低失效风险。此外，研究“扭转偶”还推动了材料科学的发展。研究人员探索能够更好地抵抗扭转力的新材料，提高机械系统的性能。复合材料和先进合金等创新通常是在理解“扭转偶”与不同物质相互作用的基础上开发的，从而导致更强大和更具韧性的产品。总之，“扭转偶”的概念在力学和工程中起着关键作用。从日常工具的设计到复杂结构的构建，理解这些力如何工作对于确保安全和功能至关重要。随着技术的发展，掌握“扭转偶”原理的重要性将继续增长，使其成为工程和物理学习中的一个基本主题。因此，学生和专业人士在这些领域中必须优先学习“扭转偶”，以增强他们对机械原理的理解和应用。