axial torque

简明释义

轴向转矩;

英英释义

例句

1.The engineer calculated the axial torque 轴向扭矩 required to tighten the bolts on the assembly.

工程师计算了组装时紧固螺栓所需的轴向扭矩。

2.We need to adjust the settings to control the axial torque 轴向扭矩 during operation.

我们需要调整设置以控制操作期间的轴向扭矩。

3.During the test, we measured the axial torque 轴向扭矩 applied to the shaft.

在测试过程中，我们测量了施加在轴上的轴向扭矩。

4.The specifications outlined the maximum axial torque 轴向扭矩 that could be safely applied.

规格说明了可以安全施加的最大轴向扭矩。

5.Excessive axial torque 轴向扭矩 can lead to mechanical failure in the system.

过大的轴向扭矩可能导致系统的机械故障。

作文

Understanding the concept of axial torque is essential in various fields of engineering and physics. In simple terms, axial torque refers to the twisting force that acts along the axis of an object. It is a critical factor in the design and analysis of mechanical systems, particularly those involving rotating components. For instance, consider a car engine where the crankshaft rotates. The axial torque generated by the combustion process must be effectively managed to ensure smooth operation and longevity of the engine. Without proper handling of this torque, components can wear out prematurely or even fail catastrophically.In structural engineering, axial torque plays a crucial role in determining how structures respond to various loads. When designing beams and columns, engineers must account for the axial torque that may occur due to forces acting on the structure. This is particularly important in tall buildings or bridges, where lateral forces such as wind can create significant axial torque on structural elements. By understanding how to calculate and mitigate these forces, engineers can create safer and more resilient structures.Moreover, the concept of axial torque is not limited to large-scale engineering projects. It also applies to everyday items like screws and bolts. When tightening a screw, the axial torque applied determines how securely the screw holds materials together. Too little torque may result in a loose connection, while too much can strip the threads or break the screw altogether. Therefore, understanding axial torque is vital for anyone involved in DIY projects or assembly tasks.In addition to mechanical and structural applications, axial torque is also relevant in the field of robotics. Robots often have motors that need to generate specific amounts of axial torque to perform tasks efficiently. For example, robotic arms used in manufacturing must apply the correct axial torque to lift and manipulate heavy objects without causing damage. Engineers must carefully calculate the required torque to ensure that the robot operates within safe limits while achieving its intended functions.Furthermore, advancements in technology have led to the development of tools and instruments designed to measure axial torque accurately. Torque wrenches, for example, are commonly used in automotive and construction industries to apply precise amounts of torque to fasteners. These tools help prevent over-tightening and ensure that components are secured correctly, highlighting the importance of understanding axial torque in practical applications.In conclusion, the concept of axial torque is fundamental across various disciplines, from mechanical engineering to everyday tasks. Understanding how axial torque works allows engineers and technicians to design better systems, create safer structures, and perform tasks more effectively. As technology continues to evolve, the significance of axial torque will only grow, making it an essential topic for future study and application.

理解轴向扭矩的概念在工程和物理学的各个领域都是至关重要的。简单来说，轴向扭矩是指沿着物体轴线作用的扭转力。这是机械系统设计和分析中的一个关键因素，特别是涉及旋转部件的系统。例如，考虑汽车发动机，其中曲轴旋转。燃烧过程产生的轴向扭矩必须有效管理，以确保发动机的平稳运行和长寿命。如果不正确处理这种扭矩，部件可能会过早磨损甚至发生灾难性故障。在结构工程中，轴向扭矩在确定结构如何响应各种载荷方面发挥着至关重要的作用。在设计梁和柱时，工程师必须考虑由于作用于结构的力而可能发生的轴向扭矩。这在高层建筑或桥梁中特别重要，因为风等横向力可能会对结构元素产生显著的轴向扭矩。通过理解如何计算和减轻这些力量，工程师可以创建更安全、更具韧性的结构。此外，轴向扭矩的概念不限于大规模工程项目。它还适用于日常物品，如螺丝和螺栓。紧固螺丝时，施加的轴向扭矩决定了螺丝将材料固定在一起的安全程度。扭矩过小可能导致连接松动，而过大则可能剥离螺纹或折断螺丝。因此，理解轴向扭矩对于任何参与DIY项目或组装任务的人来说都是至关重要的。除了机械和结构应用外，轴向扭矩在机器人领域也很相关。机器人通常有需要生成特定量的轴向扭矩以高效执行任务的电动机。例如，用于制造的机器人手臂必须施加正确的轴向扭矩来提升和操纵重物而不会造成损坏。工程师必须仔细计算所需的扭矩，以确保机器人在安全范围内操作，同时实现其预期功能。此外，技术的进步导致开发出旨在准确测量轴向扭矩的工具和仪器。例如，扭矩扳手在汽车和建筑行业中被广泛使用，用于向紧固件施加精确的扭矩。这些工具有助于防止过度拧紧，并确保组件正确固定，突显了在实际应用中理解轴向扭矩的重要性。总之，轴向扭矩的概念在机械工程到日常任务的各个学科中都是基础。理解轴向扭矩的工作原理使工程师和技术人员能够设计更好的系统、创建更安全的结构以及更有效地执行任务。随着技术的不断发展，轴向扭矩的重要性只会增加，使其成为未来研究和应用的一个重要主题。