torsional oscillation
简明释义
扭转振荡
英英释义
Torsional oscillation refers to the oscillatory motion of an object around its axis of rotation, where the object twists back and forth due to applied torque. | 扭转振荡是指物体围绕其旋转轴的振荡运动,其中物体由于施加的扭矩而前后扭动。 |
例句
1.The research focused on how torsional oscillation 扭转振荡 affects the performance of rotating machinery.
研究集中于<承>扭转振荡如何影响旋转机械的性能。
2.The team developed a model to predict the impact of torsional oscillation 扭转振荡 in high-speed trains.
团队开发了一个模型来预测<承>扭转振荡在高速列车中的影响。
3.In automotive design, torsional oscillation 扭转振荡 can lead to vibrations that affect passenger comfort.
在汽车设计中,<承>扭转振荡可能导致影响乘客舒适度的振动。
4.Engineers must account for torsional oscillation 扭转振荡 when designing wind turbine shafts.
工程师在设计风力涡轮轴时必须考虑<承>扭转振荡。
5.The engineer conducted tests to measure the effects of torsional oscillation 扭转振荡 on the bridge's stability.
工程师进行了测试,以测量<承>扭转振荡对桥梁稳定性的影响。
作文
Torsional oscillation is a phenomenon that occurs in various mechanical systems, where an object twists around its axis and experiences periodic motion. This type of oscillation is particularly significant in engineering and physics, as it can affect the stability and performance of structures and machines. Understanding torsional oscillation (扭转振动) is crucial for designing systems that can withstand dynamic loads and vibrations without failing. For instance, in automotive engineering, the drive shaft of a vehicle is subject to torsional oscillation (扭转振动) due to the engine's rotational forces. If these oscillations are not properly managed, they can lead to excessive wear and tear on components, ultimately resulting in mechanical failure.In addition to vehicles, torsional oscillation (扭转振动) is also prevalent in structures such as bridges and buildings. Engineers must account for these oscillations when designing structures to ensure they can handle external forces like wind or seismic activity. For example, during an earthquake, a building may experience torsional oscillation (扭转振动) if the ground shifts unevenly. This can cause one side of the building to twist more than the other, leading to potential structural damage. Therefore, incorporating damping systems or flexible materials can help mitigate the effects of torsional oscillation (扭转振动) in construction.Moreover, torsional oscillation (扭转振动) plays a vital role in the field of robotics. Robots often have joints that can rotate, and understanding how these joints behave under different loads is essential for their design. If a robotic arm were to experience uncontrolled torsional oscillation (扭转振动), it could lead to inaccurate movements or even damage the robot itself. By analyzing the torsional oscillation (扭转振动) characteristics of the joints, engineers can create control algorithms that compensate for these oscillations, ensuring precise operation.In the realm of music, torsional oscillation (扭转振动) can also be observed in musical instruments such as strings and woodwinds. The twisting motion of a string can produce different harmonics, contributing to the unique sound of an instrument. Musicians and instrument makers must understand how torsional oscillation (扭转振动) affects sound production to create instruments that perform well and resonate beautifully.In conclusion, torsional oscillation (扭转振动) is a fundamental concept that spans multiple disciplines, from engineering to music. Its implications are vast, affecting everything from the safety and reliability of machines to the artistry of musical performance. By studying torsional oscillation (扭转振动), professionals can innovate and improve designs, ensuring that systems are both efficient and resilient. As technology continues to advance, the importance of understanding torsional oscillation (扭转振动) will only grow, making it an essential topic for future research and application.
扭转振动是一个在各种机械系统中发生的现象,其中物体围绕其轴线扭转并经历周期性运动。这种振动在工程和物理学中尤其重要,因为它会影响结构和机器的稳定性和性能。理解torsional oscillation(扭转振动)对于设计能够承受动态载荷和振动而不发生故障的系统至关重要。例如,在汽车工程中,车辆的传动轴由于发动机的旋转力而受到torsional oscillation(扭转振动)的影响。如果这些振动没有得到妥善管理,它们可能导致组件过度磨损,最终导致机械故障。除了车辆之外,torsional oscillation(扭转振动)在桥梁和建筑等结构中也很常见。工程师在设计结构时必须考虑这些振动,以确保它们能够承受风或地震等外部力量。例如,在地震期间,如果地面不均匀移动,建筑物可能会经历torsional oscillation(扭转振动)。这可能导致建筑物的一侧比另一侧扭转得更多,从而可能造成结构损坏。因此,结合阻尼系统或柔性材料可以帮助减轻建筑物中torsional oscillation(扭转振动)的影响。此外,torsional oscillation(扭转振动)在机器人领域也起着至关重要的作用。机器人通常有可以旋转的关节,了解这些关节在不同负载下的行为对其设计至关重要。如果一个机器人手臂经历不可控的torsional oscillation(扭转振动),可能导致动作不准确甚至损坏机器人本身。通过分析关节的torsional oscillation(扭转振动)特性,工程师可以创建补偿这些振动的控制算法,从而确保精确操作。在音乐领域,torsional oscillation(扭转振动)也可以在弦乐器和木管乐器中观察到。弦的扭转运动可以产生不同的谐波,促成乐器独特的声音。音乐家和乐器制造商必须理解torsional oscillation(扭转振动)如何影响声音的产生,以创造出表现良好且音色优美的乐器。总之,torsional oscillation(扭转振动)是一个跨越多个学科的基本概念,从工程到音乐,其影响广泛,涉及从机器的安全和可靠性到音乐表演的艺术性。通过研究torsional oscillation(扭转振动),专业人员可以创新和改善设计,确保系统既高效又韧性强。随着技术的不断进步,理解torsional oscillation(扭转振动)的重要性只会增加,使其成为未来研究和应用的关键主题。
相关单词
