rotary oscillation

简明释义

旋转摆动

英英释义

例句

1.The gyroscope operates based on principles of rotary oscillation 旋转振荡, providing stability to the system.

陀螺仪基于旋转振荡 旋转振荡的原理运行，为系统提供稳定性。

2.In the design of the pendulum clock, rotary oscillation 旋转振荡 is crucial for maintaining accurate time.

在摆钟的设计中，旋转振荡 旋转振荡对保持准确时间至关重要。

3.The engineer explained how the motor generates rotary oscillation 旋转振荡 to drive the machinery.

工程师解释了电动机如何产生旋转振荡 旋转振荡来驱动机械。

4.The scientist studied the effects of rotary oscillation 旋转振荡 on fluid dynamics in her research.

科学家在她的研究中研究了旋转振荡 旋转振荡对流体动力学的影响。

5.To improve efficiency, the team focused on optimizing the rotary oscillation 旋转振荡 of the engine components.

为了提高效率，团队专注于优化发动机部件的旋转振荡 旋转振荡。

作文

In the realm of physics and engineering, understanding various forms of motion is crucial for developing advanced technologies. One such form of motion that plays a significant role in many mechanical systems is rotary oscillation. This term refers to the repetitive movement around a central axis, combining both rotational and oscillatory motions. To grasp the concept better, let us explore its applications, significance, and underlying principles.Firstly, rotary oscillation can be observed in numerous everyday devices. For instance, consider a pendulum clock. The swinging motion of the pendulum represents an oscillation, while the clock's gears rotate to keep time. Here, the pendulum's back-and-forth movement is a prime example of rotary oscillation, as it not only moves in a linear path but also maintains a consistent rotation around its pivot point.Moreover, rotary oscillation is essential in the design of various machines, such as engines and turbines. In an internal combustion engine, the pistons move up and down, creating oscillations, while the crankshaft converts this linear motion into rotational motion. This interplay between oscillation and rotation is vital for the engine's efficiency and overall performance. Similarly, in wind turbines, the blades experience rotary oscillation as they rotate around a central hub, harnessing wind energy to generate electricity.The significance of rotary oscillation extends beyond basic mechanics; it also plays a critical role in the field of robotics. Robotic arms often utilize rotary oscillation to perform precise movements. For instance, a robotic arm may need to rotate and oscillate to pick up objects from different angles. By mastering the principles of rotary oscillation, engineers can create more efficient and versatile robots capable of performing complex tasks in manufacturing, surgery, and even space exploration.Additionally, the study of rotary oscillation is not limited to mechanical applications. In the field of acoustics, sound waves can exhibit oscillatory behavior that may also have a rotational component. For example, certain musical instruments, like the violin, rely on the rotary oscillation of strings to produce sound. The vibration of the strings creates waves in the air, leading to the rich tones we hear. Understanding the relationship between rotary oscillation and sound production is essential for musicians and audio engineers alike.In conclusion, rotary oscillation is a fundamental concept that bridges various fields, from mechanical engineering to robotics and acoustics. Its applications are vast and varied, influencing the design and functionality of countless devices we rely on daily. By studying rotary oscillation, we gain insight into the intricate dance of motion that powers our world, paving the way for innovations that will shape the future. Whether in the ticking of a clock, the hum of an engine, or the melodies of a violin, rotary oscillation remains a vital force in our technological landscape.

在物理和工程领域，理解各种运动形式对于开发先进技术至关重要。其中一种在许多机械系统中发挥重要作用的运动形式是旋转振荡。这个术语指的是围绕中心轴的重复运动，结合了旋转和振荡运动。为了更好地掌握这一概念，让我们探讨它的应用、重要性和基本原理。首先，旋转振荡可以在许多日常设备中观察到。例如，考虑一个摆钟。摆锤的摆动运动代表了一种振荡，而钟表的齿轮旋转以保持时间。在这里，摆锤的前后运动是旋转振荡的一个典型例子，因为它不仅沿直线路径移动，还围绕其支点保持一致的旋转。此外，旋转振荡在各种机器的设计中至关重要，例如发动机和涡轮机。在内燃机中，活塞上下移动，产生振荡，而曲轴将这种线性运动转换为旋转运动。这种振荡与旋转之间的相互作用对发动机的效率和整体性能至关重要。同样，在风力涡轮机中，叶片在中央轴周围经历旋转振荡，利用风能发电。旋转振荡的重要性不仅限于基础机械；它在机器人领域也发挥着关键作用。机器人手臂通常利用旋转振荡来执行精确的运动。例如，机器人手臂可能需要旋转和振荡，以从不同角度拾取物体。通过掌握旋转振荡的原理，工程师可以创建更高效和多功能的机器人，能够在制造、外科手术甚至太空探索中执行复杂任务。此外，旋转振荡的研究不限于机械应用。在声学领域，声波可以表现出振荡行为，也可能具有旋转成分。例如，某些乐器，如小提琴，依赖于弦的旋转振荡来产生声音。弦的振动在空气中产生波动，导致我们听到的丰富音调。理解旋转振荡与声音产生之间的关系对音乐家和音频工程师来说至关重要。总之，旋转振荡是一个基本概念，连接了从机械工程到机器人和声学等多个领域。它的应用广泛而多样，影响着我们每天依赖的无数设备的设计和功能。通过研究旋转振荡，我们深入了解推动我们世界的复杂运动舞蹈，为塑造未来的创新铺平道路。无论是在钟表的滴答声、发动机的嗡嗡声，还是小提琴的旋律中，旋转振荡始终是我们技术景观中的一股重要力量。