rotating

简明释义

英[rəʊˈteɪtɪŋ]美[ˈroʊteɪtɪŋ]

adj. 旋转的

v. 旋转，转动；轮流，轮值；轮作，换茬（rotate 的现在分词）

英英释义

单词用法

同义词

反义词

例句

1.It is the clock of the rotating neutron star.

中子星旋转的计时，如果中子星。

2.Do you understand why it's still rotating?

你们能知道，为什么，它还在旋转吗？

3.In its original state, there were rotating dials and other indicators on the top, with letters and drawings showing the Sun, the phases of the moon and different constellations.

最初，它的顶部有旋转的刻度盘和其他指示物，上面的字母和图画描绘了太阳、月相和不同的星座。

4.It tells you it is rotating about a vertical axis.

它是绕垂直轴旋转的。

5.Mars, in contrast, has a wildly oscillating tilt and chaotic seasonality, while Venus, rotating slowly backward, has virtually no seasonality at all.

相比之下，火星有着剧烈的倾斜和混乱的季节性，而金星则缓慢地向后旋转，几乎没有实质上的任何季节性。

6.If you think a molecule's rotating, they could always spin faster.

如果你考虑分子的旋转，它们总能更快地自旋。

7.The carousel is rotating slowly, attracting children's attention.

旋转木马正在慢慢旋转，吸引孩子们的注意。

8.She is rotating the dial to set the timer.

她正在旋转拨盘来设置定时器。

9.The rotating mechanism helps in adjusting the angle of the solar panels.

旋转机制有助于调整太阳能电池板的角度。

10.The fan is rotating to cool down the room.

风扇正在旋转以降温。

11.The Earth is rotating on its axis, creating day and night.

地球在其轴上旋转，形成昼夜交替。

作文

In the world of science and technology, the concept of rotating (旋转) objects is fundamental to understanding various phenomena. From the simple act of spinning a top to the complex mechanics of planetary motion, rotating (旋转) bodies play a critical role in our universe. This essay will explore the significance of rotating (旋转) systems in different fields, including physics, engineering, and even everyday life.Firstly, let’s delve into physics. The laws of motion, as articulated by Sir Isaac Newton, describe how objects behave when forces are applied. When an object is rotating (旋转) around an axis, it experiences centripetal force, which keeps it in a circular path. For instance, the Earth itself is a massive rotating (旋转) sphere that spins on its axis, resulting in the cycle of day and night. This rotating (旋转) motion not only affects our daily lives but also influences the climate and weather patterns across the globe. Understanding this rotating (旋转) behavior is crucial for meteorologists who predict weather changes.In engineering, rotating (旋转) machinery is ubiquitous. From turbines generating electricity to engines powering vehicles, the principles of rotating (旋转) systems are applied extensively. Engineers design these machines to optimize efficiency and performance. For example, wind turbines harness the energy of the wind by utilizing large blades that rotate (旋转) in the breeze, converting kinetic energy into electrical energy. The effectiveness of these devices relies heavily on the understanding of rotating (旋转) dynamics, which involves calculations of torque, angular velocity, and other essential factors.Moreover, rotating (旋转) systems can also be seen in our daily activities. Take, for instance, a washing machine. Its drum rotates (旋转) during a wash cycle to agitate the clothes, ensuring they are cleaned thoroughly. The design of the washing machine incorporates the principles of rotating (旋转) motion to achieve optimal cleaning results while minimizing water and energy consumption. This practical application of rotating (旋转) technology illustrates how deeply embedded these concepts are in our lives.Furthermore, the concept of rotating (旋转) is not limited to physical objects; it can also apply to abstract ideas such as perspectives and viewpoints. In discussions or debates, one might consider rotating (旋转) their perspective to understand an issue more comprehensively. By rotating (旋转) our viewpoint, we can gain insights that may have been overlooked initially, fostering empathy and better communication.In conclusion, the idea of rotating (旋转) is deeply woven into the fabric of both the natural world and human innovation. Whether it is the rotating (旋转) motion of celestial bodies or the intricate designs of machines, this concept is essential for understanding and interacting with our environment. As we continue to advance in technology and science, the importance of mastering the principles of rotating (旋转) systems will only grow, paving the way for new discoveries and innovations. Therefore, embracing the knowledge of rotating (旋转) dynamics can empower us to create a better future.

在科学和技术的世界中，物体的旋转（rotating）概念对于理解各种现象至关重要。从简单的陀螺旋转到复杂的行星运动，旋转（rotating）物体在我们的宇宙中发挥着关键作用。本文将探讨旋转（rotating）系统在物理学、工程学乃至日常生活中的重要性。首先，让我们深入探讨物理学。牛顿所阐述的运动定律描述了当施加力时物体的行为。当一个物体围绕某个轴线旋转（rotating）时，它会经历向心力，这种力使其保持在圆形轨道上。例如，地球本身就是一个巨大的旋转（rotating）球体，它围绕其轴线旋转，导致昼夜交替。这种旋转（rotating）运动不仅影响我们的日常生活，还影响全球的气候和天气模式。理解这种旋转（rotating）行为对于预测天气变化的气象学家至关重要。在工程学中，旋转（rotating）机械无处不在。从涡轮发电机到为车辆提供动力的发动机，旋转（rotating）系统的原理被广泛应用。工程师设计这些机器以优化效率和性能。例如，风力涡轮机通过利用在微风中旋转（rotating）的巨大叶片来捕获风能，将动能转化为电能。这些设备的有效性在很大程度上依赖于对旋转（rotating）动态的理解，包括扭矩、角速度和其他重要因素的计算。此外，旋转（rotating）系统也可以在我们的日常活动中看到。以洗衣机为例。它的滚筒在洗涤周期中旋转（rotating），以搅动衣物，确保它们被彻底清洗。洗衣机的设计结合了旋转（rotating）运动的原理，以实现最佳的清洁效果，同时最小化水和能源消耗。这种旋转（rotating）技术的实际应用说明了这些概念在我们生活中的根深蒂固。此外，旋转（rotating）的概念不仅限于物理对象；它也可以应用于观点和视角等抽象思想。在讨论或辩论中，人们可能会考虑旋转（rotating）自己的观点，以更全面地理解问题。通过旋转（rotating）我们的观点，我们可以获得一些最初可能被忽视的见解，促进同理心和更好的沟通。总之，旋转（rotating）的概念深深融入了自然世界和人类创新的结构中。无论是天体的旋转（rotating）运动还是机器的复杂设计，这一概念对于理解和与我们环境互动至关重要。随着我们在技术和科学方面的不断进步，掌握旋转（rotating）系统原理的重要性只会增加，为新的发现和创新铺平道路。因此，拥抱对旋转（rotating）动态的知识可以使我们能够创造一个更美好的未来。