rotative
简明释义
adj. 回转的;循环的
英英释义
与旋转相关或以旋转为特征的。 | |
能够围绕轴旋转或转动的。 |
单词用法
旋转运动 | |
旋转机制 | |
旋转发动机 | |
旋转系统 |
同义词
| 旋转的 | 旋转发动机 | ||
| 循环的 | 旋转门 | ||
| 圆形的 | 圆锯 |
反义词
| 静止的 | The machine remains stationary while the process is ongoing. | 机器在过程进行时保持静止。 | |
| 固定的 | 物体的固定位置阻止了任何移动。 |
例句
1.Life is a lane but it is a rotative course.
生命是单行道,但是一个循环的过程。
2.This paper deals with an intelligent instrument for measuring torque and rotative velocity, which is constructed of microcomputer and some relevant interfaces.
本文叙述了用微型计算机和相应的接口构成智能转矩转速测量仪。
3.Measurement for rotative velocity of full-closed compressor by the method of measuring vibration frequency is discussed.
讨论了用测量振动频率的方法对全封闭式压缩机进行转速的测量。
4.The present paper proposes two kinds of new method for detecting and measuring rotative speed, and analyzes their performance.
本文提出两种新的转速检测方法,并对其特性进行了研究。
5.The other component of rotative speed is used for test data of oscillating raises concept of balance.
旋转角速度的其他分量用于振荡天平试验数据。在综合使用数据时提出了综合因子的概念。
6.The result suggested that the correct classification ratio be increased by rotative transformation for the textures with intense direction.
对方向性强的纹理,在进行旋转变换后,可以提高纹理分类的正确率。
7.In this experiment, we will observe the rotative 旋转的 motion of the planet around the sun.
在这个实验中,我们将观察行星围绕太阳的旋转的运动。
8.The artist used a rotative 旋转的 canvas to create a unique painting experience.
艺术家使用了一个旋转的画布来创造独特的绘画体验。
9.The rotative 旋转的 display at the museum attracted a lot of visitors.
博物馆的旋转的展览吸引了很多游客。
10.The engineer designed a new rotative 旋转的 mechanism for the machine to improve its efficiency.
工程师为机器设计了一种新的旋转的机制,以提高其效率。
11.This rotative 旋转的 tool allows for more precise cuts in woodworking.
这个旋转的工具可以在木工中实现更精确的切割。
作文
In the world of engineering and machinery, the term rotative refers to mechanisms that involve rotation. Understanding how rotative systems function is crucial for anyone involved in design or maintenance of machines. For instance, consider the internal combustion engine, which relies heavily on rotative motion to convert fuel into mechanical energy. The engine’s pistons move up and down, while the crankshaft rotates, showcasing a perfect example of how rotative elements work together to produce power.The principles of rotative motion extend beyond engines. In wind turbines, large blades rotate around a central hub, converting wind energy into electrical energy. This rotative action is essential for harnessing renewable energy sources efficiently. Similarly, in hydroelectric plants, water flows through turbines causing them to spin. The rotative movement of these turbines generates electricity, demonstrating the versatility and importance of rotative systems in modern technology.Moreover, the concept of rotative motion can be observed in everyday appliances as well. For example, a washing machine uses rotative cycles to clean clothes effectively. The drum spins at high speeds, agitating the water and detergent, thereby ensuring that garments are thoroughly cleaned. This practical application of rotative motion shows how integral it is to our daily lives, often without us even realizing it.In addition to practical applications, the study of rotative systems also has theoretical implications in physics. The laws of motion, particularly those formulated by Sir Isaac Newton, provide the foundation for understanding rotative dynamics. Concepts such as torque and angular momentum are critical when analyzing rotative systems. Engineers must apply these principles to ensure that machines operate safely and efficiently.Furthermore, advancements in technology have led to innovations in rotative mechanisms. For instance, the development of brushless motors has revolutionized industries by providing more efficient rotative motion with less wear and tear. These motors are now widely used in various applications, from electric vehicles to household appliances, showcasing the ongoing evolution of rotative technology.In conclusion, the term rotative encapsulates a vital aspect of both engineering and everyday life. Whether it’s in complex machinery or simple household items, rotative motion plays a key role in functionality and efficiency. As technology continues to advance, understanding the principles behind rotative systems will be essential for future innovations. Embracing this knowledge not only enhances our appreciation for the mechanics of the world around us but also prepares us for the challenges of designing and maintaining the technologies of tomorrow.
在工程和机械的世界中,术语rotative指的是涉及旋转的机制。理解rotative系统的功能对任何参与设计或维护机器的人来说都是至关重要的。例如,考虑内燃机,它在很大程度上依赖于rotative运动将燃料转化为机械能。发动机的活塞上下移动,而曲轴旋转,展示了rotative元素如何协同工作以产生动力。rotative运动的原理不仅限于发动机。在风力涡轮机中,大型叶片围绕中心轴旋转,将风能转化为电能。这种rotative动作对于有效利用可再生能源至关重要。类似地,在水电站中,水流过涡轮,导致它们旋转。这些涡轮的rotative运动产生电力,展示了rotative系统在现代技术中的多功能性和重要性。此外,rotative运动的概念也可以在日常电器中观察到。例如,洗衣机利用rotative循环来有效清洗衣物。滚筒以高速旋转,搅拌水和洗涤剂,从而确保衣物被彻底清洗。这种rotative运动的实际应用显示了它在我们日常生活中的重要性,往往是在我们没有意识到的情况下。除了实际应用,rotative系统的研究在物理学上也有理论意义。牛顿爵士提出的运动定律为理解rotative动态提供了基础。扭矩和角动量等概念在分析rotative系统时至关重要。工程师必须应用这些原则,以确保机器安全高效地运作。此外,技术的进步导致了rotative机制的创新。例如,无刷电动机的发展通过提供更高效的rotative运动和更少的磨损,彻底改变了各个行业。这些电动机现在广泛用于各种应用,从电动车到家用电器,展示了rotative技术的持续演变。总之,术语rotative概括了工程和日常生活中一个重要的方面。无论是在复杂的机械中还是简单的家用物品中,rotative运动在功能性和效率上都发挥着关键作用。随着技术的不断进步,理解rotative系统背后的原理将对未来的创新至关重要。接受这一知识不仅增强了我们对周围世界机械的欣赏,而且为设计和维护未来技术的挑战做好了准备。
