all-round crank motion

简明释义

曲柄旋转动作

英英释义

例句

1.The engine's performance improved significantly after optimizing the all-round crank motion system.

在优化了全方位曲柄运动系统后，发动机的性能显著提高。

2.Using a device with all-round crank motion allows for smoother operation and less wear on components.

使用具有全方位曲柄运动的设备可以实现更平稳的操作，并减少部件磨损。

3.The bicycle design incorporates an all-round crank motion to enhance pedaling efficiency.

这款自行车设计采用了全方位曲柄运动以提高踩踏效率。

4.The innovative design features an all-round crank motion that reduces energy loss during operation.

这款创新设计具有全方位曲柄运动，可以减少操作过程中的能量损失。

5.In our workshop, we learned about the mechanics of all-round crank motion in various machines.

在我们的车间里，我们学习了各种机器中全方位曲柄运动的机械原理。

作文

The concept of all-round crank motion is pivotal in understanding various mechanical systems, particularly in the realm of engineering and physics. This term refers to the comprehensive movement facilitated by a crank mechanism that allows for rotational motion to be converted into linear motion and vice versa. In essence, all-round crank motion encompasses the full range of motion that a crank can achieve, making it an essential component in many machines and devices.To illustrate this concept, consider the example of a bicycle. The pedals of a bicycle are attached to cranks that rotate around a fixed axis. When a cyclist pedals, the all-round crank motion transforms the circular motion of the pedals into the linear motion of the bicycle moving forward. This transformation is not only efficient but also demonstrates the elegance of mechanical design. The ability of the crank to facilitate such a versatile motion is what makes it a fundamental element in numerous applications.In addition to bicycles, all-round crank motion is also evident in various engines, such as internal combustion engines. Here, the crankshaft plays a crucial role in converting the linear motion of the pistons into rotational motion, which ultimately powers the vehicle. This process showcases the versatility and importance of crank mechanisms in modern machinery. Without the all-round crank motion, many of our everyday machines would not function as effectively.Moreover, the principles behind all-round crank motion extend beyond just mechanical systems. In robotics, for instance, engineers design robotic arms that utilize crank-like mechanisms to achieve precise movements. These robotic systems often rely on the same principles of motion conversion, allowing them to perform complex tasks with ease. The adaptability of the crank mechanism highlights its significance in advancing technology and automation.Furthermore, the study of all-round crank motion is not limited to practical applications; it also serves as an important topic in theoretical physics. Understanding how forces interact within a crank system can lead to insights about energy transfer and efficiency. Engineers and physicists alike analyze these systems to optimize performance and reduce energy loss, showcasing the relevance of all-round crank motion in both academic and practical settings.In conclusion, the term all-round crank motion encapsulates a fundamental aspect of mechanical engineering that is crucial for the operation of various machines and systems. Its ability to convert motion types makes it indispensable in everyday applications, from bicycles to advanced robotic systems. As technology continues to evolve, the principles of all-round crank motion will remain integral to innovation and efficiency in engineering. By understanding and mastering this concept, we can appreciate the intricate designs that make our modern world possible.

‘全方位曲柄运动’的概念在理解各种机械系统中至关重要，特别是在工程和物理学领域。这个术语指的是通过曲柄机制促进的全面运动，使旋转运动转化为线性运动，反之亦然。实质上，‘全方位曲柄运动’涵盖了曲柄可以实现的全部运动范围，使其成为许多机器和设备中的基本组成部分。为了说明这个概念，可以考虑自行车的例子。自行车的踏板连接到围绕固定轴旋转的曲柄。当骑自行车的人踩踏板时，‘全方位曲柄运动’将踏板的圆形运动转化为自行车向前移动的线性运动。这种转化不仅高效，而且展示了机械设计的优雅。曲柄能够促进如此多样化的运动正是它成为众多应用中的基本元素的原因。除了自行车之外，‘全方位曲柄运动’在各种发动机中也显而易见，例如内燃机。在这里，曲轴在将活塞的线性运动转化为旋转运动中发挥着关键作用，这最终为车辆提供动力。这个过程展示了曲柄机制在现代机械中的多样性和重要性。如果没有‘全方位曲柄运动’，我们日常的许多机器将无法有效运作。此外，‘全方位曲柄运动’背后的原理不仅限于实际应用；它还是理论物理学中的一个重要主题。了解力在曲柄系统中的相互作用可以为能量转移和效率提供见解。工程师和物理学家都分析这些系统，以优化性能并减少能量损失，展示了‘全方位曲柄运动’在学术和实际环境中的相关性。总之，术语‘全方位曲柄运动’概括了机械工程的一个基本方面，对于各种机器和系统的运行至关重要。它转换运动类型的能力使其在日常应用中不可或缺，从自行车到先进的机器人系统。随着技术的不断发展，‘全方位曲柄运动’的原理将继续在工程创新和效率中发挥核心作用。通过理解和掌握这一概念，我们可以欣赏到使我们现代世界成为可能的精密设计。