train of gearings
简明释义
齿轮系
英英释义
例句
1.When climbing steep hills, the train of gearings allows for easier pedaling.
在爬陡坡时,传动齿轮组使得踩踏变得更加轻松。
2.Adjusting the train of gearings can improve efficiency during long rides.
调整传动齿轮组可以提高长途骑行的效率。
3.The mechanic explained how the train of gearings affects the overall speed of the vehicle.
机械师解释了传动齿轮组如何影响车辆的整体速度。
4.The bicycle's performance is greatly enhanced by the train of gearings.
这辆自行车的性能因其传动齿轮组而大大提升。
5.Each bike model has a different train of gearings to suit various riding styles.
每种自行车模型都有不同的传动齿轮组以适应各种骑行风格。
作文
In the world of mechanics and engineering, the concept of a train of gearings plays a crucial role in the functioning of various machines and devices. A train of gearings refers to a series of gears that are interconnected to transmit power and motion from one part of a machine to another. This intricate system allows for the multiplication of torque and the alteration of speed, making it essential in applications ranging from simple household appliances to complex industrial machinery.To better understand the significance of a train of gearings, let’s consider its application in a common device: the bicycle. When a cyclist pedals, the motion is transferred through a series of gears, which constitute a train of gearings. This arrangement enables the cyclist to adjust their pedaling effort based on the terrain. For instance, when climbing a hill, a lower gear ratio in the train of gearings allows for easier pedaling, while a higher gear ratio is more efficient for flat surfaces. This adaptability provided by the train of gearings enhances the overall performance and usability of the bicycle.Moreover, the design of a train of gearings can significantly impact the efficiency of a machine. Engineers must carefully calculate and select the appropriate gear sizes and arrangements to achieve the desired output. A well-designed train of gearings minimizes energy loss due to friction and maximizes the transfer of power, leading to improved performance and reduced operational costs.The importance of a train of gearings extends beyond bicycles and into various industries, including automotive engineering, robotics, and manufacturing. In automobiles, for example, the transmission system relies heavily on a train of gearings to optimize engine performance and fuel efficiency. By selecting the right gear ratios, manufacturers can create vehicles that accelerate smoothly and maintain power across different speeds.In robotics, the use of a train of gearings allows for precise control of movement and positioning. Robots often require intricate movements for tasks such as assembly, welding, or material handling. The train of gearings in these systems enables fine adjustments, allowing robots to perform complex tasks with accuracy and reliability.In conclusion, the train of gearings is a fundamental component in many mechanical systems, serving as the backbone for power transmission and motion control. Its applications are vast and varied, influencing how we interact with machines in our daily lives. Understanding the principles behind a train of gearings not only enhances our appreciation for engineering but also highlights the importance of innovation in designing efficient and effective machinery. As technology continues to advance, the role of train of gearings will undoubtedly evolve, paving the way for new possibilities in the realms of automation and mechanical design.
在机械和工程的世界中,齿轮传动系统的概念在各种机器和设备的运作中起着至关重要的作用。齿轮传动系统指的是一系列相互连接的齿轮,用于将动力和运动从机器的一部分传递到另一部分。这种复杂的系统使得扭矩的乘法和速度的改变成为可能,因此在从简单的家用电器到复杂的工业机械等应用中都是必不可少的。为了更好地理解齿轮传动系统的重要性,让我们考虑它在一个常见设备中的应用:自行车。当骑自行车的人踏脚时,运动通过一系列齿轮传递,这些齿轮构成了齿轮传动系统。这种安排使得骑行者可以根据地形调整踏板的力度。例如,当爬坡时,齿轮传动系统中的较低齿比允许更轻松的踏板,而在平坦的地面上则较高的齿比更为高效。齿轮传动系统所提供的这种适应性增强了自行车的整体性能和可用性。此外,齿轮传动系统的设计可以显著影响机器的效率。工程师必须仔细计算并选择适当的齿轮尺寸和排列,以实现所需的输出。设计良好的齿轮传动系统可以最小化由于摩擦造成的能量损失,并最大限度地提高动力传输,从而提高性能并降低运营成本。齿轮传动系统的重要性超越了自行车,扩展到汽车工程、机器人技术和制造业等各个行业。例如,在汽车中,传动系统严重依赖于齿轮传动系统来优化发动机性能和燃油效率。通过选择合适的齿比,制造商可以制造出加速平稳且在不同速度下保持动力的车辆。在机器人技术中,齿轮传动系统的使用使得运动和定位的精确控制成为可能。机器人通常需要进行复杂的运动来完成装配、焊接或材料处理等任务。这些系统中的齿轮传动系统能够进行细微调整,使机器人能够以准确和可靠的方式执行复杂任务。总之,齿轮传动系统是许多机械系统中的基本组成部分,是动力传输和运动控制的支柱。它的应用广泛而多样,影响着我们与日常生活中机器的互动。理解齿轮传动系统背后的原理不仅增强了我们对工程的欣赏,还突显了在设计高效和有效机械方面创新的重要性。随着技术的不断进步,齿轮传动系统的角色无疑将会演变,为自动化和机械设计领域的新可能性铺平道路。
