driving torque
简明释义
传动转矩
英英释义
Driving torque refers to the rotational force applied to an object, typically measured in Newton-meters (Nm), that causes it to rotate around an axis. | 驱动扭矩是指施加在物体上的旋转力,通常以牛顿米(Nm)为单位测量,使其绕轴旋转。 |
例句
1.In electric motors, the driving torque is crucial for determining the efficiency of the machine.
在电动机中,驱动扭矩对确定机器的效率至关重要。
2.The bicycle's performance is greatly affected by the driving torque applied to the pedals.
自行车的性能受到施加在踏板上的驱动扭矩的很大影响。
3.Understanding the driving torque helps engineers design better gear systems.
理解驱动扭矩有助于工程师设计更好的齿轮系统。
4.In a race car, maximizing the driving torque can lead to better lap times.
在赛车中,最大化驱动扭矩可以带来更好的圈速。
5.The engine produces a significant amount of driving torque, allowing the vehicle to accelerate quickly.
发动机产生了大量的驱动扭矩,使得车辆能够快速加速。
作文
Driving torque is a fundamental concept in mechanics and engineering, particularly when discussing the performance of engines and machinery. It refers to the rotational force that is generated by an engine or motor, which ultimately drives the movement of a vehicle or machine. Understanding driving torque (驱动扭矩) is crucial for engineers and mechanics as it directly influences the efficiency and power output of various mechanical systems.In the context of automobiles, driving torque (驱动扭矩) plays a significant role in determining how quickly a car can accelerate and how well it can climb steep inclines. When a driver presses the accelerator pedal, the engine produces a certain amount of torque that is transmitted to the wheels. This torque is what propels the vehicle forward. The higher the driving torque (驱动扭矩), the more powerful the acceleration will be.Moreover, driving torque (驱动扭矩) is not only essential for acceleration but also for maintaining speed. When a vehicle is cruising at a constant speed, the engine must generate enough torque to overcome various resistive forces such as air resistance and friction. Therefore, understanding how to optimize driving torque (驱动扭矩) can lead to better fuel efficiency and overall performance.In addition to vehicles, driving torque (驱动扭矩) is also critical in industrial applications. For instance, in manufacturing plants, electric motors are often used to drive conveyor belts and other machinery. The amount of driving torque (驱动扭矩) produced by these motors determines how much load they can handle. If the torque is insufficient, the motor may struggle to move the equipment, leading to inefficiencies and potential breakdowns.Furthermore, the relationship between driving torque (驱动扭矩) and power is defined by the equation Power = Torque × Angular Velocity. This means that for a given amount of torque, increasing the speed at which the system operates will result in higher power output. Engineers must carefully consider this relationship when designing systems to ensure they meet performance requirements without exceeding limitations.When discussing driving torque (驱动扭矩), it is also important to consider factors such as gear ratios and wheel size. The gear ratio of a vehicle affects how torque is transmitted from the engine to the wheels. A lower gear ratio provides more torque for acceleration but may limit top speed, while a higher gear ratio can enhance fuel efficiency at cruising speeds but may reduce acceleration capabilities.In conclusion, driving torque (驱动扭矩) is a vital aspect of both automotive and industrial engineering. Its impact on performance, efficiency, and power output cannot be overstated. By understanding and optimizing driving torque (驱动扭矩), engineers can design better systems that meet the demands of modern technology and consumer expectations. Whether in cars, machinery, or any mechanical application, the principles behind driving torque (驱动扭矩) remain integral to achieving success in engineering and mechanics.
驱动扭矩是力学和工程学中的一个基本概念,尤其是在讨论发动机和机械性能时。它指的是由发动机或电动机产生的旋转力,最终推动车辆或机器的运动。理解驱动扭矩(driving torque)对工程师和机械师至关重要,因为它直接影响各种机械系统的效率和功率输出。在汽车的背景下,驱动扭矩(driving torque)在决定汽车加速的速度和爬坡能力方面发挥着重要作用。当驾驶者踩下油门踏板时,发动机会产生一定量的扭矩,这些扭矩会传递到车轮上。这种扭矩就是推动车辆前进的力量。驱动扭矩(driving torque)越高,加速的力量就越强。此外,驱动扭矩(driving torque)不仅对加速至关重要,也对维持速度至关重要。当一辆车以恒定速度巡航时,发动机必须产生足够的扭矩来克服空气阻力和摩擦等各种阻力。因此,理解如何优化驱动扭矩(driving torque)可以提高燃油效率和整体性能。除了车辆外,驱动扭矩(driving torque)在工业应用中也至关重要。例如,在制造工厂中,电动机通常用于驱动输送带和其他机械。这些电动机产生的驱动扭矩(driving torque)的大小决定了它们能够处理的负载。如果扭矩不足,电动机可能难以移动设备,从而导致效率低下和潜在的故障。此外,驱动扭矩(driving torque)与功率之间的关系由公式功率 = 扭矩 × 角速度定义。这意味着在给定的扭矩下,提高系统操作的速度将导致更高的功率输出。工程师在设计系统时必须仔细考虑这一关系,以确保它们满足性能要求而不超出限制。在讨论驱动扭矩(driving torque)时,还需要考虑齿轮比和车轮尺寸等因素。车辆的齿轮比影响扭矩从发动机到车轮的传递。较低的齿轮比为加速提供更多的扭矩,但可能限制最高速度,而较高的齿轮比可以在巡航速度下提高燃油效率,但可能降低加速能力。总之,驱动扭矩(driving torque)是汽车工程和工业工程中的一个重要方面。它对性能、效率和功率输出的影响不容小觑。通过理解和优化驱动扭矩(driving torque),工程师可以设计出更好的系统,以满足现代技术和消费者期望的需求。无论是在汽车、机械还是任何机械应用中,驱动扭矩(driving torque)背后的原理始终是实现工程和机械成功的关键。
相关单词
