induced torque

简明释义

感应扭矩

英英释义

例句

1.The analysis showed that the induced torque 诱导扭矩 increased with the load on the motor.

分析显示，随着电动机负载的增加，诱导扭矩 induced torque 也随之增加。

2.In electrical engineering, understanding induced torque 诱导扭矩 is crucial for designing efficient motors.

在电气工程中，理解诱导扭矩 induced torque 对于设计高效的电动机至关重要。

3.During testing, we measured the induced torque 诱导扭矩 to ensure the motor met performance standards.

在测试过程中，我们测量了诱导扭矩 induced torque 以确保电动机符合性能标准。

4.The induced torque 诱导扭矩 created by the magnetic field is essential for the operation of transformers.

磁场产生的诱导扭矩 induced torque 对变压器的运行至关重要。

5.The motor generates an induced torque 诱导扭矩 that helps in rotating the machinery efficiently.

电动机产生的诱导扭矩 induced torque 有助于有效地旋转机械。

作文

In the realm of physics and engineering, the concept of induced torque plays a crucial role in understanding the behavior of rotating systems. Torque, in general, refers to the rotational force that causes an object to rotate around an axis. When we talk about induced torque (诱导扭矩), we are referring to the torque that is generated as a result of certain actions or conditions within a system. This phenomenon can be observed in various applications, such as electric motors, generators, and even in the dynamics of vehicles.To better comprehend induced torque, let’s consider its application in electric motors. An electric motor converts electrical energy into mechanical energy through the interaction of magnetic fields. When current flows through the motor windings, it creates a magnetic field that interacts with the permanent magnets or other magnetic fields present in the motor. This interaction leads to the generation of induced torque, which causes the rotor to spin. The amount of induced torque produced is influenced by several factors, including the strength of the magnetic field, the amount of current flowing through the windings, and the design of the motor itself.Understanding induced torque is essential for engineers and designers when creating efficient and effective machines. For instance, if the induced torque is too low, the motor may not be able to start or operate effectively under load. Conversely, if the induced torque is too high, it can lead to excessive wear and tear on the motor components, potentially causing failure. Therefore, engineers must carefully calculate and optimize the parameters that affect induced torque to ensure reliable performance.Another interesting aspect of induced torque is its relevance in the field of robotics. In robotic systems, joints and actuators often rely on motors that generate induced torque to facilitate movement. The control systems in these robots must take into account the induced torque to achieve precise movements and maintain stability. If the induced torque is not correctly managed, the robot may struggle to perform tasks or could even topple over.Moreover, induced torque is also significant in the automotive industry, particularly in electric and hybrid vehicles. These vehicles utilize electric motors that produce induced torque to drive the wheels. Understanding how to maximize the induced torque during acceleration can lead to improved performance and efficiency, making it a key focus for automotive engineers.In summary, the concept of induced torque is vital across various fields of technology and engineering. Whether it is in electric motors, robotics, or automotive applications, the ability to understand and manipulate induced torque can significantly impact the design and functionality of mechanical systems. As technology continues to advance, the study of induced torque will remain an important area of research, driving innovations that enhance performance and efficiency in numerous applications.

在物理和工程领域，诱导扭矩的概念在理解旋转系统的行为中起着至关重要的作用。扭矩通常指的是使物体围绕某个轴旋转的旋转力。当我们谈论诱导扭矩时，我们指的是在系统内由于某些动作或条件而产生的扭矩。这种现象可以在各种应用中观察到，例如电动机、发电机，甚至是车辆的动力学。为了更好地理解诱导扭矩，让我们考虑其在电动机中的应用。电动机将电能转化为机械能，通过磁场的相互作用来实现。当电流通过电动机绕组时，会产生一个与电动机中存在的永久磁铁或其他磁场相互作用的磁场。这种相互作用导致产生诱导扭矩，使转子旋转。产生的诱导扭矩的大小受多个因素的影响，包括磁场的强度、绕组中流动的电流量以及电动机本身的设计。理解诱导扭矩对于工程师和设计师在创建高效和有效的机器时至关重要。例如，如果诱导扭矩过低，电动机可能无法在负载下启动或有效运行。相反，如果诱导扭矩过高，可能会导致电动机部件的过度磨损，甚至导致故障。因此，工程师必须仔细计算和优化影响诱导扭矩的参数，以确保可靠的性能。诱导扭矩的另一个有趣方面是在机器人领域的相关性。在机器人系统中，关节和驱动器通常依赖于产生诱导扭矩的电动机来促进运动。这些机器人的控制系统必须考虑诱导扭矩以实现精确的运动并保持稳定。如果诱导扭矩没有得到正确管理，机器人可能会难以执行任务，甚至可能会倾倒。此外，诱导扭矩在汽车工业中也具有重要意义，特别是在电动和混合动力汽车中。这些汽车利用电动机产生诱导扭矩来驱动车轮。了解如何在加速过程中最大化诱导扭矩可以提高性能和效率，使其成为汽车工程师的关键关注点。总之，诱导扭矩的概念在各个技术和工程领域都是至关重要的。无论是在电动机、机器人还是汽车应用中，理解和操控诱导扭矩的能力都可以显著影响机械系统的设计和功能。随着技术的不断进步，对诱导扭矩的研究将仍然是一个重要的研究领域，推动在众多应用中提升性能和效率的创新。