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The Dynamics of Torque and Power in Rotating Machinery

In engineering, torque and power are fundamental concepts that play a critical role in the design, analysis, and operation of mechanical systems.

Torque, often described as a measure of rotational force, determines how effectively a force can cause an object to rotate around an axis. It is typically measured in Newton-meters (Nm) and is essential in systems involving motors, gears, and rotating shafts.

Power, on the other hand, is the rate at which work is done or energy is transferred. In mechanical systems, power quantifies how quickly torque can be applied to produce rotational motion. It is measured in watts (W) and is calculated as the product of torque and angular velocity.

Together, torque and power define the performance capabilities of engines, turbines, electric motors, and other rotating machinery. Understanding the relationship between these two parameters allows engineers to optimize system efficiency, ensure structural integrity, and meet performance requirements in a wide range of applications, from automotive drivetrains to industrial equipment and aerospace systems.

Torque, T, can be thought of as the rotational equivalent of force.

Linear Inertia – Force (N)  F = ma

Angular Inertia – Torque (Nm)  T = Iα

Where I = Inertia

Torque, T and Power, P are connected by the following fundamental equation:

P = Tω

How to calculate inertia is explained in a previous post

Radius of Gyration

It is often useful to consider a further parameter known as the radius of gyration (k), which is often a known quantity or for more complex rotating objects such as motor vehicle wheels, motor armatures and turbine rotors the value of radius of gyration is generally found from experimental test data.

I = mk2

Example 1

a) A wheel of mass 150 kg and radius of gyration 0.6 m, accelerates uniformly at 2 rad/s2. Find the torque required to produce this acceleration.

b) If the wheel accelerates from rest for 3 s and then runs at constant velocity for 1 minute before slowing down. Calculate the power required during the constant velocity period.

Solutions:

a)

I = mk2

I = (150) (0.6)2

I = 54 kgm2

T = Iα

T = (54) (2)

T = 108 Nm

b)

α = ω/ t

ω = αt

ω = (2)(3) = 6 rad/s

P = Tω

P = (108)(6) = 648 W

Example 2

A flywheel retards uniformly from 1500 rpm to 500 rpm in 3 minutes when under a friction torque of 200 Nm. Find the moment of inertia of the flywheel.

Solution:

The change in angular velocity is given in RPM, so we will need to convert to SI units:

ω = 1500 – 500 = 1000 rpm

ω = 1000 RPM = 1000/60 rev per second = 1000/60x 2π rad/s

ω = 104.7 rad/s

The angular acceleration can now be found:

α = Δω/Δt= 104.7/3x 60 = 0.58 rad/s2

Finally:

T = Iα

I = T/α

I = 200/0.58

I = 344 kgm2

 

Example 3

A mass of 20 kg is supported on a light rod of negligible mass so that it rotates in a horizontal plane at a radius of 300 mm at 150 rpm. Find the centripetal acceleration and hence centripetal force acting on the mass.

Solution:

Find angular velocity

ω =  150/60x 2π

ω = 15.7 rad/s

Find tangential velocity

vt= ωr

vt= (15.7) (0.3)

vt= 4.7 m/s

Find centripetal acceleration

ac= vt2 / r

ac= 4.72 / 0.3

ac= 74.0 m/s2

Finally, the centripetal force

Fc= mac

Fc= (20 )(74.0)

Fc= 1480N


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