Atwood machine

Illustration of Atwood machine, 1905.

The Atwood machine (or Atwood's machine) was invented in 1784 by the English mathematician George Atwood as a laboratory experiment to verify the mechanical laws of motion with constant acceleration. Atwood's machine is a common classroom demonstration used to illustrate principles of classical mechanics.

The ideal Atwood Machine consists of two objects of mass m₁ and m₂, connected by an inextensible massless string over an ideal massless pulley.^[1]

When m₁ = m₂, the machine is in neutral equilibrium regardless of the position of the weights.

When m₁ ≠ m₂ both masses experience uniform acceleration.

Equation for constant acceleration

The free body diagrams of the two hanging masses of the Atwood machine. Our sign convention, depicted by the acceleration vectors is that m₁ accelerates downward and that m₂ accelerates upward, as would be the case if m₁ > m₂

We are able to derive an equation for the acceleration by using force analysis. If we consider a massless, inextensible string and an ideal massless pulley, the only forces we have to consider are: tension force (T), and the weight of the two masses (W₁ and W₂). To find an acceleration we need to consider the forces affecting each individual mass. Using Newton's second law (with a sign convention of $m_{1}>m_{2}$ ) we can derive a system of equations for the acceleration (a).

As a sign convention, we assume that a is positive when downward for $m_{1}$ and upward for $m_{2}$ . Weight of $m_{1}$ and $m_{2}$ is simply $W_{1}=m_{1}g$ and $W_{2}=m_{2}g$ respectively.

Forces affecting m₁:

$\;m_{1}g-T=m_{1}a$

Forces affecting m₂:

$\;T-m_{2}g=m_{2}a$

and adding the two previous equations we obtain

$\;m_{1}g-m_{2}g=m_{1}a+m_{2}a$ ,

and our concluding formula for acceleration

$a=g{m_{1}-m_{2} \over m_{1}+m_{2}}$

Conversely, the acceleration due to gravity, g, can be found by timing the movement of the weights, and calculating a value for the uniform acceleration a: $a={\frac {2d}{t^{2}}}$ .

The Atwood machine is sometimes used to illustrate the Lagrangian method of deriving equations of motion.^[2]

Equation for tension

It can be useful to know an equation for the tension in the string. To evaluate tension, substitute the equation for acceleration in either of the 2 force equations.

$a=g{m_{1}-m_{2} \over m_{1}+m_{2}}$

For example, substituting into $m_{1}a=m_{1}g-T$ , results in

$T={2gm_{1}m_{2} \over m_{1}+m_{2}}={2g \over 1/m_{1}+1/m_{2}}$

Equations for a pulley with inertia and friction

For very small mass differences between m₁ and m₂, the rotational inertia I of the pulley of radius r cannot be neglected. The angular acceleration of the pulley is given by the no-slip condition:

$\alpha ={a \over r},$

where $\alpha$ is the angular acceleration. The net torque is then:

$\tau _{\mathrm {net} }=\left(T_{1}-T_{2}\right)r-\tau _{\mathrm {friction} }=I\alpha$

Combining with Newton's second law for the hanging masses, and solving for T₁, T₂, and a, we get:

Acceleration:

a={{g(m_{1}-m_{2})-{\tau _{\mathrm {friction} } \over r}} \over {m_{1}+m_{2}+{{I} \over {r^{2}}}}}

Tension in string segment nearest m₁:

T_{1}={{m_{1}g(2m_{2}+{{I} \over {r^{2}}}+{{\tau _{\mathrm {friction} }} \over {rg}})} \over {m_{1}+m_{2}+{{I} \over {r^{2}}}}}

Tension in string segment nearest m₂:

T_{2}={{m_{2}g(2m_{1}+{{I} \over {r^{2}}}+{{\tau _{\mathrm {friction} }} \over {rg}})} \over {m_{1}+m_{2}+{{I} \over {r^{2}}}}}

Should bearing friction be negligible (but not the inertia of the pulley and not the traction of the string on the pulley rim), these equations simplify as the following results:

Acceleration:

a={{g(m_{1}-m_{2})} \over {m_{1}+m_{2}+{{I} \over {r^{2}}}}}

Tension in string segment nearest m₁:

T_{1}={{m_{1}g(2m_{2}+{{I} \over {r^{2}}})} \over {m_{1}+m_{2}+{{I} \over {r^{2}}}}}

Tension in string segment nearest m₂:

T_{2}={{m_{2}g(2m_{1}+{{I} \over {r^{2}}})} \over {m_{1}+m_{2}+{{I} \over {r^{2}}}}}

Practical implementations

Atwood's original illustrations show the main pulley's axle resting on the rims of another four wheels, to minimize friction forces from the. Many historical implementations of the machine follow this design.

An elevator with a counterbalance approximates an ideal Atwood machine and thereby relieves the driving motor from the load of holding the elevator cab — it has to overcome only weight difference and inertia of the two masses. The same principle is used for funicular railways with two connected railway cars on inclined tracks, and for the elevators on the Eiffel Tower which counterbalance each other.

Notes

↑ Tipler, Paul A. (1991). Physics For Scientists and Engineers (3rd, extended ed.). New York: Worth Publishers. p. 160. ISBN 0-87901-432-6. Chapter 6, example 6-13
↑ Goldstein, Herbert (1980). Classical Mechanics (2nd ed.). New Delhi: Addison-Wesley/Narosa Indian Student Edition. pp. 26–27. ISBN 81-85015-53-8. Section 1-6, example 2

External links

Professor Greenslade's account on the Atwood Machine
Atwood's Machine by Enrique Zeleny, The Wolfram Demonstrations Project.

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