The simple machine called a
wheel and axle refers to the assembly formed by two disks, or cylinders, of different diameters mounted so they rotate together around the same axis. The thin rod which needs to be turned is called the axle and the wider object fixed to the axle, on which we apply force is called the wheel. A tangential force applied to the periphery of the large disk can exert a larger force on a load attached to the axle, achieving
mechanical advantage. When used as the
wheel of a
wheeled vehicle the smaller cylinder is the axle of the wheel, but when used in a
windlass,
winch, and other similar applications (see medieval mining lift to right) the smaller cylinder may be separate from the axle mounted in the bearings. It cannot be used separately. Assuming the wheel and axle does not dissipate or store energy, that is it has no
friction or
elasticity, the
power input by the force applied to the wheel must equal the power output at the axle. As the wheel and axle system rotates around its bearings, points on the circumference, or edge, of the wheel move faster than points on the circumference, or edge, of the axle. Therefore, a force applied to the edge of the wheel must be less than the force applied to the edge of the axle, because power is the product of force and velocity. Let
a and
b be the distances from the center of the bearing to the edges of the wheel
A and the axle
B. If the input force
FA is applied to the edge of the wheel
A and the force
FB at the edge of the axle
B is the output, then the ratio of the velocities of points
A and
B is given by
a/b, so the ratio of the output force to the input force, or
mechanical advantage, is given by :MA = \frac{F_B}{F_A} = \frac{a}{b}. The mechanical advantage of a simple machine like the wheel and axle is computed as the ratio of the resistance to the effort. The larger the ratio the greater the multiplication of force (torque) created or distance achieved. By varying the radii of the axle and/or wheel, any amount of mechanical advantage may be gained. In this manner, the size of the wheel may be increased to an inconvenient extent. In this case a system or combination of wheels (often toothed, that is,
gears) are used. As a wheel and axle is a type of lever, a system of wheels and axles is like a compound lever. On a powered wheeled vehicle the transmission exerts a force on the axle which has a smaller radius than the wheel. The mechanical advantage is therefore much less than 1. The wheel and axle of a car are therefore not representative of a simple machine (whose purpose is to increase the force). The friction between wheel and road is actually quite low, so even a small force exerted on the axle is sufficient. The actual advantage lies in the large rotational speed at which the axle is rotating thanks to the transmission.
Ideal mechanical advantage The mechanical advantage of a wheel and axle with no
friction is called the
ideal mechanical advantage (IMA). It is calculated with the following formula: :\mathrm{IMA} = {F_\text{out} \over F_\text{in}} = { \mathrm{Radius}_\text{wheel} \over \mathrm{Radius}_\text{axle}}
Actual mechanical advantage All actual wheels have friction, which dissipates some of the power as heat. The
actual mechanical advantage (AMA) of a wheel and axle is calculated with the following formula: :\mathrm{AMA} = {F_\text{out} \over F_\text{in}} = \eta \cdot { \mathrm{Radius}_\text{wheel} \over \mathrm{Radius}_\text{axle}} where :\eta = {P_\text{out} \over P_\text{in} } is the efficiency of the wheel, the ratio of power output to power input ==References==