Pulleys are mechanisms compost by wheel and rope used to lift heavy objects onto tall heights. They change the direction of an applied force and they can even reduce the force needed to lift a weight. Pulleys systems are common used in constructions.

In the exhibit, systems of one to five
pulleys are uses to lift a weight of 1lb onto a 1 ft height.

**A SIMPLE BLOCK
AND TACKLE**

In order to
lift the 1lb weight **W** you
have to apply a force of** F** on
the rope equal to the weight **W**.
The rope is now under a tension **T
**equal to the force **F**.

To lift this
weight a distance of **H**=1 ft
you will have to pull in a length **
L= H=1** ft of the rope.

The mechanical
advantage **M** is one:
**M=W/F=1.**

**ADDING A PULLEY**

In order to
lift the 1lb weight **W** you
have to apply a force of **
F**
on the rope. Like in the simple case of the block and tackle the
rope is under a tension **T**
equal to the applied force **F**.
But in this case the weight is supported by twice the tension:
**2T=W**. The
force **F**
you have to apply then is only half of the weight
**W**.

By having the
second pulley you have decreased the force needed to lift the weight.
The mechanical advantage **M** is
now two**: M=W/F=2T/T=2.**

However, order
to lift the weight a distance of
**H**=1 ft you will have
to pull in a length **L** =
**H **x**
M** =2
ft of the rope.

You gained by having to apply a smaller force, but
had to compensate by having to pull a longer length of rope.

**MORE PULLEYS
**

Here the
mechanical advantage is M=3

**Conclusion**

The mechanical advantage **M** is equal to number of ropes present at the weight end**.
**The force needed to raise the weight is
**W/M**. In order to lift the
weight a distance **H** you will
have to pull a corresponding longer length of rope
**L = H x M**.