In a first-class lever, like a seesaw, this component sits directly in the middle between the effort and the load.

A knife blade and an axe head are examples of this simple machine, which is essentially two inclined planes placed back-to-back.

A doorknob and a steering wheel are classic examples of this two-part simple machine.

If a machine has a mechanical advantage exactly equal to 1, it isn't multiplying your force, but it is changing this.

This is the standard scientific unit used to measure both work and energy.

Wheelbarrows and bottle openers are everyday examples of this specific class of lever, where the load is in the middle.

This simple machine is an inclined plane wrapped around a central cylinder.

This specific type of pulley stays attached to a single spot and only changes the direction of your pulling force, providing a mechanical advantage of 1.

This abbreviation stands for the mechanical advantage a machine would have if there were absolutely no friction.

No machine can ever be 100% efficient because some input energy is always converted into heat by this force.

When you use a hockey stick or tweezers, your effort is in the middle, making it this class of lever.

While a ramp reduces the force needed to lift an object, it increases this trade-off factor.

This type of pulley moves along with the load and cuts the effort force required in half.

You exert a force of 10 Newtons on a machine, and it lifts a 50-Newton box. This is the machine's actual mechanical advantage.

This term describes a machine that is made up of two or more simple machines working together, like a bicycle or a pair of scissors.