# Perpetual Motion Quiz

On Earth, perpetual motion machines don't stand a chance. You don't even have to look at one to know it won't work. “Oh,” you can say knowingly, “it'll be killed by friction and other dissipative forces.” And most of the time you will be right, which is pretty annoying.

So to make things more interesting, we've put this quiz on Slippery, a planet in the star system Wenwet. On Slippery there is no friction, drag, or viscosity (or any other one-way process that steals energy from machines). You can't walk on Slippery, because your foot can't push against the floor. But you can build perpetual motion machines.

This doesn't mean, however, that every machine you make will run forever. If you try to make a machine that has to do work as well as keep running, it will eventually come to a stop because more energy will be coming out than going in. How good an engineer are you? Can you tell which of these machines will stop on Slippery and which will run forever?

## Hammer Wheel

### How It Is Supposed to Work

Because there is an odd number of hammers, there are more hammers on one side of the wheel than the other. This lack of balance makes the wheel turn round.

### Would It Keep Running on Slippery?

Provided it went round once, it would keep going forever. The flopping hammers just make it jerky, like the guy who thought it up. At least that's what one physicist told us. Another one, though, isn't so sure. The hammers would bounce back and fourth (everything bounces perfectly on Slippery), so the interaction between hammers and wheel is very complicated and may not repeat from one rotation to the next. If you can answer this one, you're ready for your Ph.D. in physics.

## Perpetual Fountain

### How It Is Supposed to Work

The weight of the liquid in the goblet forces the underlying liquid up the tube.

### Would It Keep Running on Slippery?

The inventor didn't understand liquid. The weight of the stuff in the goblet would force liquid only partway up the tube. It would stop when it was perfectly level with the liquid in the goblet.

## Anti-Gravity Pendulum

### How It Is Supposed to Work

The bowling ball is a pendulum. Once started, gravity will tend to keep it moving. Just to make things interesting, we've stuck an imaginary gravity shield under half of its swing. What happens to the pendulum if you do that?

### Would It Keep Running on Slippery?

Every physicst we showed this to hated it. How can you put imaginary physics in a children's magazine? Well, there's no such planet as Slippery, either, and on Slippery, this gizmo doesn't just run forever, it gets faster and faster. (On the anti-grav side the pendulum keeps its speed going up, then gets faster going down.)

## Magnet Machine

### How It Is Supposed to Work

The magnet draws a steel ball up the ramp until it drops through the hole near the top. It rolls back to the bottom hole, where the magnet draws it back up again.

### Would It Keep Running on Slippery?

Yes, maybe if you could just set everything up exactly right: magnet, ramp, ball…. But even then, no way… too many things bumping into each other…yes…no…oh, forget this one! We're not sure! (But leaning toward no.)

## Self–Blowing Windmill

### How It Is Supposed to Work

Wind from the bellows blows against the vanes of the windmill, making it rotate. Its rotation opens and closes the bellows, blowing air against the windmill.

### Would It Keep Running on Slippery?

No Way! This machine has a major energy leak. Very little of the wind's energy would go into moving the vanes of the windmill; the rest would blow away. On Earth, it would be even worse.

## Vocabulary

dissipative:
Scattered; wasted.

perpetual:
Continuing without interruption; constant.

viscosity:
The condition or property of having a high resistance to flow.