Powered Vehicle

Will the Chassis need to be strengthened to withstand the pull of the elastic?

Should the driven wheels be wide or narrow?

Activity: How can you make the vehicle go faster? (Clue: is the Chassis too heavy or is there too much Rolling Friction?)

A famous scientist called Sir Isaac Newton described 3 Laws of Motion and the 3rd one says that Actions and Reactions are always equal and opposite - which is how Astronauts move about in space for example.

Activity: Try inserting first a single drinking straw, then two, three or even more to control the amount of air escaping to see if this makes a difference. Does it make the vehicle go faster or go further? (Clue: make sure the vehicle runs on the same flat, smooth surface each time).

Fixing the bottle to a Chassis will transfer this force to the vehice.

Activity: Try different amounts of water to find just the right amount to make the Rocket perform best. (Clue: water needs to be pumped out all the time there is pressurised air, but if any is left it becomes just dead-weight). Engineers would call this finding the Optimum amount of water.

Why do you think Water Rockets seem so much more powerful than Balloons? (Clue: Force = Mass x Acceleration and water is heavier than air)

Model aircraft propellors can be obtained in different diameters and powered by a rubber motor which can be made by knotting together elastic bands or, better still, using the strip elastic from model shops which is made for this purpose.

Winding up the rubber motor will place a considerable Compressive force on the Chassis and the bearing between it and the propellor. The Chassis may need to be strengthened and a small bead placed between it and the propellor may reduce Friction.

Activity: Try different diameter propellors to see which is best (Clue: if too small, the motor may 'burn out' before the vehicle has got going)

Activity: Decide on a shape of Sail, make different size versions out of centimetre squared paper and try them. Count the squares and find out the maximum sail area before your Chassis tips over.

Where is the Main Mast best positioned on the Chassis - in the middle, to the front or to the rear? Is it best to have wide wheels or narrow wheels? Can you redesign the Chassis so there are only 3 wheels?

Note: The force of the wind can be assumed to act through the Centre of Pressure of the sail. This can be assumed to be the Centre of Area or Centroid of the sail shape (e.g. for squares and rectangles it is where the diagonals cross and for triangles, join each apex to the centres of the sides opposite - i.e. it is where where the Medians cross). The higher this point is above the Chassis then the greater will be the Leverage exerted by the wind tending to tip the vehicle over.

It is possible also to use wide elastic bands directly on to the model motor spindle, but these need to drive barrel-shaped, or rounded, pulleys such that the belt rides up to the highest point in the centre of the pulley. Large wooden beads can be used for this purpose instead of having to make a barrel-shaped pulley

Activity: Visit a local Industrial Museum to see how Line Shafts were once used with barrel-shaped Pulleys to drive all machines in the factory from a central engine.

A visit a local Industrial Museum might also reveal similar mechanisms in the form of Roasting Jacks once used to rotate roasting spits above open fireplaces.

Problems with using a descending weight to power a vehicle include:

• How can the vehicle be made to travel further than the descent of the weight? (Clue: see Windlass and Block and Tackle.
• What happens to the weight once its descent is completed? Must it be carried as dead-weight or can it be discarded? If so, how?
• Will the weight add too much Rolling Friction to allow the vehicle to move at all?
• Will the Chassis structure be strong enough to support the weight?