M.6(1) - FAN CART

It can be used to demonstrate the effect on propulsion when a 45° sail introduces a new component of force. Without its sail in place, the cart moves along a smooth, leveled surface. When the sail is set perpendicular to the air flow it does not move; if you adjust the sail's angle with respect to the "wind," the cart moves at different speeds, to different directions.
The fan cart also demonstrates uniform acceleration.
Dimmensions: 30 cm in length with a 25 cm x 25 cm sail.

M.6(2) - ACTION AND REACTION

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M.6(3) - PARADOX OF FORCES

This demonstration illustrates equilibrium of static forces as well as Newton's Third Law. The set-up consists of a spring scale connected through pulleys to 1 kg masses hanging on each side, as in the drawing. First, a 1 kg mass is suspended from the spring scale and the needle position noted for the class. The spring scale is now laid across the table with 1 kg attached to each side. The students are then asked to guess the reading on the spring scale. The scale can then be tipped sideways to show that it reads exaclty the same as before.

M.6(4) - REACTION CARTS

Various sets of dynamics carts are available: all of them are about 20 cm long and 500 grams in mass, with low-friction ball-bearing wheels. In one set the carts have strong horse-shoe magnets attached to them. All the others have built-in spring plungers. The carts can be held together by a string loop or hook and loop fasteners. Burning this string loop or activating the trigger button, launches each cart in opposite directions. Different masses can be added to the carts, to observe the different reactions.

M.6(5) - MAGNETS ON A BALANCE

Two ring magnets are balanced against a weight. Equilibrium is maintained, regardless of the orientation of the magnets: they can be set floating on each other's fields, (repelling), or close to each other, (attraction).

M.6(6) - HERO'S JET ENGINE

This apparatus illustrates the earliest known form of steam engine. Apart from its historical interest, it is a useful demonstration of jet propulsion, showing Newton's Third law of motion, in action. It consists of a 10 cm stopped glass bulb with jet arms extending at opposite sides. The bottle is fastened with a rubber stopper and a rod attached to a bearing wheel, so that it is free to rotate under the reaction forces of the steam jets emanating from both sides. The flask has a little water, and is mounted by its supporting rod to a stable stand. Bring the gas burner underneath it. When the steam pressure is sufficient for the flask to begin to spin, turn the flame down somewhat. The flask will continue to spin until the pressure has diminished. Do not overheat it, to avoid having boiling water being thrown across the room.

M.6(7) - CO₂ ROCKET - THE ROCKET PROPULSION DEMONSTRATOR

The demonstration includes a counter weighted metal crossbar which rests on a vertical support rod mounted on a sturdy base. A CO₂ cartridge is inserted in the holder at one end of the crossbar and the spring loaded pin is used as a firing device. When the cartridge is punctured, the release of CO₂ gas propels the crossbar around, simulating rocket flight and demonstrating that for every action there is an equal and opposite reaction.

M.6(8) - JET PROPULSION DEMONSTRATOR

The demonstration includes a counter weighted metal crossbar which rests on a vertical support rod mounted on a sturdy base. A CO₂ cartridge is inserted in the holder at one end of the crossbar and the spring loaded pin is used as a firing device. When the cartridge is punctured, the released of CO₂ gas propels the crossbar around, simulating rocket flight and demonstrating that for every action there is an equal and opposite reaction.