91热爆

Children meet an Olympic hill-climb cycling champion to learn about gears on a bike. They find out why their bikes have eight gears, the difference between high and low gears, and when you should use them.

They experience that the lowest gear (gear one) makes it easier to cycle but they go slower, whereas the highest gear (gear eight) makes it harder to cycle but they go faster.

How gears work is explained using model gears, linked together in pairs on a board.

By counting the number of teeth on different-sized gears, and counting the number of times each linked gear turns, they learn about gear ratios.

They then carry out a simple experiment on their bikes, to demonstrate the distance travelled for one turn of the pedal in different gears.

The bike with a high gear (high gear ratio) has a smaller gear wheel and moves further than the bike with a low gear (low gear ratio).

The bike with the low gear is easier to pedal.

Children then use their understanding of gears to decide which gear they will need to use to pull the piano uphill.

This short film is from the 91热爆 series, Operation Awesome, in which students explore a range of amazing practical science challenges with presenter Steve Mould.

Teacher Notes

Key Stage 2:

This short film could be used to introduce the idea that some mechanisms, including gears, allow a smaller force to have a greater effect.

This could be used to prompt discussion around their own experience of cycling with gears. They could explore other real-life examples of machines that use gears to make work easier e.g. egg-whisks/food mixers, tin-openers, clock gears etc.

Your pupils could investigate gear ratios themselves, using sets of 鈥榗ogs鈥 made out of bottle tops fixed to a board, with corrugated cardboard round them to form the teeth, and count the number of turns of each cog.

The quantitative concept of gear ratios can be used to challenge the more able.

Key Stage 3:

This could be used to introduce the idea that simple machines give bigger force but at the expense of smaller movement (and vice versa): product of force and displacement unchanged.

They could extend your pupils' understanding of bicycle gears by considering the combined effect of both front and rear gear wheels.

Pupils could explore other examples where gears are used in real life e.g. simple examples such as egg-whisks/food mixers, tin-openers, clock gears and more complex examples such as car gearbox, rack-and-pinion gears in car steering etc.

Pupils could be encouraged to consider gears as a type of lever or 鈥榝orce-magnifier鈥, identifying the fulcrum or turning point, the effort force and the load force, in different gear systems and calculating the total work done.

Curriculum Notes

This short film will be relevant for teaching science at Key Stage 2 or Second Level in Scotland, or physics at Key Stage 3 or Third Level in Scotland.

More from Operation Awesome

Will pulleys allow children to beat Britain鈥檚 strongest man? video

Britain鈥檚 strongest man pulls a 12 tonne truck. Steve Mould challenges a group of 9 and 10 year olds to use the science of pulleys to do the same.

Will pulleys allow children to beat Britain鈥檚 strongest man?

Helicopter rescue and the science of floating. video

Steve Mould鈥檚 treasure is lost underwater. Children use the science of floating and displacement to raise it from the bottom of the pool with the smallest amount of air.

Helicopter rescue and the science of floating

How to make the fizziest bath bomb. video

Challenged by Steve Mould to make the fizziest possible bath bomb, children test a range of recipes. They work out how to measure 鈥榝izziness鈥 (the amount of CO2) and make sure it鈥檚 a fair test.

How to make the fizziest bath bomb

How dinosaurs footprints get made in solid rock. video

A group of children are challenged to find real dinosaur footprints on the beach 鈥 and discover why it takes many millions of years for footprints to be made in solid rock.

How dinosaurs footprints get made in solid rock

How to calculate the height of a dinosaur from its footprint. video

How do you find the height of the dinosaur from dinosaur footprints? Because human and dinosaur legs are similar, you can do it by measuring the length of your own leg and foot.

How to calculate the height of a dinosaur from its footprint

Seeing through smoke - the heat camera. video

A group of 10 and 11 year olds have to rescue someone from a smoke filled building in the dark. They get to choose a special camera to help. How will they pick the right one?

Seeing through smoke - the heat camera