The young investigators are set a challenge by Dr Yan Wong.
Once the Bloodhound supersonic car has hit 1000 mph, how will it slow down again? They visit a motor sport event, where they meet Bloodhound engineer Annie Berrisford.
They find a car a bit like Bloodhound, a Split Second car powered by jet engines. It's slowed down in two ways - a parachute to bring it down from the top speed followed by wheel brakes.
Annie explains that Bloodhound will have both types too; the wheel brakes are for low speeds of less than 100 mph. They meet a young drag racer, who tells them what it's like to race at 85 mph.
Back in the hanger, Dr Yan shows them the air brakes on the side of the Bloodhound that will create drag, just like the parachute.
This short film is from the series The Bloodhound Adventure.
Teacher Notes
Students could be asked what their understanding of air resistance is, and think of examples of where they encounter it in everyday life.
To consolidate understanding, there could be a discussion about why the car needed both wheel brakes for lower speeds, and the parachutes for high speeds.
Challenge students to design their own parachutes using a selection of materials. They could test it on themselves by measuring the time taken to run 50 metres, then again with a plastic bag parachute attached, and again with a parachute made of different material. Which design had the most air resistance, and therefore slowed the students the most as they ran?
This experiment could be recorded as a video so that students can evaluate their experiment and streamline their parachutes.
Curriculum Notes
This clip will be relevant for teaching Science or Design and Technology at Key Stage 2 in England, Wales and Northern Ireland, and Level 2 in Scotland.
More from The Bloodhound Adventure
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Experimenting with reaction times video
Children from New Invention Junior School in the West Midlands investigate their reaction times and how these are affected by distractions.
What's Bloodhound like to drive? video
Primary school children investigate what driving a car at over 1000 mph would be like, by trying out at RAF flight simulator and taking a flight with Bloodhound's driver Andy Green.
Experimenting propulsion with water rockets. video
Primary school children investigate the theory behind what makes the Bloodhound Supersonic car's rocket engine work, trying to make their water rockets travel the farthest.
Harnessing air resistance with parachutes. video
Children from Links Primary School in London investigate harnessing air resistance in order to safely drop an egg, experimenting with different parachute designs.
Investigating air and water resistance. video
Primary school children investigate which shapes travel fastest through water, to understand what is the best design for the Bloodhound Supersonic car.
Investigating friction. video
Dr Yan Wong and children from Links Primary School in London investigate friction by trying to separate two interleaved books.
Is the Bloodhound SSC a car, a boat or a plane? video
Bloodhound Investigators find out if Bloodhound SSC is a car, a boat or a plane. They compare and contrast features of each with input from members of the Bloodhound team.
What impact does air resistance and density have on travelling fast? video
Primary school children try skydiving, flying a microlight and racing in a swimming pool to understand how air resistance and density will affect the Bloodhound Supersonic car.
Why doesn't Bloodhound have tyres? video
Primary school investigate why cars normally have tyres - even though Bloodhound SSC does not. They visit a race track to find out about grip and traction, and ride bikes to find out about comfort.
What makes a supersonic car move? video
Primary school children find out about the engines that will propel the Bloodhound Supersonic car to 1000 mph, a jet engine and a rocket engine.