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Published byMaria Butler Modified over 9 years ago
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Year 9 STEM Club The Skeleton Luge
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CHALLENGE Make a model of a bob skeleton sled See how far you can launch a Barbie! Present an answer to the question: Athlete or Machine? Which is more important in the sport of bob skeleton? http://www.youtube.com/watch?v=rwOTbxO44j8
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Session plans Week 1 – Intro and start building Week 2 – Finish building and test Week 3 – Competition – Distance and Speed Week 4 – Athlete or Machine?
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Week 1 Introduction to the task Video Meet Barbie Each team given resources and drilling template Start building
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Make a 1:5 bob skeleton sled Make the runners by bending the metal rod Attach runners to pod with cable ties Make sled’s launch tube using acetate sheet, tape and a plastic nose cone (check that it fits onto the pump’s launch tube) Fix the launch tube to the pod with double-sided sticky pads
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Drilling template
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Week 2 Continue to build Start testing the launch Redesigns and refinements
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Launch the model bob skeleton sled. Launch Barbie!
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Week 3 Competition time Distance with and without Barbie Speed with and without Barbie Timing gates
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Extension Set up timing gates to measure the speed of the sled with and without the Barbie.
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What factors are going to affect the speed at which Barbie travels? What factors are going to affect the speed of the real Skeleton Luge on an ice track?
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Factors Weight The athlete’s shape The athlete’s position Aerodynamic lift Steering Clothing and equipment Starting Corners Ergonomics (how the body fits a product) Track incline (the slope down the length of the track) Friction on the ice Aerodynamic drag (air resistance) Tuning the characteristics of the skeleton Material choice Sled runners
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Week 4 Athlete vs Machine Use calculations to work out which element of the luge/athlete partnership is the most influential to its success. Summary and extension
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Potential Energy (PE) = m x g x h Change in PE for our athlete and sled = 144 639 Joules (J) Kinetic Energy (KE) = ½ x m x v 2 0.5 x 97 kg x (40.23 x 40.23) = 78495 J Amy Williams max speed Max speed if all PE transferred into KE Mass (m) of athlete and sled = 97kg Vertical drop of track (h) = 152m 1450m (diagram not to scale) Gravity (g) = 9.81 m/s 2 Energy transfer Why isn’t the all of the athlete’s and sled’s potential energy transferred into kinetic energy?
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Calculating friction force F f = x m x g F f = ………………………… =Mu, the coefficient of friction (steel on ice = 0.03). m =Mass (kg). g =The acceleration due to the gravity, which is 9.81 m/s 2. What is the friction force acting on the runners of a bob skeleton sled and athlete with the combined mass of 97 kg (athlete = 68 kg, sled = 29 kg)?
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Calculating drag force F DRAG = ½ x x C D x A f x V 2 F DRAG = …………………………. =1.2 kg/m 3 (density of air) C D =0.45(drag coefficient of athlete and sled) A f =0.139 m 2 (frontal area of athlete and sled) V =40 m/s(velocity) Calculate the drag force acting on the athlete and sled as they travel down the track at 40 m/s?
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What is the total force resisting the forward movement of the athlete and her sled down the track? F TOTAL = …………………………………… Between which velocities is friction force dominant? ……………………………………………….. Between which velocities is drag force dominant? ……………………………………………….. You can compare the two forces on the graph here. 10 0 20 30 40 50 60 70 80 5 10 15 20 25 30 35 4045 Speed in metres/second (m/s) Force in Newtons (N)
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Prove that it is better to be heavy and narrow when competing in The sport of bob skeleton. ATHLETE 1 Total mass: 97 kg A f : 0.139 m 2 ATHLETE 2 Total mass: 100 kg A f : 0.129 m 2
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Athlete or Machine? Which is more important in the sport of bob skeleton? Discuss this question with your partner/team Present your answer to the rest of the group
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Summary and Extension
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