Hover Frenzy
Transcription
Hover Frenzy
rev. 10/2012 Hover Frenzy Scenario Your team has been selected as one of the final qualifiers to supply hovercraft to evacuate personnel from the Australian Antarctic base in the event of an emergency. Today each team is building a model hovercraft that will be tested against the other finalists. Aim The aim of this full-day activity is to design, build and fly a model hovercraft that is fast, manoeuvrable and has a good hover height. What to do Each team gets a lift fan, two motor/propellers, a battery, controller, saw, cutting block, scissors, and consumables (balsa wood, styrofoam trays, plastic sheet, tape, etc) to make a working model hovercraft. Some things to consider when building the hovercraft are: • Should your hovercraft have a skirt? If so, what type? • Where and how should the motors and fans be mounted? • How much drag does the craft experience? How can this be reduced? • How is weight distributed around the hovercraft? What effect does it have? • Is speed the most important design goal? Discuss these questions and build the craft! Get as much practice as possible ‘flying’ the hovercraft over the 3 courses. There is one course to test the craft’s speed, another to test hover height, and the third to test the craft’s manoeuvrability around an obstacle course. Improve the hovercraft design (and the pilot’s skill!) by practice, trial and error. Rules For all the tests, the lift fan and thrust propellers may only be turned on when the coordinator is watching and indicates that it is time do so. Steering or braking the hovercraft by pulling on the power cable is not allowed. There is a 10 point penalty per offence. In the obstacle course the hovercraft must fly between the red and the white witch’s hats in the correct order. The hovercraft must start the hover height test sitting, stationary, on the rubber matting with the rear of the craft level with the end of the matting. Scoring The total score is obtained by adding together the results of 3 individual tests. Tips The lift fan only blows air in one direction. This is denoted on the fan by a coloured dot; placing this dot down will push the air beneath the craft. A pair of motor/propellers is used to provide forward movement and to steer the hovercraft. Slowing the right propeller causes the craft to turn right, etc. This material may not be reproduced without permission 1 rev. 10/2012 STUDENT ACTIVITY NOTES Hover Frenzy The problem The aim of this activity is to design, build and fly a model hovercraft that is fast, manoeuvrable and has a good hover height. Duration This activity runs for a full day (approximately 4 hours). Terms There are some terms used in this activity that you may not be familiar with: Skirt Flexible material (either individual ‘fingers’ or a continuous strip) attached to the edge of the hovercraft that forms a seal between the base of the hovercraft and the ground. When inflated the skirt increases the craft’s hover height and allows it to clear obstacles. It can also improve the craft’s controllability. Ground effect The lift fan forces air under the hovercraft forming a cushion of air. The air also rebounds off the ground causing a force that lifts the craft. This lift force is known as the ground effect. Baffle Sometimes a diffusing panel known as a baffle is mounted under a hovercraft’s lift fan. It is used to improve the airflow (particularly with advanced skirt designs) and to reduce the tendency of the hovercraft to rotate about its axis. Materials Each team will be given a lift fan, 2 propulsion motor/propellers, a control box and a battery. Scissors and a balsa saw are also supplied to cut the materials. Various other consumable materials are also available including two sizes of styrofoam trays, balsa wood, plastic sheeting (for the skirt), paper binders, masking tape and plasticine (used as ballast). Rules The rules are straightforward: 1. For all the tests, the lift fan and thrust propellers may only be turned on when the coordinator is watching and indicates that it is time do so. 2. Steering or braking the hovercraft by pulling on the power cable is not allowed. There is a 10 point penalty per offence. 3. In the obstacle course the hovercraft must fly between the red and the white witch’s hats in the correct order. There is a penalty of 5 points for each tennis ball that is knocked off a witch’s hat. 4. The hovercraft must start the hover height test sitting on the rubber matting with the rear of the craft level with the end of the matting. When instructed by the coordinator, the craft must travel over as many steps as possible, as quickly as possible. This material may not be reproduced without permission 2 rev. 10/2012 Scoring The total score for each team is obtained by adding together the results of three individual tests: 1. A speed test over 12 metres, worth a maximum of 100 points. This models the craft’s ability to quickly cross open waters. 2. An obstacle course worth a maximum of 200 points. Points will be awarded based on the time taken to negotiate the course and the number of obstacles hit. This test models the craft’s manoeuvrability. 3. A hover height test, worth a maximum of 150 points, simulates the climb up out of the water. Your team’s score for this test will be a combination of the number of steps crossed and the time taken. Tips Don’t forget to bring these notes with you to the Challenge. Think carefully about size and materials used. Also, consider the type of flexible plastic skirt on the hovercraft (if any). The addition of a skirt will greatly increase the hover height and controllability of the craft but may slow it down. The lift fan only blows air in one direction. This is denoted on the fan by a coloured dot; placing this dot down will push the air beneath the craft. A pair of motor/propellers is used to provide forward movement and to steer the hovercraft. Slowing the right propeller causes the craft to turn right, etc. The control box has three parts. The central switch turns the lift fan on or off. The sliders on either side of the control box are connected to the thrust motors via a long, flat power cable. When centred, these sliders provide no power to the motors. However, when they have been moved forward or backward, they power the motors in the forward or reverse direction. The direction of the fan rotation can be reversed by flipping the switch immediately next to the slider. A ‘skirt’ increases the craft’s hover height and, because a skirt can fold and deform, allows the craft to negotiate rough surfaces and obstacles. There are three main types of skirts. 1. A bag skirt (shown below in figure 1) consists of one sheet of material that covers the base of the craft and has holes in it to allow the air to escape. This type of skirt is simple to manufacture and reduces friction with the ground. Unfortunately it may have poor hover height. Air intake for lift propeller Skirt Skirt Air flow Air cushion Holes in skirt Holes in skirt Figure 1: LEFT: Cross-section through a hovercraft. RIGHT: View underneath a bag skirt. This material may not be reproduced without permission 3 rev. 10/2012 2. A tube skirt (shown below in figure 2) is similar to a bag skirt except that the material forms a loop around the edge of the craft. The top edge of the loop is attached to the rim of the craft, the bottom edge of the loop is attached to the edge of the baffle mounted below the lift fan. Holes are placed on the inside wall of the tube, allowing the air to escape and form the air cushion. Air intake for lift propeller Baffle Skirt Holes in skirt Skirt Holes in skirt Figure 2: LEFT: Cross-section through a hovercraft. RIGHT: View of underneath a tube skirt. 3. A segmented skirt is similar to a tube skirt but is composed of a large number of individual segments. Each segment inflates to give a good hover height and excellent obstacle clearance. This type of skirt is most commonly used in real hovercraft but should not be used on your model hovercraft as it is extremely difficult to make and install. Air intake for lift propeller Baffle Skirt Skirt Individual segments with holes on inside Segments of skirt Figure 3: LEFT: Cross-section through a hovercraft. RIGHT: View of underneath a segmented skirt. The tube and segmented skirt designs use a baffle underneath the lift fan to improve air flow, cushion formation, and hover height. Setting up a baffle can be very tricky. If your team uses a baffle and the performance of the hovercraft doesn’t improve, it may be better to remove it. This material may not be reproduced without permission 4 rev. 10/2012 SCORE SHEET Hover Frenzy School name: ___________________________________________ 1. Speed test Attempt Time Score = 100 - time (seconds) 1 2 3 Best score (A) 2. Obstacle course Attempt Time (seconds) Score (B) = 200 - time (C) = Tennis balls x 5 Total score Number of balls knocked off witch’s hats x 5 =B-C 1 2 3 Best score (D) 3. Hover height test Attempt Time (seconds) Step number Score from lookup table on back of this sheet 1 2 3 Best score (E) Additional 10 points for disassembling and returning parts (F) ____________ Penalties (G) _______ Subtract 10 points for each time the power cord was used to steer or brake FINAL SCORE = ( A + D + E + F ) - G = __________ This material may not be reproduced without permission 5 rev. 10/2012 Lookup table for the hover height test Time (s) Step 1 Step 2 Step 3 Step 4 Step 5 Step 6 Step 7 Step 8 Step 9 Step 10 2 34 44 54 64 74 84 94 110 130 150 3 33 43 53 63 73 83 93 109 129 149 4 32 42 52 62 72 82 92 108 128 148 5 31 41 51 61 71 81 91 107 127 147 6 30 40 50 60 70 80 90 106 126 146 7 29 39 49 59 69 79 89 105 125 145 8 28 38 48 58 68 78 88 104 124 144 9 27 37 47 57 67 77 87 103 123 143 10 26 36 46 56 66 76 86 102 122 142 12 25 35 45 55 65 75 85 101 121 141 14 24 34 44 54 64 74 84 100 120 140 16 23 33 43 53 63 73 83 99 119 139 18 22 32 42 52 62 72 82 98 118 138 20 21 31 41 51 61 71 81 97 117 137 22 20 30 40 50 60 70 80 96 116 136 24 19 29 39 49 59 69 79 95 115 135 26 18 28 38 48 58 68 78 94 114 134 28 17 27 37 47 57 67 77 93 113 133 30 16 26 36 46 56 66 76 92 112 132 32 15 25 35 45 55 65 75 91 111 131 34 14 24 34 44 54 64 74 90 110 130 36 13 23 33 43 53 63 73 89 109 129 38 12 22 32 42 52 62 72 88 108 128 40 11 21 31 41 51 61 71 87 107 127 42 10 20 30 40 50 60 70 86 106 126 44 9 19 29 39 49 59 69 85 105 125 46 8 18 28 38 48 58 68 84 104 124 48 7 17 27 37 47 57 67 83 103 123 50 6 16 26 36 46 56 66 82 102 122 52 5 15 25 35 45 55 65 81 101 121 54 4 14 24 34 44 54 64 80 100 110 56 3 13 23 33 43 53 63 75 90 100 58 2 12 22 32 42 52 62 70 80 90 60 or more 1 11 21 31 41 51 61 65 70 80 This material may not be reproduced without permission 6