Difference between revisions of "Flying Bird"
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==Overview== | ==Overview== | ||
− | '''Flying Bird''' was a trial event for both divisions at the [[University of Wisconsin 2011|2011 National Tournament]]. The top three overall teams in this event were awarded medals. It is an aviation event in which competitors build an ornithological flying device (i. e. a device which flies by the flapping of wings; hence the name "Flying Bird"), called | + | '''Flying Bird''' was a trial event for both divisions at the [[University of Wisconsin 2011|2011 National Tournament]]. The top three overall teams in this event were awarded medals. It is an aviation event in which competitors build an ornithological flying device (i. e. a device which flies by the flapping of wings; hence the name "Flying Bird"), called an "ornithopter". Due to the difficulty of this event, it is unlikely that it will become a full event in the near future. |
One version of the rules from 2009/2010 can be found [http://soinc.org/sites/default/files/uploaded_files/Flying%20Bird%209-3-09%20C.pdf here]. | One version of the rules from 2009/2010 can be found [http://soinc.org/sites/default/files/uploaded_files/Flying%20Bird%209-3-09%20C.pdf here]. | ||
− | == | + | ==Construction== |
− | + | A basic ornithopter consists of a wing, stabilizer, motor stick, a flapping mechanism, and connecting rods. Very light balsa wood and lightweight covering are needed to construct the wing and horizontal stabilizer. Mylar film and Japanese Esaki tissue are good options for covering. Flapping mechanisms are more complicated, and typically require music wire, a metal bearing tube, wooden connecting rods, and a plastic bead. | |
+ | ===Wing=== | ||
+ | The simple "membrane" type of ornithopter wing is the most commonly used. It consists of only a balsa leading spar and a wing membrane in the shape of a half circle from lightweight covering. The membrane portion of the wing will passively lag behind the rigid wing spar. When the wing is going up, it will also tilt upward. When the wing is going down, it will angle downward. This is called the twisting of wings. | ||
+ | ===Stabilizer=== | ||
+ | The horizontal stabilizer or tail is usually cone-shaped. Using a flat triangular tail like in an actual bird will result in decreased stability and control. The stab usually provides a downforce to keep the nose up, so the incidence or angle relative to the wing is much more than you would find in an airplane. Typically the angle is around 15 degrees, but may need to be adjusted depending on the bird. | ||
+ | ===Flapping Mechanism=== | ||
+ | The basis for most mechanisms is called a "four-bar linkage". There is a rotating crank shaft, driven by the motor. As the crank goes around, the connecting rods push the wings up and down. However, when the second wing is added, with this mechanism there will be asymmetric flapping. The two connecting rods leave the crank at different angles. This causes them to flap at different times. Asymmetric flapping lowers the efficiency and makes the ornithopter want to turn to one side. This problem can be remedied by using a staggered crank. The connecting rods go off at different angles, but their timing is corrected by having them placed on separate crank throws. The staggered crank is most easily constructed from bent wire. | ||
+ | ==Flight== | ||
+ | After your bird is built, it's time to fly and test it. Success will come from constant testing and adjusting. Remember to keep a flight log! Looking back on data will help you figure out which adjustment works best. | ||
+ | ===Materials=== | ||
+ | You will need a winder (5:1 ratio may work for ornithopters, but 10:1 or 15:1 ratio winders are faster), rubber for the motor, and a lubricant to allow the motor to crank more winds in. Do not use regular rubber bands for the motor (they will break easily and will not give you enough winds for a good flight). Use Tan Super Sport Rubber, or the rubber provided in your kit if you used one. A silicone based lubricant works best. Armorall works well, but avoid petroleum based lubricants such as WD-40, which will degrade rubber. Two little plastic or rubber o-rings strung onto the motor greatly help transfer the motor from winder to rear hook. | ||
+ | ===Winding=== | ||
+ | Apply the lubricant before the flight. Have one partner hold onto the motorstick gently. Attach one end of the motor to the crank hook, the back end on the winder. The partner winding should stretch the rubber back 3-6 times longer than the original motor size. When you have wound halfway the desired winds, slowly move closer while continuing to wind. This is called stretch winding and allows you to make the most of your rubber motor. Transfer the motor from the winder to the rear hook on the motorstick carefully. Hold the bird by the motorstick horizontally, and then let go. No need to thrust or throw the bird into the air. | ||
+ | ===Adjusting=== | ||
+ | Start out with just a test flight. Wind only around 250 winds at first. More winds come later, when your bird flies smoothly. | ||
+ | ====Sharp turn followed by crash==== | ||
+ | If this is the case, add weight to the wingtip on the outside of the turn. Adjust weight as needed. This may have also occurred because you have wound the motor backward. Make sure to wind clockwise. | ||
+ | ====Stalling==== | ||
+ | Stalling is when the nose of the bird points upward slowing almost to a stop and then quickly falls into a dive, losing height. This can be solved by carefully lowering the tail incidence. Errors in the strut length or the hole spacing of the connecting rods can also cause this. | ||
+ | ====Diving==== | ||
+ | Again, make sure to wind clockwise. If the bird is still nose-diving, increase the tail incidence. Errors in the strut length or the hole spacing of the connecting rods can also cause this. | ||
==Competition== | ==Competition== | ||
− | + | At the competition, use time wisely. Only 8 minutes will be allowed for two official flights. | |
===Scoring=== | ===Scoring=== | ||
+ | Score will equal the time aloft in seconds in the longest flight. Ties will be broken with the lesser flight. | ||
+ | {|class="wikitable" | ||
+ | |+ | ||
+ | !Violation | ||
+ | !Deduction | ||
+ | |- | ||
+ | |Flight Logs are Incomplete | ||
+ | |30% deduction from final score | ||
+ | |- | ||
+ | |Flight Logs are not turned in | ||
+ | |50% deduction from final score | ||
+ | |- | ||
+ | |Building Violation | ||
+ | |2nd tiered (scored below all legal devices) | ||
+ | |- | ||
+ | |} | ||
{{Stub}} | {{Stub}} |
Revision as of 16:44, 21 August 2017
Overview
Flying Bird was a trial event for both divisions at the 2011 National Tournament. The top three overall teams in this event were awarded medals. It is an aviation event in which competitors build an ornithological flying device (i. e. a device which flies by the flapping of wings; hence the name "Flying Bird"), called an "ornithopter". Due to the difficulty of this event, it is unlikely that it will become a full event in the near future.
One version of the rules from 2009/2010 can be found here.
Construction
A basic ornithopter consists of a wing, stabilizer, motor stick, a flapping mechanism, and connecting rods. Very light balsa wood and lightweight covering are needed to construct the wing and horizontal stabilizer. Mylar film and Japanese Esaki tissue are good options for covering. Flapping mechanisms are more complicated, and typically require music wire, a metal bearing tube, wooden connecting rods, and a plastic bead.
Wing
The simple "membrane" type of ornithopter wing is the most commonly used. It consists of only a balsa leading spar and a wing membrane in the shape of a half circle from lightweight covering. The membrane portion of the wing will passively lag behind the rigid wing spar. When the wing is going up, it will also tilt upward. When the wing is going down, it will angle downward. This is called the twisting of wings.
Stabilizer
The horizontal stabilizer or tail is usually cone-shaped. Using a flat triangular tail like in an actual bird will result in decreased stability and control. The stab usually provides a downforce to keep the nose up, so the incidence or angle relative to the wing is much more than you would find in an airplane. Typically the angle is around 15 degrees, but may need to be adjusted depending on the bird.
Flapping Mechanism
The basis for most mechanisms is called a "four-bar linkage". There is a rotating crank shaft, driven by the motor. As the crank goes around, the connecting rods push the wings up and down. However, when the second wing is added, with this mechanism there will be asymmetric flapping. The two connecting rods leave the crank at different angles. This causes them to flap at different times. Asymmetric flapping lowers the efficiency and makes the ornithopter want to turn to one side. This problem can be remedied by using a staggered crank. The connecting rods go off at different angles, but their timing is corrected by having them placed on separate crank throws. The staggered crank is most easily constructed from bent wire.
Flight
After your bird is built, it's time to fly and test it. Success will come from constant testing and adjusting. Remember to keep a flight log! Looking back on data will help you figure out which adjustment works best.
Materials
You will need a winder (5:1 ratio may work for ornithopters, but 10:1 or 15:1 ratio winders are faster), rubber for the motor, and a lubricant to allow the motor to crank more winds in. Do not use regular rubber bands for the motor (they will break easily and will not give you enough winds for a good flight). Use Tan Super Sport Rubber, or the rubber provided in your kit if you used one. A silicone based lubricant works best. Armorall works well, but avoid petroleum based lubricants such as WD-40, which will degrade rubber. Two little plastic or rubber o-rings strung onto the motor greatly help transfer the motor from winder to rear hook.
Winding
Apply the lubricant before the flight. Have one partner hold onto the motorstick gently. Attach one end of the motor to the crank hook, the back end on the winder. The partner winding should stretch the rubber back 3-6 times longer than the original motor size. When you have wound halfway the desired winds, slowly move closer while continuing to wind. This is called stretch winding and allows you to make the most of your rubber motor. Transfer the motor from the winder to the rear hook on the motorstick carefully. Hold the bird by the motorstick horizontally, and then let go. No need to thrust or throw the bird into the air.
Adjusting
Start out with just a test flight. Wind only around 250 winds at first. More winds come later, when your bird flies smoothly.
Sharp turn followed by crash
If this is the case, add weight to the wingtip on the outside of the turn. Adjust weight as needed. This may have also occurred because you have wound the motor backward. Make sure to wind clockwise.
Stalling
Stalling is when the nose of the bird points upward slowing almost to a stop and then quickly falls into a dive, losing height. This can be solved by carefully lowering the tail incidence. Errors in the strut length or the hole spacing of the connecting rods can also cause this.
Diving
Again, make sure to wind clockwise. If the bird is still nose-diving, increase the tail incidence. Errors in the strut length or the hole spacing of the connecting rods can also cause this.
Competition
At the competition, use time wisely. Only 8 minutes will be allowed for two official flights.
Scoring
Score will equal the time aloft in seconds in the longest flight. Ties will be broken with the lesser flight.
Violation | Deduction |
---|---|
Flight Logs are Incomplete | 30% deduction from final score |
Flight Logs are not turned in | 50% deduction from final score |
Building Violation | 2nd tiered (scored below all legal devices) |
- This page is a stub. You can help the Science Olympiad Student Center by expanding it.
Division B: Flying Bird · MagLev · Wright Stuff Capacitor | Division C: Flying Bird · Materials Science · Robot Arm |