Team Mertz's Ball Drop
Team Mertz approached the problem of the ball drop from a completely different direction than the other teams; they built a cabled "descender", which would use a rope and frictional forces to slow their ball's descent instead of air resistance.
The group members were:
Some of the ideas that came up during the brainstorming session were seemingly complicated and uncreative. Such as the parachute, the kite, and the glider.
With avoidance of a parachute-based design in mind, Team Mertz began considering friction-based descenders. These ideas largely centered around the use of the electrical tape as a cable which the tennis ball would "ride" to the ground; a number of ideas were proposed for how to slow the ball's descent, including wrapping the ball in the tape cord, applying friction to the cable with the lid and body of the tape container, and building a "counterweight"-based system.
After a prototype of the "counterweight" descender was demonstrated to work, the design was selected. The basic premise of the design was that forcing the ball to change direction in order to descend would slow its descent.
Final Design & Construction
First, Team Mertz punctured the tennis ball and drove two dowels through, in such a way that they made an “X.” Then, they folded almost the whole length of the tape across the middle of the sticky side, producing roughly thirty feet of non-sticky tape. They then wrapped the tape in a figure of 8 around the two longest protruding legs of the “X.” Finally, they attached the end of the tape to the third dowel, so that they could use the dowel to hold the device as far from the building as possible when it was falling.
Team Mertz's descender achieved a time of 15.44 ± 0.2 seconds. Pretty sweet, eh?
(Side note: They also ran one test from the roof of Hicks in which they achieved a time of 55 SECONDS. Again, pretty sweet, eh?)
When we wrapped the tape around the dowels, we used a single wrap because we were concerned about snags. In hindsight, we could have used a double wrap to make our apparatus descend even slower.
Our ingenious design seemed to have irritated many of our competitors. A number of them have somehow gotten the idea that our project had broken some design rules. To quote the rules: "Use the material provided to design an apparatus to maximize the length of time the tennis ball will stay in the air when it is released from rest from the roof of Hicks (the ball must fall, you can't simply tape it to the building). The time must be less than 1 minute. No chemical reactions (i.e. fire) can be used." First of all, we clearly did not employ any chemical reactions. Second, our project descended well within the 1 minute time limit. Finally, we released the tennis ball allowing it to fall to the ground from the third floor window. Our project abided by all of the design rules.