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In a classic carnival ride, patrons stand against the wall in a cylindrically shaped room. Once the room gets spinning fast enough, the floor drops from the bottom ofthe room! Friction between the walls of the room and the people on the ride make them the “stick” to the wall so they do not slide down. In one ride, the radius of thecylindrical room is R = 6 m and the room spins with a frequency of 23.2 revolutions per...
I need the answers for 5 and 6 parts In a classic carnival ride, patrons stand against the wall in a cylindrically shaped room. Once the room gets spinning fast enough, the floor drops from the bottom of the room! Friction between the walls of the room and the people on the ride make them the "stick" to the wall so they do not slide down. In one ride, the radius of the cylindrical room is R = 6.1 m...
In a classic carnival ride, patrons stand against the wall in a cylindrically shaped room. Once the room gets spinning fast enough, the floor drops from the bottom of the room! Friction between the walls of the room and the people on the ride make them the "stick" to the wall so they do not slide down. In one ride, the radius of the cylindrical room is R = 6.4 m and the room spins with a frequency of 21.8...
In a classic carnival ride, patrons stand against the wall in a cylindrically shaped room. Once the room gets spinning fast enough, the floor drops from the bottom of the room! Friction between the walls of the room and the people on the ride make them the "stick" to the wall so they do not slide down. In one ride, the radius of the cylindrical room is R 6m and the room spins with a frequency of 23.2 revolutions per...
In a classic carnival ride, patrons stand against the wall in a cylindrically shaped room. Once the room gets spinning fast enough, the floor drops from the bottom ofthe room! Friction between the walls of the room and the people on the ride make them the “stick” to the wall so they do not slide down. In one ride, the radius of thecylindrical room is R = 6.8 m and the room spins with a frequency of 22.4 revolutions per...
Concept 8A/B: This fall, my husband, kids and I were visiting our home town during Pacelli Panacea (a popular carnival-type event). At Panacea, and many amusement parks, there is a popular ride where the floor of a rotating cylindrical room falls away, leaving the backs of the riders ‘plastered’ against the wall. Suppose the radius of the room is 3.30m and the speed of the wall is 10.0 m/s when the floor falls away.a. Concept 8A: What is the source...
“The Rotor” is a fun carnival ride. It’s made of a large hollow cylinder of radius R, that’s rotated rapidly about the center axis. A rider stands with her back against the inner wall. At a certain speed, the floor drops, but the rider does not fall. 9) The Rotor" is a fun carnival ride. It's made of a large hollow cylinder of radius R, that's rotated rapidly about the center axis. A rider stands with her back against the...
A camival ride is designed to allow the general public to experience high acceleration motion. The ride rotates about Point Oin a horizontal circle such that the rider has a spoed vo. The rider recines on a platform A which rides on rolers such that friction is negligible. A mechanical stop prevents the platform from rolling down the incine. The carnival ride is modified so that 80 kg riders can move up and down the inclined wall as the speed...
Please write out answers up to 4 significant figures. Please be thorough as the more steps the better i can understand. Also, can you please check my force diagram for completeness and correctness? I have n for normal force, mg as downward force of mass times gravity (should i have written just g?), and Centripetal force (not sure if this is a true force). 2) A graviton ride at the fair consists of a 10 m diameter cylindrical drum that...
3. Rotor (6 points) The Rotor is an amusement park ride consisting of a large, vertical cylinder with radius R- 2.5 m. A rider stands on the inside wall, and the cylinder begins rotating. When the angular velocity is high enough, the floor is lowered but, due to static friction, the rider does not slide down the wall. Suppose the Rotor is spinning with an angular velocity of 4 rad/s. (a) (2 points) How much time does it take for...