(Sorry if this is in the wrong spot.)
The question asks: "If a person starts at the rim of a spinning platform and is pushed radially toward the central axis by a moving exterior wall, then what happens to the normal force felt by that person due to the wall?"
Answer reads: "It decreases, since r decreases."
I understand that the centripetal acceleration decreases as r decreases because centripetal acceleration=w^2 x r, but how is it that a decrease in centripetal force causes a decrease in the normal force if both point in the same direction?
If centripetal acceleration, centripetal force, and normal force are all pointing inward then wouldn't the sum of all forces = ma = Fc + Fn; which would mean that Fn = ma-Fc and thus a decrease in Fc would increase Fn? Fc = ac x mass so a decrease in ac means a decrease in Fc which, according to the above calculation, would increase Fn if ma stays constant (in the answer discription is states that the platform spins at a constant speed).
Conceptually, if the centripetal force decreases, and there's less inward force acting on the object, then more force is placed on the wall--which translates to an increase in the normal force (assuming the wall doesn't move backwards). The normal force would have to 'pick up' what the centripetal force lost because they both act in the same direction.
What am I doing wrong?
The question asks: "If a person starts at the rim of a spinning platform and is pushed radially toward the central axis by a moving exterior wall, then what happens to the normal force felt by that person due to the wall?"
Answer reads: "It decreases, since r decreases."
I understand that the centripetal acceleration decreases as r decreases because centripetal acceleration=w^2 x r, but how is it that a decrease in centripetal force causes a decrease in the normal force if both point in the same direction?
If centripetal acceleration, centripetal force, and normal force are all pointing inward then wouldn't the sum of all forces = ma = Fc + Fn; which would mean that Fn = ma-Fc and thus a decrease in Fc would increase Fn? Fc = ac x mass so a decrease in ac means a decrease in Fc which, according to the above calculation, would increase Fn if ma stays constant (in the answer discription is states that the platform spins at a constant speed).
Conceptually, if the centripetal force decreases, and there's less inward force acting on the object, then more force is placed on the wall--which translates to an increase in the normal force (assuming the wall doesn't move backwards). The normal force would have to 'pick up' what the centripetal force lost because they both act in the same direction.
What am I doing wrong?
