Please do not copy and paste answers from elsewhere on the internet. I will rate
ID: 1393852 • Letter: P
Question
Please do not copy and paste answers from elsewhere on the internet. I will rate the answer badly if you do.
A mass m constrained to move on a frictionless horizontal surface is attached to a frictionless peg by an ideal, massless spring with spring constant k. The unstretched length of the spring is L_1, as shown in Figure 1. When the mass moves in a circle about the peg with constant angular velocity w, the length of the spring is L_2 as shown in Figure 2. Express your answers in terms of some or all of the quantities m, k, w and L_1, and any necessary constants.
Assume the total energy of the system in Figure 1 is zero. Determine the total energy of the rotating system in Figure 2.
Explanation / Answer
When moving in circle,
the centripetal force necessary to move in circle must be provided by the spring force
Now, spring force, Fs = k*x
where x = extension of spring = L2 - L1
So, Fs = k*(L2 - L1)
Now, centripetal force, Fc = m*W^2*R
where R = radius of circle = L2
So, Fc = m*W^2*L2
For circular motion, Fc = Fs
So, m*W^2*L2 = k*(L2 - L1) ----------- (1)
So, m*W^2/k = (L2-L1)/L2 = 1 - L1/L2
So, L1/L2 = 1 - mW^2/k
So, L2 = L1/(1 - mW^2/k) = k*L1/(k - mW^2) <----------answer
b)
Total energy = Spring Potential energy + Kinetic energy of mass = Up + KE
Up = 0.5*k*x^2 = 0.5*k*(L2-L1)^2
KE = 0.5*m*W^2*R^2 = 0.5*m*W^2*(L2)^2
So, TE = 0.5*k*(L2-L1)^2 + 0.5*m*W^2*(L2)^2 <------------answer
You can plug in the value of L2 in terms of L1 to simplify more if you want. But you havent asked about it so have left it...