Please show all of your work. A 3.5-kg piece of putty is dropped 1.9 m onto...
A 2.8-kg piece of putty is dropped 2.2 m onto the initially stationary block, which is supported by four springs, each of which has a constant k = 800 N/m. Determine the displacement x as a function of time during the resulting vibration, where x is measured from the initial position of the block as shown. Once you have the general solution answer the questions. 2.8 kg 2.2 m 25 kg WVW
xample: The 2-kg piece of putty (m) is dropped 2 m onto the 18-kg block (M) initially at rest on the two springs, each with a stiffness k=1.2 kN/m . Calculate the additional deflection ? due to the impact of the putty which adheres to the block upon contact 2m
Problem 2 - Particle Kinetics (10 pts) The 2 kg piece of putty is dropped 6 m onto the 18 kg block initially at rest on the two springs, each with a stiffness k = 500 N/m. Calculate the deflection d of the springs due to the impact of the putty, which adheres to the block upon contact. 2 kg 6 m 18 kg 8 k = 500 N/m
A 3.5 kg block is attached to a spring with stiffness of 500 N/m. While at rest in the equilibrium position, the block is given suddenly given an initial velocity of 0.5 m/s. Assume the displacement as a function of time is given by x(t) = A1cos(w0t) + A2sin(w0t). Solve for A1, A2, w0 , and compute the total energy of system.
Please show all work. Thanks inn rim 0 x=A Consider the spring-mass system above. A block of mass 4.00 kg is attached to the end of a spring with a force constant of k = 600 N/m. The spring is stretched to a position of x A, and then released to oscillate over a frictionless surface. The maximum speed achieved by the block is 3.00 m/s 2. a. What is the maximum displacement A of the spring from equilibrium (the...
A spring stretches 0.150 m when a 0.300 kg. mass is hung vertically from it. From this information you can determine the spring constant, k. Next, the spring is set up horizontally with the 0.300 kg. mass resting on a frictionless table. The block is pushed so that the spring is compressed 0.100 m from the equilibrium point, and released from rest. Determine: The spring constant k (in N/m)? The amplitude of the horizontal oscillation (in m)? The angular frequency,...
7.7. Please answer all the questions and show your work. A 4.20-kg block is set into motion up an inclined plane with an initial speed of v_1 = 7.60 m/s (see figure below). The block comes to rest after traveling d = 3.00 m along the plane, which is inclined at an angle of theta = 30.0 degree to the horizontal. For this motion, determine the change in the block's kinetic energy. J For this motion, determine the change in...
A block of mass m = 3.5 kg is on an inclined plane with a coefficient of friction μ1 = 0.31, at an initial height h = 0.53 m above the ground. The plane is inclined at an angle θ = 54°. The block is then compressed against a spring a distance Δx = 0.11 m from its equilibrium point (the spring has a spring constant of k1 = 39 N/m) and released. At the bottom of the inclined plane...
PLEASE SHOW ALL WORK. THANKS. III, SIMPLE HARMONIC HECK (30 pts: 10 pts each piece), The statements immediately to follow (even when long and complicated) are considered in this context) GIVEN You may assume and rely on them for the problem/proof to follow a bit further down. Note: In some cases, "GIVEN' might mean 'self-evident' or 'obvious', but in other cases, it might not. GIVEN might not mean "obvious"; it can simply mean 'somehow established prior to this discussion'. GIVEN...
please show all work. need help with question c,d,e Name Problem 3 A standing wave is setup c 1 a string at the third harmonic (n-3), as seen in the figure. The length of the s ring is 0.350 m, the tension in the string is 2.44 N and the mass per unit lengtl is 0.100 kg/m. (5 Points)/ a) What is the wavelength a ad frequency fof the standing wave? 5 points)b) If the amplitude of the v ave...