8.67 Blocks A (mass 6.00 kg) and B (mass 14.00 kg, to the right of A)...
Blocks A (mass 3.50 kg ) and B (mass 7.00 kg ) move on a frictionless, horizontal surface. Initially, block B is at rest and block A is moving toward it at 5.00 m/s . The blocks are equipped with ideal spring bumpers. The collision is head-on, so all motion before and after the collision is along a straight line. Let +x be the direction of the initial motion of block A. Part A Find the maximum energy stored in...
Blocks A (mass 3.00 kg ) and B (mass8.00 kg ) move on a frictionless, horizontal surface. Initially, block B is at rest and block A is moving toward it at 3.00 m/s . The blocks are equipped with ideal spring bumpers. The collision is head-on, so all motion before and after the collision is along a straight line. Let +x be the direction of the initial motion of block A. A. Find the maximum energy stored in the spring...
Blocks A (mass 4.50 kg) and B (mass 15.00 kg) move on a frictionless, horizontal surface. Initially, block B is at rest and block A is moving toward it at 1.00 m/s.The blocks are equipped with ideal spring bumpers. The collision is head-on, so all motion before and after the collision is along a straight line. Let +x be thedirection of the initial motion of AFind the maximum energy stored in the spring bumpers and the velocity of each block...
Blocks A (mass 5.00 kg ) and B (mass 14.50 kg ) move on a frictionless, horizontal surface. Initially, block B is at rest and block A is moving toward it at 9.00 m/s . The blocks are equipped with ideal spring bumpers. The collision is head-on, so all motion before and after the collision is along a straight line. Let +x be the direction of the initial motion ofA. Part A Find the maximum energy stored in the spring...
A block of mass m1 = 1.0 kg initially moving to the right with a speed of 3.2 m/s on a frictionless, horizontal track collides with a spring attached to a second block of mass m2 = 3.4 kg initially moving to the left with a speed of 2.6 m/s as shown in figure (a). The spring constant is 530N/m. (A) Find the velocities of the two blocks after the collision. (B) During the collision, at the instant block 1...
A Two-Body Collision with a Spring A block of mass m,-1.9 kg initially moving to the right with a speed of 3.2 m/s on a frictionless, horizontal track collides with a spring attached to a second block of mass m2 - 3.9 kg initially moving to the left with a speed of 1.8 m/s as shown in figure (a). The spring constant is 505 N/m in A moving block collides with another moving block with a spring attached: (a) before...
Sphere A, of mass 0.600 kg, is initially moving to the right at 4.00 m/s. Sphere B, of mass 1.80 kg, is initially to the right of sphere A and moving to the right at 2.00 m/s. After the two spheres collide, sphere B is moving at 3.00 m/s in the same direction as before. (a) What is the velocity (magnitude and direction) of sphere A after this collision? (b) Is this collision elastic or inelastic? (c) Sphere B then...
Question 12 In the figure, block 2 of mass 2.20 kg oscillates on the end of a spring in SHM with a period of 14.00 ms. The position of the block is given by x = (1.40 cm) cos(wt + x/2). Block 1 of mass 4.40 kg slides toward block 2 with a velocity of magnitude 8.40 m/s, directed along the spring's length. The two blocks undergo a completely inelastic collision at time t = 3.50 ms. (The duration of...
A block of mass m_1 = 1.80 kg moving at v_1 = 2.00 m/s undergoes a completely inelastic collision with a stationary block of mass m_2 = 0.300 kg. The blocks then move, stuck together, at speed v_2. After a short time, the two-block system collides inelastically with a third block, of mass m_3 = 2.20 kg, which is initially at rest. The three blocks then move, stuck together, with speed v_3. (Figure 1) Assume that the blocks slide without...
From University Physics, 5th edition. Please help clarify this problem, and show work if you can! :) (18 points) A 2.00 kg block is moving mass 3.00 kg is moving to the left a 2.00 kg block is moving to the right with a speed of 1.50 m/s and a second block of U kg is moving to the left and towards the other block at a speed of 1.75 m/s. An ideal Spring is attached to the front of...