TUUUURJE Question 1 4 points The 3 kg block is subjected to a force F 153...
Question 2 of 3 Question 2 3 points Save An The steel ingot has a mass of 2,148 kg. It travels along the conveyor at a speed of 3 m/s when it collides with the "nested spring assembly. Detemine the maximum defiection in spring "A needed to stop the motion of the ingot. Take kA 66 kN/m, kg 1.3 kNm Question 2 of 3 Question 2 3 points Save An The steel ingot has a mass of 2,148 kg. It...
Question 4 The steel ingot has a mass of 1800 kg. It travels along the conveyor at a speed of 0.5 m/sec when it collides with the "nested" spring assembly. Determine the maximum deflection in spring "A" needed to stop the motion of the ingot. Take kA 5 kN/m, kB- 3 kN/m 0.5 m 0.45 m kp KA 0 0.050 m 0.255 m 0.455 m 0.655 m
Review The steel ingot has a mass of 2000 kg . It travels along the conveyor at a speed 0.6 m/s when it collides with the "nested" spring assembly. (Figure 1) Part A Figure ② 1 of 1 If the stiffness of the outer spring is ka = 5 kN/m, determine the required stiffness kb of the inner spring so that the motion of the ingot is stopped at the moment the front, C, of the ingot is 0.3 m...
draw datum and free body diagram please ! The steel ingot has a mass of 1800 kg. It travels along the conveyor at a speed v = 0.5 m/s when it collides with the "rested" spring assembly. Determine the maximum deflection in each spring needed to stop the motion of the ingot. Take ka = 5 kN/m, kb = 3 kN/m. 0.5 m -0.45 m kg kA с B
Block A (0.40 kg) and block B (0.5 kg) are on a frictionless table (see figure). Spring 1 connects block A to a frictionless peg at O and spring 2 connects block A and block B. When the blocks are in uniform circular motion about 0, the springs have lengths of 0.60 m and 0.40 m, as shown. The springs are ideal and massless, and the linear speed of block B is 2.0 m/s. If the distance that spring 2...
005 (part 1 of 4) 10.0 points A block of mass 49 kg slides along a friction- front of it, and moving in the opposite direc- tion with a speed of 13 m/s, is a block of mass 65 kg. A massless spring with spring constant 1566 N/m is attached to the second block as in the figure. 42 m/s 13 m/s 1566 N/m 49 kg 65 kg Before the 49 kg block makes contact with the spring, what is...
A 2.5-kg, frictionless block is attached to an ideal spring with force constant 315N/m is undergoing simple harmonic motion. When the block has displacement 0.27 m, it is moving in the negative x-direction with a speed 4 m/s part a: find the amplitude of the motion ? (........m) part b: find the magnitude of the maximum force the spring exerts on the block? (..........N)
Problem 10. (20 pts) The displacement of a block of mass 0.2 kg on a spring is given by x(t) = (0.25 m) cos((2/s)t + π/5) A) What are the angular frequency (in rad/s), frequency (in Hz), and period of this motion? B) Find the spring stiffness of the spring. C) Find the x-component of the velocity of the block as a function of time. D) Find the total energy of the block/spring system E) Find the maximum speed of...
A spring of spring constant k=261 N/m is attached to a block of mass 1.38 kg and stretched horizontally to a position 15.0 cm from the springs equilibrium position. The spring and mass are released and oscillate in simple harmonic motion across a frictionless horizontal surface. What is the maximum speed obtained by the mass? m/s
A block of mass 1.20 kg is attached to a horizontal spring that has force constant k = 300 N/m. The block moves on a horizontal frictionless surface. The maximum speed of the block during its motion is 5 m/s. What is the amplitude A of the simple harmonic motion of the block?