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An ideal spring hangs from the ceiling. A 1.45 kg mass is hung from the spring,...
An ideal spring hangs from the ceiling. A 1.45 kg mass is hung from the spring,...
An ideal spring hangs from the ceiling. A 1.45 kg mass is hung from the spring, stretching the spring a distance d = 0.0865 m from its original length when it reaches equilibrium. The mass is then lifted up a distance L = 0.0275 m from the equilibrium position and released. What is the kinetic energy of the mass at the instant it passes back through the equilibrium position?
An ideal spring hangs from the ceiling. A 1.25 kg mass is hung from the spring,...
An ideal spring hangs from the ceiling. A 1.25 kg mass is hung from the spring, stretching the spring a distance d = 0.0865 m from its original length when it reaches equilibrium. The mass is then lifted up a distance L = 0.0285 m from the equilibrium position and released. What is the kinetic energy of the mass at the instant it passes back through the equilibrium position?
An ideal spring hangs from the ceiling. A 1.85 kg mass is hung from the spring,...
An ideal spring hangs from the ceiling. A 1.85 kg mass is hung from the spring, stretching the spring a distance d = 0.0905 m from its original length when it reaches equilibrium. The mass is then lifted up a distance 0.0265 m from the equilibrium position and released. What is the kinetic energy of the mass at the instant it passes back through the equilibrium position? d kinetic energy J Equilibrium position
An ideal spring hangs from the ceiling. A 2.15 kg mass is hung from the spring, stretching the sp...
An ideal spring hangs from the ceiling. A 2.15 kg mass is hung from the spring, stretching the spring a distance d = 0.0865 m from its original length when it reaches equilibrium. The mass is then lifted up a distance L = 0.0235 m from the equilibrium position and released. What is the kinetic energy of the mass at the instant it passes back through the equilibrium position?
Problem 6. A mass of 1.00 kg is hung from the ceiling by an ideal spring....
Problem 6. A mass of 1.00 kg is hung from the ceiling by an ideal spring. When a mass of 0.500 kg is added to the original mass, the spring stretches by an additional 0.933 cm. (a) What is the force constant of the spring? (b) By how much did the spring stretch when only the 1.00kg mass was hung from it? The system (with the 1.50kg mass) is now set in oscillation with an amplitude of 2.20cm. (c) What...
A spring with spring constant k and equilibrium length rho degree hangs from the ceiling. A...
A spring with spring constant k and equilibrium length rho degree hangs from the ceiling. A block of mass m is attached to the spring and released from rest at a distance of rho degree from the ceiling (i.e. the equilibrium length of the spring), as shown in figure on right. The block then undergoes simple harmonic motion. Sketch the vertical position of the block as a function of time, including three full oscillation periods. hat is the maximum sped...
A spring of equilibrium length L1 and spring constant k1 hangs from the ceiling. Mass m1...
A spring of equilibrium length L1 and spring constant k1 hangs from the ceiling. Mass m1 is suspended from its lower end. Then a second spring, with equilibrium length L2 and spring constant k2, is hung from the bottom of m1. Mass m2 is suspended from this second spring. How far is m2 below ceiling?
An ideal spring dangles from the ceiling at its relaxed length of 5 cm. A 3-kg...
An ideal spring dangles from the ceiling at its relaxed length of 5 cm. A 3-kg mass is carefully hung from the end of the spring while the spring is relaxed, and then the mass is released from rest at time t = 0, which begins to stretch the spring. The spring stretches to its maximum length at time t = 130 ms when the mass reaches its lowest point. Then the mass returns upward, shortening the spring. The oscillation...
A 1.10 kg mass hangs from a spring of force constant 400 N/m . The mass...
A 1.10 kg mass hangs from a spring of force constant 400 N/m . The mass is then pulled down 13.0 cm from the equilibrium position and released. At the end of five complete cycles of vibration, the mass reaches only 10.0 cm from the equilibrium position. Part A: How much mechanical energy is lost during these five cycles? Part B: What percentage of the mechanical energy is lost during the five cycles?
1) A0.4-kg mass is attached to a spring that can compress as well as stretch. The...
1) A0.4-kg mass is attached to a spring that can compress as well as stretch. The mass and spring are resting on a horizontal tabletop. The spring constant is 50 N/m. The mass is pulled, stretching the spring 48 cm. The mass is then released, and the spring-mass system begins to oscillate. a) Construct a complete energy system diagram to predict the speed of the mass as it passes a point that is a distance of 39 cm from its...
An ideal spring hangs from the ceiling. A 1.85 kg mass is hung from the spring, stretching the spring a distance d = 0.0905 m from its original length when it reaches equilibrium. The mass is then lifted up a distance 0.0265 m from the equilibrium position and released. What is the kinetic energy of the mass at the instant it passes back through the equilibrium position? d kinetic energy J Equilibrium position
Problem 6. A mass of 1.00 kg is hung from the ceiling by an ideal spring. When a mass of 0.500 kg is added to the original mass, the spring stretches by an additional 0.933 cm. (a) What is the force constant of the spring? (b) By how much did the spring stretch when only the 1.00kg mass was hung from it? The system (with the 1.50kg mass) is now set in oscillation with an amplitude of 2.20cm. (c) What...
A spring with spring constant k and equilibrium length rho degree hangs from the ceiling. A block of mass m is attached to the spring and released from rest at a distance of rho degree from the ceiling (i.e. the equilibrium length of the spring), as shown in figure on right. The block then undergoes simple harmonic motion. Sketch the vertical position of the block as a function of time, including three full oscillation periods. hat is the maximum sped...
1) A0.4-kg mass is attached to a spring that can compress as well as stretch. The mass and spring are resting on a horizontal tabletop. The spring constant is 50 N/m. The mass is pulled, stretching the spring 48 cm. The mass is then released, and the spring-mass system begins to oscillate. a) Construct a complete energy system diagram to predict the speed of the mass as it passes a point that is a distance of 39 cm from its...
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