A 0.3 kg mass is attached to a spring with a force constant of 1500 N/m. The mass is pulled to a distance Xmax, and released. If the total mechanical energy of the mass at t = 30 s is 188J, what is Xmax ?
A) 5.0 m B) 0.5 m C) 1.0 m D) 0.05 m E) 15.0 m
A 0.3 kg mass is attached to a spring with a force constant of 1500 N/m....
A block of mass m = 1.07 kg is attached to a spring with force constant 134.0 N/m. The block is free to move on a frictionless, horizontal surface as shown in the figure. The block is released from rest after the spring is stretched a distance A = 0.15 m to the right. What is the potential energy of the spring/block system 0.28 s after releasing the block?
A block of mass m = 1.23 kg is attached to a spring with force constant 157.0 N/m. The block is free to move on a frictionless, horizontal surface as shown in the figure. The block is released from rest after the spring is stretched a distance A = 0.11 m to the right. What is the potential energy of the spring/block system 0.28 s after releasing the block?
A block of mass m = 0.57 kg is attached to a spring with force constant 144.0 N/m. The block is free to move on a frictionless, horizontal surface as shown in the figure. The block is released from rest after the spring is stretched a distance A = 0.16 m to the right. What is the potential energy of the spring/block system 0.20 s after releasing the block? J
A block with mass 5.0 kg is attached to a horizontal spring with spring constant 300.0 N/m. If the block is initially pulled out a distance (x) cm and then released, and its velocity when it first reaches the equilibrium point is 0.51 m/s, find x.
a 0.675 kg mass is attached to a spring of spring constant
42.4 n/m, pulled, and released. what is the frequency of the
resulting oscillation
A 0.675 kg mass is attached to a spring of spring constant 42.4 N/m, pulled, and released. What is the frequency of the resulting oscillation? (Unit = Hz) Enter 2000 Acelas Corporation. All Rights Reserved ONHOQE
A 0.403 kg mass is attached to a spring with a force constant of 25.4 N/m and released from rest a distance of 3.20 cm from the equilibrium position of the spring. Calculate the speed of the mass when it is halfway to the equilibrium position.
A 0.40-kg mass is attached to a spring with
a force constant of k = 207 N/m, and the mass–spring
system is set into oscillation with an amplitude of A =
2.0 cm. Determine the following.
(a) mechanical energy of the system
_____ J
(b) maximum speed of the oscillating mass
_____ m/s
(c) magnitude of the maximum acceleration of the oscillating
mass
_____ m/s2
A 0.40-kg mass is attached to a spring with a force constant of k =...
The force of constant of a spring of spring pendulum is 50N/m. A block of mass 0.5 kg, attached to it is pulled through a distance of 0.01 m before being released. Calculate the following expressions: a) the time period and frequency b) velocity amplitude and acceleration amplitude; c) the time required by the block to move half-way towards the center from its initial position d) total energy of the system.
attached to a spring with a force constant of 1000 N/m the speed of the block 2. Figure 2 depicts a 1.6-kg frictionless mass Initially, the weight of the mass extends the spring by Ax-this is the system's The spring is then pulled an additional distance x' and released. Calculate as it passes back through the equilibrium position. equ librium of Hint: Apply Newton's Law to the mass in its equilibri energy to the mass in (2c) Ax 2a 2b...
A 2.0-kg mass is attached to a spring with a force constant of 98 N/m. The mass is resting on a frictionless horizontal plane in a similar situation as in Fig. 1. As a horizontal force of 9.8 N is applied to the mass, and it is then released, the amplitude (A) and time period (T) of the SHM generated would be O 0.01 m, 9s O 0.01 cm, 90s O 0.1 m, 0.9 s O 0.1 m, 0.09 s