In the figure here, a cylinder having a mass of 3.7 kg can
rotate about its central axis through point O. Forces are applied
as shown: F1 = 8.4 N, F2 = 6.4 N, F3 = 6.6 N, and F4 = 5.6 N. Also,
r = 7.9 cm and R = 18 cm. Ta?king the clockwise direction to be
negative, find the angular acceleration of the cylinder. (During
the rotation, the forces maintain their same angles relative to the
cylinder.)
In the figure here, a cylinder having a mass of 3.7 kg can rotate about its...
Question 8 In the figure here, a cylinder having a mass of 1.8 kg can rotate about its central axis through point o. Forces are applied as shown: F1 - 4.7 N, F2 = 3.3 N, F3 = 5.0 N, and F4 = 3.4 N. Also, r = 3.1 cm and R = 17 cm. Taking the clockwise direction to be negative, find the angular acceleration of the cylinder. (During the rotation, the forces maintain their same angles relative to...
In the figure below a cylinder having a mass of 3.0 kg can rotate about its central axis through point O. Forces are applied as shown: 1 = 3.0 N, 2 = 2.0 N, 3 = 1.0 N, and 4 = 2.0 N. Also, r = 5.0 cm and R = 12 cm. Find the magnitude and direction of the angular acceleration of the cylinder. (During the rotation, the forces maintain their same angles relative to the cylinder.) magnitude ___...
The wide A 2 kg solid cylinder can rotate about its central axis through point O. Forces are applied as shown: F1 = 6 N, F2 = 4 N, F3 = 10 N and FA = 20 N. The positions at which the forces are applied are Ri = 6 cm and R2 = 12 cm. During the rotation, all forces maintain their same angles relative to the cylinder. Find the angular acceleration (magnitude and direction) of the cylinder. Rotation...
A 2 kg solid cylinder can rotate about its central axis through point applied as shown: F1 = 6 N, F2 = 4N, F3 = 10 N and F4 = 20 N. The positio torces are applied are R = 6 cm and R2 = 12 cm. During the rotation, all forces same angles relative to the cylinder. Find the angular acceleration (magnitude and direction) of the cylinder.
The 27.3-cm-diameter disk can rotate on an axle through its center. What is the net torque about the axle? (a=4.5 cm, q=41°, F1=25 N, F2=59 N, F3=30 N, F4=33 N.)
Rotation Dynamics A uniform disk can rotate around its center like a merry-go-round. The disk has a radius of 2.00 cm and a mass of 20.0 grams and is initially at rest. The angular acceleration is 200 rad/s2counterclockwise. If F1 has a magnitude of 0.100 N, what is the magnitude of F2? 9. Fo
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5. An oscillator consists of a block attached to a spring (k = 318 N/m). At some time t, the position (measured from the system's equilibrium location), velocity, and acceleration of the block are x = 0.129 m, v = -18.2 m/s, and a = -136 m/s. Calculate the mass of the block. (a) 0.252 kg (b) 0.272 kg (c) 0.292 kg (d) 0.302 kg (e) None of the above 6. In the figure here, a cylinder having...
A constant-density cylinder of mass 0.5 kg and radius 4 cm can rotate freely about an axis through its center. It has thread wound around an attached axle of radius 0.5 cm that also runs through its center (Fig. as shown) The thread is attached to a mass of 1 kg, which slides down an inclined plane of angle ф-300 with an acceleration of 0.1 m/s. a) Draw a free body diagram of the system by PROBLEM 4: (12pts) R....
A uniform disk with mass m = 8.55 kg and radius R = 1.35 m lies in the xy plane and centered at the origin. Three forces act on the disk in the +y-direction (see figure below): (1) a force F1 = 335 N at the edge of the disk on the +x-axis, (2) a force F2 = 335 N at the edge of the disk on the ?y-axis, and (3) a force F3 = 335 N at the edge...
The figure shows a uniform disk that can rotate around its center like a merry-go-round. The disk has a radius of 2.0 cm and a mass of 18 grams and is initially at rest. Starting at time t = 0, two forces are to be applied tangentially to the rim as indicated, so that at time t = 1.2 s the disk has an angular velocity of 300 rad/s counterclockwise. Force F1 has a magnitude of 0.101 N. What is...