4. A uniform disc of mass m = 3 kg and radius R=0.5 may roll without slip on the 30 degree incline shown. An elastic spring of stiffness k = 100 newtons/meter is connected to the center C of the disc. Initially, the disc is held in place in the position shown, with the spring neither stretched nor compressed and with the disc at rest. At t = 0 the disc is released and is subjected to a constant force of Fo= 30 newtons along the incline. Determine the maximum speed achieved by the disc center C as the disc moves up the incline. For gravity use g = 10 m/sec². (note: initially the constant force Fo will be greater than the forces exerted by the spring and by gravity, and the disc will accelerate up the incline; but there will come a distance x along the incline after which the spring force + gravity will overtake the force Fo, and the disc will then decelerate). gravity → P=30 N no friction

Elements Of Electromagnetics
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Author:Sadiku, Matthew N. O.
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4. A uniform disc of mass m = 3 kg and radius R= 0.5
may roll without slip on the 30 degree incline shown.
An elastic spring of stiffness k= 100 newtons/meter is
connected to the center C of the disc. Initially, the disc
is held in place in the position shown, with the spring
neither stretched nor compressed and with the disc at
rest. At t = 0 the disc is released and is subjected to a
constant force of Fo = 30 newtons along the incline.
Determine the maximum speed achieved by the disc
center C as the disc moves up the incline. For gravity
use g = 10 m/sec². (note: initially the constant force Fo
will be greater than the forces exerted by the spring and
by gravity, and the disc will accelerate up the incline;
but there will come a distance x along the incline after
which the spring force + gravity will overtake the force
Fo, and the disc will then decelerate).
gravity
Fo= 30 N
30°
no friction
Transcribed Image Text:4. A uniform disc of mass m = 3 kg and radius R= 0.5 may roll without slip on the 30 degree incline shown. An elastic spring of stiffness k= 100 newtons/meter is connected to the center C of the disc. Initially, the disc is held in place in the position shown, with the spring neither stretched nor compressed and with the disc at rest. At t = 0 the disc is released and is subjected to a constant force of Fo = 30 newtons along the incline. Determine the maximum speed achieved by the disc center C as the disc moves up the incline. For gravity use g = 10 m/sec². (note: initially the constant force Fo will be greater than the forces exerted by the spring and by gravity, and the disc will accelerate up the incline; but there will come a distance x along the incline after which the spring force + gravity will overtake the force Fo, and the disc will then decelerate). gravity Fo= 30 N 30° no friction
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