The 0.2-kg pin P is constrained to move in the smooth curved slot, which is defined...
The 0.3-kg pin P is constrained to move in the smooth curved slot, which is defined by the lemniscate (0.6 cos20) m. Its motion is controlled by the rotation of the slotted arm O A, which has a constant clockwise angular velocity of 0 = -3 rad/s. (Figure 1) r= Part A Determine the force arm O A exerts on the pin P when 0 = 0°. Motion is in the vertical plane. Express your answer to three significant figures...
The particle has a mass of
0.35 kg and is confined to move along the smooth vertical slot due
to the rotation of the arm OA. The rod is rotating with a constant
angular velocity θ = 2 rad/s. Assume the particle contacts only
one side of the slot at any instant. (Figure 1)Part ADetermine the magnitude of the force of the rod on the particle when θ=30°.Part BDetermine the magnitude of the normal force of the slot on the...
Given: The particle has a known mass m and is confined to move along the smooth horizontal slot due to the rotation of the rod OA. Also, the rod is rotating with a known constant angular velocity of θ. Assuming the particle contacts only one side of the slot at any instant, Find: a) The radial (vr) and transverse components (vθ) of the particle's velocity at the given instant. b) The radial (ar) and transverse components (aθ) of the particle's acceleration at the given...
The particle has a mass of 0.8 kg and is confined to move along the smooth vertical slot due to the rotation of the arm OA. The rod is rotating with a constant angular velocity θ = 2 rad/s. Assume the particle contacts only one side of the slot at any instant.(Figure 1).
Part A
Determine the magnitude of the force of the rod on the particle when θ = 30°. Express your answer to three significant figures and include the appropriate...
Pin P is attached to the wheel shown and slides in a slot cut in bar BD. The wheel rolls to the right without slipping with a constant angular velocity of 22 rad/s 0 140 min 200 mm Problem 15.154.a- Plane motion, velocity of a particle with respect to a rotating reference frame Knowing that x= 480 mm at θ = o", determine the angular velocity of the bar and the relative velocity of pin P with respect to the...
The particle has a mass of 0.45 kg and is confined to move along the smooth vertical slot due to the rotation of the arm OA. The rod is rotating with a constant angular velocity Part A 0 2 rad/s. Assume the particle contacts only one side of the slot at any instant. Figure 1) Determine the magnitude of the force of the rod on the particle when 6-30 Express your answer to three significant figures and include the appropriate...
Problem 2: Arm OA rotates about O. The positive 0-direction is definert ss eosss terclockwise from the fixed a-axis indicated in the igure. The partiele P Ys s tm of 2 kg and is constrained to move on a track in the horizontal plane describes polar coordinates by2+sin 30, where r is the radial coordinate mensuree pusred fro meters. For the instant where-0°, θ : 0.2 rad/s, andi-0.15 τα,.enl e magnitude of the force (N) applied by arm OA. 2+sin...
Using a forked rod, a 0.35-kg smooth peg P is forced to move along the vertical slotted path T' = (0.5 0) m, where 0 is in radians. The angular position of the arm is 0 (t)rad where t is in seconds. The peg is in contact with only one edge of the rod and slot at any instant. (Figure 1) Part A Determine the magnitude of the force of the rod on the peg at the instant t =...
A 0 5 kg block 5slides without friction inside a slot cut in arm OA which rotates n a encal plane. The rod has a constant angular acceleration θ 10 rad S2 Know that when θ 60° and 08 m the eocry of the block is zero. References eBook & Resources Section Break Difficulty: Easy Required information 25.00 points Determine at this instant, the relative acceleration of the block with respect to the am. (Round the final answer to two...
A 0.2-kg spool slides down along a smooth rod. If the roc has a Part A constant angular rate of rotation = 2rad/s in the vertical plane, the equations of motion for the spool are-1r - 9.81 sin 0 and 0.8 N,-1.962 cos- 0, where , is the magnitude of the normal force of the rod on the spool. (Figure 1) Using the methods of differential equations. it can be shown that the solution of the first of these equations...