The forked rod is used to move the smooth 2 lb. particle around thehorizontal path in...
Using a forked rod, a smooth 3-lb particle is forced to move along around the horizontal path in the shape of a limaçon, r = (5+sin o) ft. If 0 = -12 rad, where t is in seconds, determine the force of the rod and the normal force of the slot on the particle at the instant t= 3sec. The fork and path contact the particle on only one side.
II Review The forked rod is used to move the smooth 3-lb particle around the horizontal path in the shape of a limaçon, r = (2 + cos 0) ft.(Figure 1) Part A If 0 = (0.5t2) rad, where t is in seconds, determine the force which the rod exerts on the particle at the instant t = 1 s. The fork and path contact the particle on only one side. Express your answer with the appropriate units. Figure 1...
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 =...
< Assignment #7 Problem 13.94 2 of 5 Using a forked rod, a smooth oyinder P, having a mass- of 0.6 kg, is forced to move along the vertical slotted path r (0.60) m, where 0 is in radians. (Figure 1) Part A If the cylinder has a constant speed of vcー1.7 m/s . determine the force ofthe rod and the normal force of the soton the cylinder at the instant rad. Assume the cylinder is in contact with only...
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 0.35 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...
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...
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...
Rod OA rotates counterclockwise with a constant angular velocity of θ = 5 rad/s. The double collar B is pin-connected together such that one collar slides over the rotating rod and the other slides over the horizontal curved rod, of which the shape is described by the equation r = 1.5(2-cosθ)ft. (Figure 1) Part AIf both collars weigh 0.80 lb, determine the magnitude of the normal force which the curved rod exerts on one collar at the instant θ = 135°....
Rod O A rotates counterclockwise with a constant angular velocity of θ=5 rad / s. The double collar B is pin-connected together such that one collar slides over the rotating rod and the other slides over the horizontal curved rod, of which the shape is described by the equation r=1.5(2-cosθ) ft. (Figure 1)Part AIf both collars weigh 0.80 lb, determine the magnitude of the normal force which the curved rod exerts on one collar at the instant θ=110° . Neglect...