a Rod 1.5 m and mass 91.0 kg can pivot at 1 end but is held...

A cylindrical rod of mass 0.82 kg and length 1.88 m is free to rotate about...

A cylindrical rod of mass 0.82 kg and length 1.88 m is free to rotate about a pivot fixed at one end. A ball with a mass of 3.2 kg is attached to the other end of the rod. The rod-and ball system is held in a horizontal position by a vertical force that acts 1.41 m from the pivot. The force is then removed, and the rod-and-ball swings down. (a) What was the vertical force used to hold the...

The uniform thin rod in the figure below has mass M = 2.00 kg and length...

The uniform thin rod in the figure below has mass M = 2.00 kg and length L = 2.87 m and is free to rotate on a frictionless pin. At the instant the rod is released from rest in the horizontal position, find the magnitude of the rod's angular acceleration, the tangential acceleration of the rod's center of mass, and the tangential acceleration of the rod's free end. HINT An illustration shows the horizontal initial position and vertical final position...

A thin, uniform, 15.5 kg post, 2.35 m long, is held vertically using a cable and...

A thin, uniform, 15.5 kg post, 2.35 m long, is held vertically using a cable and is attached to a 5.00-kg mass and a pivot at its bottom end (the figure (Figure 1)). The string attached to the 5.00-kg mass passes over a massless, frictionless pulley and pulls perpendicular to the post. Suddenly the cable breaks. A) Find the angular acceleration of the post about the pivot just after the cable breaks. B)Will the angular acceleration in part (A) remain...

A cylindrical rod of mass 0.82 kg and length 1.88 m is free to rotate about...

A cylindrical rod of mass 0.82 kg and length 1.88 m is free to rotate about a pivot fixed at one end. A ball (mass 3.2 kg) is attached to the other end of the rod. The rod-and- ball system is held in a horizontal position by a vertical force that acts 1.41 m from the pivot. The force is then removed, and the rod-and-ball swings down. (a) (4 points) What was the vertical force used to hold the system...

A rigid rod of mass 5.30 kg and length of 1.50 m rotates in a vertical...

A rigid rod of mass 5.30 kg and length of 1.50 m rotates in a vertical (x,y) plane about a frictionless pivot through its center. Particles m_1 (mass=6.30 kg) and m_2 (mass=2.20 kg) are attached at the ends of the rod. Determine the size of the angular acceleration of the system when the rod makes an angle of 42.1° with the horizontal.

A meterstick (L = 1 m) has a mass of m = 0.134 kg. Initially, it...

A meterstick (L = 1 m) has a mass of m = 0.134 kg. Initially, it hangs from two short strings: one at the 25 cm mark and one at the 75 cm mark. 1) What is the tension in the left string? N 2) Now the right string is cut! What is the initial angular acceleration of the meterstick about its pivot point? (You may assume the rod pivots about the left string, and the string remains vertical) rad/s^2...

A cylindrical rod of length 2.0 m, radius 0.5 m, and mass 1.5 kg has two...

A cylindrical rod of length 2.0 m, radius 0.5 m, and mass 1.5 kg has two spheres attached on its ends. The centers of the spheres are 1.0 m from the center of the rod. The mass of each sphere is 0.66 kg. The rod is capable of rotating about an axis passing through its center and perpendicular to the plane of the page, but the set up is stationary to begin with. A small mass of value 0.19 kgmoving...

A long, thin rod of length l and mass m hangs from a pivot point about...

A long, thin rod of length l and mass m hangs from a pivot point about which it is free to swing in a vertical plane like a simple pendulum. Calculate the total angular momentum of the rod about the pivot point as a function of its instantaneous angular frequency ω. Calculate the total kinetic energy of the rod.

A thin, cylindrical rod ℓ = 27.0 cm long with a mass m = 1.20 kg...

A thin, cylindrical rod ℓ = 27.0 cm long with a mass m = 1.20 kg has a ball of diameter d = 10.00 cm and mass M = 2.00 kg attached to one end. The arrangement is originally vertical and stationary, with the ball at the top as shown in the figure below. The combination is free to pivot about the bottom end of the rod after being given a slight nudge. Calculate the M.I of flywheel in moon...

A uniform rod of mass M and length L is pivoted at one end. The rod...

A uniform rod of mass M and length L is pivoted at one end. The rod is left to freely rotate under the influence of its own weight. Find its angular acceleration α when it makes an angle 30° with the vertical axis. Solve for M=1 Kg, L=1 m, take g=10 m s-2. Hint: Find the center of mass for the rod, and calculate the torque, then apply Newton as τ= Ι·α