The figure shows a uniform beam of length L = 6 m being suspended at a point x1 = 2 m from the right end. The weight of the beam is Pv = 56 N and makes an angle θ = 45 ° with the vertical. At the right end of the beam is suspended a weight Pd = 100 N. An unknown weight p is suspended at its other end at a distance x2 = 4 m. Find the value of p in N.
The figure shows a uniform beam of length L = 6 m being suspended at a point x1 = 2 m from the ri...
In (Figure 1) a 6.00-m-long, uniform beam is hanging from a point 1.00 m to the right of its center. The beam weighs 160 N and makes an angle of 30.0 with the vertical. At the right- hand end of the beam a 100.0 N weight is hung; an unknown weight w hangs at the left end. Part A If the system is in equilibrium, what is w? You can ignore the thickness of the beam. Express your answer with...
Part A In the figure (Figure 1)a 6.00-m-long, uniform beam is hanging from a point 1.00m to the right of its center. The beam weighs 139 N and makes an angle of 30.00 with the vertical. At the right-hand end of the beam a concrete block weighing 100N is hung; an unknown weight w hangs at the other end. If the system is in equilibrium, what is w? You can ignore the thickness of the beam. IVO ALOM O 2...
A uniform horizontal beam with a length l = 8.00 m and weight of Wb = 200 N is attached to a wall by a pin connection. Its far end is supported by a cable that makes an angle of θ = 53.0◦ with the beam. A person of weight Wp = 600 N stands a distance d = 2.00 m from the wall. Find the tension in the cable.
In the figure, a uniform beam of weight 550 N and length 2.3 m is suspended horizontally. On the left it is hinged to a wall; on the right it is supported by a cable bolted to the wall at distance D above the beam. The least tension that will snap the cable is 1100 N What value of D corresponds to that tension? Number Units im The number of significant digits is set to 2, the tolerance is +/-1%
The figure shows a uniform, horizontal beam (length = 10.0 m, mass = 30.0 kg) that is held by a horizontal pin (pivoted at the wall), with its far end supported by a cable that makes an angle of 51 degree with the horizontal. A person of mass M stands 3.00 magnitude of 454 N. (a) Calculate the mass M of the person standing on the beam? (b) What are the horizontal and vertical components of the force the pin...
rarong questions) Question 1. A uniform horizontal beam with a length of L=10.00 m and weight is 250 N is attached to a wall by a pin connection as shown. Its far end is supported by a cable that makes an angle of = 60.0' with the beam. A person of weight 500 N stands a distance d = 2.50 m from the wall. Find the tension in the cable. (16 points) ათ ESON 60.0 SOON P=2.50 swo
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The figure shows a uniform horizontal beam (length = 8 m, mass = 20 kg) that is pivoted at the wall, with its far end supported by a cable that makes an angle of 50 degree with the horizontal. If a store's sign (mass = 30 kg) is hung at the end of beam, find all forces on the beam.
The figure below shows a uniform rod of length L=1.3 m and mass M (not required in answer) which is free to rotate about one end, and which is initially at rest at an angle θ=40º with respect to the horizontal. Find the (linear) speed of the center of mass of the rod when it reaches the vertical position (θ=-90°).
As shown in the figure below, a uniform beam is supported by a
cable at one end and the force of friction at the other end. The
cable makes an angle of θ = 30°,the length of the beam is L= 4.00
m, the coefficient of static friction between the wall and the beam
is μs = 0.500, and the weight of the beam is represented
by w. Determine the minimum distance x from point
A at which an additional...
As shown in the figure below, a uniform beam is supported by a cable at one end and the force of friction at the other end. The cable makes an angle of θ = 30°, the length of the beam is L = 4.25 m, the coefficient of static friction between the wall and the beam is μs = 0.420, and the weight of the beam is represented by w. Determine the minimum distance x from point A at which...