03. (25%) Stress and deflection, of simply supported beam 6.08 inches from the bottom flange edge...
The beam is subjected to a moment of 15 kip*ft. Determine the resultant force the bending stress produces on the top flange A and the bottom flange B. Also compute the maximum bending stress developed in the beam.
2. A 30 ft long simply supported beam supports a uniformly distributed load of 2 kips/ft over the entire span. The beam and cross section are shown below. Draw the shear and moment diagrams, find the neutral axis location, moment of inertia of the composite section, the maximum bending stress on the cross section. (40 points) 10" 2 k/ft 1-3" 30'-0"
3 ft, 3 ft 3 ft Problem 3. The beam is supported by a pin at point B and a roller at point E. A distributed load q = 1 kip/ft is applied across AC, and a point load P = 5 kips and counter-clockwise moment M = 9 kips . ft are applied at point D. Determine the reactions at the supports, and draw the shear and bending moment diagrams.
The beam is subjected to a moment of 15 kip·ft. Determine the resultant force the bending stress produces on the top flange A and bottom flange B. Also calculate the maximum bending stress developed in the beam.
1. For the simply supported beam subjected to the loading shown, Derive equations for the shear force V and the bending moment M for any location in the beam. (Place the origin at point A.) a. b. Plot the shear-force and bending-moment diagrams for the beam using the derived functions c. Report the maximum bending moment and its location. 42 kips 6 kips/ft 10 ft 20 ft
Please refer AISC 15th edition 1. You are given a simply supported, uniformly loaded beam (W14x26), 20-ft long which is laterally supported and which carries a dead load of 0.5kips/ft and a live load of 1.5 kips/ft. You are to compute the maximum live load deflection and compare it with the maximum allowable live load deflection of L/360. If your live load deflection is larger than the allowable live load deflection, determine the magnitude of the moment of inertia needed...
The beam is simply supported. Problem 3. (30 points) A wooden beam is composed of a 2 x8" (1.5"x7.25") top flange and a 3"x10 (2.5"x9.25") web to form a T section. Assume that the two members are glued together. L-16 ft. (a) For a uniform dead load of 20 lb/ft over the entire beam span and a uniform live load of 80 lb/ft over the left half of the span, draw the shear and moment diagrams. (b) Determine the cross-sectional...
The simply supported beam, with a U cross section, is subjected to a uniformly distributed force of 8 kN/m and a concentrated load of 12 kN as shown. (a) Determine the reaction at supports A and B, (b) sketch the shear diagram and the moment diagram, (c) determine the location of the neutral axis of the cross section and calculate its area moment of inertia about the neutral axis, and (d) determine absolute maximum bending stress and (e) absolute maximum...
04 m 8 KN 2. A simply supported beam is shown below. a. b. c. Draw a proper FBD of the beam showing all the known and unknown forces acting on it. Determine the support reactions at A and B. Draw the shear (V) and bending moment (M) diagrams for the beam. 2500 lb 500 Ib/it 3 ft -3 ft 3 ft 3. Draw a proper FBD of member ABC showing all the known and unknown forces acting Determine the...
Please refer AISC 15th edition 1. You are given a simply supported, uniformly loaded beam (W14x26), 20-ft long which is laterally supported and which carries a dead load of 0.5kips/ft and a live load of 1.5 kips/ft. You are to compute the maximum live load deflection and compare it with the maximum allowable live load deflection of L/360. If your live load deflection is larger than the allowable live load deflection, determine the magnitude of the moment of inertia needed...