consider the beam and the loading Question #3: (8 marks/20) I/I BET el, e2 and e3)...
Question 2 For the beam and loading shown in Figure Q2: a. Determine the support reactions b. Draw the shear and bending moment diagrams c. Determine the maximum absolute value of shear force and bending moment.
QUESTION 2 Beam ABCD is 8 m in length and is pin-supported at A and roller-supported at C as shown in Figure Q2. A counter-clockwise concentrated moment acts about the support A. A uniformly-distributed load acts on span BC and a vertical concentrated load acts at the free end D a) Determine the reactions at supports A and C. 4 marks) b) Obtain the shear force and the bending moment functions (in terms of x) for each segment along the...
Assume a beam has the loading shown and a rectangular cross section. is at the center and G is at the bottom. Assume point E is at the top, F Cross Sectional View of plane cut at B 400 lb 4 in 500 lb 3 in 10 in. 15 it 1 5 in 1) The beam is cut along a face at B that is perpendicular to the X axis. What is the internal resistive shear force at this face?...
Draw the influence lines
Question 6 (8 marks) Consider the moving load Pm 1 that may be applied to the structure shown below in Figure 6. Note that support A is a pin support and supports B and C are roller supports. Figure 6 In the spaces provided below, draw the Influence Lines for (i) the shear force at point E, (i) the bending moment at point E, and (ili) the bending moment at point D (i) Influence Line "VE...
3. Draw the shear and bending-moment diagrams for the beam and loading shown, and determine the maximum a bsolute value (a) of the shear, (b) of the bending moment. (40 Points) 300 lb 240 lb 360 lb CVDVE 4 in. 3 in. 4 in. 5 in.
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Problem 5 (6 marks) For the beam and loading shown, a) Draw the shear and bending-moment diagrams. b) Determine the maximum absolute value of the shear and bending moment. c) Determine the minimum required depth h of the beam. Knowing that the material used has an ultimate normal and shear stresses, use the given factor of safety in each loading case in the following table. P A LLL Dimensions, material properties and load values are presented in...
Question AT For the beam and loading shown in Figure Al: - a. Determine the support reactions b. Draw the shear and bending moment diagrams c. Determine the maximum absolute value of shear force and bending moment. 30 kN/m 60 kN C D K-2m-imta2m- Figure A1
The simply supported beam shown in Figure 1 is pin-supported at A and roller-supported at D. la) Replace the distributed loads in Figure 1 by an equivalent resultant force and locate its location with respect to A. {2 + 3 marks 1b) Calculate the reactions at supports A and D. {2 marks 1c) Calculate the shear force and bending moment at point C. {4 marks) 15 kN/m 6 kN/m D B q 3.0 m 3.0 m 3.0 m Figure 1
5. (20 Points) For the loading on the simply supported beam shown below. a) What is the internal shear and bending moment at point C? b) Given the beam has a rectangular cross section with a width of 8 in. and a height of 20 in., find the maximum normal stress (om) in the cross section at C from the bending moment calculated above. 600 lb 200 lb/ft
1) The uniform beam shown is supported by a pin at A and a light rope at B. A 1,000 lb weight is supported at C. Determine the normal force, shear force, and bending moment at point P. (15 p.) 30 3 А 2) The uniform beam shown is supported by a pin at and a roller at B. Using the analytical method (i.e., sections), construct the shear and moment diagrams. Write your equations V(x) and Mix) for each section...