3 (a) For the beam shown in Figure Q3.1, E 200GPa and I 22:10 m throughout....
3 (a) For the beam shown in Figure Q3.1, E 200GPa and I 22:10 m throughout. By using the stiffness method and neglecting axial effects: (i) Calculate the rotations of each of the supports [5 marks (ii) Calculate the bending moment and shear force diagrams. [10 marks] (iii) Calculate the reactions and check equilibrium. [5 marks] 7.5kNm SkNm 2 2 Im Im Figure Q3.1
3 (a) For the beam shown in Figure Q3.1, E 200GPa and I 22:10 m throughout....
For the beam shown in the figure below a. Draw the shear and moment diagrams for this beam b. Calculate the maximum bending stress, maximum axial stress, and maximum shear stress acting on the beam cross section c. Sketch the distributions of shear stresses and bending stresses acting on the beam cross section at the locations where these stresses are maximum.
Calculate the reactions at the supports A, B, and C for the beam in figure 4 and then draw the shear force and bending moment diagrams. At A and B there are simple supports while at C there is a pin joint. If the cross section of the beam is rectangular, with dimensions b-10 mm and h-24 mm what is maximum bending stress in the beam? 12 kN 9 kN/m 22 224m 2
Q5: Using force method, determine the reactions of the
supports for the beam shown in Figure (5). Then draw shear and
bending moment diagrams for the beam. EI is constant. Use conjugate
beam method to determine deflections.
I need it in 30min or 1 h
6 m 50 KN 200 kN.m 22 А В. С 9 m to 3m
For the beam shown in below, determine the displacements and rotations at the nodes, the forces in each element, and reactions. Also, draw the shear force and bending moment diagrams 10 kN 2 E210 GPa .20 kN m
For the beam shown in below, determine the displacements and rotations at the nodes, the forces in each element, and reactions. Also, draw the shear force and bending moment diagrams 10 kN 2 E210 GPa .20 kN m
Using force method , determine the reactions of the
supports for the beam shown in Figure ( 5 ) . Then draw shear and
bending moment diagrams for the beam El is constant Use conjugate
beam method to determine deflections ,
6 m 50 KN 200 kN. 9 m - 3 m Fig. (5) BEST WISHES
500 N/m 2b Figure 1 (a) Determine the reactions at the supports at A and B. 4 Marks) Determine the equations defining the shear force and bending moment at any (6 Marks) Draw the shear force and bending moment diagrams for the beam, showing the (6 Marks) (b) point between points A and C (c) values at all points between points A and B. (d) Find the dimensions of the cross-section of the beam if the allowable bending stress for...
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...
x7=12KN , x8=19kN/m, x4=4m, x5=39m, x6=5m,
Q2. In the 3-span beam shown in the Figure 2, the support at C settles by 15 mm. Using the method of moment distribution method, a) Calculate joint moments (10 marks); b) Draw the bending moment diagram (10 marks); c) Calculate the supports' vertical reactions (10 marks); and d) Draw the shear force diagram (5 marks). Hint: For the calculation of Fixed End Moments, you can use the principle of superposition to add the settlement-related...
A simply supported beam as shown in the figure. The beam section is W18x211. The beam must support its own weight and must carry the following loading: Super-imposed distributed dead load = 0.25 kip/ft Distributed live load = 1 kip/ft Concentrated dead load = 12 kip The beam span L = 26 ft and the distance of the concentrated load from the right support a=6 ft. Consider analy- sis of beam subjected to load combination 1.2 dead + 1.6 live....