For the structural system shown in the figure determine the value of the deflection and slope at point C, apply the virtual working method with unit load
For the structural system shown in the figure determine the value of the deflection and slope...
The structural system shown in the figure is determined, using the moment area method to determine the value of the deflection and slope of point C, that has been identified on the beam. The stiffness value is in accordance with what is shown in the figure, the cross section of the beam is uniform and constant 12 kN/m c3eІ ZEI В A 1 2.4om 3.40 m 5.80 m
The beam is shown in the figure below. Use the slope-deflection method. The support Ais pinned, support B is a roller, and support C is fixed. Assume El = 21537 kNm2. The support at B settles by 73 mm (downwards). The segment AB is subjected to a uniformly distributed load w= 11 kN/m. The segment BC is subjected to a point load P = 91 KN. Enter the digit one in the answer box. The link will be provided on...
Structural Analysis For the load shown in the figure, determine A) The equation of the elastic curve for the cantilever AB B) The deflection at the free end C) The slope at the free end. PS: Determine the equations of slope and elastic curve by the DOUBLE INTEGRATION METHOD PS: Calculate the slopes and deflections requested in each beam by the MOMENTAL AREA METHOD.
2. Determine the vertical deflection at point C of the beam shown in Figure 2 with the virtual work method. PE 10 kN 2 kN/m El constant E= 2x 105 MPa 1-1x10 mm Figure 2 2. Determine the vertical deflection at point C of the beam shown in Figure 2 with the virtual work method. PE 10 kN 2 kN/m El constant E= 2x 105 MPa 1-1x10 mm Figure 2
(3) Use the method of virtual work to determine the slope and the yertical deflection at (10 points) point C 120 kN m 100 kN A В 6 m 3m 21 E constant 70 GPa I = 500 (106) mm
A=1200mm2 Problem #4: Determine the horizontal deflection at joint C of the frame shown in the Figure including the effect of axial deformations, by the virtual work method. El- constant, E 70 GPa, l = 554(106) mmt (25 Points) 10 m 15 kN/m -75 kN- 6 m BHinge 6 m Problem #4: Determine the horizontal deflection at joint C of the frame shown in the Figure including the effect of axial deformations, by the virtual work method. El- constant, E...
For the steel beam shown in the figure, compute the slope at A and C. Also, determine the location and value of the maximum deflection. If the maximum deflection is not to exceed 0.6 in, what is the minimum required value of I? El is constant and E= 29000 ksi We were unable to transcribe this imageCompute the slope of the elastic curve at B and C and the deflection at C for the cantilever beam shown in the figure....
4. Determine the slope and deflection at end point C of the cantilever beam shown in the figure. Use E = 200 GPa, I = 10 x 106 mm 3 kN/m 2 kN.m A B 2 m 2 m
Using Conjugate Beam Method, Determine the Deflection and slope at mid-span of a simply supported beam, as shown in figure Using Conjugate Beam Method, Determine the Deflection and slope at mid 40 kN 60 kN
Slope-Deflection method only please! Step by step Determine all reactions for the beam shown in Figure 6. El is constant. 8 kN-m 2 m 2 m Figure 6 Slope-Deflection Equations 3A + FEM 2EI 20,+0 - M AB AB 2EI 20, +0, 3A + FEM BA M BA Fixed-End Moments (4L - 3a) (6L - Bal +3k') 12 12 12