Structural Analysis
Structural Analysis
6th Edition
ISBN: 9781337630931
Author: KASSIMALI, Aslam.
Publisher: Cengage,
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Chapter 13, Problem 41P
To determine

Calculate the support reactions for the given structure using method of consistent deformation.

Sketch the shear and bending moment diagrams for the given structure.

Expert Solution & Answer
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Answer to Problem 41P

The vertical reaction at A is Ay=23k_.

The vertical reaction at B is By=63k_.

The vertical reaction at D is Dy=48k_.

The vertical reaction at F is Fy=63k_.

The vertical reaction at G is Gy=23k_.

The moment at A is MA=0_.

The moment at B is MB=210k-ft()_.

The moment at C is MC=180k-ft()_.

The moment at D is MD=180k-ft()_.

The moment at F is MF=210k-ft()_.

Explanation of Solution

Given information:

The structure is given in the Figure.

Apply the sign conventions for calculating reactions, forces and moments using the three equations of equilibrium as shown below.

  • For summation of forces along x-direction is equal to zero (Fx=0), consider the forces acting towards right side as positive (+) and the forces acting towards left side as negative ().
  • For summation of forces along y-direction is equal to zero (Fy=0), consider the upward force as positive (+) and the downward force as negative ().
  • For summation of moment about a point is equal to zero (Matapoint=0), consider the clockwise moment as positive when moment taken from left and the counter clockwise moment as positive when moment taken from right.
  • Consider the positive sign indicates the clockwise moment the negative sign indicates the counterclockwise moment.

Calculation:

The beam and the loading are symmetric since only analyze only the right half DG of the beam.

Sketch the free body diagram of the right half DG of the beam as shown in Figure 1.

Structural Analysis, Chapter 13, Problem 41P , additional homework tip  1

Refer Figure 1.

Find the degree of indeterminacy of the structure:

Degree of determinacy of the beam is equal to the number of unknown reactions minus the number of equilibrium equations.

The beam is supported by 5 support reactions and the number of equilibrium equations is 3.

Therefore, the degree of indeterminacy of the beam is i=2.

Select the vertical reaction Fy and Gy at the supports F and G as redundant.

Release the support F and G and consider the notation of moments due to external load as MO.

Sketch the free body diagram of primary beam subjected to external loading without support F and G as shown in Figure 2.

Structural Analysis, Chapter 13, Problem 41P , additional homework tip  2

Refer Figure 2.

Find the reactions at the supports without considering support F and G using equilibrium equations:

Summation of moments of all forces about D is equal to 0.

MD=0MDO=50(15)2(30)(302+30)=3,450k-ftMDO=3,450k-ft()

Summation of forces along y-direction is equal to 0.

+Fx=0DyO502(30)=0DyO=110k()

For unit value of the unknown redundant Fy:

Consider the notation of moments due to external load as mF.

Sketch the free body diagram of primary beam Subjected to unit value of redundant Fy as shown in Figure 3.

Structural Analysis, Chapter 13, Problem 41P , additional homework tip  3

Refer Figure 3.

Find the support reaction and moment at D when 1 k vertical load applied at C.

Summation of moments of all forces about A is equal to 0.

MD=0MDF=1(30)MDF=30k-ft()

Summation of forces along y-direction is equal to 0.

+Fy=0DyF+1=0DyF=1k()

For unit value of the unknown redundant Gy:

Consider the notation of moments due to external load as mG.

Sketch the free body diagram of primary beam Subjected to unit value of redundant Gy as shown in Figure 4.

Structural Analysis, Chapter 13, Problem 41P , additional homework tip  4

Refer Figure 4.

Find the support reaction and moment at D when 1 k vertical load applied at C.

Summation of moments of all forces about A is equal to 0.

MD=0MDG=1(60)MDF=60k-ft()

Summation of forces along y-direction is equal to 0.

+Fy=0DyG+1=0DyG=1k()

Find the moment equation of the beam for different sections on the beam.

Consider a section XX in the portion DE of the primary structure at a distance of x from D.

Refer Figure 1.

Draw the primary structure with section XX as shown in Figure 5.

Structural Analysis, Chapter 13, Problem 41P , additional homework tip  5

Refer Figure 5.

Portion AB.

Consider origin as A. (0x15ft).

Find the moment at section XX in the portion DE as shown in Figure 5.

MO=3,450+110(x)=3,450+110x

Similarly calculate the moment of the remaining section in the external loading and redundant loading structures.

Tabulate the moment equation of different segment of beam as in Table 1.

Segmentx-coordinateMO (k-ft)mFY (k-ft/k)mGY (k-ft/k)
OriginLimits (ft)
DEA0153,450+110x301(x)601(x)
EFE15303,450+110(x)50(x15)301(x)601(x)
FGG0302x22=x20x

The vertical deflection at point F due to external loading is ΔFO, vertical deflection at point G due to external loading is ΔGO,  and the flexibility coefficient representing the deflection at F due to unit value of redundant Fy is fFF, the redundant Gy is fGG, and the both redundant Fy and Gy is fFG=fGF.

Calculate the value of ΔFO using the equation as follows:

ΔFO=ΣMOmFYEIdx=1EI{015(3,450+110x)(30x)dx+1530[3,450+110(x)50(x15)][30x]dx+030(x2)(0)dx}=1EI[916,875168,750+0]=1,085,625EIk-ft3

Calculate the value of ΔGO using the equation as follows:

ΔGO=ΣMOmGYEIdx=1EI{015(3,450+110x)(60x)dx+1530[3,450+110(x)50(x15)][60x]dx+030(x2)(x)dx}=1EI[2,098,125776,2502,02,500]=3,076,875EIk-ft3

Calculate the value of fFF using the equation as follows:

fFF=ΣmFY2EIdx=1EI{015(30x)2dx+1530(30x)2dx+030(0)2dx}=1EI[7,875+1,125+0]=9,000EIk-ft3/k

Calculate the value of fGG using the equation as follows:

fGG=ΣmGY2EIdx=1EI{015(60x)2dx+1530(60x)2dx+030(x)2dx}=1EI[41,625+21,375+9,000]=72,000EIk-ft3/k

Calculate the value of fFG using the equation as follows:

fFG=fGF=ΣmFYmGYEIdx=1EI[015(30x)(60x)dx+1530(30x)(60x)dx+030(0)(x)dx]=1EI[18,000+4,500+0]=22,500EIk-ft3/k

Find the reactions and moment:

Find the horizontal and vertical reaction at F and G.

Show the first compatibility Equation as follows:

ΔFO+fFFFy+fFGGy=0

Substitute 1,085,625EIk-ft3 for ΔFO, 9,000EIk-ft3 for fFF, and 22,500EIk-ft3/k for fFG.

1,085,625EI+(9,000EI)Fy+(22,500EI)Gy=09,000Fy+22,500Gy=1,085,625        (1)

Show the second compatibility Equation as follows:

ΔGO+fGFFy+fGGGy=0

Substitute 3,076,875EIk-ft3 for ΔGO, 22,500EIk-ft3/k for fGF, and 72,000EIk-ft3/k for fGG.

3,076,875EI+(22,500EI)Fy+(72,000EI)Gy=022,500Fy+72000Gy=3,076,875        (2)

Solve Equation (1) and (2).

Fy=63k()Gy=23k()

The beam is symmetrical. Hence, Fy=ByandGy=Ay.

Find the vertical reaction at D.

Summation of forces along y-direction is equal to 0.

+Fy=0Ay+By+Fy+Gy+Dy=50+2(30)+50+2(30)

Substitute 23 k for Ay, 63k for By, 63 k for Fy and 23 k for Gy.

23+63+63+23+Dy=220Dy=48k

Therefore, the vertical reaction at A is Ay=23k_.

Therefore, the vertical reaction at B is By=63k_.

Therefore, the vertical reaction at D is Dy=48k_.

Therefore, the vertical reaction at F is Fy=63k_.

Therefore, the vertical reaction at G is Gy=23k_.

Sketch the free body diagram with support reactions of the beam as shown in Figure 6.

Structural Analysis, Chapter 13, Problem 41P , additional homework tip  6

Refer Figure 6,

Find the shear force (S) for the given beam:

For span AB,

At point A.

SA=23k

At point B, (negative side):

SB=232(30)=37k

For span BD,

At point B, (positive side):

SB+=37+63=26k

At point C, (positive side):

SC+=26k

At point C, (negative side):

SC=2650=24k

At point D, (negative side):

SD=24k

For span DF,

At point D, (positive side):

SD+=24+48=24k

At point E, (positive side):

SE+=24k

At point E, (negative side):

SE=2450=26k

At point F, (negative side):

SF=26k

For span FG,

At point F, (positive side):

SF+=26+63=37k

At point G,

SG=372(30)=23k

Sketch the shear diagram for the given beam as shown in Figure 7.

Structural Analysis, Chapter 13, Problem 41P , additional homework tip  7

Refer Figure 7.

The points of zero shear as H and I.

Find the point of zero shear force from A and G.

232(x1)=SF02x1=23x1=11.5ft

Refer Figure 6.

Find the bending moment (M) for the beam:

For span AB,

At point A, (hinge end)

MA=0

At point H,

MH=23(11.5)2(11.5)(11.52)=264.5132.25132k-ft

At point B,

MB=23(30)2(30)(302)=690900=210k-ft

For span BD,

At point C,

MC=23(45)2(30)(302+15)+63(15)=1,0351,800+945=180k-ft

At point D,

MD=23(60)2(30)(302+30)+63(30)50(15)=1,3802,700+1,890750=180k-ft

The moment at E, F, I, and G is equal to the moment at C, B, H, and A respectively due to symmetry of the beam.

Sketch the bending moment diagram for the given beam as shown in Figure 8.

Structural Analysis, Chapter 13, Problem 41P , additional homework tip  8

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