Find the reactions and all bar forces for the truss.

Question

Want to see more full solutions like this?

Answer 1

Question

Chapter 9, Problem 38P

To determine

Find the reactions and all bar forces for the truss.

Expert Solution & Answer

Explanation of Solution

Given information:

EI is constant.

The Young’s modulus E of the beam is 30,000 kips/in.2.

The area of all the bars are 2 in2.

Calculation:

Consider the force in the member AC and the horizontal reaction at support B are the redundant.

Remove the redundant to get the released structure.

Sketch the released structure with external loading as shown in Figure 1.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 1

Refer Figure 1.

Consider the force in the member AC as zero.

Find the value of the angle θ as follows:

tanθ=1520θ=tan−1(1520)θ=36.869°

Find the support reaction as follows:

Apply Equation of Equilibrium,

∑MA=0−60×15+By1×20=0By1=90020By1=45 kips

∑Fy=0Ay1+By1=0Ay1=−By1Ay1=−45 kips

∑Fx=0Ax1+60=0Ax1=−60 kips

Consider support A.

Apply Equation of Equilibrium,

∑Fy=0Ay1+FAD1=0FAD1=−Ay1FAD1=−(−45) kipsFAD1=45 kips(T)

∑Fx=0Ax1+FAB1=0FAB1=−Ax1FAB1=−(−60) kipsFAB1=60 kips(T)

Consider joint C.

Apply Equation of Equilibrium,

∑Fx=0−FCD1+60=0FCD1=60 kips(T)

∑Fy=0FBC1=0

Consider joint D,

Apply Equation of Equilibrium,

∑Fx=0FCD1+FBD1cosθ=0FCD1+FBD1cos(36.869°)=060+0.8FBD1=0FBD1=75 kips(T)

Sketch the P system for Δ10 and Δ20 as shown in Figure 2.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 2

Sketch the released structure with unit member force in member AC as shown in Figure 3.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 3

Refer Figure 4.

Consider the force in the member AC is 1 kips.

The support reactions at A and B are zero as no external load acts on the truss.

Consider support A.

Apply Equation of Equilibrium,

∑Fx=0FACcosθ+FAB=01cos(36.869°)+FAB=0FAB=−0.8 kipsFAB=0.8 kips(C)

∑Fy=0FACsinθ+FAD=01sin(36.869°)+FAD=0FAD=−0.6 kipsFAD=0.6 kips(C)

Consider joint C.

Apply Equation of Equilibrium,

∑Fx=0−FCAcosθ−FCD=0−cos(36.869°)−FCD=0FCD=−0.8 kipsFCD=0.8 kips(C)

∑Fy=0−FCAsinθ−FCB=0−sin(36.869°)−FCB=0FCB=−0.6 kipsFCB=0.6 kips(C)

Consider joint D,

Apply Equation of Equilibrium,

∑Fx=0FCD+FBDcosθ=0−0.8+FBDcos(36.869°)=0−0.8+0.8FBD=0FBD=1 kips(T)

Sketch the Q system for Δ10 as shown in Figure 4.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 4

Sketch the Q system for Δ20,δ21,δ22 and P system for δ22 as shown in Figure 5.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 5

Refer Figure 5.

Find the support reaction at A as follows:

Applying Equation of Equilibrium,

∑Fx=0Ax−1=0Ax=1 kips

There is no external load at joint D and C and no vertical reaction at A and B.

The force in all the members of the truss except AB is zero.

Consider joint A.

Applying Equation of Equilibrium,

∑Fx=0Ax+FAB2=01+FAB2=0FAB2=−1 kipsFAB2=−1 kips

Find the deflection Δ10 as follows:

Δ10=FQFPLAE=[(−0.8)×60×(20 ft×12 in.1 ft)2×30,000×2+(−0.6)×45×(15 ft×12 in.1 ft)2×30,000+1×(−75)×(25 ft×12 in.1 ft)4×30,000]=−0.6525 in.

Find the deflection Δ20 as follows:

Δ20=FQFPLAE=−1×60×(20 ft×12 in.1 ft)2×30,000=−0.24 in.

Find the deflection δ11 as follows:

δ11=FQ2LAE=[(−0.8)2×(20 ft×12 in.1 ft)2×30,000×2+(−0.6)2×(15 ft×12 in.1 ft)2×30,000+12×(25 ft×12 in.1 ft)2×30,000+12×(25 ft×12 in.1 ft)4×30,000]=0.0148 in.

Find the deflection δ21 as follows:

δ21=FQFPLAE=(−1)(−0.8)×(20 ft×12 in.1 ft)2×30,000=0.0032 in.

Find the deflection δ12 as follows:

δ12=FQFPLAE=(−0.8)(−1)×(20 ft×12 in.1 ft)2×30,000=0.0032 in.

Find the deflection δ22 as follows:

δ22=FQFPLAE=(−1)(−1)×(20 ft×12 in.1 ft)2×30,000=0.004 in.

Show the compatibility Equation for Δ1,AC REL as follows:

Δ1,AC REL=0Δ10+δ11X1+δ12X2=0−0.6525+0.0148X1+0.0032X2=00.0148X1+0.0032X2=0.6525 (1)

Show the compatibility Equation for ΔBX as follows:

ΔBX=0Δ20+δ21X1+δ22X2=0−0.24+0.0032X1+0.004X2=00.0032X1+0.004X2=0.24 (2)

Solve Equation (1) and (2).

X1=37.62 kips

X2=29.9 kips

Find the reaction and bar forces in the members of the truss as shown in 6 and 7.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 6

Apply the sum shown in Figure 6 to get the final reactions and member forces shown in Figure 7.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 7

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 2

Question

Chapter 9, Problem 38P

To determine

Find the reactions and all bar forces for the truss.

Expert Solution & Answer

Explanation of Solution

Given information:

EI is constant.

The Young’s modulus E of the beam is 30,000 kips/in.2.

The area of all the bars are 2 in2.

Calculation:

Consider the force in the member AC and the horizontal reaction at support B are the redundant.

Remove the redundant to get the released structure.

Sketch the released structure with external loading as shown in Figure 1.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 1

Refer Figure 1.

Consider the force in the member AC as zero.

Find the value of the angle θ as follows:

tanθ=1520θ=tan−1(1520)θ=36.869°

Find the support reaction as follows:

Apply Equation of Equilibrium,

∑MA=0−60×15+By1×20=0By1=90020By1=45 kips

∑Fy=0Ay1+By1=0Ay1=−By1Ay1=−45 kips

∑Fx=0Ax1+60=0Ax1=−60 kips

Consider support A.

Apply Equation of Equilibrium,

∑Fy=0Ay1+FAD1=0FAD1=−Ay1FAD1=−(−45) kipsFAD1=45 kips(T)

∑Fx=0Ax1+FAB1=0FAB1=−Ax1FAB1=−(−60) kipsFAB1=60 kips(T)

Consider joint C.

Apply Equation of Equilibrium,

∑Fx=0−FCD1+60=0FCD1=60 kips(T)

∑Fy=0FBC1=0

Consider joint D,

Apply Equation of Equilibrium,

∑Fx=0FCD1+FBD1cosθ=0FCD1+FBD1cos(36.869°)=060+0.8FBD1=0FBD1=75 kips(T)

Sketch the P system for Δ10 and Δ20 as shown in Figure 2.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 2

Sketch the released structure with unit member force in member AC as shown in Figure 3.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 3

Refer Figure 4.

Consider the force in the member AC is 1 kips.

The support reactions at A and B are zero as no external load acts on the truss.

Consider support A.

Apply Equation of Equilibrium,

∑Fx=0FACcosθ+FAB=01cos(36.869°)+FAB=0FAB=−0.8 kipsFAB=0.8 kips(C)

∑Fy=0FACsinθ+FAD=01sin(36.869°)+FAD=0FAD=−0.6 kipsFAD=0.6 kips(C)

Consider joint C.

Apply Equation of Equilibrium,

∑Fx=0−FCAcosθ−FCD=0−cos(36.869°)−FCD=0FCD=−0.8 kipsFCD=0.8 kips(C)

∑Fy=0−FCAsinθ−FCB=0−sin(36.869°)−FCB=0FCB=−0.6 kipsFCB=0.6 kips(C)

Consider joint D,

Apply Equation of Equilibrium,

∑Fx=0FCD+FBDcosθ=0−0.8+FBDcos(36.869°)=0−0.8+0.8FBD=0FBD=1 kips(T)

Sketch the Q system for Δ10 as shown in Figure 4.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 4

Sketch the Q system for Δ20,δ21,δ22 and P system for δ22 as shown in Figure 5.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 5

Refer Figure 5.

Find the support reaction at A as follows:

Applying Equation of Equilibrium,

∑Fx=0Ax−1=0Ax=1 kips

There is no external load at joint D and C and no vertical reaction at A and B.

The force in all the members of the truss except AB is zero.

Consider joint A.

Applying Equation of Equilibrium,

∑Fx=0Ax+FAB2=01+FAB2=0FAB2=−1 kipsFAB2=−1 kips

Find the deflection Δ10 as follows:

Δ10=FQFPLAE=[(−0.8)×60×(20 ft×12 in.1 ft)2×30,000×2+(−0.6)×45×(15 ft×12 in.1 ft)2×30,000+1×(−75)×(25 ft×12 in.1 ft)4×30,000]=−0.6525 in.

Find the deflection Δ20 as follows:

Δ20=FQFPLAE=−1×60×(20 ft×12 in.1 ft)2×30,000=−0.24 in.

Find the deflection δ11 as follows:

δ11=FQ2LAE=[(−0.8)2×(20 ft×12 in.1 ft)2×30,000×2+(−0.6)2×(15 ft×12 in.1 ft)2×30,000+12×(25 ft×12 in.1 ft)2×30,000+12×(25 ft×12 in.1 ft)4×30,000]=0.0148 in.

Find the deflection δ21 as follows:

δ21=FQFPLAE=(−1)(−0.8)×(20 ft×12 in.1 ft)2×30,000=0.0032 in.

Find the deflection δ12 as follows:

δ12=FQFPLAE=(−0.8)(−1)×(20 ft×12 in.1 ft)2×30,000=0.0032 in.

Find the deflection δ22 as follows:

δ22=FQFPLAE=(−1)(−1)×(20 ft×12 in.1 ft)2×30,000=0.004 in.

Show the compatibility Equation for Δ1,AC REL as follows:

Δ1,AC REL=0Δ10+δ11X1+δ12X2=0−0.6525+0.0148X1+0.0032X2=00.0148X1+0.0032X2=0.6525 (1)

Show the compatibility Equation for ΔBX as follows:

ΔBX=0Δ20+δ21X1+δ22X2=0−0.24+0.0032X1+0.004X2=00.0032X1+0.004X2=0.24 (2)

Solve Equation (1) and (2).

X1=37.62 kips

X2=29.9 kips

Find the reaction and bar forces in the members of the truss as shown in 6 and 7.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 6

Apply the sum shown in Figure 6 to get the final reactions and member forces shown in Figure 7.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 7

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 3

Question

Chapter 9, Problem 38P

To determine

Find the reactions and all bar forces for the truss.

Expert Solution & Answer

Explanation of Solution

Given information:

EI is constant.

The Young’s modulus E of the beam is 30,000 kips/in.2.

The area of all the bars are 2 in2.

Calculation:

Consider the force in the member AC and the horizontal reaction at support B are the redundant.

Remove the redundant to get the released structure.

Sketch the released structure with external loading as shown in Figure 1.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 1

Refer Figure 1.

Consider the force in the member AC as zero.

Find the value of the angle θ as follows:

tanθ=1520θ=tan−1(1520)θ=36.869°

Find the support reaction as follows:

Apply Equation of Equilibrium,

∑MA=0−60×15+By1×20=0By1=90020By1=45 kips

∑Fy=0Ay1+By1=0Ay1=−By1Ay1=−45 kips

∑Fx=0Ax1+60=0Ax1=−60 kips

Consider support A.

Apply Equation of Equilibrium,

∑Fy=0Ay1+FAD1=0FAD1=−Ay1FAD1=−(−45) kipsFAD1=45 kips(T)

∑Fx=0Ax1+FAB1=0FAB1=−Ax1FAB1=−(−60) kipsFAB1=60 kips(T)

Consider joint C.

Apply Equation of Equilibrium,

∑Fx=0−FCD1+60=0FCD1=60 kips(T)

∑Fy=0FBC1=0

Consider joint D,

Apply Equation of Equilibrium,

∑Fx=0FCD1+FBD1cosθ=0FCD1+FBD1cos(36.869°)=060+0.8FBD1=0FBD1=75 kips(T)

Sketch the P system for Δ10 and Δ20 as shown in Figure 2.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 2

Sketch the released structure with unit member force in member AC as shown in Figure 3.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 3

Refer Figure 4.

Consider the force in the member AC is 1 kips.

The support reactions at A and B are zero as no external load acts on the truss.

Consider support A.

Apply Equation of Equilibrium,

∑Fx=0FACcosθ+FAB=01cos(36.869°)+FAB=0FAB=−0.8 kipsFAB=0.8 kips(C)

∑Fy=0FACsinθ+FAD=01sin(36.869°)+FAD=0FAD=−0.6 kipsFAD=0.6 kips(C)

Consider joint C.

Apply Equation of Equilibrium,

∑Fx=0−FCAcosθ−FCD=0−cos(36.869°)−FCD=0FCD=−0.8 kipsFCD=0.8 kips(C)

∑Fy=0−FCAsinθ−FCB=0−sin(36.869°)−FCB=0FCB=−0.6 kipsFCB=0.6 kips(C)

Consider joint D,

Apply Equation of Equilibrium,

∑Fx=0FCD+FBDcosθ=0−0.8+FBDcos(36.869°)=0−0.8+0.8FBD=0FBD=1 kips(T)

Sketch the Q system for Δ10 as shown in Figure 4.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 4

Sketch the Q system for Δ20,δ21,δ22 and P system for δ22 as shown in Figure 5.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 5

Refer Figure 5.

Find the support reaction at A as follows:

Applying Equation of Equilibrium,

∑Fx=0Ax−1=0Ax=1 kips

There is no external load at joint D and C and no vertical reaction at A and B.

The force in all the members of the truss except AB is zero.

Consider joint A.

Applying Equation of Equilibrium,

∑Fx=0Ax+FAB2=01+FAB2=0FAB2=−1 kipsFAB2=−1 kips

Find the deflection Δ10 as follows:

Δ10=FQFPLAE=[(−0.8)×60×(20 ft×12 in.1 ft)2×30,000×2+(−0.6)×45×(15 ft×12 in.1 ft)2×30,000+1×(−75)×(25 ft×12 in.1 ft)4×30,000]=−0.6525 in.

Find the deflection Δ20 as follows:

Δ20=FQFPLAE=−1×60×(20 ft×12 in.1 ft)2×30,000=−0.24 in.

Find the deflection δ11 as follows:

δ11=FQ2LAE=[(−0.8)2×(20 ft×12 in.1 ft)2×30,000×2+(−0.6)2×(15 ft×12 in.1 ft)2×30,000+12×(25 ft×12 in.1 ft)2×30,000+12×(25 ft×12 in.1 ft)4×30,000]=0.0148 in.

Find the deflection δ21 as follows:

δ21=FQFPLAE=(−1)(−0.8)×(20 ft×12 in.1 ft)2×30,000=0.0032 in.

Find the deflection δ12 as follows:

δ12=FQFPLAE=(−0.8)(−1)×(20 ft×12 in.1 ft)2×30,000=0.0032 in.

Find the deflection δ22 as follows:

δ22=FQFPLAE=(−1)(−1)×(20 ft×12 in.1 ft)2×30,000=0.004 in.

Show the compatibility Equation for Δ1,AC REL as follows:

Δ1,AC REL=0Δ10+δ11X1+δ12X2=0−0.6525+0.0148X1+0.0032X2=00.0148X1+0.0032X2=0.6525 (1)

Show the compatibility Equation for ΔBX as follows:

ΔBX=0Δ20+δ21X1+δ22X2=0−0.24+0.0032X1+0.004X2=00.0032X1+0.004X2=0.24 (2)

Solve Equation (1) and (2).

X1=37.62 kips

X2=29.9 kips

Find the reaction and bar forces in the members of the truss as shown in 6 and 7.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 6

Apply the sum shown in Figure 6 to get the final reactions and member forces shown in Figure 7.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 7

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 4

Question

Chapter 9, Problem 38P

To determine

Find the reactions and all bar forces for the truss.

Expert Solution & Answer

Explanation of Solution

Given information:

EI is constant.

The Young’s modulus E of the beam is 30,000 kips/in.2.

The area of all the bars are 2 in2.

Calculation:

Consider the force in the member AC and the horizontal reaction at support B are the redundant.

Remove the redundant to get the released structure.

Sketch the released structure with external loading as shown in Figure 1.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 1

Refer Figure 1.

Consider the force in the member AC as zero.

Find the value of the angle θ as follows:

tanθ=1520θ=tan−1(1520)θ=36.869°

Find the support reaction as follows:

Apply Equation of Equilibrium,

∑MA=0−60×15+By1×20=0By1=90020By1=45 kips

∑Fy=0Ay1+By1=0Ay1=−By1Ay1=−45 kips

∑Fx=0Ax1+60=0Ax1=−60 kips

Consider support A.

Apply Equation of Equilibrium,

∑Fy=0Ay1+FAD1=0FAD1=−Ay1FAD1=−(−45) kipsFAD1=45 kips(T)

∑Fx=0Ax1+FAB1=0FAB1=−Ax1FAB1=−(−60) kipsFAB1=60 kips(T)

Consider joint C.

Apply Equation of Equilibrium,

∑Fx=0−FCD1+60=0FCD1=60 kips(T)

∑Fy=0FBC1=0

Consider joint D,

Apply Equation of Equilibrium,

∑Fx=0FCD1+FBD1cosθ=0FCD1+FBD1cos(36.869°)=060+0.8FBD1=0FBD1=75 kips(T)

Sketch the P system for Δ10 and Δ20 as shown in Figure 2.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 2

Sketch the released structure with unit member force in member AC as shown in Figure 3.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 3

Refer Figure 4.

Consider the force in the member AC is 1 kips.

The support reactions at A and B are zero as no external load acts on the truss.

Consider support A.

Apply Equation of Equilibrium,

∑Fx=0FACcosθ+FAB=01cos(36.869°)+FAB=0FAB=−0.8 kipsFAB=0.8 kips(C)

∑Fy=0FACsinθ+FAD=01sin(36.869°)+FAD=0FAD=−0.6 kipsFAD=0.6 kips(C)

Consider joint C.

Apply Equation of Equilibrium,

∑Fx=0−FCAcosθ−FCD=0−cos(36.869°)−FCD=0FCD=−0.8 kipsFCD=0.8 kips(C)

∑Fy=0−FCAsinθ−FCB=0−sin(36.869°)−FCB=0FCB=−0.6 kipsFCB=0.6 kips(C)

Consider joint D,

Apply Equation of Equilibrium,

∑Fx=0FCD+FBDcosθ=0−0.8+FBDcos(36.869°)=0−0.8+0.8FBD=0FBD=1 kips(T)

Sketch the Q system for Δ10 as shown in Figure 4.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 4

Sketch the Q system for Δ20,δ21,δ22 and P system for δ22 as shown in Figure 5.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 5

Refer Figure 5.

Find the support reaction at A as follows:

Applying Equation of Equilibrium,

∑Fx=0Ax−1=0Ax=1 kips

There is no external load at joint D and C and no vertical reaction at A and B.

The force in all the members of the truss except AB is zero.

Consider joint A.

Applying Equation of Equilibrium,

∑Fx=0Ax+FAB2=01+FAB2=0FAB2=−1 kipsFAB2=−1 kips

Find the deflection Δ10 as follows:

Δ10=FQFPLAE=[(−0.8)×60×(20 ft×12 in.1 ft)2×30,000×2+(−0.6)×45×(15 ft×12 in.1 ft)2×30,000+1×(−75)×(25 ft×12 in.1 ft)4×30,000]=−0.6525 in.

Find the deflection Δ20 as follows:

Δ20=FQFPLAE=−1×60×(20 ft×12 in.1 ft)2×30,000=−0.24 in.

Find the deflection δ11 as follows:

δ11=FQ2LAE=[(−0.8)2×(20 ft×12 in.1 ft)2×30,000×2+(−0.6)2×(15 ft×12 in.1 ft)2×30,000+12×(25 ft×12 in.1 ft)2×30,000+12×(25 ft×12 in.1 ft)4×30,000]=0.0148 in.

Find the deflection δ21 as follows:

δ21=FQFPLAE=(−1)(−0.8)×(20 ft×12 in.1 ft)2×30,000=0.0032 in.

Find the deflection δ12 as follows:

δ12=FQFPLAE=(−0.8)(−1)×(20 ft×12 in.1 ft)2×30,000=0.0032 in.

Find the deflection δ22 as follows:

δ22=FQFPLAE=(−1)(−1)×(20 ft×12 in.1 ft)2×30,000=0.004 in.

Show the compatibility Equation for Δ1,AC REL as follows:

Δ1,AC REL=0Δ10+δ11X1+δ12X2=0−0.6525+0.0148X1+0.0032X2=00.0148X1+0.0032X2=0.6525 (1)

Show the compatibility Equation for ΔBX as follows:

ΔBX=0Δ20+δ21X1+δ22X2=0−0.24+0.0032X1+0.004X2=00.0032X1+0.004X2=0.24 (2)

Solve Equation (1) and (2).

X1=37.62 kips

X2=29.9 kips

Find the reaction and bar forces in the members of the truss as shown in 6 and 7.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 6

Apply the sum shown in Figure 6 to get the final reactions and member forces shown in Figure 7.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 7

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 5

Chapter 9, Problem 38P

To determine

Find the reactions and all bar forces for the truss.

Expert Solution & Answer

Explanation of Solution

Given information:

EI is constant.

The Young’s modulus E of the beam is 30,000 kips/in.2.

The area of all the bars are 2 in2.

Calculation:

Consider the force in the member AC and the horizontal reaction at support B are the redundant.

Remove the redundant to get the released structure.

Sketch the released structure with external loading as shown in Figure 1.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 1

Refer Figure 1.

Consider the force in the member AC as zero.

Find the value of the angle θ as follows:

tanθ=1520θ=tan−1(1520)θ=36.869°

Find the support reaction as follows:

Apply Equation of Equilibrium,

∑MA=0−60×15+By1×20=0By1=90020By1=45 kips

∑Fy=0Ay1+By1=0Ay1=−By1Ay1=−45 kips

∑Fx=0Ax1+60=0Ax1=−60 kips

Consider support A.

Apply Equation of Equilibrium,

∑Fy=0Ay1+FAD1=0FAD1=−Ay1FAD1=−(−45) kipsFAD1=45 kips(T)

∑Fx=0Ax1+FAB1=0FAB1=−Ax1FAB1=−(−60) kipsFAB1=60 kips(T)

Consider joint C.

Apply Equation of Equilibrium,

∑Fx=0−FCD1+60=0FCD1=60 kips(T)

∑Fy=0FBC1=0

Consider joint D,

Apply Equation of Equilibrium,

∑Fx=0FCD1+FBD1cosθ=0FCD1+FBD1cos(36.869°)=060+0.8FBD1=0FBD1=75 kips(T)

Sketch the P system for Δ10 and Δ20 as shown in Figure 2.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 2

Sketch the released structure with unit member force in member AC as shown in Figure 3.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 3

Refer Figure 4.

Consider the force in the member AC is 1 kips.

The support reactions at A and B are zero as no external load acts on the truss.

Consider support A.

Apply Equation of Equilibrium,

∑Fx=0FACcosθ+FAB=01cos(36.869°)+FAB=0FAB=−0.8 kipsFAB=0.8 kips(C)

∑Fy=0FACsinθ+FAD=01sin(36.869°)+FAD=0FAD=−0.6 kipsFAD=0.6 kips(C)

Consider joint C.

Apply Equation of Equilibrium,

∑Fx=0−FCAcosθ−FCD=0−cos(36.869°)−FCD=0FCD=−0.8 kipsFCD=0.8 kips(C)

∑Fy=0−FCAsinθ−FCB=0−sin(36.869°)−FCB=0FCB=−0.6 kipsFCB=0.6 kips(C)

Consider joint D,

Apply Equation of Equilibrium,

∑Fx=0FCD+FBDcosθ=0−0.8+FBDcos(36.869°)=0−0.8+0.8FBD=0FBD=1 kips(T)

Sketch the Q system for Δ10 as shown in Figure 4.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 4

Sketch the Q system for Δ20,δ21,δ22 and P system for δ22 as shown in Figure 5.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 5

Refer Figure 5.

Find the support reaction at A as follows:

Applying Equation of Equilibrium,

∑Fx=0Ax−1=0Ax=1 kips

There is no external load at joint D and C and no vertical reaction at A and B.

The force in all the members of the truss except AB is zero.

Consider joint A.

Applying Equation of Equilibrium,

∑Fx=0Ax+FAB2=01+FAB2=0FAB2=−1 kipsFAB2=−1 kips

Find the deflection Δ10 as follows:

Δ10=FQFPLAE=[(−0.8)×60×(20 ft×12 in.1 ft)2×30,000×2+(−0.6)×45×(15 ft×12 in.1 ft)2×30,000+1×(−75)×(25 ft×12 in.1 ft)4×30,000]=−0.6525 in.

Find the deflection Δ20 as follows:

Δ20=FQFPLAE=−1×60×(20 ft×12 in.1 ft)2×30,000=−0.24 in.

Find the deflection δ11 as follows:

δ11=FQ2LAE=[(−0.8)2×(20 ft×12 in.1 ft)2×30,000×2+(−0.6)2×(15 ft×12 in.1 ft)2×30,000+12×(25 ft×12 in.1 ft)2×30,000+12×(25 ft×12 in.1 ft)4×30,000]=0.0148 in.

Find the deflection δ21 as follows:

δ21=FQFPLAE=(−1)(−0.8)×(20 ft×12 in.1 ft)2×30,000=0.0032 in.

Find the deflection δ12 as follows:

δ12=FQFPLAE=(−0.8)(−1)×(20 ft×12 in.1 ft)2×30,000=0.0032 in.

Find the deflection δ22 as follows:

δ22=FQFPLAE=(−1)(−1)×(20 ft×12 in.1 ft)2×30,000=0.004 in.

Show the compatibility Equation for Δ1,AC REL as follows:

Δ1,AC REL=0Δ10+δ11X1+δ12X2=0−0.6525+0.0148X1+0.0032X2=00.0148X1+0.0032X2=0.6525 (1)

Show the compatibility Equation for ΔBX as follows:

ΔBX=0Δ20+δ21X1+δ22X2=0−0.24+0.0032X1+0.004X2=00.0032X1+0.004X2=0.24 (2)

Solve Equation (1) and (2).

X1=37.62 kips

X2=29.9 kips

Find the reaction and bar forces in the members of the truss as shown in 6 and 7.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 6

Apply the sum shown in Figure 6 to get the final reactions and member forces shown in Figure 7.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 7

Answer 6

Chapter 9, Problem 38P

To determine

Find the reactions and all bar forces for the truss.

Expert Solution & Answer

Explanation of Solution

Given information:

EI is constant.

The Young’s modulus E of the beam is 30,000 kips/in.2.

The area of all the bars are 2 in2.

Calculation:

Consider the force in the member AC and the horizontal reaction at support B are the redundant.

Remove the redundant to get the released structure.

Sketch the released structure with external loading as shown in Figure 1.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 1

Refer Figure 1.

Consider the force in the member AC as zero.

Find the value of the angle θ as follows:

tanθ=1520θ=tan−1(1520)θ=36.869°

Find the support reaction as follows:

Apply Equation of Equilibrium,

∑MA=0−60×15+By1×20=0By1=90020By1=45 kips

∑Fy=0Ay1+By1=0Ay1=−By1Ay1=−45 kips

∑Fx=0Ax1+60=0Ax1=−60 kips

Consider support A.

Apply Equation of Equilibrium,

∑Fy=0Ay1+FAD1=0FAD1=−Ay1FAD1=−(−45) kipsFAD1=45 kips(T)

∑Fx=0Ax1+FAB1=0FAB1=−Ax1FAB1=−(−60) kipsFAB1=60 kips(T)

Consider joint C.

Apply Equation of Equilibrium,

∑Fx=0−FCD1+60=0FCD1=60 kips(T)

∑Fy=0FBC1=0

Consider joint D,

Apply Equation of Equilibrium,

∑Fx=0FCD1+FBD1cosθ=0FCD1+FBD1cos(36.869°)=060+0.8FBD1=0FBD1=75 kips(T)

Sketch the P system for Δ10 and Δ20 as shown in Figure 2.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 2

Sketch the released structure with unit member force in member AC as shown in Figure 3.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 3

Refer Figure 4.

Consider the force in the member AC is 1 kips.

The support reactions at A and B are zero as no external load acts on the truss.

Consider support A.

Apply Equation of Equilibrium,

∑Fx=0FACcosθ+FAB=01cos(36.869°)+FAB=0FAB=−0.8 kipsFAB=0.8 kips(C)

∑Fy=0FACsinθ+FAD=01sin(36.869°)+FAD=0FAD=−0.6 kipsFAD=0.6 kips(C)

Consider joint C.

Apply Equation of Equilibrium,

∑Fx=0−FCAcosθ−FCD=0−cos(36.869°)−FCD=0FCD=−0.8 kipsFCD=0.8 kips(C)

∑Fy=0−FCAsinθ−FCB=0−sin(36.869°)−FCB=0FCB=−0.6 kipsFCB=0.6 kips(C)

Consider joint D,

Apply Equation of Equilibrium,

∑Fx=0FCD+FBDcosθ=0−0.8+FBDcos(36.869°)=0−0.8+0.8FBD=0FBD=1 kips(T)

Sketch the Q system for Δ10 as shown in Figure 4.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 4

Sketch the Q system for Δ20,δ21,δ22 and P system for δ22 as shown in Figure 5.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 5

Refer Figure 5.

Find the support reaction at A as follows:

Applying Equation of Equilibrium,

∑Fx=0Ax−1=0Ax=1 kips

There is no external load at joint D and C and no vertical reaction at A and B.

The force in all the members of the truss except AB is zero.

Consider joint A.

Applying Equation of Equilibrium,

∑Fx=0Ax+FAB2=01+FAB2=0FAB2=−1 kipsFAB2=−1 kips

Find the deflection Δ10 as follows:

Δ10=FQFPLAE=[(−0.8)×60×(20 ft×12 in.1 ft)2×30,000×2+(−0.6)×45×(15 ft×12 in.1 ft)2×30,000+1×(−75)×(25 ft×12 in.1 ft)4×30,000]=−0.6525 in.

Find the deflection Δ20 as follows:

Δ20=FQFPLAE=−1×60×(20 ft×12 in.1 ft)2×30,000=−0.24 in.

Find the deflection δ11 as follows:

δ11=FQ2LAE=[(−0.8)2×(20 ft×12 in.1 ft)2×30,000×2+(−0.6)2×(15 ft×12 in.1 ft)2×30,000+12×(25 ft×12 in.1 ft)2×30,000+12×(25 ft×12 in.1 ft)4×30,000]=0.0148 in.

Find the deflection δ21 as follows:

δ21=FQFPLAE=(−1)(−0.8)×(20 ft×12 in.1 ft)2×30,000=0.0032 in.

Find the deflection δ12 as follows:

δ12=FQFPLAE=(−0.8)(−1)×(20 ft×12 in.1 ft)2×30,000=0.0032 in.

Find the deflection δ22 as follows:

δ22=FQFPLAE=(−1)(−1)×(20 ft×12 in.1 ft)2×30,000=0.004 in.

Show the compatibility Equation for Δ1,AC REL as follows:

Δ1,AC REL=0Δ10+δ11X1+δ12X2=0−0.6525+0.0148X1+0.0032X2=00.0148X1+0.0032X2=0.6525 (1)

Show the compatibility Equation for ΔBX as follows:

ΔBX=0Δ20+δ21X1+δ22X2=0−0.24+0.0032X1+0.004X2=00.0032X1+0.004X2=0.24 (2)

Solve Equation (1) and (2).

X1=37.62 kips

X2=29.9 kips

Find the reaction and bar forces in the members of the truss as shown in 6 and 7.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 6

Apply the sum shown in Figure 6 to get the final reactions and member forces shown in Figure 7.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 7

Answer 7

Chapter 9, Problem 38P

To determine

Find the reactions and all bar forces for the truss.

Answer 8

Expert Solution & Answer

Explanation of Solution

Given information:

EI is constant.

The Young’s modulus E of the beam is 30,000 kips/in.2.

The area of all the bars are 2 in2.

Calculation:

Consider the force in the member AC and the horizontal reaction at support B are the redundant.

Remove the redundant to get the released structure.

Sketch the released structure with external loading as shown in Figure 1.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 1

Refer Figure 1.

Consider the force in the member AC as zero.

Find the value of the angle θ as follows:

tanθ=1520θ=tan−1(1520)θ=36.869°

Find the support reaction as follows:

Apply Equation of Equilibrium,

∑MA=0−60×15+By1×20=0By1=90020By1=45 kips

∑Fy=0Ay1+By1=0Ay1=−By1Ay1=−45 kips

∑Fx=0Ax1+60=0Ax1=−60 kips

Consider support A.

Apply Equation of Equilibrium,

∑Fy=0Ay1+FAD1=0FAD1=−Ay1FAD1=−(−45) kipsFAD1=45 kips(T)

∑Fx=0Ax1+FAB1=0FAB1=−Ax1FAB1=−(−60) kipsFAB1=60 kips(T)

Consider joint C.

Apply Equation of Equilibrium,

∑Fx=0−FCD1+60=0FCD1=60 kips(T)

∑Fy=0FBC1=0

Consider joint D,

Apply Equation of Equilibrium,

∑Fx=0FCD1+FBD1cosθ=0FCD1+FBD1cos(36.869°)=060+0.8FBD1=0FBD1=75 kips(T)

Sketch the P system for Δ10 and Δ20 as shown in Figure 2.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 2

Sketch the released structure with unit member force in member AC as shown in Figure 3.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 3

Refer Figure 4.

Consider the force in the member AC is 1 kips.

The support reactions at A and B are zero as no external load acts on the truss.

Consider support A.

Apply Equation of Equilibrium,

∑Fx=0FACcosθ+FAB=01cos(36.869°)+FAB=0FAB=−0.8 kipsFAB=0.8 kips(C)

∑Fy=0FACsinθ+FAD=01sin(36.869°)+FAD=0FAD=−0.6 kipsFAD=0.6 kips(C)

Consider joint C.

Apply Equation of Equilibrium,

∑Fx=0−FCAcosθ−FCD=0−cos(36.869°)−FCD=0FCD=−0.8 kipsFCD=0.8 kips(C)

∑Fy=0−FCAsinθ−FCB=0−sin(36.869°)−FCB=0FCB=−0.6 kipsFCB=0.6 kips(C)

Consider joint D,

Apply Equation of Equilibrium,

∑Fx=0FCD+FBDcosθ=0−0.8+FBDcos(36.869°)=0−0.8+0.8FBD=0FBD=1 kips(T)

Sketch the Q system for Δ10 as shown in Figure 4.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 4

Sketch the Q system for Δ20,δ21,δ22 and P system for δ22 as shown in Figure 5.

Fundamentals Of Structural Analysis:, Chapter 9, Problem 38P , additional homework tip 5

Refer Figure 5.

Find the support reaction at A as follows:

Applying Equation of Equilibrium,

∑Fx=0Ax−1=0Ax=1 kips

There is no external load at joint D and C and no vertical reaction at A and B.

The force in all the members of the truss except AB is zero.

Consider joint A.

Applying Equation of Equilibrium,

∑Fx=0Ax+FAB2=01+FAB2=0FAB2=−1 kipsFAB2=−1 kips

Find the deflection Δ10 as follows:

Δ10=FQFPLAE=[(−0.8)×60×(20 ft×12 in.1 ft)2×30,000×2+(−0.6)×45×(15 ft×12 in.1 ft)2×30,000+1×(−75)×(25 ft×12 in.1 ft)4×30,000]=−0.6525 in.

Find the deflection Δ20 as follows:

Δ20=FQFPLAE=−1×60×(20 ft×12 in.1 ft)2×30,000=−0.24 in.

Find the deflection δ11 as follows:

δ11=FQ2LAE=[(−0.8)2×(20 ft×12 in.1 ft)2×30,000×2+(−0.6)2×(15 ft×12 in.1 ft)2×30,000+12×(25 ft×12 in.1 ft)2×30,000+12×(25 ft×12 in.1 ft)4×30,000]=0.0148 in.