EBK MECHANICS OF MATERIALS
EBK MECHANICS OF MATERIALS
7th Edition
ISBN: 8220102804487
Author: BEER
Publisher: YUZU
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Textbook Question
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Chapter 11.9, Problem 103P

11.103 and 11.104 Each member of the truss shown is made of steel and has a cross-sectional area of 500 mm2. Using E = 200 GPa, determine the deflection indicated.

11.103 Vertical deflection of joint B.

11.104 Horizontal deflection of joint B.

Chapter 11.9, Problem 103P, 11.103 and 11.104 Each member of the truss shown is made of steel and has a cross-sectional area of

Fig. P11.103 and P11.104

Expert Solution & Answer
Check Mark
To determine

Calculate the vertical deflection of joint B (δB).

Answer to Problem 103P

The vertical deflection of joint B (δB) is 0.1459mm_.

Explanation of Solution

Given information:

The Young’s modulus of the steel (E) is 200GPa.

The area of the each member (A) is 500mm2.

The vertical load act at the joint C (P) is 4.8kN.

The length of the member AD (LAD) is 2.4m.

The length of the member CD (LCD) is 2.5m.

Calculation:

Consider the vertical force (Q) at joint B.

Show the free body diagram of the truss members as in Figure 1.

EBK MECHANICS OF MATERIALS, Chapter 11.9, Problem 103P , additional homework tip  1

Refer to Figure 1.

Calculate the length of the member AB (LAB):

LAB=1.22+1.62=2m×103mm1m=2×103mm

The length of the member BD (LBD):

LBD=LAB=2×103mm

The length of the member AD (LAD):

LAD=2.4m×103mm1m=2.4×103mm

The length of the member CD (LCD):

LCD=2.5m×103mm1m=2.5×103mm

Calculate the length of the member BC (LBC):

LBC=1.22+(2.51.6)2=1.5m×103mm1m=1.5×103mm

Show the diagram of the joint C as in Figure 2.

EBK MECHANICS OF MATERIALS, Chapter 11.9, Problem 103P , additional homework tip  2

Here, FBC is the force act at the member BC and FCD is the force act at the member CD.

Refer to Figure 2.

Calculate the horizontal forces by applying the equation of equilibrium:

Sum of horizontal forces is equal to 0.

Fx=035FBC+FCD=0 (1)

Calculate the vertical forces by applying the equation of equilibrium:

Sum of vertical forces is equal to 0.

Fy=045FBC4.8=045FBC=4.8

FBC=4.8×54FBC=6kN

Calculate the force act at the member CD (FCD):

Substitute 6kN for FBC in Equation (1).

35(6)+FCD=0FCD=3×65FCD=3.6kN

Show the diagram of the joint B as in Figure 3.

EBK MECHANICS OF MATERIALS, Chapter 11.9, Problem 103P , additional homework tip  3

Here, FAB is the force act at the member AB and FBD is the force act at the member BD.

Refer to Figure 3.

Calculate the horizontal forces by applying the equation of equilibrium:

Sum of horizontal forces is equal to 0.

Fx=045FAB+45FBD3.6=045FAB+45FBD=3.6 (2)

Calculate the vertical forces by applying the equation of equilibrium:

Sum of vertical forces is equal to 0.

Fy=035FAB35FBD4.8Q=035(FABFBD)=4.8+Q

FABFBD=(4.8+Q)×53FAB=8+53Q+FBD

Calculate the force act at the member BD (FBD):

Substitute (8+53Q+FBD) for FAB in Equation (2).

45(8+53Q+FBD)+45FBD=3.66.4+43Q+45FBD+45FBD=3.685FBD=3.66.443Q85FBD=2.843Q

FBD=(2.843Q)×58FBD=7456Q

Calculate the force act at the member AB (FAB):

Substitute (7456Q) for FBD in Equation (2).

45FAB+45(7456Q)=3.645FAB7523Q=3.645FAB=3.6+75+23Q

FAB=(5+23Q)×54FAB=254+56Q

Show the diagram of the joint D as in Figure 4.

EBK MECHANICS OF MATERIALS, Chapter 11.9, Problem 103P , additional homework tip  4

Here, FAD is the force act at the member AD.

Refer to Figure 4.

Calculate the vertical forces by applying the equation of equilibrium:

Sum of vertical forces is equal to 0.

Fy=035FBD+FAD=0FAD=35FBD (3)

Calculate the force act at the member AD (FAD):

Substitute (7456Q) for FBD in Equation (3).

FAD=35(7456Q)FAD=2120+12Q

Partial differentiate the force act at the member AB (FAB) with respect to Q.

FABQ=0+56=56

Calculate the deflection of the member AB (δAB) using the formula:

δAB=FABLABAE×FABQ

Substitute (254+56Q) for FAB, 2×103mm for LAB, 500mm2, for A, 200GPa for E, and 56 for FABQ

δAB=(254+56Q)×2×103500×200GPa×1kN/mm21GPa×56=548+172Q

Partial differentiate the force act at the member AD (FAD) with respect to Q.

FADQ=0+12=12

Calculate the deflection of the member AD (δAD) using the formula:

δAD=FADLADAE×FADQ

Substitute (2120+12Q) for FAD, 2.4×103mm for LAD, 500mm2, for A, 200GPa for E, and 12 for FADQ.

δAD=(2120+12Q)×2.4×103500×200GPa×1kN/mm21GPa×12=635,000+3500Q

Partial differentiate the force act at the member BD (FBD) with respect to Q.

FBDQ=056=56

Calculate the strain energy of the member BD (δBD) using the formula:

δBD=FBDLBDAE×FBDQ

Substitute (7456Q) for FBD, 2×103mm for LBD, 500mm2, for A, 200GPa for E, and (56) for FBDQ.

δBD=(7456Q)×2×103500×200GPa×1kN/mm21GPa×(56)=7240+172Q

Partial differentiate the force act at the member BC (FBC) with respect to Q.

FBCQ=0

Calculate the strain energy of the member BC (δBC) using the formula:

δBC=FBCLBCAE×FBCQ

Substitute 6kN for FBC, 1.5×103mm for LBC, 500mm2, for A, 200GPa for E, and 0 for FBCQ.

δBC=6×1.5×103500×200GPa×1kN/mm21GPa×0=0

Partial differentiate the force act at the member CD (FCD) with respect to Q.

FCDQ=0

Calculate the strain energy of the member CD (δCD) using the formula:

δCD=FCDLCDAE×FCDQ

Substitute (3.6kN) for FBC, 2.5×103mm for LBC, 500mm2, for A, 200GPa for E, and 0 for FBCQ.

δBC=3.6×2.5×103500×200GPa×1kN/mm21GPa×0=0

Calculate the vertical deflection of joint B (δB):

δB=δAB+δAD+δBD+δBC+δCD

Substitute (548+172Q) for δAB, (635,000+3500Q) for δAD, (7240+172Q) for δBD, 0 for δBC, and 0 for δCD.

δB=[(548+172Q)+(635,000+3500Q)+(7240+172Q)+0+0]=0.14590.0338Q

Substitute 0 for Q.

δB=0.14590.0338(0)=0.1459mm

Hence the vertical deflection of joint B (δB) is 0.1459mm_.

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Chapter 11 Solutions

EBK MECHANICS OF MATERIALS

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