EBK MECHANICS OF MATERIALS
EBK MECHANICS OF MATERIALS
7th Edition
ISBN: 8220100257063
Author: BEER
Publisher: YUZU
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Chapter 9.6, Problem 144P
To determine

The magnitude (yK) and location (xK) of the largest downward deflection.

Expert Solution & Answer
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Answer to Problem 144P

The magnitude (yK) and location (xK) of the largest downward deflection are 0.212in.(downward)_ and 5.15ft_ respectively.

Explanation of Solution

Given information:

The elastic modulus (E) is 29×106psi.

The section of the beam is W12×26.

Calculation:

Refer Appendix C, “Properties of Rolled steel shapes”.

The moment of inertia (I) for the given section is 204in.4.

Use moment area method:

Show the free body diagram of the beam as in Figure 1.

EBK MECHANICS OF MATERIALS, Chapter 9.6, Problem 144P , additional homework tip  1

Determine the reaction of the support by taking moment at point B.

MB=0(RA×10)+[(5×4)(4+42)]+(8×4×42)=0RA=18.4kips

Determine the reaction of the support by considering the vertical equilibrium condition:

Fy=0RA+RB=(5×4)+(8×4)RA+RB=52

Substitute 18.4kips for RA.

RB+18.4=52RB=33.6kips

Show the moment (MEI) diagram for the given loading of the beam as in Figure 2.

EBK MECHANICS OF MATERIALS, Chapter 9.6, Problem 144P , additional homework tip  2

Calculate the moment (M1) using the formula:

M1=RA×10

Substitute 18.4kips for RA.

M1=18.4×10=184kipsft

Calculate the ratio of M1EI:

Ratio=M1EI

Substitute 184kipsft for M1.

M1EI=184kipsftEI

Calculate the area (A1+A2) due to the moment (M1) using the formula:

A1+A2=12bh

Here, b is the width of the triangle in area (A1+A2) and h is the height of the triangle in area (A1+A2).

Substitute 10ft for b and 184kipsftEI for h.

A1+A2=12×10×(184kipsftEI)=920EIkipsft2

Calculate the moment (M2) using the formula:

M2=RA×6ft

Substitute 18.4kips for RA.

M2=18.4×6ft=110.4kipsft

Calculate the ratio of M2EI:

Ratio=M2EI

Substitute 110.4kipsft for M2.

M2EI=110.4kipsftEI

Calculate the area (A1) due to the moment (M2) using the formula:

A1=12b1h1

Here, b1 is the width of the rectangle in area (A1) and h1 is the height of the rectangle in area (A1).

Substitute 6ft for b1 and 110.4kipsftEI for h1.

A1=12×6×(110.4kipsftEI)=331.2EIkipsft2

Calculate the moment (M3) using the formula:

M3=5×8×82=160kipsft

Calculate the ratio of M3EI using the relation:

Ratio=M3EI

Substitute 160kipsft for M3.

M3EI=160kipsftEI

Calculate the area (A3+A4) due to the moment (M3) using the formula:

A3+A4=13b3h3

Here, b3 is the width of the parabola in area (A3+A4) and h3 is the height of the parabola in area (A3+A4).

Substitute 8ft for b3 and 160kipsftEI for h3.

A3+A4=13×8×(160kipsftEI)=426.667EIkipsft2

Calculate the moment (M4):

M4=(5×4)42=40kipsft

Calculate the ratio of M4EI using the relation:

Ratio=M4EI

Substitute 40kipsft for M4.

M4EI=40kipsftEI

Calculate the area (A3) due to the moment (M4) using the formula:

A3=13b4h4

Here, b4 is the width of the parabola in area (A3) and h4 is the height of the parabola in area (A3).

Substitute 4ft for b4 and 40kipsftEI for h4.

A3=13×4×(40kipsftEI)=53.333EIkipsft2

Show the moment (M5EI) diagram for the given loading of the beam as in Figure 3.

EBK MECHANICS OF MATERIALS, Chapter 9.6, Problem 144P , additional homework tip  3

Calculate the moment (M5) using the formula:

M5=(85)kips/ft×4×42=24kipsft

Calculate the ratio of M5EI:

Ratio=M5EI

Substitute 24kipsft for M5.

M5EI=24kipsftEI

Calculate the area (A5) due to the moment (M5) using the formula:

A5=13b5h5

Here, b5 is the width of the parabola in area (A5) and h5 is the height of the parabola in area (A5).

Substitute 4ft for b5 and 24kipsftEI for h5.

A5=13×4×(-24kipsftEI)=32EIkipsft2

Calculate the slope at the end A related to the point B (tB/A) using the formula:

tB/A=[(A1+A2)×(13×10)]+[(A3+A4)×(14×8)]+[A5×(14×4)]

Substitute 920EIkipsft2 for A1+A2, 426.667EIkipsft2 for A3+A4, 32EIkipsft2 for A5, 29×103ksi for E, and 204in.4 for I.

tB/A=[920EI(13×10)]+[426.667EI(14×8)]+[32EI(14×4)]=3,066.667EI853.334EI32EI=3,066.667853.33432EI

=2,181.333kipsft229×103×204144in.2/ft2=53.096×103ft

Calculate the slope (θA) at point A using the formula:

θA=tB/AL

Substitute 53.096×103ft for tB/A and 10ft for L.

θA=53.096×103in.(10)in.=5.31×103rad

Calculate the slope (θE/A) using the formula:

θE/A=(A1+A3)

Substitute 331.2EI for A1, 53.333EI for A3, 29×103ksi for E, and 204in.4 for I

θE/A=(331.2EI+53.333EI)=129×103×204144in.2/ft2(331.253.33)=6.7636×103rad

Calculate the slope (θE) at point E using the formula:

θE=θA+θE/A

Substitute 5.31×103rad for θA and 6.7636×103rad for θE/A

θE=5.31×103+6.7636×103=1.4536×103rad

Let point K be location of the largest downward deflection.

Hence, the slope at point E is greater than zero, the point K of zeros slope lies to the left of the point E.

Calculate the moment (M6) using the relation:

M6=18.4×xK=18.4xK

Calculate the ratio of M6EI using the relation:

Ratio=M6EI

Substitute 18.4xK for M6.

M6EI=18.4xKEI

Calculate the moment (M7) using the relation:

M7=5×(xK2)×(xK2)2=5(xK2)22

Calculate the ratio of M7EI:

Ratio=M7EI

Substitute 5(xK2)22 for M7.

M7EI=5(xK2)22EI=5(xK2)22EI

Show the moment (MEI) diagram for section of beam AK as in Figure 4.

EBK MECHANICS OF MATERIALS, Chapter 9.6, Problem 144P , additional homework tip  4

Calculate the area (A6) using the formula:

A6=12(M6EI)xK

Substitute 18.4xKEI for (M6EI).

A6=12×18.4xKEI×xK=9.2xK2EI

Calculate the area (A7) using the formula:

A7=13(M7EI)(xK2)

Substitute 5(xK2)22EI for M7EI.

A7=135(xK2)22EI(xK2)=5(xK2)36EI

Calculate the slope (θK) using the formula:

θK=θA+θK/A=θA+A6+A7

Substitute 9.2xK2EI for A6, 5(xK2)36EI for A7 and  218.134EI for θA.

θK=218.134EI+9.2xK2EI5(xK2)36EI0=1EI(218.134+9.2xK256(xK2)3)0=218.134+9.2xK256(xK2)3 (1)

Differentiate the Equation (1).

f(xK)=218.134+9.2xK256(xK2)3 (2)

dfdxK=0+18.4xK2.5(xK2)2 (3).

Solve the value xK by iteration.

Iteration 1:

Substitute 5 for xK in Equation (2).

f(5)=218.134+9.2(5)256(52)3=10.634

Substitute 5 for xK in Equation (3).

dfdxK=0+18.4(5)2.5(52)2=69.5

Iteration 2:

Calculate the value xK using the relation:

xK=(xK)0f(dfdxK)

Substitute 5 for (xK)0, 10.634 for f and 69.5 for (dfdxK).

xK=510.63469.5=5+0.153=5.153

Similarly calculate the value xK and tabulated in the below Table 1.

xKf(dfdxK)
5-10.63469.5
5.153-0.03769.962
5.0005-10.59769.5.02
5.15250.001 

The value of xK is 5.1525ft.

Calculate the slope at the end A related to the point K (tA/K) using the formula:

(tA/K)=A6(23xK)+A7(2+34(xK2))

Substitute 9.2xK2EI for A6, 5(xK2)36EI for A7, 5.1525ft for xK, 29×103ksi for E and 204in.4 for I.

(tA/K)=9.2×5.15252EI(23×5.1525)5(5.15252)36EI×(2+34(5.15252))=838.978EI113.949EI=725.02929×103×204144in.2/ft2

=0.017648ft=0.017648ft×12in.1ft=0.212in.

Calculate the magnitude (yK) of the largest downward deflection using the relation:

yK=tA/K

Substitute 0.212in. for tA/K.

yK=0.212in.

Thus, the magnitude (yK) and location (xK) of the largest downward deflection are 0.212in.(downward)_ and 5.15ft_ respectively.

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Chapter 9 Solutions

EBK MECHANICS OF MATERIALS

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