Mechanics of Materials, SI Edition
Mechanics of Materials, SI Edition
9th Edition
ISBN: 9781337093354
Author: Barry J. Goodno, James M. Gere
Publisher: Cengage Learning
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Chapter 8, Problem 8.4.19P

A W 12 X 14 wide-flange beam (see Table F-l(a), Appendix F) is simply supported with a span length of 120 in. (see figure). The beam supports two anti-symmetrically placed concentrated loads of 7,5 kips each.

At a cross section located 20 in. from the right-hand support, determine the principal stresses (7]and (7\ and the maximum shear stress Tmaw at each of the following locations: (a) the top of the beam, (b) the top of the web, and (c) the neutral axis,

  Chapter 8, Problem 8.4.19P, A W 12 X 14 wide-flange beam (see Table F-l(a), Appendix F) is simply supported with a span length

(a).

Expert Solution
Check Mark
To determine

To find: Values of principal stresses and maximum shear stress at top of beam.

Answer to Problem 8.4.19P

Values of principal stress :

σ1=3.46 ksi ,σ2=0 ksi

Maximum shear stressτmax=1.73 ksi

Explanation of Solution

Given Information:

Beam lengthL=10 ft=120 in

Point loadP=7.5 kips

Dimensions of beam,

h=11.91b=3.97t=0.2h1=11.46

Concept Used:

Bending stressσx=MyI

Shear stressτxy=VQIt

Principal normal stressesσ1,2=σx+σy2±(σxσy2)2+τxy2

Maximum shear stressτmax=(σxσy2)2+τxy2

Mechanics of Materials, SI Edition, Chapter 8, Problem 8.4.19P , additional homework tip 1

From equilibrium:

RB×1207.5×80+7.5×40=0RB=2.5 kips

So, bending moment at pointC is :

  M=RB×20=2.5×20=50 kip-in

Shear force at pointC is

  V=RB=2.5 kip

Moment of inertia:

  I=bh312bh1312+th1312 about the neutral z axis.I=3.97×11.913123.97×11.46312+0.2×11.46312I=86.074 in4

First moment of area at the top of beam shall be zero,Q=0 m3

So, bending stress at top:

σx=MyIσx=50×5.95586.1σx=3.46 ksi

And shear stress at that point:

τ=VQItτ=0 ksi

For this situation no stress iny direction soσy=0

Values of normal stress is given by following equation:

σ1,2=σx+σy2±(σxσy2)2+τxy2σ1,2=3.46+02±(3.4602)2+02σ1,2=1.73±1.73σ1=1.73+1.73=3.46 ksiσ2=1.731.73=0 ksi

Maximum shear stress:

τmax=(σxσy2)2+τxy2τmax=(3.4602)2+02τmax=1.73 ksi

Conclusion:

Hence, we get:

Values of principal stress:

σ1=3.46 ksi ,σ2=0 ksi

Maximum shear stressτmax=1.73 ksi

(b).

Expert Solution
Check Mark
To determine

To find: Values of principal stresses and maximum shear stress at top of web.

Answer to Problem 8.4.19P

Values of principal stress:

σ1=3.5 ksi ,σ2=0.165 ksi

Maximum shear stressτmax=1.83 ksi

Explanation of Solution

Given Information:

Beam lengthL=10 ft=120 in

Point loadP=7.5 kips

Dimensions of beam,

h=11.91b=3.97t=0.2h1=11.46

Concept Used:

Bending stressσx=MyI

Shear stressτxy=VQIt

Principal normal stressesσ1,2=σx+σy2±(σxσy2)2+τxy2

Maximum shear stressτmax=(σxσy2)2+τxy2

Mechanics of Materials, SI Edition, Chapter 8, Problem 8.4.19P , additional homework tip 2

From equilibrium,

RB×1207.5×80+7.5×40=0RB=2.5 kips

So, bending moment at pointC is :

  M=RB×20=2.5×20=50 kip-in

Shear force at pointC is

  V=RB=2.5 kip

Moment of inertia:

  I=bh312bh1312+th1312 about the neutral z axis.I=3.97×11.913123.97×11.46312+0.2×11.46312I=86.074 in4

First moment of area of flange:

  Q=A1×y1=3.97×11.9111.462×(11.462+11.9111.464)=5.22 in3

So, bending stress at top of web:

σx=MyIσx=50×5.7386.1σx=3.33 ksi

And shear stress at that point:

τxy=VQItτxy=2.5×5.2286.1×0.2τxy=0.76 ksi

For this situation no stress iny direction soσy=0

Principal normal stresses are given by following equation,

σ1,2=σx+σy2±(σxσy2)2+τxy2σ1,2=3.33+02±(3.3302)2+0.762σ1,2=1.665±1.83σ1=1.665+1.83=3.5 ksiσ2=1.6651.83=0.165 ksi

Maximum shear stress,

τmax=(σxσy2)2+τxy2τmax=(3.3302)2+0.762τmax=1.83 ksi

Conclusion:

Hence we get,

Principal stresses

σ1=3.5 ksi ,σ2=0.165 ksi

Maximum shear stressτmax=1.83 ksi

(c).

Expert Solution
Check Mark
To determine

Find principal stresses and maximum shear stress at neutral axis.

Answer to Problem 8.4.19P

Principal stresses

σ1=4.7 ksi ,σ2=4.7 ksi

Maximum shear stressτmax=4.7 ksi

Explanation of Solution

Given Information:

Beam lengthL=10 ft=120 in

Point loadP=7.5 kips

Dimensions of beam,

h=11.91b=3.97t=0.2h1=11.46

Concept Used:

Bending stressσx=MyI

Shear stressτxy=VQIt

Principal normal stressesσ1,2=σx+σy2±(σxσy2)2+τxy2

Maximum shear stressτmax=(σxσy2)2+τxy2

Mechanics of Materials, SI Edition, Chapter 8, Problem 8.4.19P , additional homework tip 3

From equilibrium,

RB×1207.5×80+7.5×40=0RB=2.5 kips

So bending moment at pointC is

  M=RB×20=2.5×20=50 kip-in

Shear force at pointC is

  V=RB=2.5 kip

Moment of inertia,

  I=bh312bh1312+th1312 about the neutral z axis.I=3.97×11.913123.97×11.46312+0.2×11.46312I=86.074 in4

First moment of area for the section above the neutral axis,

  Q=A1×y1+A2×y2Q=3.97×11.9111.462×(11.462+11.9111.464)+0.2×11.462×(11.464)Q=8.5 in3

So bending stress at neutral axis,

σx=M(y=0)Iσx=0 ksi

And shear stress at that point,

τxy=VQItτxy=2.5×8.586.1×0.2τxy=1.234 ksi

For this situation no stress iny direction soσy=0

Principal normal stresses are given by following equation,

σ1,2=σx+σy2±(σxσy2)2+τxy2σ1,2=0+02±(002)2+1.2342σ1,2=0±1.234σ1=0+1.234=1.234 ksiσ2=01.234=1.234 ksi

Maximum shear stress,

τmax=(σxσy2)2+τxy2τmax=(002)2+1.2342τmax=1.234 ksi

Conclusion:

Hence we get,

Principal stresses

σ1=1.234 ksi ,σ2=1.234 ksi

Maximum shear stressτmax=1.234 ksi

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Chapter 8 Solutions

Mechanics of Materials, SI Edition

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