Mechanics of Materials (MindTap Course List)
Mechanics of Materials (MindTap Course List)
9th Edition
ISBN: 9781337093347
Author: Barry J. Goodno, James M. Gere
Publisher: Cengage Learning
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Concept explainers

Buckling of columns
The column is described as a vertical member of the structure that carries an axial compressive load, and buckling is a lateral deformation of the column under the application of load.
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Textbook Question
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Chapter 11, Problem 11.4.10P

The roof beams of a warehouse are supported by pipe columns (see figure) having an outer diameter d2= 100 mm and inner diameter d2, = 90mm. The columns have a length L = 4.0 m, modulus E = 210 GPa, and fixed supports at the base.

Calculate the critical load Pcrof one of the columns using the following assumptions: (a) the upper end is pinned and the beam prevents horizontal displacement; (b) the upper end is fixed against rotation and the beam prevents horizontal displacement; (c) the upper end is pinned, but the beam is free to move horizontally; and (d) the upper end is fixed against rotation, but the beam is free to move horizontally.

  Chapter 11, Problem 11.4.10P, The roof beams of a warehouse are supported by pipe columns (see figure) having an outer diameter

i.

Expert Solution
Check Mark
To determine

The critical load when the upper end is pinned and the beam prevents horizontal displacement.

Answer to Problem 11.4.10P

The critical load when the upper end is pinned and the beam prevents horizontal displacement is 447 kN

Explanation of Solution

Given:

E=210 GPa

L= 4 m

d1= 90 mm

d2= 100 mm

Concept Used:

  Momentofinteriaofthecolumn,I=π(d04di4)64Thecriticalloadofthecolumn,Pcr=π2EILeffective2Where,I=momentofinertiaE=modulusofelasticity

Calculation:

  Momentofinteriaofthecolumn,I=π(d04di4)64I=π(1004904)64I=1688×103mm4Thecriticalloadofthecolumn,Pcr=π2EILeffective2ForpinnedpinnedendcoditionLeffective=0.699LPcr=π2×210×103×1688×103(0.699×4000)2Pcr=447kN

Conclusion:

The critical load for the pinned-pinned condition is 447 kN

ii.

Expert Solution
Check Mark
To determine

The critical load when the upper end is fixed for rotation and the beam prevents horizontal displacement.

Answer to Problem 11.4.10P

The critical load when the upper end is fixed for rotation and the beam prevents horizontal displacement is 875 kN

Explanation of Solution

Given:

E=210 GPa

L= 4 m

d1= 90 mm

d2= 100 mm

Concept Used:

  Momentofinteriaofthecolumn,I=π(d04di4)64Thecriticalloadofthecolumn,Pcr=π2EILeffective2Where,I=momentofinertiaE=modulusofelasticity

Calculation:

  Momentofinteriaofthecolumn,I=π(d04di4)64I=π(1004904)64I=1688×103mm4Thecriticalloadofthecolumn,Pcr=π2EILeffective2ForfixedfreeendcoditionLeffective=L2Pcr=π2×210×103×1688×103×4(4000)2Pcr=875kN

Conclusion:

The critical load when the upper end is fixed for rotation and the beam prevents horizontal displacement is 875 kN

iii.

Expert Solution
Check Mark
To determine

The critical load when the upper end is pinned but beam free to move horizontally.

Answer to Problem 11.4.10P

The critical load when the upper end is pinned but beam free to move horizontally is 54.7 kN

Explanation of Solution

Given:

E=210 GPa

L= 4 m

d1= 90 mm

d2= 100 mm

Concept Used:

  Momentofinteriaofthecolumn,I=π(d04di4)64Thecriticalloadofthecolumn,Pcr=π2EILeffective2Where,I=momentofinertiaE=modulusofelasticity

Calculation:

  Momentofinteriaofthecolumn,I=π(d04di4)64I=π(1004904)64I=1688×103mm4Thecriticalloadofthecolumn,Pcr=π2EILeffective2ForfixedpinnedendcoditionLeffective=2LPcr=π2×210×103×1688×103(2×4000)2Pcr=54.7kN

Conclusion:

The critical load when the upper end is pinned but beam free to move horizontally is 54.7 kN .

iv.

Expert Solution
Check Mark
To determine

The critical load when the upper end is fixed under rotation but the beam is free to move horizontally.

Answer to Problem 11.4.10P

The critical load when the upper end is fixed under rotation but the beam is free to move horizontally is 219 kN

Explanation of Solution

Given:

E=210 GPa

L= 4 m

d1= 90 mm

d2= 100 mm

Concept Used:

  Momentofinteriaofthecolumn,I=π(d04di4)64Thecriticalloadofthecolumn,Pcr=π2EILeffective2Where,I=momentofinertiaE=modulusofelasticity

Calculation:

  Momentofinteriaofthecolumn,I=π(d04di4)64I=π(1004904)64I=1688×103mm4Thecriticalloadofthecolumn,Pcr=π2EI4×Leffective2ForpinnedpinnedendcoditionLeffective=L2Pcr=π2×210×103×1688×103(4000)2Pcr=219kN

Conclusion:

The critical load when the upper end is fixed under rotation but the beam is free to move horizontally is 219 kN.

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Chapter 11 Solutions

Mechanics of Materials (MindTap Course List)

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Column buckling; Author: Amber Book;https://www.youtube.com/watch?v=AvvaCi_Nn94;License: Standard Youtube License