Topic%20 compression

Dr. Seshu Adluri

Structural Steel Design
Compression Members

Columns
in
Buildings

Compression members -Dr. Seshu Adluri

Columns in Buildings


Column
supports


Compression members in trusses


Compression members in OWSJ


Compression members in bridges

Howrah bridge, Kolkata, India


Compression members in towers

Eiffel Tower (1887 - 89)

The new Tokyo Tower is set to be completed in 2011. It will stand 610m high.


Compression in
equipment


Introduction
Steel Compression members
Building columns
Frame Bracing
Truss members (chords and bracing)
Useful in pure compression as well as in beam-
columns
Design Clauses: CAN/CSA-S16
Over-all strength as per Clause 13.3
Local buckling check: Clause 11 (Table 1)
Built-up members: Clause 19


Column erection


Different
column c/s
shapes


Instability and bifurcation

Stable, neutral
and unstable
equilibriums


Buckling


Instability and bifurcation
Instability effect
To compress or not to compress?
Energy considerations

Long column


Compression terminology -review
Moment of inertia I x = ∫ y 2 dA
A
Parallel axis theorem I = I + Ax
x′ x
2

Radius of gyration r=
I
A
Effective length kL Symmetric (major)
Slenderness ratio kL/r axis
h
Principal axes (major and minor)
Critical Load Pcr b
Unsymmetric
Factored compressive strength, Cr (minor) axis


Compression members
Bucking
Elastic (Euler) buckling
Inelastic buckling
Buckling modes
Overall buckling
Flexural buckling
Torsional buckling
Torsional-flexural buckling
Local buckling


Elastic Buckling
Equilibrium equation
Internal moment + applied moment = 0

d 2w
EI 2 + Pw = 0; w = 0 @ y = 0; w=0@ y = L
dx
πx
Solution : w = A sin satisfies the b.c.
L
Substituting int o the differential equation,
  π 2 
EI  − A  sin πx  + P A sin πx  = 0
 
 L L   L

2
π 
−   EI + P = 0
L
π 2 EI
Pcr = 2
L

Inelastic Buckling


Compression members
σpl = σy - κΛ/ρes

Moment of inertia σpl = (0.5~1.0)σy
Radius of gyration
Effective length
Slenderness ratio


Effective length factors
Different end
conditions
give different
lengths for
equivalent
half-sine wave


Theoretical Effective length factors


Effective
length
factors

US
practice


Effective lengths in different
directions


Effective length factors
Canadian practice

k = .65 k = .8 k = 1.2 k = 1.0 k = 2.0 k = 2.0


US
recommended Engrg. Eff.
Boundary Theoretical Eff.
values
Length
Conditions Length, LeffT
LeffE

Free-Free L (1.2·L)

Hinged-Free L (1.2·L)

Hinged-Hinged
L L
(Simply-Supported)

Guided-Free 2·L (2.1·L)

Guided-Hinged 2·L 2·L

Guided-Guided L 1.2·L

Clamped-Free
2·L 2.1·L
(Cantilever)

Clamped-Hinged 0.7·L 0.8·L

Clamped-Guided L 1.2·L

Clamped-Clamped 0.5·L 0.65·L

Canadian
recommended Engrg. Eff.
Boundary Theoretical Eff.
values –
Length
Appendix F Conditions Length, LeffT
CAN/CSA/S16-01
LeffE

Free-Free L (1.2·L)

Hinged-Free L (1.2·L)

Hinged-Hinged
L L
(Simply-Supported)

Guided-Free 2·L (2.0·L)

Guided-Hinged 2·L 2·L

Guided-Guided L 1.2·L

Clamped-Free
2·L 2.0·L
(Cantilever)

Clamped-Hinged 0.7·L 0.8·L

Clamped-Guided L 1.2·L

Clamped-Clamped 0.5·L 0.65·L

Effective lengths in frame columns


Real columns -Factors for consideration
Partially plastic
buckling
Initial out-of-
straightness
(L/2000 to L/1000)


Real columns -
Factors for
consideration
Residual stresses in
Hot-rolled shapes
(idealized)


Real
columns -
Factors for
consideration

Residual stresses
in Hot-rolled
shapes (idealized)


Perfect column failure


Practical column failure


Column curve


Intermediate
Short Column Long Column
Column
(Strength (Elastic Stability
(Inelastic
Limit) Limit)
Material Stability Limit)

Slenderness Ratio ( kL/r = Leff / r)

Structural Steel kL/r < 40 40 < kL/r < 150 kL/r > 150

Aluminum Alloy
kL/r < 9.5 9.5 < kL/r < 66 kL/r > 66
AA 6061 - T6

Aluminum Alloy
kL/r < 12 12 < kL/r < 55 kL/r > 55
AA 2014 - T6

Wood kL/r < 11 11 < kL/r < (18~30) (18~30)<kL/r<50


Over-all buckling
Flexural
Torsional
Torsional-flexural


Flexural Buckling
About minor axis (with
higher kL/R) for
doubly symmetric
shapes
About minor axis (the
unsymmetric axis) for
singly symmetric
shapes

1964 Alaska quake, EqIIS collection


Flexural Buckling


Torsional buckling
Short lengths
Usually kL/r less than
approx. 50
doubly symmetric sections
Wide flange sections, cruciform
sections, double channels,
point symmetric sections, ….
Not for closed sections
such as HSS since they are
very strong in torsion


Torsion
Torque is a moment that causes twisting along the length of a bar.
The twist is also the torsional deformation. For a circular shaft, the
torque (or torsional moment) rotates each c/s relative to the nearby
c/s.


Torsional
deformation


Torsion of non-circular sections
Torsion of non-circular sections involves torsional shear
and warping.
Torsional shear needs the use of torsion constant J.
J is similar to the use of polar moment of inertia for circular
shafts.
J=Σbt3/3
Warping calculation needs the use od the constant Cw.
Both J and Cw are listed in the Handbook
In addition, we need to use the effective length in torsion
(kzLz). Usually, kz is taken as 1.0


Torsional buckling of open sections
Buckling in pure torsional mode (not needed for HSS or closed
sections):
Kz is normally taken as 1.0.
Cw, J, rx, ry are given in the properties tables, x and y are the axes of
symmetry of the section.
E= 200 000 MPa (assumed), G=77 000 MPa (assumed).

1  π 2 ECw 
Fez =  + GJ  ro2 = xo + yo + rx2 + ry2
2 2
Aro  ( K z L )
2 2

 
Fy
( )
−1 n
λ= Cr = φ AFy 1 + λ 2n
Fe


Shear centre
Sections always rotate about shear centre
Shear centre lies on the axis of symmetry


Torsional-
flexural
buckling
For of singly
symmetric
sections, about
the major axis
For
unsymmetric
sections, about
any axis
Rotation is
always about
shear centre


Torsional-flexural buckling


Shear flow


Shear centre


Shear flow effect


Local (Plate) buckling


Plate buckling


Plate buckling
Effective width concept


Plate buckling
Different types of buckling
depending on
b/t ratio
end conditions for plate
segments
Table 1 for columns
Table 2 for beams and
beam-columns


Web buckling


Plate buckling
b/t ratio effect


Built-up columns
Two or more sections
Stitch bolts
Batten plates
Lacing
Combined batten &
lacing
Perforated cover
plates


Built-up columns
Two or more sections
Stitch bolts
Batten plates
Lacing
Combined


Built-up
columns


Built-up
columns

Closely spaced
channels


Built-up columns
Built-up member
buckling is somewhat
similar to frame
buckling
Batten acts like beams
Battens get shear and
moment due to the
bending of the frame
like built-up member at
the time of buckling


Battened column


Built-up columns
Design as per normal
procedure
Moment of inertia
about the axis which
shifts due to the
presence of gap
needs parallel axis
theorem
Effective slenderness
ratio as per Cl. 19.1


References
AISC Digital Library (2008)
ESDEP-the European Steel Design Education Programme - lectures
Earthquake Image Information System
Hibbeler, R.C., 2008. “Mechanics of Solids,” Prentice-Hall


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