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Design of Steel Beams Dr. Bashar Behnam
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General When a beam bends, the compression region above the neutral axis is analogous to a column and it will buckle if the member is slender enough. The compression portion/region of the cross section is restrained by the tension portion. The outer deflection (flexural buckling) is accompanied by twisting (torsion)
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Lateral-Torsional Buckling
This form of instability is called lateral-torsional buckling (LTB). Lateral-Torsional buckling can be prevented by bracing the beam against twisting at sufficiently close intervals. This can be accomplished two different types of stability bracing.
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Stability Bracing There are two types of stability bracing
Lateral bracing: X-bracing Concrete deck Torsional bracing: Cross frame Diaphragm
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Lateral bracing X-Bracing Concrete Deck
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Torsional bracing Cross-Frame Diaphragm
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Failure Modes There are four failure modes
The cross section of the beam becomes fully plastic. Lateral-torsional buckling (LTB), either elastically or inelastically. Flange local buckling (FLB), either elastically or inelastically. Web local buckling (WLB), either elastically or inelastically.
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Classification of Shapes
AISC Manual (American institute of Steel Construction) classifies cross-sectional shapes as: Compact Noncompact Slender
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The unbraced length The unbraced length Lb is the distance between points of lateral support, or bracing. The moment strength of compact shapes is function of the unbraced length, Lb.
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Nominal Flexural Strength
If the unbraced length, no longer than Lp, the beam is considered to have full lateral support and the nominal flexural strength can be calculated
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Nominal Flexural Strength
If Lb is greater than Lp but less than or equal to the parameter Lr, then the strength is based on inelastic LTB.
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Nominal Flexural Strength
If Lb is greater than Lr, the strength is based on elastic LTB.
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