CTC 422 Design of Steel Structures - PowerPoint PPT Presentation

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CTC 422 Design of Steel Structures

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CTC 422 Design of Steel Structures Beams - Flexure – PowerPoint PPT presentation

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Title: CTC 422 Design of Steel Structures


1
CTC 422Design of Steel Structures
  • Beams - Flexure

2
Objectives of Structural Design
  • Structure is adequate to support loads which will
    be applied during its life
  • Strength provided strength required
  • Structure will meet serviceability requirements
  • Deflection
  • Vibration
  • Structure will meet functional requirements
  • Structure will meet economic requirements

3
Beam Design
  • Student Objectives
  • Analyze a beam to calculate load, shear, moment
    and deflection and to determine if a given beam
    is adequate
  • Design (select) a beam to safely to support a
    load considering moment, shear and deflection

4
Beam Design
  • Beam
  • A structural member which carries loads applied
    perpendicular to its longitudinal axis
  • These loads cause shear and bending (moment)
  • Different terms used for beams depending on
    application or location
  • Girder, stringer, joist, lintel, spandrel,
    purlin, girt
  • Behavior of all is the same.
  • All are beams

5
Load and Resistance Factor Design - LRFD
  • Design strength Required strength
  • FRn Ru
  • For bending
  • Fb Mn Mu
  • Where
  • Mn Nominal moment strength
  • Fb Strength reduction factor for bending 0.9
  • Mu Required moment strength based on factored
    loads

6
Load and Resistance Factor Design - LRFD
  • Nominal moment capacity, Mn, depends on the
    failure mechanism of the beam
  • Beam can fail by
  • Full yielding of the cross-section
  • Lateral torsional buckling (LTB)
  • Can be inelastic or elastic buckling
  • Flange local buckling (FLB)
  • Web local buckling (WLB)
  • Failure mechanism is related to
  • Lateral bracing of the beam
  • Whether or not the beam cross-section is compact

7
Failure Mechanism and Nominal Moment Capacity, Mn
  • If beam remains stable up to its full plastic
    moment capacity
  • Failure is by yielding of the full section
  • Mn Mp
  • Instability could be overall beam instability
  • Lateral torsional buckling (elastic or inelastic)
  • Prevented by adequate lateral bracing of the
    beams compression flange
  • Instability could also be local instability
  • Flange local buckling or web local buckling
  • Dependent on width / thickness ratios of
    compression elements
  • Compactness, non-compactness or slenderness of
    section

8
Compactness
  • Structural shapes are classified as compact,
    non-compact, or slender
  • Compact
  • Section reaches its full strength (yield) before
    local buckling occurs
  • Strength of section is governed by material
    strength
  • Non-compact
  • Only a portion of the cross-section reaches its
    full strength (yield) before local buckling
    occurs
  • Slender
  • Cross-section does not yield before local
    buckling occurs
  • Strength is governed by buckling
  • Compactness, non-compactness, or slenderness is a
    property of the cross-section itself
  • A function of the width / thickness ratios of its
    flanges and its web
  • Flange width / thickness bf / 2tf
  • Web width / thickness h / tw

9
Compactness
  • Classification is given in Table B4.1
  • Notation
  • ? width / thickness ratio
  • ?p upper limit for compact category
  • ?r upper limit for non-compact category
  • If ? ?p and the flange is continuously attached
    to the web, the shape is compact
  • If ?p ? ?r, the shape is non-compact
  • If ? gt ?r, the shape is slender
  • Category is based on the worst width / thickness
    ratio
  • Example If web is compact and flange is
    non-compact, section is classified as non-compact
  • Most standard W, M, S, and C sections are compact
  • A few are non-compact because of their flanges,
    but none are slender

10
Bending Strength of Compact Shapes
  • Moment strength of a compact shape is a function
    of, Lb, the unbraced length of its compression
    flange
  • Lb distance between points braced against
    lateral displacement of compression flange
  • Lp limiting laterally unbraced length for limit
    state of yielding
  • Lr limiting laterally unbraced length for limit
    state of inelastic lateral torsional buckling
  • Compression flange may be braced by
  • Perpendicular framing
  • Steel roof deck or floor deck
  • Concrete slab
  • Cross-bracing

11
Bending Strength of Compact Shapes
  • If the compression flange is continuously braced
    (Lb Lp)
  • Failure will be by yielding at full plastic
    moment
  • Nominal moment capacity, Mn Mp Fy Zx (AISC
    Eq. F2-1)
  • Design strength Fb Mn Fb Mp
  • For unbraced length Lb gt Lp
  • Failure will be by inelastic lateral torsional
    buckling
  • Nominal moment capacity, Mn lt Mp
  • At Lb Lp, Mn 0.7 Fy Sx
  • For Lp lt Lb lt Lr , linear interpolation from Mn
    Mp to Mn 0.7 Fy Sx (AISC Eq. F2-2)
  • For unbraced length Lb gt Lr
  • Failure will be by elastic lateral torsional
    buckling
  • Rapid reduction in Mn (AISC Eq. F2-3)

12
Bending Strength of Non-compact Shapes
  • Most standard W, M, S, and C sections are compact
  • A few are non-compact because of their flanges,
    but none are slender
  • Shapes with noncompact flanges are listed in User
    note on page 16.1-49
  • Sections with compact webs and noncompact (or
    slender) flanges
  • Nominal moment capacity, Mn lt Mp
  • Calculate Mn using provisions of Code Section F3
  • Sections with noncompact webs
  • Nominal moment capacity, Mn lt Mp
  • Calculate Mn using provisions of Code Section F4

13
Design Aids Braced Beams
  • Table 3-2, W-Shapes Selection by Zx
  • Applies to wide flange shapes with Fy 50 ksi
  • Applies mainly to sections which are adequately
    braced (Lb Lp)
  • Can be used for unbraced length up to Lb Lr
  • Best to use this table only if fully braced
  • Table lists Zx, Lp, Lr, and Moment Capacity, Fb
    Mp
  • Also lists Ix, and Shear Capacity Fv Vnx
  • Non-compact sections indicated by the footnote
    f
  • Moment capacity in table has been adjusted for
    non-compactness
  • Sections in table are grouped by weight
  • Lightest section in group is in bold
  • Choose this section if there is no depth
    restriction

14
Design Aids Unbraced Beams
  • Table 3-10, Available Moment vs. Unbraced Length
  • Applies to wide flange shapes with Fy 50 ksi
  • Also applies to channel shapes with Fy 36 ksi
  • Table is a plot of available flexural strength,
    FbMnx, versus unbraced length Lb
  • Bending Coefficient in Table conservatively taken
    as Cb 1
  • See Table 3-1 for values of Cb
  • Choose beam that has available moment strength
    FbMnx Mu at an unbraced length Lb Design Lb
  • Choose a beam above and to right of (Lb, Mu)
  • Solid line Beam chosen is lightest section
    available for the given combination of Mu and Lb
  • Dashed line A lighter section is available

15
Design Aids Channels
  • Braced Channels
  • Table 3-8, Maximum Total Uniform Load C Shapes
  • Applies to channel shapes with Fy 50 ksi
  • Applies only to sections which are adequately
    braced (Lb Lp)
  • Best to use this table only if fully braced
  • Table lists Zx, Lp, Lr, and Moment Capacity, Fb
    Mp
  • Also lists Shear Capacity Fv Vnx
  • Unbraced Channels
  • Table 3-10, Available Moment vs. Unbraced Length
  • Applies to channel shapes with Fy 36 ksi
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