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Teaching Modules for Steel Instruction

Teaching Modules for Steel Instruction. Advanced Flexure Design COMPOSITE BEAM THEORY SLIDES. Developed by Scott Civjan University of Massachusetts, Amherst. Composite Beams. Composite action accounts for the steel beam and floor slab working together to resist bending moments.

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Teaching Modules for Steel Instruction

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  1. Teaching Modules for Steel Instruction Advanced Flexure Design COMPOSITE BEAM THEORY SLIDES Developed by Scott Civjan University of Massachusetts, Amherst Composite Beam Theory

  2. Composite Beams Composite action accounts for the steel beam and floor slab working together to resist bending moments. Advantages over non-composite design: Increased strength Increased stiffness For given load conditions can achieve: Less steel required Reduced steel depth Composite Beam Theory

  3. Composite Behavior c c NA Composite NA Concrete T c NA Steel T T • Non-Composite • Slip at Interface • Two Neutral Axes • Mn= Mnconcrete+Mnsteel • I = Iconcrete + Isteel • Fully Composite • Assumed no slip at Interface • One Neutral Axes • Mn >> Mnconcrete+Mnsteel • I >> Iconcrete+Isteel • Shear at interface transferred by shear connectors. Composite Beam Theory 3

  4. Slabs Composite Metal Deck Slabs – most commonly used today. Advantages: Stay in place form. Slab shoring typically not required. Metal deck serves as positive reinforcement. Metal deck serves as construction platform. Flat Soffit Slabs – typically, older construction. Composite Beam Theory

  5. Effective Width of Slab beff = effective width of the slab Function of: Span length Distance to nearest beam Distance to edge of slab beff beff s3 s2 s1 edge edge Composite Beam Theory

  6. Flat Soffit Slabs beff ts, slab thickness Composite Beam Theory

  7. Metal Deck Slab - Ribs Parallel to Beam Span A beff hr tc A hr = height of deck tc= thickness of concrete above the deck Composite Beam Theory 7

  8. Metal Deck Slab - Ribs Perpendicular to Beam Span A beff hr tc A Composite Beam Theory

  9. REFERENCES: COMPOSITE BEAMS Steel Deck Institute web pages Nelson Headed Studs web pages Steel Deck Manufacturer Catalogs These can be found on-line Composite Beam Theory

  10. Typical Framing Column Girder Beam Slab/Deck Span PLAN Composite Beam Theory

  11. INSERT PHOTOS: AISC Four Story Office Building Photo Slide Shows Metal Decking Slides Shear Studs Slides Composite Beam Theory

  12. Flexural Strength Composite Beam Theory

  13. Flexural Strength Positive Moment The strength is determined as the plastic stress distribution on the composite section. Negative Moment It typically is assumed that the concrete carries no tensile forces and reinforcement is minimal, therefore strength is identical to a bare steel section. Composite Beam Theory

  14. Flexural Strength Positive Moment Fully Composite: The strength of either the floor slab in compression or the steel beam in tension is transferred at the interface. Partially Composite: The force transfer between the slab and beam is limited by the connectors. Composite Beam Theory

  15. Flexural Strength Positive Moment Lateral Torsional Buckling is prevented by the slab (continuous bracing). Local Flange Buckling is minimized by the slab. In general, strength is controlled by Mp. Composite Beam Theory

  16. INSERT INFORMATION: STRENGTH OF FULLY COMPOSITE BEAM SECTION CALCULATIONS Handout on Calculations: FullyCompositeCalcs.PDF Composite Beam Theory

  17. Flexural Strength The bare steel section must support the temporary construction loads (before the concrete has set), or the steel beam must be shored until the composite section is effective. Composite Beam Theory

  18. Shear Transfer Between Slab and Beam Typically, provided by headed shear studs. Shear flow, n, is calculated along the interface between slab and beam. Minimal slip allows redistribution of forces among shear studs. Therefore, studs are uniformly distributed along the beam. The total shear flow, n, must be provided on each side of Mmax. Composite Beam Theory

  19. Shear Transfer Between Slab and Beam Compression Force Tension Force Composite Beam Theory 19

  20. Shear Transfer Between Slab and Beam Compression Force Tension Force Composite Beam Theory 20

  21. Shear Transfer Between Slab and Beam n = shear flow Composite Beam Theory 21

  22. Shear Transfer Between Slab and Beam • = shear flow to be transferred by shear studs • V = Shear at the location considered • Q = first moment of inertia of area above the interface • Itr= moment of inertia of the transformed cross section Composite Beam Theory

  23. Partially Composite Beam Consider when fully composite strength is greater than required. This may occur when: The shape is based on construction loads. The shape is based on architectural constraints. The lightest shape has excess strength. Composite Beam Theory

  24. INSERT INFORMATION: STRENGTH OF PARTIALLY COMPOSITE BEAM SECTION CALCULATIONS Handout on Calculations: PartiallyCompositeCalcs.PDF Composite Beam Theory

  25. Serviceability For composite section deflections: Transform section into equivalent steel section. Compute center of gravity of transformed section. Compute Itr of transformed section. Composite Beam Theory

  26. Serviceability beff beff/n tc tc hr hr Note: modular ratio, n = Es/Ec Composite Beam Transformed Beam Composite Beam Theory 26

  27. Shear Strength It typically is assumed that the slab carries no shear forces, therefore composite strength is identical to that of a bare steel section. Composite Beam Theory

  28. Teaching Modules for Steel Instruction Advanced Beam Design COMPOSITE BEAM AISC Manual -14thEdition Developed by Scott Civjan University of Massachusetts, Amherst

  29. Chapter I: Composite Member Design Composite Beam - AISC Manual 14th Ed

  30. Slab effective width, be To each side of the beam, be is limited by: one-eighth beam span one-half distance to adjacent beam distance to edge of slab Lowest value controls. Composite Beam - AISC Manual 14th Ed

  31. Metal Deck Slab ≥0.5” tc ≥ 2” ≥1.5” hr ≤ 3” wr ≥ 2” steel beam wr = average deck width hr = height of deck tc = thickness of concrete above the deck Composite Beam - AISC Manual 14th Ed 31

  32. Fully Composite Beam: Bending Strength Composite Beam - AISC Manual 14th Ed

  33. fb = 0.90 (Wb = 1.67) Bending Strength Composite Beam - AISC Manual 14th Ed

  34. Bending Strength POSITIVE MOMENT For h/tw The strength is determined as the plastic stress distribution of the composite section.  (*Note: All current ASTM A6 W, S and HP shapes satisfy this limit.) NEGATIVE MOMENT It is typically assumed that the concrete carries no tensile forces and reinforcement is minimal, therefore strength is identical to a bare steel section. Composite Beam - AISC Manual 14th Ed

  35. INSERT INFORMATION: STRENGTH OF FULLY COMPOSITE BEAM SECTION CALCULATIONS Handout on Calculations: FullyCompositeCalcs.PDF Composite Beam - AISC Manual 14th Ed

  36. Bending Strength Fully Composite Strength can be determined by using Table 3-19. Y2 - Calculated per handout Y1 = 0 if PNA in the slab, Calculated per handout if PNA in the beam flange or web. Composite Beam - AISC Manual 14th Ed

  37. Table 3-19 Nomenclature (Pg. 3-14) TFL 1 2 3 4 Eq. spaces tf 4 BFL 5 Beam Flange Enlarged Detail be a/2 Location of effective concrete flange force (SQn) a Ycon Y2 TFL(pt.1) 1 5 BFL(pt.5) 6 7 Y1 = Distance from top of steel flange to any of the seven tabulated PNA locations Composite Beam - AISC Manual 14th Ed

  38. Bending Strength To reach fully composite strength, shear studs must transfer SQn for Y1 = 0 (maximum value) listed in Table 3-19. This is equivalent to value C* in calculations (handout). Composite Beam - AISC Manual 14th Ed

  39. Shear Stud Strength Composite Beam - AISC Manual 14th Ed

  40. Strength of each stud, Qn Equation I8-1 limits value to crushing of concrete around the shear stud. limits value to strength of individual shear studs. Composite Beam - AISC Manual 14th Ed

  41. Asa= cross sectional area of shear stud Ec= modulus of elasticity of concrete Fu = shear stud minimum tensile strength (typically 65ksi) Rg accounts for number of studs welded in each deck rib and wr/hr. Values are 1.0, 0.85 or 0.7. Rp accounts for deck rib orientation with respect to the beam, stud engagement in the concrete above the rib, and weak or strong stud location. Values are 0.75 or 0.6. Composite Beam - AISC Manual 14th Ed

  42. Strength, Qn, for one shear stud Table 3-21 Composite Beam - AISC Manual 14th Ed

  43. Limitations on shear stud placement for shear studs placed in metal decking: Center-Center Spacing: >4 times diameter ≤ 8 times slab thickness ≤ 36 inches Shear Stud Diameter: ≤ 3/4” ≤ 2.5 times flange thickness unless over web Composite Beam - AISC Manual 14th Ed

  44. Composite strength requires that shear studs transfer SQn to each side of the maximum moment in the span. If SQn strength of the shear studs is inadequate to provide fully composite action, the beam is partially composite. Composite Beam - AISC Manual 14th Ed

  45. Partially Composite Beam: Bending Strength Fb = 0.90 (Wb = 1.67) Composite Beam - AISC Manual 14th Ed

  46. INSERT INFORMATION: STRENGTH OF PARTIALLY COMPOSITE BEAM SECTION CALCULATIONS Handout on Calculations: PartiallyCompositeCalcs.PDF Composite Beam - AISC Manual 14th Ed

  47. Partially Composite Strength can be determined by using Table 3-19. Y2 - Calculated per handout Y1 - Calculated per handout Composite Beam - AISC Manual 14th Ed

  48. Partially Composite Action is limited by the total strength of shear studs. SQn listed in Table 3-19. This is equivalent to value C* in calculations (handout). Composite Beam - AISC Manual 14th Ed

  49. Composite Beam: Shear Strength Composite Beam - AISC Manual 14th Ed

  50. SHEAR STRENGTH It typically isassumed that the slab carries no shear forces. Therefore, strength is identical to a bare steel section. Composite Beam - AISC Manual 14th Ed

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