Steel Design

Design

  • Design procedures in accordance with 15th Edition AISC Steel Construction Manual and 2016 Specification for Structural Steel Buildings (ANSI/AISC 360-16) provisions for Allowable Stress Design (ASD).

  • Section dimensions and properties of steel shapes are USCS values given by AISC Shapes Database.

  • ASTM material specifications given by AISC Steel Construction Manual Table 2-4.

    • All W shapes are designed using ASTM A992.

    • The modulus of elasticity () for all steel members is equal to 29,000 ksi.

  • Lateral-torsional buckling modification factor () conservatively taken equal to 1.0 and cannot be modified in software.

  • Stiffeners, doubler plates, and/or beam bearing plates are not considered for design.

  • All user input loads are assumed to be applied from above to the top flange or through shear center of the member.

  • The length of bearing (ℓ) for point loads is equal to 3.25 in., unless noted otherwise.

  • Deflection analysis considers applied loads and the nominal weight of a member.

    • Shear deflection and deflection due to long-term loading (e.g. creep) are not considered.

  • The allowable flexural strength (Mn/Ωb) is determined in accordance with ANSI/AISC 360-16 Chapter F. For all provisions of ANSI/AISC 260-16 Chapter F, the value of Ωb = 1.67.

  • The allowable shear strength (Vn/Ωv) is determined in accordance with ANSI/AISC 360-16 Chapter G. For Section G2.1(a), the value of Ωv = 1.50. For all other provisions of Chapter G, Ωv = 1.67.

The applicability of the limit states for flanges and webs with concentrated forces is given in the table below.

[1] Flange local bending applies to only tensile concentrated forces (e.g. negative point load, uplift at support).

[2] Web local crippling applies to only compressive concentrated forces.

[3] Web sideways buckling applies to only compressive concentrated forces where relative lateral movement between the loaded compression flange and the tension flange is not restrained.

[4] Web compression buckling applies to only a pair of compressive concentrated forces (e.g. point load over support).

  • Design procedures in accordance with 11th Edition CISC Handbook of Steel Construction and 8th Edition CSA S16 Design of Steel Structures (CAN/CSAS16-14) provisions for Limit States Design (LSD).

  • Section dimensions and properties of steel shapes are SI values given by AISC Shapes Database.

  • ASTM material specifications given by CISC Handbook of Steel Construction Table 6-7 and Table 6-8.

    • All W shapes are designed using ASTM A992. This grade was chosen since the CISC Handbook of Steel Construction Table 6-8 refers to A992 as the “grade preferred for relative availability” for W sections. Steel shapes in CISC Handbook of Steel Construction refer to ASTM A6/A6M which in turn details A992 for use in building framing.

    • In terms of strength comparisons, CAN/CSA G40.21-04 350W grade of steel has an Fy = 350MPa, whereas the Fy = 345MPa for ASTM A992. Therefore, A992 should give a (slightly) conservative result.

    • The modulus of elasticity () for all steel members is equal to 200,00 MPa.

    • The shear modulus of elasticity () for all steel members is equal to 77,000 MPa.

    • The coefficient of linear expansion () for all steel members is equal to 0.00117 per 100°C change in temperature.

  • In lieu of a more accurate analysis, Mu was determined using ω=1.0 with effective unbraced beam length equal to 1.2L for simply supported ends and 1.4L for segments with any other flexural end restraint.

  • Stiffeners, doubler plates, and/or beam bearing plates are not considered for design.

  • All user input loads are assumed to be applied from above to the top flange or through shear center of the member.

  • The length of bearing (ℓ) for point loads is equal to 82.55 mm (3.25 in.), unless noted otherwise.

  • Deflection analysis considers applied loads and the nominal weight of a member.

    • Shear deflection and deflection due to long-term loading (e.g. creep) are not considered.

The applicability of the limit states for flanges and webs with concentrated forces is given in the table below.

[1] Flange local bending applies to only tensile concentrated forces (e.g. uplift at support, negative point load).

[2] Web local crippling applies to only compressive concentrated forces.

[3] Web compression buckling applies to only a pair of compressive concentrated forces (e.g. point load over support).

* Weyerhaeuser software shall return a warning message if point load located at ≤.

Member Types

Steel members are available for residential floor flush beams and floor drop beams only.

Spans and Supports

Design of steel members do not currently analyze cantilevers, and as such an error message will appear on the report.

Loads

Steel beam design is assuming loads are applied from above the top flange or through the shear center of the member.

Holes

Design of steel members do not currently analyze holes and will be ignored during analysis.

Bracing

Software will have the standard options for bracing during input but will default to “End Supports Only” when “Maximum Allowable” has been selected which will be accurately displayed on the report.

Product Selection

The available products for steel will have a different notation for the depth selection, which will be sorted by nominal depth and weight.

Section dimensions and properties of steel shapes are given by AISC Shapes Database.

Report

The graphic on the report will be updated in color to better represent steel. In addition there will be new notes below the design results that describe applicable design standards and assumptions for specific factors in design.