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Both Wind Loads (ASCE 7-16) and Wind Loads (ASCE 7-22) include MWFRS (Directional Procedure) per ASCE 7 Chapter 27. This mode calculates direction-dependent wind pressures on walls and roofs using building geometry, wind direction, and external pressure coefficients from Fig. 27.3-1.
Create a wind load sheet with the Directional Procedure preset:

Background

The Directional Procedure evaluates wind pressures for a single wind direction at a time. You choose whether wind acts normal to the long building axis or normal to the short axis, and the calculator determines windward, leeward, sidewall, and roof pressures from interpolated CpC_p values in Fig. 27.3-1. This differs from the MWFRS (Envelope Procedure) (Chapter 28), which envelopes multiple load cases without selecting a primary wind direction. Use the Directional Procedure when you need explicit direction-specific MWFRS pressures tied to L/BL/B, h/Lh/L, and roof angle.

Key properties

Under Key Properties, set Type of Calculation to MWFRS (Directional Procedure). Project defaults for Basic Wind Speed, Exposure Category, and Risk Category work the same as other wind load modes. Override them at the top of the sheet if needed.

Wind Load Parameters

When MWFRS (Directional Procedure) is selected, Gust Effect Factor (GG) appears in the Wind Load Parameters section below Key Properties. It defaults to 0.85 for rigid buildings (natural frequency greater than 1 Hz) per Cl. 26.11.1. Gust Effect Factor input in the Wind Load Parameters section

Building properties

Define roof geometry, dimensions, and enclosure classification as usual. For the Directional Procedure, Roof Type supports Flat, Gable, Hip, and Monoslope (the Envelope Procedure is limited to flat and gable roofs). Directional-specific inputs and computed values include:
  • Wind Direction: choose N-S Direction (Normal to Ridge) or E-W Direction (Parallel to Ridge). This sets which building dimension is treated as LL (parallel to wind) and BB (normal to wind).
  • Horizontal Dimension Parallel to Wind Direction (LL) and Horizontal Dimension Normal to Wind Direction (BB): derived from Width (Perpendicular to Ridge) and Length (Parallel to Ridge) based on the selected wind direction.
  • L/B Ratio (for Directional Procedure): used for the leeward wall CpC_p.
  • h/L Ratio (for Directional Procedure): mean roof height divided by LL; used for roof CpC_p interpolation.
  • Roof Angle in Wind Direction (θdir\theta_{dir}): equals the roof slope for most cases, or 0° when wind is parallel to the ridge (E-W on a gable roof).
A diagram under Wind Direction in the summary shows windward and leeward surfaces for the selected direction. Optional Include Roof Overhangs? = Yes adds Roof Overhang External Pressure Coefficient and Roof Overhangs Bottom Surface Pressure for the directional procedure (Cl. 27.3.3).

Intermediate calculations

The calculator follows the ASCE 7 Chapter 27 workflow:
  1. Velocity Pressure (qhq_h) at mean roof height, including exposure, topographic, and ground elevation factors where applicable.
  2. Wind Directionality Factor (KdK_d) per Table 26.6-1 (included in ASCE 7-22 directional pressure equations; computed on ASCE 7-16 sheets but not multiplied into the directional summary pressures).
  3. Internal Pressure Coefficient (GCpiGC_{pi}) from enclosure type.
  4. Roof External Pressure Coefficients table: CpC_p for windward wall, leeward wall, sidewall, and roof surfaces from Fig. 27.3-1, with linear interpolation for L/BL/B, h/Lh/L, and θdir\theta_{dir} where permitted by the figure notes.
Calculator assumptionThe reduction in roof pressure coefficients per footnote b in Fig. 27.3-1 (linear reduction with tributary area) is not applied in the current template.
For sloped roofs (θdir10°\theta_{dir} \geq 10°), the roof table reports separate windward minimum/maximum and leeward coefficients. For low-slope roofs (θdir<10°\theta_{dir} < 10°), roof zones are split by distance from the windward edge (0 to h/2h/2, h/2h/2 to hh, hh to 2h2h, and beyond 2h2h), with separate minimum and maximum CpC_p values where Fig. 27.3-1 requires both.

Results

The summary includes:
  • Wind Pressures: design pressures for each MWFRS surface, reported as Wind Pressure (Positive Internal) and Wind Pressure (Negative Internal) to cover both internal pressure cases.
  • Wind Pressures for Windward Wall: height-varying pressures on the windward wall when velocity pressure varies with height (including topographic effects).
  • Note: Minimum design wind pressures (Directional): ASCE 7 requires minimum ultimate pressures of 16 psf on windward walls and 8 psf on leeward walls and roofs (Cl. 27.1.5). Compare calculated values against these minimums in your design.
Design pressure form:
  • ASCE 7-22: p=qhKd(GCpGCpi)p = q_h K_d (G C_p \mp GC_{pi})
  • ASCE 7-16: p=qh(GCpGCpi)p = q_h (G C_p \mp GC_{pi}) (the template applies Kd=0.85K_d = 0.85 in other modes but omits it from the directional pressure equations shown in the summary)
Both editions report Wind Pressure (Positive Internal) and Wind Pressure (Negative Internal) columns to cover both internal pressure cases. When Include Parapets? is enabled, see Wind Load Parapets (ASCE 7-16 and ASCE 7-22) for parapet pressure outputs.
ASCE 7-22 tornado loadsIf Tornado Loads Required is Yes, the calculator notes that MWFRS (Directional Procedure) does not currently include tornado load calculations. Contact support if you need this functionality on a directional sheet.