Aisc Manual | Table 6-2

Define (LRFD): [ p = \frac98 \cdot \frac\phi_b M_nx\phi_c P_n ] But note: In Table 6-2, ( p ) is typically tabulated as: [ p = \frac98 \cdot \frac1\phi_c P_n ] Wait – check carefully: AISC Table 6-2’s ( p ) is not directly ( \frac98 \cdot \frac\phi_b M_nx\phi_c P_n ). Instead, AISC uses a normalized form:

The interaction equation becomes: [ M_ux \leq \phi_b M_nx - p \cdot P_u ] Where: [ p = \frac98 \cdot \frac\phi_b M_nx\phi_c P_n \quad \text→ Wait, no. Let's correct: ] aisc manual table 6-2

This table is found in the 15th and 16th Editions of the AISC Steel Construction Manual, within Chapter 6 (Design of Members Subjected to Combined Forces). 1. Core Identity: What is Table 6-2? Official Title: W-Shapes, Selection by ( P_p ) (Axial Strength) for Combined Forces and Strong-Axis Bending Define (LRFD): [ p = \frac98 \cdot \frac\phi_b

[ M_ux \leq \phi_b M_nx - p \cdot P_u ] where ( p ) is tabulated in ( 10^-3 ) (kip-ft/kip), meaning: [ p_\textactual = \fracp_\texttable1000 \quad \textin ft ] 5. Using Table 6-2 Step-by-Step (LRFD Example) Given: W12×65, ( L_b = 10 \text ft ), ( P_u = 150 \text kips ), ( M_ux = 250 \text kip-ft ), ASTM A992 (Fy=50 ksi). Using Table 6-2 Step-by-Step (LRFD Example) Given: W12×65,

Manually calculating the interaction equations for multiple load cases and member sizes is tedious. Table 6-2 pre-calculates key coefficients, allowing the engineer to compute a single “interaction value” and compare it to 1.0 in seconds.

Now, express this as: [ M_ux = \phi_b M_nx \cdot \frac98 - \frac98 \cdot \frac\phi_b M_nx\phi_c P_n \cdot P_u ]