Note: When lateral loads applied to the top flange of the beam do not pass through the centroid of the section, reduce the plastic/elastic section modulus for the y-axis by 50%.
Purlin Load Components
For a roof slope angle $\theta$, resolve the gravity load into components normal and parallel to the roof plane.
506.6 I-Shaped Members and Channels Bent about their Minor Axis
The nominal flexural strength, $M_n$, is the lower value obtained according to the limit states of yielding (plastic moment) and flange local buckling.
506.6.1 Yielding
$$ M_n = M_p = F_y Z_y \leq 1.6 F_y S_y $$
506.6.2 Flange Local Buckling
1. For sections with compact flanges, the limit state of yielding shall apply.
CE Board November 2010 Light-grade steel channel was used as a purlin of a truss. The top chord of the truss is inclined 1V:3H and distance between trusses is equal to 3m. The purlin has a weight of 71N/m and spaced at 1.2m on centers. The dead load including the roof materials is 1200Pa, live load is 1000Pa and wind load is 1440Pa. Coefficient of pressure at leeward and windward are 0.6 and 0.2, respectively. Sag rods are placed at the middle thirds and Fbx=Fby=138MPa. Use: Sx=4.48x10⁴mm³ Sy=1.18x10⁴mm³ Using the interaction formula, determine the following:
Maximum ratio of actual to allowable bending stress for combination of (D+L) load.
0.469
0.438
0.496
0.483
Maximum ratio of actual to allowable bending stress for combination of 0.75(D+L+W)--windward side.
0.393
0.327
0.286
0.295
Maximum ratio of actual to allowable bending stress for combination of (D+L) if one line of sag rod was placed at the midspan.
0.616
0.514
0.723
0.567
Resolve the roof loads normal and parallel to the 1V:3H roof line, include the purlin self-weight, and use the simple-span moments for each axis. Check biaxial bending with $f_{bx}/F_{bx}+f_{by}/F_{by}$.
Part 1. For $D+L$, the resolved moments divided by $S_x$ and $S_y$ give an interaction ratio of $\boxed{0.469}$.
Part 2. For the windward combination $0.75(D+L+W)$, include the windward pressure coefficient and resolve the wind load along both purlin axes. The ratio is $\boxed{0.393}$.
Part 3. One midspan sag rod changes the weak-axis unbraced length and therefore the weak-axis bending moment. Reapplying the interaction formula gives $\boxed{0.616}$.