Question 12.P.11: If the concrete in the composite beam in P.12.10 has a reduc...

The available compressive force in the concrete is

0.4 × 15 × 2 × 10^{3} × 175 × 10^{-3}=2100 kN

The available tensile force in the steel is

0.87 × 350 × 9490 × 10^{-3}=2890 kN

Since the available compressive force in the concrete is less than the available tensile force in the steel the neutral axis of the composite beam section lies within the steel beam. Then, from Eq. (12.30) 0.4 \sigma_{\mathrm{cu}} b h_{\mathrm{c}}+2 \times\left(0.87 \sigma_{\mathrm{Y}}\right) A_{\mathrm{sc}}=0.87 \sigma_{\mathrm{Y}} A_{\mathrm{s}}

0.4 × 15 × 2 × 10^{3} × 175+2 × 0.87 × 350 A_{sc}=0.87 × 350 × 9490

which gives

A_{sc} = 1297 mm²

From Steel Tables the flange thickness of the steel beam is 17 mm so that, by inspection, the neutral axis lies within the flange of the beam. Then

152 h_{f}=1297

from which

h_{f} = 8.5 mm

and

h_{sc} = 175 + 8.5 = 183.5 mm

From Eq. (12.31) M_{\mathrm{u}}=0.87 \sigma_{\mathrm{Y}} A_{\mathrm{s}}\left(d-\frac{h_{\mathrm{c}}}{2}\right)-2 \times\left(0.87 \sigma_{\mathrm{Y}}\right) A_{\mathrm{sc}}\left(h_{\mathrm{sc}}-\frac{h_{\mathrm{c}}}{2}\right)

M_{u}=0.87 × 350 × 9490(405.5-87.5)-2 × 0.87 × 350 × 1297(183.5-87.5)

which gives

M_{u} = 843 kN m