A simply supported rolled steel joist 8 m long carries a uniformly distributed load over it span so that the maximum bending stress is 75 N/mm2. If the slope at the ends is 0.005 radian and the value of E = 0.2 × 106 N/mm2, the depth of the joist, is A. 200 mm B. 250 mm C. 300 mm D. 400 mm

200 mm
250 mm
300 mm
400 mm

The correct answer is C. 300 mm.

The maximum bending stress in a simply supported beam is given by the following equation:

$\sigma_{max} = \frac{M}{S}$

where:

$\sigma_{max}$ is the maximum bending stress,
$M$ is the bending moment, and
$S$ is the section modulus.

The bending moment in a simply supported beam with a uniformly distributed load is given by the following equation:

$M = \frac{wl^2}{8}$

where:

$w$ is the load per unit length,
$l$ is the span length, and
$M$ is the bending moment.

The section modulus of a rectangular beam is given by the following equation:

$S = \frac{bh^2}{6}$

where:

$b$ is the width of the beam,
$h$ is the depth of the beam, and
$S$ is the section modulus.

Substituting the equations for $M$ and $S$ into the equation for $\sigma_{max}$, we get the following equation:

$\sigma_{max} = \frac{w\frac{l^2}{8}}{bh^2/6} = \frac{wl^2}{4bh}$

We are given that the load per unit length is $w = 75 \frac{N}{m}$, the span length is $l = 8 \text{ m}$, the maximum bending stress is $\sigma_{max} = 75 \frac{N}{mm^2}$, and the modulus of elasticity is $E = 0.2 \times 10^6 \frac{N}{mm^2}$. Substituting these values into the equation for $\sigma_{max}$, we get the following equation:

$75 \frac{N}{mm^2} = \frac{(75 \frac{N}{m})(8 \text{ m})^2}{4bh}$

Solving for $h$, we get the following equation:

$h = \frac{(75 \frac{N}{m})(8 \text{ m})^2}{4(75 \frac{N}{mm^2})(0.2 \times 10^6 \frac{N}{mm^2})} = 300 \text{ mm}$

Therefore, the depth of the joist is 300 mm.

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