The maximum deflection of a simply supported beam of span L, carrying an isolated load at the centre of the span; flexural rigidity being E$$I$$, is A. $$\frac{{{\text{W}}{{\text{L}}^3}}}{{3{\text{E}}I}}$$ B. $$\frac{{{\text{W}}{{\text{L}}^3}}}{{8{\text{E}}I}}$$ C. $$\frac{{{\text{W}}{{\text{L}}^3}}}{{24{\text{E}}I}}$$ D. $$\frac{{{\text{W}}{{\text{L}}^3}}}{{48{\text{E}}I}}$$

$$rac{{{ ext{W}}{{ ext{L}}^3}}}{{3{ ext{E}}I}}$$
$$rac{{{ ext{W}}{{ ext{L}}^3}}}{{8{ ext{E}}I}}$$
$$rac{{{ ext{W}}{{ ext{L}}^3}}}{{24{ ext{E}}I}}$$
$$rac{{{ ext{W}}{{ ext{L}}^3}}}{{48{ ext{E}}I}}$$

The correct answer is $\frac{{{\text{W}}{{\text{L}}^3}}}{{8{\text{E}}I}}$.

The maximum deflection of a simply supported beam of span $L$, carrying an isolated load at the center of the span, can be calculated using the following formula:

$$\delta = \frac{{{\text{W}}{{\text{L}}^3}}}{{8{\text{E}}I}}$$

where:

  • $\delta$ is the maximum deflection,
  • $W$ is the load,
  • $L$ is the span,
  • $E$ is the Young’s modulus, and
  • $I$ is the moment of inertia.

The formula can be derived by considering the bending moment diagram for a simply supported beam with an isolated load at the center of the span. The bending moment diagram is a plot of the bending moment along the length of the beam. The maximum bending moment occurs at the center of the span, and is equal to $WL/2$.

The deflection of a beam can be calculated using the following formula:

$$\delta = \int_{0}^{L} \frac{M(x)}{EI} dx$$

where:

  • $\delta$ is the deflection,
  • $M(x)$ is the bending moment at a distance $x$ from the left end of the beam,
  • $E$ is the Young’s modulus, and
  • $I$ is the moment of inertia.

The bending moment at a distance $x$ from the left end of the beam is equal to $WL/2$ for $0 < x < L/2$, and is equal to 0 for $L/2 < x < L$. Substituting these values into the formula for the deflection gives:

$$\delta = \int_{0}^{L/2} \frac{WL}{2EI} dx + \int_{L/2}^{L} \frac{0}{EI} dx = \frac{WL^3}{16EI}$$

The maximum deflection occurs at the center of the span, where $x=L/2$. Substituting this value into the formula for the deflection gives:

$$\delta = \frac{WL^3}{16EI} = \frac{{{\text{W}}{{\text{L}}^3}}}{{8{\text{E}}I}}$$

Therefore, the maximum deflection of a simply supported beam of span $L$, carrying an isolated load at the center of the span, is $\frac{{{\text{W}}{{\text{L}}^3}}}{{8{\text{E}}I}}$.

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