Question 11.EP.1: Assume a pile having a diameter of 0.3 m and a length of 6 m...

Geotechnical Earthquake Engineering

Assume a pile having a diameter of 0.3 m and a length of 6 m will be driven into a nonplastic silty sand deposit having shear strength properties of c = 0 and Φ’ = 30°. Assume that the location of the groundwater table is located 3 m below the ground surface, the total unit weight above the groundwater table is 19 kN/m³, and the buoyant unit weight $\gamma_{b}$ below the groundwater table is 9.9 kN/m³. Using the Terzaghi correlation shown in Fig. 11.13, calculate the allowable end-bearing capacity using a factor of safety of 3.

11.13

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The vertical effective stress $\sigma _{v}^{\prime}$ at the pile tip equals:

\sigma_{v}^{\prime}=(3 m )\left(19 kN / m ^{3}\right)+(3 m )\left(9.9 kN / m ^{3}\right)=87 kPa

From Fig. 11.13, using Φ’ = 30° and the Terzaghi relationship, $N_{q}$ = 30
Using Eq. (11.9):

$q_{ ult }=\frac{Q_{p}}{\pi r^{2}}=\sigma_{v}^{\prime} N_{q}$ (11.9)

Ultimate end-bearing capacity $q_{\text {ult }}$ = (87 kPa)(30) = 2600 kPa
Multiplying $q_{\text {ult }}$ by the area of the pile tip (πr²), or:

Q_{p}=(2600)(\pi)(0.15)^{2}=180 kN

Using a factor of safety of 3, the allowable pile tip resistance = 60 kN

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