Design Calculation Example | Tower Crane Foundation

7.0 m × 7.0 m × 1.5 m thick. 5. Stability Checks 5.1 Overturning (ULS) [ M_overturning,ULS = M_d = 6300 , \textkNm ] Restoring moment (about edge): [ M_restoring = N_total,ULS \times \fracL2 = (1148 + 1837.5) \times 3.5 = 2985.5 \times 3.5 = 10449 , \textkNm ] Factor of safety: [ FOS = \frac104496300 = 1.66 > 1.5 \quad \text✓ OK ] 5.2 Sliding (ULS) Sliding force (H_d = 97.5 , \textkN) Friction resistance: (\mu = 0.45) (concrete on stiff clay) [ R_friction = N_total,ULS \times \mu = 2985.5 \times 0.45 = 1343.5 , \textkN ] [ FOS_sliding = 1343.5 / 97.5 = 13.8 \gg 1.5 \quad \text✓ OK ] 6. Structural Design of Pad (ULS) 6.1 Bending moment at column base interface Ultimate bearing pressure distribution (simplified for ULS) – Use factored loads and effective area.

[ W_conc = 7\times7\times1.5\times25 = 1837.5 , \textkN ] [ N_total = 850 + 1837.5 = 2687.5 , \textkN ] [ e = 4200 / 2687.5 = 1.563 , \textm ] [ L/6 = 7/6 = 1.167 , \textm; \quad e > L/6 \rightarrow \textstill partial uplift ] [ L' = 3\times(3.5 - 1.563) = 5.811 , \textm ] [ q_max = \frac2\times2687.57 \times 5.811 = \frac537540.677 \approx 132.2 , \textkPa < 150 , \textkPa \quad \text✓ OK ] Tower Crane Foundation Design Calculation Example

Moment about column edge = pressure resultant × lever arm. Use trapezoidal distribution? For simplicity, take average pressure = (204.5 + 0)/2? No, partial uplift. Actually, use effective width method: Structural Design of Pad (ULS) 6