Mandatory Checklist for End bearing Piles Foundation Design.

Mandatory Checklist for Friction Piles Foundation Design
Mandatory Checklist for Friction Piles Foundation Design

Designing the foundation for end-bearing piles involves considerations for soil conditions, structural loads, and the interaction between the piles and the load-bearing strata. Below is a detailed checklist with explanations and examples for the design of an end-bearing piles foundation:

1. Site Investigation:

  • Explanation: Conduct a thorough site investigation to understand soil conditions.
  • Example: Perform soil tests (SPT, CPT) to determine soil properties, identify load-bearing strata, and assess the presence of weak or compressible soil layers.

2. Load Analysis:

  • Explanation: Analyze and calculate loads acting on the piles.
  • Example: Consider vertical loads from the structure, lateral loads from wind or seismic forces, and moments from uneven settlement.

3. Bearing Capacity of Load-Bearing Strata:

  • Explanation: Ensure that the load-bearing strata can support the applied loads.
  • Example: If the total vertical load is 500 kN and the bearing capacity of the load-bearing strata is 250 kN/m², design the foundation with at least two piles to share the load.

4. Pile Type Selection:

  • Explanation: Choose the appropriate end-bearing pile type based on load requirements and soil conditions.
  • Example: Select driven piles (concrete, steel, or timber) for cohesive soils or piles with a suitable tip (such as a steel point) for penetration into load-bearing strata.

5. Pile Spacing and Arrangement:

  • Explanation: Determine the optimal spacing and arrangement of piles for even load distribution.
  • Example: Space the piles evenly to ensure uniform settlement and reduce the risk of differential settlement.

6. Pile Length:

  • Explanation: Calculate the required length of the piles to reach load-bearing strata.
  • Example: If the load-bearing strata is at 10 meters below the ground surface, design piles with lengths exceeding 10 meters to ensure adequate embedment.

7. Pile Tip Design:

  • Explanation: Design the pile tip to optimize penetration into the load-bearing strata.
  • Example: Select a steel-tipped pile for cohesive soils to enhance penetration and bearing capacity.

8. Pile Cap Design:

  • Explanation: Design the pile cap to distribute loads to individual piles.
  • Example: Include a reinforced concrete pile cap with appropriate dimensions and reinforcement to transfer loads from the structure to the piles.

9. Reinforcement:

  • Explanation: Specify reinforcement in the piles and pile cap, if required.
  • Example: Include reinforcing bars in the pile cap to enhance its tensile strength and improve overall stability.

10. Pile Installation:

  • Explanation: Specify procedures for pile installation.
  • Example: Use proper driving techniques or other suitable methods to achieve the desired pile lengths and capacities.

11. Pile Load Testing:

  • Explanation: Conduct load tests on selected piles to verify their capacity.
  • Example: Apply incremental loads to test piles and compare the measured settlement to predicted settlement to confirm design assumptions.

12. Negative Skin Friction:

  • Explanation: Account for negative skin friction in cohesive soils.
  • Example: Consider measures such as a shear key or vertical drains to mitigate negative skin friction effects on end-bearing piles.

13. Pile Group Effects:

  • Explanation: Consider interactions between closely spaced end-bearing piles in a group.
  • Example: Account for pile group effects in the design to avoid excessive settlement or lateral deflection.

14. Construction Sequence:

  • Explanation: Develop a construction sequence that ensures stability during and after construction.
  • Example: Install end-bearing piles, construct the pile cap, and then build the superstructure while monitoring for settlement or other issues.

15. Quality Control:

  • Explanation: Implement quality control measures during construction.
  • Example: Monitor pile installation for proper alignment, penetration, and verify the dimensions of the pile cap.

16. Code Compliance:

  • Explanation: Ensure compliance with local building codes and standards.
  • Example: Adhere to relevant codes such as ACI 318 for concrete piles, ASTM standards for steel piles, or local geotechnical standards.

17. Professional Engineer Involvement:

  • Explanation: Engage a qualified geotechnical and structural engineer to oversee the design.
  • Example: Have licensed engineers review and approve the end-bearing piles foundation design to ensure it meets safety and code requirements.

18. Record Keeping:

  • Explanation: Maintain detailed records of the end-bearing piles foundation design process.
  • Example: Document all design calculations, soil test results, construction activities, and as-built drawings for future reference and audits.

By following this checklist, engineers can ensure a well-designed end-bearing piles foundation that effectively supports the structural loads, provides stability, and minimizes potential failure modes.

By Md Abu Zaed Khan

Hello, this is Engr. Zaed Khan Planning Engineer, Associate member of Society of Engineers UAE. Expert in construction project planning, FIDIC red book, computation of extension of time claim, Contract agreement and contractual letters.

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