751.39 Pile Footings

Note: All pile shall be vertical.

General Requirements

Water elevation is to be determined for the site conditions by the preliminary design section; generally, less than the average of high and low water.

Determine the uplift force per pile by deducting the weight of the seal course and friction between seal course and sheet piling of cofferdam from the uplift force produced by the hydrostatic head "h".

Use a friction value between the seal course and the sheet piling of 2 lbs./in² acting on (perimeter x depth) of seal course.

Pile Pull-out Force

Allowable uplift force per pile shall be determined by the minimum of:

(1) The allowable friction capacity of pile = skin friction capacity of pile divided by a safety factor of 3.5. Use "DRIVEN" program to calculate skin friction capacity of pile (without end bearing or tip capacity). (See AASHTO Table 4.5.6.2A.)

(2) Allowable pull-out capacity of pile due to shear cone failure equal to ultimate pull-out capacity of pile due to shear failure (with maximum shear stress of ${\displaystyle 2{\sqrt {f'c}}}$ ) divided by a safety factor of 3. See Figs. 751.39.1, 751.39.2 and the following example. (See AASHTO 8.16.6.2.)

(3) Allowable Maximum pull-out capacity = 0.25 * Yield strength of steel * steel area of pile. (See AASHTO 4.5.7.3.)

Note: Since CIP pile is not filled at this stage, use steel pipe pile area without concrete to determine the allowable maximum pull-out capacity.

For Cast-in-Place Pile	For H Pile
Surface Area = πS(r + R)	Surface Area = (2a + 2b+ πR)S
Fig. 751.39.1, Full Shear Cone Failure Surface

For Cast-in-Place Pile	For H Pile
Reduced Surface Area = πS(r + R)	Reduced Surface Area = (2a + 2b+ πR)S
Fig. 751.39.2, Reduced Shear Cone Failure Surface

The reduced surface area defined in Fig. 751.39.2 is a conservative value compared to the actual reduced surface area. The geometry of the actual surface area is time consuming and complicated to compute, so a standard shape was chosen to ensure efficient use of the designer's time.

Example, Seal Course

Problem

Check if Seal Course design is adequate.

Given

• Concrete Strength f'c= 3000 psi
• Pile spacing = 3'-0"
• 12 - HP 10 x 42 piles
• Area of an individual HP 10 x 42 Pile = A = 12.4 in²
• Yield strength of steel F_y = 36 ksi
• Maximum axial load P_y = F_y (A) = 36 ksi (12.4 in²) = 446.4 kips
• Hydrostatic head h = 19'
• Seal Course = 12' x 15' x 3'
• Pile embedment below seal course = 15'

Fig. 751.39.3, Seal Course Elevation

Fig. 751.39.4, Typical Shear Cone Failure Area

Fig. 751.39.5, Shear Failure Area for Individual Pile

Solution

Actual Uplift Force:

Allowable Uplift Force:

Use the minimum of:

(1) Allowable friction capacity of pile:

Using "DRIVEN" program, the skin friction capacity of pile is 53.97 kips.

Allowable friction capacity = 53.97 kips/3.5 = 15.42 kips

(2) Allowable pull-out capacity of pile due to shear cone failure:

(Reference Figs. 751.39.4 and 751.39.5)

• Total Reduced Shear Cone Area for H-pile

= (2a + 2b + πR)S

= (2 x 9.7" + 2 x 10" + 3.1416 x 13") x 18.38"

= 1474 in²

• Ultimate Shear Strength

= ${\displaystyle 2{\sqrt {f'c}}}$

= ${\displaystyle 2{\sqrt {3000}}}$

= 109.5 psi

• Total Pull-Out Capacity

= (Total Shear Cone Area) x (Ultimate Shear Strength)

= 1474 in² x 0.1095 ksi = 161.4 kips ≤ P_y = 446.4 kips

• Allowable Pull-Out Capacity

= Total Pull-Out Capacity / Factor of Safety

= 161.4 kips/3 = 53.8 kips

(3) Allowable Maximum Pull-Out Capacity

= 0.25 x F_y x steel area of pile

= 0.25 x 36 x 12.4

=111.6 kips

Minimum from (1), (2) & (3):

Allowable uplift force = 15.42 kips

Actual uplift force = 7.17 kips

15.42 kips > 7.17 kips O.K.

Try seal course depth = 2'-6"

Actual Uplift Force:

Allowable Uplift Force:

Use the minimum of:

(1) Allowable friction capacity of pile: Using "DRIVEN" program, the skin friction capacity of pile is 54.37 kips. Allowable friction capacity 54.37 kips/3.5 = 15.53 kips

(2) Allowable pull-out capacity of pile due to shear cone failure = 53.8 kips

(3) Allowable maximum pull-out capacity = 111.6 kips

Minimum from (1), (2) & (3):

Allowable uplift force = 15.53 kips

Actual uplift force = 8.45 kips

15.53 kips > 8.45 kips

(Thus, using a depth of 2'-6" is an economical design.)