1. Brown Drilled Foundations 2017

 Advances in the the Use of Drilled Foundations Dan Brown, P.E., Ph.D. President, Dan Brown and Associates, and President, Deep Foundation Institute

Overview !

Why drilled foundations? !

Micropiles

!

Continuous Flight Auger (CFA) Piles and Drilled Displacement (DD) Piles

!

Drilled Shafts (Bored Piles)

Micropiles !

Typically <12” dia

!

Relies on steel for structural capacity

!

Installed with lightweight, versatile drilling equipment

!

Effective in difficult ground conditions World Trade Center, NYC

 Advancements in Micropiles !

Standards for design & construction

!

Higher capacity piles

!

Improvements in drilling and more versatile drilling rigs

!

Innovative applications

Micropiles – Design Details !

Casing near surface

!

Center bar(s) through bond zone

 AASHTO Design Design Section 10.9

!

FHWA FHW A Micropile Manual, Dec. 2005 2 005

Micropiles – Design Details !

Example Cross-sections

Micropiles in Difficult Ground Conditions !

Karst

!

Till & Boulders

Difficult Site  Access

!

!

Restricted Headroom

Drilled Shaft

International Marketplace, Hawaii Micropiles up to 90m deep in soft alluvium

(photo courtesy of Hayward-Baker)

Case History – Foothills Bridge

Foothills Bridge Area of Colluvium Abutment 1 Abutment 2

Foothills Bridge Pier 

Residual Soil

Cased zone

Anchor (to rock)

 4.6 m (15 ft) uncased bond zone

Weathered Rock

Sound Rock

Foothills Bridge

Foothills – Trestle Foundation

Foothills – Pier Foundations

Rouchleau Mine Crossing, Minnesota

Pier Foundations

52m

Pile Location in Mine Dump Fill

107m

History

Downhole Hammer Drill Crossover Sub-Seal Crossover Sub Port Shock  Absorber Hammer Pilot Bit

Drill Head and Casing Ring Bit

Drilling

Final Pile Design  Approximate depth 55m

! !

762mm dia steel pipe filled with concrete

!

End bearing on hard rock

!

Design axial resistance = structural capacity of the pile cross section

Note: !

two 600mm dia test piles loaded to 17MN

Continuous Flight Auger Piles

Continuous Flight Auger Piles !

Drill rig capabilities – deeper, larger diameter

!

Control of the drilling process in unstable soils

!

Control of the casting process for quality control / quality assurance

Continuous Flight Auger Piles !

Drill rig capabilities

Continuous Flight Auger Piles Control of the Drilling and Concreting Process

Drilled Displacement Piles

Drilled Displacement Piles !

Reduce or eliminate spoil

!

Requires heavier, more expensive drilling equipment than CFA

!

Increased axial resistance

!

Improve ground

!

Slower than CFA

!

Eliminate risk of subsidence

!

Limited depth of penetration

!

Drill effort related to axial resistance

Kentucky Hospital !

Drilled displacement columns for ground improvement

!

Liquefaction mitigation

!

Bearing capacity for spread footings

Drilled Displacement Piles

Bearing Tests

./(0&1( 2(&0"+1 30(##40(, 53& #

(##

# !(#

   )    )  , !'#    +    *    (    )!&#    (    '    & !%#     %    $    #    "    ! !$# !"#

)*+, ( )*+, ' )*+, &

'##

&##

%##

Drilled Shafts (Bored Piles) !

Larger, Deeper Machine Capabilities !

Oscillator/Rotator Machines

!

Reverse Circulation

!

Base Grouting

!

Verification Testing

Oscillator Equipment

Rotator Equipment

Seating Casing into Rock

Considerations Advantages !

!

!

!

Stability of fully cased excavation Minimal vibrations for casing installation Easy removal of spoil & obstructions  Avoid or minimize slurry materials

Limitations !

Mobilization cost

!

Equipment support requirements

!

Potential to become stuck for deep shafts

!

Non-level base with hammer-grab excavation

Rotator Construction  – Huey P. Long Bridge, New Orleans

Huey Long Bridge Shaft/Cap Connection

Isolation Casing Shaft Cutoff at -11

Completed Foundation

Surface Texture

Restricted Headroom with Rotator Casing Moses Wheeler Bridge, Connecticut Permanent Casing

Obstructions? VE solution to cut through existing piling

Reverse Circulation Top-Drive Drill

Drilling rock socket into schist

Reverse Circulation Drilling Wolf Creek Dam

Deeper Drilled Shafts Case History: Wolf Creek Dam, Kentucky Embankment wall

Secant pile wall

275 ft deep

Wolf Creek Dam Secant Piles

Base Grouting 0

5

O-cell load (MN) 15

10

20

25

30

0

0.0

-1    )   s   e    h   c   n    i    ( -2   e    t   a    l   p    l    l   e -3   c      O    f   o    t -4   n   e   m   e   c   a    l   p -5   s    i    D

-25.4    )   m   m -50.8    (   e    t   a    l    P    l    l -76.2   e   c      O    f   o -101.6    t   n   e   m   e   c   a    l -127.0   p   s    i    D

T3 (Not Grouted)

-6

-152.4

-7

-177.8 0

500

1,000

1,500 2,000 O-cell load (tons)

2,500

3,000

Load test data from John James Audubon Bridge, Mississippi River, Louisiana

3,500

Widespread Use of Polymer Slurry !

Disposal advantages

!

Improved side resistance

!

Benefits in degradable shales

Widespread Use of Polymer Slurry

Polymer Slurry in Shale at Bond Bridge Sample

River Water Polymer Slurry

Natural Moisture Content (%) 8.3 8.3

Slake Durability Index Type Id(2) (%) II 72.2 II 98.2

Durability Rating Based on Shear Strength Loss Type DR s Intermediate 61.9 Hard, more durable 78.6

Load test: 800 kPa unit side resistance  After 4 days exposure

Influence on Axial Resistance    f 1.6   s    k1.4  ,   e   c1.2   n   a 1    t   s    i   s0.8   e    R0.6   e    d    i 0.4    S    t    i 0.2   n    U 0

Polymer Bentonite

0

0.5

1

1.5

2

 Axial Displacement, inches

Data from Auburn University National Geotechnical

!

Research Site (Brown, ASCE GT Journal, 2002)

!

Verification Testing !

Integrity Testing

!

Load Testing

!

Verification testing allows performance basis for specification !

Design-build

!

Value engineering

 ATC, Mississippi River Bridge, St. Louis O-cells

Cored rock from test shaft excavation