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Pile Testing and Evaluation for the Sand Creek Byway, Sandpoint, Idaho Presented by Dean E. Harris, P.E., CH2M HILL.

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Presentation on theme: "Pile Testing and Evaluation for the Sand Creek Byway, Sandpoint, Idaho Presented by Dean E. Harris, P.E., CH2M HILL."— Presentation transcript:

1 Pile Testing and Evaluation for the Sand Creek Byway, Sandpoint, Idaho Presented by Dean E. Harris, P.E., CH2M HILL

2 Project Description Current alignment is through the City Realignment will provide a non-stop route for through traffic WGI is completing roadway and structural design CH2M HILL is responsible for geotechnical and structural design

3 Sand Creek Byway

4 Project Features Project features include two interchanges, a smaller bridge crossing a city street, and numerous MSE walls Community is sensitive to appearance and function Community supports the project

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6 Sand Creek Crossing

7 Geotechnical Explorations Piezocone (CPTu) was the primary method of subsurface exploration Maximum depth of CPTu soundings of 80 m Soil borings were advanced adjacent to many soundings to collect samples. Other testing included vane shear testing and shear wave velocity tests

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9 Cone rig and barge in Sand Creek

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11 Typical Soil Profile Upper 10 m: Medium stiff sandy silt to clay, N = 9 to 15 blows per 0.3 m 10 to 39 m: Very soft to soft clay with thin layers of loose to medium dense sandy silt, N = 0 to 5 blows per 0.3 m 39 to 67 m: Alternating soft to medium silt and clay, N = 7 to 13 blows per 0.3 m

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13 Pile Loading Test Axial compression loading test on a 0.41 m (16 in) steel pipe pile, driven to a depth of 45 m, with PDA and CAPWAP analysis Pile was instrumented at 8 levels, with vibrating wire gauges on sister bars, and 2 telltales; concrete-filled Osterberg Cell (O-Cell) used at the head of the pile, with steel reaction frame

14 Pile driving with APE D36-32

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17 Loading System

18 Loading test

19 Load-Movement Curves from Loading Test

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21 Findings from Loading Test Plunging failure occurred at movement of 11 mm Analysis considered pile residual load For clay layer,  = 0.1, N t = 6

22 ConditionCapacity (kN) End of Initial Driving260 Restrike (after 24 hours setup) 980 Static Loading Test (50 days after driving) 1900

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24 Strain Gauge Placement

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26 Neutral Plane Analysis

27 Interpretation of Gauge Load

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29 Summary and Conclusions Pile Setup is a major factor affecting construction and estimated capacity Instrumentation is necessary to extrapolate the pile testing data to other pile lengths Residual load effects are significant in interpreting capcity

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