Expert Modelling: Hands-on help from Rocscience Engineers. Register Here
 

Search Results

Telescopic Drilled Pier with Bell

1.0 Introduction

In this tutorial a telescopic bored pile with enlarged base is solved for carrying capacity using the program RSPile. Before proceeding with the tutorial, make sure you’ve gone through Tutorial 01 - RSPile Quick Start so you’re familiar with the product’s basic functions and features.

Topics Covered in this Tutorial:

  • Defining Pile Sections
  • Pile Types
  • Designing Bells

Finished Product:

The finished product of this tutorial can be found in the Tutorial 9 - Telescopic Drilled Pier with Bell.rspile2 data file. All tutorial files installed with RSPile can be accessed by selecting File > Recent Folders > Tutorials Folder from the RSPile main menu.

2.0 Model

When the RSPile program is started, a new blank document is already opened, allowing you to begin creating a model immediately.

2.1 PROJECT SETTINGS

  1. Select Analysis > Project Settings (CTRL + J) or click on the Project Settings Icon Project Settings icon in the toolbar.
  2. Project Settings dialog

  3. Set your Pile Analysis Type as Carrying Capacity and then select Bored.
  4. Click Advanced to see the Advanced Settings and set the step length for showing capacity results.
  5. In this example the results are presented every 1 m as indicated in the Pile Depth Increment (m) field.
  6. Click OK to close the dialog.

2.2 GROUND WATER

The Ground Water Table for this example is at 2 m below ground surface. To set the ground water surface in your in model:

  1. Select Analysis > Groundwater.
  2. Check Enable Groundwater.
  3. Set the Water Table Elevation (m) to -2.
  4. Click OK to close the dialog.

3.0 Soils

From the ground surface we will be defining a 12m layer of cohesive stiff clay overlaying another 12m layer of cohesionless soil, as well as a water table.

3.1 SOIL PROPERTIES

  1. Select Soils > Define Soil Properties (CTRL + 8) or click on the Soil properties with pencil icon Define Soil Properties icon in the toolbar.
  2. Click on the Green Plus icon plus icon on the bottom left of the dialog to define two soil properties.
  3. Select each property in the left side bar and enter the following soil profile data:

Property 1 (Cohesive Clay):

  • Name = Clay
  • Soil Type = Cohesive
  • Method = Total Stress Calculations - Alpha method
  • Unit weight = 18
  • Saturated unit weight = 20kPa
  • Choose Alpha = 0.7
  • Undrained shear strength Su = 100 kPa
  • Bearing Capacity Factor Nc = 9
  • Since no cap is applied for capacity the Skin Friction and End Bearing limits are set to 10000 kPa.

Soil Properties dialog

Property 2 (Cohesionless Sand):

  • Name = Dense Sand
  • Soil Type = Cohensionless
  • Unit weight = 20 kN/m3
  • Unit Saturated unit weight = 22 kN/m3
  • Internal friction Angle
  • Skin Friction Angle = 38
  • End Bearing Angle = 38
  • Method = Ks-Delta/NQ Method
  • OCR = 1
  • Ks/Ko = 1
  • Delta/phi =0.7
  • Bearing Capacity Factory Nq = 50
  • The skin friction is capped with 400kPa.
  • The end bearing is left uncapped and uses value of 10000 kPa.

Soil Properties dialog for Dense Sand

  1. Click OK to close the dialog.

3.2 BOREHOLE EDITOR

Next we will use the Borehole Editor to define our borehole and layer thicknesses.

  1. Select Soils > Borehole Editor or click on the Borehole editor icon Edit All Boreholes icon in the toolbar.
  2. Edit Borehole dialog

    As mentioned in the previous section, each layer will have a thickness of 12 m.

  3. Click on the Insert Layer Below button to insert the second layer. The Clay and Dense Sand properties should be applied automatically.
  4. Change the thickness for Layer 1 and 2 to 12 m.
  5. Set the x,y location to (2,2)
  6. The Borehole Top Elevation will remain as 0.
  7. Click OK to close the dialog.

4.0 Piles

The pile for this example is a telescopic pile with three segments that are 5 m in length each and a bottom piece that is extended with a bell of 1.93 m.

4.1 DEFINE PILE SECTIONS PROPERTIES

The three sections we are creating have diameters of 1.4 m, 1.2 m, and 1.0 m respectively with the same concrete strength of 40MPa.

To define the properties of each section:

  1. Select Piles > Pile Section Properties or click on the Pile Section with Pencil Icon Define Pile Section Properties icon in the toolbar.
  2. Define Pile Section Properties dialog

  3. Select Pile Section 1.
  4. The Pile Cross section shoud be set to Circular.
  5. Enter a diameter (m) of 1.4 m.
  6. Concrete Cylinder Strength (kPa) = 40000.
  7. Select Pile Section 2. The properties should be the same as Pile Section 1 but with a diameter of 1.2 m.
  8. Select Pile Section 3. The properties should be the same as Pile Section 1 but with a diameter 1 m.
  9. Click OK to close the dialog.

4.2 EDIT PILE TYPE

The defined pile sections can now be used in our Pile Type.

To define the Pile Type:

  1. Select Piles > Pile Types in the menu or click on the Pile Types Icon Define Pile Types button in the toolbar.
  2. Set the Cross Section Type to Uniform with Bell.
  3. Click on the Insert Below icon three times to insert Pile Section 2 and 3 and the Bell.
  4. Set the Length for each pile section to 5 m.
  5. Set the length of the bell to 1.93 m.
  6. Click on Define Bell Property.
  7. Edit Bell Property dialog

  8. Enter the following Bell Properties:
    • Base Diameter (m) = 1.5
    • Bell Angle = 60
    • Bell Base Thickness (m) = 0.5
    • Length Above Bell (m) = 1

    NOTE: the program will not allow you to have a bell with a different diameter from the section above the bell.

  9. Click OK to close the Bell Properties dialog and the click OK again to close the Pile Type Dialog.

4.3 ADD PILE

  1. Select Piles > Add Pile or click on the Add Single Pile icon Add Single Pile icon in the toolbar.
  2. Pile Type 1 should be selected by default.
  3. Click OK.
  4. Enter the Pile Location in the Prompt line at the bottom right of the screen as (0,0) or use your mouse to place the pile in the plan view.

5.0 Results

5.1 COMPUTE

Save and compute the file by clicking on the Calcuator icon Compute icon in the toolbar.

Image of computed results

5.2 GRAPH PILE

Detailed tables and charts of your results can be obtained by right clicking on the pile and choosing Graph Pile or by clicking on the Graph Pile icon in the toolbar and selecting the pile in the plan view.

Image of Graphed Pile

In the graph view you can see graphs for Skin Friction, End Bearing and Ultimate Capacity as well as a table of values below.

From the analysis for this example we have learned:

Ultimate skin resistance of the pile:

  • In the clay layer is 70 kPa.
  • In the sand layer is varied from 26.95 to 32.56 kPa.
  • The skin resistance is decreased to zero at the bell part.

Ultimate end bearing of the pile:

As laid at 16.93m below ground surface the enlarged base gave an ultimate unit end bearing resistance of 9899.85 kPa (note that it is still below the default cap of 10000). While the ultimate unit end bearing resistance in the clay layer was 900kPa.

Total ultimate capacity:

The total ultimate capacity of the pile is 21092.36 kPa as may be found at the bottom row of the capacity table.

Account Icon - click here to log in or out of your account Shopping Cart icon Click here to search our site Click here to close Learning Tech Support Documentation Info Chevron Delete Back to Top View More" PDF File Calendar Location Language Fees Video Click here to visit Rocscience's LinkedIn page Click here to visit Rocscience's YouTube page Click here to visit Rocscience's Twitter page Click here to visit Rocscience's Facebook page Click here to visit Rocscience's Instagram page Bookmark Network Scroll down for more Checkmark Download Print Back to top Single User Multiple Users CPillar Dips EX3 RocFall RocPlane RocSupport RocTopple RS2 RS3 RSData RSPile Settle3 Slide2 Slide3 SWedge UnWedge Commercial License Education License Trial License Shop safe & secure Money-back guarantee