Unit 1 - Site Investigation PDF

Summary

This document provides an introduction to site investigation (SI), a crucial process in foundation design. It covers important aspects like the objectives of site investigations and the program of site investigations. The document includes various methods and tools used in site investigation.

Full Transcript

SITE INVESTIGATION (Unit-1)

1
 Foundation Earth Structure Design
CE 438
Site Investigations
Contents
– Introduction
– Program of site investigation
– Planning

– Implementation

– Reporting
 Introduction

 What is Site Investigation (SI)?

 Why Site Investigation?

 Objectives of Site Investigation
Introduction

 What is site investigation (SI)?

The design of foundations of
structures (such as buildings,
bridges, and dams) generally
requires information about:
Structure
Structure
Ground Ground
 Introduction
 What is site investigation (SI)?
Site investigation (SI) or soil exploration is the process of gathering
information, within practical limits, about the stratification (layers) and
engineering properties of the soils underlying the proposed construction site.

The principal engineering properties of interest are the
strength, deformation, and permeability characteristics.

Drilling rig Structure

Site
Investigation Ground
Borehole

Layers
 Introduction
 Why site investigation (SI)?

Many engineering failures could have been avoided if a proper
site investigation had been carried out.

The site has a
sinkhole risk which
might have been
discovered in a
proper site
investigation

Sinkhole
 Introduction
 Why site investigation (SI)?
The success or failure of a foundation depends essentially on the reliability of
the knowledge obtained from the site investigation.
Sophisticated theories alone will not give a safe and sound design.
 Introduction
 Objectives of site investigation
The knowledge about the ground of the proposed construction site is
obtained by Site Investigation, and used to determine:

Design
Suitability: of site parameters: such
for the proposed as strength,
Effect of compressibility,
construction?
changes: How will permeability &

Site Investigation
the design affect other parameters
adjacent properties used for
and the ground geotechnical
water? design
Type of design Geo-materials:
solution: e.g. available on site
type of which can be re-
foundation: used?
shallow or deep.
Ground or Ground-water conditions: that would
affect the design and construction? e.g. expansive
soil, collapsible soil, high ground water…
 Introduction

 Objectives of site investigation

Suitability: of site for
the proposed
construction?
Effect of Design

Site Investigation
changes: Ho parameters: such
w will the as strength,
design affect compressibility,
adjacent permeability &
Manage the other parameters
properties and
the ground geotechnical used for
water? risk geotechnical
Type of design design
solution:
Geo- e.g.
type of
materials:
foundation:
available on
shallow or deep.
site which can
be re-used?
 Program of site investigation

 Before Site Investigation

 The sequence of Site Investigation
 Program
 Before Site Investigation
Site Investigation is usually carried out as part of Subsurface
Exploratory program.

Before conducting the Site Investigation, the program usually
include: Desk Study and Site Reconnaissance.

Site Reconnaissance
Visual inspection of the
site.
Desk Study
Collect and review
preliminary information
about the site, and the
structure to be built.
Program  Before Site Investigation

Desk Study
Collecting general information about the structure, from
the architectural and structural design:

Information about the Structure;
– Type, dimensions, and use of the
structure, and any special architectural
considerations.
Structure

– the load that will be transmitted by the
superstructure to the foundation system Ground

– the requirements of the local building
code (e.g. allowable settlement)
Program  Before Site Investigation

Desk Study
Collecting general information about the ground, from already existing
data such as: geological maps, seismic maps, Ariel Photography,
Services records (Gas, Water, Electricity), Previous geo-
environmental or geotechnical reports, … etc. at or near site.

Information about the ground:
– the geological conditions of the ground
(e.g. layers, Geological features, Ground
water, Flood & Earthquake risk in the area, Structure..).

– the historical use of the site – if Ground
previously used as quarry, agricultural
land, industrial unit with contamination
issue, man-made fill/slope, etc.
Ariel Photograph taken for a site – shows a possible sinkhole
Program  Before Site Investigation

Site Reconnaissance
The Site Reconnaissance is normally in the form of a walk-over survey of
the site.

What things
do I need to
look for?

Engineer during Site Visit
Program  Before Site Investigation

Site Reconnaissance
Important evidence to look for is:

1. Stratification of soil: from deep cut, such as those made for the
construction of nearby highway or other projects – if any.

2. Slope: signs of slope instability include bent trees, shrinkage cracks on the
ground and displaced fences or drains.

Stratification of soil Signs of slope instability
Program  Before Site Investigation

Site Reconnaissance
Important evidence to look for is:

3. Structures: type of buildings in the area and the existence of any cracks
in walls or other problems. You may need to ask local people.

Indication of
Tipping settlement Differential settlement possible ground-
(often without cracks) (with cracks) related problem
Program  Before Site Investigation

Site Reconnaissance
Other important evidence to look for is:
4. Mining: The presence of previous mining is often signs of
subsidence and possibly disused mine shafts. Open cast
mining is indicated by diverted streams replaced or removed
fence/hedge lines.
5. Hydrogeology: Wet marshy ground, springs or seepage,
ponds or streams and Wells.
6. Topography: possible existence of drainage ditches or
abandoned debris or other man-made features.
7. Vegetation: may indicate the type of soil.
8. Access: It is essential that access to the site can be easily
obtained. Possible problems include low overhead cables
and watercourses.
Program  The sequence of Site Investigation

Soil exploration is a requirement for the

Sequence of Site Investigation
design of foundations of any project.
In large construction projects, 2 site Planning
investigations (SI) are carried out:
– Preliminary SI, followed by
– Detailed SI.
Whether investigation is preliminary or Implementation
detailed, there are three important
phases:
Reporting
 Planning,
 Implementation and
 Reporting.
 Sequence of Site Investigation
Planning
Planning

 Why planning
Implementation

 Depth of investigation
Reporting
 Spacing of boreholes
 Planning
 Why planning?

How many borings do we need?
How deep the borings should be?
The more the better, but what about the cost?

Borehole
 Planning
 Why planning?
Planning for site investigation is required to:

Minimize cost of explorations and yet give reliable data.
Decide on quantity and quality depending on type, size and
importance of project and whether investigation is
preliminary or detailed.

Decide on minimum
depth and spacing of
Depth of Borehole Borehole Spacing
exploration.
 Planning
 Depth of investigation

In general, depth of investigation should
be such that any/all strata that are likely to

Depth of Borehole
experience settlement or failure due to
loading.
The estimated depths can be changed
during the drilling operation, depending
on the subsoil encountered.
To determine the approximate minimum
depth of boring, engineers may use the
following rules:
 Planning
 Depth of investigation
Determination of the minimum depth of boring
1. Determine the net increase of stress,  under a foundation with depth as
shown in the Figure.
2. Estimate the variation of the vertical effective stress, ‘0 , with depth.
3. Determine the depth, D = D1, at which the stress increase ’ is equal to
(1/10) q (q = estimated net stress on the foundation).
4. Determine the depth, D = D2, at
which /'0 = 0.05.
5. Unless bedrock is encountered, the
smaller of the two depths, D1 and q
D2, is the approximate minimum
depth of boring required.
D
Example
A 1.25 m square footing is subjected to a contact
pressure of 300 kN/m². The unit weight of the cohesive
soil supporting the footing is 18.5 kN/m³ and
groundwater is known to be at a depth. Determine the
minimum depth of boring that should be carried out in  0’
the site  ’
 Depth of Boring
For hospitals and office buildings, the following rule could be use to determine
boring depth.
The approximate required minimum depth of the borings should be predetermined.
The estimated depths can be changed during the drilling operation, depending on
the subsoil encountered.
To determine the approximate minimum depth of boring, engineers may use the
following rule:

Db=3S0.7 (for light steel or narrow concrete buildings)

Db=6S0.7 (for heavy steel or wide concrete buildings)

Where:
Db = Depth of Boring, in meters

S = Number of Stories
When deep excavations are anticipated, the depth of boring should be at, least 1.5
times the depth of excavation.
Sometimes subsoil conditions are such that the foundation load may have to be
transmitted to the bedrock.
The minimum depth of core boring into the bedrock is about 3m.
If the bedrock is irregular or weathered, the core borings may have to be extended
to greater depths.
 Exercise
Planning Site investigation is to be made for a structure of 100
 Depth of investigation m length and 70 m width. The soil profile is shown
below, if the structure is subjected to 200 kN/m2.
Determine the approximate depth of borehole (Assume
γw = 9.81 kN/m3).
Table shows the minimum depths of borings for buildings based on
the preceding rule.

Building Number of Stories
width
(m)
Depth of Boring

What do you notice about this
table?
Planning  Spacing of boreholes
There are no strict or no hard and fast rules rules for the spacing of the
boreholes.
The following table gives some general guidelines for borehole spacing.
These spacing can be increased or decreased, depending on the subsoil
condition.
If various soil strata are more or less uniform and predictable, the number
of boreholes can be reduced.

Type of project Spacing (m)

What do you notice
about this table?

27
 Implementation

Sequence of Site Investigation
 Overview Planning
 Boring
 Sampling
Implementation
 Testing

Reporting
 Implementation

 Overview
The implementation phase of site investigation usually includes three
important aspects:

1 2 3

Boring Sampling Testing

Trial pits Soil In-situ
Sampling tests

Rock Laboratory
Boreholes
Sampling tests
 Implementation

 Boring

1 2 3

Boring Sampling Testing

Trial pits Soil In-situ
Sampling tests

Rock Laboratory
Boreholes
Sampling tests
Implementation  Boring
Trial pits
Trial pits are shallow excavations - less
than 6m deep.
The trial pit is used extensively at the Pick and
surface for block sampling and shovel Backhoe
detection of services prior to
borehole excavation.
For safety ALL pits below a depth of
1.2m must be supported.
Trial Pit
Depth Excavation Method 6m > depth
0-2m By Hand
2-4m Wheeled Back Hoe
4-6m Hydraulic Excavator
 Implementation  Boring
Boreholes
Boreholes may be excavated by one of these methods:

1. Auger Boring
2. Wash Boring
3. Rotary Drilling
4. Percussion Drilling
Borehole
The right choice of method depends on:
– Ground condition: presence of hard
clay, gravel, rock.
– Ground-water condition: presence of
high ground-water table (GWT).
– Depth of investigation
– Site access
Implementation  Boring
Boreholes
1. Auger Boring
Power driven augers
This is the simplest of the methods. Hand
operated or power driven augers may be used.
Suitable in all soils above GWT but only in
cohesive soil below GWT.

Hand operated augers

Post hole auger Helical auger
Implementation  Boring
Boreholes
2. Wash Boring

A casing is driven with a drop
hammer. A hollow drill rod with
chopping bit is inserted inside the
casing.
Soil is loosened and removed from
the borehole using water or a drilling
mud jetted under pressure.
Wash boring is a very convenient
method for soil exploration below
the ground water table provided the
soil is either sand, silt or clay. The
method is not suitable if the soil is
mixed with gravel or boulders.
Implementation  Boring
Boreholes
3. Percussion Drilling

In this method a heavy drilling bit
is alternatively raised and
dropped in such a manner that it
powders the underlying materials
which form a slurry with water
and are removed as the boring
advances.
Possibly this is the only method
for drilling in river deposits mixed
with hard boulders of the
quartzitic type.
 Implementation  Boring
Boreholes
4. Rotary Drilling

In this method a rapidly retaining Movement
drilling bit (attached to a drilling rod) transmitter
cut the soil and advance the borehole.
When soil sample is needed
the drilling rod is raised and Rotary Head
the drilling bit is replaced by
a sampler.
Drilling rod
This method is suitable
for soil and rock.
Drilling bit
 Implementation

 Sampling

1 2 3

Boring Sampling Testing

Trial pits Soil In-situ
Sampling tests

Rock Laboratory
Boreholes
Sampling tests
Implementation  Sampling
Soil sampling

Samples from each type of soils are required for laboratory testing to
determine the engineering properties of these soils.
Soil samples are recovered
carefully, stored properly to
prevent any change in physical
properties, and transferred to
laboratory for testing.

Soil Sampling equipment?

Disturbed vs Undisturbed?
Implementation  Sampling
Soil sampling
Soil Sampling equipment

There is a wide range of sampling methods such as Split-spoon sampler,
Thin-walled Tube. The choice of method depends on:
The requirement of disturbed or undisturbed samples
Type of soil discovered at site (Gravel, Sand, Silt, Clay)

Split-spoon Sampler

Soil Sample
advancement
Implementation  Sampling
Soil sampling
Soil Sampling equipment
 Implementation  Sampling

Soil sampling
Disturbed vs Undisturbed Samples

Two types of soil samples can be obtained during sampling: disturbed
and undisturbed.
The most important engineering
properties required for foundation
design are strength,
compressibility, and permeability.
These tests require undisturbed
samples.
Disturbed samples can be used for
determining other properties such
as Moisture content, Classification
& Grain size analysis, Specific
Gravity, and Plasticity Limits.
 Implementation  Sampling
Soil sampling
Disturbed vs Undisturbed

It is nearly impossible to obtain a truly undisturbed sample of soil.
The quality of an "undisturbed" sample varies widely between soil
laboratories. So how is disturbance evaluated?

Quality of samples is evaluated by calculating
Area Ratio AR:

soil

The thicker the wall of the sampling tube, the
greater the disturbance.
Good quality samples AR < 10%. Sampling tube
 Implementation  Sampling
Soil sampling
Disturbed vs Undisturbed Samples

Samples collected in Split-spoon Sampler is usually classified as “disturbed”.
What is the Area Ratio?

Area Ratio AR = ----------------- =
Implementation  Sampling

Rock Sampling (Coring)

Rock samples are called “rock cores”, and
they are necessary if the soundness of the
rock is to be established.

Core drilling equipment?

Core recovery parameters?
 Implementation  Sampling
Rock Sampling (Coring)
Core drilling equipment Drill rod

Coring is done with either
tungsten carbide or diamond
core bits.
Inner
Rock sampler is called “core Core barrel
barrel” which usually has a barrel Outer

Rock

Rock
single tube. barrel

Rock

Rock
Double or triple tube core
barrel is used when sampling Rock
of weathered or fractured core
rock. Coring
bit

Diamond Drill Bit
(a) (b)
Core barrel:
45 (a) Single-tube; (b) double-tube
Implementation  Sampling
Rock Sampling (Coring)
Core drilling equipment

Cores tend to break up inside the drill
barrel, especially if the rock is soft or
fissured.
Core recovery parameters are used to
describe the quality of core.
Length of pieces of core are used to
determine:
– Core Recovery Ratio (Rr)
– Rock Quality Designation (RQD)
Rock cores
 Implementation  Sampling
Rock Sampling (Coring)
Core drilling equipment

Assuming the following pieces for a given core run:

Core recovery (lengths of intact pieces of core)
Rr Recovery Ratio, Rr
(Core run)
Rock Quality Designation, RQD

10 L i
= 100% ( L i ≥ 10 cm )
(Core 47
run) L
 Implementation  Sampling

Rock Sampling (Coring)
Core recovery parameters

So Rock Quality Designation (RQD) is the percentage of rock cores that have
length ≥ 10 cm over the total drill length (core run).

RQD may indicate the degree of
jointing or fracture in a rock mass. e.g.
High-quality rock has an RQD of more
than 75%.
RQD is used in rock mass classification
systems and usually used in estimating
support of rock tunnels.
Implementation  Sampling
Rock Sampling (Coring)
Core recovery parameters

Class Example
Work out Rr and RQD for the following
core recovery (intact pieces),
assuming the core run (advance) is
150 cm.

What is the rock mass quality based
on RQD?
 Implementation  Sampling
Rock Sampling (Coring)
Core recovery parameters

Solution:
Total core recovery L = 125 cm
Core recovery ratio:
Rr = 125/150 = 83% ?

On modified basis (for pieces ≥
10cm), 95 cm are counted, thus:

L i
RQD = 100% = 95/150 = 63 %
L
RQD = 50% - 75%  Rock mass
quality is “Fair”
L= ? L i ?
Implementation  Testing

1 2 3

Boring Sampling Testing

Trial pits Soil In-situ
Sampling tests

Rock Laboratory
Boreholes
Sampling tests
Implementation  Testing

In-situ tests
Introduction Plate Load Test (PLT)
Groundwater measurements Pressure-meter Test (PMT)
Standard Penetration Test (SPT) Flat Dilatometer Test (DMT)
Cone Penetration Test (CPT) Vane shear test (VST)
The Borehole Shear Test (BST).

PLT
Piezometer

In Borehole 52
Implementation  Testing : In-situ tests

Introduction

Definition:
In-situ tests are carried out in the field with intrusive testing
equipment.
If non-intrusive method is required, then it is better to use
geophysical methods which use geophysical waves – i.e. without
excavating the ground.
Advantage of in-situ testing (against lab testing)
It avoids the problems of sample recovery and disturbance
some in-situ tests are easier to conduct than lab tests
In-situ tests can offer more detailed site coverage than lab testing.
Testing standards
American Society for Testing and Materials (ASTM)
British Standard (BS)
Implementation  Testing : In-situ tests

Groundwater measurements

Why Groundwater: Standpipe

Groundwater conditions are fundamental Ground
factors in almost all geotechnical analyses water level
and design studies.

Types of Groundwater measurements:
Determination of groundwater levels (GWT)
and pressures. Borehole instrumented with
Piezometer is used for this purpose.

Measurement of the permeability of the
subsurface materials, particularly if seepage
Piezometer
analysis is required. The test called Pumping
test.
 Implementation  Testing : In-situ tests

Standard Penetration Test (SPT)
Definition

This empirical test consists of driving a split-
Falling
spoon sampler, with an outside diameter of 50 Hammer
mm, into the soil at the base of a borehole.
760 mm
Drivage is accomplished by a trip hammer,
weighing 65 kg, falling freely through a distance Drive head
of 760 mm onto the drive head, which is fitted
at the top of the rods.
The split-spoon is driven three times for a
distance of 152.4 mm (6 in) into the soil at the
bottom of the borehole. The number of blows
required to drive (only) the last two 152.4 mm Slit
are recorded. The blow count is referred to as spoon
the SPT-N. 152.4 mm (6 in) x 3 times
The first one does not count
Implementation  Testing : In-situ tests

Standard Penetration Test (SPT)
Advantage

Relatively quick, simple, reasonably cheap, and
suitable for most soils.
Good correlation between SPT-N and soil
properties.
Provides a representative soil sample for further
testing.

Disadvantage
SPT does not typically provide continuous data
Limited applicability to soil containing cobbles
and boulders.
Samples obtained from the SPT are disturbed.
SPT N blow require correction
 Implementation  Testing : In-situ tests

Standard Penetration Test (SPT)
Corrections for energy and equipment

Corrections are normally applied to the SPT blow count (N) to account for:
– Energy loss: during the test (about only 60% of energy remains)
– Equipment differences: hammer, sampler, borehole diameter, rod

The following equation is used to compensate for these factors:

(usually 0.50-0.80)
(1.0-1.15)
60% (0.8-1.0)
(0.75-1.0)

Usually this correction is made by the Site Investigation operator.
Implementation  Testing : In-situ tests

Standard Penetration Test (SPT)
Corrections for overburden pressure

In granular soil (sand, gravel) the SPT blows are influenced by the effective
overburden pressure at the test depth:

CN = overburden pressure correction factor

Many equations have been suggested for CN – see Page 86, (Das’s text
book). For example:
Correlation between CN, o’ and Pa
Correlation between CN, o’ and Pa
Correlation between CN, o’ and Pa
 Implementation  Testing : In-situ tests

Standard Penetration Test (SPT)
Correlation between N and friction angle
There are many equations suggested. The figure shows the correlation
with the angle of shearing resistance of sand (according to Pecks, 1974).
Corrected SPT N blow

Angle of shearing resistance ’ (degree)
Implementation  Testing : In-situ tests

Standard Penetration Test (SPT)
Class example

The following are the recorded numbers of SPT blows required for spoon
penetration of three 152.4cm (6 in) in a sand deposit:
Depth from ground 1.5 3 4.5 6 7.5
surface (m)
SPT blows (blow/ 6 in) 3, 4, 5 7, 9, 10 7, 12, 8, 13, 10, 14,
11 14 15
Note. Assume the above SPT blows are corrected for energy and equipment.
The ground water table (GWT) is located at a depth of 4.5m. The wet unit weight
of sand above GWT is 18 kN/m3, and the saturated unit weight of sand below
GWT is 19.81 kN/m3.
Draw a sketch of the foundation showing the given details of the soil.
Determine the standard penetration number (SPT-N) at each depth.
What is the corrected (SPT-N) value? (use Seed’s equation).
Determine the friction angle at depth 4m below the footing. (Use Peck’s
Equation or Chart).
 Implementation  Testing : In-situ tests

Standard Penetration Test (SPT)
Solution
Z, SPT
m blow N60 ’ (kPa) CN N ’

2 1.5 3, 4, 5 4+5=9 1.5x18 =27 0.27 1.7 15.3 29.79o

3 7, 9, 10 9+10=19 54 0.54
=18 kN/m3
7, 12,
4
4.5 11 23
8, 13,
sat=19.8 kN/m3 6 14 ?
10, 14,
7.5 15
Z
Only the last 2 sets of blows count

Corrected
 Implementation  Testing : In-situ tests

Standard Penetration Test (SPT)
Correlation between N and undrained shear strength

The corrected SPT N blow can be approximately correlated to many important
engineering properties of soil such as shear strength & compressibility.
This equation shows the correlation with undrained shear strength Su (or Cu)
of clay. (also with OCR = Over Consolidation Ratio).
In Clay
 Implementation  Testing : In-situ tests

Standard Penetration Test (SPT)
Correlation between N and undrained shear strength

The table shows the correlation corrected SPT-N with undrained shear
strength Su (or Cu) of clay (according to Terzaghi et al. 1996)
Correlation between N60 and Relative
Density of Granular Soil
Correlation between N60 and Relative
Density of Granular Soil
Correlation between N60 and Relative
Density of Granular Soil
Correlation between Angle of Friction and
Standard Penetration Number
Correlation between Angle of Friction and
Standard Penetration Number

71
Correlation between Modulus of Elasticity and
Standard Penetration Number
Implementation  Testing : In-situ tests

Standard Penetration Test (SPT)
Class Example

the Figure
shown below
Implementation  Testing : In-situ tests

Standard Penetration Test (SPT)
Solution

Z, m N60 ’ (kPa) Cu (kPa) ’ (MPa) OCR

1.5x16.5+ 100x0.29 38.5/1000= 0.193x(5/
3 5 1.5x(19-9.81) = 38.5 x50.72 =92.3 0.0385 0.038)0.689 = 5.5
38.5+1.5x(16.5-
4.5 8 9.81) = 48.5 129.6 0.0485

6 8

7.5 9

9 10
Cu -av = OCRav =
 Implementation  Testing : In-situ tests

Standard Penetration Test (SPT)
Correlation between N and Relative Density Dr
correlation between N60 and Relative Density of Granular Soil

General For Clean sand only
Implementation  Testing : In-situ tests

Standard Penetration Test (SPT)
Correlation between N and Relative Density Dr

Very loose
Loose
Medium
Dense
 Implementation  Testing : In-situ tests

Standard Penetration Test (SPT)
Correlation between Modulus of Elasticity and Standard Penetration Number

The modulus of elasticity of granular soils (Es) is important parameter in
estimation the elastic settlement of foundation.
An approximate estimation for Es was given by Kulhawy and Mayne
(1990) as:
Principles of Foundation Engineering, 8th edition Das

Vane Shear Test
The vane shear test may be used during the drilling operation to
determine the in situ undrained shear strength (c )of clay soils—
u
particularly soft clays.
Torque is applied at the top of the rod to
rotate the vanes at a standard rate of
0.1o/sec.
Rotation will induce failure in a soil of
cylindrical shape surrounding the vanes.
The maximum torque, T, applied to cause
failure is measured.
T
Cu = C u = in situ undrained shear strength
K
K = vane constant
78 © 2016 Cengage Learning Engineering. All Rights Reserved.
Principles of Foundation Engineering, 8th edition Das

Vane Shear Test
For rectangular Vanes
For tapered vanes
2
pd
d
K= (h + ) d
d 2
d
2 3 K (   6h)
3
12 cos iT cos iB
If h/d = 2 then K = 7p d iB and i are angles defined in the shear
T
Advantages: 6 vane picture.
Moderately rapid
Economical
Gives good results in soft and medium-stiff
clays
Excellent in determining the properties
of sensitive clays

Errors:
Poor calibration of torque measurement
Damaged vanes.
If rate of rotation of the vane is not properly controlled, other errors can be introduced
79 © 2016 Cengage Learning Engineering. All Rights Reserved.
Principles of Foundation Engineering, 8th edition Das

Vane Shear Test
Undrained shear strength values from vane shear tests are too
high.
Values are corrected according to the equation
' 0.83
s = 7.04[Cu( field ) ]
c l = correction factor
Most common equation for correct factor
l = 1.7 - 0.54log[PI%]
Relationship for estimating the preconsolidation pressure of a
natural clay deposit C = lC u(corrected ) u
'
s c
= Preconsolidation pressure (kN /m2 )
Cu( field ) = Field vane shear strength (kN /m2 )

80 © 2016 Cengage Learning Engineering. All Rights Reserved.
Principles of Foundation Engineering, 8th edition Das

Vane Shear Test
Relationship for overconsolidation ratio (OCR).
Cu( field )
OCR = b

s o'

The value of b is determined by any of the equations

-0.48
b = 22[PI(%)]

1 222
b= b=
0.08 + 0.0055(PI) w(%)
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Principles of Foundation Engineering, 8th edition Das

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Principles of Foundation Engineering, 8th edition Das

Cone Penetration Test
Formally known as Dutch cone penetration test.
Also currently referred to as static penetration test.
Versatile sounding method
Used to determine the materials in a soil profile.
Estimates material engineering properties.
No boreholes are necessary.

Penetrometers measure
Cone resistance (qc) to penetration
Equal to vertical force applied to the cone, divided by its horizontally
projected area.
Frictional resistance ( f c )
Resistance measured by a sleeve located above the cone with the local
soil surrounding it.

Equal to the vertical force applied to the sleeve, divided by its surface area (the sum of
friction and adhesion).
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Principles of Foundation Engineering, 8th edition Das

Cone Penetration Test
Two types of penetrometers
Mechanical friction-cone penetrometer

Electric friction-cone penetrometer

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Principles of Foundation Engineering, 8th edition Das

Cone Penetration Test
Mechanical friction-cone penetrometer
The tip of this penetrometer is connected to an inner set of rods.
Tip is first advanced about 40 mm, giving the cone resistance.
Further thrusting engages the friction sleeve.
As inner rod advances, the rod force is equal to the sum of the vertical force on the cone
and sleeve.
Subtracting the force on the cone gives the side resistance.

Electric friction-cone penetrometer
The tip is attached to a string of steel rods.
The tip is pushed into the ground at the rate of 20 mm/sec.
Wires from the transducers are threaded through the center of the rods and continuously
measure the cone and side resistances.

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Principles of Foundation Engineering, 8th edition Das

Cone Penetration Test
Several correlations useful in estimating the properties of soils for
the point resistance and the friction ratios.

fc
Fr = (frictional resistance)/(cone resistance)=
qc
Fr (%) = 1.45 - 1.36log D50 (electric cone)

Fr (%) = 0.7811 - 1.611logD50 (mechanical cone)

D50 = size through which 50% of soil will pass through
(mm) – Size ranges 0.001 mm to 10 mm

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 Principles of Foundation Engineering, 8th edition Das

Correlation between Relative Density(Dr )and qc
for Sand
OCR = Overconsolidation Ratio

qc
pa = atmospheric pressure
1 pa
Dr  [ ' ]
305Qc OCR 1.8
 o 0.5
( )
Qc = compressibility factor

pa
Recommended Values of Qc qc
Dr (%) = 68[log( ) - 1]
Highly compressible sand = 0.91 pa.s 0'
Moderately compressible sand = 1.0
Low compressible sand = 1.09 pa = Atmospheric Pressure
'
87
s o = Vertical effective stress
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Principles of Foundation Engineering, 8th edition Das
'
Correlation between qc and Drained Friction Angle for f
Sand

' -1 qc
f = tan [0.1 + 0.38log( '
)]
s o

' -1 qc
f = tan [0.38 + 0.27og( '
)]
so
Correlations using horizontal
'
effect stress ( s h)

' qc 0.1714
f = 15.575( '
)
sh
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Principles of Foundation Engineering, 8th edition Das

Correlation between q and N
c 60

qc a Values for C and a are found in the table.
( )/ N60 = cD50

pa

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Principles of Foundation Engineering, 8th edition Das

Correlations for Undrained Shear Strength ( C ), Preconsolidation
s ' u
Pressure ( c), and Overconsolidation Ratio (OCR) for Clays

Undrained shear strength is determined by the equation
qc - s o
Cu =
Nk
s o = total vertical stress
Nk = bearing capacity factor

The value of N can vary form 11 to 19.
k

90 © 2016 Cengage Learning Engineering. All Rights Reserved.
Principles of Foundation Engineering, 8th edition Das

Correlations for Undrained Shear Strength ( C u ), Preconsolidation
Pressure (s c'), and Overconsolidation Ratio (OCR ) for Clays

'
Correlations for preconsolidation pressure (s ) and overconsolidation ratio
c
(OCR)

' 0.96
s = 0.243(qc )
c

qc - s o 1.01 qc
OCR = 0.37( '
) '
f = 15.575( )0.1714
s o s h'

 oand '
o= total and effective stress, respectively

© 2016 Cengage Learning Engineering. All Rights Reserved.

91
Implementation  Testing : In-situ tests

Cone Penetration Test (CPT)

Advantages:
Borehole is not necessary
Almost continuous data (reading every 10mm)
Elimination of operator error (automated)
Reliable, repeatable test results

Disadvantages:
Inability to penetrate through gravels and
cobbles
Newer technology = less populated database
than SPT
Lack of sampling
Implementation  Testing : In-situ tests

Cone Penetration Test (CPT)
Class example: Correlation with shear strength

Use equation proposed
93 by Ricceri et all’s. 2002.
 Implementation  Testing: In-situ tests

Cone Penetration Test (CPT)
Solution:

Depth, qc (MPa)
m ’ (kPa) qc /’ ’ (Rad) ’ (deg)

1.5 2.06 1.5 x 16 =24 2060 / 24 = 85.8 0.69 0.69x180/=40o

3 4.23 48 88.1

4.5 6.01
6 8.18
7.5 9.97

9.0 12.42 ’av =

94
Note. tan -1 is inverse tangent, the angle returned is in Radian.
’av = ’ / 6
 Implementation  Testing : In-situ tests

Plate Load Test (PLT)

Plate load test is a field test
to determine the ultimate
bearing capacity of soil.

The test essentially consists
in loading a rigid steel plate
at the foundation level and
determining the settlement
corresponding to each load
increments.
The ultimate bearing capacity is
then taken as the load at which the
plate starts sinking at a rapid rate.
95
Student Practice

Principles of Foundation Engineering by
Braja M. Das Page 126-130.

96
Implementation  Testing

Laboratory tests

Basic physical properties tests (Moisture
content, Specific gravity, Soil Indexes,..)
Particle size test (sieving, Sedimentation)
Direct shear box test
Unconfined compression test
Triaxial test
Consolidation test
Permeability test
Other lab tests: Chemical test (pH,
contamination,..)

97
 Reporting

Sequence of Site Investigation
Planning
 Preparation of Borehole
 Site Investigation Report
Implementation

Reporting
Reporting  Preparation of Boring Logs

Initial information: Name
and address of the drilling
company, Driller’s name, Job
description and reference
number, boring information
(number, type, and location
of, and date of boring).

Example of a typical boring log
 Reporting  Preparation of Boring Logs

Subsurface stratification:
which can be obtained by
visual observation of the soil
brought out by auger, split-
spoon sampler, and thin-
walled Shelby tube sampler.

Groundwater: Elevation of
water table and date
observed, use of casing and
mud losses, and so on
Reporting  Preparation of Boring Logs

In-situ tests:
Standard penetration
resistance and the
depth of SPT

Samples: Number, type,
and depth of soil sample
collected; in case of rock
coring, type of core barrel
used and, for each run, the
actual length of coring,
length of core recovery, and
RQD.
Reporting  Preparation of Boring Logs

Class example

The following borehole is part of a site investigation (SI) carried
out over a proposed location of a bridge.
Assess the subsoil conditions and ground-water conditions based
on the borehole data.
In particular write about:

Soil layers: types, description, depth…
Soil properties: shear strength properties -based on SPT.
Ground water depth
103
 Reporting  Site Investigation Report

When: After the completion of
all of the field and laboratory
work, a site investigation report
is prepared.
Why: for the use of the design
office and for reference during
future construction work.
The report is also called soil
exploration report or
Geotechnical Factual report.

What should be included in the site investigation report?
 Reporting  Site Investigation Report

The report should contain descriptions of the followings:

Purpose & Scope of the investigation
Site & Structure: site location, existing structures, drainage conditions,
vegetation,… and information about the structure.
Factual Details of field exploration: boreholes, samples, and testing.

Usually given in another report
(Geotechnical Design Report)
For each type, quantities, method, tools should be presented.
Geological setting of the site (variation of depth and thickness of layers
as interpreted from the borings)
Subsoil and water-table conditions, (soil parameters as interpreted
from the testing results).
Design analysis & recommendations: type of foundation, allowable
bearing pressure, settlement estimation, and any special construction
procedure; alternatives design solution.
Conclusions and limitations of the investigations
Reporting  Site Investigation Report
The following graphical presentations must be
attached to the report:

1. General map showing site location
2. A plan view of the location of the borings
with respect to the proposed structures
and those nearby
3. Boring logs (including in-situ tests results
and samples)
4. Laboratory test results
5. Other graphical presentations
(geotechnical cross section based on the
boring logs, photos of the field work and
soil samples,…)
Reporting  Site Investigation Report
Geotechnical cross section based on the boring logs