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Chapter 2. SOIL INVESTIGATION METHODS
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2.1
Standard Penetration Test (SPT)
The
SPT is a well-established and unsophisticated method, which was developed
in the United States around 1925. It has since undergone refinements with
respect to equipment and testing procedure. The testing procedure varies in
different parts of the world. Therefore, standardisation of SPT was
essential in order to facilitate the comparison of results from different
investigations. The equipment is simple, relatively inexpensive and rugged.
Another advantage is that representative but disturbed soil samples are
obtained. The reliability of the method and the accuracy of the result
depend largely on the experience and care of the engineer on site.
A
split-barrel sampler is driven from the bottom of a pre-bored hole into the
soil by means of a 63.5 kg hammer, dropped freely from a height of 0.76 m.
The diameter of the pre-bored hole varies normally between 60 and 200 mm.
If the hole does not stay open by itself, casing or drilling mud should be
used. The sampler is first driven to a depth of 15 cm below the bottom of
the pre-bored hole, then the number of blows required to drive the sampler
another 30 cm into the soil, the so called N30 count, is recorded. The rods
used for driving the sampler should have sufficient stiffness. Normally,
when sampling is carried out to depths greater than around 15 m, 54 mm rods
are used.
The
quality of test results depends on several factors, such as actual energy
delivered to the head of the drill rod, the dynamic properties (impedance)
of the drill rod, the method of drilling and borehole stabilisation. The
actually delivered energy can vary between 50 - 80% of the theoretical
free-fall energy. Therefore, correction factors for rod energy (60 %) are
commonly used, Seed and De Alba (1986). The SPT can be difficult to perform
in loose sands and silts below the ground water level (typical for land
reclamation projects), as the borehole can collapse and disturb the soil to
be tested. The following factors can affect the test results: nature of the
drilling fluid in the borehole, diameter of the borehole, the configuration
of the sampling spoon and the frequency of delivery of the hammer blows.
Therefore, it should be noted that drilling and stabilisation of the
borehole must be carried out with care. The measured N-value (blows/0.3 m)
is the so-called standard penetration resistance of the soil. The
penetration resistance is influenced by the stress conditions at the depth
of the test. Peck et al. (1974) proposed, based on settlement observations
of footings, the following relationship for correction of confinement
pressure. The measured N-value is to be multiplied by a correction factor CN to obtain a reference
value, N1, corresponding to an effective overburden stress of 1
t/ft2 (approximately 107 kPa),
where CN is a stress correction factor and p' is the effective
vertical overburden pressure.
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CN =
0.77 . log10 (20/p')
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(2)
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Seed
(1976) proposed a similar correction factor for the assessment of
liquefaction problems in loose saturated sands. This relationship was
developed for earthquake problems and is based on extensive laboratory
tests on mainly loose to medium dense sands,
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CN =
1- 1.25. log10 (s 0'/s 1')
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(3)
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where s 0' is the effective overburden
pressure (in t/ft2) and s 1' is the reference
stress (1 t/ft2). The correction of SPT results with respect to the
effective overburden pressure is of importance for the evaluation of
compaction results. Therefore, consideration should be given to this aspect
when compaction criteria are to be based on N-values. Unfortunately, this
fact is not always appreciated.
The
resistance (N30) has been correlated with the relative density of granular
soils. Sand and gravel can be classified as shown in Table 1, Broms (1986).
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Relative Density
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Standard Penetration Resistance
(N30, blows/0.3 m)
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Loose
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£ 10
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Medium Dense
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10 - 30
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Dense
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³ 30
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Table
1. Classification of
sand and gravel after Broms (1986)
The
Standard Penetration Test is mainly used to estimate the relative stiffness
and strength (bearing capacity) of soils. Deformation characteristics of
granular soils can be estimated from empirical correlations, Peck et al.
(1974). It is also possible to get some indications from SPT of the shear
strength in cohesive soils. The SPT used frequently for the evaluation of
the liquefaction potential of water-saturated, loose sands and silts in
seismic areas, Seed and De Alba (1986).
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2.2 Cone Penetration Tests (CPT)
The CPT was invented and developed in Europe but
has gained increasing importance in other parts of the world, especially in
connection with soil compaction projects. Different types of mechanical and
electric cone penetrometers exist but the electric cone is most widely used. A
steel rod with a conical tip (apex angle of 60° and a diameter of 35.7 mm) is
pushed at a rate of 2 cm/s into the soil. The steel rod has the same diameter
as the cone. The penetration resistance at the tip and along a section of the
shaft (friction sleeve) is measured. The friction sleeve is located immediately
above the cone and has a surface area of 150 cm2. The electric CPT is provided
with transducers to record the cone resistance and the local friction sleeve.
A CPT probe, equipped with a porewater pressure
sensor is called CPTU. It is important to assure complete saturation of the
filter ring of the porewater (piezo) element. Otherwise, the response of the
piezo-transducer, which registers the variation of pore water pressure during
penetration, will be slow and may give erroneous results. The CPTU offers the
possibility to determine hydraulic soil properties (such as hydraulic
conductivity - permeability) but is most widely used for identification of soil
type and soil stratification. The CPT can also be equipped with other types of
sensors, for example vibration sensors (accelerometer or geophone) for
determination of vibration acceleration or velocity. The "seismic
cone" is not yet used on a routine basis but has, because of the relative
simplicity of the test, potential for wider application especially on soil
compaction projects.
The CPT is standardised and the measurements are
less operator-dependent than the SPT, thus giving more reproduceable results.
The recent geotechnical literature contains comprehensive information about
different types of cone penetration tests, detailed descriptions of the test
procedures and data evaluation/interpretation, Lunne et al. (1998). Therefore,
only some aspects of importance for soil compaction projects will be discussed
below.
The CPT measures the cone resistance qc and the sleeve friction fs from which the friction ratio, FR can be determined. FR is the
ratio between the local sleeve friction and the cone resistance, expressed in
percent (fs/qc). In spite of the limited accuracy of
sleeve friction measurements, the valuable information, which can be obtained
in connection with compaction projects, has not yet been fully appreciated. As
will be discussed below, the sleeve friction measurement reflects the variation
of lateral earth pressure in the ground, and can be used to investigate the
effect of soil compaction on the state of stress, as will be discussed later.
Cone and sleeve friction measurements are also strongly affected by the effective
overburden pressure. It is necessary to take this effect into account, similar
to the SPT. A correction factor CM for the cone resistance was proposed by
Massarsch (1994),
where s m' is the mean effective stress. It should be noted that for SPT
correction the overburden pressure is used, which does not take into
consideration the effect of lateral earth pressure. The mean effective stress
can be determined from
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s m' = s v' (1+2 Ko)
/ 3
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(5)
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where s v' is the vertical effective stress and Ko is the
coefficient of lateral earth pressure at rest. Figure 3 compares the different
correction factors for SPT and CPT, respectively. It should be noted that for
Massarsch uses the mean effective stress while the SPT correction factor is
based on the vertical effective stress.
Figure 3. Stress correction factors CN (SPT) and CM (CPT) with KO = 0,57, cf. equation (1, 2 and 3)
The measured cone penetration resistance, qc can be corrected for the
effect of the mean effective stress sm' at any given depth
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qco =
qc CM = qc (100 / s m')0.5
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(6)
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where qco is the
normalised cone penetration value. When considering the difference between the
vertical and the mean effective stress, there is good agreement between the
different correction factors for the SPT and CPT, respectively. However, as
will be shown later, soil compaction can significantly increase the horizontal
stress and this effect should be taken into consideration when evaluating the
densification effect. It is recommended to limit the correction factor CM to a value of 2,5. It is suggested that the corrected cone resistance qco be used
for specification of compaction criteria, as this will assure more homogeneous
soil layers and avoid unnecessary overcompaction close to the ground surface.
One important objective of the CPT
investigations in connection with soil compaction is to obtain information
concerning soil stratification and variation in soil properties both in
horizontal and vertical direction. The friction ratio is often used as an
indicator of soil type (grain size) and can provide valuable information when
evaluating alternative compaction methods.
Measurement of the excess pore water pressure
with the CPTU can detect layers and seams of fine-grained material (silt and
clay). It is also possible to obtain more detailed data information concerning
soil permeability and thus soil stratification.
2.3
Comparison between SPT and CPT
In
areas like North America, many geotechnical engineers have developed
considerable design experience, based on local correlation between the SPT and
performance of foundations. Therefore, engineers may feel more comfortable by
converting CPT data to equivalent SPT N-values and then comparing these with
their SPT-based design methods. A considerable number of studies have been
carried out in the past to quantify the relationship between SPT N-value and
CPT cone bearing resistance (qc), Robertson and Campanella (1986).
The author has compiled data from various case histories, which are compared in
fig. 4 with the data published by Robertson and Campanella (1986).
In
spite of some scatter between individual test points and different soil types,
there exists a clear correlation between the qc /N ratio and the mean particle size.
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2.4
Pressuremeter Test (PMT)
The
PMT was invented by the Menard in 1962 - 1963 in France, where this test is
widely used. National standards exist and geotechnical design is based
almost exclusively on this type of test. Over the years the PMT has been
further developed in France, the United Kingdom and Japan, and has found
increasing acceptance in several countries. However, the PMT is still a
specialist tool, which requires experience in test performance and data
interpretation.
The
standard pressuremeter is either inserted into a pre-bored hole or directly
jacked or driven into the ground. A slotted tube protects the measuring
cell, which consists of a cylindrical rubber membrane. In order to reduce
the influence of soil disturbance during probe insertion, the self-boring
pressuremeter was developed. This type of pressuremeter is, however,
limited to fine-grained soils, while the standard pressuremeter can be used
in most soil types. A detailed description of the PMT is beyond the scope
of this paper. However, guidelines for data evaluation and interpretation
as well as design recommendations were published by Baguelin et al. (1986).
The PMT is an intermittent test and can thus not provide a continuous
profile. The test is comparatively time-consuming and thus expensive.
Figure
4. Variation of qc /N ratio with mean
grain size (note that the cone resistance in MPa)
From
the PMT, a stress-deformation curve (applied pressure vs. volumetric
strain) can be obtained in situ. From this curve, a deformation modulus and
a value of the limit strength can be obtained. Also the "at rest"
lateral earth pressure can be estimated, which is of considerable interest
for soil compaction project. Few correlations exist between the PMT and
other in situ tests. Because of the necessity to drill borehole, the
quality of the test results may be suspect in loose sand below the ground water
table.
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2.5
Dilatometer Test (DMT)
The
dilatometer test (DMT), which is a simple and reliable in-situ testing
tool, was developed in Italy and later introduced in Europe and North
America, Marchetti (1980). The dilatometer consists of a flat, 15 mm thick
and 95 mm wide blade and has a length of 220 mm. A flexible, stainless
steel membrane, 60 mm in diameter, is located on one face of the blade.
Inside the steel membrane there is a pressure chamber and a distance gauge
for measurement of the movements of the membrane when the pressure inside
is changed. The probe is pushed into the soil with the aid of hollow
sounding rods and does not require drilling of a hole. When the membrane is
inflated, the pressure required to just lift the membrane off the sensing
device (p0) and to cause 1.10
mm deflection (p1) are recorded. As
the pressure is released and the membrane returns to its initial lift-off
position, another reading can be taken. The pressure values p0 and p1 can be used to
define three index parameters. Marchetti (1980) calls these parameters the
material index (ID), the horizontal
stress index (KD) and the dilatometer modulus (ED),
respectively.
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ID =
( p1 - p0 ) / (p0 -
u0 )
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(7)
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where uo = pore water pressure at rest (not
excess pore pressure). The ID value varies from about 0.6 to 1.8
for silt and is about 1.8 for sand. The DMT is especially suited for
monitoring of compaction projects as it can be used to assess the
deformation characteristics of soils. From these index values, empirical
relationships have been developed to determine geotechnical parameters. For
instance, assuming that the soil behaves elastically, the dilatometer
modulus can be deduced from the relation:
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ED =
48.1 ( p1 - p0 )
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(8)
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The
dilatometer modulus is commonly used to assess the compression (oedometer)
modulus M of sand, silt and clayey silt. Experience has shown that the
following relation obtains a good estimation of M
where Rm varies depending of the soil.
Schmertman (1986) has suggested design procedures for settlement estimates
based on the DMT.
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2.6
Seismic tests
Conventional
seismic tests, such as wave refraction measurements, have been used in the
past primarily for soil and rock layer identification. However, during the
past decade, several new seismic in situ tests have been developed and
applied successfully on a variety of soil compaction projects, Massarsch
and Westerberg (1995). The "seismic" cone penetrometer, which has
been briefly discussed above, incorporates a small rugged velocity sensor
in an electronic penetrometer. Woods (1986) has published a detailed
description of different seismic field testing methods.
The
most common seismic test for compaction control is the down-hole test. A
vibration sensor is installed in a borehole, or by pushing the sensor into
the ground (cf. seismic CPT). A polarised shear (and/or compression) wave
is generated at the ground surface and the time required for the wave to
travel across the soil layers to a receiver is measured. Different methods
of signal interpretation can be used to determine the first arrival time of
the signal. From the known distance the wave propagation velocity (shear
wave or compression wave) can be calculated. Down-hole tests are relatively
easy to perform, as only one sensor must be installed in the ground. The
down-hole test is suitable for compaction control as it measures the
average properties of a relatively large soil volume, compared to
penetration tests. Signal interpretation is basically simple (determination
of first arrival time at the two sensor locations), but more complex
evaluation concepts (e.g. signal cross-correlation) are used. An important
advantage of the shear wave velocity is that the ground water level does
not affect the measurements.
In
the case of a cross-hole test, two sensors are installed in the ground and
the wave is generated in a borehole at the same level. The distance between
the vibration source and the sensors must be determined accurately in order
to obtain sufficient accuracy. The distance between the sensors is
typically 3 - 6 m. The cross-hole test is more cumbersome to perform than
the down-hole test and is mainly used for research purposes.
Another,
increasingly popular seismic testing method is the Spectral Analysis of
Surface Wave Technique, SASW, Woods (1986). It uses a seismic source
(impact or vibration generator) at the ground surface and at least two
vibration transducers at the ground surface. The vertical transducers
record the propagation of surface (Rayleigh) waves. By analysing the phase
information for each frequency contained in the wave train, the Rayleigh
and shear wave velocity, can be determined. The evaluation of SASW
measurements is relatively complex and requires specially developed
computer software. However, user-friendly hardware and software has been
developed which simplify the application of SASW also for compaction
control. SASW measurements can determine wave velocity profiles to depth
exceeding 20 m, which is sufficient for most foundation projects. The main
advantage of SASW is that large soil volume can be investigated relatively rapidly.
From
the calculated shear wave velocity Cs, the shear modulus G can
be calculated from the following relationship
where r is the bulk
density of the soil mass. As the strain level of the propagating shear wave
is low (< 10-4%) and the elastic wave velocity is measured.
It should be noted that the "dynamic" (small-strain) shear
modulus decreases with increasing strain level and can thus not be directly
converted into a "static" (large-strain) modulus value. A modulus
reduction factor can be used to estimate the static modulus Gstat from the dynamic
modulus, Gmax. Approximate values of the modulus reduction
factor R can be obtained from Table 2. Semi-empirical correlations can be
used to estimate the equivalent static shear modulus (secant modulus),
Gstat
where
R is a reduction factor, which takes into account the strain-softening
effect of soils (at strains of approximately 0,1 % strain).
Table
2. Modulus reduction
factor R for determination of the static (secant) modulus from dynamic
tests, Massarsch (1984)
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Soil Type
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Reduction Factor, R
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Gravel
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0,20
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Sandy Gravel
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0,19
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Loose Sand
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0,18
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Medium Dense Sand
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0,15
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Dense Sand
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0,12
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It
is interesting to note that the static modulus in sand is only about 10 to
20 % of the dynamic modulus. The Young's modulus, Estat and the constrained
(oedometer) modulus Mstat can be readily calculated from the shear modulus
Gstat (Poisson's ratio of n: 0,3)
From
the above relationships it is obvious that the Young's modulus and the
constrained modulus are significantly larger than the shear modulus. This
aspect must be taken into account when evaluating the results of dynamic
soil tests.
The
damping (attenuation) characteristics of the soil can also be determined
using seismic techniques, Woods (1986). However, the practical application
of these measurements for compaction projects is not yet well understood.
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