1. SCOPE
1.1 This standard ( Part 16 ) covers the laboratory method for determination
of California Bearing Ratio ( CBR ).
2. TERMINOLOGY
2.0 For the purpose of this standard, the definitions given in IS : 2809-
1972? and the following shall apply.
2.1 Standard Load - Load which has been obtained from the test on
crushed stone which was defined as having a California Bearing Ratio
of 100 percent ( see also 7.3 >.
2.2 California Bearing Ratio (CBR) - The ratio expressed in percentage
of force per unit area required to penetrate a soil mass with a circular
plunger of 50 mm diameter at the rate of 1’25 mm/min to that required
for. corresponding penetration in a standard material. The ratio is
usually determined for penetration of 2’5 and 5 mm. Where the ratio
at 5 mm is consistently higher than that at 2’5 mm, the ratio at 5 mm
is used.
3. APPARATUS
3.1 Moulds with Base Plate, Stay Rod and Wing Nut - These shall
conform to 4.1, 4.3 and 4.4 of IS : 9669 - 19801.
3.2 Collar - It shall conform to 4.2 of IS : 9669 - 1980$.
3.3 Spacer Disc - It shall conform to 4.4 of IS : 9669 - 1980$.
3.4 Metal Rammer - As specified in IS : 9198 - 19795.
3.5 Expansion Measuring Apparatus - The adjustable stem with perforated
plates and tripod shall conform to 4.4 of IS : 9669 - 1980$.
3.6 Weights - This shall conform to 4.4 of IS : 9669 - 1480$.
*Rules for rounding off numerical values ( revised ).
Glossary of terms and symbols relating to soil engineering (first revision ).
Specification for CBR moulds and its accessories.
Specification for compaction rammer for soil testing.
3.7 Loading Machine - With a capacity of at least 5 000 kg and
equipped with a movable head or base which enables the plunger to
penetrate into the specimen at a deformation rate of 1’25 mm/min-
The machine shall be equipped with a load machine device that can
read to suitable accuracy.
NOTE - In the machine priming ring can also be used.
3.8 Penetration Plunger - This shall conform to 4.4 of IS : 9669 -
1980*.
3.9 Dial Gauges - Two dial gauges reading to 0’01 mm.
3.10 Sieves - 47’5 mm IS Sieve and 19 mm IS Sieve [ see IS : 460
( Part 1 ) - 1985: I.
3.11 Miscellaneous Apparatus - Other general apparatus, such as a
mixing bowl, straightedge, scales, soaking tank or pan, drying oven,
filter paper, dishes and calibrated measuring jar.
PREPARATION OF TEST SPECIMEN
4.1 The test may be performed on:
a) undisturbed specimens, and
b) remoulded specimens which may be compacted either statically
or dynamically.
NcITE-T~~ static method of compaction gives the required density but
requires considerable pressure and there is a possibility of the actual density
varying with depth though the mean density may be the one desired.
4.2 Undisturbed Specimens - Undisturbed specimens shall be obtained
by fitting to the mould, the steel cutting edge of 150 mm internal diameter
and pushing the mould as gently as possible into the ground.
This process’may be facilitated by digging away soil from the outside as
the mould is pushed in. When the mould is sufficiently full of soil, it
shall be removed by under digging, the top and bottom surfaces are
then trimmed flat so as to give the required length of specimen ready
for testing. If the,mould cannot be pressed in, the sample may be
collected by digging at a circumference greater than that of the mould
and thus bringing out a whole undisturbed lump of soil. The required
size of the sample to fit into the test mould shall then be carefully
trimmed from this lump. If the specimen is loose in the mould, the
annular cavity shall be filled with paraffin wax thus ensuring that the
soil receives proper support from the sides of the mould during the
penetration test.
The density of the soil shall be determined either by weighing the
soil with mould when the mould is full with the soil, or by measuring the
*Specification for CBR moulds and its accessories.
specification for test sieves : Part 1 Wire cloth test sieves ( third revision ).
dimensions of the soil sample accurately and weighing or by measuring
the density in the field in the vicinity of the spot at which the sample is
collected in accordance with the method specified in IS : 2720
(Part 28 ) - 1974* or IS : 2720 ( Part 29 ) - 1975 In all cases, the water
;;;: shall be determined in accordance with IS : 2720 ( Part 2 ) -
4.3 Remoulded Specimens - The dry density for a remoulding shall
be either the field density or the value of the maximum dry density
estimated by the compaction tests 1 see IS : 2720 ( Part 7 1 - 19805, and
and IS : 2720 (Part 8) - 1983 11I , or any other density at which the bearing
ratio is desired. The water content used for compaction should be the
optimum water content or the field moisture as the case may be.
-4.3.1 Soil Sample - The material used in the remoulded specimen
shall pass a 19-mm IS Sieve. Allowance for larger material shall be
made by replacing it by an equal amount of material which passes a
19-mm.IS Sieve but is retained on 4’75-mm IS Sieve.
c 4.3.2 Statically Compacted Specimens - The mass of the wet soil at
the required moisture content to give the desired density when occupying
the standard specimen volume in the mould shall be calculated. A batch
of soil shall be thoroughly mixed with water to guvs the required water
content. The correct mass of the moist soils shall be placed in the
mould and computation obtained by pressing in the displace disc, a
filter paper being placed between the disc and the soil.
4.3.3 Dynamically Compacted Specimen - For dynamic compaction,
a representative sample of the soil weighing approximately 4’5 kg or
more for fine-grained soils and 5’5 kg or more for granular soils shall
be taken and mixed thoroughly with water. If the soil is to be compacted
to the maximum dry density at the optimum water content determined
in accordance with IS : 2720 (Part 71 - 19809 or IS : 2720
( Part 8 )- 19831) exactness of soil required shall be taken and the
necessary quantity of water added so that the water content of the soil
sample is equal to the~determined optimum water content.
*Methods of test for soils : Part 28 Determination of dry density of soils in-place
by the sand replacement method (first revision ).
Methods of test for soils : Part 29 Determination of dry density of soils in-place
by the core cutter method (first revision ).
Methods of test for soils : Part 2 Determination of water content (second
revision ).
Methods of test for soils : Part 7 Determination of water content-dry density
relation using light compaction (second revision).
Methods of test for soils : Part 8 Determination of water content-dry density
The mould with the extension collar attached shall be clamped
to the base plate. The spacer disc shall be inserted over the base plate
and a disc of coarse filter paper placed on the top of the spacer disc.
The soil-water mixture shall be compacted into the mould in accordance
with the methods applicable to the 150 mm diameter mould specified in
IS : 2720 ( Part 7) - 1980* or IS : 2720 ( Part 8 ) - 1983t. If other
densities and water contents are desired, they may be used and indicated
in the report.
4.3.3.2 The extension collar shall then be removed and the compacted
soil carefully trimmed even with the top of the mould by means of a
straightedge. Any hole that may then, develop on the surface of the
compacted soil by the removal of coarse material, shall be patched with
smaller size material; the perforated base plate and the spacer disc shall
be removed, and the mass of the mould and the compacted soil specimen
recorded. A disc of coarse filter paper shall be placed on the perforated
base plate, the mould and the compacted soil shall be inverted and the
perforated base plate clamped to the mould with the compacted soil in
contact with the filter paper.
4.3.4 In both cases of compaction, if the sample is to be soaked,
representative samples of the material at the beginning of compaction and
another sample of the remaining material after compaction shall be
taken for determination of water content. Each water content sample
shall weigh not less than about 50 g.
If the sample is not to be soaked, a representative sample of material
from one of the cut-pieces of the material after penetration shall be
taken to determine the water content. In all cases, the water content
shall be determined in accordance with IS : 2720 ( Part 2 )-1973
PROCEDURE
5.1 Test for Swelling
5.1.1 A filter paper shall be placed over the specimen and the adjustable
stem and perforated plate shall be placed on the compacted soil
specimen in the mould. Weights to produce a surcharge equal to the
weight of base material and pavement to the nearest 2’5 kg shall be placed
on the compact soil specimen. The whole mould and weights shall be
immersed in a tank of water allowing free access of water to the top
and bottom of the specimen. The tripod for the expansion measuring
*Methods of test for soils : Part 7 Determination of water content-dry density
relation using light compaction ( second revision ).
Methods of test for soils: Part 8 Determination of water content-dry density
relation using heavy compaction ( second revision ).
Methods of test for soils : Part 2 Determination of water content (second
revision ) .
7
device shall be mounted on the edge of the mould and the initial dial
gauge reading recorded. This set-up shall be kept undisturbed for 96
hours noting down the readings every day against the time of reading.
A constant water level shall be maintained in the tank through-out the
period.
5.1.2 At the end of the soaking period, the change in dial gauge
shall be noted, the tripod removed and the mould taken out of the water
tank.
5.1.3 The free water collected in the mould shall be removed and the
specimen allowed to drain downwards for 15 minutes. Care shall be
taken not to disturb the surface of the specimen during the removal of
tbe water. The weights, the perforated plate and the top filter paper
shall be removed and the mould with the soaked soil sample shall be
weighed and the mass recorded.
NOTB - The swelling test may be omitted if it is unnecessary and the ptnetration
test specified in 5.2 may be carried out directly.
5.2 Penetration Test (see Fig. 1 ) - Tfie mould containing the specimen,
with the base plate in position but the top face exposed, shall be placed
on the lower plate of the testing machine. Surcharge weights, sufficient
to produce an intensity of loading equal to the weight of the base
material and pavement shall be placed on the specimen. If the specimen
has been soaked previously, the surcharge shall be equal to that used
during the soaking period. To prevent upheaval of soil into the hole of
the surcharge weights, 2’5 kg annular weight shall be placed on the soil
surface prior to seating the penetration plunger after which the remainder
of the surcharge weights shall be placed. The plunger shall be
seated under a load of 4 kg so that full contact is established between
the surface of the specimen and the plunger. The load and deformation
gauges shall then be set to zero ( In other words, the initial load applied
to the plunger shall be considered as zero when determining the load
penetration relation ). Load shall be applied to the plunger into the soil
at the rate of 1’25 mm per minute. Reading of the load shall be taken
at penetrations of 0’5, 1’0, 1’5, 2’0, 2’5, 4’0, 5’0, 7’S, 10’0 and 12’5 mm
(The maximum load and penetration shall be recorded if it occurs for a
penetration of less than 12.5 mm). The plunger shall be raised and the
mould detached from the loading equipment. About 20 to 50 g of soil
shall be collected from the top 30 mm layer of the specimen and the
water content determined according to IS : 2720 ( Part 2 )-1973*. If the
average water content of the whole specimen is desired, water content
sample shall be taken from the entire depth of the specimen. The
undisturbed specimen for the test should be carefully examined after the
test is completed for the presence of any oversize soil particles which
are likely to affect the results if they happen to be located directly below
the penetration plunger.
LOAD APPLIED
PROVING RING FOR
MEASURING LOAD
............. , ................
............................
.............................
.............................
............................
............................
............................
.............................
............................
.......
....... SOIL SPECIMEN : : ; : : : : : :
........ . ...................
............................
...........................
............................
......... i., ................
............................
............................
............................
............................
........... . ................
............................
............................
FIG. 1 SET-UP FOR CBR TEST
RECORD OF OBSERVATIONS
6.1 Specimen Data - The specimen data shall be recorded on the data
sheet as shown in Appendix A. Apart from soil identification, etc, this
includes ?he condition of the specimen at the time of testing, type of
compaction adopted, the amount of soil fraction above 20 mm that has
been replaced and the water content and density determinations before
and after the mould has been subjected to soaking.
6.2 Penetration Data -. The readings for the determination of expansion
ratio and the load penetration data shall be recorded in the data sheet as
shown in Appendix B.
9
CALCULATION
7.1 Expansion Ratio - The expansion ratio based on tests conducted as
specified in 5.1 shall be calculated as follows:
where
Expansion ratio= 7 &-& x100
&=final dial gauge reading in mm,
&=initial dial gauge reading in mm, and
h=initial height of the specimen in mm.
The expansion ratio is used to qualitatively identify the potential
expansiveness of the soil.
7.2 Load Penetration Curve - The load penetration curve shall be
plotted (see Fig. 2). This curve is usually convex upwards although the
initial portion of the curve may be convex downwards due to surface
irregularities. A correction shall then be applied by drawing a tangent
to the point of greatest slope and then transposing the axis of the load
so that zero penetration is taken as the point where the tangent cuts the
axis of penetration. The corrected load-penetration curve would then
consist of the tangent from the new origin to the point of tang ency on
the re-sited curve and then the curve itself, as illustrated in Fig. 2.
7.3 California Bearing Ratio - The CBR values are usually calculated
for penetrations of 2’5 and 5 mm. Corresponding to the penetration
value at which the CBR values is desired, corrected load value shall be
taken from the load penetration curve and the CBR calculated as follows:
California Bearing Ratio = 5p s x 100
where
PT=corrected unit ( or total ) test load corresponding to the chosen
penetration from the load penetration curve, and
Ps=unit ( or total ) standard load for the same depth of penetration as
for Pr taken from the table given in Fig. 2
Generally, the CBR value at 2’5 mm penetration will be greater than
that at 5 mm penetration and in such a case, the former shall be taken
as the CBR value for design purposes. If the CBR value corresponding
to a penetration of 5 mm exceeds that for 2’5 mm, the test shall be
repeated. If identical results follow, the CBR corresponding to 5 mm
penetration shall be taken for design.
PRESENTATION OF RESULTS
8.1 The results of the CBR test are presented as the CBR value and the
expansion ratio.
12
SPECIMEN DATA
PROJECT : TEST NO. :
SAMPLE NO. : DATE :
SOIL IDENTIFICATION : TEST B%
CONDITION OF SPECIMEN AT UNDISTURBED/REMOULDED/
TEST : SOAKED/UNSOAKED
TYPE OF COMPACTION : Static/Dynamic Compaction
Light/Heavy Compaction
Soil Fraction above 20 mm replaced--kg.
Water Content Before After test
soaking ~_~~~~-h~~~~~~
field Top Centre Bottom
Can No.
Wt of canfwet soil (g)
Wt of can+dry soil (8)
Wt of water (g)
Wt of can (g)
Wt of dry soil (g)
Water content (%I
Condition of Specimen Before Soaking After Soaking
Wt of mould+soil (kg)
Wt of mould (kg)
Wt of soil (kg)
Volume of the specimen (cc)
Bulk density (g/cc)
Average water content (%)
Dry density (g/cc)
13
1s : 2720 ( Part 16 > - 1987
APPENDIX B
( Ckmse 6.2 )
SOIL MECHANICS LABoRATORY
CALIFORNIA BEARING RATIO TEST
PENETRATION DATA
Surcharge weight used = kg
Test 1 Test 2
~-_---_h-_--- h--,7
Penetration Load Measuring Lzd Load%;i%g Load
Device Reading (kg) Device Reading (kg)
CBR of specimen at 2’5 mm penetration =
CBRof specimen at 5’0 mm penetration =
CBR of specimen = percent
Expansion Ratio
Surcharge Weight used (kg) =
Period of soaking (days) =
Initial height of specimen, h (mm) =
Initial dial gauge reading, & (mm) =
Final dial gauge reading, df (mm) =
c&-d,
Expansion ratio= ~XlhO O =
Remarks:
. ..a* . . . . . . . . . . . . . . . . . . . . . . . . . . . . * . . . . . . . . . . . . . . . . . . . . . . . . . . . . ** . . . . . . . . . . . . . . . . , . ,
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ” . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . * . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .I . .
INTERNATIONAL SYSTEM OF UNITS ( SI UNITS )
Base Units
Quantity
Length
Mass
Time
Electric current
Thermodynamic
temperature
Luminous intensity
Amount of substance
Supplementary Units
Quantity
Plane angle
Solid angle
Derived Units
Quantity.
Force
Energy
Power
Flux
Flux density
Frequency
Electric conductance
Electromotive force
Pressure, stress
Unit
meter
kilogram
second
ampere
kelvin
candela
mole
Unit
radiant
steradian
Unit
newton
joule
watt
Weber
Tesla
hertz
Siemens
volt
Pascal
Symbol
m
kg
S
A
K
cd
mol
Symbol
rad
sr
Symbol
N
J
W
Wb
T
Hz
S
V
Pa
Definition
1N = 1 kg,m/st
1J = 1 N.m
1 W = 1 J/s
1 Wb = 1 V.s
1T = I Wb/m2
1 Hz = 1 c/s( s-l)
IS = 1 A/V
1v = 1 W/A
1 Pa - 1 N/al2
1.1 This standard ( Part 16 ) covers the laboratory method for determination
of California Bearing Ratio ( CBR ).
2. TERMINOLOGY
2.0 For the purpose of this standard, the definitions given in IS : 2809-
1972? and the following shall apply.
2.1 Standard Load - Load which has been obtained from the test on
crushed stone which was defined as having a California Bearing Ratio
of 100 percent ( see also 7.3 >.
2.2 California Bearing Ratio (CBR) - The ratio expressed in percentage
of force per unit area required to penetrate a soil mass with a circular
plunger of 50 mm diameter at the rate of 1’25 mm/min to that required
for. corresponding penetration in a standard material. The ratio is
usually determined for penetration of 2’5 and 5 mm. Where the ratio
at 5 mm is consistently higher than that at 2’5 mm, the ratio at 5 mm
is used.
3. APPARATUS
3.1 Moulds with Base Plate, Stay Rod and Wing Nut - These shall
conform to 4.1, 4.3 and 4.4 of IS : 9669 - 19801.
3.2 Collar - It shall conform to 4.2 of IS : 9669 - 1980$.
3.3 Spacer Disc - It shall conform to 4.4 of IS : 9669 - 1980$.
3.4 Metal Rammer - As specified in IS : 9198 - 19795.
3.5 Expansion Measuring Apparatus - The adjustable stem with perforated
plates and tripod shall conform to 4.4 of IS : 9669 - 1980$.
3.6 Weights - This shall conform to 4.4 of IS : 9669 - 1480$.
*Rules for rounding off numerical values ( revised ).
Glossary of terms and symbols relating to soil engineering (first revision ).
Specification for CBR moulds and its accessories.
Specification for compaction rammer for soil testing.
3.7 Loading Machine - With a capacity of at least 5 000 kg and
equipped with a movable head or base which enables the plunger to
penetrate into the specimen at a deformation rate of 1’25 mm/min-
The machine shall be equipped with a load machine device that can
read to suitable accuracy.
NOTE - In the machine priming ring can also be used.
3.8 Penetration Plunger - This shall conform to 4.4 of IS : 9669 -
1980*.
3.9 Dial Gauges - Two dial gauges reading to 0’01 mm.
3.10 Sieves - 47’5 mm IS Sieve and 19 mm IS Sieve [ see IS : 460
( Part 1 ) - 1985: I.
3.11 Miscellaneous Apparatus - Other general apparatus, such as a
mixing bowl, straightedge, scales, soaking tank or pan, drying oven,
filter paper, dishes and calibrated measuring jar.
PREPARATION OF TEST SPECIMEN
4.1 The test may be performed on:
a) undisturbed specimens, and
b) remoulded specimens which may be compacted either statically
or dynamically.
NcITE-T~~ static method of compaction gives the required density but
requires considerable pressure and there is a possibility of the actual density
varying with depth though the mean density may be the one desired.
4.2 Undisturbed Specimens - Undisturbed specimens shall be obtained
by fitting to the mould, the steel cutting edge of 150 mm internal diameter
and pushing the mould as gently as possible into the ground.
This process’may be facilitated by digging away soil from the outside as
the mould is pushed in. When the mould is sufficiently full of soil, it
shall be removed by under digging, the top and bottom surfaces are
then trimmed flat so as to give the required length of specimen ready
for testing. If the,mould cannot be pressed in, the sample may be
collected by digging at a circumference greater than that of the mould
and thus bringing out a whole undisturbed lump of soil. The required
size of the sample to fit into the test mould shall then be carefully
trimmed from this lump. If the specimen is loose in the mould, the
annular cavity shall be filled with paraffin wax thus ensuring that the
soil receives proper support from the sides of the mould during the
penetration test.
The density of the soil shall be determined either by weighing the
soil with mould when the mould is full with the soil, or by measuring the
*Specification for CBR moulds and its accessories.
specification for test sieves : Part 1 Wire cloth test sieves ( third revision ).
dimensions of the soil sample accurately and weighing or by measuring
the density in the field in the vicinity of the spot at which the sample is
collected in accordance with the method specified in IS : 2720
(Part 28 ) - 1974* or IS : 2720 ( Part 29 ) - 1975 In all cases, the water
;;;: shall be determined in accordance with IS : 2720 ( Part 2 ) -
4.3 Remoulded Specimens - The dry density for a remoulding shall
be either the field density or the value of the maximum dry density
estimated by the compaction tests 1 see IS : 2720 ( Part 7 1 - 19805, and
and IS : 2720 (Part 8) - 1983 11I , or any other density at which the bearing
ratio is desired. The water content used for compaction should be the
optimum water content or the field moisture as the case may be.
-4.3.1 Soil Sample - The material used in the remoulded specimen
shall pass a 19-mm IS Sieve. Allowance for larger material shall be
made by replacing it by an equal amount of material which passes a
19-mm.IS Sieve but is retained on 4’75-mm IS Sieve.
c 4.3.2 Statically Compacted Specimens - The mass of the wet soil at
the required moisture content to give the desired density when occupying
the standard specimen volume in the mould shall be calculated. A batch
of soil shall be thoroughly mixed with water to guvs the required water
content. The correct mass of the moist soils shall be placed in the
mould and computation obtained by pressing in the displace disc, a
filter paper being placed between the disc and the soil.
4.3.3 Dynamically Compacted Specimen - For dynamic compaction,
a representative sample of the soil weighing approximately 4’5 kg or
more for fine-grained soils and 5’5 kg or more for granular soils shall
be taken and mixed thoroughly with water. If the soil is to be compacted
to the maximum dry density at the optimum water content determined
in accordance with IS : 2720 (Part 71 - 19809 or IS : 2720
( Part 8 )- 19831) exactness of soil required shall be taken and the
necessary quantity of water added so that the water content of the soil
sample is equal to the~determined optimum water content.
*Methods of test for soils : Part 28 Determination of dry density of soils in-place
by the sand replacement method (first revision ).
Methods of test for soils : Part 29 Determination of dry density of soils in-place
by the core cutter method (first revision ).
Methods of test for soils : Part 2 Determination of water content (second
revision ).
Methods of test for soils : Part 7 Determination of water content-dry density
relation using light compaction (second revision).
Methods of test for soils : Part 8 Determination of water content-dry density
The mould with the extension collar attached shall be clamped
to the base plate. The spacer disc shall be inserted over the base plate
and a disc of coarse filter paper placed on the top of the spacer disc.
The soil-water mixture shall be compacted into the mould in accordance
with the methods applicable to the 150 mm diameter mould specified in
IS : 2720 ( Part 7) - 1980* or IS : 2720 ( Part 8 ) - 1983t. If other
densities and water contents are desired, they may be used and indicated
in the report.
4.3.3.2 The extension collar shall then be removed and the compacted
soil carefully trimmed even with the top of the mould by means of a
straightedge. Any hole that may then, develop on the surface of the
compacted soil by the removal of coarse material, shall be patched with
smaller size material; the perforated base plate and the spacer disc shall
be removed, and the mass of the mould and the compacted soil specimen
recorded. A disc of coarse filter paper shall be placed on the perforated
base plate, the mould and the compacted soil shall be inverted and the
perforated base plate clamped to the mould with the compacted soil in
contact with the filter paper.
4.3.4 In both cases of compaction, if the sample is to be soaked,
representative samples of the material at the beginning of compaction and
another sample of the remaining material after compaction shall be
taken for determination of water content. Each water content sample
shall weigh not less than about 50 g.
If the sample is not to be soaked, a representative sample of material
from one of the cut-pieces of the material after penetration shall be
taken to determine the water content. In all cases, the water content
shall be determined in accordance with IS : 2720 ( Part 2 )-1973
PROCEDURE
5.1 Test for Swelling
5.1.1 A filter paper shall be placed over the specimen and the adjustable
stem and perforated plate shall be placed on the compacted soil
specimen in the mould. Weights to produce a surcharge equal to the
weight of base material and pavement to the nearest 2’5 kg shall be placed
on the compact soil specimen. The whole mould and weights shall be
immersed in a tank of water allowing free access of water to the top
and bottom of the specimen. The tripod for the expansion measuring
*Methods of test for soils : Part 7 Determination of water content-dry density
relation using light compaction ( second revision ).
Methods of test for soils: Part 8 Determination of water content-dry density
relation using heavy compaction ( second revision ).
Methods of test for soils : Part 2 Determination of water content (second
revision ) .
7
device shall be mounted on the edge of the mould and the initial dial
gauge reading recorded. This set-up shall be kept undisturbed for 96
hours noting down the readings every day against the time of reading.
A constant water level shall be maintained in the tank through-out the
period.
5.1.2 At the end of the soaking period, the change in dial gauge
shall be noted, the tripod removed and the mould taken out of the water
tank.
5.1.3 The free water collected in the mould shall be removed and the
specimen allowed to drain downwards for 15 minutes. Care shall be
taken not to disturb the surface of the specimen during the removal of
tbe water. The weights, the perforated plate and the top filter paper
shall be removed and the mould with the soaked soil sample shall be
weighed and the mass recorded.
NOTB - The swelling test may be omitted if it is unnecessary and the ptnetration
test specified in 5.2 may be carried out directly.
5.2 Penetration Test (see Fig. 1 ) - Tfie mould containing the specimen,
with the base plate in position but the top face exposed, shall be placed
on the lower plate of the testing machine. Surcharge weights, sufficient
to produce an intensity of loading equal to the weight of the base
material and pavement shall be placed on the specimen. If the specimen
has been soaked previously, the surcharge shall be equal to that used
during the soaking period. To prevent upheaval of soil into the hole of
the surcharge weights, 2’5 kg annular weight shall be placed on the soil
surface prior to seating the penetration plunger after which the remainder
of the surcharge weights shall be placed. The plunger shall be
seated under a load of 4 kg so that full contact is established between
the surface of the specimen and the plunger. The load and deformation
gauges shall then be set to zero ( In other words, the initial load applied
to the plunger shall be considered as zero when determining the load
penetration relation ). Load shall be applied to the plunger into the soil
at the rate of 1’25 mm per minute. Reading of the load shall be taken
at penetrations of 0’5, 1’0, 1’5, 2’0, 2’5, 4’0, 5’0, 7’S, 10’0 and 12’5 mm
(The maximum load and penetration shall be recorded if it occurs for a
penetration of less than 12.5 mm). The plunger shall be raised and the
mould detached from the loading equipment. About 20 to 50 g of soil
shall be collected from the top 30 mm layer of the specimen and the
water content determined according to IS : 2720 ( Part 2 )-1973*. If the
average water content of the whole specimen is desired, water content
sample shall be taken from the entire depth of the specimen. The
undisturbed specimen for the test should be carefully examined after the
test is completed for the presence of any oversize soil particles which
are likely to affect the results if they happen to be located directly below
the penetration plunger.
LOAD APPLIED
PROVING RING FOR
MEASURING LOAD
............. , ................
............................
.............................
.............................
............................
............................
............................
.............................
............................
.......
....... SOIL SPECIMEN : : ; : : : : : :
........ . ...................
............................
...........................
............................
......... i., ................
............................
............................
............................
............................
........... . ................
............................
............................
FIG. 1 SET-UP FOR CBR TEST
RECORD OF OBSERVATIONS
6.1 Specimen Data - The specimen data shall be recorded on the data
sheet as shown in Appendix A. Apart from soil identification, etc, this
includes ?he condition of the specimen at the time of testing, type of
compaction adopted, the amount of soil fraction above 20 mm that has
been replaced and the water content and density determinations before
and after the mould has been subjected to soaking.
6.2 Penetration Data -. The readings for the determination of expansion
ratio and the load penetration data shall be recorded in the data sheet as
shown in Appendix B.
9
CALCULATION
7.1 Expansion Ratio - The expansion ratio based on tests conducted as
specified in 5.1 shall be calculated as follows:
where
Expansion ratio= 7 &-& x100
&=final dial gauge reading in mm,
&=initial dial gauge reading in mm, and
h=initial height of the specimen in mm.
The expansion ratio is used to qualitatively identify the potential
expansiveness of the soil.
7.2 Load Penetration Curve - The load penetration curve shall be
plotted (see Fig. 2). This curve is usually convex upwards although the
initial portion of the curve may be convex downwards due to surface
irregularities. A correction shall then be applied by drawing a tangent
to the point of greatest slope and then transposing the axis of the load
so that zero penetration is taken as the point where the tangent cuts the
axis of penetration. The corrected load-penetration curve would then
consist of the tangent from the new origin to the point of tang ency on
the re-sited curve and then the curve itself, as illustrated in Fig. 2.
7.3 California Bearing Ratio - The CBR values are usually calculated
for penetrations of 2’5 and 5 mm. Corresponding to the penetration
value at which the CBR values is desired, corrected load value shall be
taken from the load penetration curve and the CBR calculated as follows:
California Bearing Ratio = 5p s x 100
where
PT=corrected unit ( or total ) test load corresponding to the chosen
penetration from the load penetration curve, and
Ps=unit ( or total ) standard load for the same depth of penetration as
for Pr taken from the table given in Fig. 2
Generally, the CBR value at 2’5 mm penetration will be greater than
that at 5 mm penetration and in such a case, the former shall be taken
as the CBR value for design purposes. If the CBR value corresponding
to a penetration of 5 mm exceeds that for 2’5 mm, the test shall be
repeated. If identical results follow, the CBR corresponding to 5 mm
penetration shall be taken for design.
PRESENTATION OF RESULTS
8.1 The results of the CBR test are presented as the CBR value and the
expansion ratio.
12
SPECIMEN DATA
PROJECT : TEST NO. :
SAMPLE NO. : DATE :
SOIL IDENTIFICATION : TEST B%
CONDITION OF SPECIMEN AT UNDISTURBED/REMOULDED/
TEST : SOAKED/UNSOAKED
TYPE OF COMPACTION : Static/Dynamic Compaction
Light/Heavy Compaction
Soil Fraction above 20 mm replaced--kg.
Water Content Before After test
soaking ~_~~~~-h~~~~~~
field Top Centre Bottom
Can No.
Wt of canfwet soil (g)
Wt of can+dry soil (8)
Wt of water (g)
Wt of can (g)
Wt of dry soil (g)
Water content (%I
Condition of Specimen Before Soaking After Soaking
Wt of mould+soil (kg)
Wt of mould (kg)
Wt of soil (kg)
Volume of the specimen (cc)
Bulk density (g/cc)
Average water content (%)
Dry density (g/cc)
13
1s : 2720 ( Part 16 > - 1987
APPENDIX B
( Ckmse 6.2 )
SOIL MECHANICS LABoRATORY
CALIFORNIA BEARING RATIO TEST
PENETRATION DATA
Surcharge weight used = kg
Test 1 Test 2
~-_---_h-_--- h--,7
Penetration Load Measuring Lzd Load%;i%g Load
Device Reading (kg) Device Reading (kg)
CBR of specimen at 2’5 mm penetration =
CBRof specimen at 5’0 mm penetration =
CBR of specimen = percent
Expansion Ratio
Surcharge Weight used (kg) =
Period of soaking (days) =
Initial height of specimen, h (mm) =
Initial dial gauge reading, & (mm) =
Final dial gauge reading, df (mm) =
c&-d,
Expansion ratio= ~XlhO O =
Remarks:
. ..a* . . . . . . . . . . . . . . . . . . . . . . . . . . . . * . . . . . . . . . . . . . . . . . . . . . . . . . . . . ** . . . . . . . . . . . . . . . . , . ,
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ” . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . * . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .I . .
INTERNATIONAL SYSTEM OF UNITS ( SI UNITS )
Base Units
Quantity
Length
Mass
Time
Electric current
Thermodynamic
temperature
Luminous intensity
Amount of substance
Supplementary Units
Quantity
Plane angle
Solid angle
Derived Units
Quantity.
Force
Energy
Power
Flux
Flux density
Frequency
Electric conductance
Electromotive force
Pressure, stress
Unit
meter
kilogram
second
ampere
kelvin
candela
mole
Unit
radiant
steradian
Unit
newton
joule
watt
Weber
Tesla
hertz
Siemens
volt
Pascal
Symbol
m
kg
S
A
K
cd
mol
Symbol
rad
sr
Symbol
N
J
W
Wb
T
Hz
S
V
Pa
Definition
1N = 1 kg,m/st
1J = 1 N.m
1 W = 1 J/s
1 Wb = 1 V.s
1T = I Wb/m2
1 Hz = 1 c/s( s-l)
IS = 1 A/V
1v = 1 W/A
1 Pa - 1 N/al2
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