Title:

Moisture-Unit Weight Relationships (Compaction Test)

Aim:

To familiarize the student with the laboratory compaction test and to obtain the moisture-

unit weight relationship for a given compactive effort on a particular soil.

Objective:

In preparing the geotechnical aspect of structures it is important to improve the soil

strength via compaction. This experiment seeks to find the maximum dry unit weight/density

(dmax/dmax) and corresponding optimum water content (wopt) for a clay soil sample consisting of

particles that have passed the US No. 4 sieve.

Introduction:

Compaction of a soil generally increases the shear strength, decreases its compressibility,

decrease its permeability and minimize long-term settlement. During this lab we used the

Standard Proctor Compaction Test, which uses the application of mechanical energy to compact

the soil sample at different water contents. The experiment simply requires accumulatively

adding water and weighing after compaction. By deduction, the heaviest sample will have the

greatest dry unit weight/density. The purpose of the experiment as stated above is to find this

maximum dry density value, dmax that is, the level of compaction required for the soil to have

maximum shear strength and minimum compressibility.

The relative compaction (RC) is defined as:

RC =

x 100(percent)

This is the term used to compare the in situ compacted soil to the laboratory compaction

curve. This value may be more or less than 100 percent, therefore it is possible that for a given

project it may be specified as greater or lower based on the required strength properties. There is

no field compaction counterpart to the laboratory impact method of soil compaction. In spite of

that, the standard compaction test is widely used to determine the compaction criteria.

The soil mass involved in the compaction process starts as a three-phase system of soil, water

and air. The aim of the process is to obtain a two-phase system of only soil and water as the high

pore pressures reduce the shear strength of the soil. It is practically impossible to have a zero air

void condition therefore the compaction curve always falls below the curve of zero-air-voids dry

unit density. To find the zero-air-void density, the following equation is used:

w is the density of water (1g/cm3)

Gs is the specific gravity of soils(2.7)

Procedure:

1) Air-dry soil was obtained, on which the compaction test was to be conducted. All

the soil lumps were broken down.

2) The soil was passed through a U.S. No. 4 sieve and all of the minus 4 material

was collected in a large pan. This should be about 15 lb (7 kg) or more.

3) Enough water was added to the minus 4 material and mixed in thoroughly to

bring the moisture content up to 2%.

4) The weight of the Proctor mould + base plate (not the extension), was

determined.

5) The extension was then attached to the top of the mould.

6) The moist soil was scooped into the mould in three equal layers. Each layer was

compacted uniformly by the standard Proctor hammer (5.5 lbs falling at a height

of 12) 50 times before another layer was added. Each layer was scratched with

the spatula forming a grid to ensure uniformity in distribution of compaction

energy before adding an additional layer to form a continuous sample.

7) It was ensured that the layers of loose soil that are being poured into the mould

extend slightly above the top of the rim of the compaction mould at the end of the

three-layer compaction.

8) The top attachment of the mould was removed and a straightedge was used to

trim the excess soil above the mould.

9) The weight of the mould + base plate + compacted moist soil in mould, was

determined.

10) The base plate was removed from the mould and a hammer was used to knock

the compacted soil cylinder out of the mould.

11) The mass of the moisture can to be used was determined.

12) A sample from the soil cylinder obtained in Step 10 was collected in the moisture

can, and the mass of the can + moist soil was determined.

13) The moisture can with the moist soil was placed in an oven to dry for at least 24

hours or until a constant weight was obtained.

14) The rest of the compacted soil broken down by hand and mixed with the leftover

moist soil in the pan. More water was added and mixed to raise the moisture

content to the desired percentage (increments of either 2% or 2.5 % were used).

15) Steps 6 to 12 were then repeated until there was a decrease in the weight of the

mould + base plate + moist soil.

16) The mass of the moisture cans + soil samples, (from step 13) were then

determined after a period of at least 24 hours.

Results:

Results from a Standard Proctor Test.

Wt. of Cylinder 2002 g

Cylinder No. K/K1

Cylinder

Volume 1311.93 cm3

Table 1: Cylinder Information

Compaction Test Results

Run No. 1 2 3 4 5

Wt. of Sample & Container [g] 3731 3826 3942 4074 4009

Wet. Wt of Sample [g] 1729 1824 1940 2072 2007

Moist Density [g/cm3] 1.31791 1.39032 1.47874 1.57935 1.52981

Moisture Content % Dry Weight 3 5 8 11 13.5

Actual Moisture Content% 4.27459 5.92126 8.89994 11.7952 13.6422

Dry Density. [g/cm3] 1.26388 1.3126 1.35789 1.41272 1.34616

Moisture Content At Saturation wsat% 4.27459 5.92126 8.89994 11.7952 13.6422

Dry Density 2.42063 2.32784 2.1769 2.04783 1.9732

Table 2: Compaction Test Results

Water Content Data

Can No. 8 H4 H3 1 H

Wet Weight Gross [g] 81.03 96.9 110.25 116.55 85.67

Dry Weight Gross [g] 78.67 93.14 103.81 106.76 77.1

Wt. of Water Ww [g] 2.36 3.76 6.44 9.79 8.57

Tare Weight [g] 23.46 29.64 31.45 23.76 14.28

Dry Weight of Soil [g] 55.21 63.5 72.36 83 62.82

Moisture Content% 3 5 8 11 13.5 Table 3:

OPTIMUM WATER CONTENT % 11.8

MAX. UNIT DRY WEIGHT g/cm3 1.41 Table 4 : Summary Data

Chart 1: Dry Density Vs Moisture Content

Chart 2: Zero Air Voids Curve

1.24

1.26

1.28

1.3

1.32

1.34

1.36

1.38

1.4

1.42

1.44

0 5 10 15

Dry Density Vs Moisture Content

Dry Density Vs Moisture Content

Dry

Den

sity

(g/c

m3)

Moisture Content (%)

0

0.5

1

1.5

2

2.5

3

0 5 10 15

Zero Air Voids Curve

Zero Voids Curve

Dry

Den

sity

(g/c

m3)

Moisture Content (%)

Chart 3: Showing The Zero air voids curve and the Dry Density vs Moisture content.

0

0.5

1

1.5

2

2.5

3

0 5 10 15

Dry Density Vs Moisture Content

Zero Air Voids Curve

Dry

De

nsi

ty(g

/cm

3)

Moisture Content (%)

CALCULATIONS The sample calculations listed below are all taken from RUN No. 1.

Volume of mould = r2h

= 1311.93cm3

Wet wt. of sample = wt. of sample & cylinder wt. of cylinder

= 3731 2002

= 1729 g

Wt. of water = wet wt. gross dry wt. gross

= 81.03 78.67

= 2.38 g

Dry wt. of soil = dry wt. gross tare wt

= = 55.21 g

Moisture content % dry weight =

=

= 4.27 %

Unit wet wt. =

=

=1.32 g/cm3

Unit dry wt. =

=

= 1.26 g/cm3

= 4.27%

Discussion:

During construction, compaction is essential to increase the shear strength, decrease the

compressibility, decrease its permeability and minimize long-term settlement in the soil. It is

difficult to check those objectives directly therefore they are checked indirectly by finding the

optimum moisture content and dry unit density. By finding the optimum moisture content and

maximum dry density it allows civil engineers to gauge the soils strength. When soils close to

0% moisture content it can only be compacted by so much but as water is added, the dry unit

weight increases because the water lubricates the particles making compaction easier. As more

water is added and the water content becomes larger than the optimum values, the void spaces

become filled with water so further compaction is not possible. Beyond this point, the dry unit

weight decreases as shown in Chart 1. The points at which this begins to happen is described as

the optimum moisture content and the maximum dry unit weight. In this test the Optimum

Moisture Content and dry unit weight were found to be 11.8% saturation and 1.42 g/cm3.

For any given water content and soil solids, the zero-air-voids dry unit weight represents the best

possible compaction. As shown in the Chart 3 the actual compaction curve was below the zero

voids curve which is an expected result. For a given soil and water content the best possible

compaction is represented by the zero-air-voids curve on Chart 3. The actual compaction curve

will always be below it.

Compaction of soil increases the density, shear strength, bearing capacity, thus reducing

the voids, settlement and permeability. Hence the optimum moisture content and the maximum

dry density are useful in the stability of field problems like earthen dams, embankments, roads

and airfields. Compaction in the field is controlled by the value of the optimun moisture content

determined by laboratory compaction test. In other words, the laboratory compaction tests results

are used to write the compaction specifications for field compaction of the soil.

Sources of error

Water may not have been thoroughly absorbed into the dry soil. As a precaution an adequate

period should be allowed to mature the soil after it is mixed with water

Each layer of soil may not have been the same depth into the collar of the mould as a precaution

proper care should be taken to make sure that each layer is nearly equal in weight. To avoid

stratification each compacted layer should be scratched with spatula before next layer is placed.

Human error in operating the hand rammer, it is impossible to apply the same compaction energy

to each layer. A possible precaution that could be taken is to ensure that the same person applies

the blows to each layer. Another will be to ensure the rammer blows are uniformly distributed

over the surface.

Improvements

More accurate results could be obtained if the manual compacting hammer was replaced with a

mechanical arm along with using a fixed height and fixed force to uniformly compact the

sample.

CONCLUSION Within the limits of experimental error, it was found that the maximum dry unit weight

was 1.42 g/cm3 and the corresponding optimum moisture content was 11.8%.

REFERENCES

Standard Proctor Compaction Test Specifications (ASTM D-698)

Craig, R. F. (2004). Soil Mechanics (7th edition). Taylor and Francis, April 2004

Smith, Ian (2006). Smith's Elements of Soil Mechanics (8th Edition). Wiley-Blackwell.

Mitchell, James K.. (1993). Fundamentals of Soil Behavior. Second edition. John Wiley and Sons, New York.

http://www.engr.uconn.edu/~lanbo/CE240LectW011fundamentals.pdf