Sieve Analysis

MD Sahadat Hossain, Ph.D., P.E.; Md Azijul Islam; Faria Fahim Badhon; Tanvir Imtiaz

3 Sieve Analysis

Introduction

The grain size analysis test is performed to determine the percentage of each size of grain that is contained within a soil sample, and the results of the test can be used to produce the grain size distribution curve. This information is used to classify the soil and to predict its behavior. The two methods generally used to find the grain size distribution are:

Sieve analysis which is used for particle sizes larger than 0.075 mm in diameter and
Hydrometer analysis which is used for particle sizes smaller than 0.075 mm in diameter

Sieve analysis is a method that is used to determine the grain size distribution of soils that are greater than 0.075 mm in diameter. It is usually performed for sand and gravel but cannot be used as the sole method for determining the grain size distribution of finer soil. The sieves used in this method are made of woven wires with square openings. The list of the U.S. standard sieve numbers with their corresponding opening sizes are provided in Table 3.1.

Table 3.1: U.S. Sieve Size

$\begin{tabular}{|c|c|c|c|} \hline Sieve No. & Opening (mm) & Sieve No. & Opening (mm) \\ \hline 4 & 4.75 & 35 & 0.500 \\ \hline 5 & 4.00 & 40 & 0.425 \\ \hline 6 & 3.35 & 45 & 0.355 \\ \hline 7 & 2.80 & 50 & 0.300 \\ \hline 8 & 2.36 & 60 & 0.250 \\ \hline 10 & 2.00 & 70 & 0.212 \\ \hline 12 & 1.70 & 80 & 0.180 \\ \hline 14 & 1.40 & 100 & 0.150 \\ \hline 16 & 1.18 & 120 & 0.125 \\ \hline 18 & 1.00 & 140 & 0.106 \\ \hline 20 & 0.85 & 200 & 0.075 \\ \hline 25 & 0.71 & 270 & 0.053 \\ \hline 30 & 0.60 & 400 & 0.038 \\ \hline \end{tabular}$

Practical Application

This test method is used primarily to grade aggregates. The results are used to determine the compliance of the particle size distribution with applicable specification requirements and to provide necessary data for controlling the production of various aggregate products and mixtures containing aggregates.
The data may also be useful in developing relationships concerning porosity and packing. Information obtained from the particle size analysis (uniformity coefficient C_u, coefficient of curvature, C_c, and effective size, D₁₀, etc.) is used to classify the soil.
Particle size is one of the criteria used to ascertain whether the soil is suitable for building roads, embankments, dams, etc.
Information obtained from particle size analysis can be used to predict the soil-water movement if the permeability test is not available.

Objective

To obtain the grain size distribution curve for a given soil sample.

Equipment

Stack of sieves with a cover,
Mortar and pestle or a mechanical soil pulverized
Balance, sensitive to 0.1 g
Oven
Mechanical sieve shaker
Brush

Standard Reference

ASTM D6913: Standard Test Methods for Particle-Size Distribution (Gradation) of Soils Using Sieve Analysis.

Method

Obtain a representative oven-dried soil sample.

Figure 3.1: Weighing some representative oven dried samples

Figure 3.2: Washing the sieves before the test
Pulverize the soil sample as finely as possible, using a mortar and pestle or a mechanical soil pulverizer.
Obtain a soil sample of about 500 g and determine its mass W₀ (g).
Stack the sieves so that those with larger openings (lower numbers) are placed above those with smaller openings (higher numbers). Place a pan under the last sieve (#200) to collect the portion of soil passing through it. The #4 and #200 sieves should always be included in the stack.

Figure 3.3: Stack of sieve in order
Make sure the sieves are clean, If soil particles are stuck in the openings, use a brush to poke them out.

Figure 3.4: Pouring the soil sample at the top of the sieves
Weigh the pan and all of the sieves separately.

Figure 3.5: Sieve shaker
Pour the soil from above into the stack of sieves and place the cover on it. Put the stack in the sieve shaker, affix the clamps, set a timer for 10 to 15 minutes, and start the shaker.

Figure 3.6: Weighing of each sieve after shaking
Stop the sieve shaker and measure the mass of each sieve and retained soil.

Video Materials

Lecture Video

A PowerPoint presentation is created to understand the background and method of this experiment.

Demonstration Video

A short video is executed to demonstrate the experiment procedure and sample calculation.

Results and Discussions

Sample Data Sheet

$\begin{tabular}{|c|c|c|c|c|c|c|c|} \hline \multirow{}{}{Sieve} & \multirow{}{}{Opening} & \multirow{}{}{Sieve Wt.} & \multirow{}{}{Sieve + Soil} & \multirow{}{}{Wt. of soil} & \multirow{}{}{Percent} & \multirow{}{}{Cumulative} & \multirow{}{}{Percent} \\ & & & & & & & \\ No & (mm) & (gm) & Wt. (gm) & retained (gm) & retained & percent retained & finer \\ \hline 4 & 4.75 & 521 & 521 & 0 & 0 & 0 & 100 \\ \hline 8 & 2.36 & 491.8 & 504 & 12.2 & 4.07 & 4.07 & 95.93 \\ \hline 16 & 1.18 & 426 & 450.5 & 24.5 & 8.17 & 12.24 & 87.76 \\ \hline 30 & 0.60 & 401.8 & 490 & 88.2 & 29.4 & 41.64 & 58.36 \\ \hline 50 & 0.297 & 375.5 & 478 & 102.5 & 34.17 & 75.81 & 24.19 \\ \hline 100 & 0.149 & 355.3 & 410 & 54.7 & 18.23 & 94.04 & 5.96 \\ \hline 200 & 0.075 & 351.1 & 368.2 & 17.1 & 5.7 & 99.74 & 0.26 \\ \hline Pan & - & 364.2 & 365 & 0.8 & - & - & - \\ \hline \end{tabular}%$

Sample Calculation

For #8 sieve,
Sieve weight = 491.8 gm
Sieve + soil weight = 504 gm
Weight of soil retained = (504 – 491.8) = 12.2 gm
Percent retained= $2.2/300 × 100 = 4.07%
Cumulative percent retained= 0 + 4.07 = 4.07%
Percent finer= 100 – 4.07= 95.93%
The grain-size distribution of the soil sample can be obtained by plotting the percent finer with the corresponding sieve on semi-log graph paper, as shown below. An example of the grain-size distribution curve is shown in Figure 3.7.

A semi-log graph where x-axis is particle size in millimeter and y-axis is percent finer by weight in %. This graph is a particle size distribution curve. — Figure 3.7: Particle size distribution curve

he values of D₁₀, D₃₀, and D₆₀, which are the diameters that correspond to the percentfiner of 10%, 30%, and 60%, respectively can be determined from the grain-size distributioncurve. The values of the uniformity coefficient C_u and the coefficient of gradation C_ccan be calculated using the following equations:

$\begin{align*} C_c&=\frac{D_{30}^2}{D_{60}\times D_{10}} \\ C_u&=\frac{D_{60}}{D_{10}} \end{align*}$

The values of C_uand C_care used to classify whether the soil is well-graded or not. Sand isconsidered well-graded, if C_uis greater than 6 and C_cis between 1 and 3. For gravel to be considered as well-graded, C_ushould be greater than 4 and C_cshould be between 1 and 3.

From Figure 3.5,

D₁₀= 0.18, D₃₀= 0.35, and D₆₀= 0.61

Uniformity coefficent, C_u=D₆₀/D₁₀=0.61/0.18=3.39

Coefficent of gradation, C_c= (D²₃₀)/(D₆₀×D₁₀)=(0.35)²/(0.61×0.18) =1.12

Blank Data Sheet

$\resizebox{\linewidth}{% \begin{tabular}{|c|c|c|c|c|c|c|c|} \hline \multirow{Sieve} & \multirow{Opening} & \multirow{Sieve Wt.} & \multirow{Sieve + Soil} & \multirow{Wt. of soil} & \multirow{Percent} & \multirow{Cumulative} & \multirow{Percent} \\ & & & & & & & \\ No & (mm) & (gm) & Wt. (gm) & retained (gm) & retained & percent retained & finer \\ \hline 4 & 4.75 & & & & & & \\ \hline 8 & 2.36 & & & & & & \\ \hline 16 & 1.18 & & & & & & \\ \hline 30 & 0.60 & & & & & & \\ \hline 50 & 0.297 & & & & & & \\ \hline 100 & 0.149 & & & & & & \\ \hline 200 & 0.075 & & & & & & \\ \hline Pan & - & & & & & & \\ \hline \end{tabular}% }$

Report

Use the template provided to prepare your lab report for this experiment. Your report should include the following:

Objective of the test
Applications of the test
Apparatus used
Test procedures (optional)
Analysis of test results – Complete the table provided and show one sample calculation. Draw the grain size distribution curve. Calculate C_u and C_c
Summary and conclusions – Comment on the shape of the grain size distribution curve of the given soil sample. Comment on whether the soil is well graded or poorly graded.

License

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Properties and Behavior of Soil - Online Lab Manual Copyright © 2021 by MD Sahadat Hossain, Ph.D., P.E.; Md Azijul Islam; Faria Fahim Badhon; and Tanvir Imtiaz is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License, except where otherwise noted.