green sand preparation (manufacturing lab /foundry)

7/22/2019 GREEN SAND PREPARATION (Manufacturing Lab /Foundry)

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Sand Testing Preparation (Green Sand)

Prepared by:

MUHAMMAD FAKHRUR RAZI BIN MUJAH 2011642844

MOHD ZAKUAN BIN ZABRI 2011864056

MUHAMMAD RABANI BIN KAMARUZZAMAN 2012853256

MUHAMMAD AIMAN FIRDAUS BIN ADNAN 2012677572

MUHAMMAD AZLAN BIN ZAINAL ABIDIN 2011864616

Bachelor in Engineering (Hons.) Mechanical

EM220

Prepared for:

Mohd Ridhwan Mohammed Redza

Lab Instructor for Manufacturing Process Lab (MEM 564)

Faculty of Mechanical Engineering

UiTM, Shah Alam

DATE OF SUBMMISSON:

3 OCTOBER 2013


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UNIVERSITI TEKNOLOGI MARA

FAKULTI KEJURUTERAAN MEKANIKAL

Program : Bachelor of Mechanical Engineering (Hons) Manufacturing (EM221)

Bachelor of Engineering (Hons) Mechanical (EM220)

Course : Mechanical Engineering Manufacturing lab

Course Code : MEM 564

Lecturer : En Mohd Ridhwan Mohammad Redza

____________________________________________________________________________

Laboratory Report

(Title of Experiment)

Sand Testing Preparation (Green Sand)

Practical Session : _26/09/2013___ Staff certification : ________________

(Date) (Signature)

Report Submission : _1/10/2013__ Staff certification : ________________

(Date) (Signature)

No Students Name Students ID Signature

1. M.FAKHRUR RAZI MUJAH 2011642844

2. MOHD ZAKUAN ZABRI 20118640563. MUHAMMAD RABANI BIN KAMARUZZAMAN 2012853256

4. MUHAMMAD AIMAN FIRDAUS BIN ADNAN 2012677572

5. MUHAMMAD AZLAN BIN ZAINAL ABIDIN 2011864616


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TABLE OF CONTENT

TOPICS PAGES

1.0 OBJECTIVE OF THE EXPERIMENT 1

2.0 BACKGROUND OF STUDY

2.1 GREEN COMPRESSION STRENGTH

2.2 PERMEABILITY2

3

3.0 APPARATUS USED IN THE EXPERIMENT

3.1 MATERIALS.3.2 EQUIPMENT

3.3 HANDS TOOLS

4

4-5

6

4.0 EXPERIMENTAL PROCEDURES 7

5.0 RESULTS & DATA ANALYSIS5.1 SAMPLE CALCULATION

5.2 FIGURES OF THE FINAL RESULTS8-9

10

6.0 DISSCUSSION 11-12

7.0 CONCLUSION 13

8.0 RECOMMENDATION 14

9.0 REFERENCES 15


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LIST OF TABLES & FIGURES

Figure 1: The sand that is produced from the addition of silica sand, coal dust, bentonite andWater altogether in the aluminum tray.

Figure 2:The digital weighing device used in this experiment in order to determine the specificWeight of the sand

Figure 3: Sand rammer that is used to ram the sand for 3 times before permeability testing.

Figure 4: Permeability Machine that is used to check the permeability properties of the rammed

Sand

Figure 5: Universal Sand Strength Testing Machine that used to determine the strength of the

Rammed sand in Ib/inch2

Figure 6: Funnel tube that is used to allow the sand specimen into the steel tube.

Figure 7: Specimen tube that functions to remove the rammed sand out from the steel cylinder.

Figure 8: Vernier caliper that used to measure the height of the sand specimen after donePermeability and strength test.

Figure 9: The condition of the rammed sand after strength testing process.

Figure 10: The specimens that failed due to height requirement are not equal to 50.8 mm.

Figure 11: The reading of the universal sand strength testing machine just after the rammed sand

Specimen crack

Table 1 : Reading for 12 trials on the Green Sand specimen.

Table 2 : Reading for the twelfth trials.

Table 3 : Theoretical properties of permeability for green sand.


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1.0OBJECTIVE OF THE EXPERIMENT

There were several objectives of this experiment. Some of the objectives are:

1. To measure the properties of molding sands, green compression strength and

permeability of the sand block.

2. To expose the knowledge of molding process and all the standard procedures to the

students.

3. Enhance the skill of using the laboratory equipments with proper method and handling.


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2.0BACKGROUND OF STUDY

2.1Green Compression Strength

Sand strength test is the measure of holding power of various bonding materials in

green and dry sand. Green sand is made up from silica sand, bentonite (clay), coal dustand water in ratio of 4:2:2:1.This test determines the cohesiveness or natural binding

capacity of the sand grains and also required the sand specimen to ruptured under

compressive loading. Usually, there are 4 types of test for sand strength: (1) compression,

(2) shear, (3) tensile, and (4) over-hang bar test. Of these tests, the compression test is by

far most widely used and is very convenient for routine testing of all types of national

bonded and synthetic moulding sand.

For green compression strength test, the test is performed on the sand specimen by

using Universal Sand Strength machine. While, preparing the sand specimen, the sample

are required to be taken out quickly from the specimen tube to avoid the sample fromdrying which will cause increase in the strength of the sample. This machine also consists

of a pusher arm and weight arm, both hanging from a pivot bearing at the top of the

machine. The weight arm applies load on the specimen while pusher arm pushes the

specimen against the weight until the specimen breaks. Then the compression strength in

Ib/inch2

may be read from the magnetic marker. The green strength of sand is generally

in the range of 0.03 to 0.16 MPa.


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2.2Permeability

Permeability can be defined as physical property of the moulded mass of sand

mixture which allows gas to pass through it. It is determined by measuring the quantity of

air that passes through a given sample of sand in prescribed time and under standard

condition. Standard permeability is determined by measuring the time necessary for 2000cm

3of air to pass through the standard specimen while it is confined in the specimen

tube. Permeability of moulding sand depends on several factors including shape of sand

grains, fineness, degree of packing, moisture content and amount of binder present. In

conclusion, coarse grained sands are more permeable than finer ones.

The permeability number of the sand sample can be calculated from the following

equation:

P =

PxAxT

VxH

Where;

Volume of air, V = 2000 cm3

Height of sand specimen, H = 2 inches

Pressure, P = 10 gm/cm2

Cross sectional area of the sand specimen, A = 1 in2

Time, sec for 2000 cm3

air to pass through specimen, T

This equation also can be reduced to AFS permeability:

P =(sec)

7.3000

Tfor old machine working with Hg

These formulas reduce to AFS Permeability for Ridscale-Dieter:

P =pxt

30557=


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3.0APPARATUS USED IN EXPERIMENT

1) Materials

a. Silica sand

b. Coal dust

c. Bentonite

d. Water

2) Equipment

a. Permeability Machine

b. Sand Rammer

c. Universal Sand Strength Testing Machine

3) Hand Tools

a. Specimen Tube

b. Ruler.


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3.1MATERIAL USED

Figure 1: The sand that is produced from the addition of silica sand, coal dust, bentonite and

water altogether in the aluminum tray.

3.2EQUIPMENT USED

Figure 2: The digital weighing device used in this experiment in order to determine the

specific weight of the sand.

Figure 3: Sand rammer that is used to ram the sand for 3 times before permeability testing.


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Figure 4: Permeability Machine that is used to check the permeability properties of the

rammed sand.

Figure 5: Universal Sand Strength Testing Machine that used to determine the strength

of the rammed sand in Ib/inch2.

Figure 6: Funnel tube that is used to allow the sand specimen into the cylindrical steel

tube.


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3.3HAND TOOLS USED

Figure 7: Specimen tube that functions to remove the rammed sand out from the cylindersteel tube.

Figure 8: Vernier caliper that used to measure the height of the sand specimen after done

permeability and strength test.


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4.0EXPERIMENTAL PROCEDURES

1. The desired green sand needed is weighted by using the digital weighing devices ranges

between 145g to 175g.2. The green sand is filled in a cylindrical steel tube with help of a funnel tube altogether

with stopper at the end of the cylindrical steel tube.

3. The cylindrical steel tube is then located below the ramming machine where the ramming

process by turning the machine three times.

4. The cylindrical steel tube then carried out from the ramming machine and correctly

placed on the top of the permeability machine. The permeability machine was turned on

and the scale was set to zero scale.

5. The permeability number was collected and recorded.

6. The sand specimen was removed from the cylindrical tube by using specimen tube and

the height was measured and recorded in the table.

7. After that, the specimen was placed to the compress part of the universal sand strength

testing machine. The rammed sand specimen need to achieve the height of 50.8mm

0.125 mm to ensure specimen broke/ failure within the strength range on the universal

sand strength testing machine.

8. The initial reading was taken by setting the magnet pieces to the zero reading

9. The sand specimen was compressed by using the universal sand strength testing machine

until the sand specimen fails to support the load.

10.The reading of the condition where the sand specimen broke/failure was recorded for

analysis purposed.


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5.0RESULTS & DATA ANALYSIS

Number of

testing

Weight of green sand

used (g)

PermeabilityHeight

(mm)

Result

1 160.00 93 57.50 failed

2 155.00 92 56.40 failed

3 145.00 92 51.80 failed

4 142.50 90 50.44 failed

5 142.75 90 50.68 failed

6 142.85 84 50.20 failed

7 142.80 83 50.06 failed

8 142.55 107 51.18 failed

9 141.85 95 51.00 failed

10 142.50 97 51.48 failed

11 141.85 95 51.58 failed

12 139.70 105 50.67 Succeed

Table 1: Reading for 12 trials on the Green Sand specimen.

By observing the table 1, it shows 12 trials in which it shows the weight of the green sand,

permeability and the height. In the laboratory work, reproducing ramming condition are achieved

by the use of a standard sand rammer and specimen tube accessories. The sand is placed in the

specimen tube and rammed by impact with three blows of a standard weight. The height of the

specimen produced should have an exact value of 50.8 mm with the tolerance of 0.125 mm.From the experiment, our group managed to get 50.67 mm of the specimen height which is still

within the tolerance limit in order to proceed to the next step which requires determining the

strength value. The strength value obtained from the experiment is as below:


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Trial Mass(g) Permeability Height(mm) Strength(lb/in )

12 139.70 105 50.67 16.3

Table 2: Reading for the twelfth trials

By referring to the table 1 above, twelve sample or trials have been done to obtain the require

value of the sample height which is 50.8 mm 0.125 mm. On the twelfth trials, the reading are

manage to be obtained within the required range. Due to the twelfth trials, the results obtained

are as in table 2, in which it produced strength of 16.3 Ib/in2. Convert the unit Ib/in

2to SI units,

as it is shown below:

16.3 Ib/in2= 114.6023 kN/m

2


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5.1 SAMPLE CALCULATION

The permeability number, P are calculated by using the formula of,

P =PxAxT

VxH

Table 3: Theoretical properties of permeability for green sand

P =14516.610

08.52000

xx

x

P = 157.48

Therefore percentage error, %:

| |

Parameters Value

Volume of air, V (cm ) 2000

Height of sand specimen (cm) 5.08

Pressure, p (gm/cm ) 10

Cross sectional area of the sand specimen (cm )

6.4516

Time, T (minute) 1


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5.2 FIGURES OF FINAL RESULTS

Figure 9: The condition of the rammed sand after strength testing process.

Figure 10: The specimens that failed due to height requirement is not equal to 50.8 mm.

Figure 11: The reading of the universal sand strength testing machine just after the rammed sand

specimen crack.


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6.0DISCUSSIONS

Based from this experiment, the sand testing preparation (green sand).We had to measure the

properties of molding sands ,green compression strength and permeability of the specimen

(rammed sand).Based from the observation of the properties of molding sands, we could see that

the sand is in dark green/black color. The presence of this color was due to the addition of coal

dust inside the composition of the sand. Not just that, we found that the strength of the black

rammed sand was quite hard compare with the ordinary rammed sand. This condition is mainly

due to the presence of bentonite and cold dust that functions to increase the strength of the

specimen.

Meanwhile, according to the definition of the compression strength in the study of

strength of material, the compressive strength is the capacity of a material or structure to

withstand loads tending to reduce size. For green compression strength, it also can be interpret as

the capacity of the rammed sand to withstand the molten metal load that will be applies on the

surface of the rammed sand during pouring process. While, permeability is the property by which

we can know the ability of material to transmit fluid/gases. The permeability is commonly tested

in order to see if this material is suitable for the use of casting conditions. Permeability and green

compression strength are among the important mechanical properties and can be considered as

an important aspect in the sand casting mould preparation. These molding sand properties play a

vital role in determining the optimum moisture content for making green sand casting mould.

Green compression strength material normally has a high melting point. In order to find a

good material that will be able to withstand high temperature cause by the material, the strength

of must be larger than it melting point. Based on the result, only the twelfth trial manages to get

an accurate value which qualifies it to run for the strength test. The value of strength for the

height of 50.67 mm is 114.6023kN/m2. This value tells us that this green sand specimen can only

hold up to 114.6023kN/m2 before it start to change characteristic which it has crack on it

surfaces. The strength of the 139.70g may be different from the specimen mass due to the ratio

which is different. The error may bring lead to the different to the strength values are caused by

parallax error when taken the reading on the Vernier caliper. Unstable reading produce by the

strength machine and the angle of the reader may somehow give difficulties to read the


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measurement correctly. Permeability of the green sand also needs to be determined from this

experiment. In order to achieve the objective of, the sand specimen was removed from the

specimen tube; the specimen was places on the adapter of the universal sand strength testing

machine. From here the compression strength can be identified as it value can be read from the

scale. The twelfth specimen gives the reading of 105. Based on the formula provided, the

theoretical value of permeability of the green sand can be calculated and yields value of 157.48.

Then both theoretical and experimental value of permeability was compared and the percentage

of error was calculated. The percentage errors obtained in this experiment are . As wecan see, there was a different in the actual and experimental value of permeability. The value of

permeability obtained from the experiment much smaller than it supposed to be in the theoretical

value. In other words, the percentage of error had shown a little high in value. These different

may be caused by several factors such as moisture contents in the sample, was drying or affected

by the surrounding temperature.

The error that occur also may be influenced by the random error especially during the

experiment was conducted. This may begin from the first steps which is when the sand is poured

into the funnel directly to the test tube. While doing this, some of the sand may stick at the

funnel and the accuracy of mass is totally reduced. Next, when it is being rammed in the sand

rammer machine, the same thing may happen where a small number of sand will also stick at the

head of the rammer. Again, the mass of the specimen will be reduced. Although, the loss of sand

due to these is very small but it still may affected the whole process especially in the term of

sand volume. Since the volume drops, thus the dimension of the specimen may not be accurate,

and thus the desired height of 50.8 mm 0.125 mm might be hardly to be achieved.


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7.0CONCLUSIONS

In conclusion, the green compression strength and permeability and the properties of the

sample are well measured and observed. From what it can be seen, the strength of the green sand

managed to get is 114.6023kN/m2

or 16.3 Ib/in2. Both green compression strength and

permeability are important to enhance the properties while producing good casting products.

Theoretically, the strength of the molding sand is 30kN/m2

until 160kN/m2. But from the

experiment, the result obtained is 16.3 Ib/in2

or more accurate 114.6023kN/m2

which is still in

the range. But for the permeability value, in theory it is calculated as 157.48 but in experiment,

the value managed to achieve is 105. From the value of the permeability, the percentage error is

49.98 % .It shows that the value of the theoretical and experimental are different may be due to

the defects and environment factors.


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8.0RECOMMENDATIONS

During performing the experiments, we notice several ideas that can be proposed in order to

increase the accuracy of this experiment:

a) SAMPLING

i) Keep the sampling sand in an air-tight container or in closed area in order to prevent loss

of moisture.

ii) Make sure that the sand samples are free from other material such as small metal and

plastic composition as two of these compositions exist in our sampling sand.

iii)Do not ram the sand inside the cylindrical steel tube more than 3 times as the final height

of the specimen/sampling may be different.

b) WATER

i) Clay sand must contain the right amount of water in order to ensure the sand specimen is

not too dry or too wet which can finally resulted to the failure or success of the green

sand testing.

c) SPECIMEN PREPARATIONi) Make sure that the composition of the silica sand, coal dust, bentonite (clay) and water is

correct or in suitable condition to get the better result.

ii) Make sure that the height of a specimen is correct h=50.8mm 0.125mm, which is

within the tolerance specified.

iii)Pull away the specimen that damage in order to get precise and accurate result.

iv)Any deviation from standard ramming practice should be reported with results.

d) SPECIMEN TESTING

i) Handle specimens carefully to avoid the rammed specimen tear out from the original

rammed position.

ii) Always follow the instructions with regard to rate and method of applying load to

Specimen


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9.0REFERENCES

There are several sources that we used in order to complete this report. There sources are:

i) http://www.mechanicalengineeringblog.com/tag/green-sand-testing/

ii) A study of the permeability of sand, Frederic Mavis and Edward Wilsey, University

Iowa City, 1936

iii) Granlund, Matt (1999-03-01), "Understanding the basics of green sand testing",

Modern Casting89 (3): 3840, archived from the original on 2010-01-27.
http://www.webcitation.org/5n64QflAvhttp://www.allbusiness.com/manufacturing/fabricated-metal-product-manufacturing/248586-1.htmlhttp://www.allbusiness.com/manufacturing/fabricated-metal-product-manufacturing/248586-1.htmlhttp://www.webcitation.org/5n64QflAv

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