This document describes an experiment to determine the fracture toughness and strength of plaster. Plaster bar and jacket samples were tested using three-point bending and compression. The fracture toughness of plaster bars was found to be 0.0256 MPa m1/2. The strength of plaster bars under compression was 151 MPa. The strength of plaster jackets under compression was 4.35 MPa. The first and second bending strengths of plaster jackets were 1.33 MPa and 3.47 MPa respectively. Results were reported in tables and figures, and were slightly different than literature values, which are accounted for later in the report.
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Design, Strength, and Failure of Paleontology Plaster Jackets
1. Georgia Institute of Technology
School of Material Science and Engineering
771 Ferst Drive
J. Erskine Love Building
Atlanta, GA 30332-0245
MSE 3005 Mechanical Behavior of Materials
Final Group Project
April 2, 2016
Through
April 2-20, 2016
Tyler Rice
Group Members: Kinsey Canova, Jarad Heimer, Shannon Parker
Submitted on April 29, 2016
Abstract
In this experiment, the fracture toughness and strength of plaster were found by using
compression and three-point bending. These values were found using plaster bar samples with
and without notches, and the strength of plaster jackets used for protecting fossils was found.
The fracture toughness was found to be 0.0256 MPa m1/2
, the strength of the plaster bars was
found to be 151 MPa, the strength of the jackets put under compression was found to be 4.35
MPa, and the first and second bending strength of the jackets were found to be 1.33 MPa and
3.47 MPa, respectively. The results found from the experiments were not exactly the same as
what was found in the literature, and are accounted for later in this report.
2. Introduction:
Plaster of Paris consist of Calcium Sulfate Hemihydrate, 𝐶𝑎𝑆𝑂4 ∙
1
2
𝐻2 𝑂. This is formed
by heating gypsum to a temperature between 120°C and 160°C. The reaction is as follows:
𝐶𝑎𝑆𝑂4 ∙ 2𝐻2 𝑂 ↔ 𝐶𝑎𝑆𝑂4 ∙
1
2
𝐻2 𝑂 + 1
1
2
𝐻2 𝑂
When in reverse, this reaction is exothermic and allows for the interlocking needle-shaped
gypsum crystals that are seen in Plaster of Paris. Plaster of Paris is a brittle solid, and has fracture
properties similar to cement, sandstone, and many other porous ceramics [1]. Plaster of Paris is
the ideal ceramic to use when forming casts to protect and transport fossils.
Plaster molds are commonly used to produce nonferrous castings because it has a
smoother as-cast surface, better dimensional accuracy, and thinner sections than what can be
produced by other sand casting techniques [2]. Plaster of Paris is very easy to make. It just takes
two parts of plaster to one part of water to rehydrate it. It is then easily poured into molds and
begins to cure within ten minutes, but takes around 72 hours to fully cure [3].
In this experiment, the strength and fracture toughness of the Plaster of Paris was found
using various techniques. Flat slabs of the plaster were used to find the data in a three-point bend
and under compression. Small scale jackets that could possibly be used to protect a fossil were
then put under three-point bend and compression as well to find the data needed to calculate the
strength and fracture toughness of the specimens.
Procedure:
The plaster used in this experiment was made using the following instructions. Mix a ¼
cup of plaster with a 1/8 cup of water to get the consistency needed to form the strength, fracture
toughness, and jacket specimens. The mixture was mixed until there were no more clumps or
powder left. Then the mixture was used to form the specimens needed for the various test.
In order to form the specimens for the strength test, the plaster mixture was poured onto
cardboard wrapped in aluminum foil that was cut to fit five specimens on it. After the mixture
was poured, a fork was used to divide the plaster into five samples needed for the testing. The
plaster was then allowed to cure for three days. The following measurements were taken on the
third day for all samples using a digital caliber: length of specimen, width of specimen, and
thickness of specimen. After these measurements were taken, each sample had a gallon jug hung
from it, and water was poured into the jug until the sample broke. The weight of the setup was
measured before and after testing each sample, with the scale being tared before each test.
3. Figure 1 Set up for Strength Specimens
To form the specimens for the fracture toughness test, the plaster was poured onto
cardboard wrapped in aluminum foil that was cut to fit five specimens on it. After the mixture
was poured, a fork was used to divide the plaster into five samples, and add the notches needed
for the testing. The plaster was then allowed to cure for four days. The following measurements
were taken on the fourth day for all samples using a digital caliber: length of specimen, width of
specimen, notch length, and thickness of specimen.
4. Figure 2 Measuring Length of Notched Specimen
After these measurements were taken, each sample was then held upright by a team
member and a gallon jug was hung from it. Water was then poured into the jug until the sample
broke. The weight of the setup was taken before and after the testing for each sample, and the
scale was tared before each test.
5. Figure 3 Set Up for Notched Specimen
To form the specimens for the compression and bending of the plaster jackets,a plumbing
cover was first cut in half and then cut into pieces big enough to be tested. Then these pieces
were covered in saran wrap and had plaster was poured onto them. The plaster was then spread
out using forks and butter knives to get the desired thickness and length of the flanges.
6. Figure 4 Making of the Jacket Specimens
These samples were then allowed to cure for three days. The following measurements
were taken on the third day for all samples using a digital caliber: length of each flange, radius of
curvature, width, and thickness of specimen.
For the compression of the plaster jackets, the jacket was laid on a flat surface while a
team member held a gallon jug in place on top of the arc of the jacket. Then, another team
member poured water into the gallon jug until the jacket broke. The weight of the set up was
taken before and after for each sample, and the scale was tared before each test.
7. Figure 5 Set Up for Compression of Jacket Specimens
For the first bending experiment, each sample had a gallon jug hung from it, and water
was poured into the jug until the sample broke. The weight of the set up was taken before and
after for each sample, and the scale was tared before each test.
Figure 6 Set Up for First Bending of Jacket Specimens
8. To form the specimens for the second bending experiment of the plaster jackets, a
plumbing cover was first cut in half and then cut into pieces big enough to be tested. Then these
pieces were covered in saran wrap. Plaster was made with three to one ratio of plaster to water,
and then poured onto the saran wrapped models. The plaster was then spread out using forks and
butter knives to get the desired thickness and length of the flanges. These samples were allowed
to cure for 48 hours. The samples were then sanded, and the following measurements were taken
for all samples using a digital caliber: length of each flange, radius of curvature, width, and
thickness of specimen. Then one of the flanges of each sample was hung after being clamped by
a wremch, while the other flange had a gallon jug hung from it. Water was then added to the jug
until fracture occurred. The gallon jug was weighed before and after each experiment, and the
scale was tared before each test.
Figure 7 Second Bending Experiment
10. Table 3. Raw Data for Compression of Plaster Jackets
Sample Radius (m) Thickness
(m)
Right
Flange (m)
Left Flange
(m)
Load (lbs) Width (m)
1 0.0246 0.00115 0.02852 0.02871 1.4 0.03092
2 0.02502 0.00246 0.02838 0.04914 1 0.02016
3 0.02594 0.00435 0.03125 0.02866 4.4 0.03068
4 0.02633 0.00243 0.03139 0.02933 3 0.02879
5 0.02563 0.00441 0.03037 0.03463 2.4 0.03205
11 0.02714 0.00454 0.03511 0.06499 2.6 0.02264
Table 4. Raw Data for First Bending of Plaster Jackets
Sample Radius (m) Thickness
(m)
Right
Flange (m)
Left Flange
(m)
Load (lbs) Width (m)
6 0.02349 0.00409 0.04039 0.0244 2.2 0.03649
7 0.02513 0.00325 0.03542 0.03069 0.6 0.02645
8 0.0263 0.00299 0.02387 0.03596 1 0.03294
9 0.02771 0.00353 0.03307 0.04603 0.6 0.03111
10 0.02776 0.0035 0.02645 0.02682 3 0.02964
Table 5. Raw Data for Second Bending of Plaster Jackets
Sample Radius (m) Thickness
(m)
Right
Flange (m)
Left Flange
(m)
Load (lbs) Width (m)
1 0.02475 0.00207 0.02595 0.04162 0.46875 0.02914
2 0.0245 0.00208 0.03226 0.0281 0.9075 0.03124
3 0.024975 0.00209 0.03332 0.0385 0.8825 0.03953
4 0.02497 0.00313 0.0281 0.03831 1.955 0.03435
5 0.02496 0.00283 0.0312 0.0343 1.4025 0.03615
11. The following equations were used to find the Stress of the Plaster Bars [4].
𝜎 =
𝑀𝑌
𝐼
(1)
Where
𝑀 =
𝐹
2
=
𝐿𝑜𝑎𝑑∗0.45359237
2
(2)
𝑌 =
𝑇ℎ𝑖𝑐𝑘𝑛𝑒𝑠𝑠
2
(3)
𝐼 =
𝑇ℎ𝑖𝑐𝑘𝑛𝑒𝑠𝑠∗𝑊𝑖𝑑𝑡ℎ3
13
(4)
Table 6. Strength of Three Point Bend Plaster Bars
Sample Number Stress (Pa)
1 1.51E+08
2 1.63E+08
3 1.98E+08
4 1.14E+08
5 1.25E+08
6 1.55E+08
Average 1.51E+08
Standard Deviation 26920863.13
The following equations were used to find the Fracture Toughness of the Plaster Bars [4].
𝐾𝐼𝐶 = 𝑓(
𝑎
𝑊
)
𝑃
𝐵√𝑊
(5)
Where:
𝑓 (
𝑎
𝑊
) =
3
𝑆
𝑊
√
𝑎
𝑊
2(1+2
𝑎
𝑊
)(1−
𝑎
𝑊
)
3
2
[1.99 −
𝑎
𝑊
(1 −
𝑎
𝑊
) ∗ {2.15 − 3.93 (
𝑎
𝑊
) + 2.7 (
𝑎
𝑊
)2
}] (6)
12. Table 7. Fracture Toughness of Plaster Bars
Sample KIC (Pa m1/2
)
1 58593.55652
2 9184.685291
3 42298.25288
4 25922.06963
6 14192.86712
7 18416.26292
8 10273.15159
Average 25554.40656
Standard Deviation 17128.08553
The following equations were used to find the stress of Compression of the Plaster
Jackets [4].
𝜎 =
𝑀𝑌
𝐼
(7)
Where:
𝑀 =
𝐹𝑜𝑟𝑐𝑒
2
∗ 𝑅𝑎𝑑𝑖𝑢𝑠 (8)
𝑌 =
𝑇ℎ𝑖𝑐𝑘𝑛𝑒𝑠𝑠
2
(9)
𝐼 =
𝑇ℎ𝑖𝑐𝑘𝑛𝑒𝑠𝑠∗𝑊𝑖𝑑𝑡ℎ3
12
(10)
13. Table 8. Stress found from Compression of the Plaster Jackets
Sample Stress (Pa)
1 11231585
2 2734889
3 2621814
4 6196279
5 1316036
11 2016546
Average 4352858.051
Standard Deviation 3440205.135
The following equations were used to find the stress of the plaster jackets under a three
point bend [4].
𝜎 =
𝑀𝑌
𝐼
(11)
Where:
𝑀 = 𝐹𝑜𝑟𝑐𝑒 ∗ 𝑅𝑎𝑑𝑖𝑢𝑠 (12)
𝑌 =
𝑇ℎ𝑖𝑐𝑘𝑛𝑒𝑠𝑠
2
(13)
𝐼 =
𝑇ℎ𝑖𝑐𝑘𝑛𝑒𝑠𝑠∗𝑊𝑖𝑑𝑡ℎ3
12
(14)
14. Table 9. First Set of Plaster Jackets Under Three Point Bend
Sample Stress (Pa)
6 1129011
7 719721.4
8 1190976
9 571941.3
10 3058718
Average 1334073.587
Standard Deviation 893890.5659
Table 10. Second Set of Plaster Jackets Under Three Point Bend
Sample Stress (Pa)
1 2478160
2 4387510
3 3404426
4 3868385
5 3224849
Average 3472665.928
Standard Deviation 640100.8568
15. Figure 8 Fracture Surface for Bending of Plaster Bar
Figure 9 Fracture Surface for Compression of Plaster Bar
16. Figure 10 Fracture Surface for Compression of Plaster Jacket
Figure 11 Fracture Surface for First Bending of Plaster Jackets
17. Figure 12 Fracture Surface of Second Bending of Plaster Jacket
Discussion:
As seen in Figures 8-12, all the fractures are brittle fractures. This can be determined
because all of the fractures appear caused by a pore, or a pre-notch. It is also seen in the figures
that they are brittle fractures because no necking occurs. If any necking had occurred, then it
would have been a ductile fracture. The fracture surfaces are also rough, which is a sign of brittle
fracture.
In the literature, it was found that the fracture toughness of the plaster is 0.14±0.015 MPa
m1/2
[1]. From the experiments, it was found that the average fracture toughness of the plaster is
0.0256 MPa m1/2
. It was also found in the literature that the tensile strength of Plaster of Paris is
3.2±0.6 MPa [1]. From the experiments performed, the average strength for the plaster bars was
found to be 151 MPa, the average stress due to the compression of the plaster jackets was found
to be 4.35 MPa, the average stress due to the first bending done on the plaster jackets was found
to be 1.33 MPa, and the average stress due to the second bending done on the plaster jackets was
found to be 3.47 MPa.
There are many possible reasons that the fracture toughness experiment was considerably
low compared to the literature. One of them is that the viscosity of the plaster mix between
18. different samples could different. This could be caused by different plaster to water ratios being
used when mixing the plaster. The ratio being inconsistent would have casued the viscosity to be
different. Along with that, there caould have been pores in the samples, allowing for a brittle
break. Pores would have made it easier for the samples to break. Pores could have formed as
water evaporated out of the samples as they cured.
On average, the strength of the plaster jackets ended up being close to what was found in
the literature. The strength of the plaster bars is very high compared to what the literature says.
The difference between the experimental and literature strengths could be caused by one of the
errors from calculating fracture toughness: either viscosity differences between samples, or the
formation of pores during the curing process. Another error that could have occurred is human
error when calculating the strength. It is possible that the wrong equations were used, wrong
assumptions were made, or errors when calculating occurred.
The assumptions made in all of the calculations were that the samples had a uniform
thickness throughout, along with the width and radius of the jackets. This is not true for any of
the samples with the thickness, width, and radius of the jackets being inconsistent throughout due
to the way the plaster samples were molded. Also, when calculating the strength of the plaster
jackets, it was assumed that the area affected the most was rectangular in shape to make
calculating Equations 4, 10, 14 easier. It is a good assumption, but it is not accurate. It does not
take into consideration that the samples are semi-circles with flanges.
The strength of the jacket specimens was predicted to be around the same strength as the
plaster bars that were first tested. This was not the case. As seen in the literature mentioned
earlier, the jackets were close to it, but the plaster bars were far from what was in the literature.
They are different because of the possible errors discussed earlier about the viscosity, pores, and
human error in math calculations.
Conclusion:
In conclusion, all of the specimens broke as they were expected to break, with a brittle
fracture that starts from either a pre-notch, or from a pore in the material. The stress that it took
for the specimens to break was not as expected. This could be caused by different viscosities
among the samples, different amount of pores present in each sample, and human error in the
calculating the stress. Plaster of Paris is known to be a porous material, which is why it makes it
ideal for the protection of fossils. It is easy to make on site, and is strong enough to protect the
fossils as seen in the experiments. It can withstand the stresses due to the transportation of the
fossils, and if it was dropped it would possibly protect the fossil by either absorbing all the force
and breaking or by absorbing the force and not breaking.
19. References:
1. G. Vekinis, M.F. Ashby, P.W.R. Beaumont, Plaster of Paris as a Model Material for
Brittle Porous Solids, Journal of Materials Science, Cambridge University Engineering
Department, Cambridge, 1993.
2. Thomas S. Piwonka, Plaster Casting, Molding Methods, ASM Handbooks Online, The
University of Alabama, 2002. Retrieved from:
http://products.asminternational.org/hbk/do/section/content/MH/D26/A03/S0079547.htm
l?anchor=_top&highlight=true&start=0.
3. A. J. Parmar, S. K. Tyagi, V. S. Dabas, J. N. Mistry, S. K. Jhala, D. N Suthar, R. H.
Bhatt, D. V. Pansuria, I. M. Bhatti, Assessment of the Physical and Mechanical
Properties of Plaster of Paris Bandage Cast Used as a Splinting and Casting Materials,
Veterinary World, December 2014.
4. Marc Meyers, Krishan Chawla, Mechanical Behaviors of Materials, Cambridge, MA:
Cambridge Univeristy Press, 2008.