Year 24 / Nº 37 / 2022 /
DOI: https://doi.org/10.36995/j.recyt.2022.37.003
Analysis of clay ceramic
microstructure with the glass waste incorporation
Análisis de la microestructura de
cerámica roja con la incorporación de residuo de vidrio
Análise microestrutural de Cerâmica
vermelha com incorporação de resíduo de vidro
Alexandre, Zaccaron1, *; Rafael G., Frizzo1;
Elton T., Zanoni1;
Leidy J.J., Nieves1; Fábio, Rosso2; Vitor S., Nandi1,2;
Oscar R. K., Montedo1; Adriano M., Bernardin1
1-
Programa de Pós-Graduação em Ciências e Engenharia de
Materiais, Universidade do Extremo Sul Catarinense, Criciúma, Brasil.
2- Departamento de Engenhara Cerâmica, Centro Universitário
Barriga Verde, Cocal do Sul, Brasil.
* E-mail: alexandrezaccaron@hotmail.com
Received: 13/05/2021; Accepted: 08/09/2021
Abstract
The study examined the microstructure of ceramics with
the addition of glass waste at different temperatures ranging from 800 to 1000
°C. Samples were molded by piston without vacuum, with the incorporation of 20%
(weight) of glass bottles, with coarse particles, for a better identification. The
raw materials were analyzed chemically and mineralogically by XRF and XRD. The
microstructural characterization was carried out by scanning electron
microscopy, SEM and optical microscopy, in order to analyze the behavior of
grain boundary and the interaction between the materials. The results showed that
there is compatibility between the materials, where the increase in temperature
causes a greater interaction, but when this temperature exceeds 900 ° C, pores
appear in the glass, a phenomenon known as overfiring.
Keywords: Clay
ceramic; Glass; Microstructure; Waste; Overfiring.
Resumen
El presente estudio examinó la microestructura de la
cerámica con la adición de residuo de vidrio a diferentes temperaturas, que
oscilan entre 800 y 1000 °C. Las
muestras fueron moldeadas por pistón sin vacío con la incorporación de 20% (en
peso) de botellas de vidrio, con partículas gruesas, para una mejor
identificación. La
materia prima fue analizada química y mineralógicamente por FRX y DRX. La
caracterización microestructural fue realizada por microscopía electrónica de
barrido (MEB) y microscopía óptica, con el fin de analizar el comportamiento
del límite de los granos y la interacción entre los materiales. Los resultados
mostraron que existe compatibilidad entre los materiales, donde el incremento
de la temperatura permite una mejor compactibilidad, sin embargo, cuando esta
temperatura supera los 900 °C aparecen poros en el vidrio, fenómeno conocido
como sobrecocción.
Palabras
claves: Cerámica roja; Vidrio; Microestructura; Residuo;
Sobrecocción.
Resumo
O presente estudo analisou a microestrutura de Cerâmica
vermelha com a adição de resíduos de vidro a diferentes temperaturas, variando
entre 800 e 1000 ° C. As amostras foram moldadas por pistão sem vácuo, com a
incorporação de 20% (em massa) de resíduos de garrafas de vidro, com partículas
grosseiras, para melhor identificação. As matérias-primas foram analisadas
química e mineralógicamente por FRX e DRX. A caracterização microestrutural foi
realizada por microscopia eletrônica de varredura (MEV) e microscopia óptica, a
fim de analisar o comportamento dos limites dos grãos e a interação entre os
materiais. Os resultados mostraram que existe compatibilidade entre os
materiais, onde o aumento da temperatura provoca uma maior interação, mas
quando esta temperatura excede os 900 °C, aparecem poros no vidro, um fenômeno
conhecido como overfiring.
Palavras
chave: Cerâmica vermelha; Vidro; Microestrutura; Resíduo; Overfiring.
INTRODUCTION
In recent years, studies have been carried out where
different wastes are incorporated into red ceramics as a viable option for the
environment and for the recovery of some wastes (thus avoiding landfill
disposal) [1]. This is because products
made from red clays have a great potential to absorb a large amount of
materials that are incorporated into the raw material due to the huge
production volume, long lifetime of these products, inertisation of waste and
the tolerance of red ceramic products and their processing to variations in raw
material composition making them attractive for encapsulation of solid waste
[2]. This allows the incorporation of reasonable amounts of waste into the
composition of pastes used in the manufacture of ceramic building products [3].
Glass used by the general population in the form of
containers is relatively inert and non-biodegradable [4]. Despite being a 100%
recyclable material, there is a large volume of material generated causing
environmental problems with regard to its storage in the appropriate place [5].
This encourages studies and research to reuse this waste in the different
manufacturing processes [6,7]. The incorporation of waste glass in products
made from clay is a natural alternative considering the compatibility of the
chemical composition of these materials and glass which is mainly composed of
silica (SiO2), sodium oxides (Na2O) and calcium oxide (CaO) [8,9].
Although there are different studies showing the
addition of the residues in red ceramics, many of these lack information
pointing to the compatibility of the materials [10,11]. It is extremely
important that there is an interaction between the incorporated residue and the
clay, so that it is not just an aggregate in the composition, thus becoming a
filler.
This study aims to evaluate the compactibility and
characterise the microstructure of ceramic pieces with the addition of glass
through microscopic analysis. The effects of firing temperature on the mixture
of clay and glass residue were discussed in terms of physico-mechanical
properties and microstructure.
MATERIALS
AND METHODS
The raw material used as the basis for the study was
provided by a ceramic company in Santa Catarina, Brazil. The standard paste
consisting of a mixture of different clay materials was taken after the
maturation and mixing process, where 100 kg of ceramic paste were collected
from four different points. Then, they were mixed and a sufficient quantity was
left for laboratory tests, obtaining at the end approximately 30 kg.
Approximately 10 kg of glass bottles were collected
and passed through the beneficiation process. The bottles were washed, aggregated
and transformed into fragments. In sequence they were dried in an electric
dryer (DeLeo brand n° 2211) and passed in a laboratory laminator (Bertan brand)
for the crushing of the grains. Finally, the crushed material was passed
through a 10 mesh (2 mm) sieve.
The red clay and glass residue were chemically
characterised using a Philips wavelength dispersive X-ray fluorescence
spectrometer (WDXRF) model PW2400. Mineralogical composition was carried out on
a Shimadzu X-ray diffractometer model XRD 6000.
Based on published studies [12,13], 20 % (by weight)
of waste glass was used in the ceramic paste. The preparation was carried out
through a helical screw mixer. Subsequently, the paste was put to rest for 24
hours for moisture homogenisation. The samples were prepared by piston
extrusion (without vacuum): 250 mm reduction with a 27 mm funnel with 45°
angle. With a constant pressure recorded by the manometer, 30 samples were
made. All the pieces were then placed in an electric dryer (DeLeo brand No
2211) at a temperature of 65 ± 5 °C for 24 h plus 12 h at a temperature of 100
± 10 °C for complete elimination of moisture. The last step of the heat
treatment process consists of firing, where the formulation was sintered in an
electric muffle furnace (Jung, model 7012), with a heating rate of 2 °C/min and
a holding time of 120 min, at three temperatures: 800, 900 and 1000 °C.
The technological properties of compressive strength
and water absorption of the samples were performed according to ABNT NBR 15270.
The mechanical test was carried out on EMIC DL-20000 equipment [14,15].
A scanning electron microscope (SEM) (Zeiss, EVO MA10)
and an optical microscope (Olympus, BX41M-LED) were used for grain boundary
analysis and to verify the interaction between the ceramic and the glass
residue.
RESULTS
AND DISCUSSION
Table 1 shows the chemical composition of the glass
containers, used as an alternative raw material in the study, and of the
ceramic paste.
Table 1.
Chemical analysis of raw material.
|
Oxides |
Raw material (%) |
|
|
Ceramic
paste |
Glass |
|
|
SiO2 |
65.63 |
70.81 |
|
Al2O3 |
18.24 |
1.94 |
|
CaO |
0.14 |
10.50 |
|
Na2O |
0.21 |
13.90 |
|
Fe2O3 |
4.95 |
1.06 |
|
K2O |
1.72 |
0.31 |
|
MgO |
0.56 |
0.62 |
|
Cr2O3 |
N.D. |
0.23 |
|
TiO2 |
0.94 |
0.06 |
|
MnO |
< 0.05 |
< 0.05 |
|
P2O5 |
0.08 |
< 0.05 |
|
P.F. |
7.50 |
< 0.39 |
P.F.
Loss on ignition
N.D.
Not detected
It is possible to observe that silica (SiO2) is
predominant in the composition of glass, and is the basic raw material with the
function of vitrification. Sodium oxide (Na2O) is the second most important
oxide in the glass composition, with the function of increasing mechanical
strength, as well as alumina (Al2O3). The oxides of calcium (CaO), magnesium
(MgO) and potassium (K2O) are other compounds that make up the glass, and have
functions such as increasing resistance to chemical attack and increasing resistance
to thermal shock. The analysis confirmed that the glass is of the
sodium-calcium type. The relevance of the study, the presence of silica (SiO2)
and sodium oxide (Na2O) in significant levels helps in the formation of liquid
phases improving the quality of the piece, especially in relation to mechanical
strength, as they are fluxing oxides and help in the vitrification of the
material [8,16].
The oxides of the chemical elements presented in Table
1 are present in the crystalline phases identified in the X-ray diffractogram
in Figure 1(a) for the clay. The crystalline phases of quartz (SiO2, JCPDS no.
46-1045), microcline (KAlSi3O8, JCPDS no. 19-932) and kaolinite
(CaAl2Si2O8.4H2O,JCPDS no. 20-0452), characteristic of a clay body used for the
manufacture of red ceramics, were identified. Figure 1(b) shows the
diffractogram for the glass residue, an amorphous structure is observed.
|
(a) |
(b) |
|
|
|
Figure
1. X-ray diffractogram of (a) clay mass and (b) glass.
The technological analysis of the sample with 20 %
glass incorporated into the clay mass (Figure 2) indicates that the increase in
temperature densifies the final piece. This behaviour is a consequence of the
formation of liquid phases caused by the high temperature where the softening
point of the glass is exceeded. This causes the glass to fill the porosity
sites contributing to the decrease of water absorption of the ceramic pieces
[17-19].
It should be emphasised that the use of solid wastes
with fluxing characteristics, such as glass, has the tendency to present a
significant increase in the compressive strength of the ceramic piece [14-15].
It is also necessary to take into consideration that the increase of
temperature improves the mechanical behaviour of the ceramic piece as a
consequence of the sintering of the grains causing a higher density. In
relation to the particle size of the glass residue, the larger the particle
size, the higher the energy required to generate the liquid phase [16], making
higher temperatures more effective in this study.
Figure
2. Analysis of the mechanical compressive strength versus water absorption
of the samples with 20% glass incorporated.
SEM analysis of the mixture of the components at 800
°C (Figure 3(a)) shows the presence of separated particles, where the glass at
this temperature only appears as an aggregate, i.e. substantially inert. After
firing at 900 °C (Figure 3(b)) of the sample surface, a stronger interaction
between the glass and the ceramic body was observed, forming a glass base very
different from the sample at 800 °C. At 1000 °C (Figure 3(c)) it can be
observed that there is a stronger interaction during firing of the glass
particles with the matrix. That is, as the firing temperature was increased,
the glass phases become more fluid allowing a better contact and interaction
with the solid phase of the clay and thus a decrease in porosity occurs
resulting in a lower water absorption which changes from 17.3% at low
temperature to 12.9 % for firing at 1000 °C [20]. Another point observed is the
geometry of the particles, which, as the temperature increases, change from
being particles with more spiny ends to more oval, this phenomenon is explained
by the increase of the energy applied to sintering which, from the same
principle as highlighted above, changes the morphology of the glass particles
[21].
Figure
3. SEM micrographs of red ceramics with a glass content of 20 wt.% as a
function of firing temperatures: (a) 800 °C, (b) 900 °C and (c) 1000 °C.
Figure
4 illustrates the results of the optical microscopy, where it can be seen
that, regardless of the applied temperature, the glass particles show affinity
with the ceramic matrix, i.e. there is a matrix-reinforcement interaction.
Figure 4. Optical
microscopy images of red ceramics with a glass content of 20 wt.% as a function
of firing temperatures: (a) 800 °C, (b) 900 °C and (c) 1000 °C.
It is possible to observe that from 900 °C onwards
there is a release of volatile substances derived from the high temperatures,
which caused the generation of bubbles in the formation of the liquid phase and
left pores in the sample as observed in some points of Figure 4. The porosity
at higher temperatures may result from the compaction stage and be generated in
the firing process itself by loss of mass caused by the release of volatiles or
as a consequence of the different coefficients of thermal expansion of the
phases present in the ceramic, generating cracks. This behaviour is explained
by a phenomenon called overfiring porosity, which occurs when a material is
fired at a temperature above that required to produce a liquid phase. The
result of this phenomenon is the appearance of deformations, bubbles or pores
[18,22,23].
CONCLUSION
From the evaluation of the microscopy results of the
samples, it was possible to observe that there is a large interaction of the
glass composite-based ceramic clay matrix.
At 800 °C the glass remains inert, and at higher
temperatures (900 and 1000 °C) there were physical changes resulting in
vitrification and pore generation as a product of gas release.
Despite these phenomena, it is concluded that glass is
a material that is suitable for the manufacture of clay-based products, giving
these wastes a sustainable environmental destination.
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