Comparison of Bentonite Characteristics Before and After Be Used as
Coagulan of
Liquid Tofu Waste
Ayu Yuliana*, Risfidian Mohadi, Fitri
Suryani Arsyad, Safaruddin
Universitas Sriwijaya, South Sumatera,
Indonesia
Email: (1*[email protected]), 2[email protected], 3[email protected],
4[email protected]
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Article Information |
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ABSTRACT |
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Received: January 17, 2023 Revised: January 29, 2023 Approved: February 16, 2023 Online: February 25, 2023 |
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The study aims to examine Bentonite characteristics before and after be used
as coagulan of liquid tofu waste. This research was conducted at the Quality Control. Bentonite obtained from East Java is a Ca-Bentonite type which has been
activated with H2SO4 20% based on the XRF results which showed CaO level of 4.15%. Bentonite can be reused after being applied as a coagulant and it�s based
on the results of the Bentonite XRD diffractogram pattern before and after
being applied as a coagulant that doesn�t have a significant change of 2q, including
the 2q montmorillonite at 21,98⁰ (516,42 cps),
35,47⁰ (384,43 cps),
62,26⁰ (100,66 cps) to 22⁰ (436,22 cps), 35,47⁰ (326,46
cps), 62,79⁰ (65,79 cps) and 2q of quartz (SiO2) at 26,5⁰ (607,56 cps) to 26,53⁰ (537,65 cps). The optimum coagulation conditionsis when height of bentonite is 900 mg
in 50 mL of liquid tofu waste pH 2, its can remove turbidity by 98% and TSS
by 84.6%. |
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Keywords |
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Bentonite;
Coagulation; XRD; Turbidity; pH; TSS |
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INTRODUCTION
Bentonite is
one of the abundant montmorillonite mineral resources in Indonesia. The
structure and content of bentonite includes hydrated alumina-silicate crystals
which have interlayers between layers and contain alkaline or alkaline earth
cations (Sakinah, 2020; Siregar & Irma, 2016). Bentonite is widely used as
an adsorbent in reducing the concentration of dyes and heavy metals. Research
result (Nugraha et al., 2017) wrote that bentonite has the potential as an
adsorbent in the adsorption process of heavy metal ions Cd (II) and bentonite
activated with acidic compounds has a higher absorption rate. However, in his
journal (Juhra & Notodarmojo, 2016) stated that the use of the adsorption
method was considered less effective in waste treatment because the adsorbed
waste could accumulate with the adsorbent, causing new problems.
Therefore,
(Suryadiputra, 1995) write down the waste treatment process with the
coagulation process believed to be a fast, effective, and efficient process in
reducing the concentration of waste by precipitating it with coagulants. The
coagulation process is a waste treatment technique that adds chemicals to
wastewater with the aim of making the impurity particles more easily settle and
bond with the coagulant to form larger flocs. Bentonite has the ability to
precipitate impurities because it contains Aluminum Oxide (Al2O3) and Al
cations in its interlayer which are the content of coagulants in general such
as alum (Husaini et al., 2018). According to Ruskandi (2020) bentonite has 2 types, including Na-Bentonite and
Ca-Bentonite. Na-bentonite has a higher swelling ability than Ca-bentonite.
However, the swelling ability of Ca-bentonite can be increased by activating
Ca-bentonite using sulfuric acid. The alkaline or alkaline earth group cations
that are in the bentonite interlayer can be replaced with H+ ions from sulfuric
acid so that the active site of bentonite increases. Maulani (2021) wrote that
liquid tofu waste originating from the process of soaking, washing soybeans,
washing tools, and filtering when printing tofu has a negative impact on the
surrounding environment, so it must be processed first.
Ginting (2021)
has conducted a study on the use of bentonite in measuring TDS and pH in his
journal stated that bentonite can reduce TDS by 98% and does not change the pH
of the water remains at pH 9 in formation water. Bentonite has also been used
to reduce turbidity by 94% and TSS by 83% in river water (Syafalni &
Pujiindayati, 2016). Bentonite clay can be a coagulant because it contains
aluminum and iron oxides (Bahri et al., 2013). In this study, bentonite
activation was carried out whose success was measured by characteristics using
XRF and XRD. The resulting bentonite will be used as a coagulant in tofu
factory wastewater. After being used as a coagulant, bentonite that has been
used will be re-characterized by XRD to see how much the intensity changes in
the bentonite crystal structure.
METHODS
This research
was conducted at the Quality Control (QC) Laboratory of PT. Semen Baturaja in
August 2022. XRD characterization was carried out at the Physics Laboratory of
Sriwijaya University. The tools used in this study included a set of laboratory
glassware, magnetic stirrer, pH meter, turbidimeter (Hach 2100Q), TSS meter
(Partech), TDS meter with portable meter HQ40D, XRF (ARL 9900 Series), and XRD
(Rigaku Miniflex-600).
Research procedure
Bentonite activation
Activated
bentonite was mixed with 500 mL 20% H2SO4 with a magnetic stirrer for 30
minutes. The mixture was allowed to stand for 5 hours until the filtrate and
precipitate separated which were then filtered using Whatman No. filter paper.
42. The resulting precipitate is then washed with distilled water at 70℃ so that the
sulfate ions from H2SO4 are completely removed and baked at 150℃ for 5 hours
to remove the water content. The precipitated powder obtained was in the form
of 20% H2SO4 activated bentonite which was then characterized using XRD and
XRF.
Performance of Bentonite as a
Coagulant of Tofu Waste based on Turbidity and pH Parameters
Bentonite Weight Variation
The initial
turbidity of tofu waste was measured with a turbidimeter. 50 mL of tofu waste
in a beaker added 100, 300, 500, 700 and 900 mg of bentonite respectively. The
mixture was stirred using a magnetic stirrer at a high speed of 1000 rpm. The
mixture was allowed to stand for 5 hours until the filtrate and precipitate
separated. After standing, the mixture is separated by filtration with filter
paper. The resulting filtrate was measured for turbidity while the precipitate
in the form of bentonite which had been used in the application was prepared
again. The precipitate is washed with distilled water until clean and oven at
150℃. Then bentonite powder was characterized using XRD.
Tofu Waste pH Variation
The initial pH
of tofu waste was measured with a pH meter. 50 mL of tofu waste was mixed with
900 mg of bentonite in a beaker glass for each tofu waste conditioned at acidic
pH (pH 2), neutral pH (pH 6), and alkaline pH (pH 8) with the addition of 0.1 M
NaOH and 0.1 M HCl. The next procedure follows the procedure for Bentonite
Weight Variation.
Measurement of Total Suspended
Solid (TSS) and Total Disolved Solid (TDS) Levels
TSS and TDS
levels were measured when bentonite weight and pH were optimum in the
deposition of tofu waste, namely 900 mg and pH 6.
RESULTS
Bentonite XRF
Based on the
results of the XRF measurements, the contents contained in the prepared and
activated bentonite are presented in Table 1 below.
Table 1
Bentonite XRF
Measurement Results
|
elements |
% content |
|
SiO2 |
61,23 |
|
Al2O3 |
8.56 |
|
Fe2O3 |
2,8 |
|
K2O |
0.44 |
|
CaO |
4,15 |
|
MgO |
0.72 |
|
Na2O |
0.00 |
Table 1 shows
the highest content in the prepared bentonite, namely SiO2 of 61.23%. The
bentonite used is known to be of Ca-bentonite type because of the CaO content
of 4.15% while the Na2O content is 0%.
XRD Activated Bentonite H2SO4 20%
In their journal, Zaher et al. (2018) wrote that the diffraction angle
for montmorillonite is at an angle of around 20⁰-22⁰ which
indicates Na/Ca-Montmorillonite, the diffraction angles of 35⁰ and
60⁰ also show other typical diffraction angles of montmorillonite, and at
an angle of 25⁰-28⁰ is the diffraction angle of quartz. The
diffractogram pattern of 20% H2SO4 activated bentonite is shown in Figure 1
below.
Figure 1.
Activated Bentonite XRD Diffractogram Pattern
Figure 1 above shows the typical diffraction angles of bentonite. The
results of observing the bentonite XRD diffractogram pattern can be seen in
Table 2 below.
Table 2
Analysis of
the Diffraction Angle of the Bentonite Diffractogram Pattern.
|
Compound Type |
Angle 2θ |
Intensity (cps) |
|
Montmorillonite |
21.98⁰ |
516,42 |
|
35.47⁰ |
384,43 |
|
|
62.26⁰ |
100.66 |
|
|
Quartz (SiO2) |
26.53⁰ |
607.56 |
The results of
the XRD analysis show that the highest intensity of bentonite is at the
diffraction angle of 26.53⁰ which is the angle of quartz (SiO2), this is
in accordance with the results obtained in the XRF analysis where the highest
content in bentonite is SiO2. The diffraction angles of 21.98⁰,
35.47⁰ and 62.26⁰ are typical angles of the montmorillonite mineral
where Ca, Al, Fe, Mg and K are contained in the interlayer.
Bentonite Weight Variation As
Coagulant
The initial
turbidity measured in tofu waste was 428 NTU. The turbidity measurement results
from variations in the weight of bentonite as a coagulant for tofu waste can be
seen in Figure 3 below. Figure 3 shows that the most effective precipitation
occurred in coaglulant weighing 900 mg with 24 NTU remaining. The percentage of
turbidity deposition of tofu waste can be calculated using the following
formula (Bangun et al, 2013).
%
Precipitation =
Information :
A = Initial Turbidity (NTU)
B = Residual Turbidity (NTU)
Figure 2. Value of
Residual Turbidity (Settlement Percentage) on Bentonite Weight Variations
Figure 2 shows that the increasing the
coagulant weight, the greater the percentage of tofu waste deposition that can
be precipitated together with bentonite. This is in accordance with the
statement of Rahimah et al. (2016) that the more coagulant, the better the
deposition of turbidity can occur. Heavy doses of coagulants greatly affect the
deposition process because if it is not appropriate, then precipitation is less
effective.
Tofu Waste pH Variation
The initial pH measured in tofu waste was pH 3. Tofu waste was conditioned
at pH 2, 6 and 8 with the addition of NaOH and HCl. The amount of turbidity
reduction (NTU) can be seen in Figure 4 below. Figure 4 shows that the most
effective turbidity deposition occurs at an acidic pH, namely pH 2, with a
remaining 9 NTU.
Figure 3. Value of Residual
Turbidity (Settlement Percentage) at Variations in pH of Tofu Waste
The figure above shows the largest percentage of deposition in the
condition of tofu waste at pH 2. This is possible because bentonite is more
active and expands in acidic conditions where the surface of the adsorbent will
have an excess of H+ protons so that the sides of the bentonite will be
positively charged and have the potential to bind impurities to the tofu waste.
anionic. The second highest percentage is in alkaline conditions, namely pH 8.
This is possible because the bentonite surface in alkaline conditions will be
negatively charged and has the potential to bind impurities in tofu waste which
are cationic (Dardinata et al., 2019). The pH of tofu waste after the coagulation
process can be seen in Figure 5 below.
Figure 4. The pH of
Tofu Waste After the Coagulation Process
Figure 5 shows
that after the coagulation process with bentonite coagulant, the pH of the tofu
waste is close to the normal pH, namely pH 6.5, which was previously pH 2.
Likewise, the tofu waste, which initially had a pH of 8, is close to the normal
pH, namely pH 7. This is in accordance with the Wastewater Quality Standards
Tofu Industry based on Regulation of the Minister of Environment of the Republic
of Indonesia No. 5 of 2014 concerning Wastewater Quality Standards, namely the
pH of tofu wastewater must be in the range of 6-9 (Sayow et al., 2020). In this
case, bentonite is good at improving the pH of tofu waste close to normal pH.
TSS
measurement
The TSS
measurement of tofu waste was carried out at the optimum bentonite weight
variation of 900 mg and the optimum pH variation of tofu waste was pH 2. The
TSS value of tofu waste before being deposited was 598 mg/L, after being
precipitated with bentonite the remaining TSS of tofu waste was 92 mg/L shown
by Figure 6. This shows that bentonite can reduce the TSS of tofu waste by 506
mg/L with a TSS reduction percentage of 84.6%.
Figure 5. TSS Value of
Residual Tofu Waste After Coagulation Process
This is in accordance with the Tofu Industry Wastewater Quality Standards
based on the Regulation of the Minister of Environment of the Republic of
Indonesia No. 5 of 2014 concerning Wastewater Quality Standards, namely TSS of
tofu wastewater with a maximum of 200 mg/L (Sayow et al., 2020).
XRD Bentonite
After Liquid Tofu Waste Coagulation Application
Bentonite that
has been used in each coagulation process is taken from the filtration process
and washed using distilled water until clean. Then the bentonite was dried
again using an oven at 150℃ to remove the water content and then measured using XRD. The bentonite
diffractogram pattern that has been applied as a coagulant can be seen in
Figure 6.
Figure 6. Diffractogram pattern of (a) Bentonite and (b) Bentonite that has been
applied as a coagulant
Figure 6 shows that there is no change in
the bentonite diffraction angle. The results of the diffractogram pattern
analysis after being applied as a coagulant (Figure 9b) are presented in Table
3 below.
Table 3
Analysis of
the diffraction angle of the bentonite diffractogram pattern after being
applied as a coagulant
|
Compound Type |
Angle 2θ |
Intensity (cps) |
|
Montmorillonite |
22⁰ |
436,22 |
|
35.47⁰ |
326,46 |
|
|
62.79⁰ |
65,79 |
|
|
Quartz (SiO2) |
26.53⁰ |
537.65 |
Table 3 shows
that there was no significant change in the XRD diffraction angle of bentonite
after being applied as a coagulant compared to benonite before being applied as
a coagulant as shown in Table 2 previously. However, the intensity of each
diffraction angle decreases. This may be caused by the reduced active side of
bentonite after depositing impurities in tofu waste so that the intensity of
the diffraction angle also decreases. Thus, bentonite that has been applied as
a coagulant can be processed and reused for the next coagulation process.
CONCLUSION
Bentonite from East Java was successfully activated
using sulfuric acid based on the results of XRF and XRD characterization.
Bentonite which has been successfully synthesized has been used as a coagulant
for tofu wastewater. Based on variations in weight of bentonite and variations
in pH of liquid tofu waste, the best turbidity deposition occurs in 50 mL of
liquid tofu waste with a coagulant weight of bentonite 900 mg and pH of tofu
waste in acid (pH 2) which can reduce turbidity by 98% and TSS by 84. 6%. The
pH condition of tofu waste after being precipitated is close to normal pH,
namely pH 6.5 (acid condition) and pH 7 (alkaline condition). The XRD
characteristics of bentonite before and after its application as a coagulant
did not experience a significant shift in the diffraction angle, but
experienced a decrease in intensity at each angle.
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