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Article

A Novel Eco-Friendly Circular Approach to Comprehensive Utilizing Bittern Waste and Oyster Shell

1
College of Chemical Engineering, Huaqiao University, Xiamen 361021, China
2
Department of Chemical Engineering and Chemistry, Eindhoven University of Technology, 5600 MB Eindhoven, The Netherlands
3
Department of Chemical & Process Engineering, Moi University, Eldoret 3900, Kenya
*
Authors to whom correspondence should be addressed.
Processes 2023, 11(4), 1209; https://doi.org/10.3390/pr11041209
Submission received: 21 March 2023 / Revised: 7 April 2023 / Accepted: 12 April 2023 / Published: 14 April 2023
(This article belongs to the Section Sustainable Processes)

Abstract

:
Efficient waste management, especially in relation to swaste reuse, has become a pressing societal issue. The waste bittern generated during salt production and discarded oyster shells present formidable environmental challenges and a waste of resources for some coastal regions. Therefore, this work developed a two-stage circular process for the environmentally friendly and efficient utilization of both waste materials. In the first stage, CO2 gas and an organic extraction phase comprising Tri(octyl-decyl)amine (R3N) and isoamyl alcohol were introduced into the waste bittern to obtain MgCO3·3H2O (s). The second stage involved reacting the reacted organic extraction phase with oyster shell powders to produce CaCl2·2H2O (s) and CO2 (g) and regenerate R3N. This work focused on investigating the yield of MgCO3·3H2O and the regeneration ratio of R3N, which are crucial indicators for the two stages involved in the process. The results indicate that, under optimal operating conditions, a maximum yield of 87% for MgCO3·3H2O was achieved, and the regeneration ratio of R3N reached 97%. Furthermore, the reaction mechanism and thermodynamic functions of the R3N regeneration process were elucidated as a crucial element in achieving a circular process. The findings of this work offer a sustainable solution to environmental pollution from waste bittern and oyster shells, and provide a promising avenue for green chemical production.

1. Introduction

Effective waste treatment and utilization, particularly of biomass wastes [1,2] and difficult-to-handle garbage [3], can promote sustainability and cost-effectiveness within green chemistry and engineering [4]. Waste bittern is a by-product of the salt-making industry and desalination processes, consisting mainly of salar bittern and sea bittern. Its release into the environment can have detrimental effects on living organisms [5,6]. Usually, the concentrations of magnesium ions and chloride ions in waste bittern are higher than those of other ions. Thus, the recovery of both salts can alleviate or eliminate environmental pollution associated with hem.
There are several techniques for salt recovery. For instance, chloride ions are recycled by concentration, crystallization, and electrolysis [7,8,9], whereas magnesium ions are recycled by trioctylamine and N235 extraction [10,11], membrane electrolysis [9], and via the preparation of Mg(OH)2, MgCO3, and struvite [12,13,14]. However, these techniques for removing ions from waste bittern suffer from drawbacks such as secondary pollution, high costs, and low efficiency. Therefore, there is a need for an environmentally friendly and efficient process to treat waste bittern before disposal into the environment.
Oyster breeding is a thriving global industry that generates a significant by-product: oyster shells, consisting mainly of calcium carbonate (approximately 95%). However, these shells are frequently disposed of in coastal waters or landfills, resulting in the emission of harmful gases, including NH3, H2S, and amines, as well as water pollution and the proliferation of insect breeding sites exacerbating environmental pollution [15]. Many research studies suggest that oyster shells can be utilized in various ways, including as fillers in the material industry. Many research studies suggest diverse uses for oyster shells, including as fillers in the material industry [16,17], building material [18,19], composite material [20,21,22], and in chemical engineering for wastewater treatment [23,24], carbon dioxide absorption [25,26], catalysis [27,28], and as a source of calcium.
However, these alternative uses often involve processing single, cheap oyster shells with large amounts of chemical raw materials or energy, resulting in high costs and poor returns. To address these challenges, a new process should be developed that allows oyster shells and other waste materials to interact with each other. This reduces the need for additional chemicals or energy, ultimately leading to reduced costs and promoting the simultaneous reuse of multiple waste streams. This process represents a critical step toward the efficient and sustainable utilization of oyster shells and other waste materials.
Therefore, the work explores a novel environmentally friendly process that utilizes oyster shells and waste bittern, both of which are sourced from the sea, to produce magnesium carbonate and other by-products. Two stages are planned in this process. In the first stage, an organic extraction phase comprising R3N, isoamyl alcohol, and CO2 from oyster shells are introduced into a waste bittern to yield MgCO3·3H2O. In the second stage, the used organic extraction phase is reacted with oyster shell powders to form CaCl2·2H2O, CO2, and R3N. Both R3N and CO2 are considered as recyclable materials and are reintroduced into the first stage. The process is optimized by systematically investigating the effects of reactant dosages, reaction time, stirring speed, temperature, and so on. Additionally, the reaction mechanism of the R3N regeneration process, which is crucial to this process, was studied. Compared to previous relevant research, this process represents a significant advancement in the simultaneous and environmentally friendly utilization of two primary sea wastes to produce chemical products without generating any new waste. All by-products are recycled within the system, resulting in an efficient and sustainable process that effectively utilizes waste materials. Therefore, the results of this study provide a new perspective on the utilization of oyster shells and bittern.

2. Materials and Method

2.1. Materials

Waste bittern was obtained from Quanzhou Seawater Salt Factory in Quanzhou, China, and the oyster shells were sourced from a seafood market in Xiamen, China. They were characterized by an X-ray fluorescence spectrometer (ARL Perform‘X 4200, Thermo Fisher Scientific, Waltham, MA, USA), and the results are shown in Table 1 and Table 2, respectively. Ethylenediaminetetraacetic acid disodium salt dihydrate (EDTA, ≥99.5%, CAS: 60-00-4), zinc oxide (≥99.0%, CAS: 1314-13-2), ammonia solution (25~28%, CAS: 1336-21-6), ammonium chloride (≥99.5%, CAS: 12125-02-9), chrome black T (IND, CAS:1787-61-7), phenolphthalein (IND, CAS: 77-09-8), sodium hydroxide (≥96.0%, CAS: 1310-73-2), calcium chloride (≥96.0%, CAS: 10043-52-4), and isoamyl alcohol (≥98.5%, CAS: 123-51-3) were all obtained as analytical reagents from Xilong Science Co., Ltd. (Guangdong, China). Hydrochloric acid (36.0~38.0%, CAS: 7647-01-0) and calcium-carboxylic acid indicator (IND, CAS: 3737-95-9) were supplied as analytical reagent by Sinopharm Chemical Reagent Co., Ltd. (Shanghai, China). Tri (octyl-decyl) amine (R3N, ≥95%, 68814-95-9) was sourced as analytical reagent from Wuhan yuancheng co-create technology Co. Ltd. (Hubei, China). Carbon dioxide (≥99.99%, CAS: 124-38-9) gas was from Quanzhou tianxing gas co. Ltd. (Fujian, China).

2.2. Method

The experimental process was divided into two parts, including waste bittern utilization process (Section 2.2.1) and oyster shell utilization process (Section 2.2.2). The process flow diagram is shown in Figure 1. All experiments were conducted thrice, and the maximum relative error observed was below 5%.

2.2.1. Waste Bittern Utilization

The experimental process involved the mixing of waste bittern with CaCl2, resulting in the formation of CaSO4·2H2O. The resultant mixture was subjected to a filtration process, which separated the solid CaSO4·2H2O residue from the waste bittern filtrate, which was free of SO42− ions. The equation of the reaction is as follows:
CaCl2 + MgSO4 + 2H2O → MgCl2 + CaSO4·2H2O↓
The next step involved subjecting the waste bittern filtrate without SO42− ions to a process that included mixing it with carbon dioxide, R3N, and isoamyl alcohol using a half-moon impeller in a 1000 mL three-necked-flask at 313.15 K. Filtration of the resulting mixture yielded a solid residue of MgCO3·3H2O and a filtrate consisting of residual waste bittern and an organic solution [29,30,31,32]. The organic solution was subsequently employed in the oyster shell utilization process. The composition of the solid residue was analyzed using X-ray fluorescence spectroscopy (XRF), and the result is tabulated in Table 3. Based on these results, the maximum purity that can be achieved is 98.75% in this work.
The equation of the reaction in this step is as follows:
MgCl2 + 2R3N + CO2 + 4H2O → MgCO3·3H2O↓ + 2R3N·HCl
The effects of different operating parameters, including the dosages of waste bittern, R3N, and isoamyl alcohol, reaction time, and stirring speed, on the yield of MgCO3·3H2O was systematically investigated. Further details on the characterization of the relevant substances in the waste bittern utilization process can be found in Appendix A. The yield of MgCO3·3H2O was calculated as follows:
λ 1 = n 1 n × 100 %
where λ1 denotes the yield of MgCO3·3H2O, n1 represents the moles of MgCO3·3H2O, and n represents the moles of magnesium in the waste bittern. The number of moles was determined by measuring the concentration of magnesium ion through titration method and calculating the volume used.
The titration method involved two steps. In the first step, the sample was diluted 100 times and mixed with triethanolamine solution, potassium hydroxide solution, and calcium–carboxylic acid indicator to determine the concentration of calcium ion. The resulting solution was titrated with a known concentration of EDTA solution (0.0213 M) until the color changed from purple to blue. In the second step, another sample from same solution was also diluted 100 times and mixed with triethanolamine solution, potassium hydroxide solution, ammonia–ammonium chloride solution, and chrome black T solution to determine the concentration of magnesium ion. This mixture was titrated with the known concentration of EDTA solution (0.0213 M) until the color changed from purple to blue. The concentration of magnesium ions was calculated based on the volume of twice-EDTA-used solution. Each titration experiment was repeated three times, and the relevant titration data can be found in Appendix B.

2.2.2. Oyster Shell Utilization

Initially, the oyster shells were thoroughly washed and ground into a fine powder. Next, the purified oil phase obtained from the first stage process, which contained R3N·HCl, was blended with the oyster shell powder and distilled water to produce R3N, CaCl2, and CO2. Calcium chloride dihydrate was then acquired by crystallizing a calcium chloride solution. The composition of CaCl2·2H2O was evaluated using XRF, and the corresponding results are provided in Table 4. Based on these results, the maximum that can be achieved is 96.63%.
The chemical reaction is as follows:
CaCO3 + 2R3N·HCl → CaCl2 + 2R3N + H2O + CO2
The characterizations of the relevant substances involved in the oyster shell utilization process can be found in Appendix A.
Although obtaining CaCl2·2H2O is an essential objective in the oyster shell utilization process, the regeneration of R3N is even more crucial because it plays a pivotal role in achieving a continued cycle in the two-stage process. Specifically, the occurrence of the R3N regeneration reaction directly impacts the feasibility of the circle process, while also positively affecting the conversion rate of calcium chloride. Therefore, the regeneration ratio of R3N is a crucial assessment index for this process, and it was determined using the following calculation:
λ 2 = n 0 ( R 3 N · H C l ) n r ( R 3 N · H C l ) n 0 ( R 3 N · H C l ) × 100 %
where λ2 represents the regeneration ratio of the R3N, and nr (R3N·HCl) and n0 (R3N·HCl) denote the final and initial moles of R3N·HCl in process, respectively. The molar concentration of R3N·HCl was determined through titration using a calibrated NaOH solution. The effects of operating parameters, including phase ratio between aqueous and oil phases and reaction temperature, on the regeneration ratio were investigated. Additionally, the thermodynamic function and reaction mechanism of the regeneration process were established in this work.

3. Results and Discussion

3.1. Effects of the Operating Conditions

3.1.1. Effect of Phase Ratio of Reactants on the Yield of MgCO3·3H2O

Figure 2 presents the effects of the phase ratio of waste bittern, R3N, and isoamyl alcohol on the yield of MgCO3·3H2O. Figure 2a shows an increase in the phase ratio between R3N and waste bittern, and an initial improvement in the yield of MgCO3·3H2O followed by a subsequent decrease. The results demonstrate that R3N, as an extractant, directly impacts the yield of the process. However, due to the high viscosity of R3N, the mixing efficiency between reactants is reduced when the phase ratio between R3N and waste bittern is larger than 4.8, ultimately resulting in a decrease in the yield. Isoamyl alcohol, as a diluent, has the capability of reducing the viscosity of the organic solution. Therefore, Figure 2b demonstrates that the addition of isoamyl alcohol improves the yield of MgCO3·3H2O by increasing the probability of contact between reactants through the viscosity reduction. However, when the dosage of isoamyl alcohol is higher, it can surround R3N molecules, thereby hindering the contact between reactants and R3H and ultimately resulting in a decrease in the yield. The results show that the best improvement in the yield of MgCO3·3H2O is achieved when the phase ratio of isoamyl alcohol is the same as that of R3H. The optimal phase ratio of waste bittern, R3N, and isoamyl alcohol in this work for achieving the highest yield is 1:4.8:4.8, respectively, which results in a yield of 87%.

3.1.2. Effect of Reaction Time and Stirring Speed on the Yield of MgCO3·3H2O

The effects of the reaction time and stirring speed on the yield of MgCO3·3H2O are shown in Figure 3. As seen in Figure 3a, the yield of MgCO3·3H2O increased with an increasing reaction time and balanced at the 7th hour, after which there was no significant change in the yield, indicating that the reaction had reached its optimal point. Longer reaction times resulted in more extraction reactions between the reactant molecules and a higher yield of MgCO3·3H2O; further increases in time had a limited effect on the yield. Therefore, an optimal reaction time of 7 h can be used to obtain a high yield of MgCO3·3H2O in this work.
It is evident from Figure 3b that the yield of MgCO3·3H2O gradually increased with an increase in stirring speed from 300 to 600 rpm and then remained generally constant. This is due to the fact that, at low stirring speeds, the oil phase and water phase were not mutually soluble, making it difficult for the reactants to come into adequate contact. A higher stirring speed, on the other hand, increased the contact between the reactants, resulting in an increased reaction rate and a higher yield of MgCO3·3H2O. However, there is a limit to the mixing capacity with a further increase in stirring, and higher stirring speeds also mean a higher energy consumption. Therefore, the optimal stirring speed can be established as 600 rpm in this work.

3.1.3. Effect of Phase Ratio of the Aqueous and Oil Phase on R3N Regeneration Rate

The regeneration rate of R3N increased gradually up to a maximum of 97% as the phase ratio of aqueous and oil phases rose from 0.0 to 0.67 and then remained relatively constant, as shown in Figure 4. Hydrochloric acid was produced during the regeneration process of R3H chemically with oyster shell powder, thereby improving the regeneration rate. Without the aqueous phase, it is difficult for the hydrochloric acid in oil phase to directly react with oyster shell powder, and the regeneration rate will be greatly reduced. However, the presence of an aqueous phase can dissolve hydrochloric acid from the oil phase and a small amount of oyster shell powder and quickly initiate a chemical reaction between the two substances, thereby promoting an increase in the regeneration rate of R3N. Therefore, increasing the phase ratio between the aqueous and oil solutions up to 0.67 is beneficial for improving the regeneration rate. However, when the phase ratio is further increased, the molecular exchange between the oil and aqueous phases may be nearing saturation, leading to the regeneration rate of R3N·HCl no longer growing, or even decreasing, due to a reduction in the concentration of hydrochloric acid in the aqueous solution that reduces the mass transfer between the two phases. According to Figure 4, the optimal phase ratio of the aqueous and oil phase can be set as 0.67 in this work.

3.1.4. Effect of Reaction Temperature on R3N Regeneration Rate

According to the data presented in Figure 5, the regeneration rate of R3N increased with an increase in the reaction temperature up to 318.15 K, achieving a maximum of 97%. Subsequently, the regeneration rate remained almost constant with a further rise in temperature. The R3N regeneration process is known to be endothermic, and detailed information can be found in Section 3.2. The higher reaction temperature facilitated the decomposition rate of R3N·HCl, resulting in an increased yield of R3N. However, temperatures beyond 358.15 K could cause the solvent in the oil phase to evaporate rapidly, leading to an increase in concentration and a slight reduction in the regeneration rate of R3N.

3.2. Thermodynamic Function Calculation and Reaction Mechanism of the R3N Regeneration Process

The reaction mechanism of the R3N regeneration process was investigated in this work. The organic regeneration solution of R3N, an aqueous solution of CaCl2, and CO2 gas were obtained by heating a mixture of the oil phase (R3N·HCl), distilled water, and oyster shell powder. The reaction equation is expressed as Equation (4). According to the equation, the equilibrium constant calculation expression is as follows:
K = C a C l 2 ( w ) [ R 3 N ( o ) ] 2 [ R 3 N · H C l ( o ) ] 2
The equilibrium constants at different temperatures were calculated, and the results are listed in Table 5.
According to van’t Hoff equation,
ln   K = Δ H R T + C
where K is the equilibrium constant, ΔH denotes the enthalpy change (J·mol−1), R is the molar gas constant (R = 8.314 J·mol−1·K−1), T is the absolute temperature (K), and C is a constant. Figure 6 displays the linear relationship between ln K and 1/T. The reaction was found to be endothermic, as evidenced by the negative slope of the line. The value of the slope was used to calculate ΔH, which was determined to be 56.0 kJ·mol−1.
The Gibbs function change (ΔG) and the entropy change (ΔS) of reaction (4) were calculated using the equilibrium constant and Gibbs function as follows:
ΔG = ΔHTΔS
ΔG = −RTlnK
The values obtained at 298.15 K were −10.1 kJ·mol−1 and 221.8 J·mol−1·K, respectively, indicating that the reaction can occur spontaneously at room temperature despite being endothermic. However, a higher temperature favors the yield of CaCl2, the overall reaction progress, and the regeneration rate of R3N.
Reaction (4) can be divided into two steps, expressed as Equation (10) and Equation (11), respectively:
R3N·HCl → R3N + HCl
CaCO3 + 2HCl → CaCl2 + H2O + CO2
The standard thermodynamic data of Reaction (11) is shown in Table 6, and the thermodynamic functions of reaction (11) are calculated as ΔH = −83.2 kJ·mol−1, ΔG = −60.9 kJ·mol−1 and ΔS = −76.7 J·mol−1·K−1 at 298.15 K. The results indicate that reaction (11) is exothermic and can occur spontaneously under room temperature and atmospheric pressure, without the need for additional energy.
According to the calculation rules governing thermodynamic functions of related reactions, reaction (10) has thermodynamic values of ΔH = 69.6 kJ·mol−1, ΔG = 25.4 kJ·mol−1, and ΔS = 149.2 J·mol−1·K−1 at 298.1 K. These values indicate that the decomposition process of R3N·HCl is endothermic and cannot occur spontaneously at room temperature.
The combination of reactions (10) and (11), achieved by adding oyster shell powder to the R3N·HCl solution, reduces the activation energy of the entire reaction, facilitating the decomposition of R3N·HCl at low temperatures and enabling a high conversion with minimal heat input. This approach is environmentally friendly and practical, not requiring harsh reaction conditions. The results also demonstrate the superiority and feasibility of the joint utilization of oyster shells and waste bittern.

4. Conclusions

This work developed an innovative, environmentally friendly two-stage process that utilizes oyster shells and waste bittern to produce magnesium carbonate and calcium chloride. In the first stage, a mixture of CO2, R3N, and isoamyl alcohol is injected into a waste bittern to obtain MgCO3·3H2O. The organic extraction phase from the first stage then reacts with the oyster shell to produce CaCl2·2H2O, CO2, and R3N in the second stage. The optimal conditions for the process were established as follows: in the first stage, a maximum yield of 87% for MgCO3·3H2O was obtained, with a phase ratio of waste bittern, R3N, and isoamyl alcohol of 1:4.8:4.8, a reaction time of 7 h, and a stirring speed of 600 rpm. In the second stage, the regeneration rate of R3N reached a maximum of 97% at a reaction temperature of 358.15 K and a phase ratio of 0.67 between the aqueous and oil phases. The process generates nearly zero waste as all by-products are recycled in the system, solving the problem of environmental pollution caused by waste bittern and oyster shells. This technology provides a new perspective for green chemical production. For future industrial applications, two main challenges in this system should be addressed: (1) the development of a more effective design for multiphase reactors to improve the efficiency of mixing and finally enhance the reaction and regeneration ratios, and (2) the optimization of the circulation efficiency of R3N, which is a crucial component that connects two stages, to reduce its loss and ensure its efficacy for future applications.

Author Contributions

Conceptualization: Q.Z. and W.P.; methodology: W.P. and S.W.; validation: D.Y. and Y.H.; formal analysis: W.P. and D.Y.; investigation: W.P.; resources: Q.Z.; data curation: W.P. and Y.Y.; writing—original draft preparation: W.P.; writing—review and editing: Y.Y. and M.A.; visualization: Y.Y.; supervision: Y.Y. and Q.Z. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by Industry-university-research collaboration project of Xiamen grant number [2022CXY02010].

Data Availability Statement

The data used to support the findings of this study are available from the corresponding author upon request.

Acknowledgments

The Instrumental Analysis Centre of Huaqiao University for analytical characterization is acknowledged.

Conflicts of Interest

The authors declare no conflict of interest.

Appendix A

Appendix A.1. Characterization Methods

The characteristic functional groups present in the oil phase were analyzed by Fourier transform infrared spectroscopy (FT-IR) over a range of 1000–3000 cm−1. The structural analysis and identification of MgCO3·3H2O, CaSO4·2H2O, and CaCl2·2H2O were conducted by powder X-ray diffraction (XRD), employing Cu Kα radiation (λ = 1.5406 Å) within a range of 2θ from 5° to 80°. The analysis results were generated using Jade software 5.0.

Appendix A.2. Characterization Results

Appendix A.2.1. The Fourier Transform Infrared Spectroscopy

The occurrence of the extraction reaction was confirmed using Fourier transform infrared spectroscopy, and the results are presented in Figure A1.
Figure A1. FT-IR spectra of R3N, isoamyl alcohol, R3N·HCl, and the mixture of R3N and isoamyl alcohol.
Figure A1. FT-IR spectra of R3N, isoamyl alcohol, R3N·HCl, and the mixture of R3N and isoamyl alcohol.
Processes 11 01209 g0a1
The stretching bands of the O–H vibration were observed within the range of 3347–3327 cm−1. When the extraction reaction did not occur, two types of hydrogen bonds, namely R3N···O–H and H–O···H–O, were identified. Upon comparing the three stretching vibration bands within the 3347–3327 cm−1 range, the peak of R3N·HCl was observed to shift 20 cm−1 higher, indicating the transformation of the hydrogen bonds from R3N···O–H and H–O···H–O to R3NH+···O–H and the occurrence of the extraction reaction. The stretching bands of the N–H vibration were observed in the range of 2700–2500 cm−1, and the presence of R3NH+···O–H in R3N·HCl led to a greater intensity and breadth of the N–H peak compared to other spectra. The stretching bands of the C–N vibration were observed at 1096 cm−1. Upon transformation from R3N···O–H to R3NH+···O–H, the peaks of the C–N stretching vibration shifted from 1096 to 1050 cm−1 [33].

Appendix A.2.2. The X-ray Diffraction Spectra for Products (MgCO3·3H2O and CaCl2·2H2O)

The diffraction patterns obtained from X-ray powder diffraction (XRD) analysis, as shown in Figure A2, exhibit a precise match with the diffraction patterns of MgCO3·3H2O and CaCl2·2H2O in the PDF-70-1433 and PDF-70-0385 databases, respectively. This result confirms that the products obtained from the process are indeed MgCO3·3H2O and CaCl2·2H2O. Additionally, the narrow peaks observed in the XRD patterns indicate the high crystallinity of the products, and the absence of any impurity peaks confirms the high purity of the products.
Figure A2. XRD patterns of (a) MgCO3·3H2O and (b) CaCl2·2H2O.
Figure A2. XRD patterns of (a) MgCO3·3H2O and (b) CaCl2·2H2O.
Processes 11 01209 g0a2

Appendix B

The calcium ions and magnesium ions concentration were calculated according to Equations (A1) and (A2):
C 1 = V 1 1000 × c M 1 × 1000 V 1000
C 2 = V 2 1000 V 1 1000 × c M 2 × 1000 V 1000
where C1 represents the mass concentration of calcium ions (mg/L), C2 represents the mass concentration of magnesium ions (mg/L), V1 represents the volume of the EDTA solution used for titrating calcium ions (mL), V2 represents the volume of the EDTA solution used for titrating magnesium ions (mL), c represents the molar concentration of EDTA (mol/L), M1 represents the molar mass of calcium (g/mol) (M1 = 40.08), M2 represents the molar mass of magnesium (g/mol) (M2 = 24.31), and V represents the volume of the water in which the waste bittern was diluted.
For example, the results for a sample are shown in Table A1.
Table A1. The results of magnesium ions concentration in a sample.
Table A1. The results of magnesium ions concentration in a sample.
Sequence of ExperimentsWater Sample Volume/mLEDTA Volume
/mL
Magnesium Ions’ Concentration/g/L
150.0054.5556.49
250.0055.2057.17
350.0055.1557.11
Average value50.0054.9756.92

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Figure 1. The process flow diagram of production of magnesium carbonate and calcium chloride from oyster shell and waste bittern.
Figure 1. The process flow diagram of production of magnesium carbonate and calcium chloride from oyster shell and waste bittern.
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Figure 2. Effect of phase ratio of reactants on the yield of MgCO3·3H2O at reaction time = 7 h, stirring speed = 600 rpm, and reaction temperature = 313.15 K: (a) the phase ratio between R3N and water bittern; (b) the phase ratio between isoamyl alcohol and R3N.
Figure 2. Effect of phase ratio of reactants on the yield of MgCO3·3H2O at reaction time = 7 h, stirring speed = 600 rpm, and reaction temperature = 313.15 K: (a) the phase ratio between R3N and water bittern; (b) the phase ratio between isoamyl alcohol and R3N.
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Figure 3. Effect of (a) reaction time (stirring speed = 600 rpm) and (b) stirring speed (reaction time = 7 h) on the yield of MgCO3·3H2O at Vwaste bitterns: VR3N: Visoamyl alcohol = 1:4.8:4.8 and reaction temperature = 313.15 K.
Figure 3. Effect of (a) reaction time (stirring speed = 600 rpm) and (b) stirring speed (reaction time = 7 h) on the yield of MgCO3·3H2O at Vwaste bitterns: VR3N: Visoamyl alcohol = 1:4.8:4.8 and reaction temperature = 313.15 K.
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Figure 4. Effect of phase ratio between aqueous and oil phases on R3N regeneration rate at stirring speed = 300 rpm, reaction time = 420 s, and reaction temperature = 353.15 K.
Figure 4. Effect of phase ratio between aqueous and oil phases on R3N regeneration rate at stirring speed = 300 rpm, reaction time = 420 s, and reaction temperature = 353.15 K.
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Figure 5. Effect of reaction temperature on regeneration rate of R3N at stirring speed = 300 rpm, reaction time = 420 s, and Va:V0 = 0.67.
Figure 5. Effect of reaction temperature on regeneration rate of R3N at stirring speed = 300 rpm, reaction time = 420 s, and Va:V0 = 0.67.
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Figure 6. The linear relationship between ln K and 1/T.
Figure 6. The linear relationship between ln K and 1/T.
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Table 1. Chemical composition of waste bittern.
Table 1. Chemical composition of waste bittern.
ElementClMgNaSKAlBr
Mass fraction/%18.244.764.152.711.350.540.25
Table 2. Chemical composition of oyster shell.
Table 2. Chemical composition of oyster shell.
ElementCaNaSClMgSiAl
Mass fraction/%21.290.640.200.420.210.090.05
Table 3. Chemical composition (%) of MgCO3·3H2O as analyzed by XRF.
Table 3. Chemical composition (%) of MgCO3·3H2O as analyzed by XRF.
CompoundMgCaSiSAl
Wt%50.130.9960.0590.0350.042
Table 4. Chemical composition (%) of CaCl2·2H2O as analyzed by XRF.
Table 4. Chemical composition (%) of CaCl2·2H2O as analyzed by XRF.
CompoundClCaMgNaS
Wt%52.7931.380.6940.6220.217
Table 5. Equilibrium concentrations and equilibrium constants at different temperatures.
Table 5. Equilibrium concentrations and equilibrium constants at different temperatures.
T/(K)c(R3N·H+)(o)/(mol/L)c(CaCl2)(w)/(mol /L)c(R3N)(o)/(mol/L)ln K
353.150.0320.6032.0657.798
343.150.0460.5942.0527.081
333.150.0660.5792.0346.313
323.150.0860.5642.0125.736
318.150.1060.5491.9925.270
302.150.1390.5241.9594.642
Table 6. Thermodynamic functions data of reaction (11).
Table 6. Thermodynamic functions data of reaction (11).
Thermodynamic Functions (298.15 K)CaCO3HClCaCl2H2OCO2
ΔfHm (KJ/mol)−1206.92−92.307−795.4−285.83−393.509
ΔfGm (KJ/mol)−1128.79−95.299−748.8−237.129−394.359
Sm (J/mol/K)92.9186.908108.469.91213.74
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Pan, W.; Yang, Y.; Yang, D.; Arowo, M.; Wu, S.; He, Y.; Zeng, Q. A Novel Eco-Friendly Circular Approach to Comprehensive Utilizing Bittern Waste and Oyster Shell. Processes 2023, 11, 1209. https://doi.org/10.3390/pr11041209

AMA Style

Pan W, Yang Y, Yang D, Arowo M, Wu S, He Y, Zeng Q. A Novel Eco-Friendly Circular Approach to Comprehensive Utilizing Bittern Waste and Oyster Shell. Processes. 2023; 11(4):1209. https://doi.org/10.3390/pr11041209

Chicago/Turabian Style

Pan, Wei, Yucheng Yang, Daomao Yang, Moses Arowo, Shuai Wu, Yingjie He, and Qingyou Zeng. 2023. "A Novel Eco-Friendly Circular Approach to Comprehensive Utilizing Bittern Waste and Oyster Shell" Processes 11, no. 4: 1209. https://doi.org/10.3390/pr11041209

APA Style

Pan, W., Yang, Y., Yang, D., Arowo, M., Wu, S., He, Y., & Zeng, Q. (2023). A Novel Eco-Friendly Circular Approach to Comprehensive Utilizing Bittern Waste and Oyster Shell. Processes, 11(4), 1209. https://doi.org/10.3390/pr11041209

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