Abstract

The desulfurization and denitrification wastewater (DDW) from the wet flue gas treatment project is difficult to be treated and recycled because of high chloride ion (Cl) concentration. Cl can cause equipment and piping corrosion. However, there is a lack of cost-effective treatment technologies for the removal of Cl from the DDW. In this research, the feasibility of Cl removal from the DDW using Friedel’s salt precipitation method was evaluated. Factors affecting the Cl removal, such as Ca(OH)2 dosage, NaAlO2 dosage, solution’s initial pH, solution’s temperature, reaction time, stirring speed, and anions (SO42−, NO3, and F), were investigated, and the optimal experimental conditions for Cl removal were determined. Experimental results showed that Friedel’s salt precipitation method can remove Cl effectively and can achieve synergistic removal of SO42−, F, and heavy metal ions. Under the best experimental conditions, the average removal efficiencies of Cl, SO42−, F, and heavy metal ions reach more than 85%, 98%, 94%, and 99%, respectively. The Cl removal mechanism studies showed that Cl can be removed by precipitation as Ca4Al2Cl2(OH)12. The purified wastewater and the precipitated solid can be reused to reduce the consumption of water and alkali. Friedel’s salt precipitation method is an effective control technology for the synergistic removal of Cl, SO42−, F, and heavy metal ions and has enormous potential to be applied in the industrial wastewater treatment field.

1. Introduction

The wet flue gas desulfurization (WFGD) technology is one of the world’s most widely used flue gas desulfurization technology due to its high desulfurization efficiency and low investment and operationg costs [1]. Meanwhile, in order to cost-effectively control SO2, NOx and other pollutants in the flue gas, scholars have developed a variety of multipollutant cooperative control technologies based on the WFGD in recent years. The main principle of the technology is through adding an oxidizing agent to the WFGD system to achieve synergistic removal of multipollutants from the flue gas. Ozone [2], chlorine dioxide [3], potassium persulfate [4], potassium permanganate [5], sodium chlorite [6, 7], and other oxidizing agents [8], have all been tested for multipollutants control, among which sodium chlorite (NaClO2) has been shown to be one of the best-performing additives [7]. Industrial demonstration of the technology in which NaClO2 is used as an oxidant has been completed in China’s industrial boilers and furnaces, and multipollutant removal efficiencies are satisfactory. However, there are still some deficiencies in the technology that need to be improved. One of the more prominent problems is the corrosion of equipment and piping caused by Cl accumulation. The concentration of Cl in the absorption solution is generally 1000–3000 mg/L. The maximum can be more than 10000 mg/L. Cl can promote corrosion through destroying the passive film of metal and accelerating the growth of pitting corrosion [9]. Furthermore, most of the corrosion and scale inhibitors cannot really inhibit the Cl corrosion [10]. Therefore, part of absorption solution must be discharged to regulate the concentration of Cl and other impurities in the solution and to form the wet flue gas DDW. Furthermore, the WFGD absorption solution, industrial cooling water, and other industrial wastewater also have the Cl accumulation problem, which leads to metal corrosion. However, the chemical precipitation method, which is usually used to treat desulfurization wastewater (DW), is difficult to remove Cl. As a result, the chlorine-containing wastewater cannot be directly discharged or reused [11]. Hence, in order to avoid Cl corrosion and promote DDW recycling, it is necessary to develop a cost-effective Cl removal technology.

Currently, various Cl removal technologies have been developed, mainly including evaporation crystallization [12], electrochemical method [13, 14], adsorption [15, 16], ion exchange [17, 18], and reverse osmosis [19]. However, these methods are complex and have high operating costs, and most of them are suitable for the treatment wastewater of a low Cl concentration. Chemical precipitation methods, such as silver salt precipitation [20], copper slag precipitation [21], and Friedel’s salt precipitation (ultra-high lime with aluminum process, UHLA) [22], are all very suitable for the treatment of wastewater with high Cl concentration. Among them, Friedel’s salt precipitation method is considered to be a cost-effective Cl removal technology. The fundamental of the UHLA method is through adding an excess of calcium salt and aluminum salt to the chlorine-containing solution, and the calcium and aluminum ions react with chloride ion to form a precipitate of Ca4Al2Cl2(OH)12 which is called Friedel’s salt at a certain reaction temperature and stirring speed, and finally the high efficient removal of chloride ion is achieved. Abdel-Wahab et al. [10, 22] evaluated Cl removal from recycled cooling water using the UHLA process and investigated the effect of aluminum dosage and lime dosage on Cl removal at room temperature. Experimental results showed that the UHLA process can effectively remove Cl by precipitation as calcium chloroaluminate [Ca4Al2Cl2(OH)12]. Cl removal was barely affected by the lime dosage, but significantly affected by the aluminum dosage. The optimal Ca/Al ratio to achieve maximum Cl removal was approximately 2.5.

However, these studies focused on the Cl removal from the circulating cooling water and did not consider the effect of coexistent anions, such as SO42−, NO3, and F, on the Cl removal. Meanwhile, there is little information about the effect of process parameters, such as the solution’s initial pH, reaction temperature, and reaction time on the Cl removal. The composition of the ions in the circulating cooling water is relatively simple, and the concentration of different kinds of ions is also lower compared to that of the DDW and the DW, but nowadays little information on the Cl removal from the DDW or the DW using Friedel’s salt precipitation method can be found in the literatures. Therefore, the research aims to evaluate the feasibility of the Cl removal from the wet flue gas DDW using Friedel’s salt precipitation method. A series of experiments to evaluate the influence of different factors on Cl removal were carried out, and the Cl removal mechanism by this process was hypothesized. In addition, removal of Cl and other ions in the actual DDW using Friedel’s salt precipitation method was also studied.

2. Experimental Setup

2.1. Materials

NaAlO2, Ca(OH)2, Na2SO4, NaOH, NaF, NaCl, KNO3, and HNO3 were analytical grade, and directly used without purification. The authors tested Cl concentration in the actual DDW and found that the Cl concentration in the DDW was about 1000–3000 mg/L. So chloride-rich simulated wastewater used in this study was prepared by dissolving anhydrous NaCl in deionized water to get initial Cl concentration of 2000 mg/L. The solution’s initial pH was adjusted using HNO3 (0.1 mol/L) and NaOH (0.1 mol/L). The actual DDW was obtained from a ceramic production enterprise located in Guangdong province, China.

2.2. Analytical Methods

The solution’s pH was measured with an MP511 pH detector (Shanghai Precision Instruments Co., Ltd.). Concentrations of NO3, F, SO42−, and Cl were measured with an ion chromatography system (Metrohm 883, Switzerland), and concentrations of heavy metal ions such as Ni2+, Pb2+, and Mn2+ were determined with an inductively coupled plasma emission spectrometer (ICP-AES 710, Agilent technologies). The precipitated solids were collected by filtering. The separated solids were then dried at room temperature. X-ray diffraction (XRD) was performed on the solids using an X-ray diffractometer (XRD-6000, Shimadzu, Japan).

2.3. Removal of Chloride Ions

Experiments were carried out on a six-league electric blender (ZR4-6, China). The experimental steps of Friedel’s salt precipitation method are as follows: the first step was conducted by adding a certain amount of Ca(OH)2 and NaAlO2 to the NaCl solution (2000 mg/L) with a volume of 1 L at the specified reaction temperature; then stirring for a certain time, at last samples were taken and filtered under vacuum through a 0.45 μm microporous membrane filter. The filtrate was analyzed for Cl and other ions using related equipments, and finally the removal efficiencies of Cl and other ions were calculated by the following equation. The solid phases formed in precipitation experiments were identified by XRD spectroscopy.where is the Cl or other ions removal efficiencies; and and are the initial and final Cl or other ions concentrations of solutions (mg/L), respectively.

According to the characteristics of ion composition of actual DDW, the literatures [10, 20, 22, 23] and an analysis of main factors influencing Cl removal, a series of experiments were conducted to evaluate Cl removal from DDW using Friedel’s salt precipitation method, and the optimal experimental conditions for Cl removal were determined by using single factor test. In addition, the removal experiments of chloride ions from a ceramic enterprise wastewater were carried out under the best experimental conditions. The experimental conditions of the individual experiments are shown in Table 1.

3. Results and Discussion

3.1. Effect of NaAlO2 Dosage and Ca(OH)2 Dosage

It was reported that Cl removal was primarily controlled by the formation of Ca4Al2Cl2(OH)12 [22]. So NaAlO2 dosage and Ca(OH)2 dosage have a significant effect on Cl removal. As shown in Figure 1, good Cl removal (>85%) was observed at reasonable ranges of NaAlO2 dosage and Ca(OH)2 dosage. It was found that the Cl removal increased upon increasing the molar ratios of NaAlO2 to Cl (Al/Cl) at first, then decreased with the Al/Cl increase when the molar ratio of Ca(OH)2 to Cl (Ca/Cl) was constant. For example, when the Ca/Cl was constant at 6 : 1, the Cl removal sharply increased from 56.3% to 91.6% when the Al/Cl varied from 1 : 1 to 3 : 1, then Cl removal decreased from 91.6% to 59.6% with an increase of Al/Cl between 3 : 1 and 6 : 1. Higher NaAlO2 dosage is not conducive to the Cl removal. Addition of excess NaAlO2 results in increasing Al(OH)4 and OH ions ((2) and (3)) in the solution, and the increases of OH and Al(OH)4 ions result in substitution of Cl with OH and Al(OH)4 ((6) and (7)) in the solid solution formation, thus increasing the fraction of Ca3Al2(OH)12 and decreasing the fractions of Ca4Al2Cl2(OH)12 and Ca4Al2(OH)14 in the solid solution. So, the results show that there is an optimum range of Al/Cl of 2–4 : 1.

Figure 2 shows the effect of Ca(OH)2 dosage on Cl removal. When the Al/Cl was 1 : 1, the Ca(OH)2 dosage had little effect on Cl removal. However, the Cl removal was greatly affected by the Ca(OH)2 dosage when the Al/Cl was more than 1 : 1. As depicted in Figure 2, when the Al/Cl was constant, Cl removal increased rapidly as the Ca/Cl increased at first, then decreased with the increase of Ca/Cl. This is because the Ca(OH)2 solubility is low, Ca2+ concentration in the solution increases with the increasing of Ca(OH)2 dosage, meanwhile OH concentration also increases in the solution. The increasing of Ca2+ concentration leads to increased Cl removal; however, the increase of OH concentration is not conducive to the Cl removal because the Cl in the Ca4Al2Cl2(OH)12 can be replaced by OH to form the Ca4Al2(OH)14 (6) under the higher OH concentration condition. So, the results show that there is an optimum range of Ca/Cl of 6–8 : 1.

In order to further determine the effect of the dosage of chemical reagents on Cl removal and to determine the reaction product type, XRD was used to examine the crystalline phases of the precipitated solids produced under different conditions, and the results are shown in Figure 3.

Examination of the samples indicates the presence of mixed phases, the major crystalline phases are Ca4Al2Cl2(OH)12 (ICDD PDF card # 35-0105, 2θ = 11.4°, 22.8°, 23.6°, 31.1°, 35.6°, and 42.7°), Ca4Al2(OH)14 (ICDD PDF card # 33-0255, 2θ = 11.4°, 31.1°, 38.9°, and 64.5°), Ca3Al2(OH)12 (ICDD PDF card # 24-0217, 2θ = 17.4°, 20.0°, 26.7°, 28.5°, 31.9°, 36.5°, 39.3°, 44.5°, 52.6°, 54.6°, and 66.4°), and Ca(OH)2 (ICDD PDF card # 04-0733, 2θ = 18.3°, 34.3°, 47.4°, and 51.0°). As shown in Figure 3(a), the intensities of characteristic diffraction peaks of Ca4Al2Cl2(OH)12 and Ca4Al2(OH)14 all increased with the increasing Ca(OH)2 dosage at first, then decreased slowly with the increase of Ca(OH)2 dosage. On the contrary, the intensities of characteristic diffraction peaks of Ca3Al2(OH)12 decreased as the Ca(OH)2 dosage increased at first, then increased with the increase of Ca(OH)2 dosage. This may be attributed to the increase in concentration of Ca2+ in solution with Ca(OH)2 dosage increase, thus promoting the Ca4Al2Cl2(OH)12 and Ca4Al2(OH)14 generation ((4), (5) and (6)). However, higher Ca(OH)2 dosage contributes to the OH concentration increase in solution and promote the progress of the reactions ((7) and (8)), resulting in an increase of Ca3Al2(OH)12 and decrease of Ca4Al2Cl2(OH)12 and Ca4Al2(OH)14 in the solids. In addition, the intensities of characteristic diffraction peaks of Ca(OH)2 increased with the increasing Ca(OH)2 dosage. The results of XRD test are in good agreement with the results of Cl removal (Figure 1).

Figure 3(b) shows that additions of NaAlO2 had significant influences on the distribution of solids in the solid solution. When the Ca/Cl was constant at 6 : 1 and the Al/Cl was more than 3 : 1, the intensities of characteristic diffraction peaks of Ca4Al2Cl2(OH)12, Ca4Al2(OH)14, and Ca(OH)2 all decreased rapidly with the increasing NaAlO2 dosage; however, the intensities of characteristic diffraction peaks of Ca3Al2(OH)12 increased rapidly as the NaAlO2 dosage increased. Especially, examination of the sample (n(Ca) : n(Al) : n(Cl) = 6 : 6 : 1) indicated that phases related to crystalline Ca(OH)2 were not observed, suggesting that almost no Ca(OH)2 was contained in the solids. The results of XRD test are in good agreement with the results of Cl removal (Figure 2).

Based on the experimental results, composition of the solids, and the literatures [10, 20, 22, 23], Cl removal reaction equations and the interactions among the solids during formation of the solid solution can be described by using the following chemical equilibrium reactions:

Considering the Cl removal and economic costs, in the next series of experiments, the molar ratio of Ca(OH)2 to NaAlO2 to Cl were constant at 6 : 3 : 1.

3.2. Effect of the Initial pH

The effect of the solution’s initial pH ranging from 3.0 to 11.0 on Cl removal has been studied. Figure 4 shows that the initial pH of solution had negligible effects on the Cl removal, and the average removal efficiencies of Cl remained at around 87% when the solution’s initial pH changed from 3.0 to 11.0. The reason is that the addition of Ca(OH)2 was excessive in this series of experiments, and regardless of whether the solution was acidic or alkaline, the solution’s pH all increased to about 13.0 after adding excessive Ca(OH)2. The initial pH of solution has little effect on Cl removal, so the effect of wastewater pH need not be considered when using the method to control the Cl in practical engineering applications.

3.3. Effect of Solution’s Temperature

Figure 5 presents the effect of the solution’s temperature on Cl removal. The Cl removal decreased with the increasing temperature of the solution. Cl removal efficiencies were 88.8%, 88.9%, 86.0%, 78.7%, and 68.5% when the solution’s temperatures were 25, 30, 40, 50, and 60°C, respectively. As Figure 5 illustrates, Cl removal decreased slowly with the solution’s increasing temperature when the solution’s temperature was less than 40°C, but when the solution’s temperature was more than 40°C, the Cl removal decreased rapidly with the increase of the solution’s temperature. Because the stable existence temperature of Ca4Al2Cl2(OH)12 is 40°C [23], a partial Ca4Al2Cl2(OH)12 will breakdown to form more stable solids such as Ca3Al2(OH)12 when the solution’s temperature is more than 40°C. So, it is necessary to reduce the wastewater temperature in practical engineering applications to achieve a higher Cl removal.

3.4. Effect of Reaction Time

The effect of reaction time on Cl removal is shown in Figure 6. Results show that the reaction time has a certain effect on Cl removal. The NOx removal sharply increased from 75.1% to 87.9% with the increase of reaction time from 10 min to 30 min and thereafter remained almost constant at about 88%–89%. The contact time of ions in the solution increased, resulting in a more complete reaction and an increase of Cl removal; however, limited by the low solubility of Ca(OH)2, the increase of contact time had a little effect on Cl removal. Taking into account the economic factor and Cl removal, the optimum reaction time is selected as 30 min.

3.5. Effect of Stirring Speed

Stirring speed has a significant effect on Cl removal. As shown in Figure 7, when stirring speed increased from 100 r/min to 200 r/min, Cl removal sharply increased from 62.7% to 82.7% and then gradually increased. When the stirring speed was more than 400 r/min, the Cl removal was little affected by the stirring speed and maintained between 89% and 91%. Increasing the stirring speed contributes to the dispersion and dissolution of the reagents and increases the probability of collision of various ions in the solution, resulting in higher Cl removal. However, excessive stirring speed not only cannot significantly improve the Cl removal, but also leads to increased operating costs, so the optimum stirring speed is selected as 400 r/min.

3.6. Effect of Anions

Various types of anions such as SO42−, NO3, and F exist in the DDW and DW, and the concentrations of these anions are often high. So, coexistent anions in the solution have a certain effect on Cl removal. In this paper, the effect of anions on Cl removal has been studied, and the results are shown in Figures 810.

Figure 8 displays the effect of SO42− concentration on Cl removal. As Figure 8 illustrates, SO42− concentration has a significant effect on Cl removal. Cl removal sharply decreased from 77.5% to 8.3% when SO42− concentration increased from 1000 mg/L to 10000 mg/L. Compared with the low Cl removal, SO42− removal almost remained stable at more than 97% when SO42− concentration varied from 1000 mg/L to 4000 mg/L, then slowly decreased with the increase of SO42− concentration. It has been reported that SO42− can react with Ca2+ and Al3+ to form insoluble ettringite (Ca6Al2(SO4)3(OH)12). The solubility products of Ca6Al2(SO4)3(OH)12 and Ca4Al2Cl2(OH)12 are about 10−109.9 and 10−27.10, respectively [10, 22]. So, Ca2+ and Al3+ in the solution are easier to react with SO42− rather than Cl, leading to higher SO42− removal and lower Cl removal.

Results show that the presence of SO42− in the solution has a significant inhibitory effect on Cl removal. In order to achieve high Cl removal, it is necessary to remove the SO42− from the solution first. Table 2 shows the results of SO42− and Cl removal using two-stage Friedel’s salt precipitation method, the average removal efficiencies of SO42− and Cl can reach 98.9% and 86.2%, respectively.

Figure 9 shows that Cl removal almost remained stable at about 88% when F concentration increased from 100 mg/L to 600 mg/L, then decreased slowly from 88.5% to 83.8% when F concentration increased from 600 mg/L to 1000 mg/L, meanwhile F removal almost remained stable at the range of 94% to 98%. Due to the large amount of Ca(OH)2 dosage compared with the stoichiometric value, it is estimated that Ca2+ in the solution is excessive, so F can react with Ca2+ to form insoluble CaF2 and not affect Cl removal when the F concentration is low. However, the further increase of F concentration causes competitive reactions of F and Cl for the Ca2+ and results in a decrease of Cl removal.

The effect of NO3 concentration on Cl removal is shown in Figure 10. The results indicate that the Cl removal was little affected when the concentration of NO3 in the solution was less than 2000 mg/L, and remained stable at about 88%; meanwhile, about 15% of NO3 removal was achieved. When the concentration of NO3 in the solution increased from 2000 mg/L to 3000 mg/L, the Cl removal slowly decreased from 87.9% to 83.3%, and the NO3 removal slowly increased from 15.4% to 23.3%. NO3 can react with Ca2+ and Al3+ to form the Ca4Al2(NO3)2(OH)12 that belong to AFm family of solids [24]; therefore, there is a certain negative impact on the Cl removal. Overall, NO3 has a certain inhibitory effect on Cl removal only under high NO3 concentration.

3.7. Determination of the Optimal Experimental Conditions

The results indicate that using Friedel’s salt precipitation method can effectively remove Cl in the solution. Cl removal depends primarily on the Ca(OH)2 dosage, NaAlO2 dosage, the solution’s temperature, and SO42− concentration, and the solution’s initial pH, reaction time, stirring speed, NO3, and F concentrations all have a certain influence on NOx removal, but these factors have a relatively little influence on the Cl removal. Finally, considering the application to the practical engineering, the optimal conditions for Cl removal using Friedel’s salt precipitation method were identified: (1) For sulfate-free wastewater, use one-stage Freund’s salt precipitation method to remove Cl. The optimal conditions were the molar ratio of Ca(OH)2 to NaAlO2 to Cl 6 : 3 : 1, solution’s temperature of 25°C, reaction time of 30 min, and stirring speed of 400 r/min. (2) For sulfate-containing wastewater, use two-stage Freund’s salt precipitation method to remove Cl. First stage mainly removed SO42−, the optimal conditions were the molar ratio of Ca(OH)2 to NaAlO2 to SO42− 4 : 1 : 1, solution’s temperature of 25°C, reaction time of 30 min and stirring speed of 400 r/min. Second stage mainly removed Cl, and the optimal conditions were the same as those used for sulfate-free wastewater.

3.8. Effect of Precipitated Solid Reuse

The XRD test (Figure 3) of the precipitated solids indicated that there existed a certain amount of Ca(OH)2 in the precipitated solids, so it is possible to replace part of Ca(OH)2 with the precipitated solids. As shown in Figure 11, Cl removal rapidly decreased with the increase of replacement ratio of Ca(OH)2, the main reason is that the Ca(OH)2 content of the precipitated solids was low, so it can’t be achieved to use precipitated solids to replace an equivalent number of Ca(OH)2. However, Cl removal can reach more than 80% when the replacement ratio of Ca(OH)2 is controlled at less than 20%.

3.9. Removal of Chloride Ion and Other Ions in Actual DDW

Removal of Cl and other ions in actual wastewater by using Friedel’s salt precipitation method was studied. The wastewater was the actual DDW from a ceramic plant. The NaClO2/NaOH solution was used to remove the NOx and SO2 in the flue gas, and the wet flue gas desulfurization and denitrification system was operated under weak acid condition. So, the effluent from the system contained large amounts of Cl and other ions (Tables 2 and 3). Two-stage Friedel’s salt precipitation method was used to purify the anion ions and other ions, and the results are shown in Tables 3 and 4. The results indicate that Friedel’s salt precipitation method had high synergistic removal efficiencies for Cl, SO42−, F, and heavy metal ions, with average removal efficiencies of 85.43%, 98.47%, 96.39%, and more than 99%, respectively. The Cl concentration in the purified wastewater met the requirements for reuse of water which is 250 mg/L in China; meanwhile, SO42−, F, and heavy metal ions were effectively removed. So the purified wastewater could be reused in the wet flue gas desulfurization and denitrification system. In addition, the pH of the purified water was about 13, so purified wastewater reuse could reduce the consumption of alkali in the flue gas treatment system.

4. Conclusions

In this study, Friedel’s salt precipitation method was used to remove the Cl, and the effects of different experimental conditions on Cl removal were mainly studied. Based on the results of the experiments, the following conclusions can be made:(1)Friedel’s salt precipitation method is a very effective Cl removal technology, and Cl removal can reach more than 85%. Meanwhile, the method can effectively synergistically remove SO42−, F, and heavy metal ions. The purified wastewater can be reused to reduce the consumption of water and alkali, and the precipitated solids can be used to replace part of Ca(OH)2. Thus, it has a great potential to be applied in the industrial wastewater treatment field.(2)Ca(OH)2 dosage, NaAlO2 dosage, the solution’s initial pH, the solution’s temperature, reaction time, stirring speed, and anions (SO42−, NO3 and F) have all effects on the Cl removal. Finally, considering the application to the practical engineering, the optimal conditions for Cl removal using Friedel’s salt precipitation method were determined.(3)The removal mechanism of Cl was deduced based on the experimental results, composition of the precipitated solids, and the literatures. The results showed that Cl can be removed by precipitation as Ca4Al2Cl2(OH)12.

Data Availability

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

Conflicts of Interest

The authors declare that they have no competing interests.

Acknowledgments

This work was supported by the National Key R&D Program of China (2017YFC0210704, 2017YFC0210803), the National Natural Science Foundation of China (NSFC-51778264), the Natural Science Foundation of Guangdong Province (2015A030310344), the Project of Science and Technology Program of Guangdong Province (2015A020220008, 2015B020215008, 2016B020241002, and 2017B020237002), the Youth Top-notch Talent Special Support Program of Guangdong Province (2016TQ03Z576), and the Pearl River S&T Nova Program of Guangzhou (201610010150).