Introduction

Industrial wastewater treatments vary according to the characteristics of the wastewater. Some industries’ wastewater can be decomposed biologically, while others might contain nonbiodegradable constituents. Industrial wastewater treatment plants generally use chemical treatment technologies. These technologies might be a stand-alone or pretreatment process before the consecutive biological treatment phases.

Coagulation–flocculation processes are the most commonly used chemical treatments for removing pollutants, such as biochemical oxygen demand (BOD), chemical oxygen demand (COD), total suspended solids (TSS), heavy metals, and color in industrial wastewater before other treatment methods are used (Jarvis et al. 2005; Syafalni et al. 2012; Galloux et al. 2015). Aluminum sulfate (Al2(SO4)3), ferric chloride (FeCl3), and polyaluminum chloride are widely used as coagulants because they have demonstrated a high affinity for removing a wide range of pollutants found in wastewater (Zhao et al. 2011a; Galloux et al. 2015). However, the coagulation–flocculation treatment methods involve these chemicals as the treating agents, which could constitute a potential risk to the quality of the environment itself and cause the generation of excess sludge during the coagulation–flocculation treatment process (Tatsi et al. 2003; Syafalni et al. 2012). Most of this sludge is solid waste from which nothing can be recovered or reused, and that then requires further treatment, such as incineration and disposal into a landfill (Shon et al. 2007). Disposal of chemical sludge into the landfill is not an acceptable method because it can cause secondary pollution, such as landfill leachate and soil contamination (Zhao et al. 2011a). Thus, it is important to apply the appropriate coagulant in the coagulation–flocculation process to overcome these potential disadvantages and increase the efficient application of an alternative treatment. A coagulant that produces less sludge or more reusable sludge offers a better solution to many environmental and economic problems associated with sludge handling (Okour et al. 2009).

In recent years, various new coagulants have been studied and developed, such as organic, inorganic, and composite coagulants. Titanium (Ti) salt, as an inorganic coagulant, is an attractive alternative to inorganic metal coagulants. Ti salt used in the coagulation of wastewater shows a high flocculation performance of turbidity and organic removal (Okour and Ahmed 2019). Recent investigations have demonstrated the strong flocs-forming properties of zirconium oxychloride (ZrOCl2·8H2O). This new coagulant has shown pronounced effects on water clarification (Priya et al. 2017). Ti and its compounds have been reported to be minimally toxic and are rarely included in any water quality guidelines (Wu et al. 2011). Similarly, it has been reported that zirconium (Zr) is generally believed to be nontoxic as an element or in compounds (Jarvis et al. 2012; Hussain et al. 2014). However, research on the use of Ti and/or Zr salts as coagulants to treat pollutants was conducted mainly for surface water treatment. A few other studies examined these metals salts for treatment of synthetic wastewater (Shon et al. 2007; Okour et al. 2009; Okour and Ahmed 2019). To the best of our knowledge, however, few studies on treatment of real wastewater by Ti and/or Zr salts have been reported (Galloux et al. 2015; Pushpalatha and Lokeshappa 2015; Aziz et al. 2018).

In the present study, the performances of Ti- and Zr-based coagulants for the treatment of real industrial wastewater were investigated and compared with traditional coagulants. The present study was conducted to achieve following five goals: (1) investigate and compare the coagulation performance of TiCl4, ZrCl4, ZrOCl2·8H2O, Al2(SO4)3·18H2O, and FeCl3 for their COD and TSS removal efficiency from industrial wastewater obtained from an organized industrial-zone wastewater treatment plant; (2) determine the experimental conditions that deliver the optimum removal efficiency; (3) determine the sludge volume index (SVI) and the volume of settled sludge for each coagulant under optimum conditions; (4) determine the total phosphorus (TP), color, and metal removal efficiencies from the wastewater under the same optimum conditions; and (5) analyze the characteristics of the residual sludge obtained under optimum conditions.

Materials and methods

Industrial wastewater

Industrial wastewater was collected from an organized industrial-zone wastewater treatment plant located in Antalya, Turkey, that uses physical, chemical, and biological treatment processes. This plant collects wastewater from food, machinery, plastics, construction, wood, chemicals, textile, fertilizers, electrical, and electronics processes. The wastewater treatment plant has the capacity of 20,000 m3/day and FeCl3 is the coagulant used in the chemical treatment phase. The wastewater was sampled from the equalization tank’s effluent and was initiated just before the chemical treatment process began.

The industrial wastewater was characterized for content immediately after the sample arrived at the laboratory and the sample was refrigerated at 4 °C.

The characteristics of the industrial wastewater are shown in Table 1. The COD, TSS, TP, and color content of this wastewater were high and contained Fe, Al, Cu, and Zn.

Table 1 Physical and chemical characteristics of the industrial wastewater used in this study

Chemicals and coagulants

The coagulants used in the jar test experiments were Al2(SO4)3·18H2O, FeCl3, zirconium tetrachloride (ZrCl4), titanium tetrachloride (TiCl4) and ZrOCl2·8H2O. For flocculation, an anionic polyelectrolyte solution was used as the flocculant. The stock solutions of Al2(SO4)3·18H2O (98%, Acros Organics, Belgium), FeCl3 (> 98% Tekkim Chemicals, Turkey), ZrCl4 (99.99%, Merck, France), ZrOCl2·8H2O (98%, Acros Organics, Belgium), and anionic polyelectrolyte (1858 U, SNF Floerger, France) were prepared separately by adding 1 g chemicals to 1 L distilled water. Stock solution of TiCl4 (> 99.9%, density 1.72 g/mL, Acros Organics, Belgium) was prepared as previously detailed (Hussain et al. 2014; Pushpalatha and Lokeshappa 2015; Aziz et al. 2018). Hydrochloric acid (HCl) and sodium hydroxide (NaOH) were used to adjust the pH of the solutions before the jar test to the predetermined levels and keep the pH constant during the coagulation process. A solution of 0.1 N HCl was prepared by adding 4.15 mL HCl (37%, Merck, Germany) to 500 mL distilled water. For 0.1 N NaOH solution, 2 g NaOH (99%, Merck, Germany) solid were weighed and later dissolved in 500 mL distilled water. Each solution was mixed thoroughly to obtain the homogenized solution.

Coagulation–flocculation experiment

Coagulation experiments were conducted in a 1000-mL beaker using a jar testing device (Velp Scientifica, JLT6, Italy) at different coagulant dosages and different initial pHs. First, the industrial wastewater samples were removed from the refrigerator and allowed to reach ambient temperature. Second, the sample bottle was thoroughly agitated for resuspension of any possibly settled solids. Finally, 300 mL industrial wastewater was poured into a beaker. The coagulant was added to within the range of 10–100 mg/L to the sample, and the pH of the sample solution was adjusted to within the range of 4–10 by adding 0.1 N HCl or 0.1 N NaOH. The operating parameters used were based on the literature reviewed. The solution was rapidly mixed at 200 rpm for 5 min, after which 5 mg/L flocculant was added followed by slow mixing at 20 rpm for 30 min. The flocs were allowed to settle for 1 h. The treated wastewater samples were collected from 3 cm below the water surface for subsequent measurements. COD and TSS were measured in these collected treated samples. The removal efficiency of these parameters has been determined by calculating the percentage removal. The experimental conditions under which optimum removal efficiency was observed were determined.

Sludge volume index

Sludge volume index (SVI) was measured after determining the optimum pH and coagulant dose for the jar test using the sludge produced under optimum conditions. SVI is a measure of sludge settleability, which is often used in the biological processes with activated sludge; however, it is applicable for chemical sludge and considered to be an index by which to assess the ability to dewater the sludge and ease of handling (Taheriyoun et al. 2020). This test was conducted according to the standard methods (APHA 2005). The standard SVI test requires a 1-L graduated cylinder for the sludge settling test. SVI tests were conducted under conditions that produced the best treatment efficiencies for each coagulant in a 1000-mL sample volume. After adding the coagulant, both rapid and slow mixing were conducted in a jar test setup and the contents were transferred to a 1-L Imhoff cones and allowed to settle for 30 min, after which the settled sludge volume was read. The settled sludge volume at the end of 60 min was also read.

Analytical procedure

The pH, total solids (TS), total suspended solids (TSS), color, and sulfate ion (SO42−) were analyzed according to the procedure described in the Standard Methods (APHA 2005). Chemical oxygen demand (COD) was determined using the Hach reactor digestion method. The metals and total phosphorus (TP) contents were determined using inductively coupled plasma optical emission spectrometry (ICP-OES) (Perkin Elmer, DV2100) by filtering the wastewater sample through 0.45-μm membrane filters.

Residual sludge produced from coagulation–flocculation under optimum test conditions was dewatered and dried at 103 °C for 12 h, and the dried residual sludge samples were ground. The surface morphology and the chemical composition of the residual sludge were analyzed using a scanning electron microscope (SEM, FEI, Quanta FEG 250) equipped with an energy-dispersive spectroscopy (EDS). To analyze the metal and TP contents, 0.1 g sludge samples were weighed and digested in a microwave containing nitric acid (HNO3) and HCl. The metal and TP contents were measured using ICP-OES (Perkin Elmer, DV2100) after the acidic microwave digestion.

All experiments were replicated to assess the reproducibility of the results; the mean values are presented.

Results and discussion

Coagulation performance of Al2(SO4)3·18H2O, FeCl3, ZrCl4, TiCl4, and ZrOCl2·8H2O for the treatment of industrial wastewater

Removal efficiencies for COD and TSS

The treatment efficiencies obtained from five different coagulant doses and five different pH values for COD removal are illustrated in Fig. 1a–d. As seen from Fig. 1a, at pH 4, 100 mg/L dose for all coagulants was the most efficient at COD removal. Under these conditions, the removal efficiencies from the highest to the lowest were ZrCl4 (67.20%) > FeCl3 (66.66%) > ZrOCl2 (66.54%) > TiCl4 (65.71%) > Al2(SO4)3 (64.30%) (Fig. 1a). At pH 6, the highest COD removal efficiency was 67.93% at 100 mg/L of TiCl4 dose, and the lowest removal efficiency was 42.84% at 10 mg/L of ZrOCl2 dose (Fig. 1b). At pH 8, the highest COD removal efficiency was 69.33% at 100 mg/L of TiCl4 dose, and the lowest removal efficiency was 44.96% at 10 mg/L of Al2(SO4)3 dose (Fig. 1c). At pH 10, the highest COD removal efficiency was 65.25% at 100 mg/L of TiCl4 dose, and the lowest removal efficiency was 54.43% at 10 mg/L of ZrCl4 dose (Fig. 1d).

Fig. 1
figure 1

Performance comparison of Al, Fe, Zr, Ti, and ZrO coagulants in terms of COD removal efficiency at various doses at pH 4 (a), 6 (b), 8 (c), and 10 (d)

The lowest dose examined in the study was 10 mg/L. At both pH 6 and 8, the COD removal efficiencies with this dose were below 55% for all coagulants. For all of the coagulants tested, the best COD removal efficiencies were achieved at 100 mg/L of coagulant dose. The highest COD removal efficiencies for ZrCl4, FeCl3, and ZrOCl2 were 67.20%, 66.66%, and 66.54% at a dose of 100 mg/L and at pH 4, respectively. However, for TiCl4, the highest removal efficiency was 69.33% at a dose of 100 mg/L and at pH 8. At a dose of 100 mg/L, the highest COD removal efficiency for AlSO4 was 64.30% at pH 6 and 64.66% at pH 8 (Fig. 1a–d).

The pH of the coagulation depends on the coagulant type and the wastewater to be treated. Except for TiCl4, the highest COD removal efficiencies were observed at pH 4. However, for TiCl4, the highest removal efficiency was at pH 8. Similarly, Zhao et al. (2011b) have reported that the highest COD and dissolved organic carbon (DOC) removal efficiencies in surface water treatment were observed with TiCl4 at pH 8. In acidic conditions, hydrolysis of TiCl4 may be restrained, while Al- and Fe-salt coagulants are seldom affected (Zhao et al. 2011a). However, at a higher pH, TiCl4 coagulant is gradually hydrolyzed, resulting in better COD removal. ZrCl4 and ZrOCl2 performed best at a low pH, which indicated that Zr polymeric cationic species are most prominent at this pH (Hussain et al. 2014). Similarly, Jarvis et al. (2012) have suggested a significant role of highly charged cationic hydrolysis species produced when ZrOCl2·8H2O is dissolved in water.

The TSS removal efficiencies from industrial wastewater using five different coagulant doses and five different pH values are shown in Fig. 2a–d. At pH 4, the highest TSS removal efficiencies were 92.46% at 30 mg/L of Al2(SO4)3 dose and 92.21% at 100 mg/L of Al2(SO4)3 dose. The lowest TSS removal efficiency was 61.04% at 10 mg/L of Al2(SO4)3 dose and at pH 4 (Fig. 2a). At pH 6, the highest TSS removal efficiency observed was 94.13% at 30 mg/L of Al2(SO4)3 dose, whereas the lowest was 49.17% at 10 mg/L of ZrOCl2 dose (Fig. 2b). At pH 8, 50 mg/L Al2(SO4)3 dose produced the highest TSS removal efficiency of 98.32%, and 10 mg/L Al2(SO4)3 dose produced the lowest TSS removal efficiency of 57.14% (Fig. 2c). At pH 10, except for TiCl4, the highest removal efficiencies were achieved at 50 mg/L of each coagulant dose with Al2(SO4)3 (98.32%) > ZrCl4 (92.46%) > ZrOCl2 (90.00%) > FeCl3 (89.94%) (Fig. 2d).

Fig. 2
figure 2

Performance comparison of Al, Fe, Zr, Ti, and ZrO coagulants in terms of TSS removal efficiency at various doses at pH 4 (a), 6 (b), 8 (c), and 10 (d)

Determination of settled sludge volume, SVI, and removal efficiency rates of metals, color, and TP under the optimum conditions

To reduce the load on biological treatment processes, it was very common to use coagulation–flocculation processes as a pretreatment method in wastewater treatment plants within organized industrial zones. The present study’s wastewater treatment plant in the organized industrial zone also contains a coagulation–flocculation pretreatment process initiated just before biological treatment.

To be able to reduce the load on biological treatment, decreasing the COD concentration of wastewater with a chemical treatment step is critical, which is why this study considered COD instead of TSS removal efficiencies while determining the optimum conditions.

The best COD removal efficiencies for FeCl3, ZrCl4, and ZrOCl2 were obtained at pH 4 and at a dose of 100 mg/L, whereas for TiCl4, this occurred at pH 8 and a dose of 100 mg/L. For Al2(SO4)3, the best COD removal efficiencies were very similar at pH 4 and 6, with 64.30% and 64.66%, respectively. Then, because TSS removal with the same coagulant was most efficient at 92.21% at pH 4, that pH was recorded as the optimum condition for Al2(SO4)3.

The five different coagulants had similar COD removal efficiencies. The best efficiency ranges obtained from these coagulants under their respective optimum conditions were between 64.30 and 69.33%. Similarly, Shon et al. (2007) have reported that Al2(SO4)3, FeCl3, and TiCl4 used to remove organic matter from synthetic wastewater resulted in similar removal efficiencies among all of them.

SVI was identified in this study for Al2(SO4)3, FeCl3, ZrCl4, TiCl4, and ZrOCl2 under optimum conditions and 30 min of settling time (i.e., SVI30). Figure 3 shows the obtained SVI30 values and settled sludge volumes 60 min after the coagulation processes were measured under optimum conditions. A lower value of SVI indicates a good settling sludge, which has a bigger floc size and requires a shorter time for the sedimentation process (Bhatia et al. 2007; Zainol et al. 2019). TiCl4 produced a lower SVI compared to the other coagulants used (Fig. 3) and is more capable of producing compact sludge at a lower settling time than the other coagulants. Settled sludge volume after 60 min was also lowest in TiCl4 (Fig. 3). Based on these results, using TiCl4 will have more of an advantage in sludge operations at the treatment plant and will produce less sludge at the final discharge point. This will make is easier for the sludge conductor to dispose of the sludge.

Fig. 3
figure 3

Sludge volume index (SVI30 = 30 min of settling time) and settled sludge volume at 60 min against each coagulant used

Figure 4 illustrates the removal efficiencies of TP, Cu, Zn, and color using five different coagulants applied under optimum conditions. In addition to COD and TSS, industrial wastewater has high TP and color strength (Table 1). With TiCl4 and ZrOCl2, TP removal efficiencies were > 93.7% (Fig. 4). With ZrCl4, TiCl4, and ZrOCl2, it was observed that the effluent standard in the regulation was met with regard to TP content (Table 1). Thus, with ZrCl4, TiCl4, and ZrOCl2 were sufficient for removing TP without needing further treatment. The removal efficiencies for Cu and Zn removal were better in Ti and Zr salt applications than the traditional coagulants performance (Fig. 4). Similarly, Galloux et al. (2015) have reported that the Ti-based coagulants had higher removal efficiency for multivalent metal than FeCl3. Color removal efficiency rates > 82.5% were obtained with Al2(SO4)3, ZrCl4, and ZrOCl2 (Fig. 4).

Fig. 4
figure 4

Removal efficiencies for TP, Cu, Zn, and color in wastewater for all five tested coagulants under optimum conditions

Characterization of residual sludge produced from coagulation–flocculation under optimum conditions

The morphology and the chemical composition of the residual sludge were analyzed using SEM–EDS analysis of the sludge after coagulation–flocculation process using all coagulants at the optimum test conditions. The sludge surface morphology was analyzed by SEM, while the containing ions were analyzed by EDX.

Figure 5a–e presents the SEM images of the residual sludge produced for all five tested coagulants under optimum conditions. SEM images generally represent the physical morphology of the particles. From these figures, it is clear that the flocs produced after the coagulation–flocculation process are hard and compact because colloidal particles entrapped in these flocs. SEM images showed that residual sludges were heterogeneous mixtures of particles with irregular shape and variable sizes with concentration of particle size at around 30 μm (Fig. 5a–e).

Fig. 5
figure 5

SEM images of TiCl4 sludge (a), ZrCl4 sludge (b), ZrOCl2 sludge (c), Al2(SO4)3 sludge (d), and FeCl3 sludge (e) at magnification 3000x

The EDS spectra of the residual sludges are shown in Fig. 6a–e. EDS analysis shows that C, P, Al, and Ca are the most abundant elements, whereas Si and S are detected at relatively low concentrations (Fig. 6a–e). The percentage of C on the floc surfaces is high which indicates that organic compounds are removed during the coagulation–flocculation process. The EDS results evidence that the coagulation–flocculation process using all five tested coagulants does not only remove dissolved organic matter, but also traps other pollutants from the industrial wastewater inside the flocs, due to the adsorption or through complexation process.

Fig. 6
figure 6

Energy-dispersive spectra of TiCl4 sludge (a), ZrCl4 sludge (b), ZrOCl2 sludge (c), Al2(SO4)3 sludge (d), and FeCl3 sludge (e)

The TP and metal contents in the residual sludge produced for all five tested coagulants under optimum conditions are provided in Table 2. A very high concentration of TP was observed in the residual sludge when Ti and Zr salt-based coagulants were used in the process.

Table 2 Characterization of residual sludge produced for all five tested coagulants under optimum conditions

Recovery processes can be applied to recycle TP from the residual sludge obtained after the coagulation–flocculation procedure. Using the chemical extraction method, the P content of the residual sludge can be transformed into the liquid phase, and an ion-exchange membrane can recover the liquid-phase P (Uysal et al. 2017).

Conclusion

The performances of Ti- and Zr-based coagulants were assessed and compared with that of traditional FeCl3 and Al2(SO4)3 for the treatment of real industrial wastewater. Coagulation performances were evaluated in terms of pollutant removal (COD, TSS, TP, metals, and color) and sludge settleability. The results showed that Ti- and Zr-based coagulants produced COD removal efficiencies nearly similar to that of FeCl3 and Al2(SO4)3. The maximum removal efficiency of COD (69.33%) was observed using 100 mg/L TiCl4, at pH 8. For the other coagulants, the best removal efficiency of COD was observed at pH 4. The pH 8 optimum value for TiCl4 is very advantageous because immediately after the chemical treatment, there is a biological treatment phase, which, in this case, the pH if would not need to be adjusted. TiCl4, ZrCl4, and ZrOCl2 performed better than FeCl3 and Al2(SO4)3 in terms of TP, Cu, and Zn removal. With TiCl4 and ZrOCl2, TP removal efficiencies over 93.7% were obtained. ZrCl4 and ZrOCl2 had higher efficient rates for color removal than TiCl4, FeCl3, and Al2(SO4)3. In addition, the SVI test showed that TiCl4 generated less sludge compared to other coagulants used. Where the SVI of TiCl4 was 48.84 mL/g, while it was 72.26 and 69.66 mL/g for the FeCl3 and Al2(SO4) under optimum conditions. The EDS analysis of the residual sludges exhibits that the high content of C was obtained with the use of all tested coagulants. The other principal chemical components were Al and P. The residual sludge obtained when Ti and Zr salt-based coagulants were used had elevated TP. Because natural P resources throughout the world are severely limited, sewage sludge is an important resource for P recovery, and when using various extraction techniques, P recovery from this residual sludge might be realized. Ti- and Zi-based coagulants can be used in further practices, such as landfill leachate, tannery wastewater, textile wastewater, that contain high levels of organic compounds, suspended solids, and heavy metals.