There have been few reports publish

There have been few reports published on the treatment of real textile wastewater. Additionally the main deficiency of EC is the lack of dominant reactor design, although reactor design affects operational parameters. In the literature, the electrocoagulation of textile wastewater has been performed using parallel plates with electrode configurations of either monopolar or bipolar systems. The parallel plate electrochemical cell with two electrodes (Merzouk et al., 2011b; Zongo et al., 2009; Chafi et al., 2011; Daneshvar et al., 2006; Zidane et al., 2008), four electrodes (Eyvaz et al., 2009; Kobya et al., 2007; Can et al., 2006; Sengil and Ozacar, 2009), five pairs of electrodes (Phalakornkule et al., 2010), and six electrodes (Kabdasli et al., 2009b) have been used in the literature. With all the works mentioned, electrochemical treatment studies have focused mainly on electrodes designed in a similar manner. In this study, a packed bed iron electrochemical reactor designed disparately from that reported in the literature was used. In this regard, the objective of this paper is to study the treatment of real textile wastewater, to the legal discharge requirements, without any pre or additional treatment using a uniquely designed electrochemical reactor. Therefore, the performance of the iron reactor has been evaluated at various operational parameters. The effects of operational parameters, such as current density, initial pH, the recirculation flow rate of wastewater and flow regime on color and the COD removal efficiency have been
investigated in this laboratory scale study. A characterization of the EC sludge using X-ray diffraction(XRD),and a cost evaluation of the treatment by electrocoagulation were also conducted.
2. Materials and methods
2.1. Wastewater
The wastewater used in experiments was provided by a local textile factory in Eskisehir, TURKEY. The textile factory was using the Imperon VioletKB with the CAS Numberof6358-46-9 for fabric dyeing when sample was taken from the wastewater. The wastewater had COD concentrations of 1953 mg/L, initial pH of 9.01, absorbance of 0.337 at 533 nm and a conductivity of 739 mS/cm. The Imperon Violet KB (also known as 2-Naphthalenecarboxamide)has chemical formula of C32H26N4O5 with a molecular weight of 546.57264. Its chemical structure is presented in Fig.1.
2.2. Experimental procedure
In this study a packed bed electrochemical reactor, designed differently from those in the literature, was used for the treatment of textile wastewater. The cathode was a cylindrical electrochemical reactor made of iron in height 50 cm with a diameter of 4.3 cm. The anode was an iron hexagonal wire netting sheet in height 50 cm with a wire diameter of 1.6 mm wrapped cylindrically to form a packed bed anode. The packed bed anode was located in the center of the reactor and its schematic representation is shown inFig.2 .The anode and cathode sets were connected to the positive and negative outlets of a DC power source respectively. Textile wastewater was fed at the bottom of the column via a peristaltic pump (Masterflex). During electrolysis the system was operated at a semi-continuous mode and 800 mL of textile wastewater was stored in a reservoir and continuously recycled throughout the reactor. Prior to each test, the pH was adjusted to a desired value using 1 N H2SO4. A specific amount of supporting electrolyte (Na2SO4) was added to the wastewater to increase the conductivity. An initial sample was taken and then current was applied to the circuit over 90 min with the current being held constant for each run.
2.3. Analyses
During an electrolytic run every 10 min, samples of wastewater were withdrawn from the reservoir and centrifuged (Hettich EBA 20)for 5min at 5000 rpm to determine the COD concentration.The conductivity and pH were determined in supernatant liquid by