All the samples were analyzed in du

All the samples were analyzed in duplicate to ensure data reproducibility, and additional measurements were carried out, where necessary. The effluent was subjected to decoloration in the electrochemical reactor and color was determined through absorbance using a UVeVis Spectrophotometer (Shimadzu UV 1700) at a wavelength corresponding to the maximum absorbance for textile wastewater, 533 nm (lmax maximum absorbance). The efficiency of color removal was expressed as a % of absorbance removal calculated as: Color Removal; % ¼ 100ðCabs0
CabsÞ=Cabs0 (7) Where;
Cabs0: Initial absorbance of wastewater (at 533 nm): 0.337 Cabs: Absorbance of effluent at t (at 533 nm)
Inthisstudy,afteranECwasrunforacertainperiodof time,the sludge that formed during the EC process was filtered and the precipitate was dried in an oven and then ground to a fine powder. ThenanXRDanalysisof thispowderwascarriedouttoconfirmthe nature of the sludge formed during the electrocoagulation. The crystalline phase of the EC sludge was examined by XRD analysis. Powder XRD patterns were recorded by means of X-ray diffractometer (Rigaku Rint 2200) using Cu Ka (l ¼ 1.540 A) radiation.
3. Results and discussion
3.1. The effect of current density
Current density is described as the amount of current applied per surface area of the anode. In pilot or laboratory studies of electrocoagulation, current density is taken into consideration, instead of applied current. This is because current density is more easily applicable when adapted to large scale electrocoagulation units than applied current.Current density is the most widely-used operational parameter (Zodi et al., 2009; Vasudevan and Lakshmi, 2011; Daneshvar et al., 2007; Tezcan Un, 2007) in electrocoagulation processes. To examine the effects of current density, assays with 20 ,30 and 50 mA/cm2 current densities were applied to an electrochemical reactor at a pH of 9, with a supporting electrolyte concentration of 0.05 M Na2SO4 and a circulation flow rate (vflowrate) of 540 mL/min. Fig. 3 shows the removal efficiency of the COD and absorbance after 90 min of electrocoagulation respectively. As can be seen in Fig. 3(a), more than 80% COD removal efficiencies were obtained at all current densities after 30 min of reaction time. With the time extended to 90 min COD removal increased to 90.84, 93.66 and 96.88% at current densities of 20, 30
and 50 mA/cm2 respectively. It can easily be concluded that the increase in the current density results in the increase in the COD reduction rate as obtained in earlier studies (Aoudj et al., 2010; Pajootan et al., 2012). According to Turkish legislation the legal discharge limit to destined environment for the cotton textiles industry is 250 mg/L for a 2 h composite sample. As a result of the experiments, after 90 min electrocoagulation, direct dischargeable effluents were obtained by reducing the initial COD concentration of 1953 mg/L to 61,124 and 179 mg/L at current densities of 50, 30 and 20 mA/cm2 respectively. Therefore further experiments proceeded at 20 mA/cm2 to prevent additional energy consumption. As can be seen from Fig. 3(b), removal of color fromwastewater is easier than removal of COD. For the first 10 min, color intensity was removed rapidly and removal efficiencies of over 90% were obtainedatallcurrentdensities.Theinitialabsorbanceof0.337was reduced to 0.033, 0.015, 0.014 at first 10 min at current densities of 20, 30 and 50 mA/cm2 respectively. Beyond this point the removal of color did not significantly change over time. So, 10 min of electrocoagulationisenough,andnofurtherelectrocoagulationprocess is necessary for the removal of color from textile wastewater. The color change of textile wastewater during EC, in relation to time, was also observed with the naked eye, as shown in Fig. 4. The electrical energy consumption (EEC) was also calculated using Eq. (8) as kWh per mg of the COD removed