Figure 1: The comparison of electrode material on the treatment efficiency of the textile wastewater (pH8.2, current flow 4 amp and EC time 15 minutes)
Figure 2: Color removal efficiency (%) with time (minutes) with stainless steel electrodes
Figure 3: Effect of different initial pH conditions on color removal efficiency
Figure 4: Effect of different pH in removal of COD
Figure 5: Electricity cost for different initial pH
Figure 6: Effect of current flow on color and COD removal (pH initial 8.4, mild steel electrodes and EC time 10 min)
Figure 7: Effect of EC time on color and COD removal (pH 6.9 and current flow 5 amp)
Figure 8: Effect of EC time on electrode and energy consumption (pH 6.9 and current flow 5 amp).
Figure 1: The comparison of electrode material on the treatment efficiency of the textile wastewater (pH8.2, current flow 4 amp and EC time 15 minutes)
Figure 2: Color removal efficiency (%) with time (minutes) with stainless steel electrodes
Figure 3: Effect of different initial pH conditions on color removal efficiency
Figure 4: Effect of different pH in removal of COD
Figure 5: Electricity cost for different initial pH
Figure 6: Effect of current flow on color and COD removal (pH initial 8.4, mild steel electrodes and EC time 10 min)
Figure 7: Effect of EC time on color and COD removal (pH 6.9 and current flow 5 amp)
Figure 8: Effect of EC time on electrode and energy consumption (pH 6.9 and current flow 5 amp).
Figure 1: The comparison of electrode material on the treatment efficiency of the textile wastewater (pH8.2, current flow 4 amp and EC time 15 minutes)
Figure 2: Color removal efficiency (%) with time (minutes) with stainless steel electrodes
Figure 3: Effect of different initial pH conditions on color removal efficiency
Figure 4: Effect of different pH in removal of COD
Figure 5: Electricity cost for different initial pH
Figure 6: Effect of current flow on color and COD removal (pH initial 8.4, mild steel electrodes and EC time 10 min)
Figure 7: Effect of EC time on color and COD removal (pH 6.9 and current flow 5 amp)
Figure 8: Effect of EC time on electrode and energy consumption (pH 6.9 and current flow 5 amp).
Figure 1: The comparison of electrode material on the treatment efficiency of the textile wastewater (pH8.2, current flow 4 amp and EC time 15 minutes)
Figure 2: Color removal efficiency (%) with time (minutes) with stainless steel electrodes
Figure 3: Effect of different initial pH conditions on color removal efficiency
Figure 4: Effect of different pH in removal of COD
Figure 5: Electricity cost for different initial pH
Figure 6: Effect of current flow on color and COD removal (pH initial 8.4, mild steel electrodes and EC time 10 min)
Figure 7: Effect of EC time on color and COD removal (pH 6.9 and current flow 5 amp)
Figure 8: Effect of EC time on electrode and energy consumption (pH 6.9 and current flow 5 amp).
Figure 1: The comparison of electrode material on the treatment efficiency of the textile wastewater (pH8.2, current flow 4 amp and EC time 15 minutes)
Figure 2: Color removal efficiency (%) with time (minutes) with stainless steel electrodes
Figure 3: Effect of different initial pH conditions on color removal efficiency
Figure 4: Effect of different pH in removal of COD
Figure 5: Electricity cost for different initial pH
Figure 6: Effect of current flow on color and COD removal (pH initial 8.4, mild steel electrodes and EC time 10 min)
Figure 7: Effect of EC time on color and COD removal (pH 6.9 and current flow 5 amp)
Figure 8: Effect of EC time on electrode and energy consumption (pH 6.9 and current flow 5 amp).
Figure 1: The comparison of electrode material on the treatment efficiency of the textile wastewater (pH8.2, current flow 4 amp and EC time 15 minutes)
Figure 2: Color removal efficiency (%) with time (minutes) with stainless steel electrodes
Figure 3: Effect of different initial pH conditions on color removal efficiency
Figure 4: Effect of different pH in removal of COD
Figure 5: Electricity cost for different initial pH
Figure 6: Effect of current flow on color and COD removal (pH initial 8.4, mild steel electrodes and EC time 10 min)
Figure 7: Effect of EC time on color and COD removal (pH 6.9 and current flow 5 amp)
Figure 8: Effect of EC time on electrode and energy consumption (pH 6.9 and current flow 5 amp).
Figure 1: The comparison of electrode material on the treatment efficiency of the textile wastewater (pH8.2, current flow 4 amp and EC time 15 minutes)
Figure 2: Color removal efficiency (%) with time (minutes) with stainless steel electrodes
Figure 3: Effect of different initial pH conditions on color removal efficiency
Figure 4: Effect of different pH in removal of COD
Figure 5: Electricity cost for different initial pH
Figure 6: Effect of current flow on color and COD removal (pH initial 8.4, mild steel electrodes and EC time 10 min)
Figure 7: Effect of EC time on color and COD removal (pH 6.9 and current flow 5 amp)
Figure 8: Effect of EC time on electrode and energy consumption (pH 6.9 and current flow 5 amp).
Figure 1: The comparison of electrode material on the treatment efficiency of the textile wastewater (pH8.2, current flow 4 amp and EC time 15 minutes)
Figure 2: Color removal efficiency (%) with time (minutes) with stainless steel electrodes
Figure 3: Effect of different initial pH conditions on color removal efficiency
Figure 4: Effect of different pH in removal of COD
Figure 5: Electricity cost for different initial pH
Figure 6: Effect of current flow on color and COD removal (pH initial 8.4, mild steel electrodes and EC time 10 min)
Figure 7: Effect of EC time on color and COD removal (pH 6.9 and current flow 5 amp)
Figure 8: Effect of EC time on electrode and energy consumption (pH 6.9 and current flow 5 amp).
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