Method for treating industrial waste waters

What we claim is: 1. Process of abatement of the Total Organic Content in an aqueous solution comprising the steps of: subjecting the aqueous solution containing organic compounds having electron-withdrawing substituents to a cathodic reduction treatment by feeding a first current density to a first undivided electrochemical cell equipped with at least one cathode, wherein the cathode is made of silver, titanium, graphite or titanium suboxide, and at least one anode, the anode is made of valve metal or titanium suboxide coated with noble metal oxides; and subjecting the treated aqueous solution to an anodic oxidation treatment by feeding a second current density to a second undivided electrochemical cell equipped with at least one cathode made of silver, titanium, graphite or titanium suboxide, and with at least one anode made of a valve metal or titanium suboxide coated with noble metal oxides, wherein the aqueous solution contains one or more organic species with at least one carbon atom being the site of an aromatic conjugated unsaturated bond provided with electron-attracting substituent, the electron-attracting substituent is one or more of halogen, nitrile, thiocyanate, isothiocyanate amide, nitryl, carbonyl, sulphoxyl, mesyl and acetyl groups, and wherein the second current density in the oxidation step is higher than the first current density in the reduction step. 2. The process according to claim 1 , wherein the one or more organic species contained in the aqueous solution to be treated comprises one or more of halogenated derivatives of picolinic acid, of benzoic acid and of benzotrifluorides. 3. The process according to claim 1 , wherein the anode of the second undivided cell is titanium expanded sheet coated with a catalytic layers comprising titanium and ruthenium oxides. 4. The process of claim 1 , wherein the first current density in the reduction step is not higher than 1 kA/m 2 and the second current density in the oxidation step is between 1 and 3 kA/m 2 . 5. Process of abatement of the Total Organic Content in an aqueous solution containing one or more organic species, the process comprising the steps of: subjecting the aqueous solution to a first current density in a first cathodic reduction treatment; and thereafter subjecting the treated aqueous solution to a second current density in an anodic oxidation treatment in the same undivided cell equipped with at least one cathode made of silver, titanium, graphite or titanium suboxide and at least one anode made of valve metal or titanium suboxide coated with noble metal oxides, wherein the aqueous solution contains one or more organic species with at least one carbon atom being the site of an aromatic conjugated unsaturated bond provided with electron-attracting substituent, the electron-attracting substituent is one or more of halogen, nitrile, thiocyanate, isothiocyanate amide, nitryl, carbonyl, sulphoxyl, mesyl and acetyl groups, and wherein the second current density in the oxidation step is increased upon completion of the reduction step. 6. The process of claim 5 , wherein the the subsequent anodic oxidation step is carried out at a current density of between 1 and 3 kA/m 2 . 7. A process of abatement of Total Organic Content in an aqueous solution containing organic compounds having electron-withdrawing substituents comprising subjecting the aqueous solution containing organic compounds having electron-withdrawing substituents to an electrochemical treatment carried out in an undivided cell comprising a cathode made of silver, titanium, graphite or titanium suboxide and an anode made of valve metal or titanium suboxide coated with catalytic noble metal oxides, the electrochemical treatment comprising a cathodic reduction step, the cathodic reduction step is carried out at a current density not higher than 1 kA/m 2 so as to withdraw the electron-withdrawing substituents of the organic compounds and produce destabilized organic compounds, and minimize an onset of concurrent anodic polymerization, and a subsequent anodic oxidation step, the subsequent anodic oxidation step of the destabilized organic compounds are carried out at a current density higher than 1 kA/m 2 . 8. The process according to claim 7 , wherein the organic compounds are derivatives of picolinic acid, chlorinated and fluorinated aromatic compounds. 9. The process according to claim 7 , wherein the subsequent anodic oxidation step is carried out at a current density of between 1 and 3 kA/m 2 .