High performance electrocoagulation systems for removing water contaminants

1 . A high performance iron electrocoagulation (Fe-EC) reactor for removing water contaminants comprising an assembly of spiral-wound or folded and inter-digited iron-containing anode and cathode plates separated with perforated insulating spacers. 2 . The reactor of claim 1 , wherein: one or both plates comprise steel; the reactor contains contaminated water and an oxidant selected from H 2 O 2 , O 3 , chlorine, and permanganate; the reactor is contained in a cylindrical tank, of circular cross-section for the spiral wound reactor, the reactor comprises a perforated insulating sheet or mesh separator disposed between the plates; the reactor comprises a 4-layer, spiral-wound assembly of electrode plate, first perforated insulating sheet or mesh separator, opposite electrode plate, second perforated insulating sheet or mesh separator, and/or the water is contaminated with an organic contaminant (e.g., pharmaceuticals, organic pesticides), ions of a metal (such as arsenic, heavy chromium, copper, manganese, nickel, cadmium, uranium, cobalt, and lead), a phosphate, a silicate (e.g. silicate minerals, ionic solids with silicate anions; as well as rock types that comprise predominantly such minerals, such as the non-ionic compound silicon dioxide SiO 2 , e.g. silica, quartz)), hexavalent chromium (this uses the same reactor design, but without adding external oxidizer). 3 . The reactor of claim 1 , contained in a tank wherein: the plates are electrically connected to a DC voltage source, a DC voltage exists between the plates, the reactor contains contaminated water; and the tank has an inlet or inlets and an outlet or outlets, configured in a flow path to flow contaminated water through the inlet or inlets, pass through the space between the plates, and exit the tank from the outlet or outlets, wherein the contaminated water is non-stationary within the tank, and in motion or flowing. 4 . A method of using the reactor of claim 1 , comprising applying a DC voltage between the plates to promote anodic dissolution of F(0) metal to release Fe(II) ions into the contaminated water, which optionally further comprises the steps of tracking changes in voltage and/or current over time to monitor degradation of electrode plates, and replacing one or both of the plates. 5 . A method for arsenic removal from water comprising: flowing arsenic-contaminated water through an iron electrocoagulation (Fe-EC) reactor comprising an anode, a cathode and an oxidant sufficient to accelerate oxidation of Fe(II) ions released from the anode to obtain Fe(III) ions, and/or to oxidize arsenic in the water, and applying a DC voltage between the anode and cathode to promote anodic dissolution of F(0) metal to release Fe(II) ions into the contaminated water, wherein the arsenic is removed from the water in the reactor. 6 . The method of claim 5 : achieving effective removal of arsenic from initial level of at least or about 10 or 100 fold, such as from >100 to <10 μg/L or >1000 μg/L to <100, e.g. 200-2,000 to 2-20 μg/L; using a flow rate of at least about, or about 2 or 3 or 4 times the reactor volume per minute, or a range of about 2 or 3 or 4 to about 4 or 6 or 8 times the reactor volume per minute, e.g. in a reactor size of 0.5 liters we achieved this removal in 15 seconds, giving a flow rate of 4 times the reactor volume per minute; or using high current density of at least about, or about 2.5, 5, 10, 20, 40, 80 or 200 mA/cm square, or a range of 2.5 or 20 or 40 or 80 to 80 or 120 or 200 mA/cm square. 7 . The method of claim 5 wherein the oxidant is H 2 O 2 , O 3 , KMnO 4 (permanganate), or K 2 Cr 2 O 7 . 8 . The method of claim 5 wherein the oxidant is H 2 O 2 , and is generated in-situ, rather than added exogenously. 9 . The method of claim 5 , wherein the reactor is contained in a tank wherein: the anode and cathode are electrically connected to a DC voltage source, a DC voltage exists between the anode and cathode, and the reactor contains the contaminated water and Fe(II) ions released from the F(0) of the anode, wherein the tank has an inlet or inlets and an outlet or outlets, configured in a flow path to flow contaminated water through the inlet or inlets, pass through the space between the anode and cathode, and exit the tank from the outlet or outlets. 10 . The method of claim 5 , wherein: the reactor comprises a perforated insulating sheet or mesh separator disposed between the anode and cathode. the reactor is an air-cathode assisted iron-electrocoagulation (ACAIE) reactor comprising an air-diffusion cathode. the reactor is a high performance iron electrocoagulation (Fe-EC) reactor comprising an assembly of spiral-wound or folded and inter-digited iron-containing anode and cathode plates separated with perforated insulating spacers. 11 . The method of claim 5 , further comprises the steps of tracking changes in voltage and/or current over time to monitor the degradation of an electrode, and replacing one or both of the anode and cathode or replacing the assembly. 12 . The method of claim 5 , wherein the separating step comprises separating the contaminated water or aqueous solution comprising the Fe(III) precipitates or Fe(II)-Fe(III) precipitates or Iron(III)(oxyhydr)oxides using a separation technique (such as filtration, coagulation, flocculation, settling or any combination of these techniques) to achieve clearer water. 13 . A method for silica removal from water comprising: flowing silica-contaminated water through an iron electrocoagulation (Fe-EC) reactor comprising an anode, a cathode, and an oxidant sufficient to accelerate oxidation of Fe(II) ions released from the anode to obtain Fe(III) ions; and applying a DC voltage between the anode and cathode to promote anodic dissolution of F(0) metal to release Fe(II) ions into the contaminated water, wherein the silica is removed from the water in the reactor. 14 . The method of claim 13 : achieving effective removal of silica from initial level of at least or about 5 or 10 fold, such as from 100-500 mg/L to 20-100 or 10-50 mg/L, e.g. 350 mg/L to 30 mg/L; using a flow rate of at least about, or about 2 or 3 or 4 times the reactor volume per minute, or a range of about 2 or 3 or 4 to about 4 or 6 or 8 times the reactor volume per minute, e.g. in a reactor size of 0.5 liters we achieved this removal in 15 seconds, giving a flow rate of 4 times the reactor volume per minute; using high current density of at least about, or about 20, 40, 80 or 200 mA/cm square, or a range of 20 or 40 or 80 to 80 or 120 or 200 mA/cm square. 15 . The method of claim 13 wherein the oxidant is H 2 O 2 , O 3 , chlorine, or permanganate. 16 . The method of claim 13 wherein the oxidant is H 2 O 2 , and is generated in-situ, rather than added exogenously. 17 . The method of claim 13 , wherein the reactor is contained in a tank wherein: the anode and cathode are electrically connected to a DC voltage source, a DC voltage exists between the anode and cathode, and the reactor contains the contaminated water and Fe(II) ions released from the F(0) of the anode, wherein the tank has an inlet or inlets and an outlet or outlets, configured in a flow path to flow contaminated water through the inlet or inlets, pass through the space between the anode and cathode, and exit the tank from the outlet or outlets. 18 . The method of claim 13 , wherein: the reactor comprises a perforated insulating sheet or mesh separator disposed between the anode and cathode; the reactor is an air-cathode assisted i