Device for efficient continuous electrokinetic dewatering of phosphatic clay suspensions

Therefore, at least the following is claimed: 1. A system for continuous electrokinetic dewatering, comprising: a cake dewatering unit including: an upper anode and a lower cathode extending at an inclined or declined angle across a dewatering chamber, where energizing the upper anode and the lower cathode establishes an electric field between the upper anode and the lower cathode; a lower conveying belt extending from a first end to a second end across and within the dewatering chamber and around the lower cathode; an upper conveying belt extending across at least a portion of the dewatering chamber and around the upper anode, the upper conveying belt offset from the first end of the lower conveying belt; a sludge inlet that supplies a sludge suspension on the first end of the lower conveying belt, where rotation of the upper and lower conveying belts draws the sludge suspension between the upper anode and the lower cathode, where the sludge suspension is dewatered as it passes through the electric field between the upper anode and the lower cathode; and a retaining dam positioned over the first end of the lower conveying belt, the retaining dam extending to at least a height of the upper conveying belt over the lower conveying belt, wherein the sludge suspension is provided by the sludge inlet between the retaining dam and the upper conveying belt. 2. The system of claim 1 , wherein the upper anode and the lower cathode extend at a downward angle across the dewatering chamber. 3. The system of claim 1 , wherein the upper anode is positioned above and substantially parallel to a lower portion of the upper conveying belt and the lower cathode is positioned below and substantially parallel to an upper portion of the lower conveying belt. 4. The system of claim 1 , wherein the dewatering chamber extends at an upward inclined angle from the first side to the second end of the lower conveying belt. 5. The system of claim 1 , wherein the upper and lower conveying belts discharge cake from the dewatering chamber after dewatering. 6. The system of claim 5 , wherein the upper conveying belt extends beyond an end of the dewatering chamber. 7. The system of claim 1 , wherein the retaining dam comprises thickened clay disposed on the lower conveying belt. 8. The system of claim 1 , further comprising a power supply configured to energize the upper anode and the lower cathode. 9. A system for continuous electrokinetic dewatering, comprising: a cake dewatering unit including: an upper anode and a lower cathode extending at an inclined or declined angle across a dewatering chamber, where energizing the upper anode and the lower cathode establishes an electric field between the upper anode and the lower cathode; a lower conveying belt extending from a first end to a second end across and within the dewatering chamber and around the lower cathode; an upper conveying belt extending across at least a portion of the dewatering chamber and around the upper anode, the upper conveying belt offset from the first end of the lower conveying belt; a sludge inlet that supplies a sludge suspension on the first end of the lower conveying belt, where rotation of the upper and lower conveying belts draws the sludge suspension between the upper anode and the lower cathode, where the sludge suspension is dewatered as it passes through the electric field between the upper anode and the lower cathode; and a suspension thickening unit including: an upper cathode and a lower anode extending across at least a portion of a thickening chamber, where energizing the upper cathode and the lower anode establishes an electric field between the upper cathode and the lower anode; a feed inlet configured to supply a dilute feed suspension comprising solids suspended in water to the suspension thickening zone; a solids conveying belt extending horizontally from an inlet side of the thickening chamber to an outlet side of the thickening chamber and around the lower anode, where the electric field between the upper cathode and the lower anode consolidates the solids away from the upper cathode and onto the solids conveying belt; a first discharge at the inlet side of the thickening chamber, the first discharge configured to remove supernatant liquid that collects over the upper cathode after separation from the dilute feed suspension in the electric field; and a second discharge at the outlet side of the thickening chamber, the second discharge configured to remove the sludge suspension from the thickening chamber. 10. The system of claim 9 , wherein the feed inlet comprises an inlet nozzle configured to distribute the dilute feed suspension between the upper cathode and the lower anode. 11. The system of claim 9 , further comprising a pump that supplies the dilute feed suspension to the feed inlet. 12. The system of claim 9 , wherein the upper cathode is positioned adjacent to a surface of the dilute feed suspension in the thickening chamber, the upper cathode substantially parallel to the lower anode. 13. The system of claim 12 , wherein the lower anode is positioned below and substantially parallel to an upper portion of the solids conveying belt. 14. The system of claim 9 , further comprising a power supply configured to energize the upper anode and the lower cathode. 15. The system of claim 9 , further comprising a power supply configured to energize the lower anode and the upper cathode. 16. The system of claim 15 , wherein the power supply is further configured to energize the upper anode and the lower cathode. 17. A system for continuous electrokinetic dewatering, comprising: a cake dewatering unit including: a lower conveying belt extending at an inclined or declined angle from a first end to a second end across a dewatering chamber, the lower conveying belt comprising a lower cathode; an upper conveying belt extending over the lower conveying belt and across at least a portion of the dewatering chamber, a first end of the upper conveying belt offset from the first end of the lower conveying belt and a second end of the upper conveying belt extending beyond the second end of the lower conveying belt, the upper conveying belt comprising an upper anode, where energizing the upper anode and the lower cathode establishes an electric field between the upper anode and the lower cathode; a sludge inlet that supplies a sludge suspension on the first end of the lower conveying belt, where rotation of the upper and lower conveying belts draws the sludge suspension between the upper anode and the lower cathode, where the sludge suspension is dewatered as it passes through the electric field between the upper anode and the lower cathode, and discharges dewatered cake over the second end of the lower conveying belt below the second end of the upper conveying belt. 18. The system of claim 17 , wherein the sludge suspension is supplied with a solids content of less than 15 wt %. 19. The system of claim 18 , wherein the dewatered cake is discharged with a solids content in a range from about 31 wt % to about 38 wt %. 20. The system of claim 17 , wherein a gap between the upper anode and the lower cathode is tapered to decrease from the first end of the upper conveying belt to the second end of the lower conveying belt.