Electrochemical water cleaning device

What is claimed is: 1. An electrochemical water cleaning device comprising: one or more deionization cells having a membrane electrode assembly including a first electrode compartment separated by an anion exchange membrane from a second electrode compartment, each of the first and second compartments configured to contain an intercalation host electrode; a first water stream compartment separated by the membrane electrode assembly from a second water stream compartment, each of the first and second water stream compartments configured to contain a saline water solution and arranged to be in respective fluid communication with the first and second electrode compartments; a power source configured to supply electric current to the intercalation host electrodes to release cations into the solution; and a controller programmed to adjust an amount of the electric current being supplied by the power source to change a flow of anions present in the saline water solution and passing through the anion exchange membrane between the first and second compartments. 2. The electrochemical water cleaning device of claim 1 , further comprising at least one inlet channel and one outlet channel and wherein the controller is programmed to adjust volumetric flow rate in at least one inlet channel, outlet channel, or both. 3. The electrochemical water cleaning device of claim 1 , wherein the device includes at least two deionization cells and the controller is programmed to control ion transport in each of the at least two deionization cells individually by supplying a different voltage to each of the at least two deionization cells. 4. The electrochemical water cleaning device of claim 1 , further comprising one or more monopolar plates positioned between the one or more deionization cells and configured to direct a flow of water within at least one of the water stream compartments. 5. The electrochemical water cleaning device of claim 1 , further comprising one or more bipolar plates positioned between the one or more deionization cells and configured to direct a flow of water within at least one of the water stream compartments. 6. The electrochemical water cleaning device of claim 4 , wherein the one or more monopolar plates includes a first flow side and a second flow side and is configured to direct a first flow of water along the first flow side and a second flow of water along the second flow side, wherein the direction of the first flow of water is the same as the direction of the second flow of water. 7. The electrochemical water cleaning device of claim 5 , wherein the one or more bipolar plates includes a first flow side and a second flow side and is configured to direct a first flow of water along the first flow side and a second flow of water along the second flow side, wherein the direction of the first flow of water is opposite the direction of the second flow of water. 8. A desalination battery comprising: a plurality of desalination battery cells having a membrane electrode assembly including a first electrode compartment separated by an anion exchange membrane from a second electrode compartment, each of the first and second compartments configured to contain an intercalation host electrode; a first water stream compartment separated by the membrane electrode assembly from a second water stream compartment, each of the first and second water stream compartments configured to contain a saline water solution and arranged to be in respective fluid communication with the first and second electrode compartments, the first and second water stream compartments further configured to define a portion of a water flow field through the plurality of desalination battery cells; a power source configured to supply electric current to the intercalation host electrodes to release cations into the solution; and a controller programmed to adjust an amount of the electric current being supplied by the power source to change the flow of anions present in the saline water solution and passing through the anion exchange membrane between the first and second compartments. 9. The desalination battery of claim 8 , further comprising two or more inlet feed channels and at least one outlet channel, wherein the controller is programmed to adjust volumetric flow rate in one or more of the inlet feed channels. 10. The desalination battery of claim 8 , wherein the controller is further programmed to control ion transport in two or more desalination battery cells individually by supplying a different voltage to each. 11. The desalination battery of claim 9 , wherein the water flow field is in fluid communication with the two or more inlet feed channels and the at least one outlet channel. 12. The desalination battery of claim 10 , wherein the water flow field is configured such that a first saline water solution flow directed through a first inlet feed channel passes through the plurality of desalination battery cells in a generally serpentine pattern and a second saline water solution flow directed through a second inlet feed channel passes through the plurality of desalination battery cells in a generally serpentine pattern. 13. The desalination battery of claim 10 , wherein the water flow field is configured such that a first saline water solution flow directed through a first inlet feed channel passes through the plurality of desalination battery cells in a generally straight-channel pattern and a second saline water solution flow directed through a second inlet feed channel passes through the plurality of desalination battery cells in a generally straight-channel pattern. 14. The desalination battery of claim 12 , wherein the direction of the first saline water solution flow opposes the direction of the second saline water solution flow in at least a portion of the flow field. 15. The desalination battery of claim 13 , wherein the direction of the first saline water solution flow opposes the direction of the second saline water solution flow in at least a portion of the flow field.