Cross-flow electrochemical separation devices and methods of assembling same

What is claimed is: 1. An electrochemical separation apparatus, comprising: a cell stack comprising: a plurality of aligned cell pairs, each of the plurality of aligned cell pairs including an ion concentrating compartment constructed and arranged to provide fluid flow in a first direction and an ion diluting compartment constructed and arranged to provide fluid flow in a second direction that is different from the first direction; each of the ion concentrating compartments comprising an anion exchange membrane, a cation exchange membrane, and a first spacer positioned between the anion exchange membrane and the cation exchange membrane, the first spacer having a masked first set of end portions and a potted second set of end portions; each of the ion diluting compartments comprising an anion exchange membrane, a cation exchange membrane, and a second spacer positioned between the anion exchange membrane and the cation exchange membrane, the second spacer having a potted first set of end portions and a masked second set of end portions; the masked first set of end portions of the first spacer being aligned with the potted first set of end portions of the second spacer, and the potted second set of end portions of the first spacer being aligned with the masked second set of end portions of the second spacer; each end portion of the first and second sets of end portions defining a channel extending therethrough, each channel being in fluid communication with those spacers through whose masked end portion the channel extends, and each channel being in fluid isolation from those spacers through whose potted end portion the channel extends; a frame surrounding the cell stack to form a first module; and a housing enclosing the first module. 2. The electrochemical separation apparatus of claim 1 , wherein each of the masked first set of end portions of each of the first spacers and masked second set of end portions of each of the second spacers comprises a sleeve surrounding the end portion of the spacer. 3. The electrochemical separation apparatus of claim 2 , wherein each of the sleeves comprises a pair of films welded together. 4. The electrochemical separation apparatus of claim 3 , wherein the pair of films are welded to each of the first or second spacers at each of the masked first or second set of end portions at multiple interior locations to form obstructions to fluid and current flow. 5. The electrochemical separation apparatus of claim 3 , wherein the pair of films are welded directly to each other at each of the masked first or second set of end portions at multiple interior locations to form obstructions to fluid and current flow. 6. The electrochemical separation apparatus of claim 3 , wherein each of the sleeves of the first plurality of sleeves comprises a plurality of ribs formed from welded together portions of the pair of plastic films. 7. The electrochemical separation apparatus of claim 2 , wherein each of the first or second spacers at each of the masked first or second set of end portions comprises a plurality of raised obstructions in an interior of the masked first or second set of end portions to obstruct fluid and current flow. 8. The electrochemical separation apparatus of claim 2 , wherein each sleeve comprises a plastic film and a portion of membrane welded to the masked first or second set of end portions of the first or second spacer, at a periphery of the end portion, the portion of membrane being a portion of one of the anion exchange and the cation exchange membrane. 9. The electrochemical separation apparatus of claim 1 , further comprising a second frame surrounding a second cell stack to form a second module within the housing, and a gasket positioned between the first module and the second module, the gasket comprising a plurality of apertures, each aperture aligned respectively with a channel of the first cell stack and a channel of the second module to provide for fluid communication between the first module and the second module. 10. The electrochemical separation apparatus of claim 1 , further comprising a second frame surrounding a second cell stack to form a second module within the housing, and a blocking spacer positioned between the first module and the second module to redirect flow between the first module and the second module. 11. The electrochemical separation apparatus of claim 1 , wherein the frame comprises a reservoir configured to hold potting material. 12. The electrochemical separation apparatus of claim 11 , wherein the frame comprises a channel configured to transfer potting material from the reservoir to the cell stack. 13. The electrochemical separation apparatus of claim 12 , wherein the frame comprises a potting diffuser mechanism proximate the cell stack and in fluid communication with the channel. 14. The electrochemical separation apparatus of claim 13 , wherein the potting diffuser mechanism comprises an angled cut-out formed in the frame, the angled cut-out configured to distribute potting material evenly to a full width of the cell stack. 15. The electrochemical separation apparatus of claim 14 , wherein the frame comprises a unitary body. 16. The electrochemical separation apparatus of claim 1 , further comprising a first electrode at a first end of the housing and a second electrode at a second end of the housing. 17. The electrochemical separation apparatus of claim 16 , further comprising a casing surrounding the first electrode, the casing comprising a sealing bracket, a sealing cap, and an o-ring positioned between the sealing bracket and the sealing cap. 18. The electrochemical separation apparatus of claim 1 , further comprising a plurality of expandable plugs extending through the cell stack and arranged to maintain alignment of the plurality of aligned cell pairs. 19. A method of assembling an electrochemical separation apparatus comprising: masking a first plurality of spacers at a first set of end portions; masking a second plurality of spacers at a second set of end portions; forming a plurality of cell pairs by, for each cell pair, positioning a spacer from the first plurality of spacers between a first anion exchange membrane and a cation exchange membrane to provide an ion concentrating compartment configured to direct fluid flow in a first direction, and positioning a spacer from the second plurality of spacers between the cation exchange membrane and a second anion exchange membrane to provide an ion diluting compartment configured to direct fluid flow in a second direction that is different from the first direction; forming a cell stack by successively stacking the formed plurality of cell pairs within a frame; potting the first set of end portions and the second set of end portions such that potting material enters the first set of end portions of the second plurality of spacers while being masked from entering the first set of end portions of the first plurality of spacers, and such that potting material enters the second set of end portions of the first plurality of spacers while being masked from entering the second set of end portions of the second plurality of spacers; defining a channel through each of the potted portions of each of the first and second sets of end portions such that each of the channels in the first set of end portions is in fluid communication with a plurality of ion concentrating compartments and fluidly isolated from a plurality of ion diluting compartments, while each of the channels in the second set of end portions is in f