Ion Exchange Exoskeleton and Filter Assembly

What is claimed is: 1 . A spiral ion exchange exoskeleton body for arrangement in an ion exchange filter cartridge having first and second end caps, wherein the spiral ion exchange exoskeleton body comprises: an inlet face for receiving coolant flow; an outlet face for discharging coolant; wherein the inlet and outlet faces are arranged on opposite axial end faces of the spiral ion exchange exoskeleton body; wherein the spiral ion exchange exoskeleton body consists of two individual sheets: a continuous first sheet as porous sheet comprising a plurality of axial pleats, each pleat extending axially from the inlet face to the outlet face of the of the ion exchange exoskeleton a continuous second sheet as a non-porous sheet overlaid directly onto the plurality of axial pleats of the porous sheet at a first side of the porous sheet, wherein the non-porous sheet is not pleated; wherein the non-porous sheet is arranged directly on the plurality of pleats on the first side, the non-porous sheet is also arranged directly on the plurality of pleats on an opposite second side of the porous sheet, the first and second sheets cooperating to form a plurality of axial flow channels on both the first and on the opposite second side of the non-porous sheet; wherein the porous sheet and the non-porous sheet are arranged such that they spirally encircle the central axis of the spiral in exchange exoskeleton body multiple times, such that the two sheets form the spiral ion exchange exoskeleton body having a plurality of overlaid layers, the pleats of the porous sheet radially closed by the non-porous sheet on both sides of the porous sheet, forming the plurality of open axial flow channels at both sides of the pleats, each individual flow channel open continuously from the first end cap to the second end cap of a tubular ion exchange filter housing, such that flow can proceed while remaining in a single flow channel of the spiral ion exchange exoskeleton body from the first end cap to the second end cap of the ion exchange filter cartridge; wherein the first set of flow channels are uncovered and fully open at the inlet face and the outlet face of the spiral ion exchange exoskeleton body; ion exchange resin beads arranged within the plurality of open axial flow channels. 2 . The spiral ion exchange exoskeleton body of 1, wherein the spiral ion exchange exoskeleton body has a total porosity of at least 50 percent. 3 . The spiral ion exchange exoskeleton body of claim 1 , wherein the plurality of open axial flow channels extend generally parallel to the central axis along a coolant flow direction from the inlet face to the outlet face of the ion exchange exoskeleton. 4 . The spiral ion exchange exoskeleton body of claim 1 , wherein the ion exchange resin beads include anode resin beads and cathode resin beads with a diameter of the anode resin beads being within 10 percent of a diameter of the cathode resin beads. 5 . The spiral ion exchange exoskeleton body of claim 1 , wherein a ratio between a height of the first set of channels and a diameter of the ion exchange resin beads is at least 4-to-1 and no more than 10-to-1. 6 . The spiral ion exchange exoskeleton body of claim 1 , wherein the porous sheet is spun bond sheet. 7 . The spiral ion exchange exoskeleton body of claim 1 , wherein the non-porous sheet is a melt-blown sheet. 8 . An ion exchange filter cartridge, comprising: a tubular ion exchange filter housing formed as an axially elongated cylindrical tube, the axially elongated cylindrical tube radially enclosing an ion exchange filter containment region, arranged between a first axial end and an opposite second axial end of the axially elongated cylindrical tube; a first end cap secured onto and closing the first axial end of the axially elongated cylindrical tube, the first end cap including a coolant inlet extending through the first end cap and opening into the ion exchange filter containment region at the first axial end of the tubular ion exchange filter housing; a second end cap secured onto and closing the second axial end of the axially elongated cylindrical tube, the second end cap including an coolant outlet extending through the second end cap and opening into the ion exchange filter containment region at the opposite second axial end of the tubular ion exchange filter housing; wherein axial herein is a direction parallel to the central axis of the axially elongated cylindrical tube, the central axial extending through both the first end cap and the second end cap; a spiral ion exchange exoskeleton body arranged within the ion exchange filter containment region, the spiral ion exchange exoskeleton body consisting of two continuous sheets: a continuous first sheet as a porous sheet comprising a plurality of pleats; a continuous second sheet as a non-porous sheet overlaid directly onto the pleats of the porous sheet at a first side of the porous sheet, wherein the non-porous sheet is not pleated; wherein the non-porous sheet is arranged directly on the plurality of pleats on the first side, the non-porous sheet is also arranged directly on the plurality of pleats on an opposite second side of the porous sheet, the first and second sheets cooperating to form a plurality of axial flow channels on both the first and on the opposite second side of the non-porous sheet; wherein the porous sheet and the non-porous sheet are arranged such that they spirally encircle the central axis multiple times, such that the two sheets form the spiral ion exchange exoskeleton body having a plurality of overlaid layers, the pleats of the porous sheet radially closed by the non-porous sheet on both sides of the porous sheet, forming the plurality of open axial flow channels at both sides of the pleats, each individual flow channel open continuously from the first end cap to the second end cap of the tubular ion exchange filter housing, such that flow can proceed while remaining in a single flow channel of the spiral ion exchange exoskeleton body from the first end cap to the second end cap; ion exchange resin beads arranged within the plurality of open axial flow channels; a first particle screen arranged between the first end cap of the tubular ion exchange filter housing and an inlet face of the spiral ion exchange exoskeleton body; a second particle screen arranged between the second end cap of the tubular ion exchange filter housing and an outlet face of the spiral ion exchange exoskeleton body. 9 . The ion exchange filter cartridge of claim 8 , wherein the exoskeleton has a total porosity of at least 50 percent. 10 . The ion exchange filter cartridge of claim 8 , wherein the first set of channels extend generally parallel to a central axis of the tubular ion exchange filter housing along a coolant flow direction from the first end cap to the second end cap. 11 . The ion exchange filter cartridge of claim 8 , wherein the ion exchange resin beads include anode resin beads and cathode resin beads with a diameter of the anode resin beads being within 10 percent of a diameter of the cathode resin beads. 12 . The ion exchange filter cartridge of claim 8 , wherein a ratio between a height of the first set of channels and a diameter of the ion exchange resin beads is at least 4-to-1 and no more than 10-to-1. 13 . The ion exchange exoskeleton of claim 8 , wherein the porous sheet is spun bond sheet. 14 . The ion exchange exoskeleton of claim 8 , wherein the non-porous sheet is a melt-blown sheet. 15 . An ion exchange filter cartridge, comprising: a tubular ion exchange filter h