Redox and plating electrode systems for an all-iron hybrid flow battery

The invention claimed is: 1. A system for a flow cell for a hybrid flow battery, comprising: one or more electrolyte inlets; one or more electrolyte outlets; a redox plate, comprising: a plurality of electrolyte flow channels; conductive inserts attached to the redox plate between adjacent electrolyte flow channels; and a redox electrode attached to a surface of the redox plate; where the conductive inserts have a long edge parallel to a long edge of the electrolyte flow channels, the long edge of the conductive inserts extending along a first side of a polymeric plate; a plating electrode, comprising a plurality of folded fins with an oscillating cross-section, the plurality of folded fins comprising: a first planar surface; a second planar surface, parallel to the first planar surface and displaced from the first planar surface in a first direction, the first direction being normal to the first and second planar surfaces and extending from the first planar surface toward the second planar surface; a plurality of ridges intersecting the first and second planar surfaces such that the plurality of ridges divides the first planar surface into a first plurality of strips, and divides the second planar surface into a second plurality of strips; a first plurality of flow channels adjacent to the first plurality of strips in the first direction; and a second plurality of flow channels adjacent to the second plurality of strips in a second direction, the second direction being opposite the first direction; and a membrane barrier located between the redox electrode and the plating electrode. 2. The system of claim 1 , wherein the electrolyte flow channels and conductive inserts form flow ribs that form a first edge of a first channel and a second edge of an adjacent second channel. 3. The system of claim 1 , wherein the plurality of folded fins comprises a plurality of perforations. 4. A system for an electrolyte flow plate for a hybrid flow battery, comprising: a polymeric plate comprising a plurality of electrolyte flow channels; and a plurality of conductive inserts attached to the polymeric plate between adjacent electrolyte flow channels; where a length of the conductive inserts is greater than a width of the conductive inserts, the length extending along a first side of the polymeric plate; wherein the electrolyte flow channels are voids comprising a long edge extending the length of the first side of the polymeric plate. 5. The system of claim 4 , wherein the conductive inserts comprise rectangular prisms having a long edge parallel to the long edge of the electrolyte flow channels, and extending the length of the first side of the polymeric plate. 6. The system of claim 5 , wherein the electrolyte flow channels and conductive inserts form flow ribs that form a first edge of a first channel and a second edge of an adjacent second channel. 7. The system of claim 6 , wherein the electrolyte flow channels are sloped from a base of the polymeric plate to a top face of the polymeric plate. 8. The system of claim 6 , wherein the electrolyte flow channels include two or more steps from a base of the polymeric plate to a top face of the polymeric plate. 9. The system of claim 4 , where the electrolyte flow channels are interdigitated or partially interdigitated. 10. The system of claim 4 , wherein the conductive inserts are Carbon/Graphite composite inserts. 11. A plating electrode for a battery, comprising: a plurality of folded fins with an oscillating cross-section, the plurality of folded fins comprising: a first planar surface; a second planar surface, parallel to the first planar surface, and displaced from the first planar surface in a first direction, the first direction being normal to the first and second planar surfaces and extending from the first planar surface toward the second planar surface; a plurality of ridges intersecting the first and second planar surfaces such that the plurality of ridges divides the first planar surface into a first plurality of strips, and divides the second planar surface into a second plurality of strips; a first plurality of flow channels adjacent to the first plurality of strips in the first direction; and a second plurality of flow channels adjacent to the second plurality of strips in a second direction, the second direction being opposite the first direction. 12. The plating electrode of claim 11 , where the plurality of ridges is perpendicular to the first and second planar surfaces. 13. The plating electrode of claim 12 , where the plurality of ridges includes a plurality of serrations. 14. The plating electrode of claim 11 , where the first plurality of strips has a first width, and the second plurality of strips has a second width, the second width being greater than the first width. 15. The plating electrode of claim 11 , where the plurality of folded fins comprises a plurality of perforations. 16. The plating electrode of claim 11 , where the first planar surface is coated with a non-conductive material. 17. The plating electrode of claim 11 , where the plurality of folded fins is fabricated from iron, an iron alloy, stainless steel, titanium, or carbon. 18. The plating electrode of claim 11 , further comprising: a base plate coupled to the second planar surface such that the base plate, the plurality of ridges, and the first plurality of strips form a plurality of channels. 19. The plating electrode of claim 18 , further comprising: one or more interdigitation or partial interdigitation plates, each interdigitation or partial interdigitation plate being perpendicular to the base plate and intersecting with a first end of the plurality of channels such that a flow of an electrolyte is restricted through the first end of the plurality of channels.