Method and system to maintain electrolyte stability for all-iron redox flow batteries

The invention claimed is: 1. A system for a hybrid flow battery, comprising: a positive electrochemical cell, coupled in line or in parallel, of a positive electrode compartment; a first electrical load coupled to the positive electrochemical cell; a negative electrochemical cell, coupled in line or in parallel, of a negative electrode compartment; a second electrical load coupled to the negative electrochemical cell; where hydrogen-rich gas circulates between headspaces of positive and negative electrolyte sources to anodes of the negative and positive electrochemical cells; and a controller configured with instructions stored in non-transitory memory, that when executed, cause the controller to: apply the first electrical load to the positive electrochemical cell based on first electrolyte pH set points; and apply the second electrical load to the negative electrochemical cell based on second electrolyte pH set points. 2. The system of claim 1 , wherein the positive electrochemical cell and the negative electrochemical cell are positioned external to the battery or within battery compartments. 3. The system of claim 1 , wherein the positive electrochemical cell is coupled directly to an inlet of the positive electrode compartment and the negative electrochemical cell is coupled directly to an outlet of the negative electrode compartment. 4. A system for a hybrid flow battery, comprising: a redox cell, comprising: a negative electrode compartment; a positive electrode compartment; and a membrane separator disposed between the negative electrode compartment and the positive electrode compartment; a positive electrolyte source coupled to the positive electrode compartment and containing a positive electrolyte; a positive electrochemical cell, coupled in line or in parallel, of the positive electrode compartment and the positive electrolyte source; a negative electrolyte source coupled to the negative electrode compartment and containing a negative electrolyte; a negative electrochemical cell, coupled in line or in parallel, of the negative electrode compartment and the negative electrolyte source; a pressure equalization line between head spaces of the positive electrolyte source and the negative electrolyte source; a line connecting the head spaces of the positive and negative electrolyte sources to the positive and negative electrochemical cells via eductors or pumps to circulate hydrogen-rich gas; a first electrical load coupled to the positive electrochemical cell; a second electrical load coupled to the negative electrochemical cell; and a controller configured with instructions stored in non-transitory memory, that when executed, cause the controller to: apply the first electrical load to the positive electrochemical cell when first electrolyte pH set points are met; apply the second electrical load to the negative electrochemical cell when second electrolyte pH set points are met. 5. The system of claim 4 , further comprising discontinuing the first electrical load to the positive electrochemical cell when a first electrolyte pH is below a second threshold. 6. The system of claim 5 , further comprising discontinuing the second electrical load to the negative electrochemical cell when a second electrolyte pH is below a fourth threshold. 7. The system of claim 6 , further comprising at least one eductor coupled to the positive and/or negative electrochemical cells, wherein the eductor delivers hydrogen gas via the line.