Mechanical energy storage in flow batteries to enhance energy storage

What is claimed is: 1 . A hybrid flow redox battery system comprising an electrochemical cell, an anolyte tank, a catholyte tank, one or more tank separators, a plurality of electrolyte pathways, one or more turbines, and one or more power generation circuits, wherein: the electrochemical cell comprises an ion-exchange membrane positioned between and electrochemically engaged with an anode and a cathode; at least one of the one or more power generation circuits is electrically coupled to the anode and the cathode; the anolyte tank includes an upper anolyte opening and a lower anolyte opening positioned below the upper anolyte opening; the catholyte tank includes an upper catholyte opening and a lower catholyte opening positioned below the upper catholyte opening; one or more of the plurality of electrolyte pathways extend between the upper anolyte opening and the anode and extend between the lower anolyte opening and the anode to fluidly couple the anolyte tank to the anode; one or more of the plurality of electrolyte pathways extend between the upper catholyte opening and the cathode and extend between the lower catholyte opening and the cathode to fluidly couple the catholyte tank to the cathode; the one or more turbines are fluidly coupled to one or more of the plurality of electrolyte pathways; the one or more tank separators are positioned within one or both of the anolyte tank and the catholyte tank; and the one or more tank separators are translatable in a downward direction to induce electrolyte flow from one or both of the lower anolyte opening and the lower catholyte opening through the one or more turbines to hydroelectrically generate power. 2 . The hybrid flow redox battery system of claim 1 , wherein: the one or more tank separators comprise an anolyte tank separator positioned within the anolyte tank and a catholyte tank separator positioned within the catholyte tank; the anolyte tank separator is positioned within the anolyte tank such that the anolyte tank separator separates a charged anolyte active material from a discharged anolyte active material; and the catholyte tank separator is positioned within the catholyte tank such that the catholyte tank separator separates a charged catholyte active material from a discharged catholyte active material. 3 . The hybrid flow redox battery system of claim 1 , wherein the one or more tank separators each comprise a density of from 1 ton/m 3 to 5 tons/m 3 and a weight of from 1 ton to 400 tons. 4 . The hybrid flow redox battery system of claim 1 , further comprising one or more valves fluidly coupled to one or more of the plurality of electrolyte pathways, wherein: each of the one or more valves are actuatable between an open position and a closed position; the open position allows electrolyte passage through the one or more valves; and the closed position prevents electrolyte passage through the one or more valves. 5 . The hybrid flow redox battery system of claim 1 , wherein: the one or more turbines are electrically coupled to one or more turbine generators; and electrolyte flow from one or both of the lower anolyte opening and the lower catholyte opening through the one or more turbines rotates the one or more turbines to generate an electrical current that is receivable by the one or more turbine generators to hydroelectrically generate power. 6 . The hybrid flow redox battery system of claim 1 , wherein the plurality of electrolyte pathways comprise: a lower anolyte pathway extending between and fluidly coupling the lower anolyte opening and the anode; an upper anolyte pathway extending between and fluidly coupling the upper anolyte opening and the anode; a lower catholyte pathway extending between and fluidly coupling the lower catholyte opening and the cathode; and an upper catholyte pathway extending between and fluidly coupled the upper catholyte opening and the cathode. 7 . The hybrid flow redox battery system of claim 6 , wherein: the lower anolyte opening comprises a first lower anolyte opening; the anolyte tank further comprises a second lower anolyte opening positioned below the upper anolyte opening and fluidly coupled to the lower anolyte pathway; the lower anolyte pathway comprises a primary branch extending between the first lower anolyte opening and the anode; the lower anolyte pathway comprises a secondary branch extending between the second lower anolyte opening and the primary branch of the lower anolyte pathway; and the one or more turbines comprise an anolyte side turbine fluidly coupled to the secondary branch of the lower anolyte pathway. 8 . The hybrid flow redox battery system of claim 7 , further comprising: a first anolyte valve fluidly coupled to the primary branch of the lower anolyte pathway between the first lower anolyte opening and an anolyte pathway convergence location of the primary branch and the secondary branch of the lower anolyte pathway; a second anolyte valve fluidly coupled to the secondary branch between the second lower anolyte opening and the anolyte side turbine; and a third anolyte valve fluidly coupled to the secondary branch between the anolyte pathway convergence location and the anolyte side turbine. 9 . The hybrid flow redox battery system of claim 8 , wherein: each of the first, second, and third anolyte valves are actuatable between a closed position and an open position; when the first anolyte valve is in the open position and the second and third anolyte valves are each in the closed position, electrolyte flow through the anolyte side turbine is impeded and; when the first anolyte valve is in the closed position and the second and third anolyte valves are each in the open position, electrolyte flow through the anolyte side turbine is not impeded. 10 . The hybrid flow redox battery system of claim 6 , wherein: the lower catholyte opening comprises a first lower catholyte opening; the catholyte tank further comprises a second lower catholyte opening positioned below the upper catholyte opening and fluidly coupled to the lower catholyte pathway; the lower catholyte pathway comprises a primary branch extending between the first lower catholyte opening and the cathode; the lower catholyte pathway comprises a secondary branch extending between the second lower catholyte opening and the primary branch; and the one or more turbines comprise a catholyte side turbine fluidly coupled to the secondary branch of the lower catholyte pathway. 11 . The hybrid flow redox battery system of claim 10 , further comprising: a first catholyte valve fluidly coupled to the primary branch of the lower catholyte pathway between the first lower catholyte opening and a catholyte pathway convergence location of the primary branch and the secondary branch of the lower catholyte pathway; a second catholyte valve fluidly coupled to the secondary branch between the second lower catholyte opening and the catholyte side turbine; and a third catholyte valve fluidly coupled to the secondary branch between the catholyte pathway convergence location and the catholyte side turbine. 12 . The hybrid flow redox battery system of claim 11 , wherein: each of the first, second, and third catholyte valves are actuatable between a closed position and an open position; when the first catholyte valve is in the open position and the second and third catholyte valves are each in the closed position, electrolyte flow through the catholyte side turbine is impeded and; when the first catholyte valve is in the closed position and the second and third catholyte valves are each in the open position, electrolyte flow through the