US2015236389A1PendingUtilityA1

Hybrid electrochemical cell systems and methods

Assignee: G4 SYNERGETICS INCPriority: Mar 15, 2013Filed: Apr 27, 2015Published: Aug 20, 2015
Est. expiryMar 15, 2033(~6.7 yrs left)· nominal 20-yr term from priority
H01M 16/00Y02E60/10H01G 11/30H01M 10/345H01G 11/04H01G 11/22H01M 10/30Y02P70/50H01G 11/26Y02E60/13
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Claims

Abstract

Disclosed herein are systems, devices, and methods for a hybrid electrochemical cell which utilizes two different chemistries in the same cell. According to one aspect, the hybrid cell includes a first pair of electrode units which form a first electrochemical cell and a second pair of electrode units, which form a second electrochemical cell. The second electrochemical cell utilizes a different chemistry than the first electrochemical cells, but both chemistries share a common electrolyte. The hybrid cell further comprises a common electrolyte layer provided between each pair of electrodes. In certain implementations, the common electrolyte layer is a single cavity such that the electrolyte is shared between both the first and the second electrochemical cell.

Claims

exact text as granted — not AI-modified
1 . (canceled) 
     
     
         2 . A hybrid energy storage cell comprising:
 a first electrochemical sub-cell comprising a first electrode unit and a second electrode unit, wherein the first electrochemical sub-cell utilizes a first chemical reaction;   a second electrochemical sub-cell comprising a third electrode unit and a fourth electrode unit, wherein the second electrochemical sub-cell utilizes a second chemical reaction that is different than the first chemical reaction;   wherein the first electrode unit and the third electrode unit are mounted on a first substrate, and wherein the second electrode unit and the fourth electrode unit are mounted on a second substrate that is different than the first substrate; and   a common electrolyte layer provided between the first electrochemical sub-cell and the second electrochemical sub-cell, wherein a common electrolyte is shared between the first electrochemical sub-cell and the second electrochemical sub-cell.   
     
     
         3 . The energy storage cell of  claim 2 ,
 wherein the first electrode unit and the third electrode unit are positive electrochemical electrode units, and   wherein the second electrode unit and the fourth electrode unit are negative electrochemical electrode units.   
     
     
         4 . The hybrid energy storage cell of  claim 3 , wherein the positive electrochemical electrode units are electrically isolated by a separator from the negative electrochemical electrode units. 
     
     
         5 . The hybrid energy storage cell of  claim 2 , wherein the first electrochemical sub-cell and the second electrochemical sub-cell are contained in a single package, and wherein the common electrolyte layer comprises a single cavity. 
     
     
         6 . The hybrid energy storage device of  claim 2 , wherein the first electrochemical sub-cell and the second electrochemical sub-cell are electrically coupled in series. 
     
     
         7 . The hybrid energy storage device of  claim 2 , wherein the first electrochemical sub-cell and the second electrochemical sub-cell are electrically coupled in parallel. 
     
     
         8 . The hybrid energy storage device of  claim 2 , wherein the first electrochemical sub-cell is configured to operate at a substantially similar voltage range as the second electrochemical sub-cell. 
     
     
         9 . The hybrid energy storage cell of  claim 2 , wherein the second electrochemical sub-cell comprises an electrochemical capacitor, and wherein the first electrochemical sub-cell comprises a nickel-metal hydride electrochemical sub-cell. 
     
     
         10 . The hybrid energy storage cell of  claim 2 , wherein the second electrochemical sub-cell is configured to discharge at a rate greater than the first electrochemical sub-cell. 
     
     
         11 . The hybrid energy storage cell of  claim 2 , wherein the first electrochemical sub-cell is configured to have a greater electrical storage capacity than the second electrochemical sub-cell. 
     
     
         12 . A hybrid energy storage cell comprising:
 a first pair of electrode units forming a nickel-metal hydride electrochemical sub-cell;   a second pair of electrode units forming a capacitor; and   a common electrolyte layer provided between each pair of electrode units, wherein an alkaline electrolyte is shared between the nickel-metal hydride electrochemical sub-cell and the capacitor.   
     
     
         13 . The hybrid energy storage cell of  claim 12 ,
 wherein the first pair of electrode units comprises a first positive electrochemical electrode unit and an adjacent first negative electrochemical electrode unit,   wherein the second pair of electrode units comprises a second positive electrochemical electrode unit and an adjacent second negative electrochemical electrode unit, and   wherein each of the electrochemical electrodes units of the same polarity are electrically coupled together in parallel.   
     
     
         14 . The hybrid energy storage cell of  claim 13 , wherein the positive electrochemical electrode units are electrically isolated by a separator from the negative electrochemical electrode units. 
     
     
         15 . The hybrid energy storage cell of  claim 12 , wherein the nickel-metal hydride electrochemical sub-cell and the capacitor are contained in a single package, and wherein the electrolyte layer comprises a single cavity. 
     
     
         16 . The hybrid energy storage device of  claim 12 , wherein the nickel-metal hydride electrochemical sub-cell and the capacitor are electrically coupled in series. 
     
     
         17 . The hybrid energy storage device of  claim 12 , wherein the nickel-metal hydride electrochemical sub-cell and the capacitor are electrically coupled in parallel. 
     
     
         18 . The hybrid energy storage device of  claim 12 , wherein the nickel-metal hydride electrochemical sub-cell is configured to operate at a substantially similar voltage range as the capacitor. 
     
     
         19 . The hybrid energy storage cell of  claim 12 , wherein the capacitor is configured to discharge at a rate greater than the nickel-metal hydride electrochemical sub-cell. 
     
     
         20 . The hybrid energy storage cell of  claim 12 , wherein the nickel-metal hydride electrochemical sub-cell is configured to have a greater electrical storage capacity than the capacitor.

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