EP0382789A1 - Catalytic recombination of corrosion evolved hydrogen in alkaline cells - Google Patents

Abstract

In rechargeable or primary electrochemical cells, hydrogen can be released. The present invention relates to the use of an auxiliary electrode material used to catalyze the combination of pressurized hydrogen, such as hydrogen subjected to pressures ranging from 5 to 15 psig until the pressure is released. of the accumulator. The accumulator consists of a sealed accumulator comprising a metal oxide cathode (12), a zinc anode (14) and an aqueous alkaline electrolyte in contact with the anode and the cathode. The auxiliary electrode material, which can be mixed with the cathode material or which can be formed into a separate auxiliary cathode (28), includes a porous substrate for absorption of pressurized hydrogen by the electrolyte . The substrate can be made of carbon, graphite or metal. The catalyst can be constituted by carbon, by catalytically active noble metals, by salts or oxides of lead, nickel, titanium, lanthanum, chromium, tantalum and by alloys of these metals or by mixtures of carbon with salts or oxides.

Description

  
 



     CATALYTIC      RECOMBINATION    OF CORROSION EVOLVED
 HYDROGEN IN   ASULINE    CELLS
FIELD OF THE INVENTION:
 This invention relates to rechargeable, alkaline, sealed cells such as alkaline zinc/manganese dioxide cells.



  In particular, the invention relates to porous electrodes which may be used as fuel cell cathodes, wherein a   catalyst    for the re-absorbtion of hydrogen is used with a porous conductive substrate. The invention aims to provide means of recombining hydrogen, which may be evolved during storage, recharging or even in use, with the active mass of electrolyte. Thus loss of water may be avoided and the risk of pressure build up within the cell may be reduced.



  BACKGROUND OF THE INVENTION:
 The prior art has concerned itself, for many years, with the problem of reducing or eliminating the loss of water in galvanic cells using aqueous electrolyte and avoiding build up of excessive gas pressure in sealed cells. Hydrogen gas is evolved during charge or standby by several electrode materials as aluminum, magnesium, zinc, iron, lead etc. The electrodes in general do not have the capability of recombining the hydrogen and the evolved gas is usually vented, causing water loss or pressure build up in hermetically sealed cells. In sealed cells, depending on the amount of hydrogen present and the rate of generation, excessive gas pressure can build up causing rupture of the safety vent and loss of   electrolyte    -- resulting in cell failure and   electrolyte    leakage.

  It has previously been found   that    cells having a porous manganese dioxide cathode have the capability of recombining the hydrogen, provided  catalytically active materials are applied to the cathode electrode.



   Two approaches are often used in efforts to solve the problems. These are: 1. Catalytic recombination of hydrogen and oxygen inside or outside the   battery;    in the latter case, provisions are made for the return of the product water to the electrolyte chamber -  [ U.S. 3,630,778 (1971), U.S.



  3,598,653 (1971), U.S. 3,622,398 (1971), U.S. 3,701,691 (1972)1.



  2. Use of an auxiliary (third) electrode as an overcharge recombination reactor as described in "Electrochem. Technol., 4, 383 (1966) by P.   Ruetschi    and
J.B. Ockerman.



   In fact,   KORDESCE      et    al in United States   Patent   
No. 4,224,384 report excellent hydrogen gas absorption capability of dry MnO powder catalyzed with salts or
 2 oxides of platinum, palladium, ruthenium, rhodium, arsenic and lead. These materials, however, when employed in a   wetted    MnO matrix, did not show significant hydrogen
 2 recombination rates at near atmospheric pressures. It has now surprisingly been found that these materials exhibit hydrogen recombination properties provided the gas pressure is increased, for example, in the range of 5 to 15 psig or up to the relief pressure of the cell. Catalytically active carbon bonded with PTFE is also useful.



   According to the invention there is provided a rechargeable electrochemical sealed cell having a cathode,  a zinc anode, and an aqueous, alkaline electrolyte contacting the anode and the cathode, in which cell hydrogen may evolve. The cathode comprises a metal oxide and auxiliary cathode material comprising a porous   substrate    and a catalyst for the absorption of pressurized hydrogen by the electrolyte, the auxiliary cathode material being located to be at least partially wetted by the electrolyte.



   The substrate may be carbon, graphite or metal, and the catalyst may be carbon, catalytically active noble metals, salts and oxides of lead, nickel, titanium, lanthanum, chromium, tantalum, and alloys thereof, and the noble metals or mixtures of carbon with the noble metals salts or oxides. The noble metals may be, for example, platinum, palladium, ruthenium, rhodium or silver.



   The auxiliary cathode material may be provided either in admixture with the metal oxide cathode, suitably in a ratio of 30:70 respectively, or as a discrete auxiliary electrode in electronic   contact    with the metal oxide cathode.



   When the auxiliary cathode material is provided as an auxiliary discrete electrode and the metal oxide cathode is cylindrically located about an anode core, then the auxiliary electrode is suitably an annulus or disk of similar diameter to the metal oxide electrode and located in electronic contact with it at one end of the anode.



   The present invention may provide economic and effective means of removing hydrogen oxygen gas in galvanic  cells. Noble metals such as platinum, palladium, rhodium, iridium, ruthenium, and osmium show high   catalytic    activity for hydrogen oxidation. In alkaline electrolytes, nickel and alloys of nickel with other metals (e.g.   titanium    and lanthanum) were found to be active catalysts. Gas diffusion electrodes applicable to the present invention are described in the Canadian   Patent    Disclosure "Metal and
Metal Oxide Catalyzed Electrodes for Electrochemical
Cells, and Method of Making Same" by K. Tomantschger and K.



  Kordesch, and can be employed if higher recombination current densities are desired.



   Embodiments of the invention will now be described by way of illustration with reference to the drawings in conjunction with the Examples, describing various electrodes of the invention and their operating characteristics.



  BRIEF DESCRIPTION OF THE DRAWINGS:
 Figure 1 is a vertical cross section of one embodiment of the invention;
 Figure 2 is a vertical cross section of another embodiment of the invention;
 Figure 3 is a graph comparing the operating characteristics of prior art and inventive cells as described in Example 2;
 Figures 4 and 5 is a graph illustrating the operating   characteristics    of prior art and inventive cells as described in Example 3.  



  DESCRIPTION OF PREFERRED EMBODIMENTS:
 Figures 1 and 2 of the drawings show two different embodiments of cells according to the invention. In both cases the cell comprises a steel can 10 housing a conventional metal oxide cathode 12. The base of can 10 has boss 11 forming the cathode contact formed cylindrically around anode 14. The cathode 12 may comprise finely divided manganese dioxide and graphite, and is separated from anode 14 which may comprise zinc powder, by an electrolyte permeable separator 16. The electrolyze, which may be aqueous potassium hydroxide, permeates the zinc powder of anode 14 and cathode 12 through separator 16.



   As shown, the anode is confined by a basket 18, made for example, of   Chicopee    Rayon/polyvinyl   acetate.    The basket 18 may be used to also carry an oxygen   re-absorbtion      catalyst,    if used. The oxygen re-absorbtion   catalyst    may be, for example, as described in copending application in the names of TOMANTSCHGER and KORDESCH. The basket 18 is provided with an end cap 20, for example of brass, insulated from the base of can 10 by insulating disk 15.



   The cathode 12 is confined into cylindrical shape by screen 22 and annular plastic cap 23.



   A current collector nail 24 projects into the anode 14 through a casing cover 25, with its head 26 being outside of the cover 25 to form the anode   contact.    The cover 25 seals the can 12 by crimping formed around its edge.



   Figure 1 shows an auxiliary discrete cathode disk  28 formed of catalytically active carbon and located on the   bottom    of can 10 below insulating disk 15.



   The auxiliary cathode disk 28 is in physical and electronic contact with cathode 12, and is wetted by   electrolyte    dispersed in the can 10.



   The embodiment of Figure 2 differs from   that    of
Figure 1 in that, in place of auxiliary cathode disk 28, an auxiliary cathode annulus 30 is placed beneath annular plastic cap 23. The auxiliary cathode annulus may, for example, comprise silver oxide, and is in physical and electronic contact with cathode 12.   It,    too, is wetted by electrolyte dispersed in the can 10.



   Figures 1 and 2 both show embodiments in which discrete auxiliary cathodes are used. When the auxiliary cathode material is mixed with the metal oxide cathode, then the inventive cell may be as described with reference to either Figures 1 or 2, but neither disk 28 nor annulus 30 would be present, and the cathode 12 incorporates the auxiliary material.



  Example I:
 A conventional rechargeable MnO -Zn cell as
 2 disclosed in U.S. 4,384,029 was prepared using a metal cage to confine the cathode active mass. The cathode mix was formed, pressed in rings, and thereafter three rings were placed in D-cell cans containing a metal case, and separator baskets   (Chicopee!    Rayon PVA)   were inserted    in the center.  



  CATHODE COMPOSITION:
 90.0 parts 84.1% EMD   TRONA"D"   
 9.5   pts    8.9% Lonza KS-44 Graphite
 7.0   pts    6.5% 9 N KOH
 0.5   pts    0.5% Acetylene Black
 Total weight:   87.5g   
   Catalytically    active cathode blends were prepared   substituting    3, 12, 20 and 30% of the EMD weight by Ag   0   
 2 and D-size test cells were fabricated incorporating a 4 g
Ag 0 rich cathode material in the pip area of the cell.



   2
 A gelled zinc anode was extruded into the center, thereafter the cell was sealed using a polyethylene disk with a brass nail current collector incorporated therein and cell closure was achieved by crimping.



  ANODE COMPOSITION:
 61.4% 3% Hg New Jersey 1205 Zn
   2.0%    ZnO
 1.0% MgO
 0.8% 70/30 CMC/940
   34.8%    9 N KOH 8% ZnO
 Total Weight: 21g
 To demonstrate the capability of the present invention in terms of hydrogen recombination, the series of
D cells containing the 3, 12, 20 and 30%   substituted    EMD was   submitted    to storage test at 65 C. The elevated temperature caused appreciable Zn gassing producing hydrogen overpressure in the cells.

  The   test    results are indicated in the following table:
 3% Ag 0 12% Ag 0 20 % Ag 0 30% A   0   
 2 2 2 g 1 wk @ 65 C 6/6 OK 6/6 OK 6/6 OK 6/6 OK 2 wk @ 65 C 3/4 OK 2/4 OK 3/4 OK 4/4 OK 3 wk @ 65 C 1/1 OK   0    1/1 OK 2/2 OK
 Typical   0%    Ag 0 control cells exhibit a failure
 2  rate of 50% after 2 weeks at 65 C, (in this case failure means cell leakage; while all the substituted cells showed improvement and the 30%   substituted    cells showed no failures.



  Example II:
 A conventional porous MnO cathode as used in
 2 primary alkaline or rechargeable alkaline MnO -Zn cells was
 2 formed, pressed in rings, and thereafter three rings were placed in C-cell cans containing a metal case to confine the cathode mass, and separator baskets   (Chicopeeo   
Rayon/PVA) placed in the center of a C-cell (Figure 2).



  CATHODE COMPOSITION:
 84.1% EMD TRONA"D"
 8.9% Lonza KS-44 Graphite
 6.5% 9 N KOH
 0.5% Acetylene Black
 Total Weight: 37.5g
 Catalytically active cathode blends were prepared substituting 0 and   308    of the EMD weight by Ag 0 and C-size
 2 test cells were fabricated incorporating a 4 g Ag 0 rich
 2 cathode ring on the open end of the cell.



   To demonstrate the capability of the present invention in terms of hydrogen recombination, two half cells of the C-cell size were fabricated, one with and one   without    the catalytically active cathode ring. Both open cells were placed vertically in a tube, the negative electrode void was filled with 9 N KOH to the height of the polyethylene spacer, a spirally wound Ni wire was  submersed into the electrolyte, and the cells were   galvanostatically    discharged at 50 mA for 20 hours removing 1 Ah stored energy from the positive electrodes   (total    capacity appr. 8 Ah). Cell tops were used to close the elements, and contained tube   fittings      attached    to U tubes filled with water by means of flexible tubing.

  After crimping the cells were gas   tight,    and any pressure change was indicated by the   manometers.   



   Both cells were   galvanostatically    charged with 10 and 25 mA to a pressure of 300 mm water. Neither cell showed significant hydrogen recombination at atmospheric pressure.



   Thereafter, the U tube was replaced by precision manometers (total gas space 2.0 ml NTP), and both cells were   galvanostatically    charged with 50 mA at room temperature until the pressure inside the cell reached 30 psig. The positive electrode reaction involves conversion of MnO(OH) to MnO , and the counter reaction involves
 2 2 hydrogen generation on the surface of the Ni spiral wire inserted into the negative electrode cavity. Hydrogen gas was evolved at a rate of 20 ml per hour   (at    50 mA). The results are summarized in Figure 3.



   Figure 3 shows the pressure build-up of hydrogen with time, and shows that pressure builds up faster in the conventional cell (curve A) than in the cell employing Ag   0   
 2   material.    Thus, it can be seen that the cell containing the catalytically active disk possessed a significant hydrogen recombination rate. Furthermore, after the power  supply was disconnected, the pressure in the cell containing the active   catalyst    decreased significantly faster than the pressure in the control cell.



  Example III:
 A conventional porous MnO cathode as used in
 2 primary alkaline or rechargeable alkaline MnO -Zn cells was
 2 formed, pressed in rings, and thereafter three rings were placed in C-cell cans containing a metal case to confine the cathode mass, and separator baskets (Chicopee
Rayon/PVA) were placed in the center of a C-cell (Figure   2).   



  CATHODE COMPOSITION:
 84.1% EMD TRONA"D"
 8.9% Lonza KS-44 Graphite
 6.5% 9 N KOH
   0.5%    Acetylene Black
 Total Weight: 37.5g
 A gas diffusion electrode, employing a mixture of
Pd/Rh as hydrogen   re-absorbtion    catalyst, was prepared and incorporated into a 400 micron layer comprising a mixture of carbon available commercially as "Black Pearls   2000    and PTFE to form a foil. As additional option a separator sheet   (Dexcerb    C1235) can be pressed in one side and a Ni screen into the other side of the carbon/PTFE layer comprising 70% carbon and   308    PTFE. A ring with an outer diameter of 25 mm and an inner diameter of 14 mm was punched out of the foil and the carbon ring placed on the top of the cathode with the separator side facing the cathode.

   After the placement of a perforated polyethylene ring, the assembly was pushed onto the cathode sleeve.  



   The function of the separator disk is to soak up electrolyte assisting in partial   wetting    of the carbon disk and providing ionic contact between hydrogen and the MnO
 2 electrode. The carbon disk maintains electronic contact with the metal can and the metal cage, establishing a "hydrogen-MnO short circuit element".



   2
 To demonstrate hydrogen   re-absorbtion,    two C-size cells were fabricated, one with and one without the catalyzed carbon ring. Both open cells were placed vertically in a tube, the cathode space was filled with 9 N
KOH to the height of the polyethylene spacer, a spirally wound Ni wire was inserted as a counter electrode and the cells were galvanostatically discharged at 50 mA for 20 hours removing 1 Ah of the negative electrodes (total capacity appr. 8 Ah). The cell tops used to close the elements contained tube fittings   attached    to precision manometer (2 ml gas space).



   Both cells were   galvanostatically    charged with 50 mA at room temperature. The positive electrode reaction consisted of oxidation of MnO(CH) to MnO . The counter
 2 2 reaction involved generation of hydrogen on the surface of the Ni wire at a rate of 20 ml hydrogen per hour   (at    50 mA). Figure 4 shows the resulting pressure curves. Curve C represents use in pressure with time for the conventional electrode   without    the catalysed carbon ring.



   The cell containing the catalytically active ring described herein invention recombined the hydrogen generated, maintaining a cell pressure of appr. 6 psig for  over four hours (curve D). During the four hours of overcharge at 50 mA, the 3.5 cm2 disk recombined over 80 ml   NPT    of hydrogen gas by maintaining the pressure.



   A 10 mA current was passed through the cell for 12 hours, then the current increased to 25, 50 and 100 mA in 12 hour intervals. Figure 5 shows   that    over a period of time of 48 hours, over 900 ml hydrogen were generated and the recombination rate maintained the internal cell pressure below 25 psig.



   The maximum hydrogen gas recombination rate was determined to be in excess of 145 ml hydrogen per hour (3.5 cm2 electrode ring area) -- which is equivalent to an hydrogen evolution current of 100 mA. For the C-size cell used, this is significantly more than required under
II   realistic    user   condition   
 To determine the long term electrode performance, the electrode described herein was placed in a half cell and operated continuously at 50 mA/cm2 for over 1000 hours.



   The test was discontinued after consumption of in excess of 20 1 NTP hydrogen. The following table demonstrates the performance obtained in 6 N KOH electrolyte at room   temperature    for hydrogen as reaction gas.



   Time Hydrogen Current IR Free Potential
    [ hrs.i    Consumption   tmA/cm21      tmV    vs.   Zn ]    
  [ 1 ] 
   0      0    50 22
 163 3.4 50 10
   3Q7    6.4 50 25
 475 9.9 50 30
 691 14.3 50 46
 859 17.8 50 47
 1003 20.8 50 49  
 [The IR free potential is determined using laboratory procedures and standards, and is measured in millivolts as against the Reversible Hydrogen Electrode
Reference]. 

Claims

1. A primary or rechargeable electrochemical sealed cell having a cathode, a zinc anode, and an aqueous, alkaline electrolyte contacting the anode and the cathode, in which cell hydrogen may evolve; said cathode comprising a metal oxide and auxiliary cathode material comprising a porous substrate and a catalyst for the absorption of pressurized hydrogen by the electrolyte, the auxiliary cathode material being at least partially wetted by the electrolyte 2. The rechargeable cell of claim 1 in which the catalyst catalyses the absorption of hydrogen pressurized in the range of from 5 to 15 psig up to pressure relief of the cell.

3. The rechargeable cell of claim 2 in which the substrate of the auxiliary cathode is chosen from the group consisting of carbon, graphite and metal and the catalyst is chosen from the group consisting of carbon, catalytically active noble metals, salts and oxides of lead, nickel, titanium, lanthanum, chromium, tantalum, and alloys thereof and said catalytically active metals, and mixtures of carbon with said metals, salts or oxides.

4. The rechargeable cell of claim 2 in which the metal oxide cathode includes MnO and the catalytically 2 active metal is a noble metal.

5. The rechargeable cell of claim 3, in which the noble metal is selected from platinum, palladium, ruthenium, rhodium, iridium, osmium and silver.

6. The rechargeable cell of claim 2 in which the cathode includes MnO and the catalytically active metal is 2 nickel or an alloy of nickel with lanthanum or titanium.

7. The rechargeable cell of claim 3, in which the auxiliary cathode material is mixed with the metal oxide.

8. The rechargeable cell of claim 4, in which the ratio of lead oxide or noble metal oxide to said metal oxide in the cathode is substantially 30:70.

9. The rechargeable cell of claim 3, in which the electrode is auxiliary cathode material is formed as a discrete electrode in electronic contact with the metal oxide cathode.

10. The rechargeable cell of claim 6, in which the discrete electrode is an annulus formed of carbon mixed with palladium and rhodium, and is located on top of the metal oxide.

11. The rechargeable cell of claim 1, in which the metal oxide comprises MnO and is mixed with 5 to 20% by 2 weight of graphite.

12. The rechargeable cell of claim 1, in which the metal oxide cathode comprises MnO and is mixed with 10 to 2 208 NiO 2 13. The rechargeable cell of claim 1, in which the metal oxide cathode comprises NiO mixed with 5 to 20% 2 graphite.

14. The rechargeable cell of claim 1, in which the anode comprises zinc powder immobilized in a gel of the electrolyte.

15. The rechargeable cell of claim 1, in which the anode comprises a paste of zinc powder.