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| Quasi-passive variable pressure regenerative fuel cell system |
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| Hollow artery anode wick for passive variable pressure regenerative fuel cells |
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| One piece fuel cell separator plate |
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| Planar fuel cell |
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| Emulsion producing apparatus and its combustion system |
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| Fuel cell cooled by latent heat of water evaporation |
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| Apparatus for manufacturing cellulosic fibrous material which can be pressed into molded parts |
| We claim: 1. An apparatus for manufacturing a dry-shaped cellulosic fibrous transportable mat ... |
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| Resin material supply apparatus for resin press molding machine |
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Bipolar separator for electrochemical cells and method of preparation thereof
| Details |
Inventors: Pellegri, Alberto; Spaziante, Placido M.;
Assignee: Oronzio deNora Impianti Elettrochimici S.p.A. (Milan, IT)
Primary Examiner: Mack; John H.
Assistant Examiner: Valentine; D. R.
Attorney, Agent or Firm: Hammond & Littell, Weissenberger and Muserlian
An improved bipolar separator for electrochemical cells comprising a molded aggregate of an electrically conductive powdered material and a powdered thermosetting resin in a weight ratio of 1:1 to 9:1 and having a resistivity coefficient, in the direction perpendicular to the major surfaces of the separator, of less than 0.3.OMEGA. cm and having the entire surface exposed to the anolyte, except the area of electrical contact with the anode, coated with a layer of a chemically resistant and electrically non-conductive thermosetting resin and electrochemical cells containing the said bipolar separator and method of producing the said bipolar separator. |
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DETAILED DESCRIPTION We claim: 1.
A bipolar separator for electrochemical cells which separates the adjacent anolyte and catholyte chambers and conducts electrical current from the anode of one cell unit to the cathode of an adjacent cell unit in a bipolar sequence of cell units comprising a molded aggregate of an electrically conductive powdered material and a thermosetting resin in a weight ratio of 1:1 to 9:1 and having a resistivity coefficient, in the direction perpendicular to the major surfaces of the separator, of less than 0.
3.
OMEGA.
cm and having the entire surface to be exposed to the anolyte, except to the area to be in electrical contact with the anode, coated with a layer of a chemically resistant and electrically non-conductive thermosetting resin.
2.
The bipolar separator of claim 1 wherein the thermosetting resin is a two-component mixture of an epoxy resin and an aromatic amine hardener.
3.
The bipolar separator of claim 1 wherein the powder of electrically conductive material is graphite powder.
4.
The bipolar separator of claim 1 wherein the separator is pressure formed and provided over both its major surfaces with a recessed central zone and a substantially flat peripheral zone, at least four holes within said flat peripheral zone, said four holes being hydraulically connected in pairs respectively to each of the recessed central zones on each of the major surfaces of the separator, projections within said recessed central zones on each of the major surfaces of the separator, said projections constituting the means for establishing the electrical contact between the bipolar separator and the electrodes of the cell.
5.
The bipolar separator of claim 4 wherein the entire surface of the bipolar separator, with the exception of the areas for the electrical contact with the electrodes of the cell, are coated with a layer of electrically insulating thermosetting resin and the areas of electrical contact with the electrodes of the cell are coated with a layer of a non-passivable metal belonging to the platinum group
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Nonmetallic Processes 
