MEMBRANE-ELECTRODE STRUCTURE FOR ELECTROCHEMTCAT. C T.. S
The present invention relates to an improved membrane-electrode structure for use in an ion exchange membrane electrolytic cell. More particularly, the invention is concerned with the use of two or more intermediate layers for the membrane-electrode structure of chlor- alkali electrolyzers to reduce the amount of hydrogen in chlorine and to improve the bonding of the electrode layer to the membrane.
It is known to attain an electrolysis by a so called solid polymer electrolyte type electrolysis of an alkali metal chloride wherein a cation exchange membrane of a fluorinated polymer is bonded with a gas-liquid permeable catalytic anode on one surface and/or a gas-liquid permeable catalytic cathode on the other surface of the membrane.
This prior art electrolytic method is remarkably advantageous as an electrolysis at a lower cell voltage because the electric resistance caused by the electrolyte and the electric resistance caused by bubbles of hydrogen gas and chlorine gas generated in the electrolysis can effectively be decreased. This has been considered to be difficult to attain in the electrolysis with cells of other configurations.
The anode and/or the cathode in this prior art electrolytic cell are bonded on the surface of the ion exchange membrane so as to be partially embedded. The gas and the electrolyte solution are readily permeated so as to remove from the electrode, the gas formed by the electrolysis at the electrode layer contacting the membrane. That is, there are few gas bubbles adhering to the membrane after they are formed. Such a porous electrode is usually made of a thin porous layer which is formed by uniformly mixing particles which act as an anode or a cathode with a binder. It has been found that when an
electrolytic cell having an ion exchange membrane bonded directly to the electrode is used, the anode in the electrolytic cell is brought into contact with hydroxyl ions which migrates back from the cathode compartment. Accordingly, both chlorine resistance and alkaline resistance for anode material are required for this prior method and an expensive material must be used. When the electrode layer is directly bonded to the ion exchange membrane, a gas is formed by the electrode reaction between an electrode and membrane and certain deformation phenomenon of the ion exchange membrane causes the characteristics of the membrane to deteriorate. In such an electrolytic cell, the current collector for the electric supply to the electrode layer which is bonded to the ion exchange membrane, should closely contact the electrode layer. When a firm contact is not obtained, the cell voltage may be increased. Therefore, the cell structure for securely contacting the current collector with the electrode layer according to this reference is disadvantageously complicated.
Additionally, in chlor-alkali electrolyzers where the cathode is directly bound to the membrane there is permeation of hydrogen through the membrane into the anolyte compartment which mixes with the chlorine. High percentages of hydrogen are then found in the chlorine so as to cause problems in the liquefaction process. Prior means for reducing the hydrogen percentage include 1) the use of a platinum black layer on the anode side of the membrane, and 2) the use of a layer (for example Ag) less electroactive than the electrode layer itself between the membrane and the electrode. These methods have proved to be expensive and ineffective.
Perfluoro membranes which are used as membranes for electrolysis reactions usually have fairly low water contents. As compared with conventional ion exchangers with same amount of water contents, the conductivity of the perfluoro membranes are abnormally high. This is because of phase separation existing in the perfluoro ionic membranes. The phase separation greatly reduces the tortuosity for sodium ion diffusion. The hydrogen diffusion path is the aqueous ionic region and the amorphous fluorocarbon region. Therefore, the tortuorsity experienced by the hydrogen molecules is also low for the phase-
segregated fluorocarbon membranes as compared with conventional hydrocarbon ionic membranes.
The phase-segregation characteristics of the fluorocarbon membranes provides the high migration rates for sodium ions. Thus, relatively lower ionic resistivity is also the cause for the high hydrogen diffusion rates and the resulting high percentage of hydrogen in chlorine. Moreover, the high permeation rate of hydrogen is even more enhanced by the high solubility of hydrogen in the fluorocarbon membranes because of the hydrophobic interaction between hydrogen molecules and the fluorocarbon chains. Therefore, reducing hydrogen permeation rates by increasing the thickness of the membranes or modifying the structure of the membranes would not be very effective because the sodium migration rate would be reduced as one tries to reduce the hydrogen diffusion rate; and the tortuosity effect is difficult to introduce because of the phase separation.
A retardation layer is defined as a layer between the electrode layer and the membrane to retard hydrogen permeation. Any kind of layer can have a certain effect to retard hydrogen permeation as long as it is (1) inactive for electrolytic hydrogen generation, and (2) flooded. The latter requirement is also important for low resistance (that is, lower voltage and good performance) . With these considerations a layer of blend of inert solid particles (usually inorganic) and binders (usually organic) would serve the purpose best. The need for a binder is obvious: the binder can (1) bind the components in the retardation layer together and also (2) provide the necessary adhesion between the retardation layer and the electrode layer and that between the retardation layer and the membrane. The function of the solid particles is also two fold: (1) providing the physical strength to the retardation layer so that there is very limited interpenetration between different layers during fabrication, and (2) forming an agglomerate with the binder.
The reason that the retardation layer is better than the membrane itself in retarding hydrogen permeation is because (1) it allows hydroxidions and sodium ions to migrate at a faster rate so relatively small voltage penalty has to be paid. On the other hand, in the membrane, sodium ion diffusion is slowed down by the coulombic
interaction exerted by the sulfonate or carboxylate groups. The situation is even worse when the membrane is immersed in strong caustic solution as in the chlor-alkali membrane. This is particularly severe for the carboxylic membranes. Ion pairing between sodium ion and carboxylate groups and hydroxide ions is believed to be the cause for the very slow diffusion rate when membrane dehydration occurs under this condition. The solubility of hydrogen is much lower in caustic solution than in the membrane, so the permeation rate (the product of diffusion coefficient and solubility) of hydrogen can be reduced by a larger factor compared with that of the sodium and hydroxide ions. By introducing the blend of inorganic particles and binder and with the necessary morphology, the resistance of the caustic solution is increased. The ratio of the resistivity of the porous medium saturated with electrolyte, Rp, to the bulk resistivity of the same electrolyte solution, Rj-, is commonly called "formation resistivity factor",
F = R
p/R
b = X/O This equation describes the relationship between F and "electric tortuosity", X, and O, the porosity. X is different from hydraulic tortuosity which takes into account the fact the effective path length experienced the diffusing species is increased by the presence of impermeable blocking materials. On the other hand, X also takes into account the special effects due to convergent-divergent nature of the capillaries, called constrictedness, besides the hydraulic tortuosity. Since conductivity is proportional to diffusion rate of the ionic species, formation resistivity factor is also related to diffusion rate in the porous medium, D
p, and the diffusion rate in the bulk electrolyte, D
j-,, by the following equation:
The present invention provides a membrane-electrode structure for use on electrolytic cell, particularly a chlor-alkali cell. The membrane-electrode structure comprises an ion exchange membrane with an electrode layer and a barrier between the membrane and the electrode layer. The barrier (that is, the retardation layer) comprises at least two layers or zones formed from a blend of inorganic particles and an organic thermoplastic polymeric binder
having a melting point of 230°F to 450°F (110 to 232°C) . The first retardation layer is adjacent to the membrane and is an inorganic particle rich layer, namely, having more than 50 percent by weight of inorganic solid particles. The second barrier layer or zone is adjacent the first barrier layer and is an inorganic particle poor layer, namely, having 50 percent by weight or less of inorganic solid particles.
Advantageously the barrier layers have decreasing amounts of inorganic particles as they near the electrode layer so as to provide better bonding with the electrode layer.
Advantageously, a barrier layer or coating is provided adjacent to the electrode layer which is free of inorganic particles to prevent contact of inorganic particles with the catalyst material.
Preferably, the barrier layer adjacent to the membrane comprises 65 percent to 75 percent by weight inorganic particles. Even more preferably, 70 percent by weight of inorganic particles and 30 percent polymeric binder.
As described above, the function of the retardation layer is to provide porosity and tortuosity to impede hydrogen diffusion. Generally, a retardation layer with porosity in the range of 5 percent to 90 percent is prepared, it is preferable to have a porosity in the range of 20 percent to 60 percent, more preferably, in the range of 30 percent to 50 percent.
Advantageously, the tortuosity/porosity ratio is in the range of 2-500, preferably in the range of 5-100, and more preferably in the range of 10-50.
Preferably, the second retardation layer comprises 50 percent by weight of inorganic particles and 50 percent by weight of polymeric binder. The retardation layers are formed utilizing a blend of inorganic particles and organic particles. The inorganic particles has a size of 0.1 to 1.0 microns, preferably 0.2 to 0.4 microns. The organic binder is 0.1 to 5 microns.
The inorganic solid particles comprise one or more of the borides, carbides and nitrides of metals of Groups IIIB, IVA, IV B, VB and VI B of the Periodic Table. Typical examples of suitable materials include Sic, YC, VC, Tie, BC, TiB, HfB, BV2, NbB2 MOB2, W2B,
VN, Si3N4, Ziθ , NbN, BN and TiB. Preferably, silicon carbide is used.
It is understood that the term "retardation layers" is meant to include laminates and as well as an interpenetration polymer network compositions having zones of the inorganic particles.
The binder which is used in the invention preferably comprises a perfluorinated ion exchange polymers which can be used alone or blended with a non-ionic thermoplastic binders. The preferred polymers are copolymers of the following monomer I with monomer II. Monomer I is represented by the general formula: CF2=CZZ' (I) where;
Z and Z' are independently selected from the group consisting of -H, -Cl, -F, or -CF3. Monomer II consists of one or more monomers selected from compounds represented by the general formula;
Y-(CF2)a-(CFRf)b-(CFRf)c-0-[CF(CF2X)-CF2-0]n-CF=CF2 (II) where; Y is -S02Z Z is -I, -Br, -Cl, -F, -OR, or -NR1R2;
R is a branched or linear alkyl radical having from 1 to 10 carbon atoms or an aryl radical;
Rj and R2 are independently selected from the group consisting of -H, a branched or linear alkyl radical having from 1 to 10 carbon atoms or an aryl radical; a is 0-6; b is 0-6; c is 0 or 1; provided a+b+c is not equal to O; X is -Cl, -Br, -F, or mixtures thereof when n>l; n is O to 6; and
Rf and Rf are independently selected from the group consisting of -F, -Cl, perfluoroalkyl radicals having from 1 to 10 carbon atoms and fluorochloroalkyl radicals having from 1 to 10 carbon atoms. It is therefore an object of the invention to provide a membrane-electrode structure for use in an electrolysis cell which
provides improved adhesion of the electrode layer.
It is a further object of the invention to provide a membrane- electrode structure for use in a chlor-alkali cell which will reduce the amount of hydrogen in the chlorine. Other objects and a fuller understanding of the invention will be had by referring to the following description and claims taken in conjunction with the accompanying drawing.
Fig. 1 is a cross-sectional view of a prior art membrane- electrode structure with a retardation layer; Fig. 2 is a cross-sectional view of a membrane-electrode structure of the invention, and
Fig. 3 is a cross-sectional view of a further embodiment of the invention.
Although specific terms are used in the following description for the sake of clarity, these terms are intended to refer only to the particular structure of the invention selected for illustration in the drawings, and are not intended to define or limit the scope of the invention.
As shown in Fig. 1, the prior art has provided a membrane- electrode structure 10 wherein at least one electrode layer 11 is formed on an ion exchange membrane 13 with an intermediate porous non- electrode layer 12. The non-electrode layer 12 is formed with inorganic particles 17 and a binder of a fluorinated polymer.
Fig. 2 illustrates a membrane-electrode structure 20 of the invention. The structure 20 is formed by an ion exchange membrane 13 which has bonded to it a layer 15 of thermoplastic polymeric material and inorganic particles which comprises an inorganic particle rich layer 1, and a layer 14 of thermoplastic polymeric material and inorganic particles which comprises an inorganic particle poor layer. Bonded to the inorganic particle poor layer 14 is a catalyst layer 11 comprising catalyst material 16 and a binder. The separate layers 14,15 are generally 0.3 to 1.5 mils (0.0076 to 0.0381 mm) in thickness, preferably 0.4 mil (0.0102 mm).
Fig. 3 illustrates a further embodiment of the invention wherein a membrane-electrode structure 25 is provided with a retardation layer comprising three layers or zones of decreasing amounts of inorganic
particles as the layer is closer to the electrode layer. The structure 25 is provided with an ion exchange membrane 13 having adjacent to it a retardation layer 15 comprising the inorganic particles 17 and a polymeric binder. Layer 15 is comprised of more than 50 percent by weight of the inorganic particles 17, preferably 65-80 percent. Bonded to the layer 15 is layer 14 which contains a polymeric binder and lower percentage amount of inorganic particles than found in layer 15, namely, 50 percent by weight of inorganic particles. A layer or zone 18, which is free of any inorganic particles, is bonded or formed adjacent to layer 14. The object of layer 18 is to provide a pure binder are a which can help build good adhesion between the electrode layer (which usually has low binder content) and the retardation layer.
The barrier layer 18 is generally sprayed onto layer 14 by placing the polymeric binder in a suitable solvent. The thickness of layer 18 is 0.1 to 0.2 mils (0.0025 to 0.0051 mm). Layers 14 and 15 are each 0.3 to 1.5 mils (0.0076 to 0.0381 mm), preferably 0.4 mils (0.0102 mm) in thickness. In accordance with the present invention, at least one of the electrodes, preferably, the cathode, is bonded to the ion exchange membrane through the retardation layer for use in an electrolytic cell, particularly a chlor-alkali cell.
When the membrane-electrode structure of the invention is used in an electrolytic cell, cell voltage can be reduced in comparison with the electrolysis in a chlor-alkali cell in which the electrode is in direct contact (but not bound to) with membrane such as a zero gap cell.
The barrier composition for preparing the retardation layer is preferably in the form of a suspension of agglomerates of particles and binders having a agglomerate size of 0.1 to 10 microns, preferably 1 to 4 microns. The suspension can be formed with an organic solvent which can be easily removed by evaporation, such as halogenated hydrocarbons, alkanols, •ethers. Preferable is Freon. The suspension may include nonionic thermoplastic binders as well. The suspension can be applied to the ion exchange membrane or its adjacent layer by spraying, brushing, screen-printing.
The retardation layer can be prepared in a single step by continuously spraying onto a membrane. Alternatively, a series of steps can be employed. That is, after the first barrier is formed, the organic solvent is evaporated and the first barrier composition is heat pressed on the membrane by a roller or press at 80 to' 220°C under a pressure of 0.01 to 150 kg/cm2 to bond the layer to the membrane. The next barrier layer is formed and heat pressed on the first barrier layer under the same conditions. The polymer which is applied in a non-hydrolyzed state and is thereafter hydrolyzed. The total barrier is 0.3 to 2 mils (0.0076 to 0.0508 mm) in thickness, preferably 0.4 - 1.0 mils (0.0102 to 0.0254 mm).
The cation exchange membrane on which the porous non-electrode layer is formed, can be made of a polymer having cation exchange groups such as carboxylic acid groups, sulfonic acid groups, phosphoric acid groups and phenolic hydroxy groups. Suitable polymers include copolymers of a vinyl monomer such as tetrafluoroethylene and chlorotrifluoroethylene, and a perfluorovinyl monomer having an ion- exchange group, such as a sulfonic acid group, carboxylic acid group and phosphoric acid group or a reactive group which can be converted into the ion-exchange group. It is also possible to use a membrane of a polymer of trifluoroethylene in which ion-exchange groups, such as sulfonic acid groups, are introduced or a polymer of styrene-divinyl benzene in which sulfonic acid groups are introduced.
The cation exchange membrane is preferably made of a fluorinated polymer having the following units:
(M) (CF2-CXX') (M mole percent) (N) (CFz-CX) (N mole percent)
I
Y-A wherein X represents fluorine, chlorine or hydrogen atom, or -CF3; X' represents X or CF3(CH2)m; m represents an integer of 1 to 5.
The typical examples of Y have the structures bonding A to fluorocarbon group such as
( CF2 )x, -0( CF2 )x, ( 0-CF2-CF )y, I
( 0-CF2 -CF ) x (0-CF2 -CF ) y and
Rf
-0-CF2 ( CF-0-CF2 ) x ( CF2 ) y (CF2 -0-CF ) z
Z Rf x, y and z respectively represent an integer of 1 to 10; Z and Rf represent -F or a C^-C^ perfluoroalkyl group; and A represents -COOM or SO3M, or a functional group which is convertible into -COOM or - SO3M by, hydrolysis or neutralization, such as -CN, -COF, -COOR^, - SO2F and -CONR2R3 or -SO2 R2R3, and M represents hydrogen or an alkali metal atom, and R^ represents a C^-C^Q alkyl group.
It is preferable to use a fluorinated cation exchange membrane having an ion exchange group content of 0.5 to 4.0 miliequivalence/gram dry polymer, especially 0.8 to 2.0 miliequivalence/gram dry polymer, which is made of said copolymer.
In the cation exchange membrane of a copolymer having the units (M) and (N) , the ratio of the units (N) is preferably in a range of 1 to 40 mol percent preferably 3 to 25 mol percent.
The cation exchange membrane used in this invention is not limited to one made of only one kind of the polymer. It is possible to use a laminated membrane made of two kinds of the polymers having lower ion exchange capacity in the cathode side, for example, having a weak acidic ion exchange group such as carboxylic acid group in the cathode side and a strong acidic ion exchange group, such as sulfonic acid group, in the anode side.
The cation exchange membrane used in the present invention can be fabricated by blending a polyolefin, such as polyethylene, polypropylene, preferably a fluorinated polymer, such as polytetrafluoroethylene, and a copolymer of ethylene and
tetrafluoroethylene.
The electrode used in the present invention has a lower over- voltage than that of the material of the porous non-electrode barrier layers. Thus the anode has a lower chlorine over-voltage than that of the porous layer at the anode side and the cathode has a lower hydrogen over-voltage than that of the layer at the cathode side in the case of the electrolysis of alkali metal chloride. The material of the electrode used depends on the material of the retardation layers bonded to the membrane. The anode is usually made of a platinum group metal or alloy, a conductive platinum group metal oxide or a conductive reduced oxide thereof.
The cathode is usually a platinum group metal or alloy, a conductive platinum group metal oxide or an iron group metal or alloy or silver.
The platinum group metal can be Pt, Rh, Ru, Pd, Ir. The cathode is iron, cobalt, nickel, Raney nickel, stabilized Raney nickel, stainless steel, a stainless steel treated by etching with a base.
The preferred cathodic materials for use with the retardation layers of the present invention are Ag and Ru02.
The preferred polymers used as binders in the present invention desirably have a water absorption within a certain desired range. It is possible to tailor the polymer preparation steps in a way to produce a polymer having a water absorption within the desired range. The water absorption is somewhat dependent upon the equivalent weight of the polymer.
The preferred polymers used as binders in the present invention desirably have an equivalent weight within a certain desired range, namely 550 to 1200. It is possible to tailor the polymer preparation steps in a way to produce a polymer having an equivalent weight within the desired range. Equivalent weight is a function of the relative concentration of the reactants in the polymerication reaction.
The preferred polymeric binders of the present invention desirably have a melt viscosity within a certain desired range. It is possible to tailor the polymer preparation steps in a way to produce a polymer having a melt viscosity within the desired range. The melt
viscosity is based upon the concentration of the initiator and by the temperature of the reaction.
The polymer obtained by one of the above process is then hydrolyzed in an appropriate basic solution to convert the nonionic thermoplastic form of the polymer to the ionic functional form which will have ion transport properties. The hydrolysis step is particularly important in the process because during the hydrolysis step the nonfunctional polymer is heated and reacted as shown below during which process, the polymer is softened and swollen with moisture in a controlled manner. Incomplete hydrolysis leaves covalentently bonded functional groups whose lack of mobile ions lead to insulating regions within the membrane. The density of the hydrolysis solution is preferably between 1.26 and 1.28 grams per ml at ambient temperature. The hydrolysis process requires two moles of NaOH for each mole of the functional group in the polymer, as shown in the following equation:
-CF2SO2Z + 2NaOH -> -CF2S03Na + NaZ + H20 where Z is -I, -Br, -Cl, -F, -OR, or -NR1R2; R is a branched or linear alkyl radical having from 1 to 10 carbon atoms or an aryl radical;
R^ and R2 are independently selected from the group consisting of —H, a branched or linear alkyl radical having from 1 to 10 carbon atoms or an aryl radical, preferably phenyl or a lower alkyl substituted phenyl. For hydrolysis, the copolymers are placed in the hydrolysis bath at room temperature, with inert, mesh materials holding the copolymers in the liquid, making sure that there are no trapped bubbles. The bath is then heated from 60°C to 90°C and then held at that temperature for a minimum of four hours to insure complete hydrolysis and expansion to the correct level.
After the hydrolysis heating step, the bath is allowed to cool to room temperature and the polymers are then removed from the bath and rinsed with high purity deionized water, then placed in a deionized water bath to leach out residual ionic substances. When the retardation layer is formed on only one surface of the membrane, namely the cathode side, the electrode placed at the other
side of the ion exchange membrane. The electrodes having an opening, such as a porous plate, gauze or expanded metal, can be placed in contact with the membrane or space can be left between them and the membrane. The present invention will be further illustrated by' certain examples and references which are provided for purposes of illustration only and are not intended to limit the present invention.
Example I
Preparation of Binder This example shows the preparation of a sulfonic fluoropolymer binder having an equivalent weight of 794 and a low shear melt viscosity of 50,000 poise (dyne sec-cm-2) at 250°C and 4.25 sec-1 and a 100°C water absorption of 50 percent.
A 132 liter glass-lined reactor equipped; with an anchor agitator, H-baffle, a platinum resistance temperature device, and a temperature control jacket was charged with 527 grams of ammonium perfluorooctanoate, 398.4 grams of Na2HP047H2θ, 328.8 grams NaH2P04H20 and 210.8 grams of (NH )2S2θ8. The reactor was then evacuated down to 0.0 atmosphere, as measured on the electronic pressure readout, and then an inert gas (nitrogen) was added to pressure up the reactor to a pressure of 448 kPa. This was done a total of 4 times, then the reactor was evacuated one more time. 99 liters of deoxygenated, deionized water was added, the agitator was started and heat was applied to the jacket. An agitator was set to 250 revolutions per minute (rpm) and then 15 ml of a terminating agent such as isopropyl alcohol was added, followed by 16.65 kg of 2-fluorosulfonyl perfluoroethyl vinyl ether was added. When the temperature reached 50° C, tetrafluoroethylene (TFE) gas was fed to the reactor at a rate of from 0.5 to 0.567 kg per minute, until a pressure of 1060 kPa was reached over a period of 17 minutes. The feed was continued until a total of 18.18 kg. of TFE had been added to the reactor. At that time, the feed was stopped and then nitrogen was blown through the gas phase portion of the system and ambient temperature water was added to the reactor jacket. The materials react to form a latex. The latex was transferred to a larger vessel for separation and stripping of residual monomer. After the contents were allowed to settle, a bottom
dump valve was opened to allow separate phase monomer to be drained away. The vessel was then heated and a vacuum was applied to remove any further monomer components. After this, a brine system circulates 20°C brine through cooling coils in the vessel to freeze the latex, causing coagulation into large polymer agglomerates. After freezing was completed, the latex was allowed to thaw with slight warming (room temperature water) and the latex was transferred into a centrifuge where it was filtered and washed repeatedly with deionized water. The latex polymer cake was then dried overnight in a rotary cone dryer under vacuum (969 Pa) at 110°C. The water content of the polymer was tested by Karl Fischer reagent and found to be 140 ppm. The isolated polymer was weighed and found to be 23,18 kg. The equivalent weight of the above polymer was determined to be 794.
The binder can be prepared in either thermoplastic form or ionic form. To prepare it in the thermoplastic form, the dried polymer was dispered in a suitable solvent and attrited to a fine dispersion.
To prepare it in ionic form, the polymer was then hydrolyzed in an approximately 25 weight percent NaOH solution. The density of the hydrolysis solution was between 1.26 and 1.28 grams per ml at ambient temperature. The hydrolysis process consumed two moles of NaOH for each mole of the functional group in the polymer, as shown in the following equation: -CF2SO2F + 2NaOH -> -CF2S03Na + NaF + H2O
The polymers were placed in the hydrolysis bath at room temperature, with inert, mesh materials holding the polymers the liquid-making sure that there were no trapped bubbles. The bath was then heated to 60°C to 90°C and then held at that temperature for a minimum of four hours to insure complete hydrolysis and expansion to the correct level. After the hydrolysis heating step, the bath was allowed to cool to room temperature and the polymers were then removed from the bath and rinsed with high purity deionized water, then placed in a deionized water bath to leach out residual ionic substances. Example 2 Two suspensions of particles of Sic and the copolymer of Example 1 were formed in Freon. One suspension contained a ratio of SiC to
copolymer of 70:30, the other of 50:50. They were prepared by adding Sic powder to an appropriate polymer dispersion prepared in accordance with example 1 and then suitable amounts of solvent was added to adjust the viscosity. The 70:30 suspension was sprayed onto a high performance sulfonic/ carboxylic bilayer ion exchange membrane of Dow to form a layer 0.4 mil (0.0102 mm) in thickness. The second suspension containing a ratio of 50:50 of particles was then sprayed onto the first layer to form a second layer of 0.4 mil (0.0102 mm) in thickness. If desired Teflon particles may be added to each of the suspensions in an amount of 10 percent by weight of total composition. An electrode layer of Ag/Ru02/ binder
(76 percent:10 percent:8 percent) of 1 mil (0.0254 mm) in thickness was then sprayed on tope of the second layer. The three layers and the membrane were then heated at 400°F (204°C) and pressed together at 0.5-1000 PSI.
If desired, an inorganic particle-free layer may be sprayed between the second SiC/binder layer and the electrode layer so as to amount to 0.6 percent by weight of the retardation layer.
The electrode/retardation layer/membrane assembly was then treated to obtain final form for electrolysis. This could involve hydrolysis in an appropriate solution to hydrolyze the membrane and/or the binder (if in thermoplastic form) .