FI77271B - ELEKTROD, ELEKTROKEMISK CELL, BIPOLAR CELL OCH FOERFARANDE FOER FRAMSTAELLNING AV EN ELEKTROD. - Google Patents

Abstract

The invention includes electrodes having a plurality of fibers wherein an essentially continuous metallic coating of high bond strength extends over at least a portion of each fiber, and wherein the fibers provide a large surface area. The electrodes of the invention have an efficient electrical connection at their terminals comprising fiber/metal matrices which provide the desired connections to the terminals without damage to the fibers. The fiber metal matrices also provide excellent electrical contact between all of the fibers, and inhibit wicking of the electrolyte or process stream into the electrical connections. Where the fibers are coated along a substantial portion of their length, they also have a high electrical conductivity. The invention further includes electro-chemical cells, and processes for forming and utilizing the electrodes and cells.

Description

! 77271

Electrode, electrochemical cell, bipolar cell, and method of making the electrode

The present invention is directed to an electrode comprising a plurality of adjacent continuous fibers, each fiber having a thin, firmly attached metal coating on top of it.

The present invention also relates to an electrochemical cell comprising at least one pair of electrodes-10, wherein the electrodes of each pair of electrodes are of opposite sign and at least one of the electrodes of each pair comprises a plurality of adjacent continuous fibers with a thin, firmly attached metal coating on each fiber.

The present invention further relates to a bipolar electrochemical cell and a method of manufacturing an electrode.

The efficiency in electrochemical processes such as electrolysis, electroplating, electro-recovery, electro-organic synthesis, and waste recovery depends to a considerable extent on the electrode surface area. Electrodes have been constructed with bristles or corrugations to increase the surface area. Sandblasting has also been used to roughen the surface of the electrode 25 and to form a large surface area in this way. The effectiveness of these known procedures for increasing the surface area has been found to be limited.

Recently, U.S. Patents 30,046,663, 4,108,754, and 4,108,757 have disclosed carbon fibers for electrodes to provide a large surface area. The electrodes consist of a plurality of carbon fibers that are generally positioned parallel to each other and pressed at one end into an electrical connection. Although the areas of these electrodes can be large, they form a relatively poor electrical connection. A particularly large number of carbon fibers invariably break when the bundle formed by these fibers is pressed into the electrical connection. This breakage of the fibers adversely affects the electrical efficiency of the bundle.

5 In addition, the mechanical connection of the carbon fibers causes an unfavorably high electrical resistance to the connection. Thus, the theoretical efficiency of the electrodes cannot be achieved due to a mechanically breakable and inefficient electrical connection.

The electrodes disclosed in U.S. Patents 4,046,663, 4,046,664, 4,108,754 and 4,108,757 also act like a suction sock, with electrolyte always being absorbed into the region of the connector. As the electrolyte evaporates, salt residues remain which adversely affect the electrical connection. Salt precipitates thermally cover the terminal, causing a rise in heat, an increase in resistance, and possibly damage to the terminal due to bridging. Although absorption and fiber damage could be controlled, there is poor electrical connection to the fibers in the center of the 20 bundles.

Several attempts have been made to place metal coatings on carbon fibers so that the bundles of coated carbon fibers could be used more efficiently as electrodes in various electrochemical processes. In most cases, the coating formed on these carbon fibers has been discontinuous, brittle and expensive to make. For example, U.S. Patent 4,132,828 discloses vacuum deposition of nickel on carbon fibers. However, the coating disclosed in this patent is not in continuous contact with the carbon fibers and breaks easily and falls off when the fiber is bent.

Non-electric (chemical) nickel baths have also been used to coat carbon fibers. However, this coating method is slow, expensive to apply and 3 77271 again results in a poor, discontinuous coating. Other disadvantageously coated fibers are disclosed in U.S. Patent 3,662,283.

In view of the above, it is an object of the present invention to provide fiber-containing electrodes having large surface areas, efficient electrical connections, and having a continuous metal coating having high bond strength to the fibers.

It is a further object of the present invention to provide coated and uncoated fiber electrodes that can be bent, twisted, woven or knitted into a variety of structures for efficient use in electrochemical cells.

The invention further relates to electrochemical cells and to methods for forming electrically conductive fibers into electrodes which do not suffer from the disadvantages of prior art electrodes.

The electrode of the present invention is characterized in that the metal-coated fiber 20 has a connector at the end, and that the electrically conductive metal extends between the metal coatings at the ends of the fibers and connects them to each other and to said connector to form a uniform metal matrix forming an effective electrical connection to the metal-coated fibers. and said connector. The coating is preferably continuous and is attached so well that if the metal-coated fiber is bent, the coating may crack but will not peel off.

The fibers for the electrodes of the invention may be semi-metallic, such as carbon and silicon carbide fibers, or non-conductive, such as nylon, polyester and / or aramid fibers.

If the fibers are semi-metallic, carbon, or silicon carbide, the metal coating can be formed by the method disclosed in U.S. Patent No. 4,771,403. The fibrous coating disclosed in U.S. Patent No. 4,661,403 is continuous and adheres. and flexibility properties have been improved. As a result, it is possible to form fibers coated by the method of U.S. Patent No. 4,661,403 into structures that are useful as electrodes and that have been found inaccessible with prior art metal-coated carbon or silicon carbide fibers. It should be noted, however, that although U.S. Patent No. 4,661,403 discloses a preferred method of coating carbon or silicon carbide fibers, the present invention is not limited thereto.

The method of manufacturing a fiber-containing electrode according to the invention is characterized in that it comprises forming a plurality of continuous-length core fibers; coating at least one end of each core fiber with a substantially flat, firmly attached metal coating; placing an electrical connector in contact with the metal-coated ends of the core fibers, and connecting the metal-coated ends and the electrical connectors together by an electrically conductive metal extending between the ends of the metal-coated fibers to form a unitary fiber / metal matrix providing an efficient electrical connection.

The fibers made according to the above method have a sufficiently high bond strength of the metal to the core to ensure that if the fiber is bent, the coating may crack, but it will not peel off. In addition, in the preferred fibers, the bond strength is more than sufficient to allow the fibers to be knotted without a significant amount, e.g., more than 5% by volume, of the coating coming off and flaking.

If the fibers are non-conductive, for example 5,777,271 nylons, polyesters and / or aramids or the like, they are first made conductive by forming a very thin metallic interlayer as disclosed in FI patent application 842529 and then coated with a metal layer as described in U.S. Pat. No. 4,661 403 is shown.

If the core fibers are semi-metallic or non-metallic, the electrode according to the invention is preferably formed of fibers coated with metal 10 near the electrode connection point to the power supply. The metal coating of the fibers allows the connection to the power supply, for example, by soldering to form a continuous fiber / metal matrix in the vicinity of the electrical connection, avoiding mechanical connections such as crimp connections that damage the fibers and reduce electrode efficiency. In addition, the solder joint and the formed fiber / metal matrix prevent absorption, which has been common in previous mechanical joints in the art and which rapidly degrades the quality of the 20 electrical joints. In addition, the solder joint and the formed fiber / metal matrix enclose all the fibers in the metal, resulting in a low contact resistance in the middle of a bundle of up to 100,000 fibers.

The present electrode can be provided with a metal-25 lip coating only on that part of the fiber bundle which is in the vicinity of the electrical connection. The electrode can also be made of a fiber bundle that is completely coated with metal and from which a portion of the metal coating has then been removed before use as an electrode. In most electrochemical applications, an electrode coated with metal only in the vicinity of the junction preferably acts as an anode.

The present invention further includes a fiber group, wherein each fiber in the group is continuously __-- π. ______ 77271 6 coated with metal along its entire length. These coated fibers form a large surface with high electrical conductivity. They are connected to the power supply, for example by soldering, to form a uniform carbon / metal matrix 5 in the vicinity of the electrical connection. As discussed above, this continuous matrix prevents damage to the fibers and significantly prevents absorption.

An electrode formed by electroplating along the entire length of each fiber is typically used as a cathode.

As a result of the improvement of the fiber coating, as described above and in U.S. Patent No. 4,661,403 and FI Patent Application No. 842529, which publications are incorporated herein by reference, it is possible to design the present fiber electrode into a number of useful structures that have not been achieved to date. In particular, the metal-coated bundle of fibers can be wound around the flow-through support piece, with little or no possibility of the metal coating coming off the fibers. about.

The electrochemical cell according to the invention is characterized by the features set forth in the characterizing part of claim 2.

The bipolar cell according to the invention, in turn, is characterized by the features set forth in the characterizing part of claim 4.

Due to the versatility of the present electrodes, several cell structures and processes are possible. For example, anodes and cathodes arranged around the support pawls 7 77271 may be alternately placed in one or more cells. The electrolyte can then pass through the cells in a manner that ensures maximum contact with the carbon fibers. In one embodiment, each cell 5 may include an anode around the flow-through support and a cathode around the flow-through support. Each such cell can be insulated by a non-conductive barrier wall, each barrier wall having passages for the electrolyte in the form of one or more holes. To achieve the desired vir-10 background pattern, the passageways in the bulkhead may be located alternately at the bottom corner or at the opposite top corner. Holes placed in this way in the barrier layers help to achieve maximum contact of the electrolyte with the electrodes.

15 In another embodiment of the above embodiment, each cell may include a plurality of fibers. . anodes and cathodes wound around flow-through support bodies. Several of these multi-electrode cells can be placed in series using interfaces between the cells, which are designed to ensure maximum electrolyte contact with the electrodes. As previously mentioned, this electrolyte flow pattern can be obtained by alternately placing openings in the barrier walls between the cells at their upper and lower corners.

The present invention also includes other electrochemical cells of varying structures. For example, porous metal plates can be used as cathodes and placed alternately with the anodes shown above. In yet another embodiment, a separation cell can be made in which a small anode such as platinum wire is used in conjunction with a large surface area metal-coated fiber cathode to deposit certain metals on the cathode and other metals remain in solution. In order to guarantee the optimum contact of the electrolyte with the electrodes of the above-mentioned separation cell, the metal-coated fiber cathode can be formed into a cylindrical structure, which cylinder 8807271 is arranged concentrically around the anode. The cylindrical fibrous cathode can be formed either by twisting the fiber bundle helically around a porous cylindrical mold or by weaving a tubular structure from a metal-coated fiber. Another cell of the invention that can be used in oxidation / reduction reactions is a bipolar cell comprising alternately placed anodes and cathodes in a cell containing both solutions, with one of the interconnected electrodes of the present invention being placed in another solution, while one of the interconnected electrodes is placed in the other solution.

In each of the above embodiments, the electrodes of the invention form large areas, efficient electrical connections, and high bond strength between the core fibers and the metal coating thereon.

The following is a detailed description of representative embodiments of the invention with reference to the accompanying drawings. It is to be understood that those skilled in the art will be able to modify and alter the invention within its spirit and scope.

Figure 1 is an elevational view, partly in section, of an electrode according to the present invention comprising a bundle of partially metallized fibers and an associated fiber / metal matrix at its end? Fig. 1a is an enlarged cross-sectional view of Fig. 1 taken along line 1a-1a; Fig. 1b is an enlarged cross-sectional view of Fig. 1 taken along line 1b-1b; Fig. 30 is an enlarged cross-sectional view of Fig. 1 taken along line lc-lc thereof; Fig. 1d is an enlarged cross-sectional view of Fig. 1 taken along line ld-ld? Fig. 2 is an enlarged elevational view, partially in section, of one fiber of the electrode of Fig. 1; Fig. 3 is an elevational view, partly in section, of the electrode of Fig. 1977271 together with a protective tube; Fig. 4 is an elevational view, partly in section, of another electrode according to the present invention comprising a bundle of fully metallized fibers; Fig. 4a is an enlarged cross-sectional view of the electrode of Fig. 4 taken along line 4a-4a; Fig. 4b is an enlarged cross-sectional view of Fig. 4 taken along line 4b-4b; Fig. 4c is an enlarged cross-sectional view 10 of Fig. 4 taken along line 4c-4c; Fig. 5 is an enlarged elevational view, partially in section, of one fiber of the electrode shown in Fig. 4; Fig. 6 is a vertical sectional view, partly in section, of the electrode of Fig. 4 used with a protective tube; Fig. 7 is an exploded perspective view of another embodiment of an electrode according to the present invention with the fiber bundle wound around a flow support body; Fig. 8 is a vertical elevational view, partly in section, of the electrode shown in Figs. Fig. 9 is a side view, partly in section, of the electrode shown in Fig. 7; Fig. 10 is a side view, partly in section, of an electrochemical cell according to the present invention comprising the electrode of Figs. 7-9; Fig. 11 is a perspective view of manifolds used in the electrochemical cell of Fig. 10; Fig. 12 is a perspective view of a flow separator interposed between the electrodes of Fig. 10; Fig. 13 is a schematic diagram of an electrochemical system including an electrochemical cell according to the present invention; Fig. 14 is a plan view of the electrochemical cell of Fig. 13; Fig. 15 is an exploded side view of Fig. 14 taken along line 15-15; Fig. 16 is a cross-sectional view of the representation of Fig. 14 taken along line 16-16 thereof; 77271 ίο Fig. 17 is an elevational view, partially in section, of a discriminating electrochemical cell according to the present invention; Fig. 18 is a perspective view of the cell of Fig. 17; Fig. 19 is a side elevational view, partly in section, of an electrochemical cell according to the invention including a porous plate electrode; Fig. 20 is a perspective view of the porous plate electrode of the cell of Fig. 19; Fig. 21 is a partially side elevational view of a bipolar electrochemical cell according to the present invention; and Fig. 22 is a perspective view of the dividing and active electrode of Fig. 21.

The electrode of the present invention is generally indicated by the number 10 in Figures 1, 1a, 1b, 1e, Id and 2. The electrode 10 is formed of a plurality of fibers 12, each comprising a central fiber, preferably carbon 13, having a diameter of about 7-11 micrometers. and a thin, same-20 central, continuous layer 14 of nickel or other galvanized metal having a thickness of, for example, about 0.5 micrometers. The coated fibers 12 are formed into a bundle 15, which is generally a parallel arrangement of a plurality of metallized fibers 12, for example about 40,000 to 50,000 fibers, with the bundle typically having a diameter of about 3.2 mm. The bundle 15 of the desired length is placed in the electrical connector 15 so that the clamping arms 17 of the electrical connector 16 engage around the other end of the bundle 15. More specifically, the electrical connector. 16 the arms 17 are fastened around the bundle 15 30 with a force sufficient to loosely hold the bundle 15, but it is ensured that the metallized fibers 12 are not damaged. This force exerted by the pressing arms 17 on the 15 is considerably less than the force normally applied if this mechanical connection 35 were to take care of the conduction of electricity.

Once the bundle 15 is attached to the electrical connector 16, the combination of the connector 16 and the bundle 15 of n 77271 is immersed in a molten metal bath, such as a solder bath containing about 60% tin and about 40% lead. The solder 18 is absorbed in the areas between adjacent metallized fibers 12 and in the area between the electrical connector 5 and the metallized fibers 12, thereby actually forming a carbon / metal matrix at the electrode 10 to provide an effective electrically conductive connection between the bundle 15 and the connector 16. The desired absorption of the metallized fibers 12 can be done in seconds, typically 10 in about 10 seconds.

A portion of the metal coating 14 of each fiber away from the connector 16 is then removed, for example, by immersion in a nitric acid bath. More specifically, the metallization 14 is removed leaving a short portion of the metallization 14, 15 extending away from the solder 18. Preferably, the metallization 14 extends 1.25-5 cm from the solder 18, as shown by the dimension "x" in Figure 2. Thus, as shown in Figure 1a, the top portion of the electrode 10 forms a unitary carbon / metal matrix comprising carbon fibers 13, metallization 15, solder 20 18, and stems 17 of connector 16. Slightly farther from connector 16, as shown in Figure Ib, shown, the unitary carbon / metal matrix comprises carbon fiber 13, metallization 14 and solder 18. Further away from the connector, as shown in Figure 1e, electrode 10 comprises carbon fibers 13 and metallization 14 but not solder 18. Metallization 14 of this without solder forms a step resistor for the average electric current from the terminal 16 to the de-metallized fiber 13. This creates a current gradient which prevents the formation of a surge current region which would be affected more rapidly by the electrolyte in contact with it. Finally, as shown in Fig. Id, the rest of the fibers 13 of the electrode 10 are loosely arranged in a bundle 15 without metallization and the electrolyte, as generally indicated by arrow 19, can flow freely between them and maximum contact with the fibers 13 is achieved. These carbon fibers are graphite and generally do not contain amorphous carbon.

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According to Figure 3, the electrode 10 is used in conjunction with a non-conductive shield tube 20 made of plastic or other inert material. The tubes 20 conform loosely over the electrode 10 and generally extend from the connector 16 to the point 5 along the electrode 10, which is located several centimeters below the surface of the electrolyte when the electrode 10 is used. The location of the protective tube 20 corresponds to the fact that the most destructive electrolyte reactions take place in the region immediately below the surface 10 of the electrolyte. The protective tube 20 thus minimizes the damaging effects in this critical area of the electrolyte. To further minimize the transition effects between the electrolyte and the electrode 10, the shield tube 20 is provided with a plurality of small holes 21 at the end of the shield tube 20 furthest from the electrical connector 16 to effectively form an electric current gradient transition area to minimize impulse current range and electrolytic effect.

The second electrode 22 according to the invention is shown in Figures 4, 4a, 4b, 4c and 5. The electrode 22 is similar in structure to the electrode 10 shown above, except that the electrode 22 comprises a metallization 14 located continuously along the entire length of each fiber 13. Thus, as shown in Figure 4a, the portion of the electrode 22 adjacent the connector 16 forms a unitary carbon / 25 metal matrix comprising the carbon fibers 13, the metal coating 14, the solder 18, and the arms 17 of the connector 16. At the electrode 22 located slightly further away from the connector 16, the unitary carbon / metal matrix comprises carbon fibers 13, metallization 14, and solder 18, as shown in Figure 30 4b. Farther from the connector 16 and extending to the opposite end of the electrode, all the fibers 13 have a metal coating 14 but, as indicated by arrow 19, the electrolyte can flow freely through the electrode 22. These metallized fibers have a high electrical conductivity.

Figure 6 shows the electrode 22 used in conjunction with a protective tube 20 which, as mentioned above,

II

13 77271 moi electrolyte damaging effects at the electrolyte-environment interface. In most electrochemical applications, the electrodes shown in Figures 4-6 are used as cathodes.

Figures 7-9 generally show a planar electrode 30 to which the present invention is applied. The electrode 30 is made of an elongate bundle 32 wound around a generally rectangular inert flow support 34 and held in place by the support 34 10 by an inert net 36. Most of the metallization may be removed from the bundle 32, as shown in Figures 1-3, or it may be fully metallized, as shown in Figures 4-6. All of the electrodes 30, whether used as anodes or cathodes, include a metallized region 38. This metallized region 38 allows the use of solder 40 to attach the electrical connector 42 to the bundle 32 and thus form a unitary carbon / metal matrix. As discussed above, the metallized region 38 preferably extends beyond the boundary of the soldered region 40 and, in certain electrodes, may extend the full length of the bundle 32. The electrode 30 further comprises a protective tube 44, which typically extends above the air-electrolyte interface to a location 7.8 to 10 cm in the electrolyte. Although the protective tube 44 may terminate above the flow support 34, it preferably extends 25 into the area adjacent to the flow support 34 to facilitate installation of the bundle 32 on the support 34. As most clearly shown in Figure 7, the flow support 34 has a plurality of openings 48 and may include an elongate section or a groove 46 in which the tube 30 44 is located. The bundle 32 can be rotated to be pushed through the opening into the flow-through support member 34 and rotated around the support member 34 in a continuous manner. Although Figure 8 shows a single bundle 32 terminated at both ends, multiple bundles and terminals may be used in the practice of the invention 35. The bundle 32 is held in place by a support member 34 and protected from damage by a net 36 14 77271 bent around the combined flow support member and the bundle 32. The mesh 36, which may be made of nylon or fiberglass, also prevents loose fibers from one electrode from contacting the other electrode.

If the electrode 30 is used as the cathode, the bundle 32 is typically considered to be fully metallized. Using the preferred electroplating described above, the metallization remains intact with the fibers in the bundle 32 despite the many sharp bends that are made to the bundle 32 during the fabrication of the electrode 30.

If the electrode 30 is used as an anode, the metallization is typically removed from the bundle 32 from all areas of the bundle 32 except the area near the solder connection 40 of the bundle 32 to the electrical connector 42. This removal of metallization from the bundle 32 can be performed either before or after the bundle 32 is placed in the flow support 34 .

In the embodiments shown in Figures 1-9, the fibers 12 that form the core of the electrode 10 or 30 are carbon. In addition, the fibers 12 may be made of other semi-metallic materials 20 such as nylon, polyesters and / or aramids and the like made electrically conductive by a thin interlayer of silver, copper, nickel and the like.

The metal coating 14 can be formed from a variety of metals, including nickel, copper, silver, lead, zinc, platinum group metals, and other metals, depending on the application. The metal coating may also be multi-layered, for example comprising a base layer of nickel and an outer layer of silver.

30 With respect to the matrix, as used herein, the term "solder" includes alloys such as tin and lead or copper and silver, as well as pure metals such as copper, where the solder matrix forms an electrical bridge between the walls of the terminal and each fiber 12.

The length of the bundle of fibers 12 depends on the width and length required for the electrode 10 or 30 1K 77271 and can be wrapped as shown in Figures 7-9 or woven or knotted. For example, bundles having a length of a few centimeters to 12 meters or more have been used satisfactorily in the practice of the invention.

One of the features of the present invention is the large surface area obtained by the electrodes in a small volume of solution, which gives a low current density with a high total current in Faraday units. For example, a bundle of 7 micrometers thick with a diameter of 8 micrometers after metallization is obtained by making a bundle of 40,000 (40K) fibers with an area of 258 cm per 2.5 cm of bundle length.

In addition, the electrical resistance of the galvanized fibers is so small that the potential in the bundle is substantially flat 15 even at a considerable distance from the terminals.

The electrodes of the present invention can be used to remove and recover soluble metals from dilute solutions such as process streams in electroplating, hydrometallurgy in the mining industry, mine effluent streams, and whenever metals are present in dilute solutions such as photographic and catalytic processes. As shown, the effective surface area of the electrodes of the present invention is large. As a result, efficient recovery currents and separation voltages can be achieved in the selective recovery of metals and the removal of impurities. In addition, the electrodes can be used in bipolar cell systems for efficient oxidation and reduction in separate chambers for solvent recovery and in organo-organic chemistry.

In the following embodiments, electrochemical cells and methods using the electrodes of the present invention are presented.

A typical application of the above electrodes is shown in Figure 10, which illustrates a tank 52 used in an electrochemical process such as removing or recovering metals from an electrolyte 54. Electro- 1Ä 77271 1 o

dits used as anodes are denoted by 30A, while electrodes used as cathodes are denoted by 30C. The anodes 30A and cathodes 30C are disposed alternately in the tank 52 with flow separation plates 56 located adjacent to the adjacent anodes 30A and cathodes 30C.

between. Tank 52 comprises a plurality of cells, each cell having one anode 30A, one flow separation plate 56, and one cathode 30C.

The anodes 30A and cathodes 30B are electrically connected to the power supply 58 by conventional wiring, as shown in Figure 10. The voltage difference generated by the power supply is a function of the current / voltage ratio for the respective electrolyte solution. The recommended voltage corresponds to the appropriate "bend" in the current / voltage curve for the particular metal to be removed or recovered.

In the tank 52 of each cell, two separating plates 60 are formed, as shown in Fig. 11. Each of the plates 60 is made of an inert, transparent material such as polymethyl methacrylate and comprises a plurality of holes 62 in the vicinity of one corner of the plate 60 and is shown arranged in a vertical row. The total area of the openings 62 is preferably about 50% larger than the area of the outlet pipe 66. The apertures 62 may be about 1.6 cm in diameter and be approximately 1.3 cm apart.

Apertures 62 are used to allow electrolyte to flow from one cell to the next in the tank 52. More specifically, the plates 60 are rotated 180 ° in the plane of the plate 60.

As a result, one plate 60 has openings 62 in the bottom corner, while the adjacent plate 60 has openings 62 in the opposite upper corner.

During operation, the electrolyte 54 is introduced into the tank 52 through a supply pipe 64 located near the top of the tank 52. The electrolyte 54 first enters the collection area 55 before passing through the openings 62 in the first distribution plate 60. This structure provides a preferred electrolyte 54 flow pattern into and through the first cell. Collection area il 17 77271

also acts as a surge equalizer and collects any accumulations in the electrolyte 54. The electrolyte 54 is finally removed from the tank 52 through an outlet pipe 66. The placement of the holes 62 in the plates 60 throughout the tank 52 causes the electrolyte 5 to flow alternately up and down and through one cell to the next. This general flow pattern of the electrolyte through the tank 52, shown graphically by arrows 68, causes an increase in the length and width of the electrolyte relative to the tank 52, maximizing the residence time of the electrolyte 10 in the tank 52 and also the contact time with the electrodes 30, all optimizing metal removal or recovery from solution. Thus, the structure of anodes 30A and cathodes 30C described above provides a very large surface area, while the structure of the tank ensures maximum contact of the electrolyte 15 54 with the anodes 30A and cathodes 30C.

with.

The metal to be removed or recovered precipitates on the cathode 30C. From time to time, therefore, it is necessary to remove the cathodes from the cell 30C to recover the metal. This recovery of the removed metal from the cathode 30C can typically be accomplished by extraction, pyrometallurgical, or anodization of the cathode in a concentration cell.

The electrochemical and structural principles outlined above can be applied to a system, as shown in Figure 25 13, for processing a process stream using the electrochemical cell shown in Figures 14 and 16 in detail. In this system, the process stream is pumped to storage tank 70 and then fed to multi-cell tank 72. Metal tank-30 is removed from the process stream to cat 72 and then removed through line 98 to collection tank 97. Discharge in collection tank 97 is pumped by pump 99 to neutralization tank 100 containing limestone and neutralized. then passed as waste through pipe 101.

35 According to Figures 14-16, a process stream containing a metal such as nickel, tin, lead, copper, etc.

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dilute acid solution is passed through a feed pipe 76 to a collector 78. The tank shown is rectangular and the separator plate 80 extends across it at one end and thus forms a chamber acting as a collector 78. The partition 80 between the collector 78 and the first cell 82A of the tank 72 comprises a channel 84 process stream 74 to the top of the flow surge control area 86. More specifically, the surge control area 86 is formed by a surge plate 88 extending across the other end of the cell above the process stream 74 in the first cell 82a at a location separate from the bottom wall 90 of the bath 72. In this case, a bottom channel 91 is formed, through which the process stream passes to the first cell 82A. The first cell 82A is provided with an alternating and repeating arrangement comprising an anode 30A, a flow-through separator plate 15 56, a cathode 30C, and a second flow-through separator plate 56. This arrangement is repeated such that each cell 82A includes a plurality of alternating anodes 30A and cathodes 30C. As shown in Figure 15, the anodes 30A and cathodes 30C are spaced apart from the bottom wall 90 and supported on portions 93 to allow deposits 20 to collect. As shown in Figure 13, the anodes 30A and cathodes 30C are connected to an adjustable power supply by conventional wiring, such as common busbars. For clarity, electrical connectors are not shown in Figures 14-16. As discussed above, the voltage for operation of the system 25 is selected to optimize the removal or recovery of metals from the electrolyte 54.

Cells 82A-82D extend across the tank 72 parallel to the collector and are separated by baffles 94. Each manifold includes one or more openings 96 located at one corner of the manifold 94. As described above, the baffles 94 are alternately rotated 180 ° with respect to their planes so that the openings are located alternately at opposite upper and lower corners. Thus, the baffle plate 94 has openings 35 between the cells 82A and 82B located at an angle as far as possible from the bottom wall and the baffle plate 88. As a result, the baffle plate 94 between the cells 82B and 82C is located at an angle closest to the baffle plate 92 and the baffle plate. 88. This particular structure ensures a process flow from end to end in the flow pattern in each cell 82A-82D either surface to bottom or bottom to surface according to the flow pattern. As before. . shown, this flow pattern optimizes the residence time of the process stream in the tank 72 while minimizing channelization. The process stream 74 is finally removed from the bath 72 through an outlet pipe 98 located near the bottom wall 92 of the bath 72.

The electrochemical cells and methods shown in Figures 10-12 and 13-16 are suitable for the removal and recovery of metals, including semi-precious and noble metals, from process or waste streams to a concentration of less than 1 ppm. For example, the system of Figures 13-16 can be used to remove about 50% of a nickel process stream containing 30 ppm nickel as a single pass at a flow rate of 18.9 liters per minute in an 189 liter multi-cell tank 72. To further remove nickel, the process can be repeated until the nickel content has decreased. to an acceptable level of 20 for discharge. This can be done by circulating the process stream from the tube 98 to the tube 76 through the tube 103 before the current is finally passed to neutralization.

The cells shown can also be used to treat a solution, whereby soluble salts, for example in municipal wastewater, are rendered insoluble for filtration from the wastewater.

The present electrodes can further be used in a separation cell, as shown in Figures 17 and 18, whereby the voltage is changed to a certain carefully selected level 30 to deposit the desired metal on the cathode and the metals higher in the electrochemical series remain in solution. In order to carry out this type of separation galvanizing, it is necessary to use a cathode with a large surface area.

This can be achieved in a small space and with a small amount of electrolyte by means of the separation cell 100 shown in Figs. 17 and 18, which uses a carbon fiber cathode 102 --- - ______ 20 77271 with a thin single-wire anode 104 made of, for example, platinum. The electrolyte 106 is supplied to the separation cell 100 through a supply pipe 108 located approximately in the middle of the separation cell 100. The supply pipe 108 is mounted on the guide base 110 and has a plurality of openings 111 which distribute the electrolyte 106 evenly in the cell 100. The single wire anode 104 is wound helically

The cathode 102 is then positioned concentrically around, but spaced from, the anode 104. As a result of this structure 10, the electrolyte flowing out of the supply pipe 108 is forced to pass past the anode 104 and through the cathode 102 to perform the desired deposition of metals on the cathode 102.

The cathode 102 used in the separation cell 100 is a nickel metallized carbon fiber electrode. Concentric mounting of the cathode 102 around the anode 104 is accomplished by uniformly winding the cathode 102 around a generally cylindrical plastic flow-through support or grid 112. The flow-through support piece 112 can be formed, for example, of a sturdy but flexible plastic mesh bent and secured into a cylindrical structure. The cathode 102 is attached to the support body 112 by a porous outer network 114. The flow characteristics of the support body 112 'and the network 114 allow the electrolyte 106 to flow easily through the cathode 102 in contact with the plurality of nickel-coated carbon fibers that make up the cathode 102.

Although the cathode 102 is shown evenly wound around the lattice 112, it should be noted that the cathode 102 may be braided into a cylindrical structure or woven into a mat which in turn is wound around the lattice 112 or some other support having a flow-through structure. An outlet tube 116 is also used to remove the electrolyte 106 from the separation cell 100. Typically, the separation cell 100 forms a closed system in which the outlet tube 116 and the supply tube 106 communicate with a common source of electrolyte-35 solution from which metal is removed. The separation cell can be designed to the desired size. For example, cell 100 21 77271 may be a small unit mounted in a large tank containing electrolyte solution. In a typical embodiment, a bundle cathode 102 comprising 40,000 nickel-coated fibers is formed as a cylinder, as shown in Figure 17, having a diameter of about 10 cm and a length of about 2,305 cm. This cathode 102 has an area of about 9 m 3a and can be mounted in a separation cell with a volume of less than 3.8 liters. If desired, much larger tanks can be built. As discussed above, once an appropriate amount of the metal in the electrolytic 106 has precipitated on the cathode 102, the process is temporarily suspended to remove and / or replace the cathode 102 so that the metal deposited thereon can be conveniently removed if the metal is impure or recovered if the metal has value.

Figures 19 and 20 show an electrochemical cell comprising a tank 122 that is substantially identical to the tank 52 shown in Figure 10. The tank 122 includes a plurality of partitions 124, each having a plurality of openings 126 through which the electrolyte 128 can pass. As indicated above, the openings 126 are located near the corner of the plate 124 and the plates 124 are alternately rotated 180 ° relative to their plane to create the desired electrolyte and lateral to lateral flow through and over the tank 122.

As discussed above, the plates 124 separate the different cells, wherein the cell 130 includes an anode 132 and a cathode 134 separated by a flow-through separation plate 136. The anode 132 comprises a carbon fiber bundle 138 wound around the flow-through support piece 140. More specifically, the carbon fiber bundle 138 of each anode 132 is formed of a plurality of carbon fibers, each of which is coated with metal in the vicinity of the power plant but is uncoated or the metal is removed from areas farther from the power plant. Thus, each anode 132 is substantially similar in structure to the anode 30A described above.

As shown in Figure 20, the cathodes 134 are through-flow or porous metal plates having a plurality of openings 142. In this embodiment, the plate 134 is made of stainless steel. The flow separation plates 136 interposed between each anode 132 and cathode 134 are substantially similar to the flow separation plates 56 described above.

Figures 21 and 22 show the following embodiment of the invention, which is particularly useful in electroorganic chemistry and synthesis as well as in the treatment of organic residues. As shown in Figure 21, the cell includes a tank 150 divided by two porous membranes 152 into two chambers for two different electrolyte solutions 154 and 156. The cell also includes anode 158 and cathode 160 that are substantially identical to the anodes 30Δ and cathodes 30C shown above. Anode 158 and cathode 160 are passive electrodes 15 electrically connected to each other at 164, but not electrically connected to an external power supply and thus bipolar. The anode 158 and cathode 160 are preferably separated by a porous membrane 152 such that the anode 160 is in a chamber containing 20 electrolyte 154 and the cathode is in a chamber containing electrolyte 156. The membrane 152 includes a hollow support body 161 around which a porous portion 168 is attached. , such as sailcloth. As shown, the membrane 152 is filled with solution 165, which may be neutral. The active electrodes of the cell 25 are the plate cathode 166 in the electrolyte 154 and the plate anode 168 in the electrolyte 156. As mentioned above, the electrolyte solutions 154 and 156 are different, one of which is acidic and the other of which is basic. Solution 154 is oxidized at anode 158, while solution 156 is reduced at cathode 160 without polarizing the fiber electrodes. In practice, the membrane 152 need not be ion-selective. Thus, the membrane 152 is relatively inexpensive and does not require much electrical energy.

The bipolar cell is particularly well suited for use where the anolyte and catholyte must be kept separate, where oxidation or reduction on either side of the cell may be ionic or where a polarized electrode is desired.

Il 23 77271

Broadly speaking, the invention is not limited to the specific embodiments shown, and changes may be made within the scope of the appended claims without departing from the principles of the invention and without compromising its main advantages.

Claims (5)

77271 An electrode (10; 22) comprising a plurality of adjacent continuous fibers (12), each fiber (12) having a thin, firmly attached metal coating (14), characterized in that the end of the metal-coated fiber (12) has: connector (16), and that the electrically conductive metal (18) extends between the metal coatings (14) at the ends of the fibers (12) and connects them 10 to each other and to said connector (16) to form a unitary metal matrix forming an effective electrical connection between the metal-coated fibers. (12) and said connector (16). An electrochemical cell comprising at least one pair of electrodes, wherein the electrodes of each pair of electrodes (30a, 30c; 102, 104; 132, 134; 158, 160; 166, 168) are of opposite sign and at least one of the electrodes of each pair comprises a plurality of electrodes. adjacent continuous fibers (12), each fiber having a thin, firmly attached metal coating (14), characterized in that the ends of the fibers (12) of said electrode comprising at least one fiber are close to each other, and that said electrode comprises each on said ends of the fiber (12) a metal coating-25 extending along each fiber (12), a connector at said metal-coated fiber ends, and an electrically conductive metal (18) extending between the metal coatings at the ends of the fibers and connecting them to each other and to said connector -30 to provide a matrix forming an efficient electrical connection between the metal-coated fibers and said n connector. An electrochemical cell according to claim 1, characterized in that one of the electrodes (134) is a metal plate with a plurality of openings 25 77271 (142) therethrough. A polar electrochemical cell, characterized in that it comprises a tank (150) with two chambers for containing different electrolyte solutions, the second chamber containing an active anode (168) and a passive cathode (160), the second chamber containing an active cathode (166) and the passive anode (158) and wherein the active electrodes (166, 168) are connected to the power supply (170) and the passive electrodes (158, 160) are electrically connected to each other and wherein both the passive anode and the cathode (158, 160) are electrically connected. ) consist of said fiber-containing electrodes, and wherein if the first and second electrolyte solutions are placed in said first and second chambers, the first solution 15 is reduced and the second solution is oxidized. A method of manufacturing a fiber-containing electrode according to claim 1, characterized in that it comprises forming a plurality of continuous-length core fibers (13); coating at least one end of each core fiber (13) with a substantially flat, firmly attached metal coating (14); placing the electrical connector (16) in contact with the metal-coated ends of the core fibers (13), and connecting the metal-coated ends and the electrical connectors (16) to each other by an electrically conductive metal (18) extending between the ends of the metal-coated fibers (12) , which provides an efficient electrical connection. --- 1. _____ 26 7 7 2 71