DE4316327C1 - Electrolytic cell having an electrode element, and use thereof - Google Patents

Abstract

An electrode element for electrolytic purposes, in particular for an electrolytic cell for the deposition of metal from liquid containing metal ions has a housing (container) which consists of electrically insulating, electrolyte-resistant material and has one sealed connection port each for the delivery and removal of the electrolyte, the supply of current to the electrode being effected via one of the two connection ports. The electrode is situated in an inner compartment of the housing, which compartment is sealed off by an ion exchanger membrane, and the current lead provided for the supply of current being of rod-like (bar-like) design and forming an angle of approximately 15 DEG with the plane of the plate-like (sheet-like) electrode. The connection port hole which accommodates the current lead is at a corresponding angular offset.

Description

Electrolytic cell with one for electrolytic purposes, especially for electrolytic Ab separation and / or separation of metals from a liquid containing metal ions, suitable electrode element, each with a housing made of electrically insulating material because at least one connection opening for supplying a liquid ion conductor and an has closing opening for removal of this ion conductor, with at least one plat ten-shaped, active part forming an electrode is arranged, on which the ion conductor ent long flows, the active surface of the electrode on at least one side of an ion exchanger membrane is covered and the electrode via a bushing with egg nem external power supply is connected, and the use of the electrolytic cell.

From EP-A-0 249 319 it is known to remove platinum from aqueous solutions of its chloro-ver to deposit bonds electrolytically. Anode compartment and cathode compartment are separated by one Ion exchange membrane separated, with an acidic platinum-chloro- Connection is located, while a solution from aqua regia is provided in the anode compartment.

DD-PS 1 39 605 also describes a process for the electrolytic production of powders known from precious metals, which is suitable for a further powder metallurgical representation of High-purity semi-finished products are suitable. The task is to be solved on electrolytic Ways of powder or platinum metals and gold from the chlorine complexes without the addition of Complexing agent while avoiding hydrogen evolution in a grain size between 0 and manufacture 1 mm; For this purpose, solutions of precious metals dissolved in acids are used where the excess acid was evaporated at a concentration of 5 to 50 g / l  Platinum metals, a pH between 0.3 to 1.0 and a current density of 10 to 150 mA / cm² at a temperature of 20 ° C and a residence time of 5 to 10 minutes electroly treated table. The powder that forms is removed by stripping or rhythms mix motion.

Anodic chlorine gas development has proven to be problematic in the known processes development, which has a considerable potential for danger and costly protective measures men requires.

Furthermore, DE-OS 36 60 040 describes an electrode arrangement in a metal recovery tion cell for cleaning industrial process solutions and waste water, which are used for holding tion of plate-shaped electrodes as an open frame made of parallel side strips Has spacer elements made of electrically insulating, corrosion-resistant plastic consists; on both sides of the anode are cathodes in a predetermined from the frame stood arranged.

With this arrangement, too, it turns out to be problematic that, due to the lack of a membra ne the occurrence of gas bubbles is to be expected, which means considerable risk potentials can arise.

From DE 40 03 516 A1 an electrode element for electrolytic cells is known, which has a a plate-shaped or box-shaped electrode introduced into a U-shaped frame, wherein the frame in a web arranged below the electrode openings for the exit of a Ion conductor in the direction of the electrode, while in an upper web of the frame Publ are arranged for removal of the ion conductor. The frame is in a pocket Formed ion exchanger membrane removably supported, this from an external outer protective box with openings is surrounded; the electrode element is called Anode used in metal recovery cells or as a cathode in oxidation cells. On because of the pocket-shaped design of the membrane, it is possible that in the upper part Gas bubbles can escape, which entails potential hazards.

Furthermore, from DE 29 23 818 A1 an electrode compartment of an electrolytic cell from the fil Terpresstyp known for the electrolysis of alkali chloride, wherein the electrode compartment alternately as Anode and cathode compartment can be formed; the electrode compartments have a frame men with an inlet for the electrolyte feed and an outlet for the outflow of the Electrolysis products, with cathodic and anodic electrode compartments  Ion exchange membranes are separated from each other. The use of such electrolysis cell len of the filter press type puts a relatively high effort in terms of a variety successively connected electrode elements, whereby for the removal of electrolytic separations a complete disassembly of the entire arrangement is required, so that there is also a relatively high operating cost.

From US 49 64 965 a box-shaped electrode housing with an opening is known which is covered by a porous electrode plate and as an anode for the electroplate serving of continuous strip material; the tape material is in one with Electrolyte supply tank, while the electrode housing with an opening for elec trolyte removal is provided; due to the open electrode configuration, the gas is used Generating electrolysis processes problematic because Gefah through gas bubbles potential can arise.

Furthermore, from US 46 05 483 an electrode with a housing is known, the housing has an opening closed with an insulating membrane, on which one is guided de layer for the electrolytic coating of printed circuit boards. Since the serving as an anode on the outside of the insulating membrane this electrode arrangement is an open construction, so that in gas-generating The occurrence of gas bubbles is to be expected in electrolysis processes. A gas discharge over the inside of the electrode housing is not possible, as this is under increased internal Air pressure is there.

The invention has for its object an electrolysis cell with an electrode element specify that both as an anode in the electrolytic cell, especially in a metal back recovery cell as well as a cathode in an oxidation cell, the elec trode surrounding electrolyte through an ion exchange membrane from the counter electrode is separated and a closed electrode space is formed, in which gases are collected gene and be discharged, and there is a regeneration of the electrolyte liquid. In particular the electrolysis cell with the electrode element as the anode in the electrolysis as Re Production and separation processes in platinum group metal separation, especially pul decision can be used.

Furthermore, the use of the electrolytic cell to achieve a low ion end con concentration, especially the final metal ion concentration.  

The object is achieved with respect to the electrolytic cell in that the housing on minde least one side has at least one opening through the ion exchanger membrane is sealed gas and liquid tight and that as the implementation of the power supply serving connection opening is also sealed gas and liquid tight.

In a preferred embodiment, the electrolysis cell has a plate-shaped electrode on that on its side facing away from the ion exchanger membrane with a rod-shaped Power supply is connected by welding; the axis of the power supply closes an angle in the range of 5 to 45 °, preferably 15 °, with the plane of the electrode; the hole of the connection opening receiving the current feeder for the removal of the liquid Io nenleiters also closes an angle with the plane of the ion exchange membrane Range from 5 to 45 °, preferably from about 15 °.

Advantageous embodiments of the electrolytic cell are specified in claims 2 to 11.

The task of specifying a use of the electrolytic cell is characterized by features of the An Proverb 12 solved; a particularly advantageous use of the electrolytic cell is claimed 13 specified.

In addition to the high level of security against chlorine gas explosions, the simple che maintenance of the electrolytic cell or the electrode element, in particular both Ion exchange membrane as well as the electrode itself in a simple way by exchange are regenerable.

Another advantage is that due to the complete sealing of the electricity line to the electrode the surface of the membrane can be largely used, d. H. that practically the entire ion exchange surface of the membrane of the Elek Trodenelements is available.

The subject matter of the invention is explained in more detail below with reference to FIGS. 1a, 1b, 1c, 2a, 2b, 3a and 3b.

Here, FIG 1a shows. The electrode element for electrolytic cell with its essential component parts of the composition.

FIG. 1b, the largely composite electrode member;

FIG. 1c, the electrode element completed with membrane;

Figures 2a and 2 are respectively a plan view and a cross-section of the housing of Elek trodenelements along the line AB and the electrode to be introduced.

Fig. 3a shows schematically in a perspective partially broken arrangement, the use of the electrode member as an anode in an electrolytic cell, in particular an electrolytic metal recovery unit,

Fig. 3b shows a cross section of this system.

The associated tank is only partially or broken open for a better overview shown.

According to FIG. 1a, the housing 1 formed from an acid-resistant, electrically insulating material consists of a cuboid housing part, which in the area of its front surface has a substantially hollow cylindrical recess as the interior 2 of the electrode element; the rear-like broad surface, not shown in the figure, is completely closed. A flat electrode 3 can be used in the interior 2 , the rod-shaped current feeder 4 of which is welded onto the rear of the electrode 3 at an angle of approximately 15 °, so that an electrically and mechanically firm connection between the flat electrode 3 and the current feeder 4 which is also acid-resistant. The housing 1 has to carry out the current arrester and to remove the electrolyte-gas mixture passed through the interior 2 , a bore 6 leading from the interior 2 to the top 5 of the housing, which is angled relative to the front plate 8 by approximately 15 ° and here is symbolically represented by dashed lines. In the area of the top 5 , the bore 6 is connected to a sealable nozzle 7 , which is provided both for the sealable power supply by means of a power supply 4 and for the discharge of the electrolyte-gas mixture from the interior of the housing 1 .

Furthermore, the interior 2 is provided with an electrolyte feed pipe 10 , which likewise consists of acid-proof, electrically insulating material and is led out of the top 5 of the housing 1 via the bore 11 and the connector 12 ; the bore 11 is shown here symbolically by broken lines; the opening of the bore 11 on the top 5 is provided with a nozzle 12 which can be connected to an electrolyte supply system, which is not shown here for a better overview. The electrolyte feed tube 10 is located in the immediate vicinity of the rear wall 9 of the interior 2 , so that when inserting electrode 3 and Stromzu conductor 4, the electrolyte feed tube 10 is covered by the flat electrode 3 . As an electrode, preferably expanded metal is used, which is circular in its circumference to largely cover the base of the interior 2 , with the power supply 4 being welded in the form of a solid rod on the rear side.

To install the electrode 3 , the power supply 4 is first inserted through the drilling tion 6 and then the electrode is centered in a preferably circular opening in the interior 2 . The interior 2 is sealed by a membrane 14 which can be applied to the level of the electrode 3 and which covers the entire opening 13 of the interior 2 and is sealed with respect to the housing 1 by means of a sealing ring 15 which surrounds the opening, the sealing being used required pressing pressure takes place through a mountable frame 16 , which is provided with openings 17 for inserting screw bolts 19 which are screwed into threads 18 of the housing 1 . It is also possible, however, in place of the thread 18 of the Gehäu ses 1 through bores in the housing 1 to provide, which are provided on the rear side with nuts for the purpose of retaining the bolt.

FIG. 1b shows the electrode member with the inserted in the interior 2 of the casing 1 electrode 3, wherein the current supply conductor 4 is in the shown dashed bore 6; the current feeder 4 is fastened to the back of the electrode 3 by welding at an angle of approximately 15 °, current distribution elements 21 of the electrical de 3 being additionally recognizable by the expanded metal grid. Furthermore, the expanded metal structure of the electro de the electrolyte feed pipe 10 can be seen. The ion exchanger membrane 14 provided for covering the opening of the interior 2 and the frame 16 are shown as individual parts to be applied for a better overview.

The completely assembled electrode element can be seen in FIG. 1 c, the interior space, which is no longer visible, being recognizable by the ion exchanger membrane 14 applied on the front and the fastening and sealing with the aid of the frame 16 and the screw bolts 19 . The top 5 of the housing 1 is provided with the connector 7 for the power supply line for the electrode and the branch pipe 22 connected to the connector 7 for removing the electrolyte-gas mixture from the housing; Furthermore, the connector 12 provided for the supply of a regenerated electrolyte can be seen on the top 5 of the housing 1 . As materials for the electrolyte housing, for example, polypropylene are suitable, the electrode and the power supply bolt and the associated power distributor being made of a valve metal, preferably titanium; serves as electrolyte in anodic operation of the electrode element in the case of a precious metal recovery system sulfuric acid.

. With reference to FIG 2a, the housing 1 can be seen with the opening formed as a hollow cylindrical interior 2, with the associated opening in the front plate 8 is surrounded by a concentric recess 25 for receiving the sealing ring 15; the recess 25 is surrounded in the radial direction by an outer circle 26 on which the threads 18 are provided for receiving the bolts. In the upper part of the housing, the bores or hollow cylindrical feedthroughs 6 and 11 shown by dashed lines are recognizable, which - as already stated above - serve to receive the power supply line 4 and discharge the electrolyte-gas mixture and to supply the electrolyte. Furthermore, the electrode 3 prepared for use with the current arrester 4 is shown, the fitting of the electrode with its current arrester being more clearly recognizable on the basis of FIG. 2b. This figure can be seen that at a guide of the power supply 4 in the bore 6 along the axis 28 is lowered in the direction of the interior 2 that the opening of the interior 2 formed in the front plate 24 is largely covered by electrode 3 .

On the basis of Fig. 2b the welding point 29 are in longitudinal section and the power distributor elements 21 apparent to the electrode 3. It can be seen here that the axis of the power supply line 4 is arranged at an angle of approximately 15 ° to the level of the electrical de 3 ; the axis 28 of the bore 6 is arranged at a corresponding angle to the plane of the opening of the interior 2 . The opening of the interior space 2 is then sealed after insertion of the electrode, as already explained with reference to FIGS . 1b and 1c, by the ion exchanger membrane and the fastening frame together with screw elements, the symbolically entered electrolyte level 30 indicating that the electrolyte supply and discharges and the conductor of the power supply are completely sealed against the electrolyte, but at the same time a simple replacement of the electrode or ion exchanger membrane is possible.

A use of the electrode element according to the invention as an anode is explained in more detail with reference to FIGS . 3a and 3b.

According to Fig. 3a is a provided with acid-resistant electrically insulating surface tank 32 is provided as an electrolytic trough which is provided with a feed line 33, chloro-salts rhodium is supplied via the aqueous solutions of chloro-compounds of platinum metals, particularly complex. The flow runs parallel to the longitudinal axis 34 of the tank 32 , plate-shaped cathodes 35 being provided for the powdery deposition of rhodium along the longitudinal axis 34 , which are surrounded on each side by an electrode element 36 as an anode, the surfaces of the respective ion exchanger Membranes 14 are net angeord parallel to the surfaces of the plates. The cells, each consisting of two electrode elements 36 and a cathode 35 , are housed in a common electrolyte space in a plurality, preferably three in each case, and connected in parallel, in accordance with a preferred embodiment a total of three cells being connected in flow in a cascade and electrically in series. The distances between the cathode and the electrodes of the electrode elements 36 serving as anodes are in the range from 0.5 to 30 cm, a voltage of 1 to 50 V being applied; the current density on the titanium cathodes is in the range of 0.001 to 100 A / dm². The pH of the solution containing the chloro compounds is in the range from 0 to 2. Because of the high current density, it is necessary to supply both the solution emerging from the electrode element 36 via connection piece 7 and branch pipe 22 and the supply via connection 12 again cool, as well as to cool the cathode by means of a temperature control medium flowing through. As can be seen from FIG. 3a, the current supply rails 38 , 39 simultaneously serve to hold the cathodes in the middle between two electrode elements 36 in each case. The supply line for the power supply of the electrode element 36 takes place via connector 7 , but it is not shown for the sake of a better overview.

Based on the schematic cross section according to FIG. 3b, it can be seen that the level of the catholyte in the tank designated by reference number 30 is so high that the ion exchanger membrane 14 is practically completely wetted by the catholyte. The provided for power supply to the anode and to discharge the anolyte gas mixture nozzle 7 is connected via branch pipe 22 and connection channel 41 to an anolyte regeneration system 42 , which speed is shown only schematically for the sake of clarity. The anolyte regeneration system 42 ensures a separation of the anolyte liquid and the gases generated at the anode, which mainly consist of oxygen, and regulates the concentration of the anolyte, which in the present case consists of sulfuric acid. The regenerated anolyte is then supplied via a pipe system 43 to the nozzle 12 again and enters the interior of the electrode element serving as an anode from here.

Claims (14)

1. Electrolysis cell with an electrode element for electrolytic purposes, in particular for the electrolytic deposition and / or separation of metals from a liquid containing metal ions, suitable electrode element, which is a housing made of electrically insulating material, each with at least one connection opening for supplying a liquid ion conductor and one Has connection opening for removal of this ion conductor, in the Ge housing at least one plate-shaped, an electrode-forming part is arranged, along which the ion conductor flows along, wherein the active surface of the electrode is covered on at least one side by an ion exchanger membrane and wherein the electrode is connected to an external current lead via a bushing, characterized in that
that the housing ( 1 ) has at least one opening ( 13 ) on at least one side, which is sealed gas and liquid-tight by the ion exchanger membrane ( 14 )
and that the connection opening serving as a feedthrough for the power supply line ( 4 ) is also sealed in a gas and liquid-tight manner. 2. Electrolytic cell according to claim 1, characterized in that the bushing for the current feeder ( 4 ) is formed by a bore ( 6 ) serving as a connection opening. 3. Electrolytic cell according to claim 1 or 2, characterized in that the current feeder ( 4 ) is rod-shaped and with the plane of the plate-shaped part of the electrode ( 3 ) forms an angle in the range of 5 to 45 °, the axis of the bore ( 6 ) also forms an angle in the range of 5 to 45 ° with the plane of the opening ( 13 ). 4. Electrolytic cell according to one of claims 1 to 3, characterized in that the current feeder ( 4 ) with the ion exchanger membrane ( 14 ) facing away from the electrode ( 3 ) is welded. 5. Electrolytic cell according to one of claims 1 to 4, characterized in that the Io nenaustauscher membrane ( 14 ) by means of a frame which can be screwed onto a housing opening ( 13 ) surrounding edge and by means of a between the edge and the Ion exchanger membrane elastically deformable sealing element ( 15 ) is sealed against the interior ( 2 ) of the housing ( 1 ). 6. Electrolytic cell according to one of claims 1 to 5, characterized in that the housing ( 1 ) on its front plate ( 24 ) has a circular opening ( 13 ) which is surrounded by a recess ( 25 ) for receiving the sealing element ( 15 ) . 7. Electrolytic cell according to one of claims 1 to 6, characterized in that the connecting pieces serving as connection openings (7, 12 ) on the top ( 5 ) of the housing are arranged. 8. Electrolytic cell according to one of claims 1 to 7, characterized in that the rear wall ( 9 ) of the interior ( 2 ) is closed. 9. Electrolytic cell according to one of claims 1 to 8, characterized in that the housing ( 1 ) consists of polyethylene, polyvinyl chloride or PVDF. 10. Electrolytic cell according to one of claims 1 to 9, characterized in that in an serving as an electrolytic trough tank ( 32 ) at least two plate-shaped ge cathodes ( 35 ) are provided, which are successively flowed around by supplied liquid, each of the cathodes between each is arranged as two anode serving electrode elements (36) so that the cathode tenflächen with their respective Plat of Elektrodenele is arranged member (36) parallel to the surface of the ion exchange membrane (14). 11. Electrolysis cell according to claim 10, characterized in that the liquid flows around the cascade Ka ( 35 ) in succession. 12. Use of the electrolytic cell according to one of claims 1 to 11, as a metal back recovery cell in which a cathode is arranged between two anodes. 13. Use of the electrolytic cell according to claim 12, with as a metal recovery cell a plate-shaped cathode, the plate sides of which are each parallel to the ion exchanger Membrane of the electrode element serving as an anode are aligned. 14. Use of the electrolytic cell according to claim 10 or 11 for the electrolytic deposition of platinum group metals from a liquid containing metal ions.