DE1197852B - Electrolysis cell for the production of alkali chlorate - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

AU SLECjE SCH RIFT

Int. α .:

COIb

German Kl »; 12 i-11/25

Number; 1197 852

File number: K 42140IV a / 12 i

Filing date: November 12, 1960

Lay-out day; August 5, 1965

The present invention relates to one with an electrolytic cell connected to an electrolyte collecting tank for the production of alkali chlorate from aqueous alkali chloride solutions with an electrolyte stream flowing through it Reaction space, which is delimited by laterally arranged walls preventing the passage of liquid and only at the opposite ends in the flow direction via free vent cross-sections communicating with the electrolyte return room located outside the reaction room connected is*

In the production of alkali chloride by the The electrolysis of aqueous alkali chloride solutions causes the chlorine ion of the dissociated alkali metal chloride at the anode discharged to elemental chlorine, while hydrogen ions are preferentially deposited on the cathode Will. In the vicinity of the anode are mostly free Chlorine and hypochlorous acid, hydrogen and free alkali available near the cathode. The latter reacts with the chlorine to form alkali hypochlorite, which forms alkali chlorate with the hypochlorous drink. In addition, however, alkali chlorate is also produced by the direct discharge of hypochlorite ions at the Anode, in a second side reaction, hydroxyl ions of the alkali are also formed on the anode " load. Both side reactions are undesirable because they degrade current efficiency and when in use graphite as anode material will reduce the service life of the anodes.

With the intention of the side reactions described To suppress, up to now the chlorate electrolysis was carried out in electrolytes that are as stationary as possible in order to thereby the formation of a pronounced which makes the penetration of hypochlorite and hydroxyl ions more difficult Diffusion layer at the anode - to favor. Accordingly, in the known cell constructions, no special advantages * kehrungeii taken to the electrolyte movement in the Reaction space between anode and cathode via the with a view to sufficient electrolyte renewal to increase the necessary level.

It is true that electrolysis cells have become known in which a circulating flow of the electrolyte occurs during operation within the cell due to the design described above, but these circulating flows are either only of low intensity and / or the circulating flow is adversely affected by cooling devices located in the reaction chamber, since As a result of the cooling by the convection, a velocity field of the electrolyte is formed, which the circulating flow of the electrolytic cell for the production of
Alkali chlorate

Applicant:

Krebs & Co. A. G., Zurich (Switzerland)

Representative:

Df.-Ing. R. Döring, patent attorney,

Braunschweig, Jasperallee 1 a

Electrolytes counteracts and thus the buoyancy flow inhibits in the reaction space and the off * prevents the formation of a continuous flow.

The present invention is based on the knowledge gained through theoretical considerations and practical experiments that an undisturbed directed flow in the area between the electrodes is favorable for the electrolysis process, particularly when high anodic current densities are used.
Accordingly, the present invention is based on the electrolysis cells mentioned and described at the beginning and is characterized according to the invention in that the reaction space of the cell is connected with flow cross-sections dimensioned in such a way and / or with additional devices for conveying the electrolyte that inside the reaction diamond at an anodic current density of at least about 5 A / dm ^2, an average flow velocity of at least 0.10 m / sec. occurs, while the cross-section of the electrolyte return space is dimensioned so that the electrolyte flow circulating within the cell it with at least 0.1 iü / sec. flows through, with cooling devices being provided in the electrolyte return space and / or in the Blektrölytkreislkufsystern located outside the cells.

It is useful here to provide an electrolyte collecting tank for a group or all of the electrolytic cells, which is used to form an outer one Circuit of the electrolyte with the cell overflows and is connected to the lower parts of the cell trough via supply lines, in which, if necessary, the cooling unit services can be accommodated.

Such an electrolyte collecting container with cooling devices leads to the fact that the electrolytic cells can even be made very small and thus only take up a small amount of space.

flow in all electrolysis cells connected to it. The chemical takes place in it at the same time Implementation of the hypochlorite in the chlorate, so that the electrolyte entering the reaction chamber, which is in the essentially flows from the collecting container, the same or approximately the same composition in each cell having.

In experiments it was found that, for example, in a test cell with graphite anodes and cathodes, which was operated with an anodic current density of 10 A / dm ^a and gave current yields between 87 and 90%, the speed in the reaction chamber was 0.35 m / sec. fraud. The amount of liquid circulated in the cell every hour as a result of the Intera flow was more than 10O times the electrolyte volume of the cell.

The use of high anodic current densities above 5 A / dm ² , high electrolyte speeds in the reaction space and the strong internal circulation of the electrolyte in the cell have the following significant advantages:

As a result of the high anodic current densities, the dimensions of the Cells and the cell room are kept smaller and thus the investment costs are reduced. It is known that the tendency towards anodic discharge of the hydroxyl and hypochlorite ions formed during the electrolysis process decreases with increasing anodic current density, thereby reducing oxidation losses in the cell is reduced and the current yield is improved accordingly. In addition, the parallel with the An increase in the anodic current density results in a higher cathodic current density and a denser structure of the diaphragm created by the sodium dichromate contained in the solution, which the cathode surfaces covered and the undesirable cathodic reductions of the alkali hypochlorite formed difficult. The consequence of this is lower cathodic reduction losses and thus an improvement the current yield. High electrolyte speed has the consequence that the anodic released elemental chlorine is detached from the anode in smaller bubbles and thus the chlorine absorption in the Electrolytes is relieved. In addition, the stronger mixing movement in the reaction space facilitates as a result the higher flow turbulence the formation of sodium hypochlorite,

ίο Due to the strong internal circulation, especially in In connection with the use of an electrolyte collecting container, a practically complete one takes place Temperature and concentration equalization in the cell's electrolyte. Local chloride depletion and thereby Loss of electricity yield and graphite losses caused by local temperature increases siud largely excluded in this way of working.

By dimensioning the flow cross-sections of the reaction space, one can achieve that as a result

ao the gas development in this space and the resulting difference in the specific weights of the Volume of the electrolyte at the intended speed of at least 0.10 m / sec. emotional will. In this case, according to the invention, additional electrolyte flow can be generated to generate the desired high electrolyte flow Devices such as circulating pumps or a gas inlet can be provided, the latter being below or in the lower part of the reaction chamber is to be carried out in order to take the buoyancy of the electrolyte with it to support.

If a cell is operated with the high current density provided for in the present invention, the result is to dissipate the heat released during the electrolysis process from the electrolyte Installation of sufficient cooling surfaces in the cell is often difficult because of the amount of heat developed, such as The example below shows that when the anodic current density in a cell increases, it increases rapidly.

Anodic current density, A / dm ²

Amount of heat developed per unit of time

6th
2.7

5.1

12th
8.6

15th
12.9

In order to limit the cooling surface requirement to a tolerable level, the electrolyte is provided outside the reaction space at a flow rate of at least 0.1 m / sec. to cool.

In order to be able to work with the intended high current densities that are required for the resolution to avoid the bichromate diaphragm formed on the cathode, which the cathodic Prevents reduction, the invention provides for the cathode plates to be perforated and only The walls delimiting the reaction space laterally from the electrolyte return space are non-perforated Form cathode plates.

Furthermore, the invention provides that the surfaces of the cell tray immediately adjacent to the anodes are also effective as cathodes, the distance between the formed as cathodes Walls of the cell tray and the newly inserted anodes immediately adjacent to them are preferred is chosen to be equal to or smaller than the distance between the actual cathodes and the anodes.

According to the invention, the distance between the adjacent anodes and cathodes should be newly inserted Anodes must be smaller than 10 mm in order to achieve the desired circulating flow of the electrolyte reach solely because of its buoyancy in the reaction space.

If the electrolysis cell is equipped with a circulation pump, it is advisable to use the reaction chamber in or against the direction of the electrolyte flow extended funnel-shaped so that it is against

the electrolyte return space forms a funnel-shaped opening in which a pump impeller that delivers the electrolyte in the axial direction is rotatably arranged. In order to achieve a uniform velocity distribution of the electrolyte in the reaction space, it is useful if, viewed in the direction of flow, a perforated plate arranged transversely to the direction of flow is provided in front of the reaction space.
It is useful to provide a pump in such a way that its direction of delivery coincides with the direction of buoyancy of the electrolyte. However, it is entirely possible to arrange the pump in such a way that it conveys the electrolyte against the direction of buoyancy if this is necessary for structural or other reasons.

A gas inlet device promoting the buoyancy movement of the electrolyte can according to the present invention Invention be designed so that in the lower

5 6

Part of the reaction space a perforated plate and therefore a lining such as hard rubber, a polyvinyl chloride, polyethylene or polyisobutylene feed pipe arranged below the plate the gas to be supplied to the electrolyte is protected against attack by free chlorine, are, that a cushion underneath the perforated plate. Experience has shown that the service life of these covers is forms and limited with the upward flowing electrolyte 5. The detachable flange connection is passes through the openings in the plate. With easy interchangeability of the endangered trough arrangement of gas inlet devices recommends upper part guaranteed. The electrolyte and the it developed electrolysis, mainly hydrogen, at the ends of the anodes on the upstream side cell gas containing the electrolyte to avoid gas congestion are inclined over the drainage tube. io zen 10 withdrawn from the cell together. An Indian

Further details of the invention emerge from the height-adjustable overflow weir 12 regulates the level

the figures shown in the drawing and that of the electrolyte in the cell. In the all around

following figure description. Relocation of the trough top is that of the cell

The drawings show, for example, cell lids made of electrically non-molds that complete the training above of electrolytic cells again, which with in the elec- 15 conductive material, z. B. polyvinyl chloride or Steintrolytrrückführraum arranged cooling devices, inserted. The anodes consist of which are equipped in parallel. epiped-shaped anode bodies 14 and the opposite

F i g. 1 shows a cross section through an electrode, these separated anode necks 13 and are from above

lysis cell in which the high electrolyte speed enters the cell by means of gas-tight feedthroughs

by utilizing the gas separation in the 20 hung through the cell cover.

Reaction space can be achieved; The current-carrying space between the anodes

F i g. 2 gives a longitudinal section of the arrangement and cathodes are assumed to be the actual reaction space

Fig. 1 again; because the primary electrolysis process, namely

F i g. 3 shows a plan view of the cell after the discharge of the ions of the alkali chloride, almost

1 with the cover lifted off; 25 exclusively to the boundaries of this space

Figs. 4, 5 and 6 show the anode and cathode surfaces, respectively, taking place. The rest-

Positions of FIGS. 1, 2 and 3 is a form of training borrowed by the electrolyte cell space

the electrolysis cell with a space below the reactor called the electrolyte return space,

tion room arranged feed pump; In the embodiment of FIG. 1 to 3

Fig. 7 shows a cross section through an electric 30 the circulating flow of the electrolyte takes place from-

lysis cell again, in which the buoyancy flow is finally due to the fact that the in the reaction space

Reaction chamber through the entry of gas into the electrolyte from the electrolyte at the anode or

lyten is reached; Cathode released, essentially from hydrogen

8 shows a section along the line or through which gas bubbles consisting of chlorine are penetrated

VIII - VIII according to FIG. 7. 35 and thus a lower specific weight than the

In the figures, the iron cell trough-lower electrolyte located in the electrolyte return space is divided up 1 in the usual way, e.g. B. by means of the four deflectors, through which an intense buoyancy flow Supports 2, which rest on the insulators 3, is generated. This one in the reaction chamber Cell foundation arranged electrically insulated. called buoyancy flow corresponds in the electrolyte die The bottom of the trough is a return space directed from top to bottom for the purpose of easy cleaning Ability to run at an angle and at the lowest point with a return flow, provided that the reaction relief valve 4 for emptying the cell and discharge space from the electrolyte return space through lateral, equipped of graphite sludge. The fresh electrode walls prevent the passage of liquid trolyt is separated from the cell through the perforated tube 5. So that this is directed, in itself guided. The cathode end plates 6 and 6fl are electrically 45 closed internal circulation in the cell as possible can form conductive with the two walls 7 of the cell trough undisturbed, has the above-described Lower part connected. The cathode plates, which cell according to the invention still have the following characteristics Metals or graphite can be manufactured, ristic features on:

are for example by welding, soldering, riveting While the cathode plate 6 between the anodes or screws with the walls? connected, 5 ° perforated, because a high cathodic which in turn can consist of solid iron or for the purpose of current density of at least 5 A / dm ^{2 in} advance to increase the electrical conductivity from both sides for a good formation of the cathodic iron-clad copper sheet. Each trough wall 7 has at least one connection diaphragm which, by adding sodium clamp 8, which is formed on the negative pole of the voltage dichromate, is used to connect the two to the source. In the electrolyte return space, the reaction space to the side of the electrolyte return space, are designed without perforation to remove the separating cathodes 6a developed in the cell, current heat, cooling surfaces 15, for example in the form of tubes around a buoyancy flow in the reaction space. obstructing equalizing flow from the electrolyte return

On the trough lower part, the cell trough upper part 9 is fitted with liquid-tight walls 6a by means of a detachable bottle guide space into the reaction space through the separating connection. This part of the cell trough is in the gas space.The distance between adjacent to the chemical attack of the anode and cathode surfaces dl developed during electrolysis is exposed to the smallest possible amount of moist hydrogen gas, which is always maintained and should not contain 10 mm of chlorine in new anodes. In addition, the 65 increases, so that the concentration of the gas bubbles in the electrolyte on the surface has a particularly high gas space and thus the reduction of the specific content of free chlorine and therefore has a particularly corrosive effect on the weight of the electrolyte in the reaction space. The iron upper part of the trough must achieve the highest possible values.

The distribution of the gas bubbles in the electrolyte should be as uniform as possible in order to avoid internal equalization flows in the reaction space. The distances dl between the trough walls 7 and the anodes adjacent to them are therefore kept in the same order of magnitude as the normal distances dl between anodes and cathodes, whereby the trough wall 7 also takes on the function of a cathode. In addition, the distances between adjacent anodes flf3 are to be as small as possible, that is to say they should be chosen to be at most 3 mm wide. While high electrolyte speeds are sought in the electrolyte gap for reasons of marriage, the speed of the electrolyte in the electrolyte return space should be kept so high that the effectiveness of the built-in cooling surfaces is significantly improved compared to that when the electrolyte is practically stagnant.

In the embodiment of FIG. 4, 5 and 6, the electrolytic cell is equipped with a pump that generates the high flow rates in the reaction chamber. For this purpose, the cell is designed in such a way that the reaction space is made from sheet iron downwards through a funnel, which in this case is rectangular in cross section. Two opposite funnel sides 16 are connected to the two outermost and non-perforated cathode plates 6a , the other two funnel sides 16a to the walls 7 of the lower part of the cell trough. The tip of the funnel opens into a circular cylindrical connecting piece 17 in which a pump impeller 18 which delivers in the axial direction rotates.

In special cases, the pump impeller is driven by an electric drive motor 19 coupled directly to the pump shaft, which is flanged from below to the bottom of the cell trough lower part. A perforated plate 20 e.g. B. off Plastic or iron ensures an even speed distribution of the electrolyte over the Flow cross-section of the actual reaction space. The drive of the pump impeller 18 can also take place by a drive unit arranged above the cell cover 11, the pump shaft of gas-tight at the top through the cell cover and then through a free space between the anodes up to the pump impeller. It is also conceivable to follow the reaction space to extend funnel-shaped at the top and to attach the pump impeller above the reaction chamber.

In the cell shown, a bottom-up pump impeller is assumed, which the Sucks electrolytes from the electrolyte return space and after passing through the perforated plate 20 pushes upwards through the actual reaction chamber at the desired high speed. It it is also possible to let the pump impeller convey from top to bottom and thereby the direction the internal circulation in the cell to reverse what the ratios for the absorption of the at the anodes developed elemental chlorine in the electrolyte is significantly improved.

Another example of a cell construction, in which according to the invention the buoyancy flow in the The reaction space is increased by the entry of gas into the electrolyte is shown in FIG. 7 and 8 shown.

The cathode plates 6 a separating the reaction space from the electrolyte return space are extended downwards. A horizontally oriented sheet provided with evenly distributed perforations for the gas passage is connected to the cathode sheets 60 and the cell trough walls between the latter in a liquid-tight manner. The gas promoting internal circulation in the cell, for which the hydrogen gas developed in the cells or a foreign gas can be used, is introduced by means of the connector 23 into the space under the perforated plate 20, where a gas cushion is formed. Electrolyte circulation pipes 21 are let into the metal sheet 20, which allow the passage of the electrolyte from the electrolyte return space into the reaction space. In order to prevent the gas passing through the sheet metal 20 in the form of small bubbles when it enters the actual electrolysis gap between cathodes and anodes, the lower ends 22 of the latter are laterally beveled. By introducing the gas, the specific weight differences between the reaction space and the electrolyte return space are increased and the buoyancy flow in the reaction space already described in the case of the cell construction described above is increased.

Claims (11)

Patent claims: 1. Electrolysis cell connected to an electrolyte collecting tank for the production of alkali chlorate from aqueous alkali chloride solutions with a reaction space through which the electrolyte stream flows and which is limited by walls arranged on the side that prevent the passage of liquid and only at the ends opposite in the flow direction via free passage cross-sections with the outside of the reaction space The electrolyte return space is communicatively connected, characterized in that the reaction space of the cell is connected to flow cross-sections dimensioned in such a way and / or with additional devices for conveying the electrolyte that within the reaction space there is an average flow ^{rate at an anodic current density of at least about 5 A / dm 2} of at least 0.10 m / sec. occurs, while the cross-section of the electrolyte return space is dimensioned so that the electrolyte flow circulating inside the cell it with at least 0.1 m / sec. flows through, with cooling devices being provided in the electrolyte return space and / or in the electrolyte circulation system located outside the cells. 2. Electrolytic cell according to claim 1, characterized in that only the reaction space laterally against the electrolyte return space delimiting walls as non-perforated cathode plates are trained. 3. Electrolytic cell according to one of claims 1 or 2, characterized in that the anodes directly adjacent surfaces of the cell tray are also effective as cathodes. 4. electrolytic cell according to claim, characterized characterized in that the distance between the cathode walls of the cell tray and the newly inserted anodes immediately adjacent to them are equal to or smaller than the Distance between the actual cathodes and the anodes is. 5. Electrolytic cell according to one or more of claims 1 to 4, characterized in that the Distance between the neighboring anodes and cathodes for newly installed anodes is less than 10 mm. 6. Electrolytic cell according to one or more of claims 1 to 5, characterized in that the Electrolysis cell is equipped with a circulation pump. 7. Electrolytic cell according to claim 6, characterized in that the reaction space in or funnel-shaped against the direction of the electrolyte flow is extended and forms a funnel-shaped opening towards the electrolyte return space, in which a pump impeller which feeds the electrolyte in the axial direction is rotatably arranged. 8. electrolytic cell according to one of claims 6 and 7, characterized in that, in flow Seen direction, in front of the reaction space a perforated one arranged transversely to the direction of flow Plate is provided. 9. Electrolytic cell according to one or more of claims 6 to 8, characterized by one of the Pump delivering electrolytes against the direction of buoyancy. 10. Electrolytic cell according to one or more of claims 1 to 5, characterized in that in the lower part of the reaction space a perforated plate and one below the plate arranged supply pipe are provided for the electrolyte to be supplied gas. 11. Electrolytic cell according to claim 10, characterized in that the ends of the Anodes beveled on the inflow side of the electrolyte to avoid gas congestion are. For this purpose 2 sheets of drawings 509 629/361 7.65 © Bundesdruckerei Berlin