DE2435185A1 - BIPOLAR ELECTROLYTE CELL - Google Patents

Description

Patent attorneys Dipl.-Ing. F. Weickmann, 2435185

Dipl.-Ing. H. Weickmann, Dipl.-Phys. Dr. K. Fincke H / WE / LI Dipl.-Ing. F. A. Weickmann, Dipl.-Chem. B. Huber

Case 381 730

8 MONKS 86, DEN,

PO Box 860 820

MÖHLSTRASSE 22, NUMBER 48 39 21/22

<983921/22>

DIAMOND SHAMROCK CORPORAiDIOK ", 1100 Superior Avenue Cleveland,

Ohio 44114, V.St.A.

Bipolar electrolyte cell

The invention relates to a substantially vertical bipolar electrolytic cell, which is particularly useful for manufacturing of alkali metal hypochlorites and separated into a large number of cell units by horizontal partitions and contains a bipolar electrode component in which a perforated, U-shaped cathode part is formed so that it can adapt an edged anode, and wherein an edged anode part around the horizontal partition connected by a conductive part.

Alkali metal r-hypochlorite, especially sodium hypochlorite, are used a lot for bleaching and disinfecting, for example in the treatment of sewage systems. To the expensive ones Transport of hypochlorite solutions, mainly from

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! Water, and prevent premature decomposition during storage to avoid it is desirable, the necessary. Hypochlorite to form in the place of its use. It exists hence there is a considerable need for a compact, powerful electrolytic cell for the formation of hypochlorite, whereby this cell is operational for long periods of time and requires a minimum of maintenance.

The present invention is therefore based on the object of a compact electrolyte cell for the formation of hypochlorite to create with high power yields.

The subject of the invention is an electrolytic cell, which contains:

(A) a substantially vertically arranged container with electrolyte inlet openings in the lower part thereof and electrolysis product outlet openings in the upper part,·

(B) a plurality of horizontally arranged, electrically non-conductive partitions dividing the container into a plurality divide by cell units;

(C) a terminal, perforated, edge-like or foil-like (sheet-like), monopolar anode, which is in the first of the Cell units arranged horizontally;

(D) a terminal, holey, monopolar cathode disposed and containing horizontally in the last of the cell units a U-shaped member which is designed to receive and encompass a holey, ridge-like anode can;

(E) Devices to generate an electrolytic current along the monopolar Imprint electrodes; and

(F) containing at least one bipolar electrode

(1) an edge-like, holey anode part _{see p}

(2) a U-shaped, holey cathode portion designed to receive the ridge-like anode and may include, and

(3) a conductive connector that connects the anode and

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Cathode parts connects;
(G) wherein the bipolar electrode is arranged horizontally in adjacent cell units on opposite sides of a partition so that

(1) the anode part is encompassed by the next adjacent cathode and is arranged parallel to the partition wall, '""'.

(2) the cathode portion comprises the next adjacent cathode and parallel to ^ and separated from the opposite Part of the partition and the next adjacent partition is arranged, and

(3) the conductive connector is held between an edge of the partition and a container side wall will, and

(H) Means for conveying electrolyte and electrolysis products from the bottom to the top of the container through the cell units in succession.

Such a cell has the great advantage that the current efficiency is very high, obviously due to the relation of two cathodes to the respective anode, which is caused by the fact that each anode is surrounded by a U-shaped cathode. Another advantage relates to the long useful life of the cell in continuous operation, at least in part due to the fact that gas-liquid interfacial corrosion is avoided (since the cell is operated in a flooded state). Another advantage of the cell unit according to the invention is that the cell unit is easy to disassemble and replace, and that the various parts can also be easily repaired if necessary.

Embodiments according to the invention are illustrated with reference to the accompanying drawings explained in more detail.

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i Fig. 1 is a perspective view showing the relationship between the electrodes and the partition walls of an inventive Cell represents;

Fig. 2 is a vertical cross section of a typical one of the present invention Cell.

The invention basically relates to a vertically arranged electrolytic cell which is divided by horizontal partitions and where bipolar electrodes are used that run parallel to opposite sides of the partitions, and wherein the positive ends of the electrodes consist of foraminous areas or foils and the negative or cathode ends are also perforated and film-like or sheet-like, but bend themselves backwards and form a "U-shape", which includes the next adjacent anode sheet. Each unit cell defined by adjacent partitions contains one U-shaped cathode comprising a sheet-like anode or edge-like anode. Because the flow sequence of electrolyte and electrolysis product Running from the bottom to the top of the entire cell, each unit is essentially submerged operated.

The cells of the invention can be useful for the production of alkali metal, especially sodium and potassium, hypochlorites Used in concentrations in the range from 1 to 20 g / l by direct electrolysis of alkali metal chlorine solutions which typically have a concentration of 5 to 100 g / l. The problem of cathodic deposits in the Use of impure alkali metal chloride solutions is well known, and in view of the fact; "that in the present invention If two cathodes are used for each anode, it is desirable to use alkali metal chloride feedstock high purity, which avoids excessive backwashing. The operating conditions and typically, for example a pH of the order of 7 to 10, tem-

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temperatures in the range from 5 to 50 ⁰ C etc.

Based on the accompanying drawings, the invention can best explained. The vertical cell container is generally referred to as 1 and contains electrolyte inlet ports 3 near the Bottom thereof and an outlet opening 4 in the upper part for unreacted electrolytes and electrolysis products. The container 1 is divided into a variety of. Cell units by a variety by elektrisi

non-conductive partitions 9 divided. Building materials for the container and the partitions can be any be mechanically strong, electrically non-conductive and corrosion-resistant materials, such as polyvinyl chloride, chlorinated polyvinyl chloride, lucite and the like; Each partition 9 is substantially sealed with the four container walls Connected way - to avoid current leakage and electrolyte leakage. As will be explained in more detail below, one and generally a corresponding edge of each partition is connected to the container wall in such a way that it includes a bipolar electrode connector. Each partition 9 is "provided with facilities to electrolyte and To conduct electrolysis products from the cell container bottom to the upper part thereof through each unit 7 in turn. Typically and conveniently these means simply consist of one or more holes 11 in diagonally opposite one another Corners of the partition walls 9 are attached to create a curved flow path, and thus a suitable one Ensure circulation and mixing with minimal current leakage.

In the first cell unit 7 ′, a perforated, dimensionally stable, monopolar, terminal anode 13 is horizontally connected to the power supply devices 15. Correspondingly, in the last cell unit 7 ″ a horizontally arranged, perforated, ″ U-shaped, monopolar, terminal cathode 17 is attached separately from the partition wall 9 and with current collection devices 19

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tied together.

An electrolysis current can thus be injected along the current devices 15 and 19. It is obvious that the polarity of the terminal electrodes in the cell units 7 'and 7 "may be reversed, that is," that the monopolar anode 13 may be present in the last cell unit 7 ". It is also not necessary that the first and Last cell units are formed by two adjacent partition walls 9, since the first partition wall and the bottom of the container can well ^{define or delimit the first cell unit 7 1} , and the last partition 9 and the cell container lid can delimit the last cell unit 7 ″.

In the illustrated embodiments, the terminal anode 13 and the terminal cathode 17 are with the current devices 15 and 19 connected around a partition edge by conductive connecting parts 33 and 35 «, other arrangements, such as a direct extension through the container wall 29 to the external flow device is also possible.

Between the terminal electrodes is at least one bipolar electrode, which has a perforated, edge-like or foil-like anode part 21, a U-shaped, holey cathode part 23, which is designed so that it can accommodate and encompass the edge-shaped anode _s and a conductive connecting part 25 that connects the anode and cathode parts. From the drawings it can be seen that the U-shaped cathode part 23 of the bipolar electrode in the first cell unit '7' comprises the terminal anode 13, both the terminal anode part 13 and the cathode part 23 being essentially parallel to the partition walls 9, which the Cell unit 7 ⁸ form, run, cathode part 23 is attached remotely from the partition walls 9, and partition parts 27 made of an electrically insulating material are suitably used. In the

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In the next adjacent cell unit 7, a bipolar anode part 21 is encompassed by a cathode part 23 of the next bipolar electrode in rows; both are removed again and arranged horizontally to the partition walls 9. Will only be two cell units. For example, the cell units 7 ¹ and 7 ", used in a particular cell, the anode part 21 of the bipolar electrode is encompassed by the terminal U-shaped cathode 17. It should be mentioned that the number of cell units and thus the bipolar electrodes is only practical mechanical considerations and the desired production to be obtained from the whole cell is limited, with containers of 2 to 25 cell units being typical.

The anode and cathode parts of each bipolar electrode are connected to one another by electrically conductive connecting parts 25 connected, which are substantially perpendicular to the horizontally arranged anode and cathode parts and that between an edge of the partition wall 9 on opposite sides where the anode and cathode parts are attached, and a container wall 29 are attached. Appropriately, and to ensure a seal, (i.e. a substantially liquid tight. Arrangement), seals 31 can be provided between the wall 29 and the partition edge 9. Alternatively each partition end may be notched to receive the connector 25, with any leakage occurring caused thereby is negligible.

A variety of materials can be used to construct the bipolar electrodes. In general, these are dimensionally stable Electrodes that are necessarily perforated to ensure proper electrolyte circulation and gas release, and which are essentially planar or foil-like or sheet-like, i.e. edge-like in their construction. The anode part can be made from any conductive, resistant material that contains a coating that is suitable for the desired

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The reaction has an electrocatalytic effect, for example expanded titanium metal which is coated in a manner known per se with a metal of the platinum group, with a metal oxide of the platinum group or in a similar manner. The cathodic part must also have suitable physical and electrochemical properties and it can be made of, for example, expanded titanium metal or palladium-titanium alloy (0.2% Pd), perforated stainless steel or nickel, or any of the aforementioned metals coated with an electrocatalytic material ( for example a metal of the platinum group) or not coated. The connecting part can be any conductive, corrosion-resistant combination of those described above, it need not be electrocatalytic. For mechanical simplicity, the bipolar electrode can consist of a continuous sheet of expanded (e.g. titanium) metal which ^{is bent to the appropriate n} S-shape ^H and contains an electrocatalytically active (e.g. metal oxide from the platinum group) coating on the anode part and on the cathode part is not coated. On the other hand, the electrode can be discontinuous in the sense that the anode part is made of expanded (titanium) metal, butt welded to perforated stainless steel connector and cathode parts. Other variations are familiar to the person skilled in the art.

To keep the anode-cathode gap as minimal as possible, as required for efficient operation, for example 0.05 to 0.25 cm (0.02 to 0.1 inch), preferably about 0.076 cm (0.03 inch), with no electrical short circuit occurring in the If anode-cathode contact occurs, spacers that maintain this gap can be used. A simple one and effective spacer "can simply consist of a flexible" shoelace "made of inert polymer, which is inserted into the holey Electrodes is woven in to maintain the gap without significantly disrupting the electrolyte circulation.

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Claims (6)

Claims An electrolytic cell containing: (A) a substantially vertically arranged container with electrolyte inlet openings in the lower part thereof and electrolysis product outlet openings in the upper part; (B) a plurality of horizontally arranged, electrically non-conductive partitions that divide the container into a Divide plurality of cell units; (C) a terminal, perforated, edge-like or foil-like, monopolar anode, which is arranged in the first of the cell units .horizontal; (D) a terminal, holey, monopolar cathode, arranged horizontally in the last of the cell units and including a U-shaped member which is formed so that it has a holey, edge-like anode can include and include; (E) devices to generate an electrolysis flow along the impress monopolar electrodes; and (F) at least one bipolar electrode containing: (1) an edge-like, holey anode part, (2) a U-shaped, holey cathode part, which is so is designed that it receive the edge-like anode and may include, and (3) a conductive connecting part which the Connects anode and cathode parts; (G) the bipolar electrode being placed horizontally in adjacent cell units on opposite sides of one Partition is arranged so that (1) the anode portion is encompassed by the nearest adjacent cathode and parallel to the partition 409886/1073 - ίο - is arranged (2) the cathode part is the next adjacent cathode comprises and parallel to and separate from the opposite part of the partition wall and the next adjacent partition is arranged, and (3) the conductive connection part between an edge of the partition and a container side wall I kept and (H) facilities to electrolyte and electrolysis product from the bottom to the top of the container through the cell units in succession. 2. Cell according to claim 1, characterized in that the bipolar Electrode contains a continuous foil or "a continuous sheet of expanded titanium mesh, the anode portion thereof including an electrocatalytic coating on the surface. 3. Cell according to claim 1, characterized in that spacers are provided to keep the anode and cathode parts away from the partition walls. 4 »Cell according to claim 1, characterized in that spacers are provided between each anode and its encompassing cathode to provide an anode-cathode gap. 5. Cell according to claim 1, characterized in that a seal is provided between the container side wall and a separating end, so that the connecting part of the bipolar electrode is held sealingly between the edge wall and the seal. 6. Cell according to claim 1, characterized in that the bipolar Electrode contains an anode part made of expanded titanium metal, which with an electrocatalytic material 409886/1073 is coated and serves the cathode parts made foraminous, stainless steel, nickel and / or palladium-titanium alloy to join. 409886/1073 Blank page