DE6607393U - ELECTROLYSIS CELL WITH FLEXIBLE LID AND DEVICES FOR FASTENING AND REGULATING THE ANODES INDEPENDENT OF THE LID - Google Patents

Description

PATENT LAWYERS

DR.-ING. R. DÖRING DIPL.-PHYS. DR. J. FRICKE

BRAUNSCHWEIG MUNICH

5226 D / Mr.

Dr. Vittorio de Nora Milan / Italy
Via Bistolfi 35

"Electrolysis cell with" flexible cover and devices, to "attach and close" the anodes independently of the cover regulate "

The present invention relates to electrolytic cells for the electrolysis of solutions, especially a new type of cover for such cells and a new type of Fixing the anodes of these cells.

If the invention is also suitable for the special pallet of horizontal Mercury cells is described as soli doeb. clear be that the scope of the invention can extend to all cells; be it Diapnragma cells or mercury cells » be it for -aqueous electrolytes or for molten ones Salts.

The present invention relates to attaching the anodes to a sturdy framework that is on the side walls the cell or on a separate external support.

The invention also relates to the use of a flexible lid between the upper band of the cell tray and the rigid supporting structure is installed. Known cells, usually called horizontal mercury cells, consist of a closed, elongated tub with a light Slope lengthways.

The cathode consists of a layer of mercury which is introduced at the upper end of the cell and which flows in at the bottom along the lower end of the line. The anodes are usually rectangular sheets of graphite suspended from graphite or copper rods of the kind. that their lower surface is at a slight distance above the cathode mercury. The base and the side walls of the cell tray are mostly made of iron, which is clad with a corrosion-resistant material such as hard rubber, cement, stone or another non-conductive material. f

The lining can be made of cement which is then covered with resin or which contains sand or stones.

The electrolyte for the operation of this cell can be the aqueous solution of any chemical compound produced by electrolysis can be broken down into the desired products. It is inserted at the top of the cell and flows to the bottom End of the cell. For example, a solution of sodium chloride can be electrolyzed in this way. In this case it forms

at the anode Ohlorgas, which is in the upper rope of the cell accumulates and from there through a corresponding opening in the lid leaves the cell.

The sodium forms on the cathode and alloys with the mercury. The sodium amalgam is at the bottom of the Cell peeled off and placed in a graphite-filled amalgam disintegrator in which the amalgam reacts with water to form sodium hydroxide, hydrogen and mercury. The mercury is sent back into the cell and serves as a cathode again. It is clear that this cell is also suitable for electrolysis of potassium chloride, barium chloride, lithium chloride, sodium sulfate and similar salts is suitable. Is of great importance to In this type of cell the distance between the graphite anodes and the mercury In order to keep the energy as small as possible To keep this distance must be kept as small as possible; but if, on the other hand, it is' too small, secondary reactions take place takes place, especially the attack of chlorine, which is present in the form of gas bubbles, on the amalgam. In the previously known Cell types are usually the anodes made of graphite, mostly using graphite rods on the power supply lines attached, in such a way that, when the lid is in its correct position, the anodes the most convenient distance from the cathode have.

Usually the cover consists of a sufficiently strong, rubberized sheet of iron, which is able to hold the anodes and their electrical ^ _ _r .., _, .., _

Sometimes lids made of ceramic material or hard rubber are also used, but these must be "particularly strong, to be able to carry the anodes.

The graphite anodes and are used up during operation as a result, the distance "between the anodes and the cathode increases, thereby reducing the consumption of electrical energy is increased. With the cells built so far, it is for the Adjustment of the electrode gap is essential, every single one Regulate anode. Another disadvantage of the previous cells is that they can be used for checking the cell or for repairs in the line is aotig, the. Cover absuneiiiiien. and up change all anode settings in this way. In make The position of each individual anode relative to the cover can be varied, but this work is generally quite demanding complicated devices »

An attempt was made to help the problem of electrode spacing Loosen the multi-part spacers between the cover and placed its pad on the cell walls and from those of. From time to time, depending on the consumption of the anodes, certain Ropes are removed so that the cover comes to rest each time lower and the distance between the graphite electrodes and the cathode is reduced accordingly. However, even in this way it was not possible to obtain a sufficiently precise anode division to reach.

With άβη currently standing in Sebzaueh the anodes individually attached to the ceiling, which in turn rests on the cell walls. . The anodes become theirs individually Location after set.

One of the features of the present invention is to provide a to use strong supporting structure for the anodes, which allows the anodes to be regulated individually or all at the same time.

Another feature of the invention is a flexible lid made of rubber or plastic material or any other material used for cell control purposes can take off without canceling the setting of the anodes and in which one on the other hand has the option of setting the anodes while maintaining the seal between the cell lid and the cell.

Occasional explosions can occur in horizontal mercury cells occur due to chlorine water mixture, which can damage both the lid and the anodes and under Danger to workers can occur under certain circumstances.

Finally, a further feature of the invention is a lid that eliminates any explosions in the cell without serious damage for the lid or the anodes.

Another feature of the invention is a support device for the anodes, which are on the outside of the cell tray and is supported independently of the cover.

The invention Afc essentially in the following description, which refers to the accompanying figures. It relates to a preferred embodiment.

Fig. 1 is a perspective view partially cut away View of an electrolytic cell according to this invention and the associated amalgam decomposer.

Fig. 1a shows a perspective and on an enlarged scale * ■ Part of the anodic power supply.

Fig. 1b shows a perspective and on an enlarged scale Part of the anodic power connections of Figure 1a.

Fig. 2 shows a cross section along the line 2-2 of Fig. 1, partly in elevation.

Figure 3 shows a cross-section of the tine along line 3-3 of Fig. 1, partly as a view.

3a shows a variant for supporting the anode support framework outside the lid and independently

J from the cell pan.

4 and 5 show some variants of the attachment of the Lid on the cell tray.

The figures show that the side walls of the cell are preferably made of iron supports 1A and that the cell bottom 1 B is made of sheet iron.

The side walls and the cell floor are clad with natural stone slabs 5 which are embedded in mortar 6. You can also by another gd ^ ö'iHießiJiaekeH. Attack resistant material

V "w ü ι W ν w £ 3 ΐ / 1

■ be clad, e.g. with a suitable synthetic resin.

The floor of the cell carries elements 9 made of iron I-I girders, which are connected to the floor 1B, at regular intervals and those as strangers between the flowing mercury serve on the cell bottom and the negative conductor 12. The anodes consist of horizontal graphite plates 8, supported of vertical graphite rods 27, which in turn atäben with metal round 30 are provided. The metal rods 30 effect the positive end connection between the rail 11 and the iDragges part.

This latter consists of a metal cross 15, which is composed of the transverse part 20 and the longitudinal part 21 attached to it. The cross rails 20 rest on the supports 19 and are adjustable. The supports 19 are on the side walls 1A or can be on other strong supports, that are not attached to the cell tray, rest. The supports 19 carry the adjusting nuts 22, the e «j allow the height of the cross 15 and thus the height of the anodes attached to it. To the Lifting off the frame 15 including the anodes attached to it, appropriate devices are provided on this frame, e.g. the hook 32.

On the side members 21 are at the appropriate intervals the sheet metal strips 40 attached to the anode suspension while

the Atxoden 8 to the Siechstreifen 40 by means of the thread provided Stäae 30 and the screw nuts 31 are attached.

As you can see in Fig. 3a, the can paralyze 15 instead of the Rest the side walls of the cell with the aid of the supports 19A on a base lying outside the cell tray. The main requirement is that the frame 15 in a fixed position relative to the cell heat and can be adjusted relative to this.

As FIG. 1 shows, the cell cover is subdivided into the three parts A, B and C ^{by means of the transverse parts A 1} and B ^{1, which extend over the upper part of the cell tray.} The anode supporting cross 15 is divided into three parts corresponding to _f so that each of these parts decrease separated from the other, and can adjust.

The cover 17 made of flexible material, through which the connections 30 to the anodes pass, closes the upper part of the cell and is screwed to the side walls and to the transverse dividing strips A ¹ and B ¹ with the sheet metal strips 24 in between.

Other fastening aids can also be used, such as the press-fit feet 24A connected to the support frame 15 by means of the parts 24B, as shown in FIG. The cover can also be fastened by means of the feet 24, which with the arms 242 of the support frame 15 ver & iß7äS3,2So2d2S against the cover film 17

the side walls 5 of the cell is pressed. However, in this case you cannot open the cell cover without the support frame 15 to lift away. Between the graphite rods 27 of the anodes, the bolt 30 and the cover 17 are provided with suitable seals, the escape of gas or the entry of air to prevent. Either one is required for the chlorine gas to escape Opening provided in the cover 17 or an opening through a side wall of the cell above the level of the electrolyte (in the prop. Not shown.)

The copper bars 12 establish the electrical connection to the cathode via the cell bottom 1B and the iron bars 9, which are connected to the base plate 1B and into the lining are embedded and which in turn are in contact with the mercury flowing on the cell floor (s)

For the anodes 8 and electrical connections via the rails 11 are provided, which are connected to the rail 16.

These latter are attached to the graphite rods 27 of each anode with the aid of the cross bars 28 and the nuts 29 to the Round bars 30 connected (see Fig.ia and 1b).

With the help of this device you can adjust the Parts 19 and 22 adjust all anodes attached to the support frame 15 at the same time without changing anything on the cover 17. In this way it is possible to keep the most expedient between the lower surfaces of the anodes and the mercury cathode Keep your distance.

• ·

-Fig. 2 shows, on an enlarged scale, a detail of the electrical connections between the rail 28 and the rail 16. FIG Separation points A ¹ and B 'of the cell are attached.

When the cell is in operation, the line 10 is used to reduce the mercury (Pig.1) introduced into the cell compartment 43 and flows under the partition wall 43A into the electrolysis compartment.

The concentrated electrolyte solution is fed through the inlet line 41 to the end of the cell which is close to the amalgam disintegrator 2 fed. The mercury and saline solution flow to the other end of the cell while the electrolysis process continues takes place in the cell. The Ghlorgas is through one. Outlet nozzle, expediently in the cover, pulled off and the diluted salt solution leaves the cell at the lower end of the line through the line 42. The amalgam passes under the Partition 45 over into the open cell compartment 46 and flows through the line 33 via a siphon 34 to the amalgam separator 2, in which the amalgam with water to form Hydroxide and hydrogen and reacts with regeneration of the mercury. The amalgam separator 2 is water over the Line 35 supplied. The hydrogen escapes through the pipe 36 and the alkali solution flows out through the pipe 37. That Mercury leaves the amalgam disintegrator through line 38

and is with the help of the pump 39 through the line 10 in the Cell returned.

While the invention has been specifically described, there is no doubt that it does not apply to that embodiment limited and that different designs are possible without departing from the spirit and scope of the invention *

Claims (6)

1. Electrolytic cell, characterized in that the anodes on an outer and from the cover independent. Tragverrichtung "are attached and that the Lid made of flexible material "through which the rods for the holder and for the supply of electricity go through it in such a way that a tight seal both arise at the cell edge as well as at the passage parts of the anode rods. 2. Electrolytic cell according to claim 1, characterized in that the anode shark tevo rri chtungen can be regulated, so that the simultaneous regulation of all anodes in relation to the Kathodenob he area the cell is possible. 3. Electrolytic cell according to one of the preceding claims, characterized in that each single anode on the ^ carrying device with the help of a special adjustment device is attached, which is independent of the position of the overall support device and the other anodes is working. 4. Electrolytic cell according to one of the preceding claims, characterized in that the Anode support device is attached to the cell body. 5. Electrolytic cell according to one of claims 1, 2 or 3, characterized in that the anode support device is not attached to the cell body. 6. Electrolytic cell according to one of the preceding claims, characterized in that the Anode carrying device in several independent ones Parts is divided.