DE393997C - Electrolytic cell - Google Patents

Description

The invention relates to improvement

electrolytic cells and particularly concerns electrolytic cells used for industrial Production of oxygen and hydrogen by electrolysis of water are suitable.

With the usual form of cells used for this purpose, it turned out to be uneconomical To use electrodes deeper than a certain limit, since,

ίο if very long electrodes are used, the gases generated at the lower parts of the electrodes as they rise above the Surface of the plates reduce the conductivity of the electrolyte so that the upper Parts of the electrodes are not doing useful work.

Since the depth of the cells is thus limited, it follows that in large systems the number of cells that are necessarily used must take up a very considerable floor space and great gifts for housing the batteries, the required electrical wiring material and the circuits claim, which must be of strong construction to meet the large required Withstand currents.

The invention is an improved form of electrolytic cells which extremely is compact 'and in which the floor space used is a minimum. The cell after the invention also has the advantage that a very uniform current distribution over the Electrodes is achieved, from which a high efficiency of the plant and great purity of products while the number of electrical circuits and conductors required for one Battery required of cells is reduced to a very considerable extent.

The invention consists essentially in that a number of cells are placed one on top of the other are that the electrodes of the same polarity of one cell on the bottom plate of the overlying cell are attached or formed from this base plate and on the same Bottom plate attached the electrodes of opposite polarity for the cell above or are formed, etc. through the whole series, which relate to z. B. 9 or 15 Cell stages can expand. For example, the negative electrodes of the bottom cell or step of a vertical row are formed as panels extending from the horizontal wall hang down or are formed from it, which the bottom of the second or next higher Cell forms. This wall also has a series of parallel,

stretching plates that form the positive electrodes for the second cell. The negative Electrodes for the second cell are then formed by parallel plates, which consist of the Hang down the bottom of the wall forming the third cell \ and alternate with the positive plates. The current thus goes directly from each cell to the cell above without external conductors or connections, where ίο the polarity when the current passes through one cell is switched to the next and the only electrical connections which are required, at the bottom of the lowest cell and on the lid of the uppermost cell of one Vertical row.

The top cell of each column or row of vertical groups or series can be of opposite Polarity must be that of the top cell of the next series, so that the current can be passed directly from each top cell to the neighboring one. With this design the lines are reduced to a minimum, as apart from the connections to the first and last cell of a row or column the only necessary connections are those between the top cells and alternately the bottom cells of adjacent vertical groups or series are.

A partition is attached to each cell near its upper end, which is depending Sleeves or diaphragms made of porous material, which surround the electrode plates of one polarity, so that the to the Electrode plates of opposite polarity generated gases are separated and in Header pipes can be derived in any way.

A preferred embodiment of the invention is illustrated in the drawings, in which Fig. Ι is a vertical longitudinal section through a vertical series or group of cells;

Figure 2 is a vertical section on line 2-2 of Figure 1;

Figure 3 is a horizontal section on line 3-3 of Figure 1;

Figure 4 is an enlarged section of a portion of the base of a cell showing various Method of insulation for the electrode ends hanging down from the bottom plate of the cell.

Like letters refer to corresponding parts in all drawings.

Each vertical series or group of cells consists of a number of cells a, b and c, placed one on top of the other, in the shape of a box or tub, any means may be provided to feed the cells with electrolyte. The bottom plate of the lowest cell c is provided with feet or flanges by which the row is supported on suitably insulated blocks ä , and a series of parallel ribs e projecting downwards form connections for the electrical current which is passed to them through copper rods or strips f attached to rib c by bolts. Parallel electrode plates g, which preferably decrease in thickness upwards, protrude upwards from the bottom plate inside the cell and cause the whole cell to be divided into a number of small narrow cells, each of which is energized through one of the ribs t ' is supplied. The upper end of the cell c is formed by the lower part of the next cell b above it, from which electrode plates h , similar to the electrodes g, hang down in an alternating arrangement with these, the plates h extending up to a small distance from the floor the cell c extend. Another series of parallel plates / extends upward from the bottom of cell l>, alternating with plates k, which hang down from the bottom of the next cell above. Each cell in the row is shaped in the same way until the top cell a is reached, the lid of which has hanging electrode plates / and ribs m parallel to the outside, to which copper power leads are connected by bolts in the same way as with the lower ribs c has been described.

The procedure for separating the gases generated in the cells is exactly the same for each cell and may be described with reference to the lowest cell c .

A horizontal partition member or diaphragm n, insulated from the cell up and down, lies a small distance below the bottom of cell b and has a series of depending tubular flanges 0 surrounding slots or openings through which the depending electrodes h go through. The flanges 0 carry porous depending diaphragms or sleeves p made of asbestos, gauze or the like, which surround the electrodes h and separate the gas generated therein from the gas generated at the electrodes b and rising from them. The gas generated at the electrodes h sweeps upwards through the partition wall or the diaphragm η into the space between the partition wall and the bottom of the cell b, and from this space the gas is discharged into a vertical collecting pipe q , which is connected by a fitting a socket; · is connected, which is cast or otherwise attached to the upper end of the cell.

The gas generated at the electrodes q is prevented by the diaphragms p from passing through the openings in the wall η and collects under the wall, from where it passes into a second collecting tube s. The collecting

tubes q and s take the gas of the corresponding electrodes of all rows of a vertical row or group, the tubes in mutually insulated sections between the individual cells by inserting short pieces of pipe t made of insulating material, such as. B. glass, are divided. Since the pipes are only exposed to the potential difference between two neighboring cells, the insulation pipes are required

ίο only have a short length, as in Fig. ι shown.

Another piece of insulating tube u is connected between the vertical tubes and the connecting pieces, through which these are connected to the main collecting gas lines w and ν , which receive the gases from a row or battery of cell groups.

If the lower edges of the electrode plates h are spaced sufficiently far from the bottom of the cell, insulation between the electrode and the bottom of the cell is not absolutely necessary. However, if desired, insulation can be provided in one of the ways shown in Fig. 4. ■

At χ a bowl-shaped layer of insulation material is shown lying on the bottom of the cell and also extends a short distance up the sides, while at y a flat strip of insulation material is shown lying on the bottom of the cell. In the other embodiments, metallic protective members ζ are held on narrow strips of insulation material 3.

Another embodiment, in which the insulation can be completely dispensed with, consists in that the diaphragms or sleeves j> below the lower ends of the electrodes h are completely or almost completely closed. In the illustrated embodiment, the electrode plates g, projecting up from the bottom of each cell, extend to the sides of the well or cell so that the cell is divided into a number of smaller, narrow cells , as shown in FIG. This construction achieves an extremely strong cell, but suffers from the inconvenience that the electrolyte must be specially supplied to each of these smaller cells and that it is difficult to ensure an equal level of the electrolyte in each cell.

In a modified construction, the electrodes g are not led to the sides of the cell or well, but have the same width as the electrodes h. This construction is not as strong as the constructions shown in the figures, but allows free circulation of the electrolyte, which can therefore only be fed to one point in the entire cell. It will be appreciated that, instead of completely separating these electrodes from the sides, they could be interconnected with them by pieces of tissue. This gives the construction strength without disturbing the circulation of the electrolyte through the entire chamber.

The embodiment described and illustrated is as an example of implementation of the invention in practice and various modifications may be made in the Details and general design are attached, deviating from the essentials Characteristics of the invention deviate.

Claims (4)

75 patent claims: 1. Electrolytic cell for the production of oxygen and hydrogen by water decomposition, characterized in that a number of cells are stacked and power supply lines are arranged at the upper end of the uppermost and at the bottom of the lowest cell, the current directly through the column of cells from each cell to the above or below with a change of polarity between two lines . 2. Electrolytic cell according to claim 1, characterized in that the partition wall parallel electrode plates hanging down between two cells in alternating fashion and cooperating with parallel electrode plates extending upwardly from the partition wall between the lower cell and the next cell underneath, this partition wall in turn depending Electrode plates for the underlying cell carries. ioo 3. Electrolytic cell according to claim 2, characterized in that the of the Lids of each cell, depending on the electrodes, pass through openings in an intermediate wall, which is tubular Wear diaphragms or sleeves surrounding the pendent electrodes. 4. Electrolytic cell according to claim 3, characterized in that a collecting tube the gas generated at the electrodes of the same polarity of each cell in a vertical row receives, the collecting tube in the number of cells corresponding sections, which are isolated from each other, is divided. For this purpose ι sheet of drawings.