CH197856A - Electrolytic water decomposer. - Google Patents

Description

  

  Electrolytic water decomposer. The invention relates to an electrolytic water disintegrator; On the one hand, it aims to quickly compensate for the differences in concentration of the electrolyte in the cathode and anode spaces that occur during electrolysis. On the other hand, it also enables significant material and cost savings. According to the invention, these advantages are achieved in that the cathode compartment of each cell is dimensioned smaller than the anode compartment. This can be achieved in a simple manner in that an electrode sheet is only used in the anode compartment.

   In the case of electrolytic water decomposers of the frame type, the different dimensions of the electrode spaces in each cell can also be made easier by using frames of different widths.



  In the drawing, an execution example of the invention is shown. A number of frames are arranged between two boundary plates 1 and 2 with sealing material 3 in between. The frames are pressed together in the usual way by a clamping device not shown in detail. In the example, frames of different shapes and different cross-sections are used. The frame of a group consist of U-shaped ge bent flat iron 3e of a relatively large width, in which a band iron 3 f inserted and z. B. is attached by welding, so that the free ends 3g of the U-piece 3e protrude to the outside.

   The frame of the second group consist of U-shaped bent flat iron 3a of kleini nerem cross-section or of solid metal, the open respectively. one side is covered by an appropriately welded iron strip 3b. The ends 3c of the iron band 3b protrude from the side and serve as support surfaces for the z. B. made of rubber seals 3. Inside the frame are the outer electrode sheets, which are connected to the power source and a total of three intervening electrode sheets 4 are arranged.



  In order to make the cathode chambers 5 considerably smaller than the anode chambers 6, a sheet metal 4 'is attached to each sheet electrode plate 4 with the exception of the right outer electrode on the anode side, which is brought up to close to the associated diaphragm 7. Half of the pre-sheets arranged on both sides of the inner electrode sheets are therefore eliminated. This results in a not inconsiderable amount of aluminum material saving, which is further increased by the fact that, as already stated above, part of the frame is less thick than the other part of the frame.

   The reduction in size of the cathode compartments 5 compared to the anode compartments 6 causes an increased circulation of the liquid in the cathodes due to the increase in the upward movement of the hydrogen in the cathode compartment during operation of the water decomposer. The anolyte is sucked in, and as a result there is a comparatively very rapid equalization of the concentration differences that develop during the electrolyte conversion in the cathode and anode spaces.



  U-irons 8 are attached above the electrode spaces, into which the gas collecting containers 9 are inserted with an interposed seal, expediently an asbestos cord. In each of the gas containers 9, a partition 10 is provided, which is also supported on a U-iron. To avoid current passage between the gas containers 9 locking plates 11 are arranged between the containers.

    The U-irons 8 on which the partition walls 11 of the gas containers 10 are supported also serve to fasten the diaphragms 7 on one side. The other ends of the diaphragms can be placed between the frames 3a, 3e and the seal 3 be inserted.

 

Claims (1)

PATENT CLAIM: Electrolytic water decomposer, characterized in that the cathode space of each cell is smaller than the anode space. SUBClaims: 1. Electrolytic water decomposer according to the patent claim, characterized in that only the anode side of each bipolar electrode (4) has an upstream electrode (4 ') connected to it in a current-conducting manner. 2. Electrolytic water decomposer according to patent claim and dependent claim 1, characterized in that the anodically effective electrode surface of each electrolytic cell is brought closer to the diaphragm (7) than the cathodically effective electrode surface.