DE518687C - Process for influencing the strength of a precipitate generated from dispersions of rubber or rubber-like substances by means of the electric current on a precipitation surface - Google Patents

Description

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ISSUED ON
FEBRUARY 19, 1931

It has already been suggested that the strength of rubber precipitates made from aqueous dispersions can be achieved by means of an electric current at an anode, to influence by the fact that between the anode and the cathode screen walls made of electrically non-conductive materials turns on. The streamlines are deflected by these screens, but they work this screen was partially completely blocking and only distracting at its edges the streamlines, so that it is difficult to achieve a uniform one by means of such gutters Achieve distribution of the streamlines over the surface of the anode.

According to the invention, the grant should now be granted the streamlines across the surface of the anode by interposing electrically conductive ones Shields can be achieved between anode and cathode. These screens "condense the streamlines running from the cathode towards the anode and let them in more evenly Flow distribution towards the anode. This is illustrated in the schematic drawing

Fig. Ι the mode of operation of the screens arranged according to the invention, while
Fig. 2 and 3 show the formation of an electrophoretic rubber precipitate on a strongly curved precipitation underlay with and without a screen.

α is the anode, c are the cathodes, while the conductive metal screens connected between anode and cathode are denoted by s. The streamlines are indicated with broken lines.

In order to keep the gas bubbles released by the electrolysis at the cathodes away from the rubber deposit k formed on the anode, it has been proposed to separate the cathode from the anode by means of diaphragms d.

The screens are shown in Figure ι. S zwsichen the diaphragm and the anode arranged. However, in order to avoid a deposit of rubber on the conductive shielding plates, it is advisable to use the shields. to be arranged between the diaphragm and the cathode, since a rubber-free electrolyte can be used in the space containing the cathode.

A practical example of the effect of the screen acting as a central conductor is off Figs. 2 and 3 can be seen. If only one were to move to the convex side of a strongly

If the anode α (Fig. 2) would deposit a rubber layer, the thickness of the deposit α would be greatest at the points closest to the cathode c and would gradually decrease as the distance between the individual points on the anode surface increases. By switching on a screen ί (Fig. 3) curved similarly to the anode α between the anode and the cathode, the distance from the anode a gradually increasing as the distance between the individual points of the anode and the cathode decreases, one can obtain a perfectly evenly strong precipitate k . The interposition of the .metal screen ί does not slow down the deposition of the rubber, because the rate of deposition depends only on the current density used. The metal screen ί which is not connected to the power source does not affect the entire current density, but only the distribution of the same on the surface of the anode.

Of course, by choosing an appropriately designed cathode, it would be possible to achieve approximately the same effect as with a special metal screen which is arranged in the cathode compartment. Now, however, the wall of the vessel is mostly used as the cathode, so that there is no freedom in choosing the shape of the cathode. Even in cases where special cathodes are used, which are housed in a special electrolyte in a space separated from the anode compartment by a diaphragm, it is advisable not to adapt the shape of the cathode itself to the respective conditions of the formation of precipitates, but to use special metal panels Select. There are several reasons for this. For example, the cathodes are to be connected to the power source, while the metal panels do not require a power connection. Now it is common in mass production to hang a number of precipitation forms simultaneously in the bath as anode, which interact with a common cathode. A single current connection is therefore sufficient for the cathode. If one wanted to use a special cathode for each form of precipitation, one would have to provide a special power connection for each one. Outside \ the carbon electrodes are mostly used as cathodes, which have a much larger surface area than would be necessary for the regulation of the precipitate, namely, on the ground in order to avoid heating of the electrodes at higher current densities. The regulation can also be carried out more easily by means of the special sheet metal screen, which is more easily adapted to the respective needs and whose distance from the cathode and the form of deposition can be changed more easily than if one were only to operate with the cathode itself, especially since there are two Means, the cathode and the metal screen, for regulation in hand.

Of course, the process can · not only be used for natural, vulcanized or unvulcanized, optionally concentrated rubber milk can be used, which in If necessary, it may also contain additives, but also for vulcanized or unvulcanized, optionally also concentrated artificial aqueous rubber dispersions or any natural or artificial aqueous rubber dispersions Dispersions of rubber-like substances (such as gutta-percha, balata) as well as for artificial dispersions made from vulcanized or regenerated rubber and the like.

Claims (2)

Patent claims: 1. \ ^r learn to influence the strength of a precipitate generated from dispersions of rubber or rubber-like substances by means of the electric current on a deposition surface, characterized in that an electrical conductor of the first class is switched on as a screen in the current path between the cathode and anodic deposition surface, which is in no metallic conductive connection with the power source. 2. The method according to claim 1, wherein a cathode compartment from the anode compartment completely separating diaphragm is used, characterized in that the with the power source in none Metallic conductive connection electrical conductors first class in the Cathode compartment is arranged. 1 sheet of drawings BERMN- * 1! EDRrCKI * IN now