KR830000063Y1 - Aqueous Electrolyzer of Metal Salt - Google Patents

Abstract

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Description

Aqueous Electrolyzer of Metal Salt

The accompanying drawings show an embodiment of the present invention,

1 shows a basic configuration of a bridged electrolytic apparatus.

2 is a diagram showing the progress of a current corresponding to the PCR method in the bridge connection.

3 shows an electrolytic device with rectification in a three-phase AC bridge connection.

4 is a diagram showing a connection state of the rectifier.

The present invention relates to an electrolytic device for separating metal, particularly zinc, from a water soluble electrolyte by regularly supplying the electrolytic current of the rectifier and a reverse current within a short time.

This type of electrolytic device and a reversible rectifier acting as a rectifier for electrolytic recovery in the copper are provided, whereby an electrolytic current is generated in a short time by appropriately adjusting the electrolytic voltage.

The periodic decomposition by electrolytic current through a short time reverse current is known as PCR method (electric reverse current) (French Patent Nos. 1,412,438 and German Patent No. 2,650,589).

This German patent publication discloses this, and this PCR method relates to a method for separating by electrolysis on a metal other than copper.

In addition to refining copper, devices for the recovery of other metal electrodes can be made using a variety of fabrication materials, which produce high polarization voltages.

This polarization voltage causes a high short-circuit current through the operation of the rectifier, and the network voltage drops during the reversible current operation of the reversible rectifier.

This short-circuit current destroys the configuration and safety device of the reversible current, and therefore, a quick switch and an over-bridge bridged reversible rectifier must be installed.

This not only requires a lot of additional reactions with increasing space, but also introduces undesirable side effects such as overvoltage and short circuit in the rectifier transformer.

Therefore, an object of the present invention is to devise a novel electrolytic device to prevent the north pole voltage from increasing, and to eliminate the side effects generated therefrom.

In addition, an object of the present invention is to install a rectifier on the bridge connecting portion of the electrolytic cell and the diagonal line of the bridge connection, one of which is a rectifier of electrolytic current, the other of which supplies reverse current in a short time. It acts as a reversible current group, thereby effectively separating the zinc.

One bridge connection is achieved through electrolysis and rectification of the rectifier, i.e., if the reversible rectifier in the straight state in the critical phase induces the flow of polarization voltage, the polarization voltage of the bridged battery is equal, and thus No current is applied above the reversible rectifier.

Next, the present invention will be described with reference to the drawings.

In FIG. 1, in the electrolytic apparatus, 1 to 4 electrolytic cells are arranged from A to D, and rectifiers 5 and 6 show arrangements of E and F diagonals.

The rectifier 5 rectifies the electrolytic current as a rectifier, and the rectifier 6 rectifies the electrolytic current and reverse current in a short time as a reversible rectifier.

The two rectifiers are equipped with a thyristor (7).

The power supply and control device for the rectifier is shown in the schematic drawing.

2 shows the path of the current J in A to D through control of the rectifier by the PCR method.

For example, FIG. 2 shows providing four bridged electrolytic currents at time t ₀ of rectifier 5.

At time t ₁ , the rectifier is shut off, so that the current in the rectifier drive returns to zero.

Here, in supplying a short current impulse to the reversible rectifier during the time points t ₂ to t ₃ , a direct current is supplied as if a reverse current is applied in A and C, and an electrolytic current is applied in B and D.

After the current impulse gradually dissipates, the reversible rectifier occurs at a short time t ₄ to t ₅ , and in A and C, the current in the direction of the electrolytic current, while in B and D the current reaches the electrolytic reverse current. Move.

At time t ₆ , the rectifier restarts the electrolyzer through the electrolyzer and returns to zero at time t ₇ .

Thus, this periodically repeats the running movement in the sections t ₂ to t ₇ .

Reversible rectifiers are sometimes rotated in a very short time, thus making the measurement possible.

As described above, the reversible rectifier for the RCR method does not use electrolysis by copper, and separates zinc by other metal electrolytes when electrolysis with high polarization voltage is performed without using a separate protective means. It becomes possible.

This is because a short circuit current occurs in the rectifier when the network in the vicinity of the reverse current drive device is dropped and the rectification of the current from the rectifier phase to the next phase is no longer possible.

In the bridge connection of an electrolytic cell, when a failure occurs, it does not flow all the way through a short-circuit current through a reversible rectifier, whereas the sum of the polarization voltages on the bridge diagonal is equal to zero.

The number of electrolytic cells in each bridge A to D must be equal, so that for each current ring line, the sum of the polarization voltages will be zero. Therefore, the number of base plates may be equivalent, and thus the metal is separated, and the charge of the battery and the battery obtained therefrom is relatively large.

3 shows the basic structure of an electrolytic device with bridged electrolytic cells 1-4 and attached rectifiers 5, 6 with a three-phase AC bridge connected thyristor 7.

The rectifier 5 and the reversible rectifier 6 are alternating current AC lines 8 and are connected to the secondary coils of the rectifier transformer 9 by the rectifier transformer 9 and the reversible rectifier 6.

The primary coil of the transformer is connected in series to the power switch 10.

The rectifier of the three-phase ac intake connection is operated and the transformer then supplies the secondary coils for the rectifier and the reversible rectifier.

4 shows a rectifier 5 and a reversible rectifier 6 in the phase of the associated common AC line 8, with a unique forming point line on the rectifier side for each of the rectifiers 5 and 6. (11) and (12) are shown.

Claims (1)

In the electrolytic device for supplying the electrolytic current and a reverse current against it in a short time by a rectifier, and separating metal, especially zinc, from the aqueous electrolyte, the bridge connecting portions (A to D) and the diagonal lines (E, F of the bridge connecting) The rectifier (5, 6) is divided into (), and the electrolytic current is always supplied in the rectifier (5), and the reverse current in a short time in the reversible rectifier (6).