SU602615A1 - Device for group monitoring of electrolyzer current diagram - Google Patents

Description

(54) DEVICE GROUP CONTROL DIAGRAM CURRENT ELECTROLYZER

The invention relates to the field of automatic control of the process of electrorefining and electroplating of metals and can be used to control the electrical mode of the electrolyzer.

A device for group control of a current diagram of an electrolytic cell is known, comprising a magnetic flux sensor of a cathode rod with sensitive elements in the form of inductors with cores made of soft magnetic material, an indication circuit with a switch 1.

The known device is not sufficiently resistant to interference, unavoidable in electrolytic workshops, and requires a lot of time for drying, measuring.

In order to improve noise immunity and reduce the monitoring time, the proposed device is equipped with an auto-oscillator, a graduated pulse driver, a digital threshold circuit and a synchronizer. Moreover, inductors, the cores of which are made of soft magnetic material, are connected through switches to the circuit of the autogenerator, the output of which is connected to the input of a digital threshold circuit connected to the information input of the display circuit connected to the command inputs of the switches and to the outputs of the synchronizer which is connected by the input to the command input of the autogenerator and to the graduated pulse shaper.

The drawing shows a block diagram of the proposed device.

The device contains a magnetic ion sensor 1 with sensitive elements 2, made in the form of inductors with cores of a magnetic material, switches 3, an auto-oscillator 4, a digital threshold circuit 5, an indication circuit 6, a graduated pulse shaper 7 and a synchronizer 8.

The device uses a frequency control method of the current diagram.

The magnetic permeability of the core of the sensing element 2 is a function of the current proportional to the magnetic flux of the cathode. Consequently, each current value corresponds to a certain inductance of the cat | icn of the sensitive element.

The oscillator 4 is used as the functional inductance converter — the oscillation frequency is 4. In this case, the oscillator generates a radio pulse, the duration of which is equal to the duration of the command given to its command input iO. Digital threshold circuit 5 counts the number of periods of the high-frequency filling of a radio pulse and compares this number with a fixed threshold. Exceeding the threshold leads to the appearance of a pulse at the information input 11 of the display circuit 6.

At a certain duration of a radio pulse, the number of periods of its high-frequency filling depends only on the oscillation frequency of the key oscillator 4. A fixed number of periods of high-frequency filling correspond to different durations of the pulse fed from the driver 7.

The digital-threshold circuit 5 is tuned to a fixed value of the number of periods, therefore the driver 7 is graduated in terms of the pulse duration directly at current values. In this case, the current of the corresponding cathode is read on the leading edge of the pulse at the output of the digital threshold circuit. To measure the current of any of the cathodes, it is necessary to change the pulse duration of the imaging unit 7 until the operation of the display circuit 6 (the display circuit operates on the leading edge of the pulse at the information input 11) and measure the current on the imaging scale. If it is necessary to determine whether the cathode current exceeds a certain value, this value is set on the driver's scale. The operation of the display circuit indicates that the set value is exceeded, otherwise the cathode current is less than this value.

The number of switches 3 is equal to the number of display elements, the input is colli to the structure of circuit 6, and corresponds to the number of simultaneously controlled cathodes. Separate inlication of cathode currents is accomplished by sending to the command inputs 12 of the display circuit 6 and 9 of the switches 3 non-overlapping during the time of the pulses generated by the synchronizer 8.

The proposed device in comparison with the known has a higher noise immunity due to the use of the noise-resistant frequency method of control currents. The monitoring time is reduced due to the continuous reading of information from the magnetic flux sensor.

Claims (1)

1. US patent No. 3753194, cl. 324-114, 1971.