SU1475993A1 - Apparatus for electrochemical dissolving of articles - Google Patents

Abstract

A device for the electrochemical dissolution of metals refers to electrochemistry and is intended primarily to study the kinetics of dissolution processes. The purpose of the invention is to increase reliability, expand functionality. The device contains a temperature controller 1 with a temperature sensor 2 installed on the electrolyzer 3, which is connected by the first input directly and the second input through a transistor switch to a bipolar voltage source 6 connected to the thyristor regulator torus 4, the reference oscillator 8, to which the thyristor voltage regulator is connected directly and through a frequency divider 9 counting inputs counters 10 and 11, to the information ones The outputs of which through push-button switches 12 and 13 are connected circuits AND 14 and 15, connected by their outputs to the inputs of a static trigger 16, to the forward output of which are connected to the installation input zero counter 10 and the first input circuit 2I-2IL21, and to the inverse output - input installation of zero counter 11, the third input of the 2I-2ILI circuit and the counting input of the counter 17 with the decoder connected to it - multiplexer 18, to the outputs of which through the multi-position switch 19 is connected to the installation input of the zero counter 17 and the counting trigger 20 connected directly m output from the second, and the inverse - the third input circuit 2I-2 or to an outlet through which the matching block 22 is connected the control input of the transistor switch. Expansion of functionality and reliability is achieved by introducing a temperature controller with a sensor, a bipolar power source, a transistor switch, a matching unit, a reference oscillator, a frequency divider, three meters, two And circuits, two pushbutton switches, a static trigger, a decoder into this device. multiplexer, multi-position switch, counting trigger, circuit 2I-2ILI. 2 hp f-ly, 3 ill.

Description

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cl

with so

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14

house through a transistor switch to a bipolar voltage source 6 connected to a thyristor voltage regulator 4, a reference generator 8 to which the thyristor voltage regulator is connected directly and through a frequency divider 9 counting inputs counters 10 and 11, to the information outputs of which through push-button switches 12 and 13 are connected to subjects And 14 and 15, connected by their outputs to the inputs of a static trigger 16, to the direct output of which are connected to the installation input zero counter 10 and the first input circuit 2I-2ILI 21, and to population-inverted output - zero setting input of the counter 11, the third input circuit 2I-2or and counting input of the counter 17c is connected thereto by multiplexer-decoder 18, which outputs

through the multi-position switch 19 is connected to the installation input zero counter 17 and the counting trigger 20 connected to the second output and inverse to the third input of the 2I-2ILI circuit, to the output of which through the matching unit 22 the control input is connected to a transistor switch 0 Functional expansion and increasing the reliability is achieved by introducing into this device a temperature controller with a sensor, a bipolar power source, a transistor switch, a matching unit, a reference oscillator, a frequency divider oy, three counters, two And schemes, two push-button switches, static trigger, decoder-multiplexer, multi-position switch, counting trigger, 2I-2ILI circuit. 2 hp f.ly. / 3 ill.

one

This invention relates to electrochemistry and is intended primarily to study the kinetics of the electrochemical dissolution of metals.

The aim of the invention is to increase reliability and enhance functionality.

FIG. 1 is a block diagram of a device for the electrochemical dissolution of metals; Fig. 2 is a block diagram of a thyristor voltage regulator; in fig. 3 is a voltage chart on the electrolyzer.

The device for electrochemical dissolution of metals contains a temperature controller 1 with a thermocouple 2 mounted on the electrolyzer 3, a thyristor voltage regulator 4, a power transformer 5, a bipolar power supply 6, a transistor switch 7, a reference generator 8, a frequency divider 9, the first 10 and second If counters, first 12 and second

13button switches, first

14 and second 15 circuits, static trigger 16, third counter 17, decoder-multiplexer 18, multi-position switch 19, counting trigger 20, circuit 2I-2ILI 21 and block

22 approvals representing

0

five

0

0

five

power amplifier operating in key mode. In this case, the thyristor voltage regulator (Fig. 2) contains a network synchronization unit 23 consisting of a diode bridge 24 to which the ballast resistor 25 and the thyristor 26 are connected in series, between the anode and the control electrode the reference diode 27 is connected, and the primary winding a pulse transformer 28, to the secondary winding of which, via diode 29, a logic levels forming unit 30 is connected, which is a limiting amplifier whose output is the output of a network synchronization unit to which the zero setting input A fourth counter 31 is connected, connected by a counting input to the output of a reference generator 8 ". To the information outputs of the fourth counter and the analog-digital converter 32 (ADC) connected by an analog input to the output of the temperature controller 1, a code comparison unit 33 is connected, whose output is one-wave The rator 34 is connected to the input of an optocoupler thyristor unit 35, consisting of two pairs of counter-connected optocoupler thyristors in parallel, with which a bipolar power supply 6, consisting of two diode bridges with condensation Oral filters connected to the secondary windings of the power transformer 5. At the same time, the first 10 and second 11 counters are connected to the output of the reference generator 8 through a divider 9 of the frequency by the counting input, the first 14 and second 15 circuits are connected to the information outputs of which through the push-button switches 12 and 13 And, to the outputs of which the first and second inputs are connected to a static trigger 16, to the direct output of which is connected to the installation input zero the first counter 10 and the first input circuit 2I-2ILI 21, and to the inverse output they are connected by the input installation zero second counter 11, third input 2I-2ILI 21 and counting input third counter 17 with decoder-multiplexer 18, connected via a multi-position switch 19 with counting trigger input 20, to the forward and inverse outputs of which are the second and fourth inputs, respectively a 2I-2ILI 21 circuit is connected, to the output of which, through a matching unit 22, which is a bipolar DC amplifier operating in a key mode, a transistor switch 7 connected by collectors of transistors is connected -p-p-type and ppn-type, respectively, with a positive and negative pole - bipolar power source 6, and emitters - with the first input of the electrolyzer 3, the second input of which is connected to a common bus bipolar power source 6.

A device for the electrochemical dissolution of metals works as follows.

From the output of the bipolar power supply 6 through the open transistor of the switch 7, the current flows to the electrolyzer 3, the temperature in which is controlled by the thermocouple 2 installed on it (temperature sensor) of the temperature regulator 1, from the output of which the control signal is fed to the analog input of the ADC 32 The digital input of which is compared with the digital code at the information output of the fourth counter 31 using the code comparison block 33

JQ 20 25 about. Q

35

45

50

55

The counting input of the fourth counter 31 pulses directly from the output of the reference oscillator 8, and using the network synchronization unit 23, which produces a short pulse at the beginning of each half-period of the mains voltage, the fourth counter 31 is zeroed.

The network synchronization unit operates as follows.

From the diode bridge 24 connected to the power network, the direct voltage goes to the locked thyristor 26 o. As soon as the voltage on the thyristor anode exceeds the voltage of the zenor breakdown of the reference diode-27, the current flowing through the control electrode rises and the thyristor 26 opens . In this case, a short pulse is generated at the output of the pulse transformer 28, which through diode 29 and the logic level forming unit 30 enters the zero setting input of the fourth counter 31, which counts the pulses during each half-period of the mains voltage, coming directly from the output of the reference generator 8 o

As soon as the digital code at the output of the fourth counter 31 becomes equal to the digital code at the output of the A / D converter 32, a level 1 is generated at the output of the code comparison block 33, which triggers the one-shot 34, from which the pulse arrives at the control input of the optocoupler block 35

At the same time, the corresponding thyristors are opened and a bipolar power supply 6, consisting of two rectifiers with capacitor filters, is connected to the secondary windings of the power transformer for the time set by the unlocking angle of the optocoupler thyristors 35 o

With increasing temperature in the electrolyte 3, the potential at the output of the temperature controller 1 increases, and the code at the output of the A / D converter 32 also increases.

Thus, with increasing temperature, the equality of the codes at the output of the ADC 32 and the fourth counter 31 occurs with a larger number of pulses arriving at its counting input from the output of the reference generator 8,

due to the check, the unlocking angle of the optocoupler thyristors 35 increases, which leads to a decrease in the voltage on the bipolar power source 6, thereby reducing the dissipated power on the electrolyzer,

Simultaneously from the output of the reference generator 8 through the divider 9 often15

In this case, the pnc-hip transistor of the switch 7 opens to saturation and connects the electrolyzer 3 to the positive pole of the bipolar power supply 6.

With the arrival of O at the first input of the 2I-2I11I circuit, the O level will form at its output.

This opens up to saturation of the pnp-type transistor of switch 7 and connects the electrolyzer to the negative pole of the bipolar voltage source.

After the inverse outflow of the counting trigger 20 forms

20

The pulses arrive at the counting inputs 10 n 1, the outputs of the first 10 and second 11 counters are also formed at the output. Assume that the direct output of the static trigger 16 has a level 1 and, accordingly, a level O at the inverse output

In this case, the first counter 10 is reset to zero and blocked, and the second counter 11 performs counting of the pulses arriving at its counting input in a cumulative total.

As soon as the predetermined number of pulses specified by the second push-button switch 13 arrives at the second counter 11, a level 1 is formed at the output of the second circuit 15 And the static trigger 16 changes its state and at its forward output the level O is formed and at the inverse - level 1, thanks to which the second counter 11 will be reset and blocked, and the first counter 10 will start the counting of pulses.

After the first counter 10 sets a predetermined number of pulses specified by the first push-button switch 12, a level 1 is generated at the output of the first circuit 14, which brings the static trigger 16 to the initial state and the entire described operating cycle repeats.

Using the first 12 and second 13 button switches, the pulse widths are set independently.

35

40

T + and T in the cycle T c (see the diagram in Fig „3).

The number of pulses in a cycle is set using a multi-position switch 19. In this case, the third counter 17 performs counting of the pulses arriving at its counting input from the inverse output of the static trigger 16 o

After dialing by a multi-position switch 19 of a predetermined number of pulses, a level 1 is formed at the corresponding output of the decoder-multiplexer 18, which closes the third counter 17, and the counting trigger 20 goes into a new state.

45

50

55

With level 1, the control of the 2I-2ILI 21 circuit is carried out with the help of a static trigger 16 already at its third input.

At the same time, with the arrival of the static trigger 16 of level 1 from the inverse output, the electrolyzer is connected with the help of the transistor n-p-type switch 7 to the positive pole of the bipolar power source 6, and the level O to the negative pole

Thus, using this device, it is possible to set the pulse duration and their number in the cycle independently, as well as to invert the pulse duration of positive and negative polarity.

In the fabricated model of this device, the pulse duration can vary from 0.4 s and the number of pulses in a cycle from 1 to 15.

Due to the use of high power transistors in the switch, the current in the electrolyzer can reach 20 A

When replacing contact switches with digital switches, the device can be controlled, for example, using a microcontroller according to a predetermined program.

Claims (3)

1. A device for the electrochemical dissolution of metals, for example, at the direct output of the counting trigger 20, level 1 takes place and, accordingly, inverse - level In this case, the control of the 2I-2ILI 21 is carried out at its first input. With the arrival at her first entrance level In this case, the pnc-hip transistor of the switch 7 opens to saturation and connects the electrolyzer 3 to the positive pole of the bipolar power supply 6. With the arrival of O at the first input of the 2I-2I11I circuit, the O level will form at its output. This opens up to saturation of the pnp-type transistor of switch 7 and connects the electrolyzer to the negative pole of the bipolar voltage source. After the inverse output of the counting trigger 20 forms n 1, the output also forms about five 0 five 0 five With level 1, the control of the 2I-2ILI 21 circuit is carried out with the help of a static trigger 16 already at its third input. With the arrival of the static trigger 16 of level 1 from the inverse output, the electrolyzer is connected by means of the transistor n-p-type switch 7 to the positive pole of the bipolar power source 6, and the level O to the negative pole. Thus, using this device, it is possible to set the pulse duration and their number in the cycle independently, as well as to invert the pulse duration of positive and negative polarity. In the fabricated model of this device, the pulse duration can vary from 0.4 s and the number of pulses in a cycle from 1 to 15. Due to the use of high power transistors in the switch, the current in the electrolyzer can reach 20 A. When replacing contact switches with digital switches, the device can be controlled, for example, using a microcontroller according to a predetermined program. Invention Formula 1. A device for the electrochemical dissolution of metals, containing Electrolyzer, power transformer and thyristor voltage regulator, characterized in that, in order to increase reliability and enhance functionality, it is equipped with a temperature controller with a temperature sensor, a bipolar power source, a transistor switch, a matching unit, a reference generator, a divider frequencies, the first, second and third counters, the first and second circuits And, the first and second 2 o The device according to claim 1, characterized in that the thyristor voltage regulator is made in the form of a network synchronization unit, a fourth counter, a comparative button switch, a static analog-digital converter (A1SC), a single-oscillator and an optocoupler unit thyristors, and the fourth counter is set to the zero input of the unit connected to the output of the block by a network trigger, a decoder, a multi-position switch, a counting trigger and a 2I-2ILI circuit, and a thyristor controller is connected to the output of the reference generator directly and through a frequency divider by counting input the first and second counters, to the information outputs of which, respectively, the first and second schemes AND are connected via the first and second pushbutton switches 25, to the outputs of which the first and second inputs are connected to a static trigger which is connected to the installation input of the zero of the first counter and the first input of the circuit 2I-2ShSh, and the input of the installation of the zero of the second counter is connected to the inverse output, the third input of the circuit 20 synchronization, and the counting input - to the reference generator, while the information output of the fourth counter and the analog-digital converter is connected to a code comparison unit, to the output of which, through a single-oscillator control input, an optical-thyristor block is connected, the output of which is the output thyristor voltage regulator. 3. Device according to claim 2, characterized in that the network synchronization unit is designed as a diode bridge, a ballast resistor, a reference diode thyristor, im30 3. The device according to 2, characterized by the fact that the block of the synchronization is made in the form of a diode bridge, a ballast resistor, a thyristor of the reference diode, 2I-2ILI and the counting input of the third pulse-transformer, diode, A transmitter with a decoder connected to its information outputs, to whose information outputs a counting trigger is connected through a multi-position switch, to the forward and inverse outputs of which, respectively, the second and fourth inputs are connected to a 2I-2IL circuit connected to their output through a matching level of a logic level and diode A thyristor ballast resistor is connected in series to the bridge; between the anode and control 40, the electrode of which includes a reference diode and the primary winding of the pulse transformer a, to whose secondary wiring a diode level forming unit is connected through the diode vanes with a transistor switch, the 45 output of which is an output connected to a bipolar source ka network synchronization. AT voltage and electrolyzer, on which is installed a temperature sensor connected to a temperature regulator, to the output of which a thyristor voltage regulator connected to a bipol p- is connected to the control input. power source and power transformer. 2 o The device according to claim 1, characterized in that the thyristor voltage regulator is made in the form of a network synchronization unit, a fourth counter, a comparison unit (ASC) of the analog-digital converter (A1SC), a single-oscillator and an opto-thyristor block, and the fourth counter by the installation input zero is connected to the output of the network unit synchronization, and the counting input is connected to the reference generator, while a code comparison unit is connected to the information output of the fourth counter and the analog-digital converter, the output of which is the output of the thyristors connected to the output of which through a single-oscillator control input ristor voltage regulator. 3. The device according to 2, characterized in that the network synchronization unit is made in the form of a diode bridge, a ballast resistor, a reference diode thyristor, pulse transformer, diode, A logical level forming unit, with a ballast resistor, a thyristor connected in series to the diode bridge, between which the reference diode is connected between the anode and the control electrode, and the primary winding of the pulse transformer, which is connected to the secondary winding of the logic levels, ka network synchronization. Hz t