SU1740502A1 - Device for automatic control of electrolysis - Google Patents

Description

The invention relates to electroplating and can be used in technological processes of metal plating, for example, in the manufacture of printed circuit boards.

A device for automatically setting current in the process of applying electrolytic coatings is known, which contains an auxiliary bath, a meter for the area of processed products, multipositional working baths with sensors for the presence of products, power supply units, a system of storage devices and digital-to-analogue converters. The device is made multi-stage with the number of stages equal to the number of electrochemical processes.

The disadvantages of this device are the following: the presence of an auxiliary bath, not involved in the main technological process, occupying the production area; large error (15–20%) of measuring the metallization area; a low percentage of yield of products due to the fact that maintaining a given current density, and not adjusting the position of the operating point of the current-voltage characteristic of a galvanic bath, does not guarantee the optimality of the cathode current; low productivity of the process at low predetermined current densities or an increased rejection rate and excess energy at high current densities.

The closest to the technical essence of the invention are a method and apparatus for adjusting the position of the operating point of the electroplating bath during electrolysis. This device contains a galvanic bath, a DC voltage source, an AC voltage source, a current shunt connected to one of the electrodes, a regulator whose inputs are connected to the current shunt and to the outputs of the AC voltage source, and the output the regulator is connected to the input of a DC voltage source.

The disadvantage of this device is that it is intended for use in electroplating processes with low currents, for example in the electrolysis of silver contained in solutions used in photographic processes. This device cannot be used in electroplating processes occurring with large values of cathode currents (100-1000 A or more), since such processes should use powerful voltage sources with high levels of pulsations (from B to 15-20% ). With such pulsations in this device, the control unit will not work, since the useful signal is lost in the signals generated by the pulsations of the cathode current.

The aim of the invention is to expand technological capabilities, save energy, increase productivity and quality by expanding the range

0 regulation of cathode current and simplified design.

The goal is achieved by the fact that the device for adjusting the position of the operating point of the electroplating bath during electrolysis contains a galvanic bath, a DC voltage source connected to the anode of the bath, an AC voltage source, a current shunt regulator made in the form of two

0 voltage amplifiers, a filter, two voltage comparators, a logic comparator connected by inputs to the outputs of the voltage comparators, the input of the first voltage comparator is connected to the output of the filter, and the other input is connected to the output of the corresponding voltage amplifier, and the inverting input of the first amplifier the voltage is connected to the negative terminal of the voltage source

0 DC and to one of the outputs of the current shunt, the other output of which is connected to the non-inverting input of the first voltage amplifier, the inputs of the second voltage amplifier are connected to the AC voltage source, and the regulator output is connected to the constant voltage source control input The current is additionally equipped with two auxiliary cathodes and a second current shunt, and the controller is made with a third voltage amplifier, a voltage adder, two pulse formers, and a pulse counter. The outputs of the third and first voltage amplifiers are connected to two inputs of a voltage adder, the output of which is connected to the filter. The output of the logic comparator is connected to the inputs of the first and second pulse shapers, the output of the first pulse shaper is connected to the forward counting input of a pulse counter, and the output of the second pulse shaper is connected to the counting input of a pulse counter, the outputs of which are

5 exits of the regulator. One of the auxiliary cathodes is connected to the non-inverting input of the first voltage amplifier of the regulator, and the other auxiliary cathode is connected to the inverting input of the third voltage amplifier

the regulator and to one of the terminals of the second current shunt, the other terminal of which is connected to the non-inverting input of the third voltage amplifier of the regulator and to one of the terminals of the AC voltage source, the other output of which is connected to the cathode and to the negative terminal of the constant voltage source current. The AC voltage source in this device is designed as a transformer, one of the primary windings of which is connected to the negative DC voltage source, the other output to the non-inverting input of the third regulator voltage amplifier, the second secondary windings are connected to the second input of the controller.

The salient features of such a device are the following: it additionally contains two auxiliary cathodes and a second current shunt; the controller further comprises a third voltage amplifier, a voltage adder, two pulse drivers, a pulse counter; the source of alternating current voltage is made in the form of a transformer; electrical connections between newly introduced elements with those present in the known device.

Figure 1 shows the functional diagram of the device; Fig. 25 shows the current-voltage characteristics of the electroplating bath and the voltage and current plots for the operation of the device.

The device for automatic regulation of electrolysis processes contains a galvanic bath 1 with an anode 2 located in it, a cathode 3 (suspension with printed-circuit board blanks) and two auxiliary cathodes 4 and 5, a voltage source

6 DC current (for example, TE type or TB type), AC voltage source 7 (for example, a transformer with two secondary windings), two current shunt 8 and 9, and a regulator 10.

The regulator 10 consists of voltage amplifiers 11, 12, and 13 (for example, K140UD7 chips), the inputs of which are the corresponding inputs of the controller, voltage adder 14 (for example, K140UD7 chips), filter 15 (for example, K140UD7 chips), two voltage comparators 16 and 17 (for example, K140UD7 chips), logical comparator 18 (for example, K140UD7 chips), two pulse formers 19 (for example, K155 L A3 chips) and 20 (for example, K140UD7 and K155LAZ chips), pulse counter 21 (e.g. ICs

K155IE6 or K155IE7), the outputs of which are the outputs of the regulator. The first input of the voltage adder 14 is connected to the output of the voltage amplifier 11. The second input 5 is connected to the output of the voltage amplifier 13, and the output of the voltage adder 14 is connected to the input of the filter 15. The input of the comparator 16 is connected to the output of the filter 15, and the output is the first input of a logic comparator

0 18. The input of the comparator 17 is connected to the output of the amplifier 12, and the output is connected to the second input of the logic comparator 16, the output of which is connected to the inputs of pulse formers 19 and 20. The output of the driver

5 pulses 19 are connected to the countdown input (-1) of the pulse counter 21, and the output of the pulse generator 20 is connected to the forward counting input (+1) of the pulse counter 21.

Anode 2 is connected to positive

0 to the output of a DC voltage source of 6, and the cathode 3 to a negative output. Auxiliary cathode 4 is connected via a current shunt 8 to the negative terminal of a DC voltage source 6.

5 Auxiliary cathode 5 is connected via a current shunt 9 to one of the terminals of the first secondary winding of an alternating current source, its second output is connected to the negative lead of a DC voltage source 6. The inverting input of voltage amplifier 11 is connected to the negative terminal of the DC voltage source 6, and the non-inverting input to the cathode 4.

5 The non-inverting input of the voltage amplifier 13 is connected to the connection point of the AC voltage source 7 with the current shunt 9, and the inverting input is connected to the auxiliary cathode 5.

0 The inputs of voltage amplifier 12 are connected to the second secondary winding of a source of voltage 7 of alternating current. The output of the regulator 10 is connected to the input of a voltage source 6 voltage reference input.

5 direct current. When considering the operation of the device, it is necessary to take into account that the areas of the auxiliary cathodes 4 and 5 and the gains of the amplifiers 11 and 13 are equal.

0 The device operates as follows.

When the voltage sources 6 and 7 are turned on, the galvanic process begins. The cathode 3 and the auxiliary cathode 4 of the relative anode 2 are supplied with the voltage of the voltage source 6 of the direct current. The auxiliary cathode 5 with respect to the anode 2 receives the total voltage (U "+ LU) of the sources of the DC voltage 6 and AC

7. The shape of the voltages on the cathodes 3 and 4 (11), 5 (U + U.,), taking into account possible ripples of the DC voltage source 6, is shown in the diagrams of FIG. 2. On current shunts 8 and 9 cathodic currents flow 1kD1 IK, respectively (fig.Z).

J The principle of operation of the device is based on the characteristics of the shape of the curve of the current-voltage characteristics of electroplating baths. As is known, the volt-ampere characteristic of a galvanic bath is an upward curve with a flat linear section of the shelf (Fig. 3, where the aolt-ampere characteristic is conventionally divided into sections I, II. III).

If the voltage on the cathode 3 is within the area I of the characteristic, the process of metallization of printed circuit boards is slow, i.e. reduced equipment performance.

If the voltage on the cathode 3 is within section 111, the metallization process is uneven, the boards of the coating of printed circuit boards can be burned, the metallization process takes place with a large excess of electrical energy, and the rejection rate of the product increases.

The most optimal mode is the mode when the voltage on the cathode 3 is within the flat section I of the current-voltage characteristic.

If the amplitude of the total voltage (IU + UJ does not exceed the limits of section II (FIG. 3), then due to the linearity of the characteristic on this section, the shape of the currents flowing through the current shunts 8 and 9, respectively, as well as the shape of the voltages Us, U2 at the outputs amplifiers 11 and 13 will repeat the shape of the voltages U "and (U), respectively. Since the voltages Us and Ua arrive at the inputs of the adder 14 in the opposite phase, then the output of the adder 14 and filter 15 will be the voltages of U4, Us replicating the form of a voltage source of alternating current voltage 7 and voltage Ui output voltage of amplifier 12.

Voltages Us. Ui arrive at the inputs of the comparators 16 and 17, respectively. At the output of the comparators 16 and 17, the voltage Us, U coincide in form, therefore, at the output of the logic comparator 18 (signal Ue) and the pulse shapers 19 and 20, the signals Ug, Uio are absent (logical zero).

If the voltage amplitude (U «+ U) is within the limits of sections I. M, the current-voltage characteristic (Fig.4), then due to non-linear distortion of the forms

the stresses Us, Ui, and, consequently, Ue, Uy do not coincide. The output of the logic comparator 18 is Ue pulses, and the output of the pulse driver 20 is the Uio signal (voltage pulses). The signals from the output of pulse shapers 20 are fed to the input of a direct count (+1) pulse counter 21. With each period following, for example, a sinusoidal voltage 0 "and an alternating current voltage source 7, the contents of counter 21 increase by two units of counting. The signals from the counter 21 in the form of a binary code are fed to the control inputs of the source of a voltage of 5 to 5 current. The magnitude of the voltage source b increases and the process continues until the voltage amplitude (U- + U-0 begins to go beyond the limits of section 1 of the volt-ampere characteristic.

If the voltage amplitude (U- + is within the limits of sections II, III of the current-voltage characteristic (figure 5), then, similarly to the previous variant, the signals with

The 5 outputs of the former 19 are fed to the countdown input (-1) of the pulse counter 21. The voltage of the DC voltage source 6 decreases. The process continues until then. while amplitude

0 voltage (U + U will not exceed the limits of section II of the current-voltage characteristic.

Thus, if as a result of an approximate setting of the voltage value

The 5 inputs of the preset A0 ... AP of the pulse counter 21, or as a result of the displacement of the current-voltage characteristic, the voltage (U) will not be within the limits of section II, will begin

0 an automatic control process which will result in setting the value of the voltage value (Ue + U,) to section II of the current-voltage characteristic of the plating bath. The proposed device

5 provides the ability to conduct electroplating processes with voltage sources of 100-1500 A with high levels of pulsations. Such currents are used in the process of galvanic processing of blanks of printed circuit boards of large sizes.

8 known devices, such as automatic lines for the production of AG-44 printed circuit boards, YGM1.211.036, the current size is set by the operator depending on the recommended current density and surface area of the printed circuit boards to be metallized. The metallization area is calculated from the design documentation for printed circuit boards {as, for example, in

lines AG-44) or measured by a device for measuring area (as, for example, in a prototype). Due to errors in determining the surface area to be metallized (up to 25-30%), as well as changes in the parameters and characteristics of electrolytes, the amount of current specified by the operator in known devices is not optimal.

At a small given current, the process equipment operates with reduced performance. At high currents, power consumption and scrap rejection rate are increased due to uneven coating and surface burn.

The proposed device automatically maintains the optimum amount of cathode current when applying the metal coating on the surface of printed circuit boards.

Claims (2)

1. Device for automatic control of electrolysis processes, containing a galvanic bath, a DC voltage source connected to the bath anode, an AC voltage source, a current shunt, a regulator made in the form of two voltage amplifiers, a filter, two comparators a logic comparator connected by inputs to the outputs of the voltage comparators, the first-voltage comparator WUOD is connected to the output of the filter, and the input of the other to the output of the corresponding voltage amplifier, and The inverting input of the first voltage amplifier is connected to the negative output of a DC voltage source and to one of the current shunt terminals, the other output of which is connected to the non-inverting input of the first voltage amplifier, the inputs of the second voltage amplifier are connected to an AC voltage source, and The regulator output is connected to the control input of a DC voltage source, characterized in that in order to expand technological capabilities, save energy, increase productivity and quality by expanding the range of cathode current regulation, it is equipped with two auxiliary cathodes and a second current shunt, and the regulator is made with a third voltage amplifier, a voltage adder, two pulse shapers The pulse counter, the outputs of the third and first voltage amplifiers are connected to two inputs of a voltage adder, the output of which is connected to a filter, the output of a logic comparator connected to the inputs of the first and second, pulse shapers, moreover, the output of the first pulse shaper is connected to the input of the direct counting pulse counter, the output of the second pulse shaper one of the auxiliary cathodes is connected to the non-inverting input of the first voltage amplifier of the regulator, and the other auxiliary cathode is connected to the inverting input of the third voltage regulator of the regulator and to one of the terminals the second current shunt, the other output of which is connected to the non-inverting input of the third voltage regulator amplifier and to one of the terminals of the AC voltage source, the other output to orogo connected to the cathode and to the negative voltage source DC. 2. The device according to claim 1, in which, in order to simplify the design, the source of the alternating current voltage is in the form of a transformer, one from the terminals of the primary winding of which is connected to the negative terminal of a source of direct current voltage, the other terminal to the non-inverting input of the third voltage amplifier of the regulator, the leads of the second secondary winding are connected to the second input of the regulator. t (7 Faye. four t 1