SU990891A1 - Apparatus for supplying electroplating baths with pulsed current - Google Patents

Description

The invention relates to electroplating and can be used to supply electroplating baths with pulsed current. A device for supplying electroplating baths with pulsed current is known, which contains an alternating current source that is controlled by a Jft rectifier, a generator of unlocking pulses, and an SI switch. A disadvantage of the known device is the impossibility of controlling the amplitude and duration of the pulse, which borders on the technological possibility of its use. The closest to the proposed technical essence and the achieved result is a device for supplying electroplating baths with pulsed current, containing an alternating current source, an adjustable rectifier, a FT pulser, a switch and p channel blocks each of which contains a short-circuiting thyristor, capacitance NoP drive, adjustable and matching elements, while the control electrode of the short-circuit thyristor is connected to the switch through an adjustable delay and according to element. The known device makes it possible to expand the possibility of varying the percentage of impurities in the deposited coatings and components in the alloys and to intensify the deposition process by adjusting g1pmple, the duration of the pulses and the frequency of the polarizing pulses TOKgl. In order to form polarized current pulses, the known device uses the energy of condensates, the charge of which is carried out by the mine Gsshanichesky bath (through current-limiting inductance and charge thyristor) 2. A disadvantage of the known device is that of the two cycles — the charge of a capacitive storage device, associated with the transfer of electricity and the inevitable electrical losses — only the discharge generates working current pulses of the electroplating bath. Otstscha barely, blowing that - .. the frequency of the capacitors is twice the frequency, followed by operating current pulses. The number of charge-discharge cycles for condensates is limited and is of the order of 10. Thus, an increase in the tracking frequency of the LAR-discharge cycles reduces the service life of the capacitors and, moreover, leads to an increase in the loss tangent capacitor energy and storage capacitance nominal parameters. The purpose of the invention is to improve the efficiency of the device and its reliability. This goal is achieved by the fact that the device for supplying electroplating baths with pulsed current, contains an alternating current source, an adjustable rectifier, a trigger pulse generator, a switch and n parallel channel blocks, each of which contains charge and short-circuited thyristors, capacitive storage, adjustable delay and matching elements, while the control electrode of the short-circuiting thyristor is connected to the switch through an adjustable delay and matching element, each channel unit with it is packed with additional charging thyristors, the thyristors being connected according to the single-phase bridge circuit included in the anode circuit of the electroplating bath. FIG. 1 shows a block diagram of the device; Figure 2 shows the time diagrams of the currents and voltages that are related to its operation. The device contains an alternating current source, an adjustable rectifier 1, a generator of 2 trigger pulses, a switch 3, and n channel blocks 4, each of which consists of a thyristor bridge (charging thyristors 5-8) whose diagonal includes a capacitive drive switching capacitors 9, short-circuit thyristor 10, adjustable delay 11, identical matching elements 12-14. In this case, the thyristor control electrodes 7 and 8 through the switching element 12, the controlling electrodes of thyristors 5 and 6 through the matching element 13, and the control electrode of the shorting thyristor 10 through the successively connected adjustable delay 11 and the matching element 14 are connected to the output of the switch 3. The device works as follows. Single-phase or three-phase voltage from an external industrial AC network is fed to regulated rectifier 1, rectified and smoothed voltage is applied to the galvanic bath 15 through five-channel blocks 4. Generator 2 generates trigger pulses with continuously adjustable over a wide range. These pulses come to switch 3, which performs two main functions: it distributes them across n channel blocks (diagram 5 for one of the blocks). Moreover, this sequence is directed to matching element 14 through adjustable delay 11 (diagram e), for one of the n-channel blocks, it separates even r and odd in the sequence of trigger pulses, and distributes them to matching elements 12 and 13. a digital counter and controlled decoders. Operation of one of the n channels for a sequence of unlocking pulses B. Upon receipt of the first trigger pulse (odd, diagram &), thyristors 7 and 8 are opened, thus forming a charge circuit for capacitors 9 through a galvanic bath 15. At the same time, capacitors 9 are charged to a voltage + US (diagram e) equal to the rectified the voltage of the controlled rectifier 1, and the charge current flows through the galvanic bath 15, forming a polarizing current pulse (diagram). As the capacitors 9 are charged, the current becomes zero and the thyristors 7 and 8 close. Next, the thyristors 5 and 6 receive an even unlocking pulse (diagram i), they are canceled, thus forming a recharging circuit of capacitors 9 through a galvanic bath 15. In this case, capacitors 9 are recharged from + Uf to -IR (diagram e), and the current Pyrezar and passes through the electroplating bath 15 in the same direction as in the previous case (when the thyristors 7. and 3). After a time determined by an adjustable delay 11, the unlocking signal (diagram 3) goes to a short-circuiting thyristor 10, which shunts the galvanic bath 15, passes a charge charge capacitor 9 through itself, and forms a rear frünt, T O lizing current pulse (diagram g) . In the future, all processes proceed similarly. Curve C is a temporary voltage pattern on a capacitive accumulator. As can be seen from the curve, the voltage drop across the capacitor plates, and, accordingly, the galvanic bath 15 is 2Uc, and the frequency of polarizing pulses is.

The current of the bath is equal to the frequency of recharging and capacitance.

Thus, the magnitude of the voltage removed from the regulated rectifier g-shtetel 1, halved (U ,.) compared with the known (from 1000 to 500 V). At the same time, the charge current of capacitors 9 does not change as the magnitude of the polarizing (discharge) current remains unchanged. Therefore, the power consumption of the regulated rectifier 1 and, accordingly, the input power of the entire converter (20 and 10 kVA) are reduced by half.

The resulting reduction in power consumption at constant output parameters leads to a corresponding increase in the efficiency of the converter and to a reduction in the specific energy consumption per unit mass of the coating by half.

Lowering the voltage applied to the thyristor blocks (from 1000 to 500 V) reduces the class of semiconductor devices (from 11th to 6th), insulation, and power capacitors, which ultimately reduces the cost of the converter, by 1.4. -1.5 times. .

Claims (2)

Invention Formula A device for supplying electroplating baths with pulsed current, containing an alternating current source, an adjustable rectifier, a trigger pulse generator, a switch and channel units, each of which contains charge and short-circuiting thyristors, an adjustable delay capacitive drive and matching elements, while the control electrode a short thyristor is connected to the switch through an adjustable delay and matching element, characterized in that, in order to increase the device efficiency and reliability, Each channel unit is equipped with additional charge thyristors, and the thyristors are connected according to the single-phase bridge circuit included in the anode circuit of the electroplating bath, a capacitive storage device is included in the bridge diagonal, and the control electrodes of the thyristors of the opposite shoulders of the bridge are connected to each other and connected to the switch through the corresponding matching element . Sources of information taken into account in the examination 1. USSR Author's Certificate No. 596664, cl. C 25 D 21/19, 1976. 2. USSR author's certificate 785382, cl. C 25 D 21/12, 1978. JUULJLJUL i JL JULit Tb F