SU1743742A1 - Device for electromechanical marking - Google Patents

Abstract

The invention is intended for use in installations for applying information to the surface of conductive products. The device contains a variable process voltage source, a controlled bridge rectifier, process time blocks on a unipolar bipolar voltage, an additional power winding connected via controlled rectifiers to the additional load and electrodes, and a control circuit containing a low-power source winding variable voltage, synchronizer, unit for adjusting the unipolar voltage pulse duration, as well as a generator for switching on controlled rectifiers and When the last channel switching similar to the control circuit. The device provides the electrochemical cell for supplying the unipolar sinusoidal process voltage with a single- and two-wavelength rectification of the pulse voltage with a pulse frequency of 50 and 100 Hz, with a steep front and a sinusoidal pulse decay, with adjustable from 0 to 10 ms pulse duration for a set processing period, with automatic contactless switching of the process voltage from unipolar to bipolar, with amplitude of inverse sine idalnogo voltage smaller than the amplitude of the direct voltage, to reduce the etch tool-working surface of the electrode and the work only on the bipolar voltage without including unipolar voltage. 2 Il. N oj 4 yu

Description

This invention relates to electrochemical machining and can be used in the electrochemical marking of parts.

A device for electrochemical marking is known, which contains a step-down power transformer, a bridge rectifier and a switch that switches the load (electrochemical cell electrodes) from the secondary

a transformer winding or with a bridge rectifier output for supplying a variable or -through two-wave sinusoidal voltage to the load.

Rectified voltage is used to obtain in-depth marking of the color of the base metal, and then alternating voltage is used to increase the contrast of the marking. At the same time

the surfaces of the signs are black oxide products.

However, the use of such a source does not allow to obtain high quality markings, since the duration of the process is established by the operator immediately when the electrodes touch the electrolyte film and the process stops after they are diluted, i.e. largely determined by the skills of the operator. In addition, when the source is continuously turned on, a voltage is present on the electrodes, which, when replacing a part, can cause unpleasant sensations to the operator when it is in contact with two electrodes (cathode and anode) at the same time. The lack of automatic switching of unipolar voltage to bipolar practical does not allow to obtain a deep, contrasting marking, since repeated contact of the electrodes in the same treatment zone after switching voltages is possible only with a special orienting device. Additional switching significantly increases the piecework processing time, which reduces the productivity of the process,

A known power source for electrochemical marking of parts with a thyristor connected in series between the interelectrode gap, the control electrode of which is connected to the circuit for switching on and controlling the marking time.

However, this power source generates single-half-wave voltage pulses, which does not allow obtaining high process efficiency, bipolar voltage supply is also not possible, which reduces the technological capabilities of the source and the quality of processing.

It is also known a device for electrochemical marking with a bridge rectifier, an electromechanical timer for the working period, a switch for unipolar and bipolar voltages, and a button for applying a voltage to the electrodes when the electrode tool is pressed and the electrodes are in contact.

The source allows the voltage to be automatically disconnected from the load in order to terminate the process, however, switching of unipolar and bipolar voltages is carried out manually, which causes a break in processing, in addition, all switching elements are located in the power circuit, which leads to burning contacts when they open and reduces

reliability of the power source. This power supply does not allow the formation of a pulsed unipolar voltage, which in some cases is necessary to obtain a minimum broadening of the marking lines. Adjusting the amplitude of the process voltage is carried out by ballast resistors connected in series to the load, at the same time it is known that when marking the current changes during processing due to an increase in the interelectrode gap with stationary electrodes, which in this case reduces the voltage drop on the ballast a resistor and an increase in the process voltage on the electrodes, i.e. to some stabilization of the current, however, it is known that processing with stabilization of the current contributes to a significant increase in the broadening of prints, which is undesirable. In addition, in a known source, there is no reliable adjustment of the amplitude of the reverse voltage, independent of the amplitude of the direct voltage, during processing at bipolar voltage. High amplitude of the reverse voltage, equal to the amplitude of the direct voltage, leads to increased electrochemical wear electrode-tool, which ultimately reduces the quality of processing due to the distortion of the shape of the electrode-tool and an increase in the interelectrode gap.

The aim of the invention is to improve the quality of processing and expansion of technological capabilities.

This goal is achieved by having an electrochemical marking device containing a variable process voltage source, a bridge rectifier and a control circuit including a process duration setting unit and switching elements of unipolar process voltage to bipolar, provided with an additional load connected in parallel with the electrodes power and low-power windings in the alternating voltage source, the first of which is connected to the electrodes through controlled rectifiers The bridge rectifier is controllable; the process duration setting unit consists of a bipolar voltage supply time setting block, whose input is connected to a unipolar voltage switching element on a bipolar voltage and through a bipolar voltage switch with the first output of the block set the duration of the supply of unipolar voltage, and the control circuit further comprises a pulse generator, three switching channels of controlled rectifiers, one three-input and two two-input logic elements And, two inverters, an OR logic unit, a pulse frequency doubling switch connected in series with the low-power winding of the voltage source, a synchronizer and a pulse duration control unit, the unipolar voltage switching elements on the bipolar voltage and the unipolar voltage supply setting unit are connected successively, the second output of the latter is fed to the first input of the OR gate, the second input of which is connected to the output of the block specifying the duration of the bipolar voltage supply eni and the input of the first inverter, and the output is fed to the first input of the three-input logic element I. The second input of which is connected to the output of the pulse width control unit, and the third input to the output of the pulse generator and the first input of the two-input logic element I connected to the input of the third commutation channel: and the first input with the output of the second inverter, the output of the first inverter simultaneously being fed to the input of the second inverter and one of the inputs of the second two-input logic element, And, the output which is connected via a pulse frequency doubling switch to the input of the second switching channel, and the second input of the AND gate is connected to the output of the three-input element And and the input of the first switching channel.

Fig. 1 is a block diagram of a device for electrochemical marking; in fig. 2 - a, b, c - voltage plots on the electrodes of the electrochemical cell for various operating modes of the device.

The device for electrochemical marking (Fig. 1) contains an alternating voltage source 1, representing a single-phase transformer with several secondary windings, one of which secondary windings is connected to a bridge rectifier on controlled elements (rectifiers) 2-5, output which is connected to an additional low-power load b and the electrodes 7 of the electrochemical cell. The latter, in turn, are connected via controlled rectifiers 8, 9 with an additional power winding 10 of source 1. The rectifier control circuit contains an element 11 that turns on the duration of the marking process and is connected via switch 12 to the inputs of blocks 13 and 14 of setting the duration of supply of unipolar voltage. and bipolar voltage, respectively, and the first output of the block 13 is connected through the switch 15 to the input

block 14. The second output of block 13 sets the duration and output of block 14 are fed to the corresponding inputs of the OR 16 logic element, and the output of block 14 is connected to the series-connected inverters 17, 18, AND 19 and the switching channel 20 controlled in series straighteners 8, 9.

In addition, the control circuit comprises a series-connected low-power winding 21 of the voltage source 1, a synchronizer 22, a voltage pulse width adjustment unit 23, a AND 24 three-input logic element and a switching channel 25 of controlled rectifiers 2,

0 5, as well as a generator of 26 pulses, a two-input logic element AND 27, a switch 28 for doubling the frequency of the pulses and a switching channel 29 of controlled rectifiers 3, 4. Moreover, the output of the generator is 26 pulses

5 is fed to one of the inputs of the AND 24 logic element, and from its output through the logical element AND 27 and the switch 28 to the input of the switching channel 29 and to the second input of the AND 19 logic element. The third input of the logical element AND 24 is connected to the output of the logic element OR 16, and the second input of the logic element And 27 is connected to the output of the inverter 17.

The device works as follows.

The signal from the output of the switch-on element for the duration of the marking process, which can be a conventional button, goes through switch 12

0 to the input of the unit specifying the duration of the feed when processing first at the unipolar voltage and then at the bipolar. If it is necessary to work only on bipolar voltage, switch 12 becomes

5 is a lower position according to the diagram, and the signal from the output of the switching element 11 is fed directly to the input of the block 14. When a logical element OR 16 of a logical voltage

0 units for the duration of processing at a unipolar voltage or for the duration of processing at a bipolar voltage, the voltage of a logical unit is formed at the output of this element,

5 allowing the impulse to turn on for the controlled rectifiers from the generator 26 through the switching channels 25, 29, 20. Depending on the voltage pulse duration set by unit 23, which is selected within the duration of one half-period of sinusoidal voltage, from almost 0 to 10 ms and is formed synchronously with the moment of transition of the sinusoidal through 0 using winding 21 and synchronizer 22 at the output of unit 23, each half-period a sinusoidal voltage appears voltage of a logical unit, providing the passage of pulses from the generator 26 through the logical element And 24. The first generator pulse 26, passed to the input channels switching, the inclusion of controlled rectifiers 2-5 or 8, 9 at time points associated with zero sinusoids and providing the necessary duration of the unipolar voltage pulse, when processing at a unipolar voltage of double frequency (100 Hz) generator 26 passes through logic elements AND 24, 27 and from the output of the latter through switch 28 to the inputs of switching channels 25 and 29, the outputs of which are connected to the control electrodes of rectifiers 2, 5 and 3, 4, respectively. pn April, corresponding to FIG. 2a or fig. 26-. The frequency of the pulses of the generator 26 is chosen to be much higher than the frequency of the technological voltage to reduce the error of the duration of the technological voltage pulse, for example, from a range of 1-10 kHz.

At the lower position of the switch 28, the control pulses do not flow through the channel 29 to the electrodes of the rectifiers 3, 4, and a pulsed unipolar process voltage twice as low as the frequency of the pulses (50 Hz) is formed at the bottom of the circuit as a result of a single-phase rectifier operating rectifiers 2, 5 (Fig. 2c). After the termination of the pulse of a logical unit from the output of block 13, a pulse arises at its lower output circuit that switches on block 14 to specify the duration of the supply of bipolar voltage. In this case, the pulses from the generator 26 begin to flow to the inputs of the switching channels 25 and 20. The passage of pulses to the input of channel 29 is blocked by the level of a logic zero coming from the output of inverter 17 to the input of logic element 27, As a result, rectifiers 2. 5 and 8, 9 begin to work, which supply a direct voltage to the load (tool cathode, workpiece -anod) of high amplitude and pulse duration set by block 23 and reverse voltage (instrument-anode, billet-cathode) lower

amplitudes and unregulated durations (Fig. 2J to obtain contrast marking and reduced tool wear on reverse voltage. The amplitudes of forward and reverse voltages can be adjusted smoothly or discretely independently of one another to select the optimal treatment modes.

Parallel to the main load — an electrochemical cell with electrodes 7, an additional low-power load 6 is introduced into the device, providing a guaranteed current through controlled rectifiers for their reliable operation.

as the current during electrochemical marking varies over a wide range, and under certain conditions, such as significant gas contamination, it can be practically zero. In addition, the additional load 6 with closed rectifiers ensures the absence of voltage on the electrodes, which is necessary to increase the safety of the operator. Otherwise, the absence of a closed load circuit leads to the appearance of an electrochemical voltage cell on the diluted electrodes, causing an unpleasant sensation to the operator when the electrodes are touched by hands,

Thus, the device allows to increase the performance of equipment for electrochemical marking, since the switching of processing from unipolar to bipolar voltage is carried out automatically.

Reliability of the device due to the absence of contact elements in the power section, switched when the technological current passes through the load;

processing quality by reducing the etching of the electrode tool when processing at bipolar voltage and the technological capabilities of the device by changing the shape of the technological

voltages over a wide range, including the application of a pulsed voltage with a short pulse front.

Claims (1)

Claims An electrochemical marking device comprising a variable process voltage source, a bridge rectifier and a control circuit; including a process time setting unit and switching elements of unipolar technological voltage to bipolar, characterized in that, in order to improve processing quality and expand technological capabilities, it is equipped with an additional load connected in parallel with the electrodes, additional power and low-power windings in the alternating voltage source - neither the first of which is connected to the electrodes through controlled rectifiers, while the bridge rectifier is made controllable, the task unit is long The process consists of a bipolar voltage supply unit setting, the input of which is connected to a unipolar voltage switching voltage on a bipolar voltage and through a bipolar voltage switch to the first output voltage setting unit of a unipolar voltage supply voltage, -a circuit The control unit additionally contains a pulse generator, three switching channels of controlled rectifiers, one three-input and two two-input AND gates, two inverters, and OR gates. a pulse frequency doubling switch connected in series with the low-power winding of the voltage source, a synchronizer and a pulse duration adjustment unit, the switching elements of the unipolar voltage for bipolar and the unit for setting the duration of supply of unipolar voltage is connected in series, the second output of the latter is fed to the first input of an OR logic element, the second input of which is connected to the output of the block that specifies the duration of supply of bipolar voltage and the input of the first inverter, and the output is fed to the first input of a three-input logic element And, the second input of which is connected to the output of the pulse duration adjustment unit, and the third input is connected to the output of the pulse generator and the first input of the two-input logic element I, the connection It is connected with the input of the third switching channel, and the first input with the output of the second inverter, the output of the first inverter simultaneously being fed to the second inverter and one of the inputs of the second two-input logic element AND, the output of which is connected to the input of the second switching channel , and the second input of the And element is connected to the output of the three-input And element and the input of the first switching channel. and yo FIG. 2