DE1765669C - Circuit arrangement for regulating the width of the working gap in electro-erosive or electrolytic processing machines - Google Patents

Description

However, here the over- The following is about the electrical control transition zones between the physical gap states and regulation of the arrangement described so far the ones that came in as normal operation, similar to a short-shot. A tap is at the Sangeais working gap Short-circuit or open-circuit state called Bracht This tap can both the electrical not clearly defined 5 variables (e.g. voltage, current, pulse duration, repetition

The invention is based on the object of setting a frequency of the pulses) as well as the hydraulic

Circuit arrangements of the type mentioned at the beginning see size relationships (e.g. fluid pressure,

to create which the various physical flow rates, temperature, etc.) in the working gap 5

Clearly differentiate between gap states and detect the disturbance. It is decided in each individual case

the resulting effects of the standstill or the ίο soft size of the electrical or hydraulic

wrestle speed of the electrode while seeing parameters in the working gap to control and

Target state for the further controllability when regulating the feed rate of the tool electrode 2

new control deviation should be avoided. In the present embodiment

The invention is characterized in that three examples of FIG. 1 is the working voltage (spark input side threshold value voltage connected in parallel) is selected as a parameter in the working gap are more present which have been applied to the three. However, this does not mean that the invention Driving forces idling, normal operation or short circuit only with this parameter as a control or regulation equivalent Values of the electrical quantity on the quantity works. On the tool electrode 1 and Working gap are set, and that the swell workpiece electrode 2 are the two lines 11, value amplifier for open circuit or short circuit per pair 20 12 connected. The one tapped in this way wise with an output of the threshold amplifier voltage reaches a potentiometer 13, on welfür Normal operation at a summing device similarly a reduced voltage by means of dt s closed to movement are. borrowed tap 131 and tapped on the filter

The device of the invention can be given at 14 both. The filter is intended to transform the pulse-shaped material removal by sparks with the dielectric working gap voltage into a corresponding liquid in the working gap as well as in the case of voltage. The details of the filter 14 are electrolytic material removal with the electrolytic described in more detail later,
see liquid being used in the working gap. This DC voltage reaches the downstream

In the following, exemplary embodiments of the switched device 15 according to the invention are described

Finding explained in more detail with reference to the drawings. 30 discontinuous amplifier trained device

It essentially contains several input-side

F i g. 1 shows an exemplary embodiment in the case of switching stages lying upstream in parallel. Each of the switching levels

thrust device with hydraulic drive in see- is a certain level value of the working gap voltage

matic representation, assigned. So a switching step speaks to high

F i g. 2 the entire electrical switchgear in 35 voltage, another on medium and another

Block diagram, on deep tension. The values of each

F i g. 3 the diagram of the mode of action of the voltage differ only so far from-

Embodiment of FIG. 1 and 2, one another, that a switching step when idling

F i g. 4 an embodiment example with a pre (high voltage at the working gap, no current feed device with electric motor drive in 40 gear through the electrolytic or dielectric Block diagram and liquid) and the other switching stage in the other

F i g. 5 shows the detailed circuit arrangement. approximate short-circuit case (very low voltage on the

In Fig. 1, the tool electrode 1 and working gap, very high current passage through the

the workpiece electrode 2 in a container 3 with liquid) comes into operation. The third switching stage

a dielectric or electrolytic liquid 45 is used in normal metalworking

4 and form a working gap 5. (Voltage and current in the working gap are normal

The working head 6 of a feed device compares level values to). In the third switching stage,

pushes the electrode 1 in its local position to what is in the normal state or in the »equal

Workpiece 2, which by sparks or electro-weight condition «on the drive 10 of the feed unit

is processed lytically. In the cylinder 7 is a 50 direction 6, 7, 8 acts, an oscillator is provided,

Piston 8 is provided, which corresponds to one of the vibrations with a certain frequency by a

hydraulic pressure that is emitted in the machine frame in the middle layer. This creates an artificial

slidably arranged working head 6 upwards Liches, unstable behavior of the drive 10 of the

or moved down. This means that the local feed device is used during normal machining.

Position of electrode 1 in relation to workpiece 2 is set. 55 caused.

The direction of movement of the working head 6 directs the operation of the discontinuous insurance then whether the hydraulic pressure medium via amplifier 15, whose outputs via the lines 16, one or the other inlet channel 81, 82 in FIGS. 17, 18 with the electromagnetic coils 102, 103 Cylinder 7 is introduced. The control for this purpose of the servo valve 10 is connected as follows: followed by the electromagnetic servo valve 10, 60 when there is no electrical discharge machining whose control piston 101 is either in the one or (idling), is via the lines 16, 17 the other direction moved by the coils 102,103 electromagnetic coil 102 actuated so that over will. At 83, the inflow and outflow lines for the actuated control piston 101 are a pressure medium draws, soft with the reservoir for the pressure from the line 83 in the line 81 and thus in medium and connected to the pressure pump. 65 the part of the cylinder 7 above the piston 8 a-This There is no flow in things in the hydraulic system. The working head 6 and the electrode 1 in particular drawn in, as they are already moving in the direction of workpiece 2. As soon as the can be assumed. Working gap 5 has become so small that a fun-

If discharge takes place through the liquid, the voltage level in this range assumes a normal value for a working gap voltage. correct value adjustable. The Schmitt trigger 152 In this case, the two electromagnetic coils 102, 163 voltage (equilibrium level) are set to a voltage level of 4 V DC-18 via the lines 16, 17. The Schmitt alternating with a certain frequency below 5 triggers 153 is at a voltage level of 2.5V Current set As a result, the control piston receives DC voltage set. Depending on which one 101 of the servo valve; 1§ a vibration of the same voltage level as the working gap voltage, Frequency. The pressure medium arrives so either the switching stage 151 or 152 or instruct over the lead 81 or lead 82 in the 153. During the switching stage 151 on the empty upper or lower part of the cylinder 7. Since the io! Conspicuous in the working gap and the switching stage 153 on Control piston 191 but only makes very little control impacts in the case of a short-circuit in the working gap, the pressure fluctuations are the speaking, under normal working conditions in the Medium in the cylinder 7 so small that the electrical working gap 5 actuates the switching stage 152. The austrode 1 hardly or not at all in oscillation gears of the switching stage 152 are set with the following movement. This is related to the entire 15 of the summing assemblies 154, 155. the The mass or the weight of the feed drive switching stage 151 is only possible with the summation arrangement together. If now a short-circuit-like 154 and the switching stage 153 occurs only with the summing case and the working gap voltage is very small arrangement 155 connected. In the summing arrangement. the electromagnetic coil 103 thus receives voltages 154, 155, the voltage signals from over the lines 17, 18 current from the amplifier 15. * o the stages 151, 152, 153 added. This is in the The pressure medium is described in more detail from the line 83 by the following: The differential verden actuated control piston ItI via the supply line stronger 156, which is connected to the outputs of the An-82 in the lower part of the cylinder 7 of the order 154, 155 thus receives either Working head 6 and electrode 1 now move the voltage signal from switching stage 151 at away from the workpiece. This happens as long as »5 idle state in working gap 5 or, in the case of short, the normal machining state in working gap, a final-like state in working gap 5 that The voltage signal from switching stage 153 is available again.

During the normal processing process according to these signals, the differential is actuated by the artificially produced stronger 156 either the coil It2 or It3 des stable behavior of a switching stage of the drive It in 30 Servoventfls It. As a result, the piston a> vibrationc brought about a central position without ItI of the servo valve either in one or the other that the working head 6 and the electrode 1 also shifted direction. If the values of the be set in swing motion. As a result of the working gap voltage corresponding to the relative leg stability behavior of the drive It, the movement of the tool electrode I to the workpiece 2 speaks entire feed device to signals, which change continuously in 35, result in clamping * - the non-normal processing cases (idle values in which not just one, but two Shah or short-circuit-similar cases) from amplifier 15 stages, z. B. 151 and 152 or 153 and 152. are spoken, very evenly with great sensitivity. In such a case the differential picks up quickly. amplifier 156 from summing assemblies 154

In FIG. 2, what has been discussed so far is now shown in 40 or 155, the added voltage values from the at-Detail. On the fotenoometer 13, the switching stages. As a result, a frequency pickup 131 is tapped off of the electromagnetic coils It2 or 193 working-cycle voltage, which has been reduced to a certain level. Another Wi- the servo valve It is possible. As in F i c. 1 derstand 132 is also provided, specifically for the described, the feed device with the help of the fact that the working gap voltages can reach the 45 of the piston 8 either in one or the other Rich value higher than 100V. Adjusted between device Under normal Arbcitsbedinguncen in these two resistors there is still a central working gap 5, only the switching stage 152 is provided in Tatickeit tap, which is also attached to the electrode and via the Summieranordnunceri 154.155 electrode 1. This central tap is used and the Differential amplifier 156 over the LeitunfÜT voltages between 60 and 100 V. The lower so geo 16. 17, 18 Anf the coils ItI. 1 «3 cyclically like-the end of the potentiometer 13 is the workpiece 2 receiving signals. As described earlier, the filter 14 is switched on when the SteoerkoTben 11t of the Scrvo tap 131 "vibrates". 1 described- Fig. 1 has been written in detail, so that ben here. The conductor 14 is followed by an emrtter photogenitor 55 more repetitively grounding needs amplifier 141. This will be described in more detail later. FIG. 3 shows the mode of operation as a diagram. The ska attached to this dtconti- der in the fig. I and 2 described Gcsamt & nordnuierlkbe amplifier 15 is not its essential manure. At A , the machining pulses in the work structure are shown in more detail. For three chip grooves 5 are shown. 60 level Lecrlaafnnpnise. Provided for the following three Im-153. As will be explained in more detail later, if the form becomes more normal, then each of these stages of the shifter starts a so-called “Bearbertangsänpulse”. For the next two, a named ^ * <iwii t-Τΐ * gy * · is shown. The briefing of the short-term sleep case is shown. afterwards it is connected again to the output of the amplifier after two connections and then again. For example, the Schmitt is a normal job. Below this, at B Trigger 151, for an economy range level from 5 to XV, the course of the range is shown as a curve such as (ilocbsrianming (alien level) this he wrikg after Fihcr 14? In the first two

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I. (. ΤιΙίΐιιΙ pulses is iiiicli the filler spanning the highest. The filte voltage drops aiii'a certain WfM under normal processing impulses. As soon as the short circuit has occurred in the working gap 5, the voltage after filing has dropped to approximately zero. After the cooling circuit has been remedied and the normal state of distribution is present in the working gap 5, the voltage at the output of the filter 14 rises again accordingly and is even higher when it runs out. In the curve Γ below, the voltage level of the Schmitt trigger is ! 53 been (, lower level from DC 2.5 V) was applied. It is clearly seen that in the case of short circuit in the working gap 5 of the Schmitt trigger 153 receives a voltage ·, raise at its output. This voltage increase is CIIE assembly 155 on the üiflcrcnlialverstärkei ! 56, where it activates the electromagnetic coil 103 of the servo valve SO via the lines! 7, 18 and thus activates the feed rdnung is moved over the piston 8 so that the F.lcklrode I see further away from the workpiece 2. In the curves />, /: the F i g. 3 shows the impulses which the Schmitt trigger 52 sends to the summing arrangements 154, 155 as soon as normal impulse ratios (see curve /!) Are present in the working gap 5. These oscillations are interrupted if there is a definite idle-IaII or a definite short-circuit. This shows the comparison of the curve / (with the curves /). / ·. '. In the curve / · 'underneath, the voltage signal is plotted, which eischcint at the output of the Schmitt-Tiigger 151 (upper level. 5 to 8 V adjustable). The comparison / between curves A and / 'shows that this Schmitt trigger responds only under Lccrlaul conditions in Aibcitsspalt 5. The curve C! shows the added voltage signals from the three switching slots 55, 152, 153, as they come from the arrangements 154, 155 to the dilTerential amplifier 156 . The oscillations from the Schmitt trigger 152 (equal weight level, A V) are added according to \ and -. The voltage curve from the Schmitt trigger 153 for similar cases is always higher than the oscillations from the Schmitt trigger! 52. This means! In other words, if a short circuit occurs, the feed device moves the electrode 1 away from the workpiece 2 particularly quickly. The absolute value of the output voltage from the Schmitt trigger 151 for Lecrlauffall in the working gap 5 is added to the voltage oscillations of the Schmitt -Triggers 152, namely to the other side than the voltage from the Schmitt trigger 153. This is a unique clear Tren voltage between given the individual signals to the differential amplifier 156, so that even with continuous, slow changing of the working gap voltage of the differential amplifier 156 via the lines 16, 17, 18 discrete and independent signals either on the coil 102 or on the coil 103 or on both coils can give at the same time. These precisely distinguishable signals are present although the Schmitt trigger 152 has an artificially detuned range in which the servo valve swings back and forth and in which the servo valve is indefinable in its control properties.

The F i g. 4 shows a further type of application for controlling and regulating the working gap width in electrical cellars, driving the feed device and with the simultaneous use of a vibrator for the electrode during normal electrocrosive machining. A further resistor 132 is connected to the potentiometer 13. The graphs for greater than K) OV, K) OV, OV are, as already described, connected to the electrode 1 or to the workpiece 2 . Via tap 131 of potentiometer 13 , the working gap voltage, reduced to a certain level, reaches filter 14 and amplifier 141. Schmitt triggers 151, 152, 153 are arranged on this. The Schmitt trigger 151, which responds to I.eerlaufbedbedingungencn in the working gap 5, is z. B. set to 5 V response voltage through the adjustable resistor 157 connected upstream. Via a so-called friction control, which consists of a pulse generator 20 and an astable multivibrator 2! exists, pulses with a Kcpctilioiisfrcquenz of 51 Iz at, iner pulse duration of 50 usec are given to the amplifier 192 and to the current amplifier 23 for the electromotive drive of the feed device. If the Schmitt trigger 151 has responded as a result of running conditions in the working gap, the motor 231 is controlled step by step. The flex electrode 1 will therefore gradually approach the workpiece 2. The Schmitt trigger 153, which exercises the potentiometer 158 is set to a response voltage of 2.5 V (short-circuit-similar condition in the working range), gives a continuous voltage to the amplifier 191 and further into the current amplifier 23 for the motor 231. The motor 231 moves continuously in the other direction and away from the workpiece 2. Ri-i normal working conditions in the working gap 5, the Schmitt trigger 152 responds to 4 V DC voltage. This Schmitt trigger emits, as already said about the previous figure, pulses; mf from the amplifier 19 and switches the transistor 24 into the sounded-through or blocked state at the same frequency. The circuit connected to the collector of the transistor 24, which consists of the resistors 241, 242 of the diode 245. Resistor 244 , belongs to the vibrator coil 243. Since the transistor is held at OV potential at its Hmittcr-Fleklrode. it switches iibci the just described arrangement, which is connected to a normal mains voltage 246, the vibrator 243. The coil 243 Vibratorspulc 1 enables the electrode to vibrate.

Since the Schmitt trigger 152 oscillates at a frequency of 200 Hz , the electrode 1 is also caused to oscillate at 200 Hz via the coil 243. Due to the vibrations of the electrode 1, the waste products of the material removed from the plant,

piece 2 better carried away; as soon as a short-circuit-like case or the no-load condition has occurred in the working gap 5, the vibration of the electrode stops and the Schmitt trigger 153 or 151 occurs in action to control the motor drive

231. The motor drive 23 is generally known and consists of eight switching transistors for actuating the rotor of the motor 231 either in one direction or in the other. This is not discussed in more detail, as this can be found in every manual

can and is not the subject of the invention.

Finally it should be mentioned that the arrangement of the F i g. 4 so it allows the vibrator

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for the rapid regulation of the entire system, see a so-called negative hysteresis. As a result of this and the motor drive for the slow regulation, a quusistabilun state is achieved in which lieriing can be used. This is also possible because this Schmitt trigger oscillates and this Schwinda the displacement speed of the vibrator on the hydraulic drive is sufficiently large, namely 0.5 mm per | isec. On 5 establishment there. The oscillation frees /. If this is the case, the entire system is essentially stable - approximately 200 Hz. Depending on the type of drive, the feed rate. This results in a better removal of the device, this number of vibrations can waste product from the working gap. Also is to be changed. The other two Schmitt triggers the wear of the electrode 1 much less 151, 153, which, as also already mentioned, and the roughness of the machined surface on the upper and lower level of the working gap on the workpiece 2 is much more favorable. address voltage, are designed so that at

FIG. 5 shows the exact, detailed arrangement of abnormal working conditions in the working gap of the individual components in the discontinuous continuous voltages on the diluent intensifier 15. The spark gap voltage of the respective stronger 156 is given. The Schmitt trigger 151 of the state is taken from the terminals Zi2, Ei, O from a transistor stage 7 '14 to T 16 and via potentiometer 13 by means of the associated resistors R 39 to R 50 and grilles or via resistor 132 to input diode D5. The Schmitt trigger 153 consists of resistance R 2 in the filter! 4 given. The arrangement of the transistor stage T 12, 73 with the corresponding capacitors C 1, Cl for inductance L and resistors / 32 to R 38 and the connections to the resistors R 3, R 4 results in a limit value D4.

frequency of 250 Hz. The pulses of the working gap- While the one output between the cons-

Voltage with a higher frequency result at the output stands R 17 and R 19 of the Schmitt trigger 152 on the filter 14, a corresponding DC voltage. the transistor T 11 of the summation disorder 154 and the Zener diode ZL 1 prevents the passage of the second output of the Schmitt trigger 152 between Spai.nung greater than K) V. In this way, the resistors R 21 and R 22 are connected to the transistor, the following transistor Γ 1 in the emitter follower Γ 6 of the summing arrangement 155 , amplifier 141 are protected. This emitter amplifier, the output between the resistors R 49, R 50, is followed by the Schmitt triggers 151, 152, 153 . of the Schmitt trigger 151 to the transistor 7 "10 of the Schmitt trigger 151 is via the input summing arrangement 154 and the output between potentiometer PS, the Schmitt trigger 152 via 30 resistor R 37 and R 38 of the Schmitt trigger 153 the Input potentiometer P 2 and the Schmitt switch to transistor T 7 of summing arrangement 155 trigger 153 via input potentiometer P 4. The construction of the summing arrangement is set to the respective voltage level, as already described 154, 155 from the transistors already mentioned in the previous figures with the resistors R 23 to R 27 and R 29 to. The Schmitt trigger 152 consists of the 35 R 31 and the diodes Tl and 7 3 with the two transistor stages Γ 2, T 3 and T 4, T 5 with trolyte capacitor C 6 has been made in such a way, the correspondingly arranged resistors R 7, that the addition of the various voltages up to R 22, the capacitors C3, C4, C5 and the values according to Figure 3, curve G, gives. This passes diode Dl. Due to this special structure of the now on the transistors T 8 and T 9 of the Differen-Schmitt trigger 152, which, as already mentioned several times 40 tial amplifier 156. The drive of the feeder, with normal voltage conditions in the direction is in this The case with the electromagnetic working gap 5 has been put into action, results in coils 102, 103 of the servo valve 10 shown.

For this purpose 2 sheets of drawings

Claims (6)

l 2 pulse train with a predetermined sequence convenient claims: shows 1. Circuit arrangement for regulating the width of the working gap in the case of electrical discharge machining or electrical C trolytic processing machines depending on a single, supplied as an input value electrical size of the working gap, with The invention relates to a Schaltungsanordnuni connected in parallel, to different values to regulate the width of the working gap at electro Schwell- io erosive or electrolytic processing machinei matched to the electrical size value amplifiers and with a subordinate input depending on a single input value thrust device, thereby marked supplied electrical size of the working gap net that three on the input side connected in parallel with connected in parallel, to different values Threshold amplifiers are available, which are adapted to the threshold value which amplify the three operating modes idling, normal amplification and with a downstream feed unit drive or short-circuit corresponding values direction. the electrical variable set at the working gap. So far, circuits are known that are based on Hanc are, and that the threshold amplifiers for physical states in the working gap are electrical Give idle or short circuit in pairs with a signal to the feed device and output here of the threshold amplifier for normal 20 through the tool electrode in the direction of workpiece operation Electrode connected to or away from a summing device. Because of this sen are. Moving the workpiece electrode is therefore the 2. Circuit arrangement according to claim 1, controlled by the width of the working gap and characterized in that the Schwellwertver- electrical discharge machining process so regulated more from transistorized Schmitt triggers as that with continuous material removal from the work and the input side at least partially piece electrode the width constant The construction remains a potentiometer for setting the threshold elements, which up to now have for such control and voltage values, whereby the sub-regulating devices have been used, differed between the set voltages _s i _c h all in that they either to electrical values in the range of 0 to 10 V. 30 ß _e n (such as voltage, current, pulse duration, im- 3. Circuit arrangement according to claim 1 pulse frequency) or on hydraulic variables of the elec- or 2, characterized in that the sumtrolytic or dielectric liquids ini a differential amplifier after-working gap (e.g. fluid pressure, flow rate ^ is switched, which a drive of the pre-volume, temperature, degree of pollution) start-up device actuated. 35 chen. According to this electrical or hydraulic 4. Circuitry for regulating the width-related states in the working gap are siguals of the working gap in the case of electrical discharge machining or electrical discharge and placed on a feed device trolytic processing machines depending on The feed device, which consists of an electro from a single train motor drive with reduction gears or as an input value led electrical size of the working gap, 4 ° can consist of an oil-hydraulic drive, with connected in parallel on different is controlled by these signals as long as odei Values of the electrical variable matched regulated until the actual threshold amplifiers prevailing in the working gap and with the downstream state with the feed device in the electrical discharge machining machine, characterized in that the set and desired target state is overindaß three 45 connected in parallel on the input side is correct. If these two states match Threshold amplifiers are available, which will aul the effect of the control circuit which terminates the feed device in the three operating cases: idle, normal. Only after you operation or short-circuit corresponding values actual state deviate again from the target state the electrical size at the working gap - further signals are given to the feed device, and that the threshold amplifiers for 50 The so-called "rest pause" in steering and idling and short circuit on the output side with the rules of the feed device, however, requires that this by at least one electric motor reversible further signals, the feed device does not controlled feed device \ 'are connected to control or regulate, that is, the tool electrode and the threshold value flag for normal operation, do not shift as theoretically due to the preferably via a controllable semiconductor, 55 signals would have to be. This is in the whole crowd based on the coil of a known vibrator - the tool electrode to be moved, facility is connected. For very heavy and large tool electrodes 5. Circuit arrangement according to claim 4, therefrom, for example, 1000kg and more weight makes itself characterized by the fact that the one with the this disadvantage of the "break" of the tax and Electric motor of the feed device connected very strongly to the feed device dene Schwelhvert amplifier a downstream noticeable. Has step control. Others 6. Circuit arrangement according to one of the known control systems for the feed an oszilsprüche 1 to 5, characterized in that the flowing voltage of the threshold amplifier tapped from the working gap for no-load and short-voltage 65 during the entire operation Finally, a DC voltage processing machine superimposed on its output. The ersignal and that the threshold-generated vibration of the electrode is for the better stronger for normal operation at the exit a removal of the waste products from the work