DE2320702C3 - Circuit arrangement for generating controllable pulses for electrical discharge machining - Google Patents

Description

The invention relates generally to the field of electrical discharge machining, and more particularly to one Circuit for controlled current and To apply voltage pulses to the spark gap consisting of the tool and workpiece electrodes.

The relaxation oscillator originally used for electrical discharge machining with a parallel connection of voltage source, energy storage and spark gap meet the condition of a short-term energy concentration, but have, among other things, the disadvantage that during the charging of the Energy storage no contribution effective erosion is delivered to the workpiece. In DE-AS 13 01 698 is has therefore already been proposed, the voltage source, a coil as an energy store and the To connect spark gap in series, so that the charging of the energy storage via the spark gap he follows; after switching off the voltage source, the energy storage device discharges accordingly polarized diode bridging the spark gap and the memory. From the aforementioned prior publication it is also known to make the edges of the current pulses steeper, either with a 2-pole Switch, the 4 poles of which are cross-connected by 2 diodes and so a pole changer for the Create tension sources, or by using a ferrous coil as an energy store and by taking advantage of the considerable change in impedance of a such a coil during the transition from the unsaturated to the saturated state. But there is always a complete one Charging and discharging of the energy store, and this requires a very small range of variation Pulse frequency; in particular, a very high pulse frequency can not be achieved, so that coarse and Finishing of a workpiece cannot be carried out with the same machine.

The object of the invention is therefore, while maintaining the energetically favorable series connection of Voltage source, energy storage and spark gap a circuit arrangement for generating electricity and to specify voltage pulses for electrical discharge machining that have steep edges and their Duration and frequency can be regulated in such a large range that rough and fine machining with the same machine can be carried out.

This object is achieved by the circuit according to the invention according to claim 1; advantageous further training the circuit according to the invention are specified in the subclaims.

To achieve the stated object, the invention is based on the knowledge that pause time and Discharge time in the spark gap is arbitrary and independent of the respective energetic state of the Storage must be controllable so that the energetic state of the storage is then controlled in a self-regulating manner must be and that steep edges of the current and voltage pulses only open by real and Closing the spark circuit, so can be generated by a switch. The invention works further from the knowledge that under these circumstances it is most expedient if the energy content of the memory fluctuates only relatively little around a constant value. To this latter To meet the condition, a further circuit is provided according to the invention in addition to the spark circuit, which is used to regulate the energy content of the storage tank.

For a better understanding of the invention, reference is made to the drawings. It shows

1 shows a first embodiment of the circuit arrangement,

F i g. 2a to 2c represent electrical quantities which determine the operation of the circuit according to FIG. 1 in the case of a Illustrate finishing,

F i g. 3a to 3c correspond to FIG. 2a to 2c however, in the case of a quick turnaround, i. H. on the operating status of the preprocessing,

4, 5 and 6 show three other embodiments,

Figure 7 illustrates a modified embodiment the circuit according to FIG. 1,

F i g. 8 shows a circuit similar to the circuit of FIG. 1 corresponds to, in the case of a processing machine, in which the circuit for generating pulses by the effective occurrence of each electrical Unloading in the processing zone is controlled.

The in F i g. The circuit shown in FIG. 1 contains a direct current source Bi which is intended to supply the machining current which is required for drawing / sparking between an electrode 1 and a workpiece 2 to be machined.

The positive terminal of the power source B _x is connected to the electrode 1 by a branch which has in series an auxiliary _{power source B 2} , an automatic on and off switch Si, a resistor R _x and a self-induction coil Li forming a magnetic energy storage device. This branch is bridged by a diode D ₂ , which connects a terminal of the current source B \ to the terminal of the coil L \ connected to the electrode 1.

The resistance R \ is very small and enables the current flowing from the current source B \ to the coil Li to be measured in a simple manner. This measured value is applied to the input of a device 3 controlling the operation of the on and off switch S \ in order to regulate it to the desired mean value by chopping it.

As a result of its very low value, the resistance R _x does not play a noticeable role in limiting the current running between the electrode 1 and the workpiece 2 to be machined. This resistance R \ is therefore not comparable with the resistances for limiting the discharge current in the known circuits mentioned above.

The negative terminal of the current source B \ is connected to the "workpiece 2 by an automatic on-off switch 52 which is actuated by a pulse generator. 4 A diode D _x connects the negative pole of the current source B \ to the connection point 5 of the on / off switch Si and the resistor Ru

Finally, a capacitor C _{x is provided in} parallel with the current source B \ to allow the passage of the current components at high frequencies.

The auxiliary power source B ₂ is not indispensable, but allows energy to be stored in the self-induction coil Li during the periods during which the electrode is removed from the workpiece to be machined and thus does not generate any current discharges. The voltage of the current source B ₂ is of the order of 4 volts, while the main current source ßi, for example, has a voltage of the order of 80 volts.

The operation of the circuit according to FIG. 1 is in The following is explained on the basis of two different cases, the first of which is an operational state of finishing and the second corresponds to an operating state of the preprocessing

During the finishing process, the current is relatively weak, while the frequency of the discharges is high. This discharge frequency is determined by the pulse generator 4, which acts on the on / off switch S2. These pulses are illustrated in Fig. 2a, the conductive state of Sz with / and the non-conductive state is represented by O

The conductive state / and the non-conductive state O of the on / off switch Si are caused by the control device 3 in accordance with the current flowing through the resistor R \ Setpoint that is below the first setpoint becomes Si conductive. As a result, the opening and closing times of the on and off switch Si can vary as a function of the desired mean current, which is fixed by the specified setpoints

Before machining, the electrode 1 is removed from the workpiece 2 so that the circuit does not constitute a path for the passage of current from the power source B \ . On the other hand, the current source B ₂ allows a current to flow in the coil Li, which current increases until it reaches a desired value. At this point in time, the control device 3 acts on Si in such a way that it switches off the current source Bi. The current in the coil L] decreases as it passes through the diode D ₂ , the current source B _x , the diode D _x and the resistor R \. As soon as it falls below a second setpoint value, which is below the first setpoint value, the control device 3 makes the on and off switch Si conductive, and the power source B _{2 again} supplies energy to the magnetic memory formed by the coil Li in order to convert the current into to enlarge this coil until it reaches the first setpoint.

At the point in time at which the electrode 1 is sufficiently close to the workpiece 2 that the spark voltage in the machining zone is below the voltage of the power source B _x , discharges are generated by pulses in the machining zone every time the on / off switch S is pressed _{2 is} conductive. In the machining state, every time the on and off switches Si and S _{2 are} simultaneously conductive, machining current is supplied from the power source B _x through the power source B ₂ , the on / off switch Si and the self-induction coil Li, so that the latter is simultaneously a stores certain energy.

During the time intervals in which the on and off switch S2 is open, but the on and off switch Si is closed, the current source B _{x is} switched off, and the current flowing in the coil Li increases when it passes through the diode D ₂ , the Current source B ₂ , the on / off switch Si and the resistor R _x . If, on the other hand, the on / off switch Si is open but S2 is closed, the current source ßi can no longer emit, and the current of the coil Li decreases when passing through the processing zone, the on / off switch S ₂ , the diode D _x and the resistance R _x . During this phase, part of the energy stored in the coil Li is transferred to the processing zone.

When the two on and off switches Si and S _{2 are} open, the current in the coil Li decreases as it flows through the diode D ₂ , the current source B _x , the diode D _x and the resistor R _x . In this latter case, a part of the coil Li

Replaced stored energy from the power source B \ .

F i g. 2c is a diagram illustrating the changes in current in the coil L \ as a function of time and the open and closed positions of the on and off switches 5i, 5 and Si shown in FIG. 2b and 2a are shown. It can be seen that when the on and off switch Si is closed, the current in the coil L \ increases markedly during each closing time of the on and off switch Si , whereas it remains essentially constant during the non-conductive periods of the last-mentioned switch. During the periods in which the on / off switch Si is open, the current of the coil L \ decreases to a certain extent, but more strongly during the periods in which it flows through the current source B \ , since the voltage of this current source is higher than is the arc voltage between the electrode t and the workpiece 2.

The F i g. 3a, 3b and 3c correspond to FIGS. 2a, 2b and 2c, however, relate to the case of the operational state of a preprocessing, in which the closing periods of the on and off switch Si are relatively long. During each such period, the on and off switch Si becomes conductive or non-conductive several times in order to keep the value of the machining current between the two setpoint values. Each conductive period of the on and off switch S \ corresponds to an increase in the current flowing through the coil L \ , while each period of the non-conducting of the on and off switch S \ corresponds to a decrease in the current in the coil L \ , since this current flows through the voltage source B \ flows.

At the point in time at which the on / off switch Si opens, ie becomes non-conductive, the current in the coil L \ continues to flow through the processing zone, the on / off switch S ₂ and the diode D \ .

When the on / off switch Si becomes non-conductive, the current in the coil L \ is reduced and flows through the diode D ₂ . the current source B \ and the diode D \. As soon as this current falls below one of the setpoint values, the on / off switch Si closes again, and at this point in time the current of the coil L _{x flows} through the diode D ₂ . the power source Bi and the on / off switch Si.

In summary, the generator circuit shown in Fig. 1 contains a main circuit which is formed by the on and off switch Si, the coil Li, the processing zone and the on and off switch Si , as well as three breakover circuits which are formed by the loops which the Make it possible to maintain the current in the self-induction coil Li when one or the other on and off switch or both on and off switches Si and Si is or are open.

The circuit according to FIG. 4 differs from the circuit according to FIG. 1 only in that the auxiliary power source Bi is omitted and the on / off switch Si is not arranged in series with, but in parallel with the machining zone.In this circuit, the discharge current is supplied to the machining zone by the power source B \ when Si is closed and S. _{2 is} open If both on and off switches Si and Si are closed, the current source B \ feeds the coil Li further via a breakover circuit, which contains the on and off switch Si, the resistor R, and the on and off switch S ₂

When the on / off switch Si is open, the current of the coil Li remains, although it decreases, and flows through the processing zone, the diode D \ and the resistor Ri, if Si is open, or through the on / off switch Si, if it is conductive, then through the diode D \ and the resistor R \. In this latter case, the decrease in current is very small because the circuit has a very low impedance.

In the case of FIG. 4, the diode Di is required to avoid overvoltages when the electrode 1 is withdrawn from the workpiece 2 to be machined and the on / off switch Si is in the open position. The current caused in the coil Li can then flow through the diode Di and the on / off switch Si if this is conductive, and in the opposite case through the diode Di, the current source Si and the diode D \.

The circuit according to FIG. 5 again comprises a main circuit which is formed by the on / off switch Si, the resistor Ri, the self-induction coil Li and the machining zone between the electrode 1 and the workpiece 2. One can also find diode D ₂ in FIG. ! and 4, which connects the electrode to the positive terminal of the power source Bi , and the diode Di again, which is parallel to the assembly comprising the resistor Ri, the coil Li and the processing space.

In this embodiment, the discharges in the machining zone are controlled by an automatic on and off switch S3, which is arranged in parallel with the self-induction coil Li and in series with a diode Dz . An auxiliary power source Bi is located between the coil Li and the electrode 1.

If the electrode 1 is not yet in the vicinity of the workpiece 2 to be machined and the two on and off switches Si and S _{3 are} closed, the current source Bi causes a current to flow in the coil Li. This current flows through two parallel branches, from one of which contains the diode Di and the on / off switch S3 and the other contains the diode Di and the on / off switch Si. When one or the other of these two on and off switches is open, the current of the current source Bi obviously only flows through one of the aforementioned branches. If both on and off switches are open at the same time, the current produced in the coil Li by the current source Bi decreases when it passes through the diode Di, the current source B \ and the diode D _x .

If the distance between the electrode 1 and the workpiece 2 is sufficiently small to enable machining, and if the on / off switch Si is closed, the power source B \ supplies the machining current through the coil Li and the power source B ₂ without regardless of the position of the on-off switch S3 that is separated from the diode Dz in fact, the voltage of the power source is W _x much higher than the voltage of the power source Bi and occurs mostly at the ends of the coil L, so that the A - and switch S3 is held at a positive potential with respect to the anode of the diode D3 . This on / off switch and this diode could therefore possibly be replaced by a thyristor. In any case, the on and off switches S2 and S3 are never closed simultaneously in the circuit according to FIG do when the on and off switch S3 is closed, ie

is conductive.

When the on / off switches S \ and 53 are open, the current of the coil L \ feeds the processing zone by flowing successively through the power source B ₂ , the diode D \ and the resistor R] . The interruption of each processing pulse is obtained by closing the on and off switch S3 , which is accompanied, so to speak, by the opening of the on and off switch Si . In this case, the current of the coil L \ is maintained when it passes through the power source B ₂ , the diode Ch, the on / off switch 53 and the resistor R \ .

In the circuit according to FIG. 6, the power source B \ with the processing room can be switched in series with the respective terminal of this power source by means of two automatic on and off switches 5 ₄ and 5 _5. Two diodes A and D ₂ connect the negative pole of the power source B \ or the electrode 1 to one or the other terminal of the on / off switch 5s.

In this circuit, the magnetic energy store is formed by a self-induction coil L ₂ , which is connected in parallel to the processing zone with the interposition of a diode Dt. As before, the current flowing through the coil L ₂ is measured by reading the voltage at the ends of a resistor R ₁ with a very small value, which is in series with the coil L ₂ . As in the case of FIG. 5, the device 3 for controlling the current acts on the on and off switch 5i by means of an AND circuit 7, one input terminal of which is connected to the pulse generator 4. In this way, the on and off switch S ₄ must follow the opening commands given to the on and off switch 5 ₅ , ie the pulse commands.

_{In the case of FIG. 6} , if the electrode is too far away from the workpiece 2 to enable machining discharges to be produced, the on / off switch S _{4 becomes conductive at the same time as S 5} , until the rated current in the coil L is reached _{2 is} obtained. During the periods in which S ₄ and S ₅ are open at the same time, the current produced in the coil L ₂ is maintained, although it decreases as it passes through the diode D ₂ , the current source B \ and the diode A. As soon as the nominal current is reached, the on / off switch S ₄ becomes non-conductive and the current source B \ can no longer be connected to the coil L ₂ .

If the distance between the electrode and the workpiece allows the production of discharges, the current flowing in the coil L ₂ runs through the processing zone every time the on and off switches S ₄ and Ss are simultaneously non-conductive. If only the on / off switch Ss is conductive, the current in the coil L ₂ remains when it passes through the diode L \ and Ss. If, on the other hand, the on / off switch Ss is open and S _{4 is} closed, the current of the coil L ₂ remains in the same way, but this time it flows through S ₄ and A-

When the two on and off switches Sk and Ss are closed, the current in the coil L _{2 increases} under the action of the current source B 1.

F i g. 7 illustrates a circuit of the type shown in FIG. 1, but with two current sources being provided. This B \ and current sources designated B3 have different voltages and may be used individually or can be connected together by automatic on-off switch S ₂ or S '. ₂ In this way, it is possible to apply the high voltage to the machining current by means of the current source B \ , as is known per se.

The circuit of FIG. 7 comprises two circuits, each of which is the circuit of FIG. 1, with each of these circuits containing one or the other of the power sources mentioned. Each circuit has an on and off switch Si or an on and off switch S ₂ . The on and off switch S ₂ is double-pole and shown in the form of two breakers S ₂ and S'2. These interrupters are each connected between the coil L \ or L \ and the electrode 1, instead of between the negative terminal of the corresponding power source and the workpiece. A diode D ₅ is intended to prevent the current source B3 with high voltage from loading the current source B \ with low voltage when the two on and off switches are closed and the current discharge between the electrode 1 and the workpiece 2 is not yet has used. When using two separate current sources B \ and Bi and an actuation independent of the on and off switches S ₂ and S'2, it would be possible to use current pulses of different levels, as is known per se, or separate supplies from at least two tool electrodes .

A variant of this circuit could be implemented by replacing the two current sources B \ and Bz with a single current source, which would consequently feed the two coils L \ and L \. The two on and off switches S ₂ and S'2 would then be synchronized, as shown in FIG. 7 is shown.

One could also just as many parallel circles and consequently just as many self-induction coils as connected in parallel to the on and off switches Si and S2 Provide transistors. Such an arrangement would have the advantage of being carried out by each transistor flowing currents can be kept in balance.

F i g. Figure 8 illustrates the application of the circuit of Figure 1 to a machine in which the pulse generator is controlled as a function of the production of the current discharge. In a circuit of this type, which is known per se, the discharge current flows through a resistor R ₂ and the voltage occurring at the ends of this resistor is applied to a trigger circuit 8 in order to deliver a pulse with the steepest possible edges each time a discharge is established . This pulse is applied to the input of a monostable multivibrator 9, which determines the duration that you want to give the pulse. To the flip-flop 9, a monostable multivibrator 10 connects, which determines the duration of which controls the end of a pulse from the start of application of the voltage to the machining area for the next pulse separates the flip-flop 10 by means of a Umpolschalters 11 a transistor T _2, the the role of the on / off switch S ₂ of FIG. 1 plays.

It is particularly pointed out that numerous variations of these circuits can be made, and particularly in the case of FIG. 1, the auxiliary power source B _{2 could be} omitted. In such a case, it would no longer be possible to provide an energy store in the coil L \ before the electrode 1 is in the machining position with respect to the workpiece 2, and the

Machining would be started by a series of pulses, their intensity progressing would increase until the nominal intensity is reached.

In the case of FIG. 1 you could also switch the auxiliary power source B2 into another breakover circuit, z. B. in series with the coil Li or in series with the diode D ₂ .

In a modified embodiment, the self-induction coil L \ could act in the circuit by means of a current transformer. One could also consider closing the second circuit of this transformer by one of the on and off switches in series with the coil L \ , so that the current flowing in this coil when the two on and off switches are open , through the power source B \

10

can flow through it in the opposite sense to the current it can deliver. The primary winding of this transformer would then be connected in parallel to the second element D _{2, which is} conductive in one direction, between one of the terminals of the current source β and one of the electrodes. The operation of such a circuit would be similar to that of the circuits which form the subject of the previous examples.

The addition of this transformer could have the benefit of reducing the voltage and current to the Utilization of one of the on and off switches and the self-induction coil as a function of the transformation ratio this transformer can be chosen.

For this purpose 3 sheets of drawings

Claims (7)

Patent claims: 1.Circuit arrangement for generating controllable pulses for the electrical discharge machining of a workpiece electrode with a tool electrode, in which a direct current source feeds the spark gap and a self-induction coil as an energy store via a first switch, in which the temporary discharge of the energy store via the spark gap takes place with the aid of a first diode and in which a second switch conducts or does not conduct the current flowing through the energy store through the spark gap, characterized in that a control device (3), known per se, is provided to control the current through the energy store with the aid of the first switch (S \) (L]) to keep constant within predetermined limits, that the second switch (S ₂ ) can be controlled by an adjustable pulse generator (4) and that a second diode (L \ ) controls the first switch (S \) and the energy store (L \ ) bridged in such a way that the current flowing through the energy store (L {) can continue to flow even when the spark electrodes (1,2) are switched off. 2. Circuit arrangement according to claim 1, characterized in that the second switch (S ₂ ) is in series with the energy store (Xi), the spark gap (1,2) and the first diode (D \) in a manner known per se. 3. Circuit arrangement according to claim 1, characterized in that the second switch (S ₂ ) is connected in parallel to the spark gap (1, 2) in a manner known per se. 4. Circuit arrangement according to claim i, characterized in that the series connection of the second switch (Sz) and a third diode (D ₃ ) is connected in parallel to the energy store (U) (Fig. 5). 5. Circuit arrangement according to claim 1, characterized in that the direct voltage source (B]) can be connected to the energy store (L ₂ ) via the first switch (Si) and via the second switch (Ss) and that the spark gap (1,2) via a diode (Di) is connected to the energy store (L ₂ ) (Fig. 6). 6. Circuit arrangement according to claim 1 or 2, characterized in that the spark gap (1, 2) apart from one of a direct current source (B \), a first switch (S \), an energy store (Li), a second switch (S ₂ ), a first diode (D]) and a second diode (D ₂ ) existing arrangement in parallel of at least one identical and from a direct current source (Bi), a first switch (S \ '), an energy store (L]), a second switch (S ₂ ), a first diode (D] ') and a second diode (D ₂ ) existing arrangement is fed (Fig. 7). 7. Circuit arrangement according to claim 1, characterized by an auxiliary power source (B ₂ ) in series with the energy store (L]).