DE1008428B - Method and device for spark erosion using alternating current - Google Patents

Description

GERMAN

The invention relates to a method and a device for material removal by means of Spark erosion using alternating current.

It is characterized in that it is located on the spark gap. AC voltage a half-wave is at least partially suppressed for the purpose Change of the stress curve and thus the gap formation.

The device for performing the method is characterized in that the electrode and the workpiece through a. Current-direction-dependent switching element with variable forward resistance are bridged in a reversible polarity, It has already been proposed that such a bridging not reversible polarity make, but with such an arrangement, the advantages explained below, of the invention. Establishment cannot be achieved.

Some exemplary embodiments of the subject matter of the invention are explained with reference to the drawing. It shows

Fig. 1 is a basic circuit diagram,

Fig. 2 is a circuit diagram of the electrical equipment for spark erosion with a tilting circle generator,

Fig. 3 a, circuit diagram of the electrical. Facilities for spark erosion with an oscillating circuit,

Fig. 4 is a circuit diagram of the electrical. Facilities, for spark erosion with a pulse generator,

5 shows a circuit diagram of the electrical equipment for spark erosion with another pulse generator,

6 shows a cross section through a workpiece produced by means of the method,

Fig. 7 a and. 7 b Cross-sections through another workpiece produced with the method.

The circuit shown in Fig. 1 consists of a generator 1, which feeds the erosion path in the usual way and whose voltage and frequency can be changed. At 2, the erosion path is shown, which can be surrounded in the usual way by a liquid dielectric. At 3 is a. Reversing switch included in the circuit, which, however, does not necessarily have to be used. In parallel to the erosion tree there is a valve 4 above another switch 5, which returns or destroys part of the total energy in one or the other direction of flow in the output circuit, as well as a variable resistor 6 in series with the valve, with which the effectiveness of the Valve can be influenced on the spark gap.

This basic arrangement can be applied to all generators commonly used up to now for electrical discharge machining; so is generator 1 in the illustration FIG. 2 shows a breakover circuit generator, FIG. 3 shows a

for spark erosion using alternating current

Applicant:

AGIE Aktiengesellschaft for Industrial Electronics, Locarno (Switzerland)

Representative: Dr.-Ing. E. Hoffmann, patent attorney, Munich 22, Widenmayerstr. 34

Claimed. Priority: Switzerland from March 19, 1956

Werner Ulimann, Locarno (Switzerland), is named as the inventor

Resonant circuit generator and in FIGS. 4 and 5 a Pulse generator. The prerequisite for the operation of these generators is that the consumer in is current-permeable in both directions; However, this requirement is present in the planar arrangement Fulfills.

Almost all known rectifier types can be used as valves are used, preferably also inductors, with sharp, saturation kinks and a direct current bias through a further winding. . "

The tension between the tool and the workpiece can also be changed. Depending on the The height of the voltage changes the dimension of the spark gap. . .

It is well known that with a spark or bed An arc removes the amount of material removed from an electrode from the polarity. Is for example

when applying the fig. 1 the cathode of the spark gap the workpiece to be machined and the anode, a working electrode, takes place on the workpiece with a relatively smaller material distance than at the electrode. If switch 6

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actuated and the inverted rectifier ¹ thus also the workpiece and the electrode exchange their polarity, now a greater Materialmetige ¹ is removed than at the electrode to the workpiece. The ratio of removal per unit of current in both directions depends on the material, but it corresponds approximately to a ratio of. 1: 4.

An example of one with the one described! procedure FIG. 6 shows the manufactured workpiece. A hole is to be made in a workpiece is extended at its end. The procedure at hand is as follows: The electrode 7 is connected to the positive pole of the voltage !, the workpiece 8 to the negative one and the electrode is introduced into the workpiece in a known manner. With this circuit, As mentioned, more material is removed from the electrode than from the workpiece, creating the neck the hole is obtained. If the electrode has reached the kink 9, the polarity of both switches is reversed; Now, the larger amount of material is removed from the workpiece, creating the bag-like expansion is won.

Depending on the use of different materials as a tool, e.g. B. different metals, semiconductors or insulating materials with metallized · surfaces on the one hand and as a workpiece on the other hand, the erosion performance at the anode and cathode is well known different.

By choosing the polarity, the voltage on the workpiece, the electrode material and the energy content, that flows through, the shunt, can that Mass of the eroded material can be changed in a known manner.

For example, if the positive voltage of 220 V is applied to the workpiece, a certain one results Electrode diameter a bore of 5.99 mm, but with the same polarity a voltage of 800 V a bore of 6.06 mm, after a polarity reversal a bore width of 6.09 mm.

By means of the variable and reversible flow resistance of the valve, all drilling widths, between these extreme values, possibly also continuous transitions between, these values.

Up until now it was very difficult to use spark erosion to precisely produce cylindrical holes, because a certain burn occurred on the electrode, which the, effective cross-section of the electrode decreased. The bore was therefore slightly conical, which approved the use of spark erosion Limited problems. By means of an advantageous; Further development of the method according to the invention can this disadvantage be circumvented by that the suppression of the half-wave continues with the advancement of the electrode in the workpiece is changed in such a way that the change in the electrode caused by the erosion of the electrode Hole cross-section is compensated for by widening the spark gap, so that completely cylindrical bores are created. The readjustment of the upstream resistor 6 is preferably carried out automatically with the advance of the electrode into the workpiece, it can, but also from other variables, such as the current strength in the spark gap, can be made dependent.

Another application of the method is for the production of workpieces which have the shape of the illustration in FIG. 7b. It has been found that when machining workpieces by means of spark erosion, protruding corners can best be formed when the workpiece is the positive pole and the electrode is the negative pole of the spark gap. In the case of recessed corners B (FIG. 7 a), however, it is more advantageous to connect the workpiece to the negative pole and the electrode to the positive pole.

In the production of z. B. holes, with the one shown in, Fig. 7 b. Cross-section, an electrode with the cross-section shown in FIG. 7 a is first used, the protruding corners, A not being formed in the electrode. When using this first electrode, only the corners are worked out. As already stated, in this part of the machining process the electrode represents the positive pole and the workpiece represents the negative pole. Once this first electrode has passed through the workpiece, the second electrode is used, which is shown in cross section in FIG. 7b is. This time the corners, B are excluded from the process, while the protruding corners are worked out, the polarity of the connections being reversed compared to the first part of the process.

Since in the method just described, there is a difficulty, the second electrode exactly to center the already created hole !, only one electrode can preferably be used, the lower part of which, first introduced into the workpiece, has the cross section of the electrode of FIG. 7 a, while the 'upper, second part has the complementary cross section as in Fig. 7b.

Claims (7)

Patent claims: 1. Process for material removal by means of spark erosion using alternating current, characterized in that from, the alternating voltage lying at the spark gap a half-wave is at least partially suppressed in order to change the voltage curve and thus the gap formation. 2. Facility for carrying out the procedure according to claim 1, characterized in that the electrode and the workpiece by a current direction-dependent switching element variable on resistance bridged reversible polarity are. 3. The method according to claim 1 for production of holes, characterized in that the suppression of the half-wave is continuous, with The progression of the electrode in the workpiece is changed in such a way that the change in the electrode caused by the erosion of the electrode Hole cross-section is compensated for by widening the spark gap, so that completely cylindrical bores are created. 4. Device according to claim 2, characterized in that the electrode is designed is that they over part of their length formally opposed to erosion with positive tension the workpiece is suitable for erosion with negative stress over a further 'part. 5. Device according to claim 2, characterized in that that the current-direction-dependent switching element consists of a rectifier and a variable resistor lying in series with it consists. 6. Device according to claims 2 and 5, characterized in that the rectifier has a has a lower forward resistance than the ignited spark gap. 7. Device according to claim 2, characterized in that that the current-direction-dependent switching element can be regulated from one with Gleiohstrom presaturated choke with a sharp kink consists in the saturation characteristic. Publications drawn in bed: »Publication series des Verlag Technik«, Berlin, Vol. 177, p. 71. 1 sheet of drawings