RU2486037C2 - Method of stabilising anode-cathode spacing in spark erosion shaping of grinding wheels by automatic optimising electrode feed controller - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to electrophysical and electrochemical processing and can be used for stabilisation of anode-cathode spacing at optimum value in spark erosion processing. In compliance with this invention, spark erosion shaping of grinding wheel is performed by shape electrode. Note here that electrode is fed unless electric power released in anode-to-cathode spacing reaches its maximum. Then, said spacing is kept at the level of maximum power by automatic optimising electrode feed controller.

EFFECT: higher precision of shaping.

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Description

The proposed method relates to electrophysical and electrochemical processing methods and can be used to stabilize the interelectrode gap at the optimum value using an automatic extremal controler for feeding the shaped electrode according to the observed electrical parameter during electrical discharge machining (profiling) of a rotary grinding wheel on a conductive bond.

A known method of automatically controlling the supply of the electrode during electrical discharge machining, analogue [1, 2, 3]. According to this method, the voltage of the working pulses, which indirectly characterizes the magnitude of the interelectrode gap, is compared with a predetermined optimal value, as well as with a reduced voltage value corresponding to a violation of the processing process, the results of the comparison are averaged, and depending on the average value of the comparison results, the electrode supply is controlled by changing the value of the interelectrode gap.

The disadvantage of this method is that with this method it is not possible to build fully automated machines, and there is a need to adjust the specified optimal voltage depending on the processing conditions.

Of the known closest in technical essence is the "Method of extreme regulation of the process of electrical discharge machining" [4]. This method includes adjusting the electrode feed according to the average value of the power released in the interelectrode gap, according to which the product of the breakdown delay time and the current value of the breakdown voltage of the interelectrode gap is determined and the repetition rate of technological pulses is changed proportionally to the indicated value.

However, this method has a low productivity of the processing process, since the value of the interelectrode gap corresponds to the average value of the power released in it, and as is known from [5, 6, 7], the maximum productivity during electrical discharge machining is achieved when the value of the interelectrode gap corresponds to the maximum value of power allocated in this gap. At the same time, this method also has a low stability of the processing process due to random changes in the delay time and breakdown voltage.

The invention is aimed at improving productivity and processing accuracy.

The essence of the proposed method lies in the fact that the stabilization of the gap between the grinding wheel and the electrode is carried out according to the observed electrical parameter, and this stabilized value of the interelectrode gap corresponds to the maximum performance and accuracy of profiling. According to the invention, the power released in the interelectrode gap is selected as the observed electrical parameter. The maximum profiling performance is achieved by establishing and further maintaining by the automatic extremal electrode feed regulator such a value of the interelectrode gap at which the power released in this gap, and therefore the productivity, will be maximum. Improving the accuracy of the processing process is carried out by establishing and further maintaining the gap between the grinding wheel and the electrode at the same level (stabilization of the interelectrode gap).

The proposed method of electrical discharge erosion profiling of a grinding wheel on a conductive bond includes electrical discharge machining of a rotary grinding wheel with a shaped electrode, while the electrode is supplied until the electric power released in the interelectrode gap increases to a maximum value, and then the value of the interelectrode gap is maintained at the maximum power level using automatic extreme regulator of the electrode feed drive.

This combination of new and well-known features allows us to simplify the equipment in comparison with the prototype, since it becomes unnecessary to determine the product of the breakdown delay time by the current value of the breakdown voltage of the interelectrode gap, and also to increase the productivity and accuracy of processing by stabilizing the interelectrode gap by a certain value corresponding to maximum power allocated in the interelectrode gap, and therefore maximum productivity.

Functional diagram of a system for automatic stabilization of the interelectrode gap during electroerosive profiling of grinding wheels that implements the proposed method is presented in figure 1.

It includes an extreme regulator 7, the output of which is connected to the feed drive 5, the output of the feed drive is connected to the feed mechanism of the electrode of the EDM profiling machine 2. A generator of technological pulses is connected to the electrode 3 and grinding wheel 4 of the EDM profiling machine 1. The power released in the interelectrode gap, measured by a power sensor 6, the output of which is connected to the input of the extreme controller 7.

The method is as follows. Before starting the processing, the output parameters of the technological pulse generator are set, the positive and negative poles of which are connected to the grinding wheel on the conductive bond and the profile disk shaped electrode, respectively. Then, a rotational movement of 1 ... 2 m / s is reported to the grinding wheel, after which the non-rotating shaped electrode is brought closer to the grinding wheel until electric discharges appear in the interelectrode gap. Tracking is done using a power sensor. As soon as the power becomes greater than zero, the erosion cutting of the shaped electrode into the grinding wheel by the size of its forming part begins, maintaining the power released in the interelectrode gap, and therefore the productivity, at the maximum, thereby stabilizing the value of the interelectrode gap at the same level. Maintaining maximum power is carried out by an automatic extreme electrode feed regulator based on readings from a power sensor. When the value of the forming part of the shaped electrode is reached during electrical discharge cutting, the approach of the electrode to the grinding wheel stops and the electrode is given a slow circular feed. With a circular feed of the shaped electrode, the gap between the grinding wheel and the electrode also stabilizes at a value at which the power released in it, and therefore the productivity, will be maximum. Maintaining maximum power is carried out by an automatic extreme electrode feed regulator based on readings from a power sensor. As the electrode rotates, new unworn sections of its surface come into effect sequentially, and the distorted profile of the grinding wheel is gradually corrected.

Profiling is performed in one revolution of the electrode, after which the depth of the profile obtained on the grinding wheel will be equal to the depth of the profile of the forming part of the profiling shaped electrode.

Thus, by stabilizing the gap between the grinding wheel and the profiling electrode with the help of an automatic extremal regulator of the electrode feed drive at a level at which the power allocated in this interval will be maximum, we obtain the maximum productivity and accuracy of the EDM profiling of grinding wheels on conductive bundles.

Example

The diamond grinding wheel was profiled according to a method where the electrode feed is controlled by an average power value. Diamond wheel parameters: ⌀250 × 15 mm, M1 bond, straight profile, grain size of the diamond powder 80/63 and the concentration of diamond grains in the diamond-containing layer 100%. The rotation frequency of the diamond wheel was 1 m / s. Interelectrode medium - industrial oil. The modes of the technological pulse generator were as follows.

Draft:

- frequency of rectangular technological pulses - 8 kHz;

- duty cycle of pulses - 3;

- pulse amplitude - 100 V;

- maximum current - 20 A.

Final transition:

- frequency of rectangular technological pulses - 20 kHz;

- duty cycle of pulses - 5;

- pulse amplitude - 100 V;

- maximum current - 14 A.

Profiling time was 6.5 hours. The magnitude of the interelectrode gap was maintained at the level of the average value of the power released in this gap. Power at the rough transition was 300 ... 350 watts, and at the finishing - 120 ... 150 watts. The processing productivity at the roughing transition was 47 μm ³ / min, and at the finishing - 8 μm ³ / min.

Profiled diamond grinding wheel according to the proposed method. Diamond wheel parameters: ⌀250 × 15 mm, M1 bond, straight profile, grain size of the diamond powder 80/63 and the concentration of diamond grains in the diamond-containing layer 100%. The rotation frequency of the diamond wheel was 1 m / s. Interelectrode medium - industrial oil. The modes of the technological pulse generator were as follows.

Draft:

- frequency of rectangular technological pulses - 8 kHz;

- duty cycle of pulses - 3;

- pulse amplitude - 100 V;

- maximum current - 20 A.

Final transition:

- frequency of rectangular technological pulses - 20 kHz;

- duty cycle of pulses - 5;

- pulse amplitude - 100 V;

- maximum current - 14 A.

Profiling time was 4.5 hours. At the same time, the value of the interelectrode gap was stabilized at the level of maximum power released in this gap with the help of an automatic extremal regulator for supplying the profiled shaped electrode. Power at the rough transition was 600 ... 670 W, and at the finish - 230 ... 250 W. The processing productivity at the roughing transition was 54 μm ³ / min, and at the finishing - 11 μm ³ / min.

Thus, the proposed method provides a technical effect and can be carried out using means known in the art.

Information sources

1. Livshits A.L. et al. Electropulse processing of metals. M., "Engineering", 1967, p.174-180.

2. A.S. 598024 (USSR), class G05B 19/02, 1973.

3. A.S. 891310 (USSR). A method for automatically controlling the supply of electrodes during electrical discharge machining and a device for its implementation / A.I. Aronov, Yu.I. Sychev, V.V. Lishenkov. - Publ. Bull. No. 47, 1981.

4. A.S. 1301594 (USSR). The method of extreme regulation of the process of electric discharge machining / A.B.Lakhmostov, V.V. Atroshchenko. - Publ. Bull. No. 13, 1987.

5. Chachin V.N., Dorofeev V.D. Profiling diamond grinding wheels. - Minsk: Science and technology, 1974. - 160 p.

6. Semenov. A.D., Nikitkin A.S., Avdeeva O.V. Algorithm for the extreme settlement of an automatic control system for an EDM process // Reliability and Quality'2010: Proceedings of the international symposium. - Penza, 2010.

7. Poduraev V.N. Technology of physicochemical processing methods. M .: Engineering, 1985.

Claims (1)

A method of electroerosive profiling of a grinding wheel on a conductive bond, including electrical discharge machining of a rotary grinding wheel with a shaped electrode, characterized in that the electrode is supplied until the electric power released in the interelectrode gap is increased to a maximum value, and then the magnitude of the interelectrode gap is maintained at the maximum power value with the help of an automatic extreme regulator of the electrode feed drive.

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