KR100579087B1 - Examination Unit of Wire Discharging Manu facturer - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wire discharge machine testing apparatus, and in particular, in the construction of a device for testing a discharge power control unit used for wire discharge machining, a discharge comprising a discharge developing voltage generator causing a discharge phenomenon and a resistance means corresponding to a workpiece. The present invention relates to a wire discharge machine testing apparatus, characterized in that the discharge control unit is tested without additional processing, so as to significantly reduce the power control unit test time of the discharge pore machine.

Wire, electric discharge machining, test equipment

Description

Wire Discharge Machine Tester {Examination Unit of Wire Discharging Manu facturer}             

1 is a view showing a general wire electric discharge machining apparatus.

2 is a view showing a discharge waveform of a processing gap.

Figure 3 is a view showing the configuration of a wire electric discharge machine testing apparatus in the present invention.

Explanation of symbols on the main parts of the drawings

50: discharge phenomenon voltage generator 60: discharge control unit

70: discharge power supply unit 90: discharge equivalent load part

100: tester

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wire discharge machine testing apparatus, and in particular, in the construction of a device for testing a discharge power control unit used for wire discharge machining, a discharge comprising a discharge developing voltage generator causing a discharge phenomenon and a resistance means corresponding to a workpiece. The present invention relates to a wire discharge machine testing apparatus, characterized in that the discharge control unit is tested without additional processing, so as to significantly reduce the power control unit test time of the discharge pore machine.

1 is a view showing a conventional wire electric discharge machining apparatus.

In the drawing, 1 is a wire electrode, 2 is a work piece, 3 is a work gap formed by the wire electrode 1 and the work piece 2, 4 is a table fixing the work piece 2, and 5a is a table 4. X-axis drive motor for driving in the X-axis direction, 5b is the Y-axis drive motor for driving the table 4 in the Y-axis direction, 6 is the axis drive control device for controlling the X, Y-axis drive motors (5a, 5b), 7 is a processing power supply for supplying a discharge current pulse to the processing gap 3, 8 is a processing power supply control circuit for controlling the switching operation of the processing power supply, 9 is a voltage detection circuit for detecting the processing voltage between the poles, and 10 is an NC An NC control circuit for inputting a program and outputting an axis drive command and machining condition parameter information, 11 is an average voltage detection circuit for detecting the average voltage between poles, and 12 is an NC program.

2 shows the discharge waveform of the processing gap in the conventional example, and 30a and 30b show the discharge current waveform.

Next, the operation will be described.

In accordance with the machining electrical condition parameters preset in the NC program 12 or the NC controller 10, the controller 10 outputs parameter information to the machining power supply control circuit 8.

The processing power supply control circuit 8 outputs a drive signal having a predetermined current peak, pulse width, and rest time to the processing power supply 7 in accordance with this parameter.

The processing power source 7 is driven under the control of its drive signal, and a predetermined current pulse is supplied to the processing gap 3 to perform processing.

The voltage detection circuit 9 detects the occurrence of the discharge in accordance with the voltage waveform in the processing gap 3 and, in addition, the delay time from when the voltage is applied to the processing gap 3 until the discharge occurs (hereinafter, ' No-load time) is measured and the measurement result is output to the processing power supply control circuit 8.

The processing power supply control circuit 8 judges that the state between the poles is close to an abnormal state such as a short circuit or an arc when the no-load time from the application of voltage to the occurrence of the discharge is short (immediate discharge) as shown in 30a of FIG. Supply a current waveform (hereinafter, referred to as 'small pulse') having a small pulse width and low peak, such as 31a.

On the contrary, when the no-load time is relatively long, such as 30b, it is determined as normal discharge, and a current waveform having a large pulse width and a high peak (hereinafter, referred to as 'large pulse') as 31b is supplied.

Triangular waveforms with different peaks are often used especially for wire discharge machining.

By controlling the current waveform (peak value, etc.) in accordance with the discharge state, disconnection of the wire electrode can be prevented, and the processing speed is greatly improved.

The average voltage detection circuit 11 detects an average voltage during processing, and according to the average voltage, the NC control device 10 outputs a drive command to the axis drive control device 6, and the axis drive control device 6 Drives the X-axis motor 5a and the Y-axis motor 5b, and increases the electrode feed speed (axis drive speed) when the detected average voltage is greater than or equal to the predetermined value, When the average voltage is less than or equal to the predetermined value, control is performed by the NC control device 10 and the shaft drive control device 6 to reduce the electrode feed speed (axis feed speed).

On the other hand, in testing whether the processing power control circuit (discharge control unit) for processing of the wire discharge pore made as described above is operating properly, conventionally, after installing the workpiece and the table as described above, a pulse is input to the discharge power supply unit and shown here. The measurement data was analyzed to test whether the discharge control unit was operating properly.

Therefore, it is very inconvenient to have a lot of time to test and to have a processing equipment every time, such as having to equip the processing equipment and test the discharge control unit in the event of a problem, and then re-install the processing equipment after testing.

In order to solve the above problems, the present invention does not test the discharge processing power control unit in the state where the processing equipment is actually provided, but includes a discharge equivalent load unit and a device for generating a discharge developing voltage. The purpose of the test is to reduce the time and effort used for testing the discharge control unit by connecting the control unit to the discharge control unit and checking the response to the input discharge voltage to test the discharge control unit.

As a means for achieving the above object,                         

The present invention relates to a discharge phenomenon voltage generator which generates a high-voltage pulse and a low-voltage pulse at regular intervals in a stepwise manner;

A discharge controller for outputting a primary voltage pulse required for starting a discharge when a high voltage pulse is applied according to a discharge voltage pulse input through the discharge detector, and outputting a primary voltage pulse for actual discharge when a low voltage pulse is applied;

A discharge power supply unit outputting a voltage for preparing for discharge machining when a primary voltage pulse is input according to a pulse provided by the discharge controller, and outputting a high voltage necessary for actual discharge when a secondary voltage pulse is input;

And a tester device configured to input the flow of power from the discharge power supply unit and the discharge equivalent load line in parallel to display the power applied from the discharge power supply to the discharge equivalent load, and determine whether there is an abnormality in the discharge control unit and the discharge power supply unit. It is characteristic.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

3 is a block diagram of the present invention, as shown

A discharge phenomenon voltage generator 50 which generates a high-voltage pulse and a low-voltage pulse at a predetermined interval in a stepwise manner;

The discharge control unit 60 outputs the primary voltage pulse required for the start of discharge when the high voltage pulse is applied according to the discharge voltage pulse input through the discharge detector, and outputs the primary voltage pulse required for the actual discharge when the low voltage pulse is applied. ;

A discharge power supply unit 70 outputting a voltage for preparation for discharging processing when a primary voltage pulse is input according to a pulse provided by the discharge control unit 60 and outputting a high voltage required for actual discharge when a secondary voltage pulse is input;

The flow of power is input in parallel from the discharge power supply unit 70 and the discharge equivalent load line 80 to display the power applied from the discharge power supply to the discharge equivalent load 90, and the discharge control unit 60 and the discharge power supply unit ( It comprises a tester device 100 to determine the abnormality of 70).

According to the present invention configured as described above, the discharge developing voltage generator 50 generates a stepped pulse and transmits the stepped pulse to the discharge controller 60 through the discharge detector.

Then, the discharge control unit 60 applies the primary voltage pulse according to the high voltage pulse and the secondary voltage pulse according to the low voltage pulse to the discharge power supply unit 70 according to the voltage pulse transmitted from the discharge developing voltage generator 50. .

Then, when the primary voltage pulse is input, the discharge power supply unit 70 outputs a low voltage for starting discharge to the discharge equivalent load, and when the secondary voltage pulse is input, the discharge voltage outputs a high voltage for discharge processing to the discharge equivalent load. .

In the present invention, the tester 100 including the current transformer may be connected in parallel between the discharge power supply unit 70 and the discharge equivalent load unit 90 to determine whether the voltage applied from the discharge power supply is suitable for discharge processing.

That is, in the related art, when the low voltage of the primary voltage pulse is output to the workpiece and the discharge point is detected and output to the discharge control circuit, the high voltage of the secondary voltage pulse is applied to the workpiece. In the present invention, a system for measuring the degree of actual discharge is used. However, in the present invention, a pulse generated artificially by the discharge developing voltage generator is applied to the discharge power through the discharge control unit to detect a waveform output from the discharge power supply. It is to know whether the output value corresponding to the output pulse comes out.

Therefore, the conventional apparatus consumes a lot of time and effort since the discharge control unit and the discharge power source must be tested by directly applying the discharge power to the actual workpiece, but using the present invention, the discharge phenomenon can be artificially produced by discharging the voltage generator. The discharge control unit and the discharge power unit can be easily tested by displaying the power generated by outputting primary and secondary pulses to the discharge equivalent load unit through the discharge power unit through the discharge power unit.

As described above, the present invention does not test the electric discharge machining power control unit in the state where the processing equipment is actually equipped, but includes a discharge equivalent load unit and a device for generating a discharge developing voltage, and connects the device to the electric discharge control unit. By checking the response to the input discharge voltage to test the discharge control unit, it provides the effect of reducing the time and effort used in the discharge control unit test.

Claims (1)

A discharge phenomenon voltage generator 50 which generates a high-voltage pulse and a low-voltage pulse at a predetermined interval in a stepwise manner; The discharge control unit 60 outputs the primary voltage pulse required for the start of discharge when the high voltage pulse is applied according to the discharge voltage pulse input through the discharge detector, and outputs the primary voltage pulse required for the actual discharge when the low voltage pulse is applied. ; A discharge power supply unit 70 outputting a voltage for preparation for discharging processing when a primary voltage pulse is input according to a pulse provided by the discharge control unit 60 and outputting a high voltage required for actual discharge when a secondary voltage pulse is input; The flow of power is input in parallel from the discharge power supply unit 70 and the discharge equivalent load line 80 to display the power applied from the discharge power supply to the discharge equivalent load unit 90, and the discharge control unit 60 and the discharge power supply unit And a tester device (100) configured to determine whether or not there is an abnormality of (70).

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