JP2011073091A - Processing machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a processing machine setting a diameter of a processed workpiece to be constant, even when processing a different diameter workpiece having a step. <P>SOLUTION: The processing machine 1 is equipped with: a self-excitation discharge power source device 2 for discharging by impressing voltage on a wire electrode 21; an NC device 3 for rotating the columnar workpiece around the axis and moving the wire electrode 21 along the axial direction of the workpiece; and a control device 4 for controlling a speed for moving the wire electrode 21, and processes the workpiece by discharging by the wire electrode 21. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a processing machine, and more particularly to a processing machine that processes a workpiece by discharging a wire electrode.

2. Description of the Related Art Conventionally, there is known a processing machine that includes a self-excited discharge power supply device that discharges a wire electrode by applying a voltage, and processes the workpiece by discharging the wire electrode (see, for example, Patent Document 1).
The electric discharge machine (machining machine) described in Patent Document 1 includes a self-excited discharge pulse power supply device (discharge power supply device) that applies a voltage to a discharge electrode (wire electrode) to cause discharge.

FIG. 4 is a schematic diagram showing a state in which a cylindrical workpiece W is being processed by the processing machine 10.
As shown in FIG. 4, the processing machine 10 rotates the columnar workpiece W around the axis (arrow A in FIG. 4) and along the axial direction of the workpiece W (arrow B in FIG. 4). A drive device (not shown) for moving the wire electrode 11 is provided. Then, as shown in FIGS. 4A to 4D, the driving device keeps the wire electrode 11 at a constant speed while maintaining a constant distance between the axis of the workpiece W and the wire electrode 11. Move with.

JP 2004-276174 A

However, when processing a workpiece W having different diameters with steps, there is a problem that the diameter of the workpiece W after processing is not constant.
Specifically, as shown in FIG. 4A, if a portion having a large diameter before processing is a large diameter portion W1 and a portion having a small diameter is a small diameter portion W2, the processing is performed. After that, as shown in FIG. 4D, the diameter of the large diameter portion W1 becomes smaller than the diameter of the small diameter portion W2.
This is because, in the processing machine 10 including the self-excited discharge power supply device, the frequency of discharge changes according to the distance between the workpiece W and the wire electrode 11 and the amount of removal of the workpiece W. Specifically, if the distance between the workpiece W and the wire electrode 11 is narrow, the frequency of discharge increases, and if it is wide, the frequency of discharge decreases. Moreover, if the removal amount of the workpiece W is large, the frequency of discharge increases, and if it is small, the frequency of discharge decreases.

Accordingly, since the frequency of discharge differs between when machining the large diameter portion W1 and when machining the small diameter portion W2, when machining a workpiece W having a different diameter with a step, the workpiece after machining is processed. The diameter of the workpiece W is not constant.
On the other hand, the interval between the workpiece W and the wire electrode 11 is adjusted by detecting the interval between the workpiece W and the wire electrode 11 and controlling the position of the wire electrode 11 according to the detected interval. Then, it is conceivable to make the diameter of the workpiece W after processing constant. However, there is a problem that it is difficult to accurately detect the distance between the workpiece W and the wire electrode 11.

Moreover, the wire electrode 11 is vibrated by the vaporization explosion of the working fluid by electric discharge or the scattering of the melted portion, as shown by two-dot chain lines in FIGS. Since the vibration of the wire electrode 11 corresponds to an increase in the diameter of the wire electrode 11, there is a problem that the problem that the diameter of the workpiece W after processing is not constant becomes even more remarkable.
On the other hand, it is conceivable to suppress the vibration of the wire electrode 11 by providing a guide or the like on the wire electrode 11. However, when the diameter of the wire electrode 11 is fine, there is a problem that it is difficult to provide a guide or the like.

  An object of the present invention is to provide a processing machine capable of making the diameter of a workpiece after processing constant even when processing a workpiece having different diameters with a step.

  The processing machine of the present invention rotates a columnar workpiece around an axis and moves a wire electrode along the axial direction of the workpiece, and applies a voltage to the wire electrode to discharge the wire electrode. A self-excited discharge power supply device, and a processing machine that processes the workpiece by discharging the wire electrode, and includes a control device that controls a speed at which the wire electrode is moved. .

According to such a configuration, since the processing machine includes the control device that controls the speed at which the wire electrode is moved, the speed at which the wire electrode is moved between when machining the large diameter portion and when machining the small diameter portion. Can be changed.
Specifically, if the speed at which the wire electrode is moved is increased, the amount of work to be removed per unit time increases and the frequency of discharge increases, so the speed of the wire electrode when machining a large diameter portion By increasing the speed of the wire electrode when processing a small diameter portion in comparison, the processing machine can process the workpiece after processing even when processing a workpiece having a different diameter with a step. The diameter can be constant.
Note that the positions of the large diameter portion and the small diameter portion in the workpiece may be set in advance by a user of the processing machine, or may be detected by a sensor or the like.

  In this invention, it is preferable that the said control apparatus controls the speed | rate which moves the said wire electrode according to the electric current which distribute | circulates the said wire electrode.

Here, since the frequency of discharge increases and decreases according to the interval between the workpiece and the wire electrode and the removal amount of the workpiece W, the current flowing through the wire electrode also increases and decreases accordingly.
According to the present invention, the control device can control the speed at which the wire electrode is moved according to the current flowing through the wire electrode, so the speed at which the wire electrode is automatically moved according to the shape of the workpiece. Can be controlled. Therefore, the processing machine can make the diameter of the workpiece after processing constant, even when processing a workpiece having different diameters with steps.

  In the present invention, the control device includes a current-voltage conversion unit that converts a current flowing through the wire electrode into a voltage, a voltage determination unit that determines a state of the voltage converted by the current-voltage conversion unit, and the voltage It is preferable to include a speed control unit that controls a speed at which the wire electrode is moved based on a result determined by the determination unit.

  According to such a configuration, since the control device includes the current-voltage conversion unit, the voltage determination unit, and the speed control unit, the speed at which the wire electrode is moved is controlled according to the current flowing through the wire electrode with a simple configuration. can do.

  In the present invention, it is preferable that the current-voltage conversion unit and the voltage determination unit are provided on the discharge power supply device side, and the speed control unit is provided on the drive device side.

Here, the current flowing through the wire electrode and the voltage converted by the current-voltage conversion unit are analog signals and are easily affected by noise, so the transmission path to the voltage determination unit is short. Is desirable. On the other hand, since the result determined by the voltage determination unit is a digital signal and is not easily affected by noise, the transmission path to be input to the speed control unit may be long.
Further, when a large-scale circuit is mounted on the discharge power supply device side, there is a problem that a large stray capacitance is generated in the discharge power supply device.
According to the present invention, since the current-voltage conversion unit and the voltage determination unit are provided on the discharge power supply device side, the analog signal transmission path can be shortened and the influence of noise can be suppressed. In addition, since the speed control unit is provided on the drive device side, it is possible to suppress the occurrence of a large stray capacitance in the discharge power supply device.

In this invention, it is preferable that the said control apparatus controls the speed which moves the said wire electrode in steps.
According to such a configuration, since the control device controls the speed at which the wire electrode is moved stepwise, an existing NC (Numerical Control) device that performs control based on numerical information can be employed as the drive device.

The block diagram which shows the processing machine which concerns on one Embodiment of this invention. The schematic diagram which shows the state which is processing the cylindrical workpiece in the processing machine in the said embodiment. The graph which shows the state of the signal in each part of the control apparatus in the said embodiment. The schematic diagram which shows the state which is processing the cylindrical workpiece with a processing machine.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing a processing machine 1 according to an embodiment of the present invention. FIG. 2 is a schematic diagram showing a state in which a cylindrical workpiece W is being processed by the processing machine 1.
As shown in FIGS. 1 and 2, the processing machine 1 rotates a self-excited discharge power supply device 2 that applies a voltage to the wire electrode 21 to discharge and a cylindrical workpiece W about its axis. (Arrow A in FIG. 2), NC device 3 that moves wire electrode 21 along the axial direction of workpiece W (arrow B in FIG. 2), and control device 4 that controls the speed at which wire electrode 21 is moved; The workpiece W is processed by discharging the wire electrode 21.

  The discharge power supply device 2 has the same configuration as the discharge pulse power supply device described in Patent Document 1 described above. As shown in FIG. 1, a wire electrode 21 and a diode 22 having a cathode connected to the wire electrode 21 A capacitor 23 having one end connected to the anode of the diode 22 and the other end grounded, and a FET (Field Effect Transistor) 24 having a gate connected to the cathode of the diode 22 and a source connected to the capacitor 23. With. Further, the discharge power supply device 2 has a positive electrode connected to the cathode of the diode 22 through the resistor 25, a negative electrode having a 5V power supply 26 connected to the anode, and a high voltage power supply 27 connected to the drain of the FET 24. With.

The discharge power supply device 2 charges the capacitor 23 with a current flowing from the high-voltage power supply 27 and applies the voltage of the capacitor 23 to the wire electrode 21 for discharge.
Specifically, since a reverse voltage is applied to the diode 22 from the power supply 26, the FET 24 is turned on so that a current flows between the drain and the source. When the FET 24 is turned on, the discharge power supply device 2 charges the capacitor 23 with the current flowing from the high voltage power supply 27. When the capacitor 23 is charged, a forward voltage is applied to the diode 22, and the voltage of the capacitor 23 is applied to the wire electrode 21. When a voltage is applied to the wire electrode 21 for discharge, a reverse voltage is again applied to the diode 22 by the power supply 26.
The discharge power supply device 2 repeatedly discharges the wire electrode 21 by repeating the above operation.

  The NC device 3 as a driving device rotates a workpiece W about an axis and moves a wire electrode 21 along the axial direction of the workpiece W, and a driving unit based on numerical information. Between the numerical control unit 31 for controlling the speed, the 4-bit rotary code switch 32 for setting the moving speed of the wire electrode 21 in the numerical control unit 31, the numerical control unit 31, and the rotary code switch 32 The switch 33 is provided. In the present embodiment, the numerical control unit 31 rotates the workpiece W at a constant speed.

The numerical control unit 31 controls in steps the speed at which the wire electrode 21 is moved in accordance with a 4-bit input signal. Specifically, the numerical control unit 31 associates the speed of the wire electrode 21 from 0 to 150% with respect to the numerical value from 0 to F in hexadecimal notation indicated by the input signal (hereinafter referred to as the numerical control unit 31). Set the input signal to the override value (0 to 150%). Here, the speed at which the wire electrode 21 is moved is 100% of a preset reference speed.
Therefore, for example, when a signal having an override value of 100% is input, the numerical controller 31 moves the wire electrode 21 at the reference speed. For example, when a signal having an override value of 150% is input, the numerical controller 31 moves the wire electrode 21 at a speed 1.5 times the reference speed.

The rotary code switch 32 switches and outputs a 4-bit signal. When the numerical control unit 31 and the rotary code switch 32 are connected via the switch 33, the numerical control unit 31 The wire electrode 21 is moved at a speed corresponding to the override value output from the cord switch 32.
The switch 33 switches between an override value output from the rotary code switch 32 and an override value input from the outside of the NC device 3. In FIG. 1, the switch 33 is switched so as to input an override value input from the outside of the NC device 3 to the numerical control unit 31.

  The control device 4 includes a current-voltage conversion unit 5 that converts a current flowing through the wire electrode 21 into a voltage, a voltage determination unit 6 that determines the state of the voltage converted by the current-voltage conversion unit 5, and a voltage determination unit 6 And a speed control unit 7 that controls the speed at which the wire electrode 21 is moved based on the result of the determination. Here, the current-voltage conversion unit 5 and the voltage determination unit 6 are provided on the discharge power supply device 2 side, and the speed control unit 7 is provided on the NC device 3 side.

The current-voltage converter 5 includes a resistor 51 having one end connected to the wire electrode 21 and the other end grounded, and converts the current flowing through the wire electrode 21 into a voltage by the resistor 51 by discharging.
The voltage determination unit 6 includes a smoothing circuit 61 that smoothes the voltage converted by the current-voltage conversion unit 5 and a comparator 62 that determines the state of the voltage smoothed by the smoothing circuit 61.
The comparator 62 outputs the result of determining the state of the voltage smoothed by the smoothing circuit 61 using three signal lines (super high, high, and low). Specifically, the three signal lines of ultra high, high, and low are used to output a signal corresponding to the magnitude of the voltage smoothed by the smoothing circuit 61.

The speed control unit 7 includes a photocoupler 71 for insulating a signal output from the comparator 62, a logic circuit 72 for controlling the speed at which the wire electrode 21 is moved based on the result determined by the comparator 62, And four rotary code switches 73 (731 to 734) arranged between the logic circuit 72 and the NC device 3.
Each of the rotary code switches 731 to 734 has the same configuration as the rotary code switch 32, the rotary code switch 731 outputs a signal with an override value of 0%, and the rotary code switch 732 outputs a signal with an override value of 50%. The rotary code switch 733 outputs a signal with an override value of 100%, and the rotary code switch 734 is switched so as to output a signal with an override value of 150%.

FIG. 3 is a graph showing signal states in each part of the control device 4. 3A is a graph showing the voltage converted by the current-voltage conversion unit 5, and FIG. 3B is a graph showing the voltage smoothed by the smoothing circuit 61. FIG. 3C is a graph showing a signal output from the comparator 62.
In FIG. 3, for the sake of explanation, it is assumed that the current flowing through the wire electrode 21 increases from the coordinate 0 to the coordinate S on the horizontal axis.

Hereinafter, the operation of the control device 4 will be described with reference to FIG.
As shown in FIGS. 3B and 3C, the comparator 62 determines the state of the voltage smoothed by the smoothing circuit 61 and outputs the determined result using the three signal lines. Further, the logic circuit 72 and each rotary code switch 73 control the speed at which the wire electrode 21 is moved based on the result determined by the comparator 62.

Specifically, the comparator 62 sets the low signal line to the H (High) level and the other signal lines to the L (High) level while the magnitude of the voltage smoothed by the smoothing circuit 61 is from 0 to V1. Low) level. In this case, the logic circuit 72 causes the rotary code switch 734 to output a signal having an override value of 150%.
The comparator 62 sets each signal line to the L level while the magnitude of the voltage smoothed by the smoothing circuit 61 is from V1 to V2. In this case, the logic circuit 72 causes the rotary code switch 733 to output a signal having an override value of 100%.

The comparator 62 sets the high signal line to the H level and the other signal lines to the L level while the magnitude of the voltage smoothed by the smoothing circuit 61 is from V2 to V3. In this case, the logic circuit 72 causes the rotary code switch 732 to output a signal having an override value of 50%.
When the magnitude of the voltage smoothed by the smoothing circuit 61 is larger than V3, the comparator 62 sets the high and ultrahigh signal lines to the H level and sets the other signal lines to the L level. In this case, the logic circuit 72 causes the rotary code switch 731 to output a signal having an override value of 0%.

Here, the current flowing through the wire electrode 21 increases / decreases depending on the frequency of discharge, and as shown in FIG. 2, the large-diameter portion W1, which is a portion having a large diameter before processing, is processed. Occasionally (arrow B in FIG. 2), since the interval between the workpiece W and the wire electrode 21 is narrow, the frequency of discharge increases, and the small-diameter portion W2, which has a small diameter before processing, is processed. Sometimes (arrow C in FIG. 2), since the distance between the workpiece W and the wire electrode 21 is wide, the frequency of discharge is reduced.
Therefore, according to the processing machine 1 as described above, the speed of the wire electrode 21 when processing the small diameter portion W2 can be increased as compared with the speed of the wire electrode 21 when processing the large diameter portion W1. .

The processing machine 1 according to the present embodiment has the following effects.
(1) Since the processing machine 1 includes the control device 4 that controls the speed at which the wire electrode 21 is moved, when processing the small diameter portion W2 compared to the speed of the wire electrode 21 when processing the large diameter portion W1. The speed of the wire electrode 21 can be increased. Therefore, even when processing a workpiece W having a different diameter with a step, the diameter of the workpiece W after processing can be made constant.
(2) Since the control device 4 can control the speed at which the wire electrode 21 is moved according to the current flowing through the wire electrode 21, it automatically moves the wire electrode 21 according to the shape of the workpiece W. The speed to be controlled can be controlled.
(3) Since the control device 4 includes the current-voltage conversion unit 5, the voltage determination unit 6, and the speed control unit 7, the speed at which the wire electrode 21 is moved according to the current flowing through the wire electrode 21 with a simple configuration. Can be controlled.

(4) Since the current-voltage conversion unit 5 and the voltage determination unit 6 are provided on the discharge power supply device 2 side, the analog signal transmission path can be shortened and the influence of noise can be suppressed. Moreover, since the speed control unit 7 is provided on the NC device 3 side, it is possible to suppress the occurrence of a large stray capacitance in the discharge power supply device 2.
(5) Since the control device 4 controls in steps the speed at which the wire electrode 21 is moved, the existing NC device 3 that is controlled by numerical information can be employed as the drive device.

[Modification of Embodiment]
It should be noted that the present invention is not limited to the above-described embodiment, and modifications, improvements, etc. within a scope that can achieve the object of the present invention are included in the present invention.
In the embodiment, the control device 4 controls the speed at which the wire electrode 21 is moved according to the current flowing through the wire electrode 21. On the other hand, for example, the control device may detect the interval between the workpiece and the wire electrode, and may control the speed at which the wire electrode is moved according to the detected interval. In short, the processing machine only needs to include a control device that controls the speed at which the wire electrode is moved.

In the said embodiment, the control apparatus 4 is provided with the current-voltage conversion part 5, the voltage determination part 6, and the speed control part 7, and the speed which moves the wire electrode 21 according to the electric current which distribute | circulates to the wire electrode 21 by simple structure. However, other configurations may be used. In short, the control device only needs to be able to control the speed at which the wire electrode is moved in accordance with the current flowing through the wire electrode.
In the embodiment, the current-voltage conversion unit 5 and the voltage determination unit 6 are provided on the discharge power supply device 2 side, and the speed control unit 7 is provided on the NC device 3 side. It may be provided at any position.
In the said embodiment, although the control apparatus 4 controlled the speed which moves the wire electrode 21 in steps, it does not need to control in steps.

  INDUSTRIAL APPLICABILITY The present invention can be used for a processing machine, and particularly, can be suitably used for a processing machine that processes a workpiece by discharging the wire electrode.

DESCRIPTION OF SYMBOLS 1 ... Processing machine 2 ... Discharge power supply device 3 ... NC apparatus (drive device)
DESCRIPTION OF SYMBOLS 4 ... Control apparatus 5 ... Current-voltage conversion part 6 ... Voltage determination part 7 ... Speed control part 21 ... Wire electrode

Claims (5)

A driving device for rotating a columnar workpiece around an axis and moving a wire electrode along an axial direction of the workpiece; and a self-excited discharge power supply device for applying a voltage to the wire electrode for discharging. A processing machine for processing the workpiece by discharging to the wire electrode,
A processing machine comprising a control device for controlling a speed at which the wire electrode is moved. The processing machine according to claim 1,
The said control apparatus controls the speed | rate which moves the said wire electrode according to the electric current which distribute | circulates the said wire electrode. The processing machine according to claim 2, wherein
The controller is
A current-voltage converter that converts the current flowing through the wire electrode into a voltage;
A voltage determination unit for determining a state of the voltage converted by the current-voltage conversion unit;
A processing machine comprising: a speed control unit that controls a speed at which the wire electrode is moved based on a result determined by the voltage determination unit. The processing machine according to claim 3,
The current-voltage conversion unit and the voltage determination unit are provided on the discharge power supply device side,
The processing machine, wherein the speed control unit is provided on the drive device side. In the processing machine according to any one of claims 1 to 4,
The processing apparatus controls the speed at which the wire electrode is moved stepwise.

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