JP3780649B2 - Electric discharge machine and electric discharge machining method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electric discharge machine such as a die-sinking electric discharge machine and a wire electric discharge machine, and an electric discharge machining method, and more particularly to an electric discharge machine that adjusts variation in machining characteristics of each machine and the machining characteristics of each machine. The present invention relates to an electric discharge machining method for performing machining.
[0002]
[Prior art]
The machining characteristics of an electrical discharge machine are not only the current peak value of the current that flows in the gap formed between the workpiece and the electrode (hereinafter simply referred to as “between electrodes”), but also the arc actually generated between the electrodes when a discharge occurs. It is also greatly influenced by the voltage (hereinafter simply referred to as “actual arc voltage”). Therefore, the machining characteristics of the electric discharge machine include a machining speed, a machined surface roughness, a current peak value, an actual arc voltage, and the like when machining is performed under specific machining conditions.
[0003]
In general, items to be set as machining conditions for an electrical discharge machine include arc voltage for controlling the actual arc voltage (hereinafter simply referred to as “set arc voltage”), no-load voltage between the electrodes, There are a peak current that flows, an ON time and an OFF time of discharge, a machining fluid flow rate, a machining fluid specific resistance, and the like. In the case of a wire electrical discharge machine, a wire feed speed, a wire tension, and the like are further added.
[0004]
When the same machining conditions are set with a plurality of electric discharge machines of the same model, it is naturally desirable that the same machining characteristics be obtained with all the electric discharge machines. However, in reality, the machining characteristics vary from machine to machine due to factors such as variations in feeder line length, wiring routing method, and the like between electric discharge machines of the same model.
When adjusting at the time of factory shipment, initial setting, and other maintenance, it is necessary to eliminate such variations in machining characteristics between EDM machines of the same model and set the same machining conditions. The same machining characteristics can be obtained with all electric discharge machines of the same model.
[0005]
In particular, even if there are causes for variations in feeder line length, wiring routing, etc., if there is no variation in processing characteristics for each machine, the same processing speed can be obtained when setting the same processing conditions. The obtained shape accuracy is not different for each machine, and the same one is obtained.
[0006]
FIG. 12 is a characteristic diagram showing the relationship between the actual arc voltage and the machining speed when a constant no-load voltage is applied between the electrodes.
In FIG. 12, when a constant no-load voltage is applied between the poles, when the three cases where the actual arc voltage is 42V, 46V, and 50V are compared, the machining speed increases as the actual arc voltage decreases. From this, it can be seen that the machining speed of the electric discharge machine can be changed by changing the actual arc voltage.
[0007]
As described above, the machining speed is generally changed by changing the actual arc voltage, which is one of the machining conditions. The setting of the machining conditions including the actual arc voltage is usually an operation performed by an operator, but experience and high technical skill are required to perform these operations.
[0008]
FIG. 13 is a processing speed-accuracy characteristic diagram showing a relationship between processing speed and processing accuracy when processing is performed using a wire electric discharge machine.
The value {(a + c) / 2} -b on the vertical axis is a parameter representing the processing accuracy (strain of the groove shape) of the wire processing groove. Here, a of the wire machining groove is a machining groove width on the upper surface of the plate-like workpiece, b is a machining groove width at the midpoint between the upper and lower surfaces of the plate-like workpiece, and c is a plate-like workpiece. The processing groove width on the lower surface of the object is shown. The horizontal axis indicates the machining speed. The machining speed increases (faster) as it goes to the right in the machining speed-accuracy characteristic diagram, and the machining speed decreases (slower) as it goes to the left.
FIG. 13 shows the results when only the first stage machining is performed and when the second stage machining is performed after the first stage machining.
As is apparent from FIG. 13, at the stage where only the first stage machining is performed, the difference in machining speed has little effect on the machining accuracy. However, at the stage where the second stage of machining is performed, it can be seen that the influence of the machining speed on the machining accuracy appears greatly.
[0009]
FIG. 14 is an actual arc voltage-set arc voltage characteristic diagram illustrating the relationship between the actual arc voltage and the set arc voltage when three electric discharge machines of the same model having different machining characteristics are used.
In FIG. 14, even if the set arc voltage is set to be the same, it can be seen that there is a difference in the actual arc voltage for each machine. That is, in an electric discharge machine with a normal machining speed, the actual arc voltage is set to 46 V when a specific set arc voltage is set. However, even if the same set arc voltage is set in the electric discharge machine with a low machining speed, the actual arc voltage is 44 V, and even in the electric discharge machine with a high machining speed, the same set arc voltage is set. The actual arc voltage is high, 50V.
[0010]
FIG. 15 is a characteristic diagram showing a difference in machining speed-set arc voltage characteristics of three electric discharge machines having the same model and different machining characteristics.
That is, for three EDM machines of the same model with different machining characteristics, the vertical axis represents the machining speed and the horizontal axis represents the set arc voltage to show the characteristics. This is an example in which three machines have different processing speeds. Regarding the relationship between the machining speeds in this case, the machining speed of each electric discharge machine is the speed of the machine 1> the speed of the machine 2> the speed of the machine 3 with respect to the same set arc voltage value.
[0011]
In an actual electric discharge machine, even if the set arc voltage for specifying the actual arc voltage is the same value, the actual arc voltage varies from machine to machine, so the shape accuracy varies from machine to machine. In order to solve this problem, when adjusting the arc voltage setting volume in the substrate of the control device of the electric discharge machine and changing the set arc voltage individually, the machining conditions except for the arc voltage are the same. In addition, the machining characteristics are adjusted for each machine so that the machining speed is within the specified range.
[0012]
FIG. 16 is a circuit diagram of a conventional electric discharge machine having a volume for setting an arc voltage.
In FIG. 16, 100 is an electrode, 101 is a workpiece, 102 is a DC power supply, 103 is a current limiting resistor, 104 is a switching element, and the switching element 104 is turned on between the electrodes 100 and the workpiece 101. By being controlled off, a pulse voltage and a pulse current are applied. The voltage between the electrodes is divided by the series circuit of the resistor 105a and the resistor 105b, and the divided voltage signal is inverted and amplified by the first inverting amplifier 108 via the input resistor 106. The gain of the first inverting amplifier 108 is the feedback resistor 107 / input resistor 106. The voltage signal corresponding to the inverted voltage between the electrodes is an actual arc voltage, which is the actual arc voltage V here.
[0013]
On the other hand, a set arc voltage is output as a digital value from a central processing unit (CPU) 109 such as a numerical controller. 110 is a DA converter for converting the set arc voltage given by the digital value into an analog voltage, and 111 is a second inverting amplifier for inverting and amplifying the analog set arc voltage. 112 is an input resistor of the inverting amplifier, 113 is also a feedback resistor of the inverting amplifier, and the feedback resistor 113 is a variable resistor so that the set arc voltage can be adjusted. The gain of the second inverting amplifier 111 is the feedback resistor 113 / input resistor 112. The actual arc voltage from the first inverting amplifier 108, the set arc voltage E from the second inverting amplifier 111 via the input resistor 117 and the input resistor 118, and the difference formed by the following differential input type subtraction circuit. Is provided to the dynamic amplifier 114. Incidentally, the output F corresponding to the interpolar movement position of the differential amplifier 114 is
F = (feedback resistor 116 / input resistor 115) × (EV)
It becomes.
[0014]
That is, the differential amplifier 114 amplifies the difference voltage between the actual arc voltage V and the set arc voltage E, and gives the output to the XY axis amplifier 119 that drives the XY axis motor of the next stage. Since the XY axis amplifier 119 is set so as to give a speed output proportional to the differential voltage to the X axis motor and the Y axis motor, the electrode 100 and the workpiece 101 are set so that the actual arc voltage V matches the set arc voltage E. The gap is controlled. Therefore, if the set arc voltage E is changed, the gap between the electrode 100 and the workpiece 101 is changed.
[0015]
Thus, conventionally, when the arc voltage setting volume of the feedback resistor 113 in the substrate is adjusted to change the set arc voltage E and the machining conditions excluding the set arc voltage E are the same, the machining speed is The machining characteristics were adjusted for each machine so as to be within the specified range.
However, in order to make this adjustment, it is necessary to know the meaning of the adjustment method and know-how for correct adjustment. For this reason, there has been a problem that adjustments cannot be made well by workers with insufficient experience and skills.
[0016]
[Problems to be solved by the invention]
Therefore, the present invention has been made to solve these problems, and facilitates adjustment of variation in machining characteristics of the same type of electric discharge machine at the time of product shipment or other adjustment work. A first problem is to provide an electric discharge machine and an electric discharge machining method that enable even an operator with a small amount of adjustment to perform an adjustment operation accurately.
In addition, the present invention accurately adjusts the variation in machining characteristics of electrical discharge machines in the same model at the time of product shipment or other adjustment work, based on the numerical values displayed on the screen even by an inexperienced operator. A second problem is to provide an electric discharge machine and an electric discharge machining method that enable easy adjustment work.
[0017]
[Means for Solving the Problems]
In the electric discharge machine according to the present invention, the machining control unit generates electric discharge between the electrode and the workpiece in accordance with the set output from the machining condition setting unit that sets the machining conditions. In an electric discharge machine for processing a workpiece, a processing section that processes the workpiece based on the processing conditions set in the processing condition setting section, and an actual situation when the processing section processes the workpiece A detecting unit that detects the machining information, and when machining the workpiece based on the machining conditions set in the machining condition setting unit, the machining conditions set in the machining condition setting unit and the detection unit The machine characteristics, which are the machine's machining characteristics, are obtained from the actual machining information obtained from the machine, and the machining characteristics calculation storage unit for storing the machine characteristics, and the machine characteristics and standards stored in the machining characteristic calculation storage unit. Standard machine consisting of machining information set in the machine And a correction unit that obtains a correction coefficient indicating the relationship of the machine characteristic with respect to the standard machine characteristic, and the machining condition set in the machining condition setting unit is corrected using the correction coefficient from the comparison unit. And a correction unit.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.
In addition, about each embodiment of this invention, the same code | symbol same as the code | symbol attached | subjected to the prior art example and each embodiment shall be attached | subjected to the same component common to a prior art example and each embodiment.
[0019]
Embodiment 1 FIG.
FIG. 1 is an example of three electric discharge machines with different machining characteristics of the same model. The machining conditions other than the set arc voltage are set the same, and the set arc voltage is adjusted so that the actual arc voltage is the same. FIG.
As shown in FIG. 1, before adjusting the set arc voltage E, each of the three electric discharge machines has a different actual arc voltage V for the same set arc voltage E value. Under the same machining condition setting, the three electric discharge machines have different machining characteristics. If the actual arc voltage 46V is made constant, the set arc voltage is set to 49V for a machine having a low machining speed, the set arc voltage is set to 46V for a machine having a normal machining speed, and the set arc voltage is set to 43. It is sufficient to set to 4V.
[0020]
That is, all the machining conditions other than the set arc voltage E are set to be the same, and only the value of the set arc voltage E is adjusted so that the actual arc voltage V becomes the same. Thus, by adjusting only the value of the set arc voltage E, when the machining conditions other than the set arc voltage E are set to be the same, the actual arc voltage V of each electric discharge machine can be made the same. . As a result, the machining speed of each electric discharge machine can be made the same.
In the illustration of FIG. 1, the case where the actual arc voltage V of three electric discharge machines is adjusted to 46V by setting the set arc voltage to 43.4V, 46V, and 49V is shown. Making the actual arc voltage V of the three electric discharge machines constant makes the actual machining speed G of the three electric discharge machines constant.
[0021]
FIG. 2 is an illustration of three electric discharge machines with different machining characteristics of the same model, and is an explanatory diagram in which the value of the actual machining speed is measured by changing the value of the set arc voltage E in six steps from 40V to 50V. It is. FIG. 3 is a characteristic diagram in which the values of FIG. 2 are graphed.
As shown in FIG. 2, for three EDM machines of the same model, the value of the set arc voltage E is changed in six stages from 40 V to 50 V, and the value of the actual machining speed G at that time is measured. In the machine 1 of the electric discharge machine, the machining speed is 5.4 to 2.8 mm / min, the machine 2 is 4.3 to 2.3 mm / min, and the machine 3 is 3.6. The processing speed is ˜2.1 mm / min.
Therefore, from the characteristic diagram obtained by graphing the result of FIG. 2 in FIG. 3, it can be seen how the value of the set arc voltage E should be adjusted in each electric discharge machine to obtain a desired machining speed.
[0022]
Based on this, the electric discharge machine is configured as follows in the present embodiment.
FIG. 4 is a functional block configuration diagram of the electric discharge machine according to Embodiment 1 of the present invention.
In FIG. 4, a machining control unit 1 has various machining conditions as described above including a machining speed, has a machining condition setting unit 1a for storing the machining conditions, and controls the entire electric discharge machine. Etc. It is comprised with the numerical control apparatus etc. which mount etc. The processing unit 2 processes the workpiece 101 based on the processing conditions specified by the processing control unit 1, and includes an X-axis servo mechanism, a Y-axis servo mechanism, a Z-axis servo mechanism set as necessary, It has a power supply for electric discharge machining, a switching element for determining machining energy, and the like. The detection unit 3 detects actual machining information such as the actual arc voltage V and the actual machining speed G. When the actual arc voltage V is detected, the voltage between the electrodes is detected or the machining speed is detected. To detect changes in the position of the encoder arranged in the X-axis servo mechanism, the encoder arranged in the Y-axis servo mechanism, and the encoder arranged in the Z-axis servo mechanism set as necessary The current position of the X-axis servo mechanism, the Y-axis servo mechanism, and the Z-axis servo mechanism set as necessary is obtained from the machining control unit 1.
When machining the workpiece 101 based on the interelectrode voltage set in the machining condition setting unit 1a, the machining characteristic calculation storage unit 4 uses the machining information obtained from the actually machined detection unit 3 to The inter-voltage and the machining characteristics of the workpiece 101 are calculated and stored. The comparison unit 5 compares the machining information stored in the machining characteristic calculation storage unit 4 with the machining conditions set in the condition setting unit 1a, and calculates a correction value by comparing the two. The correction unit 6 receives the signal from the comparison unit 5 and corrects the arc voltage between the electrodes input by the processing unit 2, that is, the set value of the set arc voltage E.
[0023]
FIG. 5 is a configuration diagram showing a specific configuration of the entire electric discharge machine according to Embodiment 1 of the present invention.
In FIG. 5, the machining control unit 1 controls the entire electric discharge machine, and sets arc voltage, no-load voltage and peak current between the electrodes, discharge on and off time, machining fluid flow rate, machining fluid resistivity, Further, in the case of a wire electric discharge machine, it has a machining condition setting unit 1a for inputting a wire feed speed, wire tension, and the like. The machining condition setting unit 1a includes a set arc voltage (E1, E2... En (which has the same meaning as the “E”)), a set machining speed (F1, F2... Fn, (the “F” and the like). The processing condition type including “)” is the address, the actually measured processing speed, that is, the actual processing speed (G1, G2... Gn, (same as the above “G”)), actual It has a memory to which machining information such as arc voltages (V1, V2... Vn, (same meaning as “V”)) is allocated. Further, a memory for storing a corresponding correction coefficient (k1, k2... Kn, (hereinafter, simply referred to as “k”)) at addresses of machining conditions such as the set arc voltage E and the set machining speed F. Also have.
[0024]
The processing unit 2 is configured to process the workpiece 101 based on the processing conditions specified by the processing control unit 1. Specifically, the XY axis amplifier 20, the X axis servo mechanism composed of the X axis motor 21 and the Y axis motor 22 driven by the XY axis amplifier 20, and the Y axis servo mechanism (the Z axis servo mechanism is not used). ), An electrode 100, a workpiece 101, a DC power source 102 that supplies discharge energy between the electrode 100 and the workpiece 101, a current limiting resistor 103 that limits a current output from the DC power source 102, and a discharge The switching element 104 that controls on / off of energy and the pulse corresponding to the on / off of the switching element 104 among the machining conditions from the machining control unit 1 and the pause signal are received, and the on / off of the switching element 104 is controlled. And a switching drive circuit 28. Here, the electrode 100, the workpiece 101, the DC power source 102, the current limiting resistor 103, the switching element 104, and the switching drive circuit 28 that controls on / off of the switching element 104 are provided between the electrode 100 and the workpiece 101. A power supply circuit for electric discharge machining is provided that applies a pulse voltage and current between the electrodes.
[0025]
The detection unit 3 that detects actual machining information converts the analog voltage of the amplifier 31 that detects the voltage between the electrode 100 and the workpiece 101 and the output of the amplifier 31 into a digital value, and performs machining control. It is comprised from the AD converter 32 output to the part 1, and this detector 3 is an example which detects an actual arc voltage. An X-axis encoder 23 and a Y-axis encoder 24 are disposed in the X-axis servo mechanism and the Y-axis servo mechanism (not using the Z-axis servo mechanism) including the X-axis motor 21 and the Y-axis motor 22. The actual machining speed G can be obtained by vector synthesis of both variables. In the present embodiment, an operation of obtaining both the actual arc voltage V and the actual machining speed G and correcting it by the average value of both will be described.
The machining characteristic calculation storage unit 4 calculates and stores machining characteristics based on the detection result of the detection unit 3, and similarly to the machining condition setting unit 1a, the relationship between the actual arc voltage V and the actual machining speed G at that time. Is stored as a machining condition.
The comparison unit 5 composed of a digital comparator compares the machining characteristic information in the machining condition setting unit 1a and the machining characteristic calculation storage unit 4, and if the two pieces of machining information do not match, according to the degree of the mismatched signal. The correction unit 6 is driven. The correction unit 6 applies the set arc voltage to obtain a predetermined machining speed from the machining characteristic information obtained in the machining characteristic calculation storage unit 4 with respect to the machining characteristic information of the set machining speed F and the set arc voltage E. Calculate the coefficient k and store it. The correction unit 6 for correcting the set arc voltage stores the result in the machining condition setting unit 1a of the machining control unit 1. Since correction to obtain a predetermined machining speed works, even if there is a variation among each machine, this corrects the variation in machining speed between EDM machines, and matches the machining characteristics of each EDM machine. Can do.
[0026]
Next, the correction method of the electric discharge machine of this Embodiment is demonstrated using FIG.4 and FIG.6.
6 is a flowchart for controlling the machining characteristics of the electric discharge machine according to the first embodiment of the present invention. FIG. 6 (a) is a flowchart for obtaining the machining characteristics. FIG. 6 (b) is a machining condition using the machining characteristics. It is a flowchart which corrects.
This routine is called at the initial stage of executing the main routine of the electric discharge machine according to the first embodiment of the present invention.
First, in step S1, machining conditions such as a set arc voltage E are set in the machining condition setting unit 1a of FIG. In step S2, machining is performed using the machining unit 2 under the set arc voltage and other machining conditions set in step S1, and the actual arc voltage V at that time is measured by the detection unit 3. At the same time, the actual machining speed G at that time is actually measured by the X-axis encoder 23 and the Y-axis encoder 24. In step S3, the set arc voltage E set in step S1, the actual arc voltage V obtained in step S2, and the actual machining speed G are stored in the memory in the machining characteristic calculation storage unit 4 as a set of machining information.
[0027]
Next, in step S4, it is determined whether or not all necessary data of the machining information has been collected. If not, the process returns to step S1, and the routine from step S1 to step S4 is repeatedly executed. When all the data of the machining information is completed, the process proceeds to step S5, and the characteristics of the electric discharge machine are calculated in the machining characteristic calculation storage unit 4 based on the machining information obtained in the routine from step S1 to step S4. In step S6, the obtained characteristic is stored in the memory in the machining characteristic calculation storage unit 4. Thus, the characteristic for every machine is calculated | required.
FIG. 7 is an explanatory diagram for controlling the machining characteristics of the electric discharge machine according to the first embodiment of the present invention. FIG. 7 (a) is a correction when calculated based on the actual machining speed, and FIG. 7 (b) is an actual arc. It is explanatory drawing explaining the correction | amendment at the time of calculating based on a voltage.
In the routine from step S1 to step S6, it is assumed that the characteristics of this machine are measured and the characteristics of this machine M and the characteristics of other machines are measured to obtain the standard machine characteristics Mm. It shall be remembered.
[0028]
The machining characteristics obtained in the routine of FIG. 6A are then used in the routine of FIG.
First, in step S11, the standard machine characteristic Mm of the electric discharge machine to be simultaneously controlled for machining selected by the machining condition setting unit 1a is read. This reading may be performed by connection between the processing control units 1 or may be input to the processing condition setting unit 1a via a person. In step S <b> 12, the set machining speed selected by the machining condition setting unit 1 a and the machining characteristics stored in the memory in the machining characteristic calculation storage unit 4 are compared by the comparison unit 5. In step S13, the comparison result is output to the correction unit 6. In step S <b> 14, the correction unit 6 corrects the signal output from the processing condition setting unit 1 a to the processing unit 2 based on the signal input from the comparison unit 5. In this embodiment, the correction value k = (kf + kv) is obtained by taking the average of the correction coefficient kf calculated based on the actual machining speed G described later and the correction coefficient kv calculated based on the actual arc voltage V. As shown in FIG. 2, the signal output from the machining condition setting unit 1a to the machining unit 2 is corrected.
[0029]
This operation will be described with reference to FIG.
FIG. 7 is an explanatory diagram for performing machining characteristic control of the electric discharge machine according to Embodiment 1 of the present invention in accordance with the flowchart of FIG.
FIG. 7A shows a case where correction is made with the characteristics of the set arc voltage E and the actual machining speed G. When the characteristics of the machine are measured in advance, the machine characteristics M are obtained. When the characteristics of other machines are measured, the standard machine characteristics Mm are obtained. In this case, the characteristics are matched with the standard machine characteristics Mm. Here, a specific actual machining speed FX common to the machine characteristic M and the standard machine characteristic Mm is obtained, and a set arc voltage EX of the machine characteristic M is obtained from the actual machining speed FX. Further, the set arc voltage EX ′ at the standard machine characteristic Mm is obtained from the actual machining speed FX. In step S12, the difference between the two is taken. If there is a difference between the two, the relationship between the actual machining speed FX, the set arc voltage EFX ', the set arc voltage EFX, and the correction coefficient kf is:
FX × (EFX '/ EFX) = FX × kf
If this machine characteristic M is operated with the machining characteristics of the standard machine characteristic Mm,
EFX '= kf ・ EFX
It becomes. In step S13, the correction coefficient k is calculated and stored in the correction unit 6. In step S12, the difference between the two is taken, and when there is no difference between them, the correction coefficient kf = 1 is set. In step S14, the signal output from the machining condition setting unit 1a to the machining unit 2 is corrected using the correction coefficient kv of the correction unit 6 and is output.
[0030]
FIG. 7B shows a case where correction is made with the characteristics of the set arc voltage E and the actual arc voltage V. When the characteristics of the machine are measured in advance, the machine characteristics M are obtained. When the characteristics of other machines are measured, the standard machine characteristics Mm are obtained. Here, it is assumed that the characteristics match the standard machine characteristics Mm. Here, the actual arc voltage VX common to the machine characteristic M and the standard machine characteristic Mm is obtained, and the set arc voltage EVX of the machine characteristic M is obtained from the actual arc voltage VX. Further, the set arc voltage EVX ′ in the standard machine characteristics Mm is obtained from the actual arc voltage VX. In step S12, when the difference between the two is present and there is a difference between them, the relationship between the actual arc voltage VX, the set arc voltage EVX ', the set arc voltage EVX, and the correction coefficient kv is
VX × (EVX ′ / EVX) = VX × kv
If this machine characteristic M is operated with the machining characteristics of the standard machine characteristic Mm,
EFX '= k · EVX
It becomes. Therefore, in step S13, the correction coefficient kv is calculated and stored in the correction unit 6. In step S12, the difference between the two is taken, and when there is no difference between them, the correction coefficient kv = 1 is set. In step S14, the signal output from the machining condition setting unit 1a to the machining unit 2 is corrected using the correction coefficient kv of the correction unit 6 and is output.
[0031]
The correction coefficient kf calculated based on the actual machining speed G and the correction coefficient kv calculated based on the actual arc voltage V have a correlation with each other. Values may be used, or both may be weighted and averaged for use. However, as in the present embodiment, the correction value k = (kf + kv) is obtained by averaging the correction coefficient kf calculated based on the actual machining speed G and the correction coefficient kv calculated based on the actual arc voltage V. In the case of correcting the signal output from the machining condition setting unit 1a to the machining unit 2 as / 2, it is possible to cope with a complicated change in the machining conditions of the workpiece 101.
[0032]
In the first embodiment, the case where a plurality of correction factors (k1, k2,... Kn) are used in the case where there are a plurality of combinations of the machining conditions and the actually measured values (actual machining speed G) corresponding thereto is described. When it is known in advance that the slopes of the characteristic curves of the machine 1, machine 2 and machine 3 shown in FIG. 3 are specified for each machine, one machining condition, the actual machining speed G corresponding to the machining condition, and the actual arc If the measured value such as the voltage V is known, the correction coefficient k of the electric discharge machine becomes constant. Also in this case, as in the first embodiment, when the set machining speed F suitable for the machining conditions is given, the correction is made based on the value of the set arc voltage E for obtaining the actual arc voltage V with respect to the set machining speed F. It can be set as the embodiment which correct | amends using the coefficient k.
In the present embodiment, if the actual machining speed G suitable for each machining condition is known for a plurality of machining conditions used for machining the workpiece 101, the value of the set arc voltage E that realizes the actual machining speed G is set. Since the value of the set arc voltage E can be calculated and automatically corrected, even a beginner can easily perform correction work, and easily correct variations in machining characteristics of the same model of electrical discharge machine, Even an inexperienced worker can make an accurate adjustment.
[0033]
Embodiment 2. FIG.
Next, there will be described an example in which the actual arc voltage V is corrected so that there are several types of processing conditions and the standard processing speed is suitable for each processing condition.
FIG. 8 is an explanatory diagram for controlling the machining characteristics of the electric discharge machine according to Embodiment 2 of the present invention. There are several kinds of machining conditions, and the actual arc voltage is set so that the standard machining speed is suitable for each machining condition. V is corrected.
(A) to (f) of FIG. 8 are obtained by taking the actual machining speed G on the vertical axis and the set arc voltage E on the horizontal axis, and depending on the plurality of machining conditions, In this example, the characteristics of the machining speed G and the set arc voltage E and the characteristics of the actual arc voltage V and the set arc voltage E change. When machining characteristics change due to changing machining conditions, it is desirable to correct the value of the set arc voltage E for each of a plurality of machining conditions. This can cope with the case of ultra-high precision machining.
[0034]
Embodiment 3 FIG.
FIG. 9 is a functional block configuration diagram of the electric discharge machine in the third embodiment.
FIG. 10 is an explanatory diagram showing machining information displayed on the screen of the electric discharge machine, and FIG. 11 is a characteristic diagram showing the relationship between the machining conditions of the electric discharge machine and the actual machining speed.
The difference between the configuration of the third embodiment and the first embodiment is that the processing characteristic calculation storage unit 4 is provided with a display function in the present embodiment. In particular, in this embodiment, Only differences from Embodiment 1 will be described.
In FIG. 9, when the machining characteristic calculation storage unit 4 processes a workpiece based on the set arc voltage set in the machining condition setting unit 1a, machining information obtained from the detection unit 3 that is actually machined. Is obtained by calculating and storing the set arc voltage E and the machining characteristics of the workpiece, and storing them. Information for correcting the set arc voltage E, the machining characteristics of the workpiece 101, the correction coefficient k, and the like. Is displayed.
For example, as shown in FIG. 10, the electric discharge machine of the present embodiment has a processing speed standard range and actual machining for each of the five machining conditions (E101 to E105) on the display screen of the display unit 40. The speed G, the value of the set arc voltage E before correction, the value of the set arc voltage E after correction, and the like are displayed.
Therefore, if any one of the five processing conditions (E101 to E105), the standard range of the processing speed, and the actual processing speed G are determined from the display screen of the display unit 40, the processing characteristic calculation storage unit 4 The machining conditions set in the machining condition setting unit 1a stored in the above may be changed from the value of the set arc voltage E before correction to the value of the set arc voltage E after correction according to the display screen of the display unit 40.
[0035]
The operator knows the values of the actual machining speed G and the set arc voltage E before correction, as well as the standard range of the machining speed for each machining condition, by performing necessary corrections while viewing the display screen of the screen display unit 40. It is possible to confirm from the screen of the screen display unit 40 how to correct the value of the set arc voltage E and confirm the corrected state by viewing the display again. it can.
[0036]
Further, as shown in FIG. 11, the relationship between the machining conditions and the machining speed F before and after the correction is such that the machining speed F having nonlinear characteristics with respect to a plurality of machining conditions before the correction is corrected after the correction. By correcting using a plurality of correction constants (k1, k2,... Kn) for a plurality of machining conditions, a linear characteristic of a specific correction constant k is obtained.
In this way, the rate of change in machining characteristics of the electric discharge machine after correction is constant, so even when machining at an intermediate machining speed other than the prescribed machining speed is desired, the machining conditions for the prescribed machining speed are interpolated. Therefore, it is possible to easily obtain the processing conditions of the uncollected area, and it is possible to realize processing corresponding to various requirements.
Further, as described in the above-described embodiment, when a plurality of electric discharge machines are operated simultaneously, one of them can be used as a standard machine having the standard machine characteristics Mm. Further, a specific standard machine characteristic Mm can be set for a user who uses a plurality of machines at the time of factory shipment.
[0037]
In the first to third embodiments, the case where both the actual machining speed G and the set arc voltage E and the actual arc voltage V and the set arc voltage E are used has been described. Is not limited to the one that uses both the actual machining speed G and the set arc voltage E and the actual arc voltage V and the set arc voltage E. The actual machining speed G and the actual arc voltage V are shown in FIG. Thus, the actual machining speed G and the set arc voltage E or only one of the actual arc voltage V and the set arc voltage E can be used, and the same effect can be obtained.
By the way, in the above embodiment, as shown in FIG. 5, in order to obtain the actual machining speed G, the X-axis servo mechanism including the X-axis motor 21 and the Y-axis motor 22, and the X-axis disposed in the Y-axis servo mechanism. The vector 23 in the X-axis direction and the Y-axis direction is combined from the encoder 23 and the Y-axis encoder 24 to calculate the movement distance. However, when the present invention is implemented, the X-axis motor 21 and the Y-axis motor 22 are calculated. The position information output from the machining control unit 1 can be directly used for the X-axis servo mechanism and the Y-axis servo mechanism.
[0038]
In the electric discharge machine of the above-described embodiment, the machining control unit 1 generates an electric discharge between the electrodes 100 and the workpiece 101 in accordance with a set output from the machining condition setting unit 1a that sets the machining conditions. In the electric discharge machine that generates and processes the workpiece 101, the processing unit 2 that processes the workpiece 101 based on the processing conditions set in the processing condition setting unit 1 a, and the processing unit 2 is the workpiece 101. The workpiece 101 is machined based on the machining conditions set in the machining condition setting unit 1a and the detection unit 3 that detects machining information such as the actual actual machining speed G and / or the actual arc voltage V when machining the workpiece. When processing, the processing characteristic of the workpiece 101 is obtained from the actual processing information obtained from the detection unit 3, the processing characteristic calculation storage unit 4 for storing the processing characteristic, and the processing conditions set in the processing condition setting unit 1a Recorded in machining characteristic calculation storage unit 4 Has been a comparison unit 5 for comparing the processing properties are those comprising a correction unit 6 for correcting the signal processing section 2 receives a signal from the comparator 5 is input.
Therefore, the machining control unit 1 processes the workpiece 101 by generating an electric discharge between the electrodes 100 and the workpiece 101, and processes the workpiece 101 under a plurality of machining conditions. The machining information is measured, the machining characteristics of the electric discharge machine are obtained from the machining conditions and the measured machining information in the machining conditions, the machining conditions are corrected using the obtained machining characteristics, and the workpiece 101 is machined. It is a thing. Therefore, even in the same type of electrical discharge machine, due to differences in feeder wire length and wiring in the machine, it is possible to eliminate the difference in machining characteristics that should be the same for each machine. The processing characteristics of the processing machine can be easily corrected.
Therefore, it is possible to easily adjust the variation in machining characteristics of the same type of electric discharge machine at the time of product shipment of the electric discharge machine or other adjustment work, and an adjustment work can be performed accurately even by an operator with little experience.
[0039]
In the electric discharge machine of the above embodiment, the machining control unit 1 is positioned between the electrode 100 and the workpiece 101 according to the set output from the machining condition setting unit 1a that sets the machining conditions. In the electric discharge machine that processes the workpiece 101 by generating electric discharge, the processing unit 2 that processes the workpiece 101 based on the processing conditions set in the processing condition setting unit 1a, and the processing unit 2 performs processing. Based on the detection unit 3 for detecting machining information such as the actual actual machining speed G and / or the actual arc voltage V when machining the workpiece 101, and the interelectrode voltage set in the machining condition setting unit 1a When processing 101, the actual processing information obtained from the detection unit 2 is displayed, the processing characteristics of the workpiece 101 are obtained, displayed, and the processing characteristics having the display unit 40 for storing it Operation storage unit 4 and machining conditions The comparison unit 5 that compares the machining conditions set in the fixing unit 1a with the machining characteristics stored in the machining characteristic calculation storage unit 4, and the correction that receives the signal from the comparison unit 5 and corrects the signal input by the machining unit 2 Part 6.
Therefore, the machining control unit 1 processes the workpiece 101 by generating an electric discharge between the electrodes 100 and the workpiece 101, and processes the workpiece 101 under a plurality of machining conditions. The machining information is measured, the machining characteristics of the electric discharge machine are obtained from the machining conditions and the measured machining information in the machining conditions, the obtained machining characteristics and the like are displayed using the display unit 40, and the displayed correction coefficient The machining conditions are corrected by k and the workpiece 101 is machined. The machining conditions were corrected using the obtained machining characteristics, and the workpiece 101 was machined. Therefore, even in the same type of electrical discharge machine, due to differences in feeder wire length and wiring in the machine, it is possible to eliminate the difference in machining characteristics that should be the same for each machine. The processing characteristics of the processing machine can be easily corrected.
Therefore, at the time of product shipment of EDM machines and other adjustment work, adjustment of variations in machining characteristics of EDM machines in the same model can be accurately adjusted based on the numerical values displayed on the screen even by inexperienced workers. Can be adjusted.
[0040]
Further, in the electric discharge machine of both the above embodiments, the machining control unit 1 is formed between the electrode 100 and the workpiece 101 in accordance with the set output from the machining condition setting unit 1a that sets the machining conditions. In the electric discharge machining method for machining the workpiece 101 by generating electric discharge, the machining obtained from the detection unit 3 when machining the workpiece 101 based on the machining conditions set in the machining condition setting unit 1a. An embodiment of an electric discharge machining method for obtaining machining characteristics of the workpiece 101 from the actual machining information therein and machining the workpiece 101 using the obtained machining characteristics may be used.
Therefore, the machining control unit 1 processes the machining characteristics of machining the workpiece 101 by generating an electric discharge between the electrodes 100 and the workpiece 101, and machining the workpiece 101 under a plurality of machining conditions. The machining information under the machining conditions is measured, the machining characteristics of the electric discharge machine are obtained from the machining conditions and the measured machining information under the machining conditions, the machining conditions are corrected using the obtained machining characteristics, and the workpiece 101 is It is intended to be processed. Therefore, even in the same type of electrical discharge machine, due to differences in feeder wire length and wiring in the machine, it is possible to eliminate the difference in machining characteristics that should be the same for each machine. The processing characteristics of the processing machine can be easily corrected. Therefore, it is possible to easily adjust the variation in machining characteristics of the same type of electric discharge machine at the time of product shipment of the electric discharge machine or other adjustment work, and an adjustment work can be performed accurately even by an operator with little experience.
[0041]
【The invention's effect】
As explained above, According to the present invention, The machining control unit actually generates electrical discharges to perform machining under multiple machining conditions, measures machining information under each machining condition, and determines machining characteristics of the electrical discharge machine from the machining conditions and measured machining information under the machining conditions. Since the machining conditions are corrected by using the obtained machining characteristics and the workpiece is machined, the machining characteristics that should originally be the same may be different from machine to machine. It is possible to easily correct the machining characteristics of the electric discharge machine. Further, not only the machining characteristics for each machine can be obtained, but also machining conditions for machining under desired machining conditions can be easily obtained.
Therefore, it is possible to easily adjust the variation in machining characteristics of the same type of electric discharge machine at the time of product shipment of the electric discharge machine or other adjustment work, and an adjustment work can be performed accurately even by an operator with little experience.
[0042]
Also, Not only the machining characteristics for each machine can be obtained using the display screen, but also machining conditions for machining under desired machining conditions can be easily obtained.
[0043]
The electric discharge machine according to claim 3 is: Claim 1 or Claim 2 In addition to the effects described in (1), the relationship between the set arc voltage and the actual arc voltage can be known for each machine, and the set arc voltage for realizing the desired actual arc voltage can be easily known for each machine. The machining characteristics can be easily corrected.
[0044]
The electric discharge machine according to claim 4 is: Claim 1 or Claim 2 In addition to the effects described above, the relationship between the set arc voltage and the actual machining speed can be known for each machine, and the set arc voltage for realizing a desired actual machining speed can be easily known.
[Brief description of the drawings]
FIG. 1 is an example of three electric discharge machines with different machining characteristics of the same model, and is a characteristic diagram when adjusting the value of a set arc voltage so that the actual arc voltage is the same.
FIG. 2 is an illustration of three electric discharge machines having different machining characteristics of the same model, and is an explanatory diagram in which machining speed values are measured when the set arc voltage value is changed in six stages.
FIG. 3 is a characteristic diagram in which the values of FIG. 2 are graphed.
FIG. 4 is a functional block configuration diagram of the electric discharge machine according to Embodiment 1 of the present invention.
FIG. 5 is a configuration diagram showing a specific configuration of the entire electric discharge machine according to the first embodiment of the present invention.
FIG. 6 is a flowchart for performing machining characteristic control of the electric discharge machine according to Embodiment 1 of the present invention.
FIG. 7 is an explanatory diagram for controlling machining characteristics of the electric discharge machine according to Embodiment 1 of the present invention.
FIG. 8 is a machining characteristic control for correcting the actual arc voltage so that there are several types of machining conditions of the electric discharge machine according to the second embodiment of the present invention and a standard machining speed suitable for each machining condition is obtained. It is explanatory drawing which performs.
FIG. 9 is a functional block configuration diagram of an electric discharge machine according to Embodiment 3 of the present invention.
FIG. 10 is an explanatory diagram showing machining information displayed on the screen of the electric discharge machine according to the third embodiment of the present invention.
FIG. 11 is a characteristic diagram showing the relationship between the machining conditions and the actual machining speed of the electric discharge machine according to the third embodiment of the present invention.
FIG. 12 is a characteristic diagram showing the relationship between the actual arc voltage and the machining speed when a constant no-load voltage is applied between the electrodes.
FIG. 13 is a machining speed-accuracy characteristic diagram showing the relationship between machining speed and machining accuracy when machining is performed using a wire electric discharge machine.
FIG. 14 is an actual arc voltage-set arc voltage characteristic diagram illustrating the relationship between the actual arc voltage and the set arc voltage of three electric discharge machines of the same model having different machining characteristics.
FIG. 15 is a characteristic diagram of machining speed-set arc voltage for three electric discharge machines having the same model and different machining characteristics.
FIG. 16 is a circuit diagram of a conventional electric discharge machine having a volume for setting an arc voltage.
[Explanation of symbols]
1 machining control unit, 1a machining condition setting unit, 2 machining unit, 3 detection unit, 4 machining characteristic calculation storage unit, 5 comparison unit, 6 correction unit.

Claims (5)

In an electric discharge machine that processes a workpiece by generating an electric discharge between the electrodes formed between the electrode and the workpiece in accordance with a set output from the machining condition setting unit that sets the machining conditions ,
A processing unit that processes the workpiece based on the processing conditions set in the processing condition setting unit;
A detection unit for detecting actual processing information when the processing unit processes the workpiece;
A standard machine characteristic consisting of machining information set in a standard machine is stored, and when the workpiece is machined based on the machining conditions set in the machining condition setting unit, the machining condition setting unit sets Further, from the actual machining information obtained from the machining conditions and the detection unit, a machine characteristic that is a machine characteristic of the machine is obtained, and a machining characteristic calculation storage unit that stores the machine characteristic,
A comparison unit that compares the machine characteristics stored in the machining characteristic calculation storage part with the standard machine characteristics, and obtains a correction coefficient indicating a relationship of the machine characteristics with respect to the standard machine characteristics;
A correction unit that stores a correction coefficient from the comparison unit and corrects a signal for processing the workpiece based on the processing condition set in the processing condition setting unit input by the processing unit;
An electric discharge machine characterized by comprising: In an electric discharge machine that processes a workpiece by generating an electric discharge between the electrodes formed between the electrode and the workpiece in accordance with a set output from the machining condition setting unit that sets the machining conditions ,
  A processing unit that processes the workpiece based on the processing conditions set in the processing condition setting unit;
  A detection unit for detecting actual processing information when the processing unit processes the workpiece;
  The standard machine characteristics including the machining information set in the standard machine are stored, and when the workpiece is machined based on the interelectrode voltage set in the machining condition setting unit, the standard machine characteristics and the detection are detected. Display the actual machining information obtained from the unit, obtain the machining characteristics of the workpiece, display it, and a machining characteristic calculation storage unit having a display unit for storing it,
  A comparison unit for comparing the machine characteristic, which is a machining characteristic of the machine stored in the machining characteristic calculation storage part, with the standard machine characteristic, and obtaining a correction coefficient indicating a relationship of the machine characteristic with respect to the standard machine characteristic; ,
  A correction unit that stores a correction coefficient from the comparison unit and corrects a signal for processing the workpiece based on the processing condition set in the processing condition setting unit input by the processing unit;
An electric discharge machine characterized by comprising: The electric discharge machine according to claim 1, wherein the detection unit is an actual arc voltage generated between the actual machining information to be detected. The electric discharge machine according to claim 1, wherein the detection unit is an actual machining speed at which actual machining information to be detected is a movement speed between electrodes. In an electric discharge machining method in which a machining control unit generates a discharge between electrodes formed between an electrode and a workpiece in accordance with a set output from a machining condition setting unit that sets machining conditions. ,
When machining the workpiece based on the machining conditions set in the machining condition setting unit, the machining conditions set in the machining condition setting unit and actual machining information when machining the workpiece The machining characteristics of the workpiece are obtained from the actual machining information during machining obtained from the detection unit for detecting the machining characteristics, and the obtained machining characteristics are compared with the standard machine characteristics including machining information set in the standard machine, An electric discharge machining method characterized in that a correction coefficient indicating a relationship between machine characteristics is obtained, a signal for machining the workpiece is corrected using the correction coefficient, and the workpiece is machined.

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