JP5124186B2 - Power supply device and power supply device for arc machining - Google Patents

Description

  The present invention relates to a power supply device having an inverter circuit for converting an input AC power source such as a commercial power source into a DC voltage and converting the DC voltage into a predetermined AC voltage, and an arc machining power source device using the power source device It is.

  For example, as disclosed in Patent Document 1, a power supply device used for an arc machine or the like is a DC converter that converts a commercial power supply (three-phase AC power supply) into a DC voltage that is rectified by a rectifier circuit and smoothed by a smoothing capacitor. A circuit and an inverter circuit for AC conversion configured by a bridge circuit of a plurality of switching elements (first to fourth switching elements). In the inverter circuit, a predetermined combination of switching elements are controlled to be turned on and off in synchronization with each other, and a DC voltage from the DC conversion circuit is converted into a predetermined high-frequency AC voltage. Then, a predetermined high-frequency AC voltage from the inverter circuit is further converted into a machining DC voltage suitable for arc machining such as arc welding or arc cutting.

  By the way, since the voltage value of the commercial power source to be input has a 200V system (200 to 240V) region and a high voltage 400V system (380 to 480V) region in the world, in the arc machining power supply device, Conventionally, the specification according to the voltage value of both has been individually manufactured.

  For example, the power supply device shown in FIG. 4 and the like of Patent Document 1 has an input AC power supply of 200V specification, and includes one smoothing capacitor. In addition, this power supply device is a power supply device that performs soft switching control, and an auxiliary capacitor is connected between power supply lines after the smoothing capacitor, and an auxiliary switching element is disposed on one power supply line between both capacitors. Has been. The auxiliary switching element is turned off a predetermined time before the switching element of the inverter circuit that is on / off controlled at the time of AC conversion is turned off, and the supply of the DC voltage to the inverter circuit is stopped. In other words, soft switching control is performed to reduce the switching loss by turning off the switching element of the inverter circuit after a predetermined time has elapsed when the discharge of the auxiliary capacitor is completed and the applied voltage of the inverter circuit becomes substantially zero voltage. Yes.

  On the other hand, the power supply apparatus shown in FIG. 11 and the like of Patent Document 1 has an input AC power supply of 400V specification, and specifically, two smoothing capacitors having the same capacity as the 200V specification smoothing capacitor described above. The first and second smoothing capacitors are connected in series between the power supply lines on the output side of the rectifier circuit. On each power supply line subsequent to the first and second smoothing capacitors, fifth and sixth switching elements are disposed as auxiliary switching elements, and between the subsequent stages of the fifth and sixth switching elements and the auxiliary capacitor. Between the power lines between them, seventh and eighth switching elements are connected in series as auxiliary switching elements. The connection point between the seventh and eighth switching elements and the connection point between the first and second smoothing capacitors are short-circuited to each other.

  Then, the combination of the fifth switching element on one power line side and the eighth switching element on the other power line side and the combination of the sixth switching element and the seventh switching element on the opposite side are alternated. On / off control is performed so that the voltage across one of the first and second smoothing capacitors is applied to the inverter circuit. That is, since the voltage between the terminals of one of the first and second smoothing capacitors is equivalent to the voltage between the terminals of the above-described 200 V specification smoothing capacitor, the inverter circuit and the subsequent circuits are configured in common with those of the 200 V specification. Yes.

Also in this 400 V specification power supply device, the fifth and sixth switching elements are turned off by a predetermined time before the switching elements of the inverter circuit that is on / off controlled at the time of AC conversion are turned off. Control is possible.
JP 2003-31408 A

  However, as described above, it is complicated that the 200V specification and the 400V specification exist individually. For this reason, there is a demand for one power supply device to cope with two voltage values of the 200V system and the 400V system.

  Therefore, based on a power supply device of 400V specification, the operation is performed as described above in the case of a 400V system input, while in the case of a 200V system input, the seventh and eighth switching elements may be always turned off. .

  However, in this correspondence, when the seventh and eighth switching elements are always turned off, the voltage between the first and second smoothing capacitors is connected to the auxiliary capacitor via a diode reversely connected to the seventh and eighth switching elements. Is constantly applied to the inverter circuit while being charged, and the switching element of the inverter circuit cannot be turned off at substantially zero voltage. That is, at the time of this 200V system input, even if soft switching control is performed, there is a problem that the effect of the control of reducing the switching loss cannot be obtained.

  As another countermeasure, a step-down DC chopper circuit composed of many electric circuit components including coils and switching elements is added to the 200V specification power supply device, and in the case of 400V input, the DC voltage is applied to the chopper circuit. Although it is conceivable to step down the voltage to a voltage equivalent to that of the 200V system, adding such a step-down DC chopper circuit is not a good idea because it causes a large-scale power supply and a large cost increase. .

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a power supply apparatus and an arc machining power supply apparatus that can cope with two different input voltages with a simple configuration. It is in.

In order to solve the above-mentioned problem, the invention according to claim 1 includes a rectifier circuit and first and second smoothing capacitors connected in series between a pair of power supply lines on the output side thereof, and an input AC power supply is provided. It is composed of a DC conversion circuit that converts to a rectified and smoothed DC voltage and a bridge circuit that uses the first to fourth switching elements, and the first to fourth switching elements are driven on and off for each predetermined set. Between the inverter circuit that converts the DC voltage supplied via the power lines into a predetermined AC voltage, and the auxiliary capacitor connected between the DC converter circuit and the power lines before the inverter circuit , Rutotomoni fifth and sixth switching elements are arranged on each power supply line seventh and eighth switching elements are connected in series between the power supply lines, the seventh and eighth switching of Each diode will be reverse connected to the element, while at the time of input of the input AC power supply of the first voltage value to supply a voltage across said first and second smoothing capacitor to the inverter circuit, the first voltage value When the input AC power supply has a second voltage value that is twice as large as the input voltage, the voltage between the terminals of the first or second smoothing capacitor is alternately switched on and off for each predetermined set of the fifth to eighth switching elements. Software that supplies to the inverter circuit, and further that predetermined elements of the fifth to eighth switching elements are turned off prior to turning off the first to fourth switching elements to stop voltage supply to the inverter circuit side. and an auxiliary switching circuit switching control is performed, the first said when the input AC power supply input voltage value of the seventh and eighth Wei switching element to the off state of the The power supply device which is adapted to the connection point between the first and second smoothing capacitor, between the connection point between the switching elements of the seventh and eighth, the conduction and interruption between each other First switching means for switching is provided , and the first switching means is configured to be capable of controlling switching between conduction and cutoff, and is based on an input of the input AC power source of the second voltage value. Switching control means for switching the first switching means to conduction and controlling the first switching means to be switched off based on an input of the input AC power supply of the first voltage value. The gist.

  In the present invention, there is a mutual connection between the connection point between the first and second smoothing capacitors and the connection point between the seventh and eighth switching elements connected in series between the power supply lines in the auxiliary switching circuit. There is provided a first switching means for switching between ON and OFF. When the high voltage second voltage value AC voltage is input, the first switching means is turned on, so that the voltage between the terminals of the first or second smoothing capacitor can be alternately supplied to the inverter circuit. . In addition, when the alternating voltage of the first voltage value is input, the first switching unit is cut off, so that the voltage at the connection point between the first and second smoothing capacitors is provided in the seventh and eighth switching elements. Supply to the inverter circuit side through the reversely connected diode is reliably prevented, and the effect of the soft switching control can be reliably obtained.

  In the present invention, the first switching means is switched to conduction based on the AC voltage input of the second voltage value under the control of the switching control means, and the first switching is performed based on the AC voltage input of the first voltage value. The means is switched to shut off. In other words, switching of the switching means is automatically performed under the control of the switching control means, and no human operation is required.

The invention described in claim 2 has a first and second smoothing capacitors connected in series between a rectifier circuit and a pair of power supply lines on the output side thereof, and a DC voltage obtained by rectifying and smoothing an input AC power supply. A DC conversion circuit for conversion and a bridge circuit using the first to fourth switching elements are provided, and the first to fourth switching elements are driven on and off for each predetermined set and supplied via the power supply lines. Switching between the inverter circuit for converting the DC voltage into a predetermined AC voltage, and the auxiliary capacitor connected between the DC converter circuit and the power supply lines in the previous stage of the inverter circuit. An element is disposed on each of the power supply lines, and seventh and eighth switching elements are connected in series between the power supply lines, and a diode is connected to each of the seventh and eighth switching elements. The two terminals of the first and second smoothing capacitors are supplied to the inverter circuit at the time of input of the input AC power source having the first voltage value by being reversely connected, while the second voltage that is twice the first voltage value is supplied. When the input AC power supply of the voltage value is input, the ON / OFF drive is performed for each predetermined set of the fifth to eighth switching elements, and the voltage between the terminals of the first or second smoothing capacitor is alternately supplied to the inverter circuit. In addition, soft switching control is performed in which predetermined elements of the fifth to eighth switching elements are turned off before the first to fourth switching elements are turned off to stop voltage supply to the inverter circuit side. A power supply device comprising an auxiliary switching circuit, wherein a phase between a connection point between the first and second smoothing capacitors and a connection point between the seventh and eighth switching elements is provided. During provided with first switching means for switching to a conducting and blocking, said inverter circuit, together with the first and third switching elements are connected in series between the power supply lines, the second and fourth A switching element is configured to be connected in series between the power supply lines, and either a connection point between the first and third switching elements or a connection point between the second and fourth switching elements. , A second switching means for switching between connection and disconnection between the seventh and eighth switching elements is provided, and the first and second switching means are connected and disconnected. Switching is configured to be controllable, and based on the input of the input AC power supply of the second voltage value, the first switching means is switched on, the second switching means is switched to shut off, Said first power Switching control means for controlling the first switching means to be cut off and the second switching means to be switched on based on an input of the input AC power supply of pressure value, and the first voltage is controlled by the switching control means. When the first switching unit is cut off and the second switching unit is switched to conduction based on the input of the input AC power supply of the value, the seventh and eighth switching elements are switched to the second switching unit. same off control the switching elements of the inverter circuit to be parallel by conductive means is made to that you operate as part of the inverter circuit and its gist.
In the present invention, there is a mutual connection between the connection point between the first and second smoothing capacitors and the connection point between the seventh and eighth switching elements connected in series between the power supply lines in the auxiliary switching circuit. There is provided a first switching means for switching between ON and OFF. When the high voltage second voltage value AC voltage is input, the first switching means is turned on, so that the voltage between the terminals of the first or second smoothing capacitor can be alternately supplied to the inverter circuit. . In addition, when the alternating voltage of the first voltage value is input, the first switching unit is cut off, so that the voltage at the connection point between the first and second smoothing capacitors is provided in the seventh and eighth switching elements. Supply to the inverter circuit side through the reversely connected diode is reliably prevented, and the effect of the soft switching control can be reliably obtained.

  In the present invention, between either the connection point between the first and third switching elements or the connection point between the second and fourth switching elements and the connection point between the seventh and eighth switching elements. Second switching means for switching between and on / off is provided. Then, when the first switching means is turned on (when the second voltage value AC voltage is input), the second switching means is cut off, so that the same operation as that when the second voltage value AC voltage is input is performed. The second switching means is turned on when the first switching means is shut off (when the first voltage value of the alternating voltage is input), so that the seventh and eighth switching elements are the second The same ON / OFF control as that of the switching elements of the inverter circuit arranged in parallel is performed by the conduction of the switching means, and operates as part of the inverter circuit. Thereby, the current flowing through the switching element of the inverter circuit in parallel with the seventh and eighth switching elements can be divided into two, and the generation of heat in the switching element is reduced.

  In the present invention, the first switching means is switched on and the second switching means is switched off based on the AC voltage input of the second voltage value under the control of the switching control means, and the AC voltage of the first voltage value is switched. Based on the input, the first switching means is switched off and the second switching means is switched on. In other words, switching of the switching means is automatically performed under the control of the switching control means, and no human operation is required.

The gist of the invention described in claim 3 is that, in the power supply device according to claim 1 or 2 , the switching means is constituted by one switch.
In the present invention, since the switching means is composed of one switch, the circuit configuration of the power supply apparatus is not complicated.

Invention of Claim 4 uses the power supply device of any one of Claims 1-3 , and is configured to generate an arc machining voltage for performing arc machining of a workpiece. Power supply device.

In the present invention, since the power supply device according to any one of claims 1 to 3 is used, the power supply device for arc machining that can obtain the effects of the above-mentioned claims can be provided.

  According to the present invention, it is possible to provide a power supply device and an arc machining power supply device that can cope with two different input voltages by adding a simple configuration such as a switching means that simply opens and closes an electric circuit.

(First embodiment)
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.
FIG. 1 shows an arc machine 10 provided with a power supply device 11 for arc machining of this embodiment. The arc machine 10 supplies the machining DC voltage output from the power supply device 11 to the torch TH, and generates an arc from the torch TH toward the workpiece M, thereby causing the workpiece M to be processed. It is a device that performs arc processing such as arc welding and arc cutting. An arc machining power supply device 11 used for such an arc machine 10 includes a DC conversion circuit 12 that converts an input commercial power supply (three-phase AC voltage) into a DC voltage, and converts the DC voltage into a predetermined high-frequency AC voltage. An inverter circuit 13 for conversion is provided, and a high-frequency AC voltage from the inverter circuit 13 is further converted into a processing DC voltage.

  The DC conversion circuit 12 is configured by a bridge circuit using six diodes D1 to D6, and performs primary wave rectification circuit DR1 for full-wave rectification of a three-phase input AC power supply, and first and second rectifier circuits on the output side of the rectification circuit DR1. The first and second smoothing capacitors C1 and C2 connected in series between the second power supply lines L1 and L2 and smoothing the output voltage of the rectifier circuit DR1 generate a DC voltage from the input AC power supply. . The first and second smoothing capacitors C1 and C2 have the same capacity. Further, in the DC conversion circuit 12, a voltage detection circuit IV for detecting a DC voltage is connected between the power supply lines L1 and L2. The voltage detection circuit IV outputs the detected DC voltage as a voltage detection signal Iv to an output control circuit SC, which will be described later, and is used for determining whether the AC power input to the power supply device 11 is a 200V system or a 400V system.

  The inverter circuit 13 is connected to the power supply lines L1 and L2, and is configured by a bridge circuit using first to fourth switching elements TR1 to TR4 made of four IGBTs. The first and third switching elements TR1 and TR3 are connected in series between the power supply lines L1 and L2, and the second and fourth switching elements TR2 and TR4 are connected in series between the power supply lines L1 and L2. Between the emitter of the switching element TR1 and the collector of the switching element TR3 is one end of the primary coil of the transformer INT, and between the emitter of the switching element TR2 and the collector of the switching element TR4 is the other end of the primary coil. It is connected. The diodes D11 to D14 are reversely connected to the first to fourth switching elements TR1 to TR4, respectively. The set of the first and fourth switching elements TR1 and TR4 and the set of the second and third switching elements TR2 and TR3 are alternately turned on / off based on the control of the output control circuit SC, and the DC conversion circuit. The DC voltage from 12 is converted into a predetermined high-frequency AC voltage and supplied to the primary coil of the transformer INT.

  An auxiliary switching circuit 14 and an auxiliary capacitor C3 are provided between the inverter circuit 13 and the DC conversion circuit 12. The auxiliary switching circuit 14 includes fifth to eighth switching elements TR5 to TR8 made of four IGBTs, and the fifth switching element is disposed on the power supply line L1 after the first and second smoothing capacitors C1 and C2. In TR5, the sixth switching element TR6 is disposed on the power supply line L2. The seventh and eighth switching elements TR7 and TR8 are connected in series between the power supply lines L1 and L2 at the subsequent stage of the fifth and sixth switching elements TR5 and TR6. Diodes D15 to D18 are reversely connected to the fifth to eighth switching elements TR5 to TR8, respectively. An auxiliary capacitor C3 is connected between the power supply lines L1 and L2 at the subsequent stage of the seventh and eighth switching elements TR7 and TR8.

  In addition, a connection point N2 between the emitter of the seventh switching element TR7 and the collector of the eighth switching element TR8 and a connection point N1 between the first and second smoothing capacitors C1 and C2 are not connected to each other. In the embodiment, a changeover switch S1 made of a relay is connected. The changeover switch S1 is turned off when the input AC power source is determined to be 200V based on the control of the output control circuit SC, and both the connection points N1 and N2 are shut off, and the input AC power source is determined to be 400V system. It is sometimes turned on to conduct both connection points N1 and N2. The fifth to eighth switching elements TR5 to TR8 are configured to reduce the switching loss of the first to fourth switching elements TR1 to TR4 of the inverter circuit 13 based on the control of the output control circuit SC. On / off driving is performed in synchronization with the TR4, and the input AC power supply is controlled differently for the 200V system and the 400V system.

  The high-frequency AC voltage generated by the inverter circuit 13 is supplied to the primary coil of the transformer INT, and a secondary rectifier circuit DR2 and a DC reactor DCL are provided on the secondary side of the transformer INT. The secondary rectifier circuit DR2 and the DC reactor DCL convert the high-frequency AC voltage from the inverter circuit 13 into an arc machining DC voltage, and this machining DC voltage is supplied to the torch TH via the output line L3 on the DC reactor DCL side. Is output. On the other hand, the output line L4 is connected to the workpiece M, and an arc is generated from the torch TH toward the workpiece M based on the supply of the machining DC voltage.

  Further, an output current detection circuit ID for detecting an actual output current value is connected to the output line L4. The output current detection circuit ID outputs the detected output current value to the comparison operation circuit ER as an output current detection signal Id. The comparison operation circuit ER outputs the output current detection signal Id and the output from the output current setting device IR. The current setting signal Ir is compared. Incidentally, in the output current setting device IR, the output current value is set by a human operation or the like so as to obtain an output current value corresponding to the workpiece M to be arced, and an output current setting signal corresponding to the setting is set. Ir is output to the comparison operation circuit ER. The comparison operation circuit ER compares the output current detection signal Id with the output current setting signal Ir, that is, outputs the difference between the output current value and the set value to the output control circuit SC as a comparison operation signal Er. Used for feedback control in the output control circuit SC.

  The output control circuit SC first detects the DC voltage generated by the DC conversion circuit 12 based on the input of the voltage detection signal Iv from the voltage detection circuit IV, and the input AC voltage is 200V or 400V based on this detection. Judging. The output control circuit SC switches the changeover switch S1 to ON when it is determined that the input is 400V system, and turns OFF the changeover switch S1 when it is determined that the input is 200V system. The inverter circuit 13 and the auxiliary switching circuit 14 are controlled according to the timing waveform 3. Incidentally, before the input AC power is turned on, the changeover switch S1 is turned on so as to be compatible with 400V system input.

[For 400V input]
In the case of 400V system input, the output control circuit SC switches the changeover switch S1 to the ON state, and the connection point N1 between the first and second smoothing capacitors C1 and C2 and the seventh and eighth switching elements TR7 and TR8. The connection point N2 between them is brought into conduction. Then, control is performed according to the timing waveform of FIG.

  The output control circuit SC is an ON time based on the output current setting value from the input in the output current setting device IR, and the combination of the first and fourth switching elements TR1 and TR4 of the inverter circuit 13 and the second and third switching elements. The combination of the switching elements TR2 and TR3 is alternately turned on / off. In this case, the first and fourth switching elements TR1 and TR4 are switched off at least a predetermined time t2 before the second and third switching elements TR2 and TR3 are switched on. The switching elements TR2 and TR3 are switched off at least a predetermined time t4 before the first and fourth switching elements TR1 and TR4 are switched on. Then, when the output current setting value is increased in the output current setting device IR, the output control circuit SC sets the ON time of each of the switching elements TR1 to TR4 to be long as long as the predetermined times t2 and t4 can be secured, and outputs When the current set value is decreased, the ON times of the switching elements TR1 to TR4 are set to be short (predetermined times t2 and t4 are long). In addition, the output control circuit SC performs feedback control using an actual output current value (output current detection signal Id), and a deviation (comparison calculation signal Er) between the actual output current value and the output current set value is determined. Based on this, the on-time of each switching element TR1 to TR4 is adjusted.

  In the auxiliary switching circuit 14, the output control circuit SC turns on / off the fifth to eighth switching elements TR <b> 5 to TR <b> 8 in correspondence with the on / off operation of the switching elements TR <b> 1 to TR <b> 4 of the inverter circuit 13. In this case, the fifth and eighth switching elements TR5 and TR8 are turned on simultaneously with the first and fourth switching elements TR1 and TR4 when turned on, and the first and fourth switching elements TR1 and TR4 are turned off when turned off. It is turned off a predetermined time t1 before switching. The sixth and seventh switching elements TR6 and TR7 are turned on simultaneously with the second and third switching elements TR2 and TR3 when turned on, and the second and third switching elements TR2 and TR3 are turned off when turned off. Turned off before a predetermined time t3.

  When the fifth and eighth switching elements TR5 and TR8 are turned on, the inverter circuit 13 has a voltage across the terminals of the first smoothing capacitor C1, that is, a voltage that is half the voltage obtained by converting the 400V system input AC power source into a DC voltage. (A voltage equivalent to a DC voltage at the time of 200 V system input) is supplied. As a result, the charging voltage on the first smoothing capacitor C1 side is applied to the primary coil of the transformer INT via the first and fourth switching elements TR1 and TR4 that are simultaneously turned on.

  When the first and fourth switching elements TR1 and TR4 are turned off, the soft switching control is performed in which the fifth and eighth switching elements TR5 and TR8 are turned off before the predetermined time t1 prior to the turning off. The supply of DC voltage from the conversion circuit 12 to the inverter circuit 13 side is stopped first, and the first and fourth switching elements TR1 and TR4 are turned off after a predetermined time t1 when the discharge of the auxiliary capacitor C3 is completed. As a result, the voltage applied to the first and fourth switching elements TR1 and TR4 is substantially zero, and the switching elements TR1 and TR4 are turned off, and the switching loss, which is the effect of the soft switching control, is reduced. In addition, when the fifth and eighth switching elements TR5 and TR8 are turned off, the voltage between the terminals of the first smoothing capacitor C1 and the auxiliary capacitor C3 becomes equal. The voltage between both terminals of TR8 becomes substantially zero voltage, and the switching loss in the fifth and eighth switching elements TR5 and TR8 is also reduced.

  The same applies when the sixth and seventh switching elements TR6 and TR7 are turned on. When the sixth and seventh switching elements TR6 and TR7 are turned on, the inverter circuit 13 includes the second smoothing capacitor C2. The voltage between terminals, that is, a voltage that is half the voltage obtained by converting a 400V input AC power supply into a DC voltage (a voltage equivalent to a DC voltage at the time of 200V input) is supplied. As a result, the charging voltage on the second smoothing capacitor C2 side is applied as a reverse voltage to the primary coil of the transformer INT via the second and third switching elements TR2 and TR3 that are simultaneously turned on.

  When the second and third switching elements TR2 and TR3 are turned off, soft switching control is performed in which the sixth and seventh switching elements TR6 and TR7 are turned off before a predetermined time t3 prior to the turning off. The supply of the DC voltage from the conversion circuit 12 to the inverter circuit 13 side is stopped first, and the second and third switching elements TR2 and TR3 are turned off after a predetermined time t3 when the discharge of the auxiliary capacitor C3 is completed. As a result, the voltage applied to the second and third switching elements TR2 and TR3 is substantially zero, and the switching elements TR2 and TR3 are turned off. In this case, the switching loss, which is the effect of the soft switching control, is also reduced. In addition, when the sixth and seventh switching elements TR6 and TR7 are turned off, the voltage between the terminals of the second smoothing capacitor C2 and the auxiliary capacitor C3 becomes equal, so that the sixth and seventh switching elements TR6 and TR6 The voltage between both terminals of TR7 becomes substantially zero voltage, and the switching loss in the sixth and seventh switching elements TR6 and TR7 is also reduced.

  As described above, at the time of 400 V system input, the auxiliary switching circuit 14 steps down the voltage to a voltage equivalent to the DC voltage at the time of 200 V system input and supplies it to the inverter circuit 13. Soft switching control is performed to reduce the switching loss of TR4.

[In case of 200V input]
In the case of 200V system input, the output control circuit SC switches the changeover switch S1 to the OFF state, and the connection point N1 between the first and second smoothing capacitors C1 and C2 and the seventh and eighth switching elements TR7 and TR8. The connection point N2 between them is cut off. And control according to the timing waveform of FIG. 3 is made.

  Similarly, at the time of the 200V system input, the output control circuit SC also has the on-time based on the output current setting value from the input at the output current setting device IR, and the first and fourth switching elements TR1, TR4 of the inverter circuit 13. And the second and third switching elements TR2 and TR3 are alternately turned on and off. In this case, the first and fourth switching elements TR1 and TR4 are switched off at least a predetermined time t2 before the second and third switching elements TR2 and TR3 are switched on. The switching elements TR2 and TR3 are switched off at least a predetermined time t4 before the first and fourth switching elements TR1 and TR4 are switched on. Then, the output control circuit SC sets the ON times of the switching elements TR1 to TR4 according to the output current set value, and adjusts the ON times of the switching elements TR1 to TR4 at that time by feedback control.

  Further, in the auxiliary switching circuit 14, the output control circuit SC turns on and off the fifth and sixth switching elements TR5 and TR6 in association with the on / off operation of the switching elements TR1 to TR4 of the inverter circuit 13, while At the time of 200V input, the seventh and eighth switching elements TR7 and TR8 are maintained in the off state. At the time of this 200V input, the fifth switching element TR5 is turned on simultaneously with the second and third switching elements TR2 and TR3 when turned on, while the first and fourth switching elements TR1 and TR4 are turned off when turned off. It is turned off before a predetermined time t1 when switching to. That is, the fifth switching element TR5 is turned off during a period from the predetermined time t1 before the first and fourth switching elements TR1 and TR4 are turned off until the second and third switching elements TR2 and TR3 are turned on. , Other periods are on. The sixth switching element TR6 is turned on simultaneously with the first and fourth switching elements TR1 and TR4 when turned on, while the second and third switching elements TR2 and TR3 are turned off when turned off. Turned off before. That is, the sixth switching element TR6 is turned off during a period from the predetermined time t3 before the second and third switching elements TR2 and TR3 are turned off until the first and fourth switching elements TR1 and TR4 are turned on. , Other periods are on.

  Therefore, during the period in which both the fifth and sixth switching elements TR5 and TR6 are on, the inverter circuit 13 has a voltage across the first and second smoothing capacitors C1 and C2, that is, a DC voltage from the DC conversion circuit 12. Will be supplied. Thus, the DC voltage is applied to the primary coil of the transformer INT during the ON period of the first and fourth switching elements TR1 and TR4 and the ON period of the second and third switching elements TR2 and TR3. As applied.

  Further, when the first and fourth switching elements TR1 and TR4 are turned off, soft switching control is performed in which the fifth switching element TR5 is turned off a predetermined time t1 before the first and fourth switching elements TR1 and TR4 are turned off. The four switching elements TR1 and TR4 are turned off at substantially zero voltage, and the switching loss, which is the effect of the soft switching control, is reduced. Similarly, when the second and third switching elements TR2 and TR3 are turned off, soft switching control is performed in which the sixth switching element TR6 is turned off before the predetermined time t3 prior to the turning off. The second and third switching elements TR2 and TR3 are turned off at substantially zero voltage, and switching loss, which is an effect of soft switching control, is reduced.

  Here, when performing soft switching control in which the fifth and sixth switching elements TR5 and TR6 are turned off prior to the switching elements TR1 to TR4 of the inverter circuit 13, between the first and second smoothing capacitors C1 and C2. In the case where the connection point N1 and the connection point N2 between the seventh and eighth switching elements TR7 and TR8 are in a conductive state and have the same configuration as the conventional one, the connection point N1 between the first and second smoothing capacitors C1 and C2 Is supplied to the inverter circuit 13 via the diodes D17 and D18 reversely connected to the seventh and eighth switching elements TR7 and TR8, and the effect of the soft switching control cannot be obtained.

  On the other hand, in the present embodiment, the connection point N1, N2 is blocked by the changeover switch S1, so that the voltage at the connection point N1 between the first and second smoothing capacitors C1, C2 is applied to the inverter circuit 13. It is prevented from being supplied, and the switching loss reduction effect of the soft switching control can be obtained even at the time of the 200V system input. Similarly, when both the fifth and sixth switching elements TR5 and TR6 are turned off, the voltage between both terminals of the first and second smoothing capacitors C1 and C2 and the terminal voltage of the auxiliary capacitor C3 are equal. The voltages between both terminals of the fifth and sixth switching elements TR5 and TR6 are substantially zero voltages, respectively, and the switching loss in the fifth and sixth switching elements TR5 and TR6 is also reduced.

  As described above, at the time of 200V system input, the auxiliary switching circuit 14 does not step down the DC voltage and supplies it to the inverter circuit 13 and reduces the switching loss of the switching elements TR1 to TR4 of the inverter circuit 13. Soft switching control is performed.

Next, characteristic effects of the present embodiment will be described.
(1) In the present embodiment, the connection point N1 between the first and second smoothing capacitors C1 and C2, and the seventh and eighth switching elements connected in series between the power supply lines L1 and L2 in the auxiliary switching circuit 14 Between the connection point N2 between TR7 and TR8, there is provided a changeover switch S1 (first changeover means) composed of a relay for switching between connection and disconnection. When the 400V system input as the second voltage value is input, the changeover switch S1 is turned on so that the voltage between the terminals of the first or second smoothing capacitors C1 and C2 can be alternately supplied to the inverter circuit 13. . Further, when the 200 V system input as the first voltage value is input, the changeover switch S1 is cut off, so that the voltage at the connection point N1 between the first and second smoothing capacitors C1 and C2 becomes the seventh and eighth switching elements. Supply to the inverter circuit 13 side through the reversely connected diodes D17 and D18 provided in TR7 and TR8 is reliably prevented, and the effect of the soft switching control can be obtained with certainty. As described above, according to the present embodiment, it is possible to provide the arc machining power supply device 11 that can cope with two different input voltages by simply adding a changeover switch S1 that simply opens and closes an electric circuit.

  (2) In the present embodiment, under the control of the output control circuit SC, the changeover switch S1 is switched to conduction based on the determination of the 400V system input, and the changeover switch S1 is switched to cutoff based on the determination of the 200V system input. That is, since the changeover switch S1 is automatically switched under the control of the output control circuit SC, no human operation is required.

(3) In this embodiment, since the changeover switch S1 is configured by one switch (relay), the circuit configuration of the power supply device 11 is not complicated.
(Second Embodiment)
Hereinafter, a second embodiment of the present invention will be described with reference to the drawings. Note that the arc machining power supply device of the present embodiment is configured by further adding a changeover switch to the circuit configuration of the first embodiment.

  In the arc machining power supply device 11a shown in FIG. 4, similarly, the connection point N1 between the first and second smoothing capacitors C1 and C2 and the seventh and eighth switching elements TR7 and TR8 of the auxiliary switching circuit 14 are connected. The switch S1 (first switch) made of a relay is connected to the connection point N2. In addition, a relay is connected between the connection point N2 between the seventh and eighth switching elements TR7 and TR8 and the connection point N3 between the first and third switching elements TR1 and TR3 of the inverter circuit 13. The second changeover switch S2 is connected. These change-over switches S1 and S2 are complementarily switched based on the control of the output control circuit SC, such as ON / OFF at the time of 400V system input and OFF / ON at the time of 200V system input. Then, the output control circuit SC controls the inverter circuit 13 and the auxiliary switching circuit 14 according to the timing waveforms of FIGS. 5 and 6 corresponding to the respective inputs.

[For 400V input]
In the case of 400V system input, the output control circuit SC switches the changeover switch S1 to the ON state, and the connection point N1 between the first and second smoothing capacitors C1 and C2 and the seventh and eighth switching elements TR7 and TR8. The connection point N2 between them is brought into conduction. Further, the changeover switch S2 is switched to the OFF state, and the connection point N2 between the seventh and eighth switching elements TR7 and TR8 and the connection point N3 between the first and third switching elements TR1 and TR3 are in the cut-off state. Is done.

  That is, in the open / closed state of the changeover switches S1 and S2, the configuration is the same as that of the power supply device 11 of the first embodiment, and the output control circuit SC of the present embodiment is the first embodiment according to FIG. The same control as that at the time of 400V input is performed. Therefore, also in the arc machining power supply device 11a of this embodiment, at the time of this 400V system input, the auxiliary switching circuit 14 steps down the voltage to a voltage equivalent to the DC voltage at the time of 200V system input and supplies it to the inverter circuit 13. Soft switching control for reducing the switching loss of each switching element TR1 to TR4 of the inverter circuit 13 is performed.

[In case of 200V input]
In the case of 200V system input, the output control circuit SC switches the changeover switch S1 to the OFF state, and the connection point N1 between the first and second smoothing capacitors C1 and C2 and the seventh and eighth switching elements TR7 and TR8. The connection point N2 between them is cut off. Further, the changeover switch S2 is switched to the ON state, and the connection point N2 between the seventh and eighth switching elements TR7, TR8 and the connection point N3 between the first and third switching elements TR1, TR3 are in the conductive state. Is done.

  The fifth and sixth switching elements TR5 and TR6 are controlled by the output control circuit SC of the present embodiment in the same manner as the control at the time of 200V system input according to the first embodiment according to FIG. . That is, the fifth switching element TR5 is turned off before the first and fourth switching elements TR1 and TR4 are turned off (before the predetermined time t1), and the sixth switching element TR6 is turned on to the second and third switching elements. Soft switching control which is turned off prior to turning off TR2 and TR3 (before a predetermined time t3) is performed.

  Further, according to the open / close state of the changeover switches S1 and S2, the seventh switching element TR7 is connected in parallel with the first switching element TR1, and the eighth switching element TR8 is connected in parallel with the third switching element TR3. Become. Therefore, the output control circuit SC of the present embodiment performs the same on / off control of the seventh and eighth switching elements TR7 and TR8 as the first and third switching elements TR1 and TR3, and as a part of the inverter circuit 13 Make it work. That is, since the changeover switch S1 is turned off, the connection point N1 between the first and second smoothing capacitors C1 and C2 and the connection point N2 between the seventh and eighth switching elements TR7 and TR8 are cut off. The seventh and eighth switching elements TR7 and TR8 can be used. It should be noted that the voltage at the connection point N1 between the first and second smoothing capacitors C1 and C2 is supplied to the inverter circuit 13 side in the present embodiment as well due to the interruption between the connection points N1 and N2 by the changeover switch S1. Is prevented, and the influence on the soft switching control is also prevented.

  Further, by operating the seventh and eighth switching elements TR7 and TR8 as a part of the inverter circuit 13, the current originally flowing in the first and third switching elements TR1 and TR3 is halved. Thereby, heat generation in the first and third switching elements TR1 and TR3 can be reduced, and a small and low-cost switching element having a small current capacity can be used.

  In this connection, there is one package in which a collector of one switching element and an emitter of the other switching element are connected to form one package. In this embodiment, the packaged pair of switching elements is used. In this case, the elements surrounded by broken lines in FIG. Specifically, a set of first and third switching elements TR1, TR3, a set of seventh and eighth switching elements TR7, TR8, a set of fifth and second switching elements TR5, TR2, It is divided into a set of sixth and fourth switching elements TR6 and TR4.

  That is, since the heat generation of the first, third, seventh, and eighth switching elements TR1, TR3, TR7, TR8 is suppressed, a package with a small current capacity (for example, 150 A) can be selected. On the other hand, since the fifth and sixth switching elements TR5 and TR6 have a long ON time, it is desirable to select one having a large current capacity (for example, 300 A). However, in this case, since the package cannot be configured in the same package, the remaining second and fourth switching elements TR2 and TR4 are paired with each other. Therefore, when it is configured using a package of a pair of switching elements, rational grouping is possible in this way.

Next, in addition to the operational effects of the first embodiment, the characteristic operational effects of the present embodiment will be described.
(1) In the present embodiment, there is a mutual connection between the connection point N3 between the first and third switching elements TR1 and TR3 and the connection point N2 between the seventh and eighth switching elements TR7 and TR8. Is provided with a change-over switch S2 (second switching means) comprising a relay for switching between ON and OFF. Then, when the changeover switch S1 is turned on (when the 400V system is input), the changeover switch S2 is cut off, so that the same operation as that when the changeover switch S1 is cut off (when the 200V system is input) is possible. When the changeover switch S2 is turned on, the seventh and eighth switching elements TR7 and TR8 are subjected to the same on / off control as the switching elements TR1 and TR3 of the inverter circuit 13 that are arranged in parallel by the conduction of the changeover switch S2. It operates as a part of the inverter circuit 13. Thereby, the current flowing through the switching elements TR1 and TR3 in parallel with the seventh and eighth switching elements TR7 and TR8 can be divided into two, and the generation of heat at the switching elements TR1 and TR3 can be reduced.

  (2) In the present embodiment, under the control of the output control circuit SC, the changeover switch S1 is switched on and the changeover switch S2 is switched off based on the determination of the 400V system input, and the changeover switch S1 based on the determination of the 200V system input. Is cut off, and the changeover switch S2 is switched to conduction. That is, since the changeover switch S1 is automatically switched under the control of the output control circuit SC, no human operation is required.

  (3) In the present embodiment, the changeover switch S2 is composed of one switch (relay) together with the changeover switch S1, so that the circuit configuration of the power supply device 11a is not complicated.

In addition, you may change embodiment of this invention as follows.
In the first and second embodiments, the selector switch S1 and selector switch S2 as switching means are each constituted by one relay, but a switch other than the relay that can be controlled by the output control circuit SC, You may comprise by the switch etc. by switching. In addition, when a manual changeover switch is used in 2nd Embodiment, it is good to make a mutual switch interlock | cooperate. Further, the switching means may be constituted by a switch circuit using two or more circuit components.

  In the second embodiment, one end of the changeover switch S2 is connected to the connection point N3 between the first and third switching elements TR1 and TR3 of the inverter circuit 13, but the second and fourth switching elements TR2, You may connect to the connection point between TR4.

In the first and second embodiments, the IGBT is used for each of the switching elements TR1 to TR8. However, a switching element other than the IGBT may be used.
In the first and second embodiments described above, the arc machining power supply devices 11 and 11a are used. However, power supply devices used for purposes other than arc machining, such as a DC conversion circuit 12, an inverter circuit 13, and an auxiliary switching circuit. You may implement in the alternating current-alternating-current conversion power supply device which has 14. Moreover, you may implement in the DC-AC conversion power supply device which has the inverter circuit 13 and the auxiliary | assistant switching circuit 14. FIG.

Next, a technical idea that can be grasped from the above embodiment and another example will be added below.
(A) DC voltage composed of a bridge circuit using the first to fourth switching elements, the first to fourth switching elements being driven on and off for each predetermined set and supplied via a pair of power supply lines An inverter circuit that converts the current into a predetermined AC voltage;
Between the first and second smoothing capacitors connected in series between the power supply lines and the auxiliary capacitor connected between the power supply lines in the previous stage of the inverter circuit, the fifth and sixth switching elements are the Seventh and eighth switching elements arranged on each power supply line are connected in series between the power supply lines, and when the input AC power supply of the first voltage value is input, the first and second smoothing capacitors While supplying both-ends voltage to the inverter circuit, the input AC power supply having a second voltage value that is twice the first voltage value is turned on / off for each predetermined set of the fifth to eighth switching elements. The voltage between the terminals of the first or second smoothing capacitor is alternately supplied to the inverter circuit, and the predetermined elements of the fifth to eighth switching elements are turned on by the first to fourth switching elements. The power supply device provided with an auxiliary switching circuit soft switching control is performed to stop the voltage supply to the inverter circuit side off prior to,
First switching means is provided between the connection point between the first and second smoothing capacitors and the connection point between the seventh and eighth switching elements for switching between conduction and cutoff. A power supply device characterized by that.

( B) In the power supply device described in (a) above,
In the inverter circuit, the first and third switching elements are connected in series between the power supply lines, and the second and fourth switching elements are connected in series between the power supply lines. Is,
Between either the connection point between the first and third switching elements or the connection point between the second and fourth switching elements, and the connection point between the seventh and eighth switching elements. Provided with a second switching means for switching between conduction and interruption;
Any of the first and third switching elements or the second and fourth switching elements rendered conductive by the second switching means and the seventh and eighth switching elements are the same on / off. A power supply device that is controlled.

It is a circuit diagram which shows the power supply device for arc processing in 1st Embodiment. It is a wave form diagram at the time of the 400V type | system | group input in 1st Embodiment. It is a wave form diagram at the time of 200V type | system | group input in 1st Embodiment. It is a circuit diagram which shows the power supply apparatus for arc processing in 2nd Embodiment. It is a wave form diagram at the time of the 400V type | system | group input in 2nd Embodiment. It is a wave form diagram at the time of 200V type | system | group input in 2nd Embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 11, 11a ... Power supply device, 12 ... DC converter circuit, 13 ... Inverter circuit, 14 ... Auxiliary switching circuit, C1, C2 ... 1st, 2nd smoothing capacitor, C3 ... Auxiliary capacitor, DR1 ... Primary side as rectifier circuit Rectifier circuit, L1, L2 ... power line, M ... workpiece, N1, N2, N3 ... connection point, S1, S2 ... changeover switch as first and second changeover means, SC ... output as changeover control means Control circuit, TR1 to TR8... First to eighth switching elements.

Claims (4)

A DC converter circuit having first and second smoothing capacitors connected in series between a rectifier circuit and a pair of power supply lines on its output side, and converting an input AC power source into a rectified and smoothed DC voltage;
The first to fourth switching elements are configured by a bridge circuit using the first to fourth switching elements, and the first to fourth switching elements are turned on and off for each predetermined set, and the DC voltage supplied via the power lines is predetermined. An inverter circuit that converts the AC voltage into
In between the auxiliary capacitor connected between the power supply lines of the inverter circuit preceding said DC converter circuit, the fifth and sixth switching elements are arranged on each power supply line Rutotomoni seventh and eighth Switching elements are connected in series between the respective power supply lines , and diodes are reversely connected to the seventh and eighth switching elements, respectively. When the input AC power supply with the first voltage value is input, the first and second switching elements are connected . The voltage across the two smoothing capacitors is supplied to the inverter circuit, while at the time of input of the input AC power source having a second voltage value that is twice the first voltage value, for each predetermined set of the fifth to eighth switching elements. The on-off drive is performed to supply the voltage between the terminals of the first or second smoothing capacitor alternately to the inverter circuit. Further, predetermined elements of the fifth to eighth switching elements are Off prior to the serial first to off of the fourth switching element and an auxiliary switching circuit soft switching control is performed to stop the voltage supply to the inverter circuit side, the input of the first voltage value A power supply device configured to maintain the seventh and eighth switching elements in an off state when an AC power supply is input ;
First switching means is provided between the connection point between the first and second smoothing capacitors and the connection point between the seventh and eighth switching elements, for switching between conduction and cutoff between each other .
The first switching means is configured to be able to control switching between conduction and interruption,
The first switching unit is switched to conduction based on the input of the input AC power source having the second voltage value, and the first switching unit is switched based on the input of the input AC power source having the first voltage value. A power supply device comprising switching control means for controlling to switch to shut-off . A DC converter circuit having first and second smoothing capacitors connected in series between a rectifier circuit and a pair of power supply lines on its output side, and converting an input AC power source into a rectified and smoothed DC voltage;
The first to fourth switching elements are configured by a bridge circuit using the first to fourth switching elements, and the first to fourth switching elements are turned on and off for each predetermined set, and the DC voltage supplied via the power lines is predetermined. An inverter circuit that converts the AC voltage into
Between the DC converter circuit and the auxiliary capacitor connected between the power supply lines in the previous stage of the inverter circuit, fifth and sixth switching elements are arranged on the power supply lines, and seventh and eighth Switching elements are connected in series between the respective power supply lines, and diodes are reversely connected to the seventh and eighth switching elements, respectively. When the input AC power supply with the first voltage value is input, the first and second switching elements are connected. The voltage across the two smoothing capacitors is supplied to the inverter circuit, while at the time of input of the input AC power source having a second voltage value that is twice the first voltage value, for each predetermined set of the fifth to eighth switching elements. The on-off drive is performed to supply the voltage between the terminals of the first or second smoothing capacitor alternately to the inverter circuit. Further, predetermined elements of the fifth to eighth switching elements are An auxiliary switching circuit soft switching control for stopping the voltage supply is turned off before the serial first to off of the fourth switching element to the inverter circuit side is performed
A power supply device comprising:
First switching means is provided between the connection point between the first and second smoothing capacitors and the connection point between the seventh and eighth switching elements, for switching between conduction and cutoff between each other.
In the inverter circuit, the first and third switching elements are connected in series between the power supply lines, and the second and fourth switching elements are connected in series between the power supply lines. Is,
Between either the connection point between the first and third switching elements or the connection point between the second and fourth switching elements, and the connection point between the seventh and eighth switching elements. Provided with a second switching means for switching between conduction and interruption;
The first and second switching means are configured to be capable of controlling switching between conduction and cutoff,
Based on the input of the input AC power supply of the second voltage value, the first switching means is switched on and the second switching means is switched off, and the input voltage of the first voltage value is input to the input AC power supply. A switching control means for controlling to shut off the first switching means and to switch the second switching means to conduction based on
When the first switching means is cut off and the second switching means is switched to conduction based on the input of the input AC power supply of the first voltage value by the switching control means, the seventh and eighth the switching element, the same on-off control the switching elements of the inverter circuit to be parallel by the conduction of the second switching means is performed, the power supply apparatus characterized that you operate as part of the inverter circuit. The power supply device according to claim 1 or 2 ,
The power supply apparatus according to claim 1, wherein the switching means is composed of a single switch. An arc machining power supply device configured to generate an arc machining voltage for performing arc machining of a workpiece using the power supply device according to any one of claims 1 to 3 .

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