JPH0333070B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a power source for a plasma arc used for plasma cutting and plasma welding.

[Background of the invention]

Many plasma cutting machines and plasma welding machines that use a transitional plasma arc supply power to the main arc circuit and pilot arc circuit from a single power source. To generate this, constant current control using an inverter or chopper is used. An example is shown in FIG.

In Figure 2, the main power supply circuit includes an AC input terminal 1, a primary rectifier 2, a smoothing capacitor 3, an inverter 4 which is an output control section, a transformer 5, a secondary rectifier 6, a DC reactor 7, and a pilot arc current limiter. It consists of a resistor 8, a high frequency generator 9 for arc starting, a coupling coil 10, and a capacitor 11 for high frequency bypass. At the time of arc starting, the no-load voltage of the power supply is applied between the electrode 12 of the plasma cutting torch and the base material 13,
At the same time, the same voltage is applied between the electrode 12 and the nozzle 14 via the resistor 8 and the contact 1Xb. Further, a high frequency voltage is superimposed and applied to the pilot arc circuit via the coupling coil 10.
A pilot arc is struck between the electrode 12 and the nozzle 14 by a high frequency discharge. At this time, the pilot arc current is limited by resistor 8. The plasma flow caused by this pilot arc is ejected from the nozzle 14 by the working gas, and the base material 13
When touched, a main arc is struck between the electrode 12 and the base material 13, and cutting begins.

The main arc current is determined by comparing the detection signal of the main arc current detector 15 and the setting signal of the main arc current setting device 16 in a comparison section 17, and transmitting the main arc current control signal outputted from the comparison section 17 to the inverter drive circuit 18. By controlling the output pulse width of the inverter 4, the plasma arc (main arc) is maintained stably. 19 is a relay drive circuit that is activated by the detection signal of the main arc current detector 15, and when a predetermined main arc current flows, it energizes the relay 1X, opens the contact 1Xb, and cuts off the pilot arc circuit. There is.

In this way, in the conventional transfer type plasma arc power supply, a resistor 8 is used to control the pilot arc current, and this resistor 8 has a no-load voltage of 200 to
In order to suppress the pilot arc current to 5 to 10A at 250V, the resistance value needs to be approximately 20Ω.
The power consumption varies depending on the arc voltage, but from 1 to
It can reach up to 2kW. This requires a large-capacity resistor, which has been an obstacle to making the power supply smaller and lighter. Further, in the conventional transfer type plasma arc power supply, constant current control is not performed on the pilot arc current, and the current value fluctuates depending on the arc voltage, so the stability of the pilot arc is not sufficient. In addition, if the electrode 12 and the nozzle 14 are started with a short circuit, the no-load voltage (200~
250V) and this voltage is applied between the nozzle 14 and the base material 13, which is dangerous.

[Purpose of the invention]

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a plasma arc power source that has excellent pilot arc stability, high safety, and can be made smaller and lighter. purpose.

[Summary of the invention]

The present invention provides a transfer type plasma arc power supply with a function of opening the pilot arc circuit when the current shifts to the main arc current, and performs constant current control for the pilot arc current and the main arc current, respectively.
Furthermore, the above-mentioned object is achieved by providing the pilot arc circuit with a low resistance such that a voltage low enough to prevent electric shock is applied to the torch even when the maximum current flows through the pilot arc circuit.

[Embodiments of the invention]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing an embodiment of a plasma arc power source according to the present invention. In FIG. 1, parts that are the same or equivalent to those in FIG. do not have.

The present invention inserts a pilot arc current detector 20 and a low resistance 24 into the pilot arc circuit, and compares the detection signal from the detector 20 with the setting signal from the pilot arc current setting device 21 to determine the pilot arc current. A comparator (second comparator) 22 is provided for controlling the constant current.
In this case, until the main arc current is detected by the relay drive circuit 19, both the comparison section (first comparison section) 17 and the comparison section 22 are in the operating state, and the detected values from the detectors 15 and 20 are It is controlled so that neither of the set values of the setters 16 and 21 are exceeded. In addition, the low resistance 24 is such that when there is a short circuit between the electrode 12 and the nozzle 14 and the maximum current (about 5 to 10 A in this case, since the pilot arc current is also controlled at a constant current in the present invention) flows through the pilot arc circuit, The resistance value (approximately 2 to 3 ohms) is selected so that the generated voltage will not cause an electric shock even if the nozzle 14 is touched, for example, approximately 10 to 30V. As a result, when a pilot arc current (approximately 5 to 10 A) flows, a voltage drop (10 to 30 V) due to the low resistance 24 occurs between the nozzle 14 and the base material 13, making it easier for arc transfer. Furthermore, since the resistance value of the low resistance 24 is low, its power consumption is, for example, 50W if it is rated at 5A and 2Ω, and a low capacity (small, lightweight) resistor can be used.

The present invention also includes a signal selection circuit 23. This signal selection circuit 23 includes, for example, diodes D 1 and _{D 2} between the common connection point P and the output end of the first comparison section 17 and between the common connection point P and the output end of the second comparison section ₂₂ . are connected so that their respective anode sides are common, and the common connection point P is connected to the DC power supply +V via a resistor _R1 , and the main arc current control signal output from the first comparison section 17 and the second comparison are made. Among the pilot arc control signals outputted from the section 22, the signal with the lower voltage level is inputted to the inverter drive circuit 18 via the diodes _D1 , _D2 and the common connection point P. The inverter drive circuit 18 compares the input control signal and the sawtooth wave signal, generates a pulse signal whose pulse width is wider as the voltage level of the control signal is higher, and uses this pulse signal to drive the transistor which is the switching element of the inverter 4. The output of the power supply is controlled so that the main arc current and pilot arc current reach their respective set values.

At the time of arc start, the AC input at the commercial frequency applied to the AC input terminal 1 is exchanged to DC by the primary side rectifier 2 and smoothing capacitor 3, and then converted to high frequency AC by the inverter 4 and applied to the primary side of the transformer 5. and generates a no-load voltage on the secondary side.

After this no-load voltage is converted into DC again by the secondary rectifier 6, it is applied between the electrode 12 and the base material 13 of the plasma cutting torch via the DC reactor 7, and at the same time, it is applied to the electrode 12 via the contact 1Xb. The same voltage is also applied across the nozzles 14. Further, a high frequency voltage generated by a high frequency generator 9 is applied to the pilot arc circuit in a superimposed manner by a coupling coil 10, and a pilot arc is struck between the nozzles 14 of the electrodes 12 by being guided by high frequency discharge. This pilot arc current is detected by a pilot arc current detector 20, and a detection signal proportional to the current value is fed back to a second comparator 22. At this time, since the pilot arc current control signal output from the second comparator 22 has a lower voltage level than the main arc current control signal output from the first comparator 17, the diode D ₂ of the signal selection circuit 23 is on, diode _D1 is off,
A pilot arc current control signal is input to the inverter drive circuit 18 through the diode _D2 , so that the inverter 4 controls the power output so that the pilot arc current reaches a set value. Next, when a plasma arc (main arc) is struck between the electrode 12 and the base metal 13 by being guided by the plasma flow caused by the pilot arc, the main arc current is detected by the main arc current detector 15, and this detection signal is When the main arc current reaches a predetermined value, the relay drive circuit 19 energizes the relay 1X, opens the contact 1Xb, and cuts off the pilot arc circuit. Until then, even if the main arc current has not reached the set value, inverter 4 will give priority to constant current control of the pilot arc current to suppress it if the pilot arc current flows in excess of the set value. . However, when the pilot arc circuit is cut off, the voltage level of the main arc current control signal generated in the first comparator 17 due to the feedback from the main arc current detector 15 is higher than that of the pilot arc circuit output from the second comparator 22. Since the voltage level is lower than the voltage level of the arc current control signal, the signal selection circuit 23
diode _D1 is turned on and diode D2 is turned off, and the inverter ₄ controls the power supply output according to the main arc current control signal input to the inverter drive circuit 18 via the diode _D1 , and the main arc current will be maintained at the set value.

The signal selection circuit 23 in this embodiment is an example in which a diode is used as a switching element, but it is possible to select between the pilot arc current control signal and the main arc current control signal using a switching contact that is linked to the ON/OFF state of the pilot arc circuit. It goes without saying that functions similar to those described above can be obtained even with a configuration that performs the following.

The above embodiment can also be used as a plasma welder by changing the working gas. Further, the present invention can also be applied to a case where the output is controlled by a chopper provided on the secondary side of the transformer 5 instead of the inverter 4.

Furthermore, in the above embodiment, the pilot arc current detector 20 was provided independently, but this is replaced by the low resistance 24.
The pilot arc current may be detected based on the generated voltage (voltage between both ends).

〔Effect of the invention〕

As described above, according to the present invention, the resistor in the pilot arc circuit can be replaced from a large-capacity resistor to a small-capacity resistor with a relatively simple configuration.
Can be made smaller and lighter. Furthermore, since the pilot arc current is made constant, the pilot arc can be stabilized. Furthermore, since the resistor has a low resistance and the pilot arc current is made constant, the voltage generated between the nozzle and the base metal can be kept to a level that does not cause electric shock even when the electrode and nozzle are short-circuited, resulting in safety. It has the effect of increasing the

[Brief explanation of drawings]

FIG. 1 is a circuit diagram showing an embodiment of the power supply of the present invention;
FIG. 2 is a circuit diagram of a conventional power supply. 12... Electrode, 13... Base material, 14... Nozzle, 15... Main arc current detector, 16... Main arc current setting device, 17... First comparison section, 18...
...Inverter (output control section) drive circuit, 20...
Pilot arc current detector, 21...Pilot arc current setting device, 22...Second comparison section, 2
3...Signal selection circuit, 24...Low resistance.

Claims (1)

[Claims] 1. A main arc current detector that detects the current value of the main arc circuit in a transition type plasma arc power supply that supplies power to the main arc circuit including the torch electrode and base material and the pilot arc circuit including the torch electrode and nozzle; Compare the pilot arc current detector that detects the current value of the pilot arc circuit, the low resistance inserted in the pilot arc circuit, the detection signal of the main arc current detector and the setting signal of the main arc current setter. a first comparison section that outputs a main arc current control signal; and a second comparison section that compares the detection signal of the pilot arc current detector and the setting signal of the pilot arc current setter and outputs a pilot arc current control signal. and a single output control unit that controls the output of the power supply so that the currents flowing through the main arc circuit and the pilot arc circuit reach their respective set values in accordance with the main arc current control signal and the pilot arc current control signal, A power source for a plasma arc, comprising a signal selection circuit that selectively inputs the main arc current control signal and the pilot arc current control signal to a drive circuit of the output control section.