JPH11170047A - Arc power source device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To surely judge whether a dc output circuit forms no load or arc load by detecting a primary current of an output transformer. SOLUTION: A power source device is composed of an input rectifier 2 which rectifies an AC power source, an output transformer 4 which is connected to this rectified dc output, a series circuit with a switching element 5 with which high frequency switching is performed, an output rectifier 11 with which an output of the output transformer 4 is rectified, and a reactor 13 with which the direct current outputted from this output rectifier is smoothed. An electric current detector 6 with which a primary current of the output transformer is detected, a first comparator 16 which outputs when a detected signal detected by this electric current detector and a first reference signal are compared and the preceding detected signal reaches the first reference signal, a switching element control unit 17 which inputs driving to the switching element 5, and at the same time, outputs a command signal commanding an off of the switching element 5 through output signal of the first comparator, a second comparator 22 which outputs when, further, a detected signal detected with the electric current detector 6 and a second reference signal are compared, and the command signal reaches a second reference signal, and a holding circuit 23 which holds a output of the second comparator, are provided.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an arc power supply controlled by a constant current, such as a power supply for welding, a power supply for cutting, and a power supply for lighting a discharge lamp, which are small and have a low DC output and a high current. Things.

[0002]

2. Description of the Related Art An arc power supply of this type is as follows. That is, the AC power supply is rectified by the input rectifier, and the rectified DC is rectified by the smoothing capacitor.
A series circuit of an output transformer and a switching element that performs high-frequency switching is provided on the smoothed DC, the switching element is switched at high frequency, and a high-frequency on / off alternating current is output to the output of the transformer. This AC is rectified by an output rectifier, smoothed by a reactor, and outputs DC. Further, a DC output current is detected by a current detector, and an error between the detection signal and an output setting signal for setting an output current value is amplified. The switching element is controlled by the error amplified signal, and the output current is controlled at a constant current. You.

However, in the above-described conventional power supply apparatus under constant current control, a current detector is provided in a DC circuit on a secondary side of a transformer, and a power supply used for welding, cutting, and lighting of a discharge lamp is used. The device has a problem that the current flowing through the DC circuit is large and the current detector becomes large.

Therefore, as shown in FIG. 3, a series circuit of an input rectifier 2 for rectifying an AC power supply to an arc power supply device, an output transformer 4 connected to a rectified DC output, and a switching element 5 for high-frequency switching. And the output transformer 4
An output rectifier 11 for rectifying the output of the output rectifier 11, a reactor 13 for smoothing with a direct current output from the output rectifier 11, and a current detector 6 for detecting a primary current of the output transformer 4;
A first comparator 16 that compares a detection signal detected by the current detector 6 with a reference signal of a first reference signal source and outputs an output signal when the detection signal reaches a reference value; Input a drive signal to the first comparator 16
A power supply device provided with a switching element control device 17 that outputs a command signal for commanding the switching element 5 to be turned off with the output signal of (1) is proposed.

In the proposed arc power supply,
When the switching element is turned on by a drive signal from the switching element control device 17, a current flows through the switching element 5. At this time, the output current gradually rises due to the leakage inductance of the output transformer 4 and the inductance of the reactor 13 and the like. When the detection signal of the current detector 6 reaches the reference value, the switching element 5 is turned off, and the current flowing on the primary side of the output transformer 4 becomes zero.
While the switching element 5 is on, a current flows from the output terminal 14 to a load (not shown). When the switching element 5 is turned off, the energy of the reactor 13 flows to the load via the flywheeling diode 12. The following is repeated sequentially.

Here, the average current flowing from the output terminal 14 to the load is Io, the current width between the peak and the peak is ΔI, and the peak current flowing through the secondary winding of the output transformer 4 is I2 (pea).
k), I2 (peak) = Io + (1/2) ×
ΔI.

On the other hand, the current flowing in the primary winding of the output transformer 4 is expressed as I1 (peak) = where n is the ratio of the number of primary windings to the number of secondary windings of the output transformer 4. nx I2 (pea
k), and I1 (peak) becomes I1 (peak) = n
× (Io + (１ ／) × △ I). Here, ΔI is small and substantially constant in a welding machine, a cutting machine, and a power supply for lighting an arc discharge lamp using an arc, and the current I1 (peak) flowing through the primary winding of the output voltage unit 4 is the output current Io. Will be proportional to

[0008]

However, an arc power supply used for welding, cutting, and lighting of a discharge lamp uses a high-frequency generator to facilitate arc starting. After the arc start, it is necessary to stop the operation of the high frequency generator. In addition, for welding and cutting, it is necessary to determine whether the DC output is no load or a closed circuit due to arc formation after the arc is started or after welding and cutting are completed.

[0009]

According to the present invention, there is provided an arc power supply device comprising: a series circuit including an input rectifier for rectifying an AC power supply, an output transformer connected to the rectified DC output, and a switching element for high-frequency switching. And an output rectifier for rectifying the output of the output transformer, and a reactor for smoothing the DC output from the output rectifier, wherein the current detector detects a primary current of the output transformer. A first comparator that compares a detection signal detected by the current detector with a first reference signal, and outputs an output signal when the detection signal reaches the first reference signal; A switching element control device for inputting a drive signal to the element and outputting a command signal for commanding the switching element to be turned off by an output signal of the comparator; A second comparator for comparing a detection signal detected by the detector with a second reference signal, and outputting when the detection signal reaches a second reference signal that is a smaller signal than the first reference signal; And a hold circuit for holding the output of the second comparator.

That is, an AC power supply is rectified by an input rectifier, a drive signal is applied to a switching element, and the switching element is turned on to output an alternating current to a secondary side of an output transformer. This AC is converted to DC by output rectification, smoothed by a reactor, and DC is output. here,
A primary current of the output transformer is detected by a current detector, and this detection signal is compared with a first reference signal by a first comparator. When the detection signal reaches the reference signal, the output signal is output from the comparator. Is output, and the switching element is turned off.
There is an approximately proportional relationship between the primary current of the output transformer and the output current of the power supply, and the power supply is controlled at a constant current.

Further, the detection signal detected by the current detector is compared with a second reference signal having a smaller current than the first reference signal, and when the detection signal reaches the second reference signal,
An output signal is output from the second comparator, and the output signal is held by the hold circuit.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described with reference to FIG. In FIG. 1, those having the same reference numerals as those in FIG. 3 indicate those having the same functions. The difference is that the detection signal of the primary current is detected in the conventional device shown in FIG. When a reference signal corresponding to the current is reached, a current detection device that outputs a signal indicating that the output current has flowed from the power supply device is added.

That is, reference numeral 21 denotes a second reference signal source corresponding to a current smaller than the peak current of the primary current.
Is a comparator that compares the reference signal with the current detection signal and outputs an output signal when the current detection signal reaches the reference signal. The output signal of the comparator 22 is input to the hold circuit 23, and the output signal of the comparator 22 is received and the hold circuit 2
3 holds. Although not shown, the output signal of the hold circuit 23 is used to stop the operation of the high frequency generator for facilitating the arc start when the load is used for welding, cutting, and lighting of the discharge lamp.

In FIG. 2, at time t1 when no load is connected to the output terminal 7, when the switching element 5 is turned on by a drive signal from the switching element controller 17, an exciting current flows through the output transformer 4. . This current is detected by the current detector 6, and the detection signal is
And the comparator 22 compares the reference signal. At this time, the detection signal is smaller than the reference signal.
“H” is continued as shown in FIG. Also, FIG.
As shown in (b), the hold circuit 23 also keeps "H".

At time t2 when a load is connected to the output terminal 5, the switching element 5 is turned on by a drive signal from the switching element control device 17, a current flows through the output transformer 4, and the output rectifier 11, the reactor 13, a current flows to a load (not shown) via the output terminal 7. At this time, I1 flows through the primary winding of the output transformer 4 as shown in FIG. The current flowing through the primary winding is detected by the current detector 6. This detection signal becomes larger than the reference signal as shown in FIG. 2A, and shifts from "H" to "L" from the comparator 22 as shown in FIG. 2B.
Then, the hold circuit 23 also shifts from “H” to “L”, and thereafter holds this “L”. This hold signal is used to stop the operation of the high frequency generator after the arc start. Further, after welding and cutting are completed, it can be determined whether the DC output is no load or a closed circuit due to arc formation.

In the above embodiment, one switching element provided on the primary side of the output transformer is used for controlling the output current. However, a two-stone Ford system using two switching elements is used. Is also good.

[0017]

The power supply device of the present invention detects the current flowing on the primary side of the output transformer, and can reliably determine whether the DC output circuit has no load or an arc load. Also, since the primary current of the output transformer is detected,
Power supplies used for welding, cutting, and lighting of discharge lamps can be made smaller.

[Brief description of the drawings]

FIG. 1 is a block diagram of an embodiment of an arc power supply device of the present invention.

FIG. 2 is a time chart of each part in FIG. 1;

FIG. 3 is a block diagram of a conventional arc power supply device.

[Explanation of symbols]

 Reference Signs List 2 input rectifier 4 output transformer 5 switching element 6 current detector 11 output rectifier 13 reactor 15 (first) reference signal source 16 (first) comparator 17 switching element control device 21 (second) reference power source 22 (second) comparator 23 hold circuit

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Takeshi Omura 2-14-3 Awaji, Higashiyodogawa-ku, Osaka-shi, Osaka Inside Sansha Electric Manufacturing Co., Ltd.

Claims (1)

[Claims] 1. An input rectifier for rectifying an AC power supply, a series circuit of an output transformer connected to the rectified DC output, and a switching element for high-frequency switching, and an output for rectifying the output of the output transformer. In an arc power supply device comprising a rectifier and a reactor for smoothing a direct current output from the output rectifier, a current detector for detecting a primary current of the output transformer, and a detection signal detected by the current detector And a first reference signal, and a first comparator for outputting an output signal when the detection signal reaches the first reference signal; a driving signal being input to the switching element; A switching element control device for outputting a command signal for commanding the switching element to be turned off by the output signal of the switching element; A second comparator that compares the reference signal and outputs the detection signal when the detection signal reaches a second reference signal; and a hold circuit that holds the output of the second comparator. And arc power supply.