JPH053679A - Current source inverter device - Google Patents

Abstract

(57) [Abstract] [Purpose] To make the rise and fall times of the load current of a current source inverter device that supplies an output to a load having a reactance component variable. A feedback capacitor 8 in which the charging polarity is inverted every time the polarity of the load current is inverted based on the switching of the inverter 5 and the output current of the inverter 5 is charged.
The diode rectifier 9 that rectifies the current flowing through the capacitor 8 and the auxiliary capacitor 10 that is variably set in capacity and that is charged by the output of the diode rectifier 9 to set the charging time constant of the feedback capacitor 8 are provided. The slope of the load current when the polarity is reversed is adjusted by the variable setting of the capacity of.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a current source inverter device for supplying a constant current controlled alternating current to a load having a reactance component.

[0002]

2. Description of the Related Art Conventionally, when color is generated on an object to be processed by surface modification such as alumite treatment of aluminum, a sine wave current or a rectangular wave current from an AC power source is applied to the object to be processed. .

When subjecting a workpiece having a reactance component to surface modification under constant current control, the sine wave current or the rectangular wave current is constant-current controlled and supplied to the workpiece. By the way, there is a current source inverter device as a power supply device suitable for this constant current AC power supply.

Then, the conventional current source inverter device is
Controlled rectifier such as thyristor rectifier, DC reactor for constant current control, and inverter are provided, and the conduction angle of the thyristor of the controlled rectifier is controlled so that the rectified output is a constant current to rectify the AC power source. Is supplied to an inverter via a DC reactor, and constant current controlled AC is output by the switching of the inverter.

[0005]

In the conventional current source inverter device, the rising and falling slopes of the output current based on the switching of the inverter are determined based on the circuit constants and the like and do not change. For this reason, when the power supply device for surface modification cannot change the rising and falling times, the slope of the rising and falling of the load current does not change, and there is a problem that the surface modification characteristics cannot be adjusted.

It is an object of the present invention to provide a current source inverter device capable of freely adjusting the characteristics of surface modification of an object having a reactance component.

[0007]

To achieve the above object, in the current source inverter device of the present invention, the charge polarity is inverted every time the polarity of the load current is inverted based on the switching of the inverter, and the output of the inverter is output. A feedback capacitor charged by a part of the current, a diode rectifier that rectifies the current flowing through the capacitor, and an auxiliary capacitor that is variably set and charged by the output of the diode rectifier to set the charging time of the feedback capacitor. By adjusting the capacity of the auxiliary capacitor, the slope of the load current at the time of polarity reversal is adjusted.

In order to effectively use the energy stored in the auxiliary capacitor, it is desirable to provide an insulating transformer between the feedback capacitor and the diode rectifier and to inject the energy stored in the auxiliary capacitor into the input side of the inverter.

[0009]

In the current source inverter device of the present invention constructed as described above, the polarity of the feedback capacitor is reversed by a part of the output current of the inverter every time the polarity of the load current is reversed by the switching of the inverter. After being charged, the load current converges to a steady value after this charging.

Further, the current flowing through the feedback capacitor is rectified by the diode rectifier and supplied to the auxiliary capacitor, and the capacity (charging voltage) of this capacitor determines the capacity (time constant) of the feedback capacitor.

By variably setting the capacity of the auxiliary capacitor, the time taken for the capacity of the feedback capacitor to change and the load current to converge to a steady value changes, so that the load current can rise and fall freely. It is variably set.

Further, when an insulating transformer is provided between the feedback capacitor and the diode rectifier to inject the stored energy of the auxiliary capacitor into the input side of the inverter, the insulating transformer separates the input side and the output side of the inverter from each other. The stored energy can be effectively used.

[0013]

EXAMPLES Examples will be described with reference to FIGS. 1 to 3.

(First Embodiment) First, a first embodiment will be described with reference to FIGS. As shown in FIG. 1, a commercial three-phase AC power source is supplied from the input terminals 1a, 1b, 1c to the primary side of the input transformer 2, and the transformer 2
The output on the next side is supplied to the controlled rectifier 3 having the bridge circuit configuration of the thyristors 3a to 3f.

This control rectifier 3 comprises thyristors 3a to 3f.
The secondary side output is rectified by controlling the conduction angle of (1) to form a constant current rectified output. Further, the rectified output of the control rectifier 3 is smoothed by the direct current reactor 4 for constant current control, and a current id converted into a substantially predetermined value Id shown in FIG. 2A is formed and supplied to the inverter 5.

The inverter 5 is composed of a bridge circuit of thyristors 5a to 5d as self-arc extinguishing type control elements, and the thyristors 5a and 5d and the thyristors 5b and 5c are switched in opposite phases to convert direct current to alternating current. Is supplied to the load 7 via the output transformer 6. The load 7 has a resistance component Ro and a reactance component Lo.

If the output current of the inverter 5 is made to be a complete rectangular wave current, the thyristors 5a to 5d may be destroyed due to the simultaneous ON state and the like, so that the rising and falling of the output current are trapezoidal. The inverter 5 is switching-controlled in the cycle T so as to obtain the characteristics.

Further, when the thyristors 5b and 5c change from OFF to ON, the commutation from negative to positive is defined, and when the thyristors 5a and 5d change from OFF to ON, the commutation from positive to negative is defined. Due to the commutation from negative to positive, the thyristor 5b passes from the thyristor 5b through the primary side of the output transformer 6.
A current flows to the load 7, and at this time, the load 7 is supplied with the output voltage eo and the output current (load current) io having the polarities shown in FIG.

In addition, the commutation from positive to negative causes the thyristor 5d from the thyristor 5a via the primary side of the output transformer 6.
Current flows to the load 7, and the polarities of the output voltage eo and the output current io supplied to the load 7 are reversed at this time. Then, the output current io is, as shown in FIG.
The trapezoidal wave characteristic alternates between Io and -Io.

Next, the detailed operation during commutation will be described.
For example, when the commutation from negative to positive occurs at the time tn of the output current io = -Io and the thyristors 5a and 5d are turned off, the output current io is mainly the reactance component Lo of the load 7.
Time t ₀ down from -Io by the energy release of the 0
Reach

An electromotive force proportional to the reactance component Lo is generated on the primary side of the output transformer 6, and the current of this electromotive force is supplied to the feedback capacitor 8 as the current irg in FIG.

This capacitor 8 is composed of thyristors 5a and 5d.
During the ON period, the battery is charged and held in the polarity shown in FIG. 1, and is reversely charged and discharged by supplying the current irg. Further, the thyristors 5b and 5c are turned on and a part of the output current of the inverter 5 is supplied to the feedback capacitor 8 as the current irg.
The capacitor 8 is charged to the opposite polarity shown.

On the basis of the output of the inverter 5, an output voltage eo and an output current io having the illustrated polarities are generated in the output transformer 6, and the current io flows through the load 7. At this time, the output current io rises to a steady value + Io with a slope according to the time constants of the feedback capacitor 8 and the load 7, and converges.

Further, the current irg decreases as the feedback capacitor 8 is charged as shown in FIG. 2C, and when the capacitor 8 is fully charged at the time tp, the current irg stops flowing thereafter. At the next commutation from positive to negative, the output current io decreases from the steady value + Io to 0, the current irg having a polarity opposite to that in FIG. 1 flows, the capacitor 8 is charged to the polarity shown, and the output The current io falls to the steady value −Io.

Then, the rise of the output current io during commutation,
Since the slope of the fall depends on the time constants of the feedback capacitor 8 and the load 7, if the capacitance (time constant) of the feedback capacitor 8 is varied to change the charging time of the capacitor 8, the rise and fall of the output current io The time changes and the slope changes. Therefore, the diode rectifier 9 having a bridge circuit configuration of the diodes 9a to 9d, the auxiliary capacitor 10, and the variable resistor 11 for adjusting the time constant are provided, and the rectifier 9 supplies the current ir.
Full-wave rectify g.

By this rectification, the current irg flows through the diode 9a, the parallel circuit of the capacitor 10 and the variable resistor 11, the diode 9d, and the capacitor 8 when the polarity is as shown in FIG. 1, and when the polarity is opposite to that shown in FIG. irg flows through the capacitor 8, the diode 9b, the parallel circuit of the capacitor 10 and the variable resistor 11, and the diode 9c.

Then, the capacity (charging voltage) of the capacitor 10 changes depending on the resistance value of the variable resistor 11, and the charging time of the capacitor 8 at the time of commutation changes due to the change of this capacity. Therefore, by changing the resistance value of the variable resistor 11, the rising and falling slope characteristics of the output current io change, and if the load 7 is a surface-modified object, the modification characteristics can be changed freely. Can be adjusted.

Since the auxiliary capacitor 10 is continuously charged with the current irg, its charging voltage (voltage between both ends) ec
Is the average value E of the one-dot chain line as shown by the solid line in FIG.
It is almost equal to c. Further, the output voltage eo changes as shown in (e) of FIG.

Further, in order to keep the rate of change of the rising and falling of the output current io constant, T ₁ = T ₂ is set. By the way, the output transformer 6 may be omitted. Also,
The inverter 5 is a GT instead of the thyristors 5a to 5d.
You may form using O and IGBT.

(Other Embodiments) Next, a second embodiment will be described with reference to FIG. In FIG. 3, the same reference numerals as those in FIG. 1 indicate the same or corresponding ones. The difference from FIG. 1 is that an insulating transformer 12 is provided between the feedback capacitor 8 and the diode rectifier 5, and instead of the variable resistor 11 of FIG. The energy stored in the auxiliary capacitor 10 is transferred to the inverter 5
The point is that a DC reactor 13 to be injected to the input side of and a variable resistor 14 for adjusting the time constant are provided.

The capacitance of the auxiliary capacitor 10 is varied by adjusting the variable resistor 14, and the capacitance of the feedback capacitor 8 is variably set as in the case of FIG.

Further, the energy stored in the auxiliary capacitor 10 is not discharged by the variable resistor 11 as shown in FIG.
It is injected into the input side of the inverter 5 via the DC reactor 13 and the variable resistor 14, and the utilization efficiency of electric power is improved. The isolation transformer 12 is provided to separate the input side and the output side of the inverter 5.

[0033]

Since the present invention is configured as described above, it has the following effects. Since the feedback capacitor 8, the diode rectifier 9, and the auxiliary capacitor 10 are provided, every time the polarity of the load current is inverted by the switching of the inverter 5, the feedback capacitor 8 is inverted in polarity and charged by a part of the output current of the inverter 5. After the charging, the negative current converges to a steady value, and the current flowing through the feedback capacitor 8 is rectified by the diode rectifier 9 and supplied to the auxiliary capacitor 10.
The capacitance (time constant) of the feedback capacitor 8 is determined by the capacitance of.

By variably setting the capacity of the auxiliary capacitor 10, the time until the capacity of the feedback capacitor 8 changes and the load current converges to a steady value changes, and the slope of the rise and fall of the load current changes. The characteristics of the surface modification can be freely set by applying the load 7 to the power supply device of the surface modification, which is an object to be processed.

Further, when the insulating transformer 12 is provided between the feedback capacitor 8 and the diode rectifier 9 and the stored energy of the auxiliary capacitor 10 is injected into the input side of the inverter 5, the insulating transformer 12 causes the input side and the output side of the inverter 5. The energy stored in the auxiliary capacitor 10 can be effectively used by separating the electric power and the electric power from each other, and the power use efficiency can be improved.

[Brief description of drawings]

FIG. 1 is a connection diagram of a first embodiment of a current source inverter device of the present invention.

2A to 2E are waveform diagrams for explaining the operation of FIG.

FIG. 3 is a connection diagram of a second embodiment of the present invention.

[Explanation of symbols]

3 control rectifier 4,13 DC reactor 5 inverter 8 Feedback capacitor 9 diode rectifier 10 Auxiliary capacitor 12 Isolation transformer

Claims (2)

[Claims] 1. A constant current rectified output of a controlled rectifier is supplied to an inverter via a direct current reactor for constant current control,
In a current source inverter device which forms an alternating current by switching of the inverter and supplies it to a load having a reactance component, the charging polarity is reversed every time the polarity of the load current is reversed based on the switching of the inverter, and one of the output currents of the inverter is reversed. And a diode rectifier that rectifies the current flowing through the feedback capacitor, and an auxiliary capacitor that is variably set and charged by the output of the diode rectifier to set the charging time constant of the feedback capacitor. A current source inverter device, comprising: a variable-capacitance setting of the auxiliary capacitor to adjust a slope of the load current when the polarity is reversed. 2. The current source inverter device according to claim 1, wherein an insulating transformer is provided between the feedback capacitor and the diode rectifier, and the stored energy of the auxiliary capacitor is injected into the input side of the inverter. .