KR200337815Y1 - Output compensation circuit of trans - Google Patents

Abstract

The present invention relates to an output compensation circuit of a transformer using an RC charging / discharging circuit, and includes a DC power source for supplying a DC power source converted from an AC power source or a DC power source from the battery 1, and a DC power source from the DC power source. A square wave generator 2 that receives two square waves having different phases from each other and a current flowing through the primary windings L1 and L2 of the transformer 4 by receiving a square wave from the square wave generator 2. The switching section 3 for determining the direction in which the flow flows, and the DC power output from the DC power source in accordance with the driving of the switching section 3, the primary winding (L1) (L2) and the secondary winding (L3) ( And a transformer (C) and a capacitor (C) connected in series with both ends of the transformer (4) for transforming and outputting the square wave by the winding ratio of L4) and the secondary winding (L4) of the transformer (4). Of square waves output from the secondary winding L4 of (4). The RC charge / discharge circuit 5 compensates the square wave output of the transformer 4 close to the sine wave waveform by increasing the rise time of the square wave below the center point and extending the fall time of the square wave above the center point.

Therefore, according to the present invention, an output waveform that can be used as a sine wave in various electronic products can be obtained without providing a separate sine wave generation circuit or a conversion circuit.

Description

Output compensation circuit of transformer using RF charging and discharging circuit

The present invention relates to an output compensation circuit of a transformer using an RC charging and discharging circuit, and more particularly, an RC to convert a square wave output from a transformer to a sine wave using a simple RC charging and discharging circuit. The present invention relates to a transformer output compensation circuit using a charge / discharge circuit.

Conventional inverters (inverters) are mostly configured to convert DC power into AC power. Accordingly, in order to convert DC power into AC power, a separate inverter must be purchased. In addition, a device for converting a DC power source into a commercial AC power source is very complicated in structure and high in price.

That is, patent application No. 81-6977 (power converter) is configured to exchange power between AC and DC using a full-wave bridge circuit, but it is composed only of a complex configuration for power conversion, finally output There is no description of the configuration that compensates for the power supply.

In addition, Patent Application No. 85-7786 (Current type power converter using a self-defense element) has an AC power connected to the input side, an inverter connected to the output side via a DC reactor, and detected a power failure of the AC power. It has a DC power supply that can supply and recharge DC power from the battery to the inverter at the time, but it has only a complicated configuration for supplying and refluxing DC power in case of power failure. There is no configuration to compensate.

In other words, there is a problem that the above-described configuration for power conversion or the configuration for preparing for power failure is complicated, so that the manufacturing process is long and the price is increased.

In consideration of the above, the present invention sets a peak value of the output power by the winding ratio of a transformer and does not include a separate sine wave generation circuit or a conversion circuit. It is an object of the present invention to provide an output compensation circuit using an RC charging / discharging circuit which can compensate a square wave output from the secondary winding of a transformer to be close to a sine wave by charging / discharging of the RC charging / discharging circuit of the circuit.

1 is a circuit diagram showing an output compensation circuit of a transformer using an RC charge and discharge circuit according to the present invention.

FIG. 2 is a time chart showing an output state at each node of FIG.

※ Explanation of code about main part of drawing ※

1 battery 2 square wave generator

3: switching unit 4: transformer

5: RC charge and discharge circuit BD: bridge diode

R, R1, R2: resistors FET1 to FET4: FET

C: Capacitor SW1, SW2: Switch

The present invention for achieving the above object is, a direct current power source for supplying a direct current power source from a direct current power source or a battery converted from an AC power supply, and two having a different phase by receiving a direct current power supply from the direct current power source A square wave generator for generating two square waves, a switching unit configured to receive a square wave from the square wave generator and determine a direction in which a current flowing in the primary windings L1 and L2 of the transformer flows; A transformer using an RC charging / discharging circuit including a transformer for converting a DC power output from a DC power source into a square wave by the turns ratio of the primary windings L1 and L2 and the secondary windings L3 and L4. An output compensating circuit comprising a resistor and a capacitor connected in series with both ends of the secondary winding L4 of the transformer, and connected to the secondary windings L3 and L4 of the transformer. And an RC charging / discharging circuit which compensates the square wave output of the transformer to be close to the sine wave waveform by lengthening the rising time of the square wave below the center point and extending the falling time of the square wave above the center point. do.

Hereinafter, with reference to the accompanying drawings, a specific embodiment of the present invention will be described in detail.

Referring to FIG. 1, an AC power source is connected to a primary winding of a transformer T, and a bridge diode BD rectifying AC power to a secondary winding of the transformer T and supplying the rectified AC power to the battery 1. ) Is connected. At this time, the switch SW1 serves to select the output of the secondary winding of the transformer T supplied to the bridge diode BD when the level of the AC power supplied to the primary winding of the transformer T changes.

The DC power output from the battery 1 is connected to supply the connection point of the primary windings L1 and L2 of the transformer 4 through the switch SW2, and the DC power charged in the battery 1 is supplied. It is connected to supply a square wave generator 2 for generating a 60 Hz square wave as a reference for converting the power into an AC power source, the square wave output of the square wave generator 2 is a resistor (R1) (R2) Through the gates of the field effect transistors FETs FET1 to FET4, respectively.

One end of the FET (FET1, FET2) and one end of the FET (FET3, FET4) are respectively connected to both ends of the primary winding (L1) (L2) of the transformer (4), the secondary winding of the transformer (4) L3 and L4 are configured with output terminals for outputting 110V or 220V AC power. Here, the square wave below the center point among the square waves output by connecting the RC charging / discharging circuit 5 composed of the resistor R and the capacitor C to the secondary winding L4 of the transformer 4 to which the AC power of 110V is output. By increasing the rising time of the square wave and the falling time of the square wave above the center point, the square wave output of the transformer 4 is compensated to be close to the sine wave waveform.

The operation of the present invention configured as described above will be described.

First, in the battery 1, when the DC power of the battery 1 is completely discharged or when the DC power of the battery 1 is not charged to the maximum capacity (for example, 12V, 100AH), the bridge diode ( The charging of the power via BD) is performed.

In more detail, AC power from the outside is lowered to a predetermined level (12V) by the transformer T and then supplied to the bridge diode BD, which rectifies the lower level AC power to DC power to the battery 1. Since the AC power is supplied, the battery 1 is charged with the DC power.

Here, the switch SW1 is an AC power applied to the bridge diode BD when an abnormality occurs in an AC power input to the primary winding of the transformer T and is input at an excessively high level or at an extremely low level. In consideration of the fact that the level of the DC power finally charged to the battery 1 changes as the level changes, the output power output from the secondary winding of the transformer T is selected.

When the switch SW2 is turned "on" while the DC power is charged to the battery 1 in this manner, the DC power supply as shown in FIG. 2A causes the primary winding L1 (of the transformer 4) ( It is supplied to the connection point of L2) and the square wave generation part 2, respectively.

Then, the square wave generator 2 generates a 60 Hz square wave as a reference for converting the DC power charged in the battery 1 into the AC power as shown in FIG. And the resistor R2 are supplied to the gates of the FETs FET1 to FET4, respectively.

Here, between the square wave supplied to the gates of the FETs FET1 and FET3 and the square wave supplied to the gates of the FETs FET3 and FET4, a predetermined phase (as shown in FIG. 2B and FIG. T1) and has a predetermined phase T2 difference between their "high" level and "low" level.

In other words, since there is a predetermined phase T1 difference between the square wave supplied to the gates of the FETs FET1 and FET3 and the square wave supplied to the gates of the FETs FET3 and FET4, the FETs FET1 and FET3 and FET3. And FET4 are driven to alternately.

As a result, the direct current power supply of the battery 1 being supplied to the connection point of the primary windings L1 and L2 of the transformer 4 has a waveform as shown in FIGS. 2 (C) and 2 (D). The primary winding L1 and the other winding L2 and the FETs (FET1, FET3) and FETs (FET3, FET4) of the flow to ground. At this time, there is also a predetermined phase T3 difference between the primary winding L1 of the transformer 4 and the DC power flowing through the other winding L2 as shown in FIG. 2D and 2E. It can be seen.

In this way, since a power source such as (D) (E) of FIG. 2 flows in different directions to the primary winding L1 of the transformer 4 and the other winding L2, the secondary winding L3 of the transformer 4 ( In L4), an AC power supply as shown in Fig. 2F can be obtained. Of course, different output terminals have different AC power levels.

Furthermore, when an AC power source such as (F) of FIG. 2 output from the secondary windings L3 and L4 of the transformer 4 passes through the RC charging / discharging circuit 5, the RC charging / discharging circuit 5 may be removed. The charging and discharging compensates the phase of the AC power supply as shown in FIG. 2F and outputs the AC power similar to a sine wave as shown in FIG. In other words, the square waves below the center point among the square waves output from the secondary windings L3 and L4 of the transformer 4 are square waves by the charging / discharging operation of the RC charging / discharging circuit 5 as shown in FIG. While the rise time of the square wave is longer than the center point, the square wave is deformed to be close to the sine wave as the falling time of the square wave is increased by the charging / discharging operation of the RC charging / discharging circuit 5 as shown in FIG. will be.

Preferably, the level of the DC power output from the battery 1 is detected in the square wave generator 2, and the level of the DC power is detected below a predetermined voltage (for example, 2V, etc.). In this case, the square wave signals supplied to the gates of the FETs FET 1 to FET 4 are not generated, thereby preventing the AC power of low level from being output from the secondary windings L3 and L4 of the transformer 4 in advance. It is.

Therefore, according to the present invention, it is possible to obtain an output waveform that can be used as a sine wave in various electronic products from a DC power supply without providing a separate sine wave generation circuit or a conversion circuit.

Although the present invention has been described in detail only with respect to the embodiments described, it will be apparent to those skilled in the art that various modifications and changes are possible within the technical spirit of the present invention, and such modifications and modifications belong to the appended utility model claims. will be.

Claims (1)

A DC power source for supplying DC power converted from an AC power source or a DC power source from the battery 1, and a square wave generator for generating two square waves having different phases by receiving DC power from the DC power source (2) ), A switching unit 3 which receives a square wave from the square wave generator 2 and determines a direction in which a current flowing in the primary windings L1 and L2 of the transformer 4 flows, and the switching unit 3 And a transformer 4 for transforming the DC power output from the DC power source into a square wave by the turns ratio of the primary windings L1, L2 and the secondary windings L3, L4. In the output compensation circuit of the transformer using the RC charging and discharging circuit, A square wave which is composed of a resistor R and a capacitor C connected in series at both ends of the secondary winding L4 of the transformer 4, and is output from the secondary winding L3 and L4 of the transformer 4. Further comprising a RC charging and discharging circuit (5) for increasing the rise time of the square wave below the center point and the fall time of the square wave above the center point to compensate the square wave output of the transformer (4) close to the sine wave waveform. Output compensation circuit of the transformer using the RC charging and discharging circuit.