KR0124614Y1 - Dc-ac converter - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a DC-AC conversion circuit in a ring signal generation circuit of an exchange system.

2. The technical problem the invention is trying to solve

In the ring signal generating circuit of the switching system, the DC-AC conversion circuit for stabilizing the output change is provided by having the same characteristics for the change of the environmental temperature.

3. Summary of solution of design

The DC-AC conversion circuit includes a control signal generator for generating a half-sine wave and a pulse wave, a transformer for electrically insulating the input and output from the compensator for compensating the anti-sine wave and outputting a comparison signal, A smoothing part that charges and discharges a voltage induced on the secondary side to smooth the dummy part, a dummy rod that induces a forced discharge of energy charged in the smoothing part, and has the same characteristics as the compensating part in an environmental temperature change, A feedback unit for feeding back the voltage induced on the secondary side, an amplifier for comparatively amplifying and outputting the comparison signal and the feedback signal, a pulse width converter for adjusting a pulse width in response to the amplified signal, and one of the transformers A switching unit connected to the vehicle side and the output terminal of the pulse width converter to induce a predetermined voltage from the primary side of the transformer to the secondary side. An AC switch connected to the secondary side of the transformer, an AC switch for switching the phase of the induced signal at predetermined intervals, and a switching operation of the AC switch in response to the pulse wave of the control signal generator. And a switching control unit for controlling the control unit and a load control unit for detecting a signal output from the feedback unit and controlling the load to be connected to the AC switch unit only at zero potential.

4. Important uses of the devise

When the DC-AC conversion circuit is implemented, it is used to stabilize the output voltage even if the ambient temperature changes.

Description

DC-AC conversion circuit.

1 is a diagram showing a conventional DC-AC conversion circuit.

2A and 2B are graphs showing relative current transfer ratios according to environmental temperature changes of a photo coupler.

3 is a view showing a DC-AC conversion circuit in the present invention.

Figure 4 is a waveform diagram showing the output waveform according to the change in environmental temperature in the present invention.

* Explanation of symbols for main parts of the drawings

20: control signal generator 4: transformer

8: PWA conversion switching unit 9, 10, 39: photo coupler

11 filter and dummy rod portion 14 AC switch

Q11: N-channel FET OP4: Operational Amplifier

12: feedback unit 13: compensation unit

The present invention relates to a ring signal generation circuit in an exchange system. In particular, the ambient temperature in converting a direct current (DC) input power source into a low frequency sine wave AC power source using pulse width modulation (PWM) is output. The present invention relates to a circuit having improved output characteristic variation due to a change.

In general, there are several methods for generating ring signals in the ring signal generation circuit of an exchange system. Accordingly, in 1995 Patent No. 16474 (1995.6.20) filed by the applicant of the present application, a ring signal generation circuit is disclosed in detail. The ring signal generation circuit in the above-mentioned patent application No. 95-16474 reduces the size of the keyphone system by miniaturizing the transformer and simplifying the configuration and control of the circuit. Therefore, the present invention is directed to a part of the control and feedback related circuit in the ring signal generation circuit of the exchange system of Patent Application No. 95-16474.

Hereinafter, a diagram showing a DC-AC conversion circuit for a control and feedback related circuit in a conventional ring signal generation circuit is shown in FIG. 1, which is disclosed in Patent Application Nos. 95-196474.

The DC-DC transformer consists of a transformer 4, a filter and dummy rod 11, a feedback 12, an amplifier OP4, a PWM converter 8, a current sensor 3, and a switch 2. In the PWM converter 8, the output voltage is varied according to the level of the amplified signal of the operational amplifier OP4 to which the PWM converter is applied. The anti-sine wave output from the control signal generator 20 is applied to the non-inverted end of the operational amplifier OP4, and the photo coupler 9 of the feedback unit 12 feeds the signal of the transformer secondary side to turn on / off the phototransistor. The feedback signal is applied to the inverting stage of the operational amplifier OP4 and compared and amplified. Thus, the output signal of the PWM converter 8 controls the duty by turning the switch 2 on and off. As the amplification signal of the operational amplifier OP4 increases, the duty increases. As the amplification signal decreases, the duty also decreases. When the switch 2 is turned on, energy is accumulated in the primary winding of the transformer 4 by magnetization inductance. Next, when switch 2 is turned off, the accumulated energy is released to the secondary winding to conduct the diode D11. At this time, the capacitor C12 smoothes the pulsed energy transmitted through the diode D11 to obtain a waveform whose amplitude is amplified in proportion to the anti-sine wave generated in the control signal generator 20. In addition, the photocoupler 10 and the AC switch 14 are phase switching circuits. In response to a predetermined control signal 24, the phase of the full wave rectified waveform output from the filter and the dummy rod unit 11 is changed at a predetermined period so that the sine wave is output. In this case, the control signal 24 is a pulse wave generated by the control signal generator 20.

That is, in order to obtain a waveform amplified in proportion to the anti-sine wave of the control signal generator 20 on the secondary side of the transformer 4, the full-wave rectified anti-sine wave signal generated by the control signal generator 20 is input to the non-inverted terminal of the acid amplifier OP4. The feedback signal in which the sink SINK current of the photocoupler 9 is voltage-converted by the resistor R23 is input to the inverting end of the operational amplifier OP4.

The waveform relationship at the anti-sine wave, the C point, and the D point is expressed by Equation 1 below.

In the game, the withdrawal voltage V _CD is a voltage between point C and D, and h _FE 1 is a current transfer rate for the phototransistor of photocoupler 9. Acting as a variable in Equation 1 is V ₂₁ . Since V ₂₁ is changed sinusoidally, a two-wave rectified sinusoidal wave of the output waveform may be generated. However, the problem in Equation 1 is the current transfer rate (h _FE 1) for the phototransistor.

2A and 2B are graphs showing environmental temperatures and relative current transfer rates according to types of photocouplers.

FIG. 2A is a graph of PC 356 (one type of port coupler), and FIG. 2B is a graph of PC 452 (one type of port coupler). Referring to FIGS. 2A and 2B, the variation in the current transfer rate from the environmental temperature of 0 ° C. to the environmental temperature of 60 ° C. is 40%. That is, the peak value of the output waveform fluctuates about 40% according to the change of the environmental temperature. The ring signal of the exchange system has a peak voltage of 120V, so if there is a 40% variation, the voltage rises up to 168V. Therefore, if you design with this problem, you have to increase the parts rating. That is, since the relative current transfer rate with respect to the environmental temperature is nonlinear, the output value changes according to the environmental temperature.

Therefore, an object of the present invention is to provide a DC-AC conversion circuit for stabilizing the output change by having the same characteristics for the environmental temperature change in the ring signal generation circuit of the exchange system.

In the DC-AC converter circuit for achieving the objects of the present invention, a control signal generator for generating a half-sine wave and a pulse wave, a compensation unit for outputting a comparison signal by temperature compensation of the anti-sine wave, input and output A transformer electrically insulating the acid, a smoothing part that charges and discharges a voltage induced on the secondary side of the transformer, a smoothing part, a dummy rod that induces a forced discharge of charged energy of the smoothing part, and the environmental temperature change A feedback unit having the same characteristics as the compensating unit and feeding back a voltage induced to the secondary side of the transformer, an amplifying unit comparing and amplifying the comparison signal and the feedback signal, and outputting a pulse width in response to the amplified signal; A pole width converter to be adjusted, and connected to the primary side of the transformer and the output end of the pulse width converter to the primary side of the sang transformer. DC-DC converter comprising a switching unit for inducing a predetermined voltage to the secondary side of the controller, an AC switch connected to the secondary side of the transformer to switch the phase of the signal induced at a predetermined period, and the control signal generator. And a switching control unit for controlling a switching operation of the AC switch in response to the spar, and a load control unit for detecting a signal output from the feedback unit and controlling the load to be connected to the AC switch unit only at zero potential. .

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that like elements in the figures represent like reference numerals wherever possible.

The DC-DC converter is composed of the amplifier OP4D, the PWM converter 8, the switch 2, the transformer 4, the filter and the dummy load 11 and the feedback unit 12 in the same manner as in the prior art. The anti-sine wave 21 generated by the control signal generator 20 is applied to the compensator 13, and the pulse wave 24 is input to a phase shift circuit composed of a photocoupler 10 and an AC switch 14. Thus, in response to the pulse wave 24, the phase of the full-wave rectified waveform output from the filter and the dummy load unit 11 is switched at a predetermined period so that the sine wave is output. The compensator 13 includes a photo coupler 39 used for temperature compensation and resistors R32, R33, and R35 to have the same characteristics as the feedback unit 12. In addition, the feedback unit 12 detects the full wave rectified sine wave on the secondary side of the transformer 4 and uses the resistor R22, which is used to set an appropriate value of the photocoupler 9D output voltage V _CD used to input the inverted end of the operational amplifier OP4, It consists of R23 and R25. The operational amplifier OP4 for comparing the comparison signal of the compensator 13 and the feedback signal of the feedback unit 12 to adjust the duty by the PWM converter 8 and the switch 2 inputs the feedback signal to the inverting stage and the comparison signal to the non-inverting stage. .

The anti-sine wave 21 output from the control signal generator 20 is output through the resistor R35 and the photo coupler 39, and the comparison signal input to the non-inverted terminal of the operational amplifier OP4 is shown in Equation 2 below.

Here, the current transfer ratios of the porter couplers 9 and 39 are denoted by h _FE1 and h _FE2 , respectively. The secondary voltage of the transformer 4 is changed by varying the output duty of the PWM converter 8 and the switch 2 while varying the output eye of the operational amplifier OP4 by the signal according to Equation 2 above. The sinusoidal voltage is fed back through the resistor R25 and the photocoupler 9 to stabilize the full-wave rectified sinusoidal voltage. In this case, the relation between the output voltage V _CD and the voltage of the feedback signal input to the inverting terminal of the operational amplifier 4 is expressed by Equation 3 same.

Summarizing Equation 3 with respect to the output voltage V _AC , Equation 4 is as follows.

The waveforms of the two input terminals of the operational amplifier OP4 are the same, and if Equation 2 is substituted into the inverting terminal of Equation 4, Equation 5 is obtained.

Here, if the resistor R22 and the resistor R32 are used as the same resistance value, and the resistors R23 and R33 are used as the same resistance value, Equation 5 is as shown in Equation 6 below.

In the same component as that of the photocoupler 9 and the photocoupler 39, since the current shear ratios h _FE1 and h _FE2 are the same, the relationship between the comparison signal waveform and the output waveform V _CD can be expressed by Equation 7 below.

As shown in Equation 7, if the comparison signal is input to the non-inverting terminal of the operational amplifier OP4 via the same photo coupler 39 as the photo coupler 9 used for the secondary voltage detection of the transformer 4, Instability can be eliminated.

FIG. 3 is a waveform diagram showing an output waveform according to a change in environmental temperature in the present invention. When the conventional DC-AC conversion circuit is used, the output waveform is changed according to the change of the environmental temperature. That is, when the environmental temperature is 25 ° C to 60 ° C, the peak value of the conventional DC-AC conversion circuit output waveform becomes large. However, in the DC-AC conversion circuit according to the present invention, the output waveform does not change significantly even if the environmental temperature is varied. As described above, although the feedback signal changes depending on the ambient temperature, the comparison signal also changes to the same level so that there is no effect on the output waveform.

As described above, the comparison signal input to the inverting terminal of the operational amplifier OP4 is input through the temperature compensation photocoupler 39 to compensate for the temperature characteristic of the photocoupler 9 used for the output voltage detection to stabilize the output voltage V _CD . do. Therefore, a constant output waveform can be obtained even with a change in the ambient temperature.

Claims (3)

A DC-AC conversion circuit comprising: control signal generating means for generating a half-sine wave and a pulse wave, compensation means for outputting a comparison signal by temperature compensating the half-sine wave, a transformer for electrically insulating between input and output, Smoothing means for charging and discharging the voltage induced in the secondary side of the transformer to smooth, a dummy rod for inducing a forced discharge of the energy charged in the smoothing means, and changes in environmental temperature and the same characteristics as the compensation means Feedback means for feeding back the voltage induced on the secondary side of the transformer, amplifying means for comparing and amplifying the comparison signal and the feedback signal, a pulse width converter for adjusting a pulse width in response to the amplified signal, and Connected to the primary side of the transformer and the output terminal of the pulse width converter, a predetermined voltage from the primary side to the secondary side of the transformer DC-DC conversion means comprising switching means for inducing, an AC switch connected to the secondary side of the transformer to switch the phase of the signal induced at a predetermined period, and the AC in response to the pulse wave of the control signal generating means. A switching control means for controlling a switching operation of the switch, and a load control means for detecting a signal output from the feedback means and controlling the load to be connected to the AC switch means only at zero potential. . 2. The apparatus of claim 1, wherein the feedback means comprises: a first resistor connected to the secondary side of the transformer, a first light emitting diode connected to the first resistor and an anode end, and a first light emitting diode operated by the first light emitting diode; A first light receiving transistor, a second resistor between the emitter terminal and the ground terminal of the first light receiving transistor, a third resistor connected to the collector terminal and the emitter terminal of the first light receiving transistor, and an emitter terminal of the first light receiving transistor DC-AC conversion circuit, characterized in that connected to the inverting end of the amplifying means. The said compensation means is the same characteristic as the said 4th resistance connected with the said control signal generation means, and the said 1st light emitting diode, The said 1st resistance and an anode terminal are connected. The second light emitting diode, the second light receiving transistor having the same characteristics as the first light receiving transistor, and operated by the second light emitting diode, and the same as the second resistance value, the emitter terminal and the ground of the second light receiving transistor A fifth resistor between the stages, the same as the third resistor value, a sixth resistor connected to the collector stage and the emitter stage of the second light receiving transistor, and the emitter stage of the second light receiving transistor are connected to the non-inverting end of the amplifying means. DC-AC conversion circuit, characterized in that.