DE3501052A1 - Converter circuit - Google Patents

Abstract

A switched-mode power supply for the power supply of video apparatuses, or a potential-isolated DC converter contains on the primary side an electronic switch (T1) which is connected in series with the primary winding of a converter transformer (Tr1). During opening and closing of the electronic switch (T1), voltages are induced on the secondary side of the circuit, which is DC-isolated from the primary side, which voltages are then rectified and produce a supply voltage or a plurality of supply voltages. Said voltage must be stabilised by a control loop. It is compared with a constant reference voltage and the adjusting signal thus formed is supplied after amplification to a pulse-duration modulator (18). The latter produces a rectangular-waveform signal whose duty ratio contains the adjusting information. They [sic] are passed via a control transformer (Tr2), which is likewise DC-isolated, to the primary side and are used there as control variables for the electronic switch. The rectangular-waveform signal is supplied to a controllable RF oscillator (20) and governs its signal amplitude. The RF signal can pass to the primary side using a simple and small transformer (Tr2). It is there supplied to a simple envelope-curve demodulator which reproduces the pulse-duration-modulated control variable. <IMAGE>

Description

Converter circuit

The invention relates to a converter circuit according to the preamble of claim 1.

Such a converter circuit is e.g. a switching or converter power supply, that is used to supply power to televisions or video recorders. On the through A converter transformer separated from the mains will be the different side of the circuit Rectified operating voltages required in a television receiver are output. These generally need to be stabilized. This is done in a secondary Voltage control circuit generates a control signal that is passed through another transformer or transmitter is transmitted to an electronic switch that is on the primary side controls the flow of current in the converter-transformer (DE-PS 32 27 152, internal file number H.D. Rosenthal 15). Such a converter circuit can also be one from the secondary side be a regulated DC voltage converter with electrical isolation.

To ensure the required security, the separation point an insulation withstand voltage of several kVolt in the converter transformer exhibit. This strength must also be demonstrated by the transmitter that regulates it The output signal of the pulse duration modulator serving the output voltage to the primary side the converter circuit transmits to control the electronic switch.

About the square-wave output signals of the pulse duration modulator to some extent To be able to transfer true to shape, the transformer must have a high inductance and a have great coupling between the two windings. This makes you feel right complex impulse transmitter with a large, closed iron core is required. Such a transmitter is heavy and bulky. Because of the large magnetic required Coupling is the distance between the current-carrying and the other metal parts of the transmitter so small that it MUST be shed.

The invention is based on the object of a converter circuit create that only requires a less expensive, unsealed transformer.

In the case of a converter circuit, this task becomes the one mentioned at the beginning Art according to the invention solved in that between the pulse duration modulator and the transmitter is a controllable high frequency oscillator, and that between the transmitter and the electronic switch a restoring the pulse duration modulated control signals Demodulator is arranged.

Advantageous further developments of the invention are set out in the subclaims marked.

An advantage of the invention is that compared to the transmission of pulse duration modulated control signals by means of a transmitter no restriction whatsoever of the duty cycle is given. Furthermore, the invention enables a simple Synchronization of the switching cycle of the electronic switch from the secondary side the end.

This option does not apply, for example, to the well-known control signal transmission by means of optocouplers.

An embodiment of the invention is described below with reference to the Drawing explained. 1 shows a converter circuit according to the invention as Block diagram and FIG. 2 details of the converter circuit according to FIG. 1.

The embodiment of the invention shown in the drawing is a switching power supply that is used to supply power to video recorders, and that is designed as a free-running flyback converter. They are just for explanation The circuit components required for the invention are shown. The primary windings a converter transformer Trl and a control transformer Tr2 are-in series with a transistor T1 acting as an electronic switch. One on two input terminals 4 applied input voltage Ue of e.g. + 300V is derived from the mains voltage Rectifier and filter circuits not shown here obtained.

A control circuit 6 contains a start-up circuit, a driver stage and a collector current limiting circuit.

The output of this control circuit goes to the base of the Transistor T1 and controls it. The switching frequency indicated in the drawing f5 of the transistor T1 can, as will be explained later, from the secondary side the converter circuit can be controlled from.

The voltage induced in the secondary winding of the transformer Trl reaches two output terminals via a rectifier diode D2 and a capacitor C2 10. The output voltage Ua given there represents a supply tension for the video recorder, although there are actually several DC voltages of different levels are delivered, which in a known manner of the supply of the individual stages of the Device.

The output voltage Ua is determined by the control circuit now described stabilized. The voltage Ua is in a comparison circuit 12 with an in a reference voltage source 13 compared reference voltage Uref generated and that The control signal obtained is amplified in a control amplifier 16 and then used as a manipulated variable Uy is given to the input of a pulse duration modulator 18. This delivers on his Output a square-wave voltage u1 (t). Their duty cycle is set so that that the output voltage Ua remains constant.

The output of the pulse duration modulator 18 is connected to the control input of a amplitude-modulable high-frequency oscillator 20 connected, here as a "switched" Oscillator is operated, i.e. only assumes the states "on" or "off". Included the oscillation frequency f HF of the HF oscillator must be large compared to the switching frequency be fS. The high-frequency voltage u2 (t) modulated in this way is applied to the input of the Control transmitter Tr2 and via this to the primary side. The shape of the control signal voltages u1 (t) and u2 (t) are indicated in the drawing. Since the transmitter Tr2 only has one If HF voltage has to be transmitted, it can be constructed very simply and thus economically to be manufactured.

To the secondary-side winding - with regard to the control signal transmission of the transformer Tr2 is in the - with regard to the overall converter circuit - on the primary side Circuit part, a demodulator 22 is connected, which from the RF signal again a square-wave voltage u3 (t) generated with the voltage u1 (t) is largely identical. This voltage is fed directly to the control circuit 6 and controls the switching transistor T1 via the driver stage contained therein.

The demodulator 22 is designed as a simple envelope curve demodulator and consists of a rectifier diode Di, a resistor R1 and a capacitor C1.

via a synchronization signal which can be fed to the pulse duration modulator 18 as required Sync can set the switching frequency fS of the transistor T1 and thus the converter circuit can be easily synchronized from the secondary side.

With the power supply unit according to the invention, control signals can be sent via the Net zt rennste 1 le are transmitted whose duty cycle is arbitrary and none Has an influence on the size of the transformer. In addition, the parameters of the control loop stable over long periods of time. The HF transmitter Tr2 can thus be implemented inexpensively that the additional effort required for the RF source is more than compensated for will. The switched-mode power supply according to the invention is thus more economical than switched-mode power supplies with conventional transformer transformers or with optocouplers.

A secondary winding w1 (Fig. 2) of the converter transformer Tr1 is Via a rectifier diode D3 and a filter circuit 30 with two output terminals 32 connected, at which the rectified output voltage Ua is output. The filter circuit contains an inductance L1 and three (or more) capacitors C3, C4 and C5.

The supply voltage is also applied to two connection terminals 34 Among other things. A series connection of a resistor R3 and two connected to these Diodes D5 and D6 connected in opposite directions form a temperature-compensated reference voltage source, which emits the comparison voltage Uref at a point 38. This comparison tension is in the comparison and control amplifier circuit 12, 16 with the to be regulated Supply voltage Ua compared, which is via a resistor R4 at the output of the Rectifier diode D3 is tapped.

The comparison and control amplifier circuit 12, 16 contains resistors R5, R6, -R7 and R8, a transistor T2 and an adjustable resistor R9.

From a point 39, the control signal reaches a pulse duration modulator 40, whose sync input 41 to a secondary winding w2 of the transformer. T rl connected. As a result, the operating mode of the converter circuit is set to "free running" set.

The pulse duration modulator 40 contains a comparator, the resistors R10, R11, R12, R13 and R14, a transistor T3 and two capacitors C11 and C12 and which corresponds to the comparison circuit 12 of FIG.

The base of the transistor T3 is on the one hand via the resistor R14 with the point 39 and on the other hand via the resistor R12 and the capacitor C12 connected to a point 42. At the secondary winding w2 of the transformer Trl a voltage of e.g. 50V is tapped and through a resistor R15 and a Capacitor C13 generates a triangular voltage at point 42.

The pulse duration modulated control signal arrives at a point 43 to the high-frequency oscillator 20, which has a transistor T5, a capacitor C17 and a resistor R20- contains. The output signal of the oscillator 20 arrives from a point 44 via a capacitor C10 to the control transformer Tr2 and via this to the demodulator 22 shown in FIG. 1.

After a start-up phase that is irrelevant to the invention, the function of the circuit arrangement according to FIG. 2 is as follows. To generate the The triangular voltage required by the comparator becomes the alternating voltage the secondary winding w2 of the RC combination R15.C13 leads, whose time constant is chosen so that it is in the working frequency range of the converter circuit exhibits integrating behavior.

The triangular voltage is regulated together with that of the; ' amplifier 16 generated manipulated variable Uy to the input of the pulse duration modulator 40 supplied to the the frequency or the frequency and the duty cycle of the control signal for the switching transistor T1 adjusts the converter circuit so that the controlled variable Ua remains constant.

The manipulated variable Uy represents the output signal of a proportional controller The value of Uy depends on the control deviation Uref - Ua.

At the output of the pulse duration modulator 40, i.e. at the point 43 S becomes now emitted a square-wave voltage, its frequency and duty cycle depending according to output power and mains voltage is set so that the supply X; voltage Ua remains constant.

The output voltage of the pulse duration modulator 40 is used by the HF oscillator 20 supplied, which is designed as a modified Colpitts oscillator. Its oscillation frequency is about 6 MHz, it must be much greater than the maximum working frequency f the Be converter circuit.

The RF oscillator 20 and the output level of the pulse duration modulator 40 are coordinated so that the high-frequency oscillation begins as soon as "High" level occurs at the output of the pulse duration modulator. The primary demodulator 22 represents the output signal of the pulse duration modulator 40 in frequency and duty cycle again.

The output signal of this demodulator is used via the control circuit 6 the switching transistor T1 is controlled. The control loop is thus closed.

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Claims (5)

Patent claims converter circuit with a primary-side circuit part, which has an electronic switch connected to the primary winding of a transformer is in series, - with a secondary-side circuit part, which is through the transformer is galvanically isolated from the primary-side circuit part, and at least contains a rectifier circuit through which the secondary voltage of the transformer rectified and a DC supply voltage is generated, - with a control circuit, their control signals depending on the value of the DC supply voltage Control the pulse duration modulator in such a way that with increasing DC supply voltage the pulse duration increases, and - with one between the pulse duration modulator and the electronic switch lying transformer through which the modulated Transfer control signals from the secondary-side to the primary-side circuit part are, characterized in - that between the pulse duration modulator (18) and the transmitter (Tr2) is a controllable high-frequency oscillator (20), and - that between the transmitter (Tr2) and the electronic switch (T1) a pulse duration modulated Control signals wi ederhe rstel lender demodulator (22) is arranged. 2. converter circuit according to claim 1, characterized in that by the output signal (u1 (t)) of the pulse duration modulator (18) the amplitude of the High frequency oscillator (20) is controlled. 3. converter circuit according to claim 1 or 2, characterized in - characterized, that the demodulator (22) is designed as an envelope demodulator. 4. converter circuit according to claim 1, characterized in that by the output signal (u1 (t)) of the pulse duration modulator (18) the frequency or the phase of the high-frequency oscillator (20) is controlled, and that the demodulator (22) is designed as a frequency or phase demodulator. 5. Converter circuit according to one of the preceding claims, characterized characterized in that the pulse duration modulator (18) by a switching frequency of the electronic switch (T1) determining synchronization signal (Sync) controlled will.