DE4422003A1 - Control of PWM signals in push=pull DC=AC converter - Google Patents

Abstract

A method for controlling PWM signals in a push-pull DC-AC converter 14 has the PWM signal pulse frequency preset by a clock generator in a control module 24 and the pulse-width controlled by a main circuit 20, 22, 24 depending on the comparison between actual and required values of output voltage and/or current. A signal corresponding to the summed quantity of charge of individual current half-waves flowing in the branches of the converter is generated and after this reaches a required value set by the main control circuit, the PWM pulse is ended. The summation is done by an integrator when the amplitude of each half-wave falls to zero, a release signal then being sent for the next pulse.

Description

The invention relates to a method for control PWM signals in a PWM signal-controlled push-pull through flux converter of a switching power supply, the pulse frequency of PWM signals from a clock in a control logic is specified and the pulse width of the PWM signals by a main control loop depending on an actual value / target Value comparison of output voltage and / or output current of the Switching power supply is controlled.

The weight and size of transformers can be decrease by changing the frequency of the alternating voltage increases. The mains voltage is fixed at 50 Hz and could not be significantly increased even with great effort. With a switching power supply, the mains voltage is initially rectified and then with an inverter back into an AC voltage with a much higher one Frequency (usually 20 kHz to 100 kHz) converted. There by switching power supplies with the same power smaller transformer than a conventional power supply.

For medium and large output powers are almost out finally push-pull flow converter used. In the in most cases the devices work with a constant Switching frequency and adjustable duty cycle. The variation the frequency as a manipulated variable is also a known Ver drive that also related to some manufacturers a quasi-resonance circuit is used.

The regulation mostly applies only to the Output voltage and / or the output current. Become frequent Protective circuits for primary current limitation are provided however, no other control tasks to sit.  

The push-pull flow converter works at idle stable, but is not short-circuit proof without protective circuits. Switching power supplies with push-pull through are also required flow converter a fixed pause time between two Half waves to ensure that not all transistors conduct simultaneously and thus the operating voltage short would close. The ratio of the duty cycle one Half-wave to the period (duty cycle) must conv tional switching power supplies limited to 0.4 to 0.45 the, d. H. during 10% to 20% of the period flows no electricity.

The object of the invention is to provide a method of ge called type to create that be regarding the properties known tax procedure is improved.

According to the method, the object is achieved in that one of the accumulated amount of charge of each one in the branches of the Push-pull flow converter ent flowing current half-wave ent speaking signal and after reaching one setpoint specified by the main control loop PWM signal pulse is ended.

This has a number of advantages. One with the inventive method primary current-controlled push-pull flow converter works stable at idle and is without Protection circuits short-circuit proof.

The transformer is without special symmetry circuits automatically balanced. The control parameter "primary current times Time ", ie the amount of charge that has flowed, accordingly, kept constant for each half-wave. Thereby a symmetrical alternating current flow is always guaranteed accomplishes. Component tolerances through which the switching times  or the current amplitude can differ, are displayed regulates.

Furthermore, the control behavior with load jumps and network voltage fluctuations compared to conventional methods improved.

In a preferred embodiment of the method is also provided that an integrator forming the summation to is reset when the amplitude of a current half-wave in the branches of the push-pull flow converter the value has dropped back to zero, with a Release signal for the next PWM signal pulse to the Control logic is sent.

The power density is therefore comparable to that of comparable dimensions sionated switching power supplies with conventional control process work, higher. Due to the primary current version, the new concept does not require any limitation of the tactile relationship. At maximum modulation (maximum pulse width te) the system-related minimum pau is automatically set time. As soon as the zero crossing of the current half-wave he the next half-wave can be switched immediately the. Depending on the switching speed of the components used, duty cycles of approximately 0.5 can be achieved. With the same dimensioning of the power semiconductors and the Transformers (same core), taking into account suitable number of turns, the maximum transferable Performance compared to conventional switching power supplies, by approx. Increase 5% to 10%.

The invention also relates to a switching network with a PWM signal-controlled push-pull flow converter, the PWM signals according to the new method be controlled.  

In addition to a control logic with a clock generator, the Pulse frequency controls the PWM signals, and a main rule circle, which by a setpoint / actual value comparison of the off output voltage and / or the output current the PWM signal controls wide, has the switching power supply according to the invention a current transformer with two primary windings, each lie in a branch of the push-pull flow converter, wherein the amplitude value of each individual detected by the current transformer Current half-wave as a measure of the rate of rise of a Serves as an integrator and a comparator ends the PWM signal, as soon as the integrator value specifies that of the main control loop setpoint reached.

Since the flow converter works in push-pull, the flows Current per half wave only through one winding. The opposite pole The arrangement of the primary windings thus ensures a change current flow through the current transformer.

The division of the current transformer into two opposite-pole winds lungs, which are fed from the DC voltage side compared to a simple converter in AC voltage lead of the transformer the advantage that the entire current flowing over the bridge can be detected. Dangerous Liche cross currents via mis-controlled transistors or about defective components, not about the transformer flow, can be recognized and switched off immediately.

The following is closer with reference to the accompanying drawings to an embodiment of a circuit according to the invention power supply received. Show it:

Figure 1 is a simplified block diagram of a switching power supply.

Figure 2 shows a current transformer for primary current detection with full bridge circuit.

Figure 3 shows a current transformer for primary current detection with half-bridge circuit.

Fig. 4 is a block diagram of a primary current-controlled pulse width modulation;

FIG. 5 shows the waveform in the assemblies of the primary current control of FIG. 4;

Fig. 6 shows the signal behavior of the primary current control with asymmetrical current amplitudes.

In a switched-mode power supply unit shown in FIG. 1, the mains voltage (230 V / 50 Hz single-phase or 400 V / 50 Hz three-phase) is rectified in a mains rectifier 10 and sieved using capacitors or an LC circuit (not shown). A subsequent current transformer 12 in the area of a push-pull flow transformer 14 detects the primary current. The push-pull flow converter 14 converts the DC voltage into a square wave voltage. The switching stage can be equipped with transistors (MOS field-effect transistors or bipolar transistors) or with IGBTs (insulated gate bipolar transistors). The power semiconductors are connected in a push-pull circuit to form a half or full bridge with free-wheeling diodes and a relief network. The exact arrangement of the current transformer will be discussed in more detail later.

The higher-frequency AC voltage generated by the push-pull flow converter 14 is transformed by a transformer 16 to the desired output voltage of the switching power supply. The transformer 16 is ren auszufüh depending on the switching frequency of the push-pull forward converter 14 with a ferrite core (f <20 kHz) or with a Schnittband- or toroidal tape core. The rectification of the high frequency AC voltage is performed in a rectifier 18, which is preferably equipped with fast epitaxial diodes having relief network is. A conventional LC circuit is used to screen the output voltage, and an LC resonance circuit filter can also be used for high output powers.

An actual value detector 20 uses a voltage divider and / or a shunt to generate the actual values for the output voltage or the output current. A controller 22 with one or more control amplifiers generates an output signal for the PWM control from these actual values by comparison with setpoints.

From the signals of the current transformer 12 and the regulator 22, it generates a PWM controller 24, a pulse-width-modulated square-wave voltage for driving the switching transistors of the counter-clock flow converter 14 .

Fig. 2 and Fig. 3 illustrate the arrangement of the current transformer 12 in the push-pull flow converter 14th The current transformer 12 has two primary windings 26 a, 26 b, a secondary winding 28 and an iron or ferrite core. The primary windings 26 a, 26 b each consist of one or a few turns, which are arranged in the branches of the push-pull flow converter 14 . For the secondary winding, depending on the current ratio, a few hundred windings are required, which can be concluded with a load resistor 30 . The secondary signal is forwarded to the PWM controller 24 .

Since the forward converter 14 works in push-pull, the current per half-wave only flows through one winding. The opposite-pole arrangement of the primary windings 26 a, 26 b thus ensures that the current transformer 12 is flooded with alternating current.

The division of the current transformer 12 into two opposite-pole windings offers the advantage over the use of a simple transformer in the AC supply line of the transformer 16 that the entire current flowing over the bridge can be detected, and thus also dangerous cross currents which occur when the transistors 32 are incorrectly controlled or are defective Construction elements within the converter 14 and not flow through the transformer 16 , can be recognized immediately and switched off.

The overvoltage peaks caused by the stray inductance when the transformer 16 is switched off are derived by freewheeling diodes 34 . After switching off the transistors 32 , the demagnetizing current flows via the freewheeling diodes 34 of the respective complementary branch. Since the ge entire bridge current flows through the current transformer 12, and the demagnetization current is detected, the in tripping by the complementary winding of the current transformer 12, but here in the reverse direction flows. The measurement signal at the output of the wall accordingly shows the demagnetizing current with the same polarity as the active current that previously flowed.

In FIG. 4, the lower-level primary current control loop, which is integrated into the PWM controller 24 is illustrated. The AC voltage signal coming from the current transformer 12 is rectified in a rectifier 36 and integrated with a presettable integrator 38 over the time of a half-wave. The output signal of the integrator 38 is proportional to the amount of current flowing through the converter (I × t = Q), ie the charge. A comparator 40 compares this signal with the control voltage (setpoint) of the controller 22 and switches off the PWM signal pulse when the setpoint is reached via a control logic (not shown) in the PWM control.

After a delay time (switching delays + demagnetization time), the measurement signal of the current transformer 12 tends to the value 0. A zero crossing detector 42 clears the integrator 38 and gives an enable signal to the control logic for switching the next half-wave.

The waveform when the output setpoint is reduced in the individual components can be seen in the diagrams in FIG. 5.

Since the zero crossing detector 42 enables the immediate switching of the next half-wave, a fixed pause time between two half-waves, as is necessary in conventional switching power supplies to avoid short circuits, can be omitted. With maximum modulation and thus also maximum pulse width, the system-related minimum pause time is set automatically, which means that the transferable power can be increased by approximately 5-10% in comparison to conventional switching power supplies with otherwise identical dimensions of the transformer 16 and the power semiconductor 32 .

Since the charge control parameter for each half-wave is kept constant according to the target value, a symmetrical alternating current flow through the transformer 16 is always ensured. As shown in Fig. 6, component tolerances through which the switching times or the current amplitudes can differ, are corrected since the slew rate of the integrator is directly dependent on the amplitude of the primary current. In the event of a short circuit, the extreme rate of increase of the integrator 38 ends the PWM pulse after an extremely short time, the control logic of the PWM controller 24 detecting such abnormal switching times and possibly switching off the switching power supply completely.

Claims (5)

1. A method for controlling PWM signals in a PWM signal-controlled push-pull flow converter ( 14 ) of a switched-mode power supply, the pulse frequency of the PWM signals being specified by a clock generator in a control logic ( 24 ) and the pulse width of the PWM signals by The main control loop ( 20 , 22 , 24 ) is controlled as a function of an actual value / setpoint comparison of the output voltage and / or output current of the switching power supply, characterized in that one of the summed charge quantity of each individual current half-wave flowing in the branches of the push-pull flow converter ( 14 ) generates a corresponding signal and, after reaching a setpoint specified by the main control loop, the PWM signal pulse is ended. 2. The method according to claim 1, characterized in that a summing integrator ( 38 ) is set back when the amplitude of a current half wave in the branches of the push-pull flow converter ( 14 ) has dropped back to zero, while a Release signal for the next PWM signal pulse is sent to the control logic ( 24 ). 3. Working according to the method of claim 1 switching power supply with a PWM signal-controlled push-pull flow converter ( 14 ), wherein a control logic ( 24 ) with a clock, the pulse frequency of the PWM signals and a main control loop ( 20 , 22 , 24 ) by an actual value / target value comparison of the output voltage and / or the output current controls the PWM signal width, characterized in that the switching power supply has a current transformer ( 12 ) with two primary windings ( 26 a, 26 b), each in a branch of Push-pull flow converter ( 14 ) are arranged, wherein the detected amplitude value of each one of the individual current half-wave detected by the current transformer ( 12 ) serves as a measure of the slew rate of an integrator ( 38 ), and a comparator ( 40 ) ends the PWM signal pulse as soon as the Integrator value reaches the setpoint specified by the main control circuit ( 20 , 22 , 24 ). 4. Switching power supply according to claim 3, characterized in that a zero crossing detector ( 42 ) clears the integrator ( 38 ) and sends an enable signal for triggering the next PWM signal pulse to the control logic ( 24 ) as soon as the measurement signal of the current transformer ( 12 ) goes back to zero. 5. Switching power supply according to claim 3 or 4, characterized in that the push-pull flow converter ( 14 ) is constructed in half or full bridge circuit.