CS236570B1 - Switching source connection with impulse stabilization of output voltage - Google Patents

Abstract

The solution concerns the connection of a switching power supply with pulse stabilization of the output voltage. Its essence lies in the fact that the inputs of a combiner and a shaper are connected to the outputs of the control generator, the output of which is connected to the input of the exciter, which is connected to the first input of the flip-flop circuit, one output of which is connected to the input of the sawtooth voltage generator, which has an output connected to the first input of the voltage comparator, the second input of which is connected both to the output of the error amplifier, connected by its input to the output of the auxiliary amplifier equipped with a filter, and to the reference source, while the voltage comparator has an output connected to the second input of the flip-flop circuit, which is connected by its second output to the third input of the control circuit.

Description

BACKGROUND OF THE INVENTION The invention relates to a switching power supply with pulsed output voltage stabilization.

Voltage sources for supplying devices, especially considering operation on built-in accumulators, can decisively improve or spoil the level of solution of the device, both in construction and economics, especially transformer weights and operating efficiency.

More complex voltage sources usually need to be dimensioned for a critical case, which usually results in an over-dimensioning of the mass and an increase in power loss and hence the efficiency of the voltage source. This will have a particularly negative effect on portable battery devices.

These drawbacks are eliminated by the connection of a switching power supply with pulse stabilization of the output voltage, which is based on the fact that the outputs of the control generator are further connected to the inputs of the combiner and former, which has the output connected to the input of the exciter. the output is connected to an input of a saw voltage generator having an output connected to a first input of a voltage comparator, the second input of which is connected both to the error amplifier output connected to its input to the output of the filter-assisted amplifier and to the reference source; the output is connected to a second flip-flop input which is connected by its second output to the third input of the control circuit.

The advantages of switching the power supply with pulse voltage stabilization can be projected into several areas. First of all, it can be advantageously used to stabilize the battery back-ups of portable battery devices, in particular when they use so-called floating voltage sources, that is to say voltage isolated from the primary source or the chassis of the apparatus.

Another advantage is to minimize losses. The last but not least advantages include the implementation on a domestic and low-cost component base while maintaining a trouble-free and reliable function even under extreme working conditions, for example when running on battery power as the primary source.

An exemplary embodiment of the circuit according to the invention is shown in the accompanying drawings, in which Fig. 1 is a block diagram, Fig. 2 is an example of one of the detailed connection options, and Fig. 3 shows the time diagrams in the first column for minimum load; column for maximum load.

The circuit according to the invention consists of a control generator 1 having its outputs connected to the inputs of a control circuit 2, which is connected by its outputs to the inputs of the switching power stage 4 connected by its outputs to a pair of inputs of a double-acting transformer 5. 21 and one of the outputs of the double-acting transformer 5 is connected to the input of one of the rectifiers E1 to 11 provided with a filter, the outputs of which are also wiring outputs, where one of the outputs of the double-acting transformer 5 is further connected an auxiliary rectifier 12 with a filter. Generator 1 is further connected by its inputs to the combiner and former 13, which has an output connected to the input of the exciter 14, which is connected to the input of the saw voltage generator 16, which has an output connected to the first input of the voltage comparator 17. errors The comparator 17 has an output connected to the second input of the flip-flop 15, which is connected by its second output to the third input of the control circuit 2.

The control generator 12 is formed by a timer 22 having its ground 24 connected to the ground, its control voltage input 25 connected via the first capacitor 34 to the ground, and its timer starting input 30 is connected to the threshold 26 of the timer 22 and secondly, it is further involved between. a second resistor 32 and a second capacitor 35 further coupled to the ground, wherein between the second resistor 32 and the first resistor 31 is connected a timer discharge discharge input 27, wherein the first resistor 31 is further coupled to the timer power supply input 28 and the input 29 to reset the timer 22 and, on the other hand, to a third capacitor 36 connected to the ground and Ze3 diode 37 and a third resistor 33 connected to the primary source 21. The output 23 of the timer 22 is connected to the clock input 39 of the flip-flop 30 of the control generator. the first input 40, the second input 41, the third input 42, the fourth input 43, the fifth input 44, the sixth input 45, the seventh input 46 and the eighth input 47 are interconnected and connected via a common terminal between the first resistor 31 and the third capacitor 36 of the control generator 1, and the first output 48 of the control generator flip-flop 30 7472 is coupled to the first input 52 of the first control circuit gate 7. and the second output 49 of the control generator flip-flop 30 7472 is coupled to the first input 55 of the second control circuit gate 51.

The second input 53 of the first gate 50 and the second input 56 of the second gate 51 of the control circuit 2 are connected to each other and the output 54 of the first gate 50 of the control circuit 2 is connected to the base of the first transistor 59 of the pulse amplifier 3 via its base resistor 60 to which it is connected in parallel the first pulse amplifier capacitor 58, and its emitter is connected to the ground, and the collector of the first transistor 59 is connected via its collector resistor 61 at the same time to one end of the fourth capacitor 64 and the third pulse amplifier capacitor 63, the other ends of which the country of engagement and the primary source 21.

And the output 57 of the second gate 51 of the control circuit 2 is connected to the base of the third transistor 69 of the pulse amplifier 3 through its base resistor 70, to which the fifth pulse amplifier 3 is connected in parallel and its emitter is connected to ground. of the transistor 69 is connected via its collector resistor 71 to the primary source 21.

Further, the base of the second pulse amplifier 65 is connected to the collector of the first pulse amplifier transistor 59 via its base resistor 66 to which the second pulse amplifier capacitor 62 is connected in parallel and its emitter is connected to the ground and the collector of the second transistor 65 is connected. through its collector resistor 67 with primary source 21.

And to the collector of the third pulse amplifier transistor 69 is connected the base of the fourth pulse amplifier transistor 73 through its base resistor 74, to which the sixth capacitor 72 is connected in parallel and its emitter is connected to ground, and the collector of the fourth pulse amplifier transistor 73 is connected via its collector resistor 75 with a primary source 21, the base of the first switching stage transistor 76 is connected to the collector of the second pulse amplifier transistor 65 via its base resistor 78, to which the first switching stage capacitor 79 and its emitter are connected in parallel firstly, it is connected to the primary power supply 21, and the collector is connected to the second terminal 84 of the double-acting transformer 5, and to the collector of the fourth pulse amplifier transistor 73 is connected the base of the second switching power transistor 77 through its base resistor 80 the second switching capacitor 81 is connected in parallel and its emitter is connected both to the emitter of the first switching power transistor 76 and to the ground of the third switching capacitor 82 and the collector of the second transistor 77 is connected to the fourth terminal 86 of a double-acting transformer 8, which has its third terminal 18 connected both to the ground of the circuit and to the primary shielding of the double-acting transformer 8.

And to the seventh terminal 89 of the double-acting transformer 8 is connected with its anode a first diode 95 of the first rectifier 5 connected by its cathode to a resistor 97, a first rectifier 5 connected to the output of the wiring, filter capacitor 99 and choke 98 of the first rectifier to which the second diode 96 of the first rectifier 8 is connected by its cathode, connected by its anode to the sixth terminal 88 of the double-acting transformer 8, the first diode 95 and the second diode 96 having their cathodes interconnected.

Further, to the first terminal 83 of the double-acting transformer 8, anode 100 of the second rectifier 4 connected by a cathode to the choke 103 of the second rectifier 4 is connected by its anode and connected to the output of wiring and resistor 102 to the second rectifier. the diode 101 of the second rectifier 8 connected by its anode to the fifth terminal 87 of the double-acting transformer 2, wherein the first diode 100 and the second diode 101 have their cathodes interconnected.

Furthermore, the choke 103 of the second rectifier 2 is connected to a filter capacitor 104, which is connected both to the third terminal 85 of the idle transformer 2 ' ^to which the ground is connected at the same time, the filter capacitor 99 and the wiring output. a third rectifier 8 connected to the resistor 107 of the third rectifier 8 to which the first diode 105 of the third rectifier 8 is connected via its cathode to the sixth terminal 88 of the double-acting transformer 5 and the filter capacitor 109 is connected to the output and choke 108 a second rectifier 80 connected to its cathode with a seventh terminal 89 of the two-wavelength transformer 5, the first diode 105 and the second diode 106 having their anodes connected to each other.

Further, to the twelfth outlet 94 of the double-acting transformer 2, the first rectifier diode 110 connected by its cathode to the resistor 112 of the fourth rectifier 2 is connected by its anode and connected to the output of the wiring, filter capacitor 114 and choke 113 of the fourth rectifier 9. The first diode 110 and the second diode 111 have their cathodes connected to each other and to the ninth terminal 91 of the double-acting transformer 2 ^and their first anode is connected by their anode. 115 of the fifth rectifier 10 connected by its cathode to the choke 118 of the fifth rectifier 10, which is connected both to the output of the wiring, to the filter capacitor 119 and to the resistor 117 of the fifth rectifier 10 to which the second diode 116 of the fifth rectifier. and a first diode 115 and a second diode 116 have their cathodes interconnected.

At the same time, the first diode 120 of the sixth rectifier 11 is connected to the eighth terminal 90 of the double-acting transformer 2 by its cathode, connected by its anode to a resistor 122 of the sixth rectifier 11 connected to the wiring output and to the filter capacitor 124 119, on the one hand with the filter capacitor 114 and on the other hand with the tenth terminal 92 of the double-acting transformer 2 ', ^{on the} one hand the floating ground connection is connected and the tenth terminal 92 of the double-acting transformer 2 is connected to the secondary shielding; and a choke 123 to which the second diode 121 of the sixth rectifier 11 is connected by its anode and which is connected by cathode to the twelfth terminal 94 of the double-acting transformer 2, wherein the first diode 120 and the second diode 121 are connected to each other.

Furthermore, the fifth pin 87 of the push-pull transformer 2 connected to its anode of the second diode 126 pomofcného rectifier 12, and a first terminal of the 83 push-pull transformer 2 3 ^e connected its anode of the first diode 125 of the auxiliary rectifier '12, wherein the two diodes 125 and 126 are by their cathodes připojenyk choke 127 the auxiliary rectifier 12, to which the filter capacitor 128 is connected to the ground and the choke 127 is connected to the adjustable resistor 130, to which the first coupling capacitor 133 and the second coupling capacitor 134 are connected in parallel, while the adjustable base resistor 130 is connected the base of the error amplifier transistor 129 and the base divider resistor 131 of the transistor 129 and the base divider thermistor 132 of the transistor 129 connected to the ground, the transistor 129 of the error amplifier 19 has the ground connected and the collector connected to the third the resistor 170 of the operational comparator 160 of the voltage comparator 17, which is connected to the second / coupling resistor 169 of the operational amplifier 160, to which the capacitor 178 of the reference source 13 is connected and connected to the capacitor 178 by its cathode Zener the diode 177 of the reference source 18, which is connected by its anode to the ground of the connection and further connected by its cathode via a resistor 176 of the reference source 18 to the primary source 21.

Further, the coupling resistor 170 of the operational amplifier 17 is coupled to an inverting input 162 of the operational comparator 160 of the voltage comparator 17, the non-inverting input 161 of which is coupled to the first coupling resistor 168 of the operational amplifier 160 of the voltage comparator 17. and the power input 164 connected to the primary power supply 21.

Further, the operational amplifier 160 of the voltage comparator 17 has a first frequency compensation input 165 coupled via a compensation capacitor 175 to a second frequency compensation input 166 of the operational amplifier 160, the output of which is connected to the first base resistor 172 of the amplifier transistor 171 first, to the second base resistor 173 of the transistor 171 of the amplifier and former 20 connected to the ground of the wiring, and secondly, the first resistor 172 of the transistor 171 is connected to its base and the emitter of transistor 171 connected to the ground of the wiring; Control generator 2 zener diodes 37 ·

The operational amplifier 160 has its first coupling resistance 168 connected to the collector of the second transistor 155 of the saw voltage generator 16, the emitter of which is connected via an adjustable emitter resistor 159 connected in series with the emitter resistor 158 of the second transistor 155 to primary source 21 and the base of transistor 155 is a second base resistor 157 coupled to the ground of the wiring and a first base resistor 156 coupled to the primary power supply 21, and a first coupling resistor 168 coupled to the collector of the first transistor 152 and a timing capacitor 154 coupled to the ground. the emitter of transistor 152 is coupled to ground, and the base of the first transistor 152 of the saw voltage generator 16 is coupled via base resistor 153 to output 151 of second gate 14 of flip-flop 15, where output 151 is further coupled to second input 146 of first gate 144 of flip-flop 15. wherein the second inlet 150 of the second gate 148 is and the first input 149 of the second gate 148 is coupled to the output 147 of the first gate 144, which is further connected to the second input 56 of the second gate 51 of the control circuit 6.

And the second input 145 of the first gate 144 is connected both to the collector resistor 143 of the exciter transistor 142 »connected to the cathode of the Zener diode 37 of the control generator 2 ^and to the collector of the exciter transistor 142 which has the emitter connected to the ground and connected to the resistor 141 connected to the ground circuit, wherein the summation combiner resistor 141 and formers 13 connected by their cathodes of the second diode 140 and the diode 139 of the first combiner and the formers 22 ^»wherein the first diode 139 is its anode connected to resistor 136 jednak.přes first derivative element and a combiner formers on the ground and on the other hand through the capacitor 135 of the first derivative cell to the first output 48 of the flip-flop 30 of the control generator 2 ^{and the} second diode 140 is connected via its anode flip-flop output 49.

The description of the function is based on the block diagram in Fig. 1 and the waveforms in Fig. 3. The control generator 2 generates rectangular signals A and its phase shifted 180 ° with a frequency in the supersonic region, about 20 kHz.

These, on the one hand, open the corresponding inputs of the control circuit 2 and, on the other hand, create synchronization pulses for the combiner and former 13 with the exciter 14 for starting the flip-flop 22 (see the diagram in FIG. 3).

This is after the arrival of the start pulse and the flip gate is opened, first control circuit and £ partly starts the generator voltage of the saw 16, which produces waveform G. The input to the voltage comparator 22 'I ¹³ ° JSH second input voltage reference source 18, to which adds the amplifier voltage to the error 19 obtained by applying a load to the filter rectifier 12, see F.

The output voltage H. of the voltage comparator 17 controls the flip-flop 15 at the time of comparison via the amplifier and the former 20, i.e., it tilts the circuit to the initial state and thus terminates the duration of the pulse C and the pulse, respectively. D passing through the pulse amplifier 3 through the switching power stages 4 to the double-acting transformer 5 and the filter rectifier 6, 8, 9, 10, 11 and 12.

The load on the filter rectifiers results in a drop in their output voltage F in dynamic mode. This drop amplified by the error amplifier 19 is added to the voltage of the reference source 18, thereby proportionally prolonging the increase in the saw voltage G until the comparison, i.e., the shaping of the signal H, thus tilting the flip-flop 15, the saw generator 16 and closing the gates of the control circuit 2.

This extends the duration of Impulse C resp. D thereby increasing the amount of energy supplied to the load as the value changes.

Claims (1)

SUBJECT OF THE INVENTION Connection of a pulse-stabilized output voltage switching power supply comprising a control generator having its outputs connected to inputs of a control circuit connected to its outputs with inputs of a pulse amplifier having its outputs connected to inputs of a switching power stage connected to its outputs with a pair of double acting inputs a transformer whose center node is connected to the primary source and one of the outputs of the double-acting transformer is connected to the input of one of the rectifiers equipped with the filter, the outputs of which are also the output outputs; characterized in that the outputs of the control generator (1) are connected by their inputs to a combiner and a former (13) having an output connected to an input of an exciter (14) which is connected to a first input of a flip-flop (15) The en output is coupled to the input of the saw voltage generator (16) having an output connected to the first input of the voltage comparator (17), the second input of which is connected to the bending amplifier output (19) connected by its input to the auxiliary amplifier output (12) filter, and on the other hand to a reference source (18), the voltage comparator (17) having an output when coupled to the input of an amplifier and a shaper (20), the output of which is connected to the second input of the flip-flop (15). the third input of the control circuit (2).