CS266185B1 - Connection of impulse voltage converter with energy circulation - Google Patents

Abstract

Wiring is particularly suitable for such applications cases where regulation is needed output voltages in the full range of load changes, including full drive unloading. Achieves this is by circulating energy whose size varies depending on the size of the load. Wiring includes excitation generator primary active switching element, transformer and secondary circuits with at least one secondary rectifier diode. In parallel connected to the secondary rectifier diode additional active switching element, parallel to the primary active switching element is additional diode connected. Primary Active switching element and additional active switching the element is connected to the field generator, which contains two delay members, ensuring that that both simultaneous switching will not occur active switching elements.

Description

The present invention relates to the connection of a pulse voltage converter which converts a supplied DC voltage into a DC voltage of different magnitude or to several DC voltages of different magnitudes. In particular, the invention relates to the connection of a single-acting pulse voltage converter comprising a transformer, at least one primary active switching element, e.g. a transistor and at least one secondary rectifier diode. The circuit usually also includes an excitation device, in which the generators generate pulses for excitation of the primary active switching element. The apparent voltage of the output voltage can be changed by the apparent duration of the excitation pulses. Zpinvhlln na uses feedback from the output terminals of the pulse voltage converter to the excitation generator, the effect of which is to maintain a constant output voltage.

Known connections of single-acting pulse voltage converters can be divided into two groups. The first group consists of circuits that use direct energy transfer from the primary circuit to secondary circuits. In this case, the secondary rectifier diodes conduct current in the first period of one cycle, i.e. in the period when both the primary active switching element is switched on and conducts current. The second group includes connections in which, in the first period of one cycle, when the primary active switching element is closed, the energy taken from the supply voltage source accumulates in the magnetic field of the transformer. Only in the following second period of one cycle, when the primary active switching element is open, is the accumulated energy dissipated by the currents passing through the secondary rectifying diodes to the appliances. The advantage of the connection from the second group is the possibility of easy regulation of the magnitude of the output voltages by changing the time of energy accumulation, ie by changing the switching time of the primary active switching element. With the connection from the first group, the possibility of regulating the magnitude of the output voltages is achieved by adding a choke and another rectifier diode to the secondary circuit. Part of the energy supplied in the first period of one cycle accumulates in this choke. In the following period, this energy is dissipated to the appliance by the action of another rectifier diode. There are also connections in which both methods of energy transfer by the transformer are used simultaneously. These include, for example, involvement according to Czechoslovak · copyright certificates No. 205 806 and No. 217 723.

A common disadvantage of all known connections of pulse voltage converters using energy storage in a transformer or in a choke is that they do not allow regulation of output voltages at the full range of load change, eg even at complete relief of outputs. When designing known connections for pulse voltage converters, it is always necessary to take into account the transmission of a certain minimum energy. In connection with this, it is necessary to maintain a certain minimum load of the inverter and the individual appliances cannot be disconnected arbitrarily.

This disadvantage of the known circuits is eliminated by the connection of the pulse voltage converter with energy circulation according to the invention. Its essence is that at least one of the secondary rectifier diodes is connected in parallel with its output terminals an additional active switching element, the first input terminal of which is connected to the third output terminal of the excitation generator, while the second input terminal of the additional active switching element is connected to the fourth the output terminal of the excitation generator. The first output terminal of the excitation generator and the second output terminal of the excitation generator are connected to the input terminals of the primary active switching element. An additional diode is connected between the output terminals of the primary active switching element.

In this connection, when the load on the outputs decreases, the excess energy in each cycle returns to the source of the supplied voltage. When the outputs are completely relieved, all the energy supplied to the output circuits in one cycle is returned to the source of the supplied voltage in the same cycle. However, the energy returned is reduced by the losses incurred in its transmission to the secondary circuits and back. When the output voltages are kept constant by the negative feedback fed from one output to the excitation generator, the pulse cycle on the transformer remains constant even when the outputs are unloaded, and even when the unloading is completely unloaded, the output voltages do not rise. Related to this is the fact that there is no premature disconnection of secondary circuits, which would result in voltage fluctuations on the transformer.

An example of the connection of a pulse voltage converter with energy circulation according to the invention is shown in Fig. 1.

CS 266 185 Bl

Fig. 2 shows an example of the connection of an additional active switching element formed by an N-P-N type transistor.

Fig. 3 shows an example of the connection of an additional active switching element formed by a transistor 1 'N 1'.

Fig. 4 shows an example of a circuit of an additional active switching element formed by an N-P-N type transistor and further by a first diode, a second diode and a first resistor.

Fig. 5 shows an example of the connection of an additional active switching element formed by a transistor of the P-N-P type and further by a third diode, a fourth diode and a second resistor.

Fig. 6 shows an example of the connection of an excitation generator consisting of a basic pulse generator and two delay members connected to it.

A primary active switching element 11 is connected in the primary circuit of the transformer 18, to the output terminals 12, 13 of which an additional diode £ 6 is connected in parallel. The first input terminal 14 of the primary active switching element 11 is connected to the first output terminal £ of the excitation generator £, the second input terminal 15 of the primary active switching element 11 is connected to the second output terminal £ of the excitation generator £. The secondary circuit forms a series connection of the secondary winding of the transformer 16, the secondary rectifier diode 17 and the filter capacitor 19, to which the appliance 20 is connected in parallel. the input terminal £ is connected to the third output terminal £ of the excitation generator £. The second input terminal £ of the additional active switching element 6 is connected to the fourth output terminal £ of the excitation generator £.

An N-P-N 18 transistor can be used as an additional active switching element £. Its collector forms the first output terminal £, the emitter forms the second output terminal 10 and at the same time forms 1 the second input terminal £. The base forms the first inlet outlet £. A field-effect transistor with an N-type conductive channel can also be used in the same connection. Its collector and emitter are connected in the same way as in the case of the N-P-N type transistor, the gate is connected as a base.

A transistor of the P-N-P 19 type can also be used as an additional active switching element £. Its emitter forms the first output terminal £ and at the same time forms the first input terminal £. The collector forms the second outlet outlet £ 0 and the base forms the second inlet outlet £. A field-effect transistor with a conductive channel P can also be used in the same connection. Its collector and editor are connected in the same way as in the case of a P-N-P type transistor, the gate is connected as a base.

An additional active switching element £ with improved switching properties can be formed by an NPN transistor 18 and a first diode 21, a second diode 22 and a first resistor 25. The collector of the NPN transistor 18 forms a first output terminal £ and is connected to the cathode of the first diode £ 1. whose anode is connected in a node to the anode of the second diode 22, this node forming the first input terminal £ of the additional active switching element £. The cathode of the second diode 22 is connected to the base of a transistor of the N-P-N type 18, the emitter of which forms the second output terminal 10 and at the same time the second input terminal £ of the additional active switching element £. The first resistor 25 is connected between the base and the emitter of the N-P-N 18 transistor.

Similarly, an additional active switching element 6 with improved switching properties can be formed by a P-N-P 19 transistor and a third diode 23, a fourth diode 24 and a second resistor 26. The emitter of the P-N-P 19 transistor forms the first output terminal 9 and also the first input terminal 6. The collector forms a second output terminal 10 and at the same time is connected to the anode of the fourth diode 24, the cathode of which is connected to the node with the cathode of the third diode 23, and this node forms the second input terminal 6 of the additional active switching element. The anode of the third diode 23 is connected to the base of the transistor type P-N-P 19 and this base is connected to the emitter by a second resistor 26.

CS 266 185 Bl

The excitation generator 2 Ιζθ is formed from the basic pulse generator 27 and the two delay members 28, 29 connected thereto. The first output terminal of the first delay member 28 forms the first output terminal 2 of the excitation generator 2, generator 2 · The first output terminal of the second delay member 29 forms the third output terminal 4 of the excitation generator 2, the second output terminal of the excitation generator 2, if nh.Mu. · Ζ. |><,?.<1<.ν _Λ <· Ι ho M «nu I νοΓ f č I v ι I ý výnlupní vývorl 5 i,„ ₍₁ ( _r f _{t | O} , _Iono _ rátora 1 .

The connection activity can be monitored in four periods of one work cycle. In the first period T1, the primary active switching element 21 is closed, the additional active switching element 2 is disconnected and the current from the supply voltage source passes through the primary winding of the transformer 22 ⁱⁿ the magnetic field of which energy is accumulated. In the second period T2 the primary active switching element 11 is disconnected and the energy accumulated in the magnetic field of the transformer 18 is dissipated by current passing through the secondary winding of the transformer 18 and the secondary rectifier diode 17 to the filter capacitor 19 and to the appliance 20. In the third period T3 the primary active switching element remains 11 is disconnected, the additional active switching element 6 is closed and the excess energy is dissipated from the filter capacitor 19 by the current flowing through the additional active switching element 2 back to the transformer 25, in the magnetic field of which it accumulates. In the fourth period T4, the additional active switching element 2 is disconnected and the excess energy accumulated in the third period T3 in the magnetic field of the transformer 18 is dissipated by the current flowing through the primary winding and the additional diode 16 back to the supply voltage source. The described process is repeated in each work cycle. The amount of excess energy returned depends on the load on the appliance 20. At full load, no energy is returned, at zero load, all the energy supplied in the second period T2 is returned to the filter condensate 19 ~. The length of individual periods also changes accordingly. At zero load, the first period T1 is approximately equal to the fourth period T4 and the second period T2 is approximately equal to the third period T3. At full load, the third period T3 and the fourth period T4 expire and the whole process takes place only in the first two periods T1 and T2, which are extended accordingly. In order not to have to change the switching times of the primary active switching element 22 ^{and the} additional active switching element 2 according to the size of the load, the circuit can be operated such that the primary active switching element 11 is closed in the fourth period T4 and the additional active switching element 6 is also closed in the second period. period T2 The first delay member 28 and the second delay member 29 in the excitation generator 2 ensure that the additional active switching element 2 is not switched on before the primary active switching element 11 opens and that the primary active switching element 11 is not switched on before the additional active switching element 11 opens. element 2 ·

The connection of the pulse converter with energy circulation according to the invention can be advantageously used, for example, in cases where it is necessary to supply several arbitrarily connected and disconnected appliances. Another example of advantageous use is the remote power supply of an appliance, in which it is desirable to be able to switch it on and off on site without changing the amount of voltage supplied. This appliance, for example, can be used to remotely power a television camera with a cable.

Claims (8)

OBJECT OF THE INVENTION 1. Connection of a pulse voltage converter and energy circulation, comprising an excitation generator, primary circuits with at least one primary active switching element, e.g. a transistor connected to an excitation generator and secondary circuits with at least one secondary rectifier diode, characterized in that at least one of A secondary active switching element (6) is connected in parallel with its output terminals (9, 10) of the secondary rectifier diodes (17), the first input terminal (7) of which is connected to the third output terminal (4) of the excitation generator (1), while the second the input terminal (8) of the additional active switching element (6) is connected to the fourth output terminal (5) of the excitation generator (1), both the first output terminal (2) of the excitation generator (1) and the second output terminal (3) of the excitation generator (1). generator (1) are CS 266 185 B1 are connected to the input terminals (14, 15) of the primary active switching element (11), while an additional diode (16) is connected between the output terminals (12, 13) of this primary active switching element (11). 2. Connection according to claim 1, characterized in that the additional active switching element (6) is formed by I ι.ηκΙπΙηΐΎΊ »π vo.Hvonl (type N PN (16), the collector of which forms the first output terminal (9) of the additional acl.ivn of the switching element (6), the emitter forms the second output output (10) and at the same time the second input terminal (8) of the additional active switching element (6), while the base forms the first input terminal (7) of the additional active switching element (6). 3. The circuit according to claim 1, characterized in that the additional active switching element (6) is formed by a PNP conductivity transistor (19), the emitter of which forms a first output terminal (9) and at the same time a first input terminal (7) of the additional active switching element. element (6), the collector forms the second output terminal (10) of the additional active switching element (6) and the base forms the second input terminal (8) of the additional active switching element (6). 4. The circuit according to item 1, characterized in that the additional active switching element (6) is formed by a field-controlled N-type conductive channel transistor, the collector of which forms the first output terminal (9) of the additional active switching element (6), the emitter forming the second output terminal (10) and at the same time the second input terminal (8) of the additional active switching element (6), while the gate forms the first input terminal (7) of the additional active switching element (6). 5. A circuit according to claim 1, characterized in that the additional active switching element (6) is formed by a field-controlled transistor with a P-type conductive channel, the emitter of which forms a first output terminal (9) and at the same time a first input terminal (7) of the additional active switching element (6), the collector forms the second output terminal (10) of the additional active switching element (6) and the gate forms the second input terminal (8) of the additional active switching element (6). 6. The circuit according to item 1, characterized in that the additional active switching element (6) is formed by an NPN type transistor (18), the collector of which forms the first output terminal (9) of the additional active switching element (6) and at the same time this collector is connected to the cathode of the first diode (21), the anode of which is connected to a node with the anode of the second diode (22), this node forming the first input terminals (7) of the additional active switching element (6), while the cathode of the second diode (22) is connected to the base an NPN transistor (18), the emitter of which forms a second output terminal (JO) and at the same time a second input terminal (8) of an additional active switching element (6), a first resistor ( 25). 7. The circuit according to item 1, characterized in that the additional active switching element (6) is formed by a PNP type transistor (19), the emitter of which forms a first output terminal (9) and at the same time a first input terminal (7) of the additional active switching element ( 6), while the collector of the PNP transistor (19) forms the second output terminal (10) of the additional active switching element (6) and at the same time this collector is connected to the anode of the fourth diode (24), the cathode of which is connected to the cathode node of the third diode 23), this node forming the second input terminal (8) of the additional active switching element (6), while the anode of the third diode is connected to the base of the PNP transistor (19) and this base is connected to the orator by the second resistor (26). 8. The circuit according to item 1, characterized in that the excitation generator (1) comprises a base pulse generator (27) to which a first delay member (28) is connected, the first output terminal of which forms the first output terminal (2) of the excitation generator (1). ), similarly the second output terminal of the first delay member (28) forms the second output terminal (3) of the excitation generator (1), a second delay member (29) is connected to the basic pulse generator (27), the first output terminal of which forms the third output terminal. (4) of the excitation generator (1) and similarly the second output terminal of the second delay member (29) forms the fourth output terminal (10) of the excitation generator (1).