FR2571562A1 - CONTINUOUS-ALTERNATIVE CONVERTER - Google Patents

Abstract

CONTINUOUS-ALTERNATIVE CONVERTER COMPRISING ONE TRANSFORMER CONVERTER 1 AND TWO COMMANDABLE SWITCHES 6, 7 WITH COVERED SWITCHING, BETWEEN THE CONTROL ELECTRODES G, F OF THE TWO COMMANDABLE SWITCHES 6, 7 BEING MOUNTED A VOLTAGE SOURCE AND THE ALTERNATIVE BETWEEN 8, 'CONTROL ELECTRODE G, F AND REFERENCE ELECTRODE B OF EACH COMMANDABLE SWITCH 6, 7 BEING SHUNTEE 9, 10.

Description

257 1562

  The present invention relates to a continuous converter

  AC comprising a converter transformer and

  two controllable switches with overlap switching.

  In the case of known devices of this type, in the case of switches controlled by control current,

  limits the control currents by means of a resistor.

  However, to obtain rapid closure of the switches, this current limiting resistor is bypassed by a

  capacitor (accelerator capacitor).

  In order to open the switches, in the known devices, an auxiliary voltage is required, which is obtained from the control current. This causes additional losses in the switchgear. In

  in addition, in the case of devices known for converting-

  dc-ac dors with a transformer

  vertisseur, in case of overlap switching, this mode

  is obtained by means of a communication source

  tation for each of the two contactors and by switching them with overlap. This not only leads to higher construction costs, but also higher losses due to the higher control energy

  when switching the two switches separately.

  The object of the invention is therefore to provide an arrangement for a DC-to-AC converter with overlapping switching which allows inexpensive joint switching of the two switches and allows operation

with overlap.

  The invention achieves this object with a device of the above type thanks to the fact that between the control electrodes of the two controllable switches is mounted an alternating voltage source, and that the channel between the control electrode and the electrode for each contactor

controllable is shunted.

  These means provide in particular the advantage that the

  mounting in opposition of the two control channels of the

  controllable mutators ensures that at least one of these is conductive each time, potential conditions defined by the shunt for the closed state being fixed for the switch which is not conductive. The polarity of the control voltage common to the two switches allows

  then to determine which of these will be conductive.

  One embodiment of a continuous converter

  according to the invention, alternating may consist in each shunt being formed by a resistor. This makes it possible, in particular in the case of switches whose control channel has a capacitive behavior (MOS field effect transistors), to behave in terms of opening.

  and closing well defined over time.

  Another embodiment of a DC converter

  according to the invention, alternating may consist of each shunt being formed from the series arrangement of a diode and a resistor, the diodes being polarized so that the

  serial connection placed between the control electrode and the elect

  reference trode of a controllable switch made con-

  conductor does not charge the AC voltage source. In

  particular with bipolar transistors as switching

  controllable torers, it is thus possible to obtain that the accumulation charge brought to the transistor which closes is maintained equal to the charge to be eliminated from the transistor which opens. This allows optimal closing and opening

bipolar transistors.

  According to the invention, it is possible to obtain an additional simplification of the ignition control of a DC-AC converter if each diode has one of its electrodes.

  connected to a control switch control electrode

  dable, and the other electrodes of the diodes are interconnected and connected to the reference potential by

  through common resistance.

  The present invention will be better understood using

  the following description of two embodiments of the

  DC converter of the invention, made with reference to the accompanying drawings, in which, - Figure 1 is a very simplified diagram of a DC converter according to the invention, and,

  - Figures 2 and 3 show continuous converters -

  alternative with a particularly advantageous arrangement

  geux of the device of the invention for switching

  of the two controllable switches of FIG. 1.

  Figure 1 is the block diagram of a continuous converter according to the invention which is preferably produced in the form of a push-pull converter

  switched to current. This converter includes a transformer

  converter converter 1 which has a primary winding 2 with center connection and at least one secondary winding 3. The

  taken from primary winding 2 is connected by an induc-

  tance 4 at a supply terminal A. The converter is supplied with energy by a voltage source 5 mounted between the supply terminal A and the reference terminal B. This voltage source 5 may for example be a voltage source direct or alternating voltage source

  with rectifier mounted downstream. The food of the converted-

  DC-alternator by a current source mounted between terminals A and B is also possible. In that case,

  inductance 4 may be absent. If the supply of the

  vertisseur is done from a switched current source,

  inductor 4 preferably forms part of it.

  The AC output voltage of the converter can

  be taken from the output terminals C, D of the secondary winding 3. An AC receiver can be connected directly to these terminals, while a receiver

  DC will preferably be connected via the

medium of a rectifier assembly.

  Each of the two ends of the primary winding 2 of the converter transformer 1 is connected to the reference terminal B by the main path between the main electrodes K, E of a controllable switch 6 or 7. The control inputs F, G of the two controllable switches 6, 7 are connected via an alternating voltage source 8. In addition, the control input of each of the controllable switches 6, 7 is connected to the

  reference terminal B by a shunt 9 or 10.

  For the description of the operation of a device

  in accordance with the invention like that of FIG. 1, it will be assumed that one is at a time when terminal F of the alternating voltage source 8 is at a potential

  positive; if we start from the fact that the switches

  usual dables like for example bipolar transistors

  switch, blockable thyristors (GTO), trans

  MOS field effect sistors, power and devices

  similar devices present, in a non-passing state, a high resistance control channel, the control circuit closes by the control channel of switch 7, the connection of the main electrode E of this switch to shunt 9,

  shunt 9 and terminal G of the alternating voltage source.

  Depending on the embodiment of the switches, that is to say depending on whether the control channel has, in the on state, a high or a low resistance, it will also pass, in the shunt 10, a corresponding current. The total control current delivered by the AC voltage source 8 is, in the case of switches with high static resistance control channels (such as, for example, power MOS field effect transistors), limited by the series connection.

  of the two shunts, while in case of tran-

  bipolar sistors which in the passing state have a characteristic

  very low resistance of the control channel formed by the base-emitter junction, the current is limited

by the shunt 9.

  Depending on the current flowing in shunt 9, a voltage

  negative will be applied to the community control channel

  tator 6, so that it will be securely maintained in the non-conducting state. The switch 7 will be kept flowing by the current in its control channel, or by the

voltage drop in the shunt 10.

  The switching operation is presented in a similar manner, whatever the practical embodiment of the switch 6 or 7. It is however particularly advantageous for the switches to have a low resistance control channel in the on state (for example bipolar transistors),

  or that, in the case of a high-resistance control channel

  tance, this has a capacitive character (MOS field effect transistors). The switching of the current conduction between the two switches is triggered by the change of polarity of the alternating voltage source. During the change, the control circuit goes from the

  terminal G now positive of the alternating voltage source

  native 8 to the main electrode of the switch 6 via the control channel thereof; the circuit

  closed by the main contact electrode

  tor 7, its control channel and terminal F of

the AC voltage source.

  The current flowing in this circuit serves as

  closing, or passing to the on state, of the switch 6.

  It goes in the opposite direction in the control channel of the switch 7 and produces the opening, or the transition to the non-conducting state, of the latter as soon as the electric charge

  accumulated in the control channel has been evacuated.

  In the ordinarily valid hypothesis where the closing of a switch takes place faster than the opening, in this way we obtain, whatever the practical realization of the switches, the recovery of the conduction

of the two switches.

  FIG. 2 shows another circuit in accordance with the invention in which the shunts 9, 10 each comprise a series circuit of a pure resistor Il or 13 and of a diode 12 or 14. The shunt in parallel with the switch 6 or 7 which has just closed then remains without current because the diode 12 or 14 is then polarized in the direction of non-conduction. This reduces the control power provided by the AC voltage source8. It is then necessary, for example for the switch 6 to be closed, that the terminal G of the AC voltage source is at a positive potential with respect to the reference electrode B. The control circuit is then formed by the channel switch 6, the shunt resistor 13 and the diode 14 polarized in the direction of conduction. The

  diode 12 is then polarized in the direction of non-conduction.

  When the switch 7 is conductive, the control circuit is formed by the control channel of this switch 7, the

  shunt resistor Il and diode 12.

  Since only one of the shunts is traversed by the current, and therefore only one of the resistors 11, 13 at a time is also traversed by this current, the function of these resistors 11, 13 can, as indicated in FIG. 3, be fulfilled by a common resistor 15- The anodes of the two diodes 13, 14 are connected and the resistor 15 is mounted between the junction point and the reference terminal B.

  Figure 3 shows a continuous converter assembly.

  AC which uses transistors as switches

bipolar 16, 17.

  The alternating voltage source 8 consists of a switching transformer 18, the winding of which

  secondary is mounted between the bases of the transistors 16, 17.

  To the primary winding of this transformer 18 is connected, as a control generator, a generator of

rectangular signals 19.

  The shunts between the base terminals of the transistors 16, 17 and the reference terminal B are each formed by a diode in series 12 or 14, the cathode of which is connected to the base of the transistor 16 or 17, and by a common resistor. 15 which is mounted between the reference terminal B and the point of

  junction of the anodes of the diodes 13, 14.

  This device gives a behavior of the bipo- transistors

  particularly in terms of opening and closing

realy advantageous.

  If the control voltage U has the polarity indicated by s the arrow, the base current for the transistor 16, at the

  positive terminal of the secondary winding of the transforma-

  switching switch 18, enters through the base of transistor 16 and goes from its emitter, through resistor 15 and

  diode 14, at the negative terminal of the secondary winding

  daire of the transformer. The permanent base current is then determined by the value of the resistor 15, the voltage drop in this resistor being equal to the control voltage U minus the base-emitter voltage of the s

  transistor 16 and the forward voltage of diode 14.

  To the base-emitter path of transistor 17 is applied a negative voltage equal to the control voltage Us minus the base-emitter voltage drop of transistor 16, which securely maintains transistor 17 in the off state. This state constitutes one of the two possible stable states in each of which a transistor is on.

and the other blocked.

  For switching, the operation of the bipolar transistors is as follows:

  When a blocked bipolar transistor must be returned-

  conductive, this operation takes place with very few losses if the basic current is brought for a short time to a value much higher than the value necessary for the complete transition of the transistor to the conductive state. For this, the base is saturated with charge carriers and this saturated state is subsequently maintained by the base current.

permanent passing.

  To block a conductive bipolar transistor, the charge accumulated in its base must first be removed by a negative base discharge current. It is only after this discharge that the transistor can block and that the base-emitter path as well as the collector-emitter path

  acquire a high resistance.

  The switching of the transistor 16 still conducting to the blocked transistor 17 is triggered by the change of

  polarity of the control voltage U. As the base channel-

s

  emitter of transistor 16 conductor has low resistance

  tance, to the transistor 17 is sent a basic current pulse whose amplitude is limited only by the setting

  in series of base-transmitter channels, now low resistance

  tance, transistors 16, 17 conductors; and resistance

  internal voltage of the control generator 19, brought back to the

secondary of the transformer 18.

  The two diodes 12, 14 are blocked and the charge of the transistor 16 is removed quickly by the large discharge current which passes. A substantially equivalent charge is then conducted at the base of transistor 17, and as soon as

  the base load of transistor 16 is completely eliminated

  born, this transistor is blocked, its base-emitter path acquiring

  high resistance. The basic circuit for transis-

  tor 17 now passing then closes by the resistor 15 and the diode 12. The resistor 15 limits the permanent base current of the transistor 17 to a relatively lower value, which ends the switching. The base discharge time represents the encroachment time of the conduction of the two transistors. For the use of this arrangement as a DC-AC converter, these switching operations are repeated at regular intervals fixed by the control generator 19. The

  command generator 19 can be for example the sub-

  TDB 0555 set from Thomson.

Claims (4)

Claims   1.- DC-AC converter comprising a trans-   converter trainer (1) and two control switches   dables (6, 7) with overlapping switching, characterized in that between the control electrodes (G, F) of the two controllable switches is mounted an alternating voltage source (8), and that the path between the electrode control (G, F) and the reference electrode (B) of   each controllable switch (6, 7) is shunted (9, 10).   2.- DC-AC converter as claimed   cation 1, characterized in that each shunt includes a resistance (9, 10).   3.- DC-AC converter according to one of the   Claims 1 and 2, characterized in that each   shunt includes a series mounting of a diode (s2, 14) and   a resistor (11, 13), the diodes (12, 14) being polarized   so that the serial circuit placed between the   control rod (G, F) and the reference electrode (B) of a controllable switch (6, 7) made conductive only   not load the AC voltage source (8).   4.- DC-AC converter as claimed   cation 3, characterized in that each diode (12, 14) has one of its electrodes connected to a control electrode   (G, F) of a controllable comautor, and the other electors   diode trodes (12, 14) are interconnected and, connected to the reference potential (B) via of a common resistance (15).