HU180780B - Driving arrangement for controling transistors in switching mode - Google Patents

Abstract

An arrangement for switching a transistor, useable in switching transistor power supplies has a base coil (50) connected between the base and emitter of the transistor (7). By controlling the polarity of pulses to a control coil (40) which is inductively coupled to the base coil (5), current is induced to flow in the base coil (50) in one direction or in the opposite direction, respectively to switch the transistor (7) ON and OFF. When the transistor (7) has been switched ON it is maintained ON by positive feed back via a feedback coil (60) inductively coupled to the base coil (50). Push pull arrangements are described, and different embodiments include various circuitry for preventing permanent magnetisation of the transformer core (8). <IMAGE>

Description

BACKGROUND OF THE INVENTION The present invention relates to a drive circuit arrangement for switching control of transistors, which can be advantageously implemented in switching power supplies and the like by implementing a cumulative or countercurrent control mode.

One group of known drive circuits for transistor switching control is made up of directly coupled circuits. Their scope is limited because. galvanic separation is a basic requirement in most applications. Thus, transformer-coupled drive circuits are generally used. In the implemented circuits, the energy required to operate the switching transistor is obtained from an auxiliary voltage source supplying the drive stage, usually with poor efficiency. Such a solution is described in M. C. Baseli, "30 V 8 Switch Mode Power Supply Operating Form - 50 V Post Office Exchange Supplies" (Mullard Technical Note 20); and Mullard in its "5 V 20 A and 40 A Switch Mode Power Supplies" article (Mullard Technical Note 32), which provides data on the power consumption of the drive circuit.

The drawback of the above solutions, apart from the high power demand, is that the counter-driven switching transistors require two separate drive circuits, do not provide short and constant switch-off times, and do not exclude the possibility of switching on the counter-switching transistors.

A substantially similar solution is described by B.W.

Dudley and R. D. Peck in "High Efficiency Modular Power Suplies Using Switching Regulators" (HP Journal Dec 1973). This solution, although using an additional circuitry, reduces the switch-off time but does not eliminate the other back-up features mentioned above.

Advance-Gould utilizes a state-of-the-art solution for large series switching power supplies, as described above, which provides better counter-current control, provides greater efficiency than previously described, and provides a base current close to collector current through a separate current monitoring stage. However, this proportionality exists only up to a certain collector current value, above which the transistor may enter active mode, which is otherwise a fault of the other solutions. However, this drive stage has a relatively high power demand and does not completely eliminate the possibility of interconnection.

The disadvantages of the known solutions have necessitated the development of a drive circuit which is free of the listed drawbacks, its power requirement is considerably smaller than the known ones, and due to its construction it provides a base current proportional to the collec30 tor current, excludes tran180780

The 190700 has the ability to operate in the active range, provides a well-defined on / off, and significantly reduces the possibility of a2 interconnection when implementing counterclockwise control mode.

The basic idea of the invention is to realize that switching control of a transistor can be easily accomplished by a switching arrangement implementing a principle of operation in which the transistor is switched on by excitation in one direction and excitation of the transistor in the other direction by excitation of the transistor between base and emitter. maintaining the transistor's conductive state by positive feedback generated by collector current feedback, preferably through a loop coil in an inductive loop, and switching on and off by a loop coil in an inductive loop.

The drive circuit arrangement of the present invention serves to control transistor (s) in a capacitive manner and is constructed using inductive coupling elements. The essence is that the first - base - coil, connected between the emitter and the base of the transistor, has a second feedback coil connected to one of its main electrodes and arranged in an inductive coupling with the first coil and a third control coil arranged in an inductive coupling with the first coil and the second coil. the third coil is connected at least to the first switch cage at the first switch auxiliary power source g} sp and at the second switch the power supply is connected to a terminal 4ik, and the third winding is connected via a magnetizing circuit or auxiliary circuit.

In a preferred embodiment of the circuit arrangement, the elsp coil, the second coil, and the third coil are arranged on a common iron core.

In order to implement switches used in implementing the circuit arrangement by means of electrically connected devices, in particular transistors, it is advantageous to connect the first switch and / or the second switch serially to the auxiliary power terminals in series with a first diode connected to the auxiliary power terminals.

In one embodiment of a demagnetizing circuit for implementing a single-phase control mode, the magnetizing circuit has a biased dielectric dode and a second diode having a shifted break point characteristic between the first terminal of the third winding and the second terminal of the auxiliary power supply source. The second terminal of the third coil is directly connected to the second terminal of the auxiliary power supply. In another preferred embodiment for implementing a single-phase control mode, the first capacitor of the demagnetizing circuit coupled between the second terminal of the third coil and the second terminal of the auxiliary power supply source and a third diode arranged parallel thereto, and a third terminal The third diode and the fourth diode are connected to the terminals of the auxiliary power supply in a closing arrangement. A fifth diode is connected in parallel with the second switch to reduce the use of transistors implementing the switches.

In this embodiment, the time between turning off and closing the transistor can be further reduced by using a current sensing unit, wherein the second end of the third coil is connected to the first terminal of the auxiliary power source via a switch controlled by the transistor current sensing unit.

In a preferred embodiment for implementing the countercurrent control mode, the first coil arranged per transistor and / or the second coil arranged separately or transposed on the transistors and arranged in common with the respective transistors is one of the following. having a hapnacijk coil, the third coil is connected to the first terminal of the auxiliary power supply via a third terminal of the second terminal and to a second terminal of the auxiliary power source via a fourth switch. In order to reduce the use of transistors implementing the switches, a fifth diode is connected in parallel with the second switch and / or the fourth switch.

In another push-pull control mode to 'arranged tranzjsztpponként ⁵ to cation embodiment ELSPED coil gs third windings, and or trangisztprpnkpjit separately elpendezett, yagy the second coil is formed to be common for össggtartpzp tpanzigzíprokra yan, and 1 ° the first terminal of the third winding of the coupled each through sixth diode second joint switch has kptye.

Kiyjtelj constituting misik preferred counter-phase control mode shape the transistor ⁴⁵ and the third coil winding arranged ELSPED and arranged separately or transistor, or a second winding for the cognate transistors with shared. The third terminal of the third windings is connected to a common second switch via a sixth diode every ⁵⁰ diodes, and a second terminal of the third winding is connected via a first capacitor and a third diode connected parallel thereto to a second terminal 55 of an auxiliary power source. connected. In this embodiment, the time between turning off the switch and closing the transistor can be further reduced by using a current control unit, wherein the common second end of the third coils is connected to the first terminal of the auxiliary power source via a switch controlled by the transistor current sensing unit.

The drive circuit according to the invention is an actuator

Due to its operation principle -2180780, the transistor is powered and provides a base current proportional to the collector current. The low power demand can be explained by the fact that only minimal energy is needed to start the positive feedback process. The switch-on process is very fast due to the positive feedback. The switch-off time is mainly determined by the charge storage properties of the controlled transistor and can be reduced by increasing the base pull-out current. The drive circuit is protected against interference by short-circuiting the third control coil. When used with a counter-stroke drive stage, the control is simpler and less of a crossover option than in the prior art solutions, it provides protection against current impulses from erroneous control or malfunctions in the feedback coil.

BRIEF DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in more detail with reference to some preferred embodiments, with reference to the accompanying schematic diagrams, wherein: FIG. 1 is a schematic diagram of a circuit arrangement according to the invention; 3a is a small power off; FIG. 3b, schematic circuit diagrams of operation of the combined gear stage of FIG. 3b, diagrammatic circuitry of operation of the circuitry of FIG. 3b, schematic circuitry of a low-power drive stage of FIG. 4a, FIG. 4b of FIG. 5a, a schematic diagram of another counter-stroke, reduced-number drive stage; FIG. 5b, a schematic diagram of the operation of the switching arrangement shown in FIG. 5a; Fig. 6b shows waveforms typical of the operation of the counter-stroke stage shown in Fig. 6a.

The simple arrangement shown in Figure 1, which illustrates in principle, serves to control transistors 7. Between the base and the emitter of the transistor 7, a first coil 50 is connected. The second emitter 60 of the transistor 7 is connected in series with the emitter. The first coil 50 and the second coil 60 are arranged on a common iron core 8. The iron core 8 is further provided with a control third winding 40, the first terminal of which is connected via a first switch 10 to a first terminal 2 of a dc auxiliary power source and a second terminal 20 to a second terminal 4 of the auxiliary power source. The second terminal of the third coil 40 is directly connected to the second terminal 4 of the auxiliary power supply. The first winding 50, the second winding 60 and the third winding 40 are in an inductive coupling.

When the transistor 7 is actuated, the first switch 10 must be set to the conductive state when the second switch 20 is open. Then, a current is initiated from the first terminal 2 of the auxiliary power source at the first switch 10 and the third coil 40 and generates an induced voltage in the first coil 50 which causes the transistor 7 to enter a conductive state. The initial collector current of the transistor 7 flows through the second coil 60, by inductive coupling between the second coil 69 and the first coil 50, providing a positive current feedback which maintains the conductive state of the transistor 7. The conductor or open state of the first switch 10 is neutral with the conductor of the transistor 7. In order to switch off transistor 7, when the first switch 10 is open, the second switch 20 must be set to a permanent conductive state. The second switch 20 then short-circuits the third coil 40, which results in a short circuit of the base of transistor 7 as a result of the inductive coupling. The loss of collector current results in the elimination of positive feedback, thus switching off transistor 7.

Fig. 2a shows a variant of the circuit arrangement illustrated in Fig. 1, supplemented with a magnetizing circuit, where the magnetizing circuit is formed by a live break-point characteristic of a closing coil between the first terminal of the third coil 40 and the second terminal 4 of the auxiliary power supply. This suitably common anode is composed of 80 second diodes and 83 zener diodes. The second switch 20 is connected in series with a second diode 82 to prevent reverse current from being connected in an open direction to the auxiliary power source terminals. The operation of the drive circuit for switching on and off is the same as the circuit shown in Figure 1. The use of a detailed demagnetizing circuit accelerates the circuit operation by reducing to zero the accumulated magnetic energy in the third coil 40 and iron core 8 when it is switched on. This avoids the magnetization and saturation of the iron core as a result of repeated repetitions. The magnetizing circuit captures the reverse voltage generated in the third winding 40 at the breakpoint voltage and provides for rapid magnetization, reducing the flux to zero.

Fig. 2b shows the open or conductive state of the first switch 10, the second switch 20, and Fig. 7

-3180780 shows the change in collector current of transistor I _{c as a} function of switch control. The broken state of the switches is indicated by the level "0" and the conductive state by the level "1". The first switch 10 is actuated at time tj. Prior to this, the second switch 20 was in a conductive state and, at the same time as the first switch 10 was switched on, was in an open state. Due to the first switch 10 to turn on the transistor 7 collector current I _c commences. After switching on, the first switch 10 has a further conductive or broken state. During switch-off, which is effected at time t _{2 by} the switching of the second switch 20 to the conductive state of the first switch 10, the collector current i _{c of} transistor 7 15 increases until the transistor is switched off and then decreases to zero at time t ₃ . During the off state, the second switch 20 is in the closed state, which ensures that the drive circuit is undisturbed.

The drive circuit shown in Fig. 3a is another embodiment of the circuit of Fig. 1. The first switch 10 is connected in series with the first diode 81, which prevents reverse current generation. In parallel with the second switch 20, a fifth diode 84 is connected to conserve the switch from reverse current. The demagnetizing circuit comprises a first capacitor 94 connected between the second terminal of the third coil 40 and the second terminal 4 of the auxiliary power supply and a third diode 85 connected in parallel thereto and a fourth diode 86 connected between the second terminal of the third winding 40 and the first terminal 2 of the auxiliary power source. The third diode 85 and the fourth diode 86 are connected to the terminals of the auxiliary power supply source in a closing arrangement.

The operation of the circuit is similar to that of FIG. The current that is triggered when the first switch 10 is turned on charges the first capacitor 94 through the first diode 81 and the third coil 40 to the auxiliary power source voltage. At the same time, transistor 7 turns on as described above. When switched off, when the first switch 10 is open to close the second switch 20, the first capacitor 94 discharged through the third winding 40 provides the closing voltage for faster switching off of the transistor 7 until its charge is reduced to zero. Subsequently, the conductive state of the third diode 85 ensures that the third coil 40 is short-circuited and the transistor 7 is turned off. The magnetizing current of the iron core 8 begins charging the first capacitor 94 to the voltage of the first terminal of the auxiliary power supply. bounds. The magnetizing current continues to flow through the fifth diode 84, the second switch 201, the third coil 40, and the fourth diode 86 until the stored magnetic energy is fed back to the auxiliary power supply. Following demagnetization, the first capacitor 94 is discharged again through the third coil 40 and the second switch 20. In a preferred embodiment, the discharge is accelerated by a first resistor 96 connected in parallel with the third winding 40.

The time between switching off and transistor 7 switching off can be further reduced by the use of a fifth switch 91 connected between the second terminal of the third coil 40 and the first terminal 2 of the auxiliary power supply 10 and operated by the collector current sensing unit 90. The fifth switch 91 is in a conductive state at the same time as the collector current starts. In the closed state, the second terminal of the third coil 40 still holds the potential of the first terminal 2 of the auxiliary power supply, preventing the first capacitor 94 from discharging until the transistor 7 is switched off while the first terminal 20 of the third coil 40 The auxiliary power source is at the potential of the second terminal 4, thereby providing reverse voltage to the third winding 40 until the base of transistor 7 is completed.

Figure 3b shows the variation of the first switch 10, second switch 20, the collector current I _c and the fifth switch 91 operation time. When you turn on the first switch 10 starts, időpillanat30 Ban to drive at the same time the second switch 20 is interrupted, the collector current I _c begins, and it is the fifth switch 91 results in contention conducting. The state of the first switch 10 after switching on is inert with the transistor 7 switched on. The switch-off process is initiated by placing the second switch 20 in a conductive state at time t ₂ , which is essential if the first switch 10 is open. The switch-off process t _{3 is} completed at 40 moments when the collector current of the transistor drops to zero, whereby the fifth switch 91 is interrupted.

Fig. 4a shows a switching arrangement for countercurrent control of two first and second transistors 71 and 72, respectively. The first windings 51 and 52 are arranged per transistor and the second transistors 60 have common second windings.

The second coil 60 is connected to a common terminal of the emitter of the first transistor 71 and the collector of the second transistor 72. The two transistors are connected in series between the terminals of a supply voltage not shown. The first coils 55 51 and 52 and the second coil 60 common to the two transistors are arranged on an iron core 8. Similarly, the iron core 8 receives a third third coil common to the two transistors. The first terminal of the third coil 40 is connected via the first switch 60 10 to the first terminal 2 of the auxiliary power supply source and via the second switch 20 to the second terminal 4 of the auxiliary power supply source. Parallel to the second switch 20, the fifth diode 84 is facing the polarity of the auxiliary power supply65

-4180780 bound. The second terminal of the third coil 40 is connected via the third switch 11 to the first terminal 2 of the auxiliary power supply source and via the fourth switch 21 to the second terminal 4 of the auxiliary power supply source. In parallel with the fourth switch 21, another diode 89 is also switched in the closing direction with respect to the auxiliary power supply polarity.

The operation of the circuit can be monitored as shown in Figure 4b. In the initial position, the second switch 20 and the fourth switch 21 are in a conductive state, the first switches 10 and 11 in an open state. To turn on the second transistor 72, _at time _t, the first switch 10 is brought to a conductive state while the second switch 20 is driven to an open state.

Flowing through the fourth switch 21 and the first switch 10, the current of the third coil 40 transforms the current into the first coil 52 and opens the second transistor 72, whose initial collector current through the second coil 60 provides positive feedback, which maintains the conductive state of the second transistor 72. . When the second transistor 72 is switched on, the first state of the first switch 10 is inactive. In order to turn off the second transistor 72 and the first state of the switch 10 being broken, it is necessary to set the second switch 20 to a conductive state at time t ₂ . The third coil 40 is then short-circuited through the conductor third switch 11 and the second switch 20, and the short-circuit current flowing through the unloading diode 89 of the fourth switch 21 is transformed into the first coil 52 and closes the second transistor 72. The collector current of the second transistor 72 is terminated at time t ₃ . After a time t ₃ , a magnetizing current is maintained through the fifth diode 84 and the fourth switch 21 in the third coil 40 to maintain the flux of the iron core 8 in the opposite direction of the short-circuit current. By controlling the third switch 11 to a conductive state and the fourth switch 21 to an open state t _{/ (at the} instant t _/ 1), the first transistor 71 is switched on in the same manner as the former. The third switch 11 is inactive after the first transistor 71 is turned on. which can occur at time t ₅ , the fourth switch 21 is required to close and the closing process is performed as described above.

Fig. 5a shows another drive circuit for countercurrent control of first and second transistors 71 and 72, respectively. Both transistors have first windings 51 and 52, respectively, in the present embodiment, second windings 61, 62, and third windings 41 and 42, respectively. The second rolls 61 and 62 may also be arranged or formed together. Each coil is arranged on a common 8 iron core. The second coil 61 and the second coil 62 are connected to the main circuit of the corresponding transistor. The second terminal of the third coils 41 and 42 is connected to the second terminal 4 of the auxiliary power supply source. The first terminal of the third coil 42 is connected via the first switch 10 and the first terminal of the third coil 41 via the third switch 11 is connected to the first terminal 2 of the auxiliary power supply. Further, the first terminal of the third coil 42 is connected to the second terminal 4 of the auxiliary power source via a sixth diode 87b and a first terminal 87 of the third coil 41 connected via the sixth diode and a second switch 20 arranged in common with the two third coils.

The operation of the circuit is illustrated in Figure 5b. In the initial position, the first switch 10 and the third switch 11 are open and the second switch 20 is in the conductive state. To turn on the second transistor 72, the first switch 10 must be driven to a conductive state and the second switch 20 to an open state. The transformer current, which is transformed through the first switch 10 and the third coil 42, activates the second transistor 72 in the first coil 52, whose initial collector current I _c2 flows through the second coil 62, providing positive feedback to the second transistor 72.

During the conductive state of the second transistor 72, the state of the first switch 10 is inert. In order to switch it off, the first switch 10 must be in the open state and the second switch 20 must be driven. The short-circuiting on the third coil 42 shuts off the second transistor 72 by transforming it through a sixth diode 87b and a second switch 20. The point in time t ₃ is reduced to the second transistor 72 collector current I _c2 is reset and thereafter maintaining flux in the iron core 8 magnetizing current flows through the third coil 41, 87 of the sixth diode and the second switch 20th At time t ₄ , the second switch 20 is open to turn on the first transistor 71 and the third switch all is driven to a conductive state. The third coil 41 current áttranszformálódva the first coil 51 is controlled by the first transistor 71 conducting state, which commenced I _cl collector current flows through the second coil 61, establishes a positive feedback and maintain conductive state of the first transistor 71, during which the duration of the 11 third switch is inert . The first transistor 71 to turn off the second switch 20 at time instants t ₅ final closure is required, when it is short-circuited the third coil 41 in an additional 87 of the sixth diode and the second switch 20 through a current is turned off and the first transistor 71st After the collector current I has stopped at time t ₆ , the magnetizing current maintaining the flux of the iron core 8 flows through the third coil 42 through the sixth diode 87b and the second switch 20.

The drive circuit shown in Fig. 6a is also against first and second transistors 71 and 72 5

It operates at -5180780 and is substantially similar to the circuit shown in FIG. 5a. The difference is in the connection of the third windings 41 and 42 to the second terminal 4 of the auxiliary power supply source, which in the present embodiment is formed by a third diode 85 arranged in a closed direction with respect to the polarity of the auxiliary power supply. A collector current sensing unit 90 is provided in each of the first and second transistors 71 and 72 of the circuit of the present embodiment and is provided with a controlled fifth switch 91 between the common second terminals of the third coils 41 and 42. The circuit is further provided with a first diode 81 connected in series with the first switch 10 and which prevents undesired current flow through the switches and is arranged in an open direction with respect to the polarity of the power supply.

The operation of the circuit is illustrated in Figure 6b. The second transistor 72 is switched on _at time instant _t by closing the first switch 10 when the second switch 20 and the third switch 11 are open. The current on the first switch 10, the first diode 81 and the third coil 42, on the one hand, drives the second transistor 72 into a conductive state and charges the first capacitor 94, as described above. The commenced I _c2 kollektoráraiüót áraméixékelő sensor unit 90 closes the fifth switch .91, and thus the first capacitor 94 voltage for the duration of the closed state of the switch - as the auxiliary power supply potential is - which is equal to the collector current flow duration. When the second transistor 72 is turned on, the firing first switch is in neutral. To switch off the second transistor 72, when the first switch 10 is open, the second switch 20 must be closed at time t ₂ . Opposite current through the third coil 42 from the first receiver 2 of the auxiliary power supply source 2 through the fifth switch 91 and the other sixth diode 87b terminates the second transistor 72 as described above. The instantaneous collector current V of second transistor 72 results in opening of the fifth switch 91, and the first capacitor 94 is discharged through the third windings 41 and 42 to maintain the flux of the iron core 8 until the third diode 85 is opened. After the opening of the third diode 85, the magnetizing current of the iron core 8 flows through the third coil 41, the sixth diode 87 and the second switch 20. To turn on the first transistor 71, when the second switch 20 is open, the third switch 11 is closed at instant ₄ , when the current generating the first transistor 71 turns on the diode 81 through the third switch 11 and the third coil 41 through the first capacitor 94. recharges to the auxiliary power supply voltage. As a result of the _starter collector current I _C1 , the fifth switch 91 enters the conducting state. The state of the third switch 11 is indifferent during the conductive state of the first transistor 71. All switch off the third switch in addition interrupted state tg at time closing the second switch 20 is required when it commenced 91 fifth switch, 41 third coil and another 87 via the sixth diode circuit closing of the first transistor 71 and IC _(results kpllektoráramának termination. 91 Fifth opposite After opening the switch, discharge of the first capacitor 94 occurs as before, until the third diode 85 is opened, whereby the magnetizing current flows through the third diode 85, the third coil 41, the 87th sixth diode and the second switch.

Patent claims

Claims (4)

Patent claims A drive circuit arrangement for controlling a transistor (s) in a single-circuit or counter-current switching mode using inductively coupled elements on a common iron core (8) arranged in a first coil (50, 51, 52) between emitter and base of the transistor (s). for a plurality of first coils (51, 52) connected to its main electrode and arranged in an inductive coupling with its first coils (50, 51, 52), separate or common - feedback - second coils (60) per first coil and with the first coil (50, 51, 52) and a second control coil (40, 41, 42) arranged in an inductive coupling with the second coil (60), the first terminal of the third coil (40, 41, 42) via a first switch (s) (10, 11), a first auxiliary power source. is connected via a second switch (20) to the second terminal (4) of the auxiliary power supply, with the first switch (10, 11) lit in series a common second switch (20) of open diode tpttan first diode (81, 81a) and a second lock (5) diode (84) or a plurality of third windings (41, 42) connected in series to each terminal in parallel with the second switch (2'0); a sixth diode (87a, 87b) is connected, and a first capacitor (94) and a third connected in parallel between the second terminal (s) of the third coil (s) (40, 41, 42) and the second terminal (4) of the auxiliary power supply source a diode (85) disposed in the closing direction of the auxiliary power source terminals, characterized in that the fifth switch (91) is controlled between the second terminal (s) of the third coil (s) (40, 41, 42) and the auxiliary power source terminal; and the control input of the controlled fifth switch (91) is connected to the control unit (90). An embodiment of a drive circuit arrangement according to claim 1, characterized in that the control unit (90) connected to the control input of the fifth switch (91) is connected in series with the second winding (60). An embodiment of a drive circuit arrangement according to claim 1, characterized in that the fifth switch (91) for the first or second terminals (2, 4) of the auxiliary power supply source 6180780 and the second switch (20) and the first diode (20). 81) is connected to a common terminal, or to a common terminal of a common second switch (20) and a sixth diode (87a and 87b). 5 4. An embodiment of a drive circuit arrangement according to any one of claims 1 to 5, characterized in that the fifth switch (91) has a single diode (86) connected in a closed direction to the auxiliary power supply source.