DE1058104B - Switching transistor with current-dependent control - Google Patents

Description

The invention has a new switching transistor arrangement to the subject, which either as controllable in terms of operation or automatically as current-dependent controllable switch can be used. Such a basic element can also go further They are used in all those circuits where a switching transistor is used and expedient provision is made that the transistor used as a switching transistor against undesired or impermissible currents are protected. The basic essence of an inventive Arrangement is that the switching transistor in the main circuit or in the consumer circuit the arrangement is, a further transistor is assigned such that the control path, for. B. Emitter-base path of one transistor depending on the voltage at the output electrodes, z. B. the emitter-collector path, the other transistor is controlled, but the Control path of the assigned transistor via a valve to the output electrode path of the im Main line strand lying transistor is connected. This valve is part of the resistance the supply voltage source connected to the voltage divider behind the main transistor of the arrangement and is open when the main transistor is open and when current flows through the voltage divider. The one mentioned Resistance, which forms the voltage divider together with the valve mentioned, is at the same time in the Control circuit or emitter-base circuit of the assigned transistor and acts when this transistor is open as a limiting resistor for the control current of this transistor. As soon as the assigned The transistor is opened and the main transistor is blocked, the valve that the voltage divider heard, claimed in the reverse direction.

For a more detailed explanation of the invention, reference is now made to a corresponding exemplary embodiment according to FIG. 1. At the terminals 1 and 2 is the supply voltage source of the arrangement, from which via the transistor 3 z. B. from the (pnp) type of consumer 4 is fed. The transistor 3, which is in the main feed line, is another transistor 5 z. B. assigned by the (pnp) -Tvp. 6 denotes a resistor in the control circuit of transistor 3. This control circuit runs from terminal 1 via the emitter-base path of transistor 3, a valve 7 and resistor 6 back to terminal 2 of the voltage source. 8 denotes a shut-off valve which, together with the resistor 9, forms a voltage divider connected to the voltage source 1, 2 downstream of the transistor 3. The base of the assigned transistor 5 is connected to the connection between the switching transistor via a valve 10
with current-dependent control

Applicant:

Siemens-Schuckertwerke

Corporation,

Berlin and Erlangen,

Erlangen, Werner-von-Siemens-Str. 50

Otto Werner, Berlin-Siemensstadt,
has been named as the inventor

the shut-off valve 8 and the resistor 9 connected. The resistor 9 is locked Valve 8 is only effective in the control circuit of transistor 5. This control circuit then runs from the Terminal 1 of the voltage source via the emitter-base path of the transistor 5, the valve 10 and the resistor 9 back to terminal 2 of the voltage source.

The following mode of action results in this arrangement:

The transistor 3 is open when a corresponding current flows to the terminal 2 of the voltage source from the terminal 1 via the emitter-base path of the transistor 3, the valve 7 and the limiting resistor 6 in the sense of the control circuit already described. When the transistor 3 is open, such a current flows through the voltage divider from the valve 8 and the resistor 9 that the valve 8 is open. In this state, the transistor 5 is blocked because the voltage that is applied to its emitter-base path is too small to be able to open it at its emitter-collector path. For safety reasons, the valve 10 is provided so that an effective control current through the emitter-base path of the transistor 5 can only arise when the voltage effective at the control circuit of the transistor 5 exceeds a threshold value specified by the valve 10. Instead of the valve 10, a corresponding counter-voltage source could also be used,

909 528/274

3 4

which corresponds to the Schwelhvert of the valve 10. The mode of operation of the device in the case of This consideration must take into account that the occurrence of an overcurrent across the load 4 is beVentil 8 is claimed in the forward direction and has already been described. One such arrangement is thus a voltage drop arises at it, which is also suitable for an operational additional control voltage in the control circuit of the Tran- 5 control as well as for an overload protection device, sistor 5 is effective and in the dimensioning of such an arrangement, as it is basically in

Valve 10 must be taken into account. Increases of Fig. 1 has been described, can also be used as an element Current through the load 4 and thus used in other circuits. A BeiTransistor 3 except for one undesired or un- play for this is z. B. an inverter in which permissible value, transistors are created at the output io as controlled elements. The sense electrodes of the transistor 3 a voltage drop, according to control of these transistors in the which then takes place as the driving voltage a control current inverter instead of corresponding can arise via the transistor 5, so that this control switch, as shown in Fig. 1, is opened. But as soon as the transistor 5 opens depending on the voltages that are applied to the primary, the resistor 6 via the transistor 5 15 winding or the partial windings of this winding fed. Because of the small voltage drop that occurs in the inverter's output transformer open transistor 5 at its emitter, and depending on the size of the working-collector path is, the current flow over the current, which is used as the control element of the Control path of transistor 3 interrupted. So that the inverter is used for the single half-wave the transistor 3 is blocked with certainty, 20 transistor can flow.

the valve 7 can be provided in its control circuit. An arrangement according to the invention, for example

which is illustrated as a counter voltage or as a resistance of this type for an inverter Scliwellwertcharakter is effective. When Fig. 2 is locked. In this figure, two units are in the meaning Transistor3 hears the current flow through the Spanmings- of Fig. 1 with the appropriate elements included, divider, which consists of the valve 8 and the counter 25 (Jm to ensure an easy overview, are the stand 9 is formed, d. That is, the valve 8 is now in the two units again as in FIG closed. The control current for the tranhander directly with the same type of parts sistor 5 is now making its way from terminal 1 to numbers, these items being in Via the emitter-base path of the transistor 5, the various units are now at the number via valve 10 and resistor 9 back to 30 with a corresponding supplementary symbol in Terminal 2 of the voltage source. This leaves the shape of a line or two lines Transistor 3 in the blocked state. have been, 16 denotes in the arrangement the

In the previous description, the arrangement is the output transformer of the inverter, which has only been described in such a way that when the primary winding occurs with parts α and b, they are assigned to the two of a certain current across the load 4 effective units. The DC voltage source is sam, that is, it acts z. B. as an automatic for the inverter is denoted by 19. It is an overcurrent protection device for the transistor 3. In this case, for the sake of simplicity, the transistor 3 can be indicated in the supply circuit of the load 4. To start the arrangement is also used in the manner of an operator-controlled pushbutton 17, which is used in series with a switch or additionally with this function 40 capacitor 18 on the base-collector path of the. For this purpose, the operating switches 11 and 12 are transistor 3 ″.

entered in FIG. 1. The mode of operation will now be explained briefly below

Closing the switch 11, which is described in the manner of a pressure this arrangement. It can be designed from this button switch, the input that the two actual operating devices are switched on, by briefly closing 45 sistors 3 'and 3 "are switched off in the locked state of the switch 12. For explanation, see during this the two working transistors assumed the state in which the auxiliary transistors 5 'and 5 "assigned to the Tran are opened, sistor 5 is open. A control system then flows to it, ie it is in the state of passage of its current from terminal 1 via its emitter-base-emitter-collector path. This switching path, the valve 10 and the resistor 9 return to the state of the arrangement as a result of which terminal 2 of the voltage source is maintained. If it is now obtained that the switch 11 is temporarily closed for the transistor 5 'by the current, then source 19 is a control current via the valve 10' and the points 13 and 14 of the circuit to the same resistor 6 'and for the transistor 5 " brought a potential so that at the emitter-base control current via the valve 10 "and the resistor section of the transistor 5 there is no longer any voltage. 55 was 6 ". When the start button is closed, the transistor 5 is therefore blocked at its emitter 17 for starting the arrangement the transistor 3 transistor 3 ″ opens. With the opening of the transistor 3 ″ opens because the emitter-collector voltage of the Tran-, the transistor 5 ″ is blocked. This in turn results in the control voltage 60 required for opening the transistor 5, so that the transistor 3 ″ remains open, and the voltage of the transistor 3 is also reached In this state, the winding order can be brought about by temporarily closing the switch 12 for part b of the primary winding of the transformer of the circuit on 65 19. Here, the end B of the primary winding of the same potential is brought, ie, the emitter transformer positive compared to the other collector voltage of the transistor 5 is practically end A of the primary winding and the center-zero, so that over the Emitter-base path of the tran- tap C Due to which no more current flows at the terminals B and C of the transistor 3 and the emitter primary winding of the transformer mators lying span-collector path of the transistor 3 is blocked. 70 voltage becomes the core of the transformer towards

Claims (6)

magnetized to its positive saturation. This is illustrated in FIG. 3. This shows a magnetization loop of the core material of the transformer core. The magnetization in the direction of positive saturation thus runs on the rising branch of the characteristic in the direction of point 1. As soon as the magnetization current over the winding part b of the primary winding of the transformer becomes so great that the voltage drop across the emitter-collector path of the transistor 3 "is sufficient to open the transistor 5" somewhat, the transistor 3 "is blocked because of the low voltage which is then only applied to its control path. The interruption of the current through the winding b changes the induction of the transformer core according to FIG 3 from a value, e.g. corresponding to point 1, to a value corresponding to the remanence determined by point 2. This change in induction induces a voltage surge of opposite polarity in the transformer windings, terminal A of the primary winding of the transformer becoming positive with respect to the connections B and C. This voltage surge causes the transistor 5 'to become total locks. If, however, the transistor 5 'is blocked, the transistor 3' is now opened and applies the positive potential of the current source to the point A of the transformer sub-winding a. The magnetization curve of the core of the transformer is traversed mm further as shown in FIG Transistor 5 'and thus to a blocking of the transistor 3'. As soon as the transistor 3 'is blocked and the current flow through it ceases, the induction of the core of the transformer changes in the direction of the remanence point 4. This change in induction creates a voltage on the windings of the transformer, which leads to the blocking of the transistor 5 " By blocking the transistor 5 ", the transistor 3" is opened, and the game then begins again. From the description it can be seen that the working transistors 3 'and 3 "are blocked when the current flowing through them is large that the voltage drop at their emitter-collector paths is sufficient to open the transistors 5 'or 5 ". With a low or normal load on the inverter, this control process is, as explained, by the increase in the magnetizing current at the end of the voltage half-wave If the load is too great, however, this phenomenon will occur earlier due to the load current Over does not go through the entire induction change at the core of the transformer. The induction jump from the respective magnetic induction value reached to the remanence point is then correspondingly smaller, so that finally the opposed-phase operating transistor does not open. Both transistors 3 'and 3 "then remain blocked until a new start command is given to the arrangement via push button 17. The arrangement according to the invention is suitable as an inverter for supplying loads of an ohmic character as well as those of an inductive or capacitive character In an arrangement according to the invention, a special voltage source can also be used for the control circuits of each of the two transistors, one pole of all voltage sources being connected to one electrode of the main transistor. only one unit, consisting of a main transistor and an auxiliary transistor, is then required. 1. Switching transistor with current-dependent control, characterized in that a main transistor (3), which is connected upstream of a consumer (4), is assigned an auxiliary transistor (S), that the control path (emitter-base path) of the main transistor (3J to the output path (Emitter-collector path) of the auxiliary transistor (5) and the control path (emitter-base path) of the auxiliary transistor (5) on the electrode located in the direction of the consumer (4) (Collector electrode) of the output path (emitter-collector path) of the main transistor (3) is connected via a rectifier (8) in series with the main transistor (3) and an ohmic resistor (9) is in the control circuit of the auxiliary transistor (5) and which when the Main transistor (3) through the flow of current through the series connection of valve (8) and Resistor (9) is open and that the auxiliary transistor " (S) with its output electrodes (emitter-collector path) via a limiting resistor (6) on. a voltage source is connected. 2. Switching transistor according to claim 1, characterized in that in the control circuit of the main transistor a counter-voltage source or a corresponding voltage-dependent, non-linear one Resistance with threshold character is provided. 3. Switching transistor according to claim 1, characterized in that in the control circuit of the auxiliary transistor a counter-voltage source or a corresponding voltage-dependent, non-linear one Resistance with threshold character is provided. 4. Switching transistor according to claim 1 or one of the following, characterized in that the Voltage at the control lines of the two transistors through temporary bridging or reduction of the control voltage automatically or as far as the operator controls it becomes that the transistor in question is blocked and thereby the other transistor inevitably is opened. 5. Switching transistor arrangement according to claim 1 or one of the following, characterized by Use of one or more units of main transistor and auxiliary transistor as controlled Elements of an inverter in which the sections of the primary winding of the output transformer are fed via the units mentioned from their direct current source and the Control takes place in such a way that the disconnection of the supply to the primary winding or the respective Partial winding from the DC voltage source depending on the level of the load current of the main transistor takes place and the activation of the because the following main transistor takes place due to the in the windings of the inverter transformer when switching off the previously switched on Main transistor voltage induced by the cessation of magnetic excitation. 6. Switching transistor arrangement according to claim 5, characterized in that for starting the arrangement, the base-collector path of a switching transistor temporarily is bridged by a capacitor. 1 sheet of drawings