DE1179989B - Replaceable amplifier with tilting properties that requires control current - Google Patents

Description

Replaceable amplifier with switching properties that requires control current In devices of modern control and regulation technology, it is common practice to use interchangeable To use structural units. It is desirable that when a structural unit is replaced no special comparison either of the structural unit or the affected control or Control device is required. Particularly difficult conditions arise if transistor amplifiers are used, as the individual transistors are used Partly have quite different current amplification factors.

In devices of the type described above, amplifiers with switching or tilting properties are still used. Characteristic curves of such amplifiers with tilting properties are shown in FIG. 1, in which output currents J are plotted against control voltages u. The curve 20 shows a normal amplifier characteristic. This amplifier characteristic curve can be set up with the aid of a positive feedback of what is known as the critical value to the curve 21 which runs practically perpendicularly. In order to ensure that the amplifier tilts, a supercritical positive feedback has been chosen to take account of temperature fluctuations, etc., in which the amplifier tilted back, for example, along curve 26. When replacing the respective amplifier in the devices previously used, both the absolute values of the positions of the curves 21 and 26 and their mutual spacing could shift considerably.

A known amplifier with tilting properties is shown in FIG. 2.

In Fig. 2 shows a three-stage transistor amplifier. This contains transistors 3 ... 5. Collector resistors 8 and 9 as well as a relay winding 11 to which a current J is applied. A positive feedback branch with a relatively high resistance 7 leads from the collector of the second transistor 4 to the base circuit of the first transistor 3. The supply and control of the amplifier is provided by a DC voltage applied to terminals 1 and 2. The control voltage u of the amplifier is formed with the aid of a series resistor 15 and a potentiometer 16 which is low in relation to the positive feedback resistor. In the base circuit of the transistor 5, an ohmic resistor 10 is arranged, which prevents the emitter-collector path of the transistor 4 from being short-circuited by the transistor 5.

In the amplifier described above, there was also an ohmic resistor 6 in the input circuit, which is connected to the potentiometer tap 17 here. intended. If the amplifier is now using plug-in connections 12. '. . 14 is exchangeable, then the voltage drops across the resistor 6 in particular influence the response values of the respective multivibrator amplifier. This should be in! will be explained in more detail below.

If the control voltage u is increased from the value zero by adjusting the potentiometer tap 17, a control current begins to flow through the resistor 6 when the threshold value of the base-emitter path of the transistor 3 is reached. Since the positive feedback resistor 7 has a high resistance to the resistor 6 and the aforementioned threshold value is relatively low, only a small part of the control current flowing through the resistor 6 is dissipated via the positive feedback resistor 7 and the conductive transistor 4. When the control voltage u reaches a value at which a corresponding base-emitter current opens the transistor 3, the transistor 4 begins to block. This results in a one-emitter-collector voltage at transistor 4, which drives a current in the sense of the base-emitter current of transistor 3 via positive feedback resistor 7. If the value of the resistor 6 is too small, a larger part of the current flowing through the resistor 7 can flow away through the resistor 6. There is then a risk that the Mitkopp-Jung is not sufficient.

Both with a critical positive feedback and with a supercritical one Positive feedback is a tilting into the switched-on state, in which the relay winding 11 current J is supplied, upon reaching point 22 of the abscissa of FIG. 1 take place along the straight line 21 lying between the points 23 and 24. the Control voltage u at point 22 or 23 is composed essentially of the threshold voltage the base-emitter path of the transistor 3 and the voltage drop that the over the potentiometer tap 17 causes the control current flowing in the resistor 6, together. The control current of the transistor 3 required to switch it into the switched-on state fluctuates with the current gain of the replaceable amplifier used. With The aforementioned control current, which differs from case to case, also changes the voltage drop across the resistor 6, so that the corresponding to toggle in the switch-on state required control voltage u changes.

The switching to the switched-off state, in which the relay winding 11 no more significant current is supplied, occurs with supercritical positive feedback, deviating from the switch-on curve 21, from point 25 along the imaginary straight line 26 to point 27 when the control voltage u from point 22 in the direction of the Value zero of the control voltage u exceeds point 27. It is done via the Resistor 6 as much of the current flowing through resistor 7 at the base-emitter path of the transistor 3 bypassed that the positive feedback does not switch on can sustain more. The amplifier switches to the switch-off state. Which Proportion of the flowing through resistor 7, in this case through resistor 6 Current that has to be dissipated depends on the current gain of transistor 3. When the amplifier is replaced, the current gain changes accordingly of the transistor 3 also the voltage drop across the resistor 6 and thus the for the Transition to the switch-off state, the decisive control voltage and in FIG. 1 lies for supercritical positive feedback, for example at point 27.

The stated disadvantages want to reduce the invention, so that in a Replacing amplifiers, no special adjustment of the arrangement is required. The invention accordingly relates to a replaceable amplifier which requires a control current with tilting properties that result from supercritical positive feedback of amplified variables the input of the amplifier are generated. The invention is characterized in that that an electric valve follows a control voltage source, that the positive feedback branch is dimensioned for a strongly supercritical positive feedback and that means for limiting the control variables that can be generated by positive feedback are provided.

The further explanations of the invention are based on the in F i g. 1 and on the basis of one in FIG. 3 illustrated embodiment the invention.

In Fig. 3 is again a three-stage transistor amplifier with Tilting properties shown. This amplifier largely corresponds to that in F. i g. 1 shown amplifier. It was therefore in F i g. 3 for those with the F i G. 1 corresponding components have been chosen with the same reference numerals. Instead of Ohmic resistance 6 in F i g. 1 is in FIG. 3 than that from the potentiometer 16 formed control voltage source following electrical valve a semiconductor diode 18 provided: Taking into account the threshold voltage (Au in FIG. 1) of the semiconductor diode 18 the control voltage u can first be selected at which the amplifier switches to the switch-on state. If the threshold voltage of the semiconductor diode 18 deviates from the representation in FIG. 1 high enough above that to flip into the on state minimum required control voltage u at the connector 13, then interfere with small forward resistance of the semiconductor diode 18 certain displacements of the base point the amplifier characteristic no longer. In addition, it is not necessary because of the small forward resistance the consideration of the different control voltage drop at the object the F i g. 1 existing resistance 6. Now stands upon reaching the resulting Threshold voltage of the base-emitter path of the transistor 3 and the semiconductor diode 18 by the control voltage u without a major increase in the control voltage for tilting control current required in the switch-on state is available.

The tilting into the switched-on state will now proceed from point 28 along straight line 29. The supercritical positive feedback can be made so large that the current flowing through the positive feedback resistor 7 is greater than the base-emitter current of the transistor 3 necessary for switching to the switched-on state for safety reasons. A more negative potential can then occur at the plug connection 13 than at the tap 17 of the potentiometer 16 . The semiconductor diode 18 blocks. The amplifier input resistance, which should be low until the start of tilting, suddenly becomes large during the tilting process. In this way, practically the entire current fed in via the positive feedback resistor 7 flows via the base-emitter path of the transistor 3 and supports the flip-flop process, so that the amplifier switches over reliably.

For the switching to the switch-off state, a current gain that changes with an exchange of the amplifier could still appear as a result of a shift in the curve 26 . In this case, too, dimensioning the positive feedback branch for a strongly supercritical positive feedback is advantageous if means are also provided for limiting the control variables that can be generated by positive feedback. A strongly supercritical positive feedback would initially result in a transition to the switch-off state in FIG. 1, the curve 26a lying between points 25a and 27a is followed. However, in order to prevent too great a difference between the response point 28 and the switch-off point 27a or 27 or to allow a transition to the switch-off state at all, the aforementioned means are provided for limiting the control variables that can be generated by strongly supercritical positive feedback. These means exist in the subject matter of FIG. 3 in a semiconductor diode 19 connected in opposite parallel to the semiconductor diode 18. The two diodes can have different properties, in particular different threshold voltages. With the aid of the diode 19 in FIG. 1 the area enclosed by points 28, 30, 25 a, 27 a is reduced by the hatched part of this area. The switching to the switched-off state is not only brought about with a control voltage u corresponding to point 27a, but rather already with a control voltage u corresponding to point 27, in that part of the current flowing through resistor 7 is dissipated through semiconductor diode 19. If the tap 17 of the potentiometer 16 is adjusted in the direction of the zero potential at terminal 2 when the amplifier is switched on, the first case is that the positive feedback voltage at the base-emitter path of transistor 3 is more negative as the voltage between the zero potential and the potentiometer tap 17. The control voltage difference obtained by coupling between the plug connection 13 and the potentiometer tap 17 is limited to its threshold value with the aid of the semiconductor diode 19. The semiconductor diode 19 forms a secondary path to the zero potential at terminal 2. In spite of the supercritical positive feedback brought about with the aid of the resistor 17, the amplifier can thus switch to the switch-off state at a point of the control voltage that has to be defined more precisely than previously.

It should also be mentioned that to protect the transistor 3, an ohmic shear Resistor 31 can be provided. This resistance limits the control current, if too high a control voltage is tapped by means of the potentiometer 16.

With the means according to the invention it is therefore possible to measure the distance and the absolute value of the in FIG. 1, practically straight curves 29 and 26 only more similar even when an amplifier is exchanged for an amplifier Maintain properties more precisely than before.

In the embodiment according to FIG. 3 is a transistor amplifier shown with pnp junction transistors. However, the inventive idea is not limited to such transistors. Rather, amplifiers can be used in the same way with npn junction transistors come into question. Furthermore, a transmission of the According to the invention on other control current amplifiers, for example Magnetic amplifier, conceivable.

Claims (5)

Claims: 1. Replaceable amplifier that requires control current with tilting properties that result from supercritical positive feedback of amplified variables the input of the amplifier are generated, d a -characterized that on a Control voltage source an electric valve (18) follows that the positive feedback branch (7) is dimensioned for a strongly supercritical positive feedback and that means (19) for Limitation (26, FIG. 1) of the control variables that can be generated by positive feedback is provided are (Fig. 3). 2. Amplifier according to claim 1 in the form of a transistor amplifier, characterized in that a semiconductor diode (18) is provided as an electrical valve, the forward voltage drop of which supplies a threshold voltage (du, F i g. 1). 3. An amplifier according to claim 1 or 2 in the form of a transistor amplifier, characterized in that a control voltage source (16) with a low impedance compared to the positive feedback branch (7) and a semiconductor diode (19) connected to this via its one terminal are used as means for limiting the control variables which can be generated by positive feedback ), the other connection of which is connected to the connection point of the positive feedback branch (7) and the amplifier input (3, 31). 4. Amplifier according to claims 2 and 3, characterized in that that the two opposite-parallel connected semiconductor diodes (18, 19) with different Properties are provided. 5. Amplifier according to claim 3 or 4, characterized in that that in the amplifier input in a known manner an additional series resistor (31) is arranged.