DE1183577B - Circuit arrangement for achieving a switching delay - Google Patents

Description

Circuit arrangement for achieving a switching delay The invention relates to a circuit arrangement for achieving a switching delay using an RC element, which is interconnected with a diode and transistors is.

Such circuit arrangements are used for a wide variety of purposes used, e.g. B. where two separate switching operations are triggered together, however, the second switching process only takes place after a certain time after the first should come into effect. There are already various solutions to this problem Circuit arrangements become known. So it is known that an electromagnetic Relay received a pull-in and drop-out delay through a short-circuit winding can. The delay times thus obtained can be adjusted by means of adjustable series resistors be varied, but have the disadvantage that the delay times are relatively short are.

Larger pick-up or drop-out delays are used in relay technology among other things also generated by RC elements, especially when a higher supply voltage is available. The switch-on or switch-on generated with such switching arrangements. Switch-off delays can be up to a few seconds, the time being controlled by a control resistor can be adjusted continuously. However, it is disadvantageous that the used Capacities must be very large, especially when with low supply voltages (e.g. 12 V) must be worked. In addition, the switching times are highly dependent on the voltage, so that the scatter range is too large for many applications. Even greater delay times (up to about a minute) are usually achieved with bimetal switches. The pear-shaped switches, however, require relatively large response powers that are not always available. In addition, the long cooling times (recovery times) long pauses are required between the individual switching operations. In addition, they are Switching times are highly voltage-dependent and generally not adjustable, but rather only adjustable within narrow limits in special designs.

The purpose of the present invention is to provide a circuit arrangement to create that does not have these disadvantages of the known arrangements.

The circuit arrangement according to the invention is characterized in that that between the poles of a DC voltage point in series a controllable resistor, a parallel connection of a further adjustable resistor and a diode and the control path of a transistor is connected that in parallel with the series circuit, consisting of the parallel connection of one adjustable resistor and the diode, and the control path has a switch which is at the beginning of the switching process to be delayed is operated so that the diode is turned on so that it is open when the switch conductive and locked when the switch is closed that at the interconnection point between the parallel connection (of diode and adjustable resistor) and the control path one connection terminal of a capacitor is connected, that the second connection: ßklemme this capacitor possibly via a resistor at the pole of the DC voltage source is, on which the first mentioned adjustable resistor is connected, that the output electrode of the transistor is connected to the second connection terminal of the capacitor and that with this output electrode of the transistor the input of a cut trigger known circuit is connected, which their at a certain input voltage Schaltzusxänd changes and thus switches an electronic device or a relay and after the input voltage has dropped below a certain value, switching back causes.

The circuit according to the invention has the advantage that both the switch-on delay as well as the switch-off delay can be regulated separately. In addition, the switching times are largely independent of voltage fluctuations. The switching process now takes place erratically, so that the spark formation on the contacts of a relay no longer occurs appear. The application of the circuit according to the invention is particularly in the case of battery-operated Devices with a low supply voltage are advantageous because of their low energy requirements.

You can also vary the switching time by the resistances of the Schmitt Triggers measured differently. The circuit then speaks z. B. only occurs at a high input value and falls at a low one Value back to the starting position.

It should also be mentioned that a circuit arrangement for the delayed actuation of relays is known from German Auslegeschrift 1027 315, in which the switching delay is also achieved with the aid of an RC element. In this arrangement, too, the RC element is connected together with a diode and with transistors and, of course, other resistors, in a manner similar to that in the subject matter of the invention. The object of the invention differs from the known circuit, however, in that the components mentioned are combined in a completely different way. An indication of the possibility of combining the elements, as taught according to the invention, could not be found by the person skilled in the art from the known circuit. Compared to the known circuit, the circuit according to the invention has the advantage that, as mentioned above, the switch-on delay and the switch-off delay can be regulated separately. Furthermore, as will be shown below, in the circuit according to the invention according to a further development of the invention, it is possible to shorten the recovery times of the circuit.

The arrangement described so far still has (as just indicated) the disadvantage that with a corresponding position of the threshold values for the Schmitt trigger relatively long recovery times are necessary. According to a further development of the invention these recovery times can be greatly reduced; this will be done on the output electrodes the Schmitt trigger switching means switched on, the pulses from the switching process derive. With these pulses switching paths are then controlled, once during the charging process of the mentioned capacitor from the time of switching the Schmitt triggers to greatly accelerate the charging process by changing the charging resistor is bridged, and on the other hand during the unloading process after tilting back the Schmitt trigger in the initial state shorten the discharge time by shorting the discharge resistor will.

In FIG. 1 of the drawing shows an embodiment of the invention. The terminals of the DC voltage source are labeled 1 and 2. Between these terminals is a series circuit, formed from the resistor 3, the adjustable resistor 4, the parallel connection of the adjustable resistor 5 and diode 6 and the base-emitter path of a transistor B. In parallel with this parallel connection of the elements 5 and 6 and the In the base-emitter path there is a switch 7, via which the switching signal to be delayed is input. At the interconnection point of the members 5, 6 and 8, one terminal of an electrolytic capacitor 9 is also connected. The other terminal of the electrolytic capacitor 9 is connected to the negative pole of the DC voltage source via a resistor 10 that can be regulated here. Likewise, the output electrode of the transistor 8 is connected to this pole via resistors. Furthermore, the output electrode of the transistor 8 is connected to the control electrode of a transistor 11 connected as an impedance converter. The Schmitt trigger circuit, formed from resistors 12 to 15 and transistors 16 and 17, is controlled by the emitter current of this transistor. While a resistor 18 is switched on in one output circuit, a relay 19 is switched on in the other output circuit, which relay should switch with a delay in relation to the time the switch is actuated: 7.

The mode of operation of the circuit arrangement described up to now is as follows: When the switch 7 is open, the capacitor 9 is almost discharged, since the voltage drop across transistor 8 (breakdown) is low. The voltage drop at the part of the potentiometer 10 between the output electrode of the transistor 8 and the second terminal of the capacitor 9 causes the capacitor 9 to be precharged, by means of which both the pull-in delay and the drop-out delay can be varied together. The emitter current of the transistor 11 is thus low. The circuit is dimensioned such that when the emitter current of the transistor 11 is low, the transistor 17 of the Sehmitt trigger has a large collector current. If, however, the switch 7 is closed, then the capacitor 9 is charged with a time constant which can be set by means of the resistor 5 and brings the voltage at the base of the transistor B to zero. During the charging process, the collector current of transistor 8 becomes smaller and smaller, with the result that the emitter current of transistor 11 increases. This increases the potential at the base of transistor 16 : At a preset potential, the Schmitt trigger circuit flips over and the collector current of transistor 16 pulls relay 19. The time of response can be brought about by presetting the threshold on the Schmitt trigger, but also by changing the charging resistor 5. The transistor 8 simultaneously linearizes the charging curve of the capacitor 9.

If now the switch opening 7 again, the diode 6 becomes conductive and the capacitor 9 is discharged through the resistor 4. In order that the potential is negative again at the base of the transistor 8 and transistor 8 is always low impedance. As a consequence of this, the potential at the base of the transistor 16 drops, and at a predetermined value of the potential which, for example, can be equal to or less than the potential of the first flip-over process, the Schmitt trigger flips back. In the present exemplary embodiment, the resistors are selected in such a way that the two potentials triggering the tilting are different from one another. The circuit has thus returned to its initial state; the relay drops out again. As already indicated above, the controllable resistor 10 is also a determining factor for the fall time.

In order to ensure that the switch can be operated again shortly after the respective tilting processes, without assuming incorrect values of the state of charge, it must be ensured that the final state - i.e. full charge or charge approximately equal to zero - is achieved shortly after the tilting process. will be produced. For this purpose, pulses are derived from the collectors of the transistors 16 and 17 by means of the resistors 20 and 22 and the capacitor 21 and 23, respectively. Tilts z. B. the Schmitt trigger in the position in which the transistor 17 is blocked, then the capacitor 21 will charge. Here, the point between the two resistors 20 is given a more negative potential. This opens the switch 24 and thus bridges the charging resistor 5. The charging up to the final value is thus greatly accelerated. In FIG. 2 this is indicated. The charging curve (state of charge over time) bears the reference number 26. At point 27, the switching of the Schmitt trigger is triggered. At the same moment, the transistor 24 is turned on, and the charging now proceeds according to the curve part 28 and not according to the dashed part of the curve 26. The final state is thus reached very soon after the point in time of the tipping over. When the Schmitt trigger tilts back (point 29 of the discharge curve 30 according to the right-hand part of FIG. 2), the switching elements 22 and 23 control the transistor 25, whereby the discharge proceeds from point 29 onwards according to part 31 of the discharge curve. The curves 26 and 30 can be set separately with the aid of the resistors 4 and 5, as already explained above. In addition, the potentials at which the tilting processes are triggered are determined by presetting on the Schmitt trigger. With fixed values (points 27 and 29) of the Schmitt trigger, the charging curve and thus the switch-on delay can be selected by setting the resistor 5, while the discharge curve and thus the switch-off delay can be varied using the resistor 4.

Claims (4)

Claims: 1. Circuit arrangement for achieving a switching delay using an RC element, which is interconnected with a diode and transistors is that between the poles of a DC voltage source in series a controllable resistor, a parallel connection of another controllable resistor Resistor and a diode and the control path of a transistor switched are that in parallel with the series connection, consisting of the parallel connection of the an adjustable resistor and the diode, and the control path a switch lies, which is actuated at the beginning of the switching process to be delayed, that the Diode is switched on in such a way that it is conductive when the switch is open and when closed switch is locked that at the interconnection point between the Parallel connection (of diode and adjustable resistor) and the control path Terminal of a capacitor is connected that the second terminal this capacitor possibly via a resistor at the pole of the DC voltage source is, on which the first mentioned adjustable resistor is connected, that the output electrode of the transistor is connected to the second connection terminal of the capacitor and that with this output electrode of the transistor the input of a Schmitt trigger known circuit is connected, which their at a certain input voltage Switching state changes and thus an electronic device or a relay switches and after the input voltage has dropped below a certain value, switching back causes. 2. Circuit arrangement according to claim 1, characterized in that the Resistance between the second capacitor terminal and one pole of the DC voltage terminal is designed as a potentiometer, with the tap of the second capacitor terminal is connected, and that the output electrode to the third terminal of this resistor of the transistor is switched on. 3. Circuit arrangement according to claim 1 or 2, characterized in that switching means at the output electrodes of the Schmitt trigger are switched on, which derive pulses from the switching process of the Schmitt trigger, and that switching paths controlled by this pulse are connected to the capacitor are such that when the capacitor is charging after switching over the Schmitt triggers the charging resistance and, if the capacitor is discharging, after it has occurred Switching back the Schmitt trigger, the discharge resistor is bridged. 4. Circuit arrangement according to claim 1, characterized in that the Schmitt trigger is constructed in this way is that the two tilting processes (tilting and tilting back) at different, if necessary adjustable input potentials are triggered. Considered publications: German publication No. 1027 315.