DE2925177A1 - Time delay release circuit for relay for windscreen motor - uses RC delay to first transistor switch on so that second is switched off - Google Patents

Abstract

The holding circuit is for a relay. When a start contact is operated a relay operates and remains operated until an RC time constant circuit has charged up to switch it off. The design stabilises the operate time and minimises the variations due to temp. and supply voltage. The system is intended for windscreen washer motor control in vehicles. A start contact (1) is operated and the second transitor (5) conducts to allow the relay (2) to operate. The relay contact (3) holds and operates the required appts. i.e. connects battery (+U) to the washer pump motor. The RC circuit capacitor (7) charges through a resistor (6) and is in the base circuit of the first transistor (4). When charged it switches on the first transistor (4) and the collector current flowing drops the base voltage of the second transistor (5) so that it switches off so de-energising the relay (2), and in turn the relay contact (3) opens. Operational stability is achieved by the emitter coupling of the two transistors by a resistor (11) and the selection of collector resistors where used.

Description

Title: Circuit for delaying actuation

of a relay contact Description The invention relates to a circuit to delay the actuation of a relay contact for which a start contact is provided is and in which the base of a first transistor with a determining the delay The base of the second transistor is connected to the collector of the capacitor first transistor is connected, a coupling of the emitters of the two transistors is provided, an emitter resistor is provided in the emitter circuit of the first transistor and the relay is fed by the second transistor.

In a known circuit arrangement of this type, it is connected to the mains a start contact and a series resistor and are between the two voltage poles a Kionidensator provided in series. The capacitor voltage is across a base resistor to the base of a first npn transistor, the collector of which is connected to a collector resistor to Ius voltage and its emitter to zero potential via an emitter resistor The base of a second npn transistor is immediate connected to the collector of the first transistor. The emitters of both transistors are directly connected. The relay is in the collector circuit of the second transistor provided, i.e. its collector is connected to positive voltage via the relay.

With this relatively inexpensive circuit arrangement, the starts first transistor to draw current as soon as the voltage on the capacitor increases than the sum of the voltage UBE (base-emitter) of the first transistor and the so-called Is the threshold voltage at the emitter resistor. The threshold voltage determining the start of the switchover but depends on the relay resistance. The emitter resistance is as small as possible to keep a lot of voltage available to the relay. But now there is the relay resistance is temperature-dependent, the threshold voltage changes and thus the start of the switchover quite strongly depending on the temperature.

It is therefore an object of the invention to provide a circuit arrangement to create the type mentioned, in which without increasing the circuit complexity greater independence of the threshold voltage from the temperature-dependent relay resistance is reached. The circuit arrangement according to the invention is, solving this problem, characterized in that the relay is provided in the emitter circuit of the second transistor and the coupling of the emitters of both transistors about one takes place at the coupling resistor branching off the emitter resistor.

When the second transistor draws current, the current flows the relay continues to flow, but the relay current no longer flows through the Emitter resistance; the threshold voltage is therefore without increased circuit complexity independent of the rather large temperature-dependent relay resistance.

The sum of the voltage UBE and the threshold voltage is practical constant regardless of the temperature, because as the temperature increases, the The threshold voltage increases somewhat, but the voltage UBE of the first transistor increases sinks. The circuit according to the invention manages without an additional component and also does not include a resistor used for temperature stabilization.

Another advantage is that now the voltage applied to the relay equal to the difference between the mains voltage, e.g. battery voltage, and the residual voltage of the second transistor is.

Because this residual voltage is much smaller than the threshold voltage is, there is an increased voltage on the relay, which is why the relay is less complicated and can be built more easily.

Then there is a voltage stabilization with the circuit according to the invention tied together. It can be seen that the through the capacitor the co-determined delay time is then constant despite varying the mains voltage, if the threshold voltage remains proportional to the respective mains voltage.

This is improved with the circuit according to the invention achieved. E.g. when the mains voltage drops from 12 volts to 6 volts the threshold voltage from 100% to approx. 54%, i.e. the deviation from the desired 50% 0 is low.

The error of a delay circuit, i.e. the deviation from the predetermined delay time depends, among other things, on the temperature and the voltage. The sum of temperature and voltage errors can generally be varied of a component or an additional component. In the inventive Circuit, errors are minimized by suitable selection of the collector resistance. It is particularly expedient and advantageous if the deviation is corrected by means of suitable Dimensioning of the collector resistance of the first transistor at most 5 O / o amounts to. This value can mainly be used for a temperature range of -10 ° up to +600 C and a voltage range of 11 volts to 15 volts.

Possibly the collector circuit of the second transistor or between the emitter of the first transistor and the coupling point of the second transistor another resistor is planned. Particularly useful and advantageous it is, however, if no resistor is provided in the collector circuit of the second transistor and / or if the emitter of the first transistor is directly connected to the emitter resistor connected. This results in particularly favorable conditions with regard to temperature independence and trigger behavior of the circuit.

The circuit according to the invention is preferably used on motor vehicles used and here in particular for actuating the pump of a washing system, preferably of the headlight glass. This pump should only be used for a certain period of time, e.g. Pump water for 0.5 seconds, regardless of how long the start contact is is pressed.

Preferred embodiments of the invention are shown in the drawing and FIG. 1 shows a circuit diagram of an arrangement for delaying actuation a relay contact and FIG. 2 shows a circuit diagram of a further arrangement for delay the actuation of a relay contact, a circuit arrangement according to FIG. 1 has a start contact 1, with which a relay 2 is operated, to which a relay contact 3 is assigned to which a device, not shown, such as a pump motor, is connected is that through Actuation of the start contact set in motion and should be switched off. The circuit arrangement has two similar npn transistors 4, 5 and a series resistor 6 and a capacitor 7 in series. Between The series resistor and capacitor are the basis of the first via a base resistor 8 Transistor 4 connected. The collector of this transistor is connected to the base of the second transistor 5 and connected via a collector resistor 9 to voltage placed. The emitter of the first transistor 4 is connected via an emitter resistor 10 placed at zero potential. The collector of the second transistor 5 is directly connected to voltage placed, whereas the emitter is at zero potential via relay 2. The emitter the two transistors 4, 5 are connected to one another via a coupling resistor 11.

When the start contact 1 is closed, the first transistor blocks 4, whereas the second transistor draws current and works as an impedance converter. That Relay 2 receives voltage, relay contact 3 closes and the one connected to it Facility is put into operation. If start contact 1 remains closed, charging the capacitor 7 slowly. on, whereby the charging time is determined by the series resistor 6 can be adjusted.

As soon as the voltage across the capacitor 7 is greater than the voltage between Base of the first transistor and zero potential, i.e. the sum of the voltage across the emitter resistor 10 and the base-emitter voltage of transistor 4, becomes the first transistor 4 direct. The voltage of the base resistor 8 is negligible. Will If the first transistor 4 is conductive, the second transistor 5, the relay 2, blocks receives one more voltage and relay contact 3 opens, although the start contact is still closed.

When the blocking of the second transistor begins, the voltage drops at its emitter and thus the voltage at relay 2.

This also reduces the so-called threshold voltage at the emitter resistor 10. As a result, the first transistor 4 is accelerated into the conductive state, whereby the blocking voltage of the second transistor 5 is accelerated again. It kicks So the per se known trigger effect on what is important for the circuit arrangement is.

The circuit arrangement according to FIG. 2 also has a start contact 1, a relay 2 and an assigned relay contact 3, which here is a relay break contact is. There are two different types of transistors 4, 5 are provided, of which the first is an npn transistor and the second is a pnp transistor As in fig a pre-resistance 67, a capacitor 7 and a resistance 3 are provided. To the first transistor 4 are a collector resistor 9 and an emitter resistor -10 assigned. Between the emitters of the two transistors i-Ci 0 coupling resistance 11 provided. the collector of the second transistor 5 is directly at zero potential placed and the emitter of the second transistor is the relay 2 is under tension. A quenching diode 12 is provided parallel to the relay 9.

If the start contact 1 is closed, it gets to the closed Relay normally closed contact connected device voltage. First of all, both are transistors 4, 5 blocked. When the voltage across capacitor 7 is high enough, the first Transistor 4 is conductive, whereby the second transistor is also conductive. The relay 2 is now pulling. on, i.e. relay contact 3 is opened, although the start contact is still closed.

Here again the coupling of the two transistors 4, 5 is over the coupling resistor 11 is provided, through which the first transistor 4 accelerates is driven into the conductive state, so that after charging the capacitor 7 the opening of the Relaisliontaktes 3 takes place almost suddenly.

In both circuits of the drawing, the npn transistors can each be replaced by pnp transistors or re-keyed, wenrl (in the drawing) above Zero potential and below a negative voltage is provided. This and others Variations are possible.

Claims (4)

Claims circuit for delaying the actuation of a relay contact, in which a start contact is provided and in which the base of a first transistor is connected to a capacitor determining the delay, the base of the second transistor is connected to the collector of the first transistor, a Coupling of the emitters of the two transistors is provided in the emitter circuit of the The first transistor is provided with an emitter resistor and the relay from the second Transistor fed, characterized in that the relay (2) in the emitter circuit of the second transistor (5) is provided and the coupling of the emitters of both transistors (4, 5) via a coupling resistor (11) branching off at the emitter resistor (10) he follows. 2. Circuit according to claim 1, wherein the deviation from the vorbestnmmten Delay time depending on temperature and mains voltage through suitable Dimensioning of a component is minimized, characterized in that the Deviation due to suitable dimensioning of the collector resistor (9) of the first Transistor (4) is at most 5%. 7. A circuit according to claim 1 or 2, characterized in that im Collector circuit of the second transistor (5) no resistor is provided. 4. A circuit according to claim 1, 2 or 3, characterized in that the emitter of the first transistor (4) directly to the emitter resistor (10) connected.