DE2426115A1 - Multivibrator for motor vehicle - applied for turning indicator and warning blinking lights - Google Patents

Abstract

The multivibrator has a first transistor stage with a feedback capacitor for a second stage with a switching element in the form of a relay with a change-over contact, whose excitation winding is in the first stage transistor emitter-collector circuit. Its fixed contact of the break contact pair is connected to one terminal of the feed-back capacitor and the fixed contact of the make contact pair is connected through a resistor to the other capacitor terminal, which also connected to the transistor base. This resistor serves as a first voltage divider. The movable contact is connected to one terminal of the supply voltage source, whose other terminal is connected via a blinking lamp to the relay make contact.

Description

Multivibrator, in particular for directional and / or hazard warning lights of a motor vehicle (addendum to patent ....... - patent application P 24 06 448.0 -VPA 74/4004) The main patent ...... (patent application P 24 06 448.0) concerns one Multivibrator in particular for a directional and / or hazard warning flasher device Motor vehicle with a first, a transistor containing stage and a Feedback capacitor through which the output of a second, downstream of the first stage and a stage containing a switching element is fed back to the input of this first stage wherein the switching element of the second stage is a relay with a changeover contact is, whose excitation winding in the particular containing the emitter-collector path Power circuit of the transistor of the first stage is whose normally closed contact is the one Connection of the feedback capacitor is connected to its normally open contact the other terminal of the R feedback capacitor located at the control terminal of the transistor across an ohmic resistor designed as a first voltage divider and on the movable contact part of the first pole on the power circuit of the ransi3-tors feeding current source, the second pole of which is above a load, in particular via a flashing lamp, connected to the normally open contact of the relay of the second stage is, wherein between the movable contact part and the second pole of the power source a second voltage divider is connected, the partial tap on the normally closed contact of the Relay is, and at the divider tap of the between the control connection of the control path, in particular the base connection of the transistor and the normally open contact of the relay lying first voltage divider which is one connection of a charging capacitor, its other connection with the further connection of the control path, in particular the emitter terminal, of the transistor is connected. With the multivibrator according to the main patent, which is designed with particularly few components and is therefore an inexpensive one Mass production is possible, lies between the moving contact part of the Switching element of the second stage representing relay and the first pole of the power source the excitation winding of another relay, which can be, for example, a reed relay can, via whose contacts an ohmic resistor parallel to one on the second Pole of the power source lying ohmic resistance of the second voltage divider switchable is that between the movable contact part of the second stage switching member representative relay and the second pole of the power source is switched.

The invention is based on the object of saving even more components and thereby making the mass production of the multivibrator even cheaper.

To solve this problem, a multivibrator is the one mentioned at the beginning Type according to the invention characterized in that between the movable contact part of the relay representing the switching element of the second stage and the first pole of the Power source the excitation winding of another relay, preferably a reed relay, lies, via whose contacts when an excitation winding is excited, the entire between the normally closed contact of the relay with the changeover contact and the second pole of the power source Lying resistance part of the second voltage divider can be switched on and when de-energized this excitation winding can be switched off.

This is compared to the multivibrator according to the main patent ohmic resistance element saved in the second voltage divider.

The invention and its advantages are based on the drawing on one Exemplary embodiment explained in more detail: The drawing shows the circuit diagram of a direction indicator device of a motor vehicle with two times two to each other connected in parallel Flashing lamps 2 and 3. This direction flashing device has a multivibrator a first stage which is provided with a pnp transistor V1. The performance group this transistor V1 contains its emitter-collector path, which is at the terminals 49 and 31 connected to a power supply source (battery) not shown is. The emitter of the transistor V1 is connected to the terminal 49 for the positive pole and the Collector of the transistor V1 at one terminal of the excitation winding K1 Relay with changeover contact, the other connection at connection 31 for the negative pole the power source. A feedback capacitor is connected to the normally closed contact 5 of this relay C2 connected, the other terminal of which is connected to the base of the transistor V1. The movable contact part 4 of the relay is via the excitation winding L2 of a reed relay connected to connection 49 for the positive pole of a power source.

The normally open contact 6 of the relay with the field winding Kl is present a connection 49a for the flashing lamps 2 and 3.

Between the movable contact part 4 of the relay with the excitation winding K1 and the connection 31 for the negative pole of the power source is one of the in Series connected ohmic resistors R2 and R5 existing voltage dividers connected, its connection line between the ohmic resistors R2 and R5 i.e. its Divider tap on the normally closed contact 5 of the relay with the field winding K1. Between the ohmic resistor R5 and the terminal 31 are the contacts-K2 of the one Normally open reed relay with the excitation winding L2. Furthermore is between the base of the transistor V1 and the terminal 49a one of the series connected ohmic resistors R3 and R4 of existing further voltage divider switched. On the connection line between the ohmic resistor R3 and the ohmic resistor R4 i.e.

at the divider tap formed from these two ohmic resistors The voltage divider is connected to one terminal of a charging capacitor C1, the other terminal of which is at the emitter of transistor V1. The excitation winding of the reed relay with contacts K2 is located between the moving contact part 4 of the relay with the field winding K1 and the connection 49 for the positive pole of the power source.

A direction switch is located between the connections 49a and 31 7 two two flashing lamps 2 and 3, each of which is connected in parallel to one another. There is also a shunt resistor in parallel with the field winding Kl of the relay K1 R1.

If the direction switch 7 is open, the base of the transistor is V1 via the feedback capacitor C2, the normally closed contact 5 and the movable contact part 4 of the relay with the field winding Kl and via the field winding L2 of the reed relay connected to the terminal 49 for the positive pole of the power source. But since the Base of transistor Vi plus potential and transistor V1 blocks. The capacitors C1 and C2 are free of charge.

If the direction switch 7 is closed, the first moment is obtained the capacitor C1 through the ohmic resistor R4 and the capacitor C2 through the ohmic resistors R3 and R4 charging current. As soon as the voltage at the base of the transistor Vi is sufficient to control the transistor V1, the excitation coil K1 of an excitation current flowed through it. by moving contact part 4 lifts from the normally closed contact 5 and finally touches the normally open contact 6. At that moment the current flows for the flashing lamps 2 and 3 via the excitation coil'L2 of the reed relay, so that the Contacts K2 of this reed relay close and that through the ohmic resistors Voltage divider formed by R2 and R5 becomes effective. At connection 49a is convenient the potential of the connection 49 for the positive pole of the power source. The movable one Contact part 4 only lifts off the normally open contact 6 when the charging current for the feedback capacitor C2, which flows through the ohmic resistor R5, to control the transistor V1 is no longer sufficient.

At the moment of lifting the movable contact part 4 from the normally open contact 6 disappears the voltage drop at the excitation coil L2 of the reed relay, which through the current flowing through the indicator lamps 2, 3 is caused. Of the Point X at the divider tap of the voltage divider formed from the ohmic resistors R2 and R5, which is connected to the normally closed contact 5, and also received the base of the transistor V1 thus a positive voltage pulse, which prevents the transistor Vi from being turned on, until the movable contact part 4 touches the normally closed contact 5. Furthermore, the the ohmic resistors R2 and R5 formed voltage divider canceled when the Open contacts K2 of the reed relay when the excitation coil L2 is de-energized. Even this creates a positive voltage pulse from point X to the base of the transistor V1 passed on, which prevents this transistor V1 from becoming conductive. In the end was the charging capacitor in the previous controlled state of transistor V1 C1 only to a fraction, e.g. to half, of the base-emitter voltage of the Transistor V1 has been charged. Has the movable contact part 4 of the normally open contact 6 just lifted off, then the indicator lamps 2,3 and the ohmic resistance R4 flowing current not through the transistor Vi, because the charging capacitor Cl still needs reloading.

If the movable contact part 4 touches the normally closed contact 5, the Point X practically at the potential of the connection 49 for the positive pole of the Power source placed. So that the voltage at the base of the transistor Vi is around the The amount of the voltage on the feedback capacitor C2 is more positive than the voltage on the Emitter of transistor V1. The transistor V1 is then safely blocked.

After the movable contact part 4 has touched the normally closed contact 5, becomes the feedback capacitor C2 across the ohmic resistors R3 and R4 as well reloaded via the turn signal lamps 2.3. As soon as the voltage on the feedback capacitor C2 has reached the turn-on voltage of transistor VI, becomes the excitation coil An excitation current flows through Ki again, and the same switching cycle begins all over again.

If one of the indicator lamps 2, 3 has failed, the current is sufficient the excitation coil L2 of the reed relay flows through when the moving contact part 4 touches the normally open contact 6, no longer to close the contacts K2 of the reed relay the end. The feedback capacitor C2 can therefore practically no longer charge current obtained so that it practically no longer has any influence on the flashing frequency of the flashing lamp Has.

This flashing frequency is now primarily used by the charging capacitor C1 and the hysteresis (pick-up / drop-out voltage) of the relay with the excitation coil K1 and the normally closed contact 5 and the normally open contact 6 are determined. This hysteresis exists in that the movable contact part 4 from the normally open contact 6 in the event of a voltage drop (Drop-out voltage) lifts off at the excitation coil K1, which is significantly lower than the voltage drop (pull-in voltage) at which the movable contact part 4 from the normally closed contact 5 takes off.

When the direction switch 7 is pressed, only one of the turn signal lamps becomes 2,3 applied to the connection 49a, the charging capacitor Cl is initially charged, then the transistor VI is turned on via the ohmic resistors R3 and R4. As a result of the exciting current flowing through the exciting coil g1, it becomes the movable one Contact part 4 is finally closed with the normally open contact 6, so the ohmic Resistor R4 practically at the potential of connection 49 for the positive pole of the Power source. The transistor V1 is now receiving by discharging the charging capacitor C1 its base-emitter current. This moves it from the saturation area to the active workspace controlled. Only when the voltage drop across the excitation coil K1 reaches the dropout voltage of the relay, the movable contact part 4 lifts off Normally open contact 6 and the charging capacitor Ci can through the ohmic resistance R4 and the turn signal lamp connected to the connection 49a via the direction switch 7 be recharged. Has the voltage at the base of transistor V1 again When the through-control voltage is reached, the excitation coil E1 is again supplied with an excitation current flowed through, i.e. the voltage drop at the excitation coil E1 exceeds the pick-up voltage, and the same switching cycle starts again.

1 claim

Claims (1)

Patent claim multivibrator in particular for one directional and / or Hazard warning device of a motor vehicle with a first one containing a transistor Stage and a feedback capacitor through which the output of a second, the first stage downstream, and a switching element containing stage to the input this first stage is fed back, wherein the switching element of the second stage Relay with a changeover contact is whose excitation winding in particular the Emitter-collector path containing the power circuit of the transistor of the first Stage is whose normally closed contact is one terminal of the feedback capacitor is connected, to whose working contact the other, to the control connection, in particular Terminal of the feedback capacitor located at the base terminal of the transistor across an ohmic resistor designed as a first voltage divider and on the movable contact part of which the first pole is also the power circuit of the Transistor feeding current source is, the second pole of a load, in particular via a flashing lamp, connected to the normally open contact of the relay of the second stage is, wherein between the movable contact part and the second pole of the power source a second voltage divider is connected, whose divider tap on the normally closed contact of the relay is and where the divider tap of the between the control terminal and the control path, in particular the base connection of the transistor and the normally open contact of the relay lying first voltage divider of one connection of a charging capacitor whose other connection is with the further connection of the control path, in particular is connected to the emitter connection of the transistor, according to patent ....... (patent application P 24 06 448.0 - VPA 74/4004), characterized in that between the movable Contact part (4) of the relay representing the switching element of the second stage and the first pole (49) of the power source the excitation winding (L2) of another relay, preferably a reed relay, is via its contacts (K2) when it is energized Excitation winding (L2) of the entire between the normally closed contact (5) -des relay with the changeover contact and the second pole (31) of the power source lying resistor part of the second voltage divider can be switched on and when the excitation winding (L2) is de-excited can be switched off.