DE2826795A1 - Signal controller overload protection circuit - has disconnection store controller, two threshold switches and flip=flop - Google Patents

Abstract

The circuit controls blinking lights on motor vehicles. It has a disconnection store controlled through a threshold switch by a critical voltage drop across a resistor in series with a power switch and the load. A first threshold switch is between the power switch and the resistor and has a delay element. A second threshold switch is between the power switch and the loads, and outputs of both threshold switches are connected to the setting input of a flip-flop whose blocking output is connected to the blocking input of the signal controller. Its resetting input is connected through the main switch to a voltage source.

Description

Attachment to

Patent application for overload protection circuit for a signal control device, in particular for controlling vehicle flashing lights "The invention relates to a overload protection circuit of the type mentioned in the preamble of claim 1.

An overload protection circuit of this type was described in the German patent application P 27 05 499.5 suggested.

Compared to previously known overload protection circuits of a similar type that with a periodically restarting, electronically controlled shutdown of the load circuit in the event of overload, far the overload protection circuit generic type has the advantage that special measures are to be taken - in Motor vehicle, for example, shutdown and restart of the ignition circuit -, to reset the shutdown memory circuit.

This in particular avoids being switched on again periodically to check whether the overload condition is still present, on average one overload of the voltage source or overload-sensitive components can occur. This also ensures that there is a one-off overload condition Also, the necessary attention is given, while it may not be at all is recognized and thereby a latent error remains when after comparatively For a short time the overload condition has just fallen below the critical value and the automatic reconnection is therefore back to steady-state operating conditions leads.

The invention is based on the object of an over-load protection circuit of the generic type in such a way that they have little circuitry complex assemblies in functionally clear interaction as inexpensive and service-friendly Mass product can be created like it demands the automotive industry for automotive electrical components.

According to the invention, this object is essentially achieved by that an overload protection circuit of the generic type according to the characterizing Features of claim 1 is constructed.

According to this solution, the shutdown memory circuit is controlled on the one hand on inadmissibly high continuous load and on the other hand on extreme overload in the form of a short circuit at the functional for this criterion most meaningful point of the load or longitudinal circle is queried. For these different ones Queries are, however, provided threshold switches configured in a matching manner, whereby only the person who queries for an unacceptably high continuous load with a additional delay element is connected. For manual reset of the once addressed shutdown memory circuit. all it takes is a simple impulse stage between the main operating switch, which is connected to the voltage source is to be provided and the reset input of the bistable multivibrator.

To uncontrolled circuit states, especially with regard to logical ones To avoid links, it is advisable to also take the measure according to the Claim 2 to meet.

It depends on the structure and mode of operation of the signal control device for the use of the overload protection circuit according to the invention in principle not at. Particularly when it is used to control vehicle indicators but it is expedient to use the signal control device as an astable multivibrator according to claim 3 to design because then a commissioning of the signal control device according to Claim 4 and possibly according to claim 5, that is, according to the switching on the flashing lights, circuitry can be implemented particularly advantageously.

The threshold switches are particularly reliable and not prone to failure according to patent claim 6, especially if the measure according to patent claim 2 an overload query takes place in cyclic operation.

The delay element that is connected to that threshold switch is the one for querying any stationary limit or overload condition is used, is then particularly easy to implement according to claim 7.

The implementation of a threshold switch according to claim 8 is circuitry more complex than a threshold switch according to claim 6, but has the advantage in terms of its response behavior in particular to be adjustable within wide limits. So it is based on the application of a control transistor used as it is in the GermanWkatentanmeldung P 27 05 499.5 for the determination the failure of one of several parallel operated Flashing lights is suggested.

The additional measure according to claim 9 is used to define Switching through when the control transistor responds in a threshold switch according to claim 8.

The delay element is also through with this threshold value switch the simple connection of a capacitor can be implemented, which in this case according to Claim 10 is to be provided.

Further features and advantages of the invention emerge from the following Description of one shown in the drawing with a restriction to the essentials preferred application example for an overload protection circuit according to the invention with two different variants for implementing the threshold value switch.

It shows: FIG. 1 in a block diagram a signal control device for Control of vehicle flashing lights with a switch-off memory circuit controlled according to the invention and upstream threshold switches, FIG. 2 shows a preferred circuitry Embodiment for the threshold switch according to FIG. 1 and FIG. 3 is another preferred one Circuitry exemplary embodiment for the threshold value switch according to FIG. 1.

In the overload protection circuit shown in FIG. 1, one is used Signal control device 1 the periodic control of consumers 2, which over one of the signal control circuit 1 electronically controllable transistor as Circuit breaker 3 and one, in this preferred implementation example, manually operable, main operating switch 4 to a voltage source 5, such as the battery a motor vehicle can be connected. The consumers 2 are im illustrated example case to direction indicator flashing lights 6i the optional Can be switched on via a direction indicator switch 7 between the consumers 2 and the circuit breaker 3 is arranged and in the unactuated state a neutral, currentless middle position (see. Fig. 1) assumes.

For querying the existence of overload conditions in the consumer circuit two threshold switches 8 are provided. One of them is available to speak to Short circuit provided across the consumers 2 and therefore between the consumers 2 and the circuit breaker 3 connected; so at a switching point that practical when changing from normal operating conditions to consumer short-circuit drops from the potential of the connection of the voltage source 5 to ground potential, because then practically the entire operating voltage supplied by the voltage source 5 drops across the circuit breaker 3. The second threshold switch 8 should respond, if critical high load conditions are stationary, but not yet at the moment occurring and quickly again decreasing overload conditions such as when switching on a flashing light 6 with a still cold filament. Therefor a delay element 9 is connected to this second threshold value switch 8, and it is with respect to the first-mentioned threshold switch 8 on the opposite Connection of the circuit breaker 3 out. This second threshold switch 8 speaks thus on the load current-dependent increase in a voltage drop across a measuring resistor 10, which is arranged between the circuit breaker 3 and the main switch 4. The resistance value of such a measuring resistor 10 is very small to avoid voltage drop and thus to keep the loss of performance at it as low as possible during normal operation, so that under normal operating conditions with closed, so low-resistance Circuit breaker 3 at both threshold switch inputs 11 practically that of the operating voltage supplied to the voltage source 5 is present.

The threshold switches 8 are designed for when the voltage drops a signal at the output 12 at the input 11 below a predeterminable, critical value to deliver, either in the event of a short circuit or in the case of stationary There is a particularly high load situation in the electrical circuit of consumer 2. In this case, a shutdown memory circuit 13 is controlled in which it is preferably an arbitrarily realizable bistable flip-flop 14. Whose Set input 15 is the threshold switch outputs via an OR circuit 16 12 downstream. When the set input 15 is activated, the bistable flip-flop leads 14 on her Blocking output 17 a signal that is sent via a blocking input 18 blocks the function of the signal control device 1 and activates the circuit breaker 3 - via a driver stage 19 provided in FIG. 1 - ended.

When the shutdown memory circuit 13 is driven once in this way was, the blocking input 18 of the signal control device 1 remains activated and thus the circuit breaker 3 is open until by manual actuation of the main switch 4 the bistable flip-flop 14 was reset again. To do this is your reset input 20 a pulse stage 2n in the form of a differentiating or C-R element is connected upstream, Via the reset input 20 of the bistable flip-flop 14 after opening the main switch 4, for example the ignition switch of a motor vehicle, triggered once in the form of a pulse when the main switch 4 is closed again. Because the series capacitor 22 of this C-R circuit to the operating voltage of the voltage source during stationary operation 5 is charged, it is useful to connect a discharge resistor 23 to it, to ensure that even after the main switch has only been opened for a short time 4 the series capacitor 22 is so far discharged that when the main switch is closed again 4 a voltage drop pulse of sufficient height occurs above the series resistance 24, in order to safely control the reset input 20 of the bistable multivibrator 14 respectively.

If the critical overload condition in the consumer circuit, the to respond to one of the two threshold switches 18 and thus to set the Shutdown memory circuit 13 had led, is no longer present, remains after Switching on the main switch 4 again resets the bistable flip-flop 14, the blocking control at the blocking input 18 of the signal control device 1 is therefore is canceled, and the normal control of the circuit breaker takes place again 3.

ei the preferred implementation of the overload protection circuit according to the invention According to Fig. 1, a blocking holding line 25 is also provided. At once blocked signal control device 1 sets it via the OR circuit 16 (and / or via threshold switch 8 according to FIG. 2) that the bistable flip-flop 14 so long lingers in its set state until due to dominant influence of the pulse at the reset input 20 is done from the main switch 4. This means that there are any floating or vibrating phenomena between the one on top of the other retroactive circuit parts equipped with switching behavior safely avoided. In Fig. 1 is beyond cinc Entkoppll ungs (l Loci {! 4i uiddcln negating The input 46 of the driver stage 19 forces the circuit breaker 3 to open reliably.

When the signal control device 1 is a single pulse generator, for example to control it of motor vehicle flashing lights 6, then it is particularly useful as astable Flip-flop 26 designed from two capacitively coupled switching stages, which can simply be gates 27 in CDIOS technology that are capacitive are coupled to each other. The output of one gate 27 acts above a decoupling resistor 44 because of interconnection with the output of another Stage, as a blocking input 28. This causes this astable flip-flop stage 26 to oscillate prevented by a constant potential is forced at the blocking input 28, im in Fig. 1 illustrated example case 0 potential from the inverted blocking output 17 of the memory circuit 13 via a blocking line 29. The output of the second Gate 27 serves as a pulse output 30 for controlling the circuit breaker 3 via the driver stage 19 and for transmitting a clock signal to threshold switches 8 according to FIG. 2 via the blocking holding line 25 in order to avoid undefined Switching states always only in the cycle of the control of the circuit breaker 3 there provided gate 33 to release.

If the feed input 31 of the signal control device 1 and thus the astable flip-flop 26 between the circuit breaker 3 and the flashing lights 6, namely the switchover 7, is connected to the power circuit 32, has that the particular advantage of controlling one of the two flashing lights 6 by means of of the switch 7 immediately with operation in a light phase, that is, with feeding this Flashing light 6 to begin, as is the case with flashing lights for motor vehicle direction indicators is prescribed. In this case, a switch 7 is selected as the the neutral (currentless) middle position shown in Fig. 1 as the rest position can take.

As shown in FIG. 2, the threshold value switches 8 can be simple each constructed from a CMOS gate 33 with an upstream voltage divider 34 be. Such gates 33 in COS-MOS technology have a defined technology for technological reasons Response threshold on, and via the voltage divider ratio is predeterminable which level at the threshold switch input 11 is required to to achieve an amplitude at the voltage divider tap 35, which is the response threshold towers above the gate input 36. As a delay element 9 (see. Fig. 1) can on Part of the voltage divider 34 connected to ground is simply a capacitor 37 for delay the voltage drop at the voltage divider tap 35 and thus also at the gate input 36 be connected in parallel. This ensures that briefly occurring Overload conditions, for example when a cold flashing light is switched on 6, do not let the threshold switch 8 respond yet; appears at output 12 so only then a shutdown signal, if the overload situation over a certain Sitspanne is pending, which in turn depends on the charging time constant of the capacitor 37 can be influenced by circuitry.

While the implementation example shown in FIG. 2 for a threshold value switch 8 responds directly to voltage fluctuations in the power circuit 32, is based Function of the embodiment shown in FIG. 3 for a threshold switch 8 based on an evaluation of the emitter current of a control transistor 38, which in turn, according to the load-dependent voltage drop across the measuring resistor 10 adjusts. Such a high base bias voltage is applied to a voltage divider circuit 39 tapped against ground that the control transistor 38 is only conductive, if due to minor Load current in the power circuit 32 only one low voltage drop across the measuring resistor 10 and possibly

is present across the closed circuit breaker 3, so that in The example case shown in FIG. 3 shows the emitter voltage am-pnp control transistor 38, i.e. at the threshold switch input 11, despite the high base bias is positive compared to the base voltage. However, if due to impermissibly increasing Load in the power circuit 32 the voltage drop across the measuring resistor 10 - or due to Short circuit the voltage drop across the circuit breaker 3 - rises sharply, this corresponds to a decrease in the voltage at the threshold switch input 11 Ground potential, i.e. a reduction in the emitter current, which now leads to blocking of the control transistor 38 leads. Since thus also the collector current of the control transistor 38 disappears, the voltage drop across the colletor resistor 40 disappears of the control transistor 38, and the voltage at the base of a downstream Control transistor 41 drops from a fairly high value (approximate emitter voltage) Ground potential. This means, however, that the control transistor that was initially blocked 41 now becomes conductive, the positive supply voltage from voltage source 5 and thus L potential is switched through to the threshold switch output 12 will.

In the embodiment of FIG. 3 it is provided between the Collector of the control transistor 41 and the Schwellwserlsc} laLtcr-Au! Ig.lllg 12 still a CMOS gate 42 provide that due to its defined Response threshold also in the case of a sliding reversal process in the control transistor 41 iSwitching behavior, i.e. a defined blocking output signal that starts at the output 12 causes. In the illustrated preferred embodiment is in the circuit the voltage divider circuit 39 to obtain the base bias for the control transistor 38 a diode 43 is provided, which compensates for temperature influences in the operating behavior of the control transistor 38 by correspondingly influencing the base bias serves as it is in detail in the earlier patent application P 27 05 499.5 with regard to the use of a compensation transistor with base-collector short circuit closer is explained.

As a delay element 9 (see. Fig. 1) is also in the embodiment a threshold switch 8 night. 3 again a capacitor 37 is provided. This is now the base-emitter path of the control transistor 41 connected in parallel to with a brief current rise in the power circuit 32 a corresponding drop in the To prevent the base voltage of the control transistor 41.

Claims (10)

"Overload protection circuit for a signal control device, in particular for controlling vehicle flashing lights for a signal control device, in particular for controlling loads in In the form of vehicle flashing lights, with a switch-off memory circuit, which is activated in the event of critical Voltage drop on one, with a circuit breaker and the consumers in series switched, measuring resistor can be controlled via a threshold switch, thereby characterized in that a first threshold switch (8) between the power switch (3) and the measuring resistor (10) connected and with a delay element (9) wired as well as a second threshold switch (8) between the circuit breaker (3) and the consumers (2) and both threshold switch outputs (12) lead to the set input (15) of a bistable multivibrator (14), its blocking output (17) switched to a blocking input (18) of the signal control device (1) and its reset input (20) via a pulse stage (21) and via a main operating switch (4) can be switched to a voltage source (5). 2. Protection circuit according to claim 1, characterized in that of a pulse output (30) of the signal control device (1) an additional blocking hold line (25) on the threshold value switch (8) and on the bistable Tilting stage (14) is performed. 3. Protection circuit according to claim 1 or 2, characterized in that that the signal control device (1) has an astable multivibrator (26) of two capacitive coupled switching stages (gate 27), of which the output of the one at the same time as the blocking input (18) and the output of the other as a pulse output (30) of the signal control device (1) is used. 4. Protection circuit according to one of the preceding claims, characterized characterized in that the signal control device (1) has a feed input (31), between the circuit breaker (3) and the consumers (2) to the consumer power circuit (32) is connected. 5. Protection circuit according to claim 4, characterized in that between the circuit breaker (3) and the consumers (2) a changeover switch (7) with neutral Middle position is arranged. 6. Protection circuit according to one of claims 1 to 5, characterized in that that each threshold switch (8) consists of a CMOS gate (33) with an upstream Voltage divider (34) consists. 7. Protection circuit according to claim 6, characterized in that the Delay element (9) is a capacitor connected in parallel to the gate input (36) (37) is. 8. Protection circuit according to one of claims 1 to 5, characterized in that each threshold switch (8) consists of a control transistor (38) in an emitter circuit with base bias voltage divider circuit (39) and connected to its collector Base of a control transistor (41) in an emitter circuit, the emitter connection of the control transistor (38) represents the threshold switch input (11). 9. Protection circuit according to claim 8, characterized in that on the collector of the control transistor (41) is connected to a CMOS gate (42), whose output represents the threshold switch output (12). 10. Protection circuit according to claim 8 or 9, characterized in that that the delay element (9) has a d =: r base-emitter path of the control transistor (41) is a capacitor (37) which can be connected in parallel.