DE3235851A1 - Circuit arrangement for connecting and disconnecting a supply voltage to a and from a load, respectively - Google Patents

Abstract

In a circuit arrangement for connecting and disconnecting a supply voltage to a and from a load, respectively, particularly to a and from a microprocessor, respectively, a voltage measuring device (M) is used for measuring the supply voltage and for outputting a control signal in the case where the supply voltage reaches a predetermined first voltage value (U1). The control signal is used for controlling a self-latching output circuit (T1, T2) from the blocked state to a self-latching state. In the self-latching state, this output circuit (T1, T2) forwards the supply voltage to the load; it measures the supply voltage supplied to the load and then passes back to the blocked state when the supply voltage occurs with a predetermined second voltage value (U3) which is below the said first voltage value (U1). <IMAGE>

Description

Circuit arrangement for switching on and off a

Supply voltage to or from a consumer The invention relates to a circuit arrangement for switching on and off a supply voltage to or from a consumer, in particular to or from a microprocessor, with a voltage measuring device measuring the supply voltage, which at with a certain voltage value occurring supply voltage a control signal outputs, and with a switching device connected to the consumer, which by said control signal is controllable.

A circuit arrangement of the type indicated above is general already known (magazine "Electronics" 1974, issue 5, pages 183, 184, in particular 13, 14).

A disadvantage of this known circuit arrangement is, however, that this is the switching on and off of the supply voltage to or from causes the consumer at a predetermined value of the supply voltage, so that it can lead to undesirable switching operations in the event that the supply voltage just has a value that corresponds to the value required for switching.

The invention is accordingly based on the object of showing a way as in the case of a circuit arrangement of the type mentioned at the outset in a simple manner it can be ensured that the switching on and off of the supply voltage to or from a consumer with different voltage values of the supply voltage can be done.

The object indicated above is achieved with a circuit arrangement of the type mentioned according to the invention in that the voltage measuring device when the relevant supply voltage occurs with a specified first Value a control signal to a latching output circuit forming the switching device emits, which as a result goes from a locked state to a self-holding state, in which the supply voltage is passed on to the consumer and from which the output circuit in question is in its locked state again it can be traced back that the output side connected to the consumer voltage lying below a predetermined value lying below said first value has second value.

The invention has the advantage that on relatively simple Way it is ensured that the connection of the supply voltage to a consumer and switching off the supply voltage from the relevant consumer such different supply voltage levels take place that no switching problems whatsoever appear. In addition, the invention advantageously enables a so-called hard switching on of the supply voltage for a consumer, in particular for a microprocessor after the relevant supply voltage mentioned has reached or exceeded the first fixed value.

In addition, the invention advantageously enables the rapid Switching off the supply voltage in the event that this is with the mentioned second Voltage value occurs which is below said first voltage value. This then ensures in a simple manner that the relevant Circuit arrangement provided with the supply voltage consumer only as long as a supply voltage is supplied, such as its safe working is guaranteed.

A diode arrangement is expediently connected to the voltage measuring device in series, the voltage drop across the diode array controlling the self-sustaining Output circuit is used. This has the advantage of being particularly low Circuit expenditure with regard to the control of the latching output circuit.

But it is also possible to use one with the voltage measuring device in Series resistor to which a transistor is connected to whose help the latching output circuit can be controlled.

This has the advantage of a particularly effective control the latching output circuit.

The latching output circuit preferably contains two transistors opposite conductivity types. This has the advantage of being particularly easy buildable self-holding output circuit with itself.

To the supply voltage to be forwarded to the consumer Limiting or stabilizing a given voltage value is the task of the voltage measuring device preferably formed by a shunt regulator.

Another advantageous embodiment of the invention is that Form voltage measuring device by a voltage comparator. This brings the Advantage of a particularly simple circuit structure with it.

The invention is exemplified below with reference to drawings explained in more detail.

Figure 1 shows an embodiment of a circuit arrangement according to the invention.

In a voltage-time diagram, FIG. 2 shows the course of one of the Circuit arrangement according to Figure 1 on the input side supplied supply voltage.

In a voltage-time diagram, FIG. 3 shows the course of one of the circuit arrangement according to Figure 1 delivered to a consumer supply voltage.

FIG. 4 shows a further exemplary embodiment of a circuit arrangement according to the invention.

The circuit arrangement shown in Figure 1 has the input side a voltage measuring device M, which is a shunt regulator, for example of the type TL 431 from Texas Instruments or a voltage comparator. The measuring device M is according to Figure 1 with a measuring input at the connection point of two resistors R1, R2 connected, which are between input terminals e and o, which one Voltage can be supplied, which represents a supply voltage for a consumer, which can be formed, for example, by a microprocessor and between Output connections a and o of the circuit arrangement concerned be connected target.

The voltage measuring device M lies with its working current path via a diode arrangement also to the Input connectors e and o. In the present case, the diode arrangement comprises two in the same direction in series switched diodes D1 and D2. These two diodes D1, D2 are also a resistor R3 connected in parallel. With the junction of the diode array and the resistor R3 on the one hand and the voltage measuring device M on the other hand is a resistor R6 connected, which via a further resistor R7 to the base of a transistor T1, which is of the pnp conductivity type.

This transistor T1 lies with its emitter-collector path between the input connection e and the output connection a of the circuit arrangement.

Between the output connection a and the connection already mentioned o two resistors R4 and R5 are provided in series with one another. At the connection point the resistors R4, R5, a transistor T2 is connected to its base. This Transistor T2 is with its collector at the junction of the already mentioned Resistors R6, R7 and connected to its emitter at connection o. The transistor T2, which is of the NPN conductivity type, together m t forms the transistor T1 self-holding output circuit, which is controlled via the resistor R6 from a blocking state - in which both transistors T1 and T2 are blocked are - can be converted into a conductive state in which both transistors T1 and T2 are conductive and in which the input terminal e with respect to the Connection o supplied input resp.

Supply voltage is forwarded to the output terminal a and thus reaches the consumer connected there.

In addition to the elements considered above, the one shown in FIG Circuit arrangement one more Capacitor C on which it is may be a smoothing electrolytic capacitor.

With reference to the voltage-time diagrams shown in FIGS the circuit arrangement considered above is explained in more detail. In the diagram According to FIG. 2, the profile of the input connection e is related to the connection o the voltage Ue that occurs as a function of the time t is illustrated. The diagram according to Figure 3 shows the course of the output terminal a in relation to the terminal o occurring output or. Supply voltage Ua as a function of time t, that is, the course of the supply voltage that is available at the connections a and o connected consumers is supplied.

As can be seen from Figure 2, the input supply voltage increases Ue initially gradually increases between the connections e and o, whereby - as shown in the figure 3 reveals - when the voltage value U1 is reached, a control and switching process he follows. In this case, namely, the measuring device M responds and performs over its Working current path a current that leads to such a voltage drop across the diode array Dl, D2 leads to the fact that the transistor T1 and thus also the transistor T2 of the self-holding Output circuit in the conductive state. Via the emitter-collector path T1 of the then conductive transistor T1 is then the input connection e with the output connection a connected to the circuit arrangement under consideration. This creates a between the Connections a and o of connected consumers with a corresponding supply voltage provided.

The latching output circuit with the transistors T1 and T2 remains in their conducting state or self- state of affairs even if the voltage drop across diodes D1 and D2 drops again a little. The relevant self-holding state of the output circuit under consideration remains as long until the output voltage resp.

the output-side supply voltage between the connections a and o reaches or falls below a value U3, i.e. a voltage value, which is below the voltage value U1. The relevant voltage value U3 is sufficient the relationship U3 = UBE (1+ R4 75 where UBE is the base-emitter voltage of the transistor T2, with R4 the resistance of the resistor R4 and with R5 the Resistance of the resistor R5 are designated.

In the circuit arrangement explained above, the measuring device measures M is the supply voltage supplied to the relevant circuit arrangement on the input side and emits a control signal when a predetermined first voltage value Ul is reached from, upon its occurrence, the latching output circuit with the two Transistors T1 and T2 come into their self-holding state. The output circuit in question then automatically monitors the on the output side of the circuit arrangement in question occurring supply voltage and is then brought back to its blocking state, when this output-side supply voltage reaches a voltage value U3 or falls below, which is lower than the aforementioned voltage value Ul. Here can the voltage measuring device M either be a voltage comparator, or by a shunt regulator can be formed, the input side fed to the connections e and o Supply voltage Ue limited or stabilized to a predetermined value U2 and thus a corresponding stabilization also with regard to the causes supply voltage Ua on the output side. These relationships are in figures 2 and 3 indicated.

FIG. 4 shows a modification of the circuit arrangement shown in FIG illustrated. In Figure 4, those circuit elements are those in the Circuit arrangement according to Figure 1 correspond to circuit elements used, with denotes the same reference numerals as in FIG. 1. In contrast to those in FIG 1 is only shown in the embodiment according to FIG a single resistor R3 to the operating current path of the voltage measuring device M connected in series. At the connection point of this resistor R3 with the voltage measuring device M is connected to the base of a transistor T3 of the pnp conductivity type is. This transistor T3 is connected with its emitter at the input terminal e, and with its collector is the transistor T3 through a resistor R9 to the base of the transistor T2 connected to the latching output circuit. The base of transistor T1 the latching output circuit is connected to the input terminal via a resistor R8 e connected. The rest of the structure of the circuit arrangement according to FIG. 4 agrees corresponds to the structure of the circuit arrangement shown in FIG.

With regard to the circuit arrangement shown in FIG. 4, it should be noted that that this works in the same way as the circuit arrangement shown in FIG.

Accordingly, the voltage device M measures that between the terminals e and o supply voltage occurring on the input side in order to be able to withstand the certain specified first voltage value U1 to output a control signal. Because of this Control signal, the transistor T3 is controlled in the conductive state, which is thereby the transistor T2 controls in the conductive state. this has to the The result is that the transistor T1 then also becomes conductive. So is the self-holding output circuit, consisting of the two transistors Ti and T2 in the self-holding state. From this self-holding state, the relevant one returns Output circuit then back to its blocking state when the between the Connections a and o occurring output-side supply voltage the voltage value U3 reached or falls below it. The height of this voltage value is also given here by the relationship already given above.

Finally it should be noted that by monitoring the mentioned supply voltage on the output side with the aid of the latching output circuit Malfunctions can be taken into account, which are on the output side of the relevant Circuit arrangement occur and the supply voltage there, for example let it sink as a result of a short circuit. The explained forwarding of the supply voltage only in the event that this supply voltage has the voltage value considered above U1 has reached, and the associated hard voltage connection to the consumer connected between the connections a and o can in the case a microprocessor in a convenient way to generate an internal reset be exploited.

6 claims 4 figures

Claims (1)

Claims 1. Circuit arrangement for switching on and off a supply voltage to or from a consumer2, in particular to a or from a microprocessor, with a measuring the supply voltage (Ue) Voltage measuring device (M), which at a certain voltage value (U1) occurring supply voltage (Ue) emits a control signal, and with a the consumer connected switching device (T1, T2), which by said control signal it is controllable that the voltage measuring device (M) when the relevant supply voltage (Ue) occurs with a specified first value (Ui) a control signal to a switching device (T1, T2) forming self-holding output circuit (T7, T2) emits, which thereby from a blocking state enters a self-holding state in which the transmission of the supply voltage to the consumer and from which the relevant output circuit (Tl, T2) can be returned to their locked state in that the at their with the consumer connected output side (a, o) lying voltage one below said first value (ui) lying predetermined second value (U3). 2o circuit arrangement according to claim 1, d a d u r c h e k e n n z e i c h n e t that with the voltage measuring device (M) a diode arrangement (D1, D2) is in series and that the voltage drop across the diode array (D1, D2) to Control of the latching output circuit (T1, T2) is used. 3. Circuit arrangement according to claim 1, d a d u r c h g e k e n n z e i c h n e t that with one lying in series with the voltage measuring device (M) Resistor (R3) a transistor (T3) is connected, with the help of which the self-holding Output circuit (T1, T2) can be controlled. 4. Circuit arrangement according to one of claims 1 to 3, d a d u r c h g e k e n n n z e i c h n e t that the latching output circuit (T1, T2) contains two transistors (T1, T2) of opposite conductivity types. 5. Circuit arrangement according to one of claims 1 to 4, d a d u r c h g e k e n n n n e i c h n e t that the voltage measuring device (M) is a shunt regulator (Damn. 6. Circuit arrangement according to one of claims 1 to 4, d a d u r c h g e k e n n 2 e i c h n e t that the voltage measuring device (M) is a voltage comparator (Damn.