DE2258975B2 - CIRCUIT ARRANGEMENT FOR CURRENT LIMITING AND SWITCHING OFF AN OVERLOAD - Google Patents

Description

interrupting independent switch-delayed shutdown stage is arranged and that the selection of the temperature-dependent resistance in connection with the implementation of the thermal coupling between the resistors is dimensioned so that a switching delay can be achieved that a response the shutdown stage in the event of switch-on current surges.

As a temperature-dependent resistor, NTC thermistors or cheaper PTC thermistors with sharp Kink of the characteristic curve can be used. The circuit arrangement according to the invention has, inter alia, the advantage that the power loss occurring in the event of a short circuit can be kept very small. Accordingly a small design is sufficient for the current limiting resistor.

Further details of the invention are explained in more detail with reference to FIGS.

The circuits according to FIGS. 1 to 4 represent exemplary embodiments for a circuit arrangement for so current limitation and short-circuit shutdown that with simultaneous supply of voltage-sensitive electronic devices or assemblies and from consumers with a high inrush current, e.g. lamp and display panels from a power supply device upstream of the last-named consumer.

The circuit according to FIG. 5 shows a particular application in an arrangement with a time switch to limit the switch-on time of a consumer, with the timer additionally the Takes over the function of the shedding stage.

The circuit arrangement according to FIG. 1, which consists of a current limiter circuit with an adjusting transistor 71 and a switch-off stage S , is connected on the input side to a power supply device (not shown) and on the output side to a strongly fluctuating load indicated by the resistor R _L.

The current limiter circuit is dimensioned in such a way that, in a known manner, there is a characteristic curve _{which has} a largely horizontal part of the characteristic curve in the load current range from J = O to J = J 11111x, i.e. only a small voltage drop occurs in this area, the one in the load circuit The collector-emitter path of the control transistor 71 is connected in parallel to a limiting resistor Rl. In series with this parallel connection and through which the load current flows, a current measuring resistor Rl is indicated, which at the same time supplies the control voltage in the base-emitter circuit of a control transistor Tl. The series connection of the measuring resistor Rl and the collector-emitter path of the control transistor Ti form a shunt to the base-emitter path of the adjusting transistor 71. In the horizontal part of the current-voltage characteristic, the adjusting transistor 71 is controlled by the current flowing through a base resistor Ri and the limiting resistor Al is ineffective. Between the maximum permissible current J _max and the short-circuit current J _K , the voltage drop occurring at the measuring resistor Rl causes the control transistor 71 to conduct and blocks the control transistor 71. The limiting resistor A1 thus takes over the current limitation. If the limiting resistor Rl is dimensioned so that the short-circuit current J _{K is} always greater than the maximum permissible load current J _max , it is ensured that in the event of a short-circuit no or only a small current flows through the setting transistor 71 and thermally stresses this transistor. As a result, a type with a lower power loss can be used for the control transistor. However, so that the limiting resistor Al does not have to absorb the large power loss occurring as a permanent load in the event of a short circuit, the current limiter arrangement is preceded by a disconnection stage S which, in the event of a short circuit, disconnects it from the supply voltage through a contact r of the relay R. The Reiais R is connected in series with a Zener diode and a temperature-dependent resistor R to the supply voltage. The switching state of the relay is controlled by the temperature-dependent resistor, which is thermally coupled to the limiting resistor Al. Since the control transistor 71 is switched on in normal operation, the limiting resistor remains cold and thus an NTC thermistor used as a temperature-dependent resistor has a high resistance. This ensures that the relay is not energized and the associated break contact r is closed. So that short-term inrush currents do not trigger the disconnection stage, the thermal coupling of the limiting resistor and the temperature-dependent resistor is designed in such a way that it has a sufficiently large time constant

In the event of a short circuit, the limiting resistor Rl is strongly heated by the power loss, so that the thermistor R ₁ becomes low-resistance. As soon as the relay responds, the short-circuit current is interrupted by opening the normally closed contact r . If the limiting resistor and the NTC thermistor have cooled down again to a certain temperature after a certain time, the relay drops out and closes the consumer circuit automatically. If the short-circuit is still present at this time, the limiting resistor heats up again and the relay interrupts the short-circuit current again. This process is repeated until the short circuit has been eliminated.

In this circuit, the thermistor can be replaced more cheaply by a PTC thermistor with a sharp bend in the characteristic curve if the relay contact / ■ is designed as a working contact at the same time. In order to avoid creeping reclosure after cooling of the PTC thermistor, a diode Dl is provided, which upon closing of the make contact r, the Zener diode Zl shorts and thereby raises the Relaistrom leaps and bounds.

In the exemplary embodiment according to FIG. 2, the disconnection stage S operates with a transistor-controlled relay. The relay R is connected to the supply voltage in series with the collector-emitter path of the switching transistor Ti and a Zener diode Zl. The base of the switching transistor Ti is connected to the tap of a voltage divider, which is formed by a thermistor as a temperature-dependent resistor R ₁ and a resistor R4 . In the working state, the switching transistor 7'3 is turned on via the resistor RA and the relay contact r is thus closed. In the event of a short circuit, the limiting resistor Rl heats up again. This means that the temperature-dependent resistor becomes low-resistance, conducts the current flowing through the resistor /? 4 to ground, blocks the switching transistor Ti and opens the relay contact 1: After the limiting resistor Rl and the temperature-dependent resistor R have cooled down,

the switching transistor 73 becomes conductive again and the relay contact r closes again. If this circuit is implemented with a PTC thermistor, a normally closed contact must be used instead of a normally open contact.

In the circuit according to FIG. 3, the relay of the previous switching examples is replaced by a switching transistor 76 in the disconnection stage 5. The control circuit is designed as a Schmitt trigger in order not to unnecessarily thermally load the switching transistor 76 when it is switched by rapidly switching the switching transistor. The current limiter arrangement and the thermal coupling of the limiting resistor Rl and temperature-dependent resistor Ä6 are unchanged. The transistors 74, 75, the temperature-dependent resistor R ₁ and the resistors R4 to Rl form a Schmitt trigger, the respective switching state of which is determined by the resistance value of the temperature-dependent resistor. In the normal operating state, the dimensioning of the circuit ensures that the transistor 75 blocks and the current flowing through the resistor R6 switches on the transistor 74, which controls the switching transistor 76 into the conductive state via the resistor R1. The thermistor R ₁ , which is low-resistance due to heating in the event of a short circuit, tilts the Schmitt trigger into its rest position. The transistor T5 becomes conductive. The transistors 74 and 76 are then blocked and thus the short-circuit current is interrupted. Since the switching transistor 76 is switched quickly by the Schmitt trigger, this transistor can also be of a type with relatively low power dissipation. The resistor R1 is dimensioned so that the switching transistor 76 is still in saturation even with a short-circuit current. In the case of higher currents, transistors coupled in a Darlinton circuit can be used for the transistors 76 and T1.
FIG. 4 shows a modified exemplary embodiment for the disconnection stage S of the circuit according to FIG. 3. The switching transistor 76 is replaced by a relay R. The way it works is unchanged.

In the switching examples according to FIGS. 2 and 4, it would also be possible to use a normally closed contact as a relay contact / ■ instead of a normally open contact. In this case the resistor RA would have to be exchanged with the temperature-dependent resistor R i and the circuit would have to be redimensioned accordingly.
Are consumers, e.g. B. lamp fields, when a message change is only switched to the power supply via a timer for a certain time, then the timer - as shown in the arrangement according to FIG. 5 - can also be used for short-circuit protection. The specified by the timer duration can be one of a shutdown relay R. controlling the transistor 77 to be prematurely terminated by a temperature-dependent resistor R ₁ in short-circuit, by supplementing the control circuit.

In Fig. 5, the shutdown stage S is replaced by the timer. Depending on a pulse generator / switchable transistor 77 is located with its collector-emitter path in the circuit of the switch-off relay R _z . The transistor 77 is part of a bistable multivibrator, which is switched on via a pulse at the E input. The control circuit of the transistor 71 is supplemented by the thermistor R ₁₁ , which is thermally coupled to the limiting resistor Rl of the control transistor 71.

For this purpose 2 sheets of drawings

Claims (8)

Shutdown stage (S) has a Schmitt trigger (74, Γ5) controlled by the temperature-dependent patent claims: gene resistor (R1), which has a switching transistor (76), 1. Circuit arrangement for current limitation whose emitter-collector path in the load and disconnection of an overload, in which the Ver 5 circuit is switched on, controls (Fig. 3).
consumer over the with a resistor in series 9. Circuit arrangement according to one of the connected emitter-collector path of a ge Proverbs 1 to 3, characterized in that the controlled setting transistor with a load current GE shutdown stage (S) are fed by a temperature-dependent, which setting transistor through the resistance additionally controlled bistable by an overcurrent at the resistance has 10 flip-flop that periodically interrupts the load circuit in the event of an unprecedented voltage drop in the reverse direction of disrupted operation (Fig. 5). controlled and with the shutdown depending on the heating of a temperature- dependent resistance takes place, the thermally to absorb power loss in the load circuit 15 The invention relates to a circuit characterized in that one of the collector emitting devices for current limitation and disconnection of a section of the setting transistor (71) is connected in parallel - Resistance in series-connected emitter-collector and with the temperature-dependent resistance section of a controlled setting transistor with a stand (R ₁ ) is thermally coupled, which are fed in the load current, which setting transistor control circuit one of the load circuit in the short-cut through an overcurrent on the Resistance final interrupting independent generated voltage drop in the reverse direction switching-delayed shutdown stage (S) is arranged and the shutdown is dependent and that the selection of the temperature dependence on the heating of a temperature-dependent resistance in connection with d it takes place through resistance, which is thermally dimensioned to a switching resistors (Al, R ₁ ) which absorb power loss in the load management of the thermal coupling between the circuit, that the device part is coupled. a switching delay can be achieved that the cut-off stage (S) with switch-on 30 tronic fuse to Schut2: from consumers Prevents electrical surges. is used against overload is already known 2. Circuit arrangement according to claim 1, da- (DT-OS 1513057). One with its emitter collector characterized in that thermistors are used as a temperature-dependent path in the load circuit arranged variable resistor ( R ₁ ). The sistor is thermally coupled with a PTC thermistor. With 3. Circuit arrangement according to claim 1, that 35 the control transistor in series is a measuring resistor, characterized in that provided as a temperature-dependent, the resistor (R ₁ ) when the load is overloaded, PTC thermistor with sharp a limitation of the load current causes by the kink of the curve are used. voltage drop occurring in the control transistor 4. Circuit arrangement according to one of the pre-controls in the blocking direction. The ones that arise at the transistor Claims, characterized thereby- 40 hendc power loss then heats the PTC thermistor, net that the shutdown stage (S) from one to one of the voltage source when its jump temperature is exceeded connected series door via a control transistor device, consisting of a Zener diode (Z), a relay blocks. (R), whose working contact (r) between Span- When supplying electronic devices voltage source and control transistor (71) in the load 45 together with other consumers with high Circuit is arranged, and the temperature inrush current and / or with strongly fluctuating dependent resistance (R ₁ ) is formed (Fig. 1). Load current from a common power supply 5. Circuit arrangement according to claim 4, ding device and »or via a common line, characterized in that the Z-diode (Z) over can inadmissible voltage drops of the Versorden relay contact (r) a forward direction 50 supply voltage the operation of the electronic reverse polarity diode ( D) is connected in parallel (Fig. 1). rate disturb. It is also undesirable that electronic 6. Circuit arrangement according to one of the fuses to see the power supply, for example in Spruchc 1 to 3, characterized in that the short inrush currents interrupt completely.
Shutdown stage (S) from a relay (R) with a relay (R) with a The invention is based on the object of preventing short-term load surges from the switch-off contact (r) and a switching transistor (73) in the circuit of the 55 circuit of the supply voltage through strong relays A base voltage divider is arranged without endangering its base-emitter circuit, a Zener diode (7.2) and the control transistor between the power source and the voltage-dependent resistor (R ₁ ) as part of the consumer through thermal overload. The power loss should be kept very small ( Fig. 2). 60 den. After switching off a short circuit, should 7. Circuit arrangement according to one of the automatic reconnection of the consumer Proverbs 1 to 3, characterized in that they take place. Shutdown stage (S) one of the temperature-dependent This object is achieved according to the invention gen resistor (R ₁ ) controlled Schmitt trigger solved that one of the collector-emitter path of the (74, 75) that connects the relay (R) with the 65 limiting resistor connected in parallel Normally open contact (r) controls (Fig. 4). the state is available and with the temperature-dependent 8. Circuit arrangement is thermally coupled according to one of the resistance, which is in the Steusprüche 1 to 3, characterized in that the circuit of the load circuit in the event of a short circuit