DE2258975A1 - CIRCUIT ARRANGEMENT FOR SHORT CIRCUIT DISCONNECTING AND CURRENT LIMITING FOR CONSUMERS WITH HIGH INRUSH CURRENT - Google Patents

Description

Circuit arrangement for circuit breaker and current limitation for consumers with high inrush current I) The invention relates to a circuit arrangement for short-circuit shutdown and current limitation for consumers with high switch-on currents and / or with heavily fluctuating load current using a current regulating circuit with a controlled transistor through which the load current flows.

To the semiconductor actuator in control circuits in case of overcurrent or To protect short circuit from thermal destruction, it is known to change the temperature to be monitored by a thermal switch on the cooling element of the actuator. When over - The maximum allowable temperature on the heat sink is exceeded by closing of the thermal switch, a relay is activated, which controls the amplifier of the control circuit switches off - and thus blocks the conductor control element (S.W. Wagner, power supply electrical circuits and devices, R.V. Deckers Verlag, 1964, page 47?). It is also known as overcurrent protection when switching on rectifiers NTC thermistors to use (saw. Wagner, power supply of electrical circuits and devices, 1964; Page 378) .- The invention is based on the object by inrush currents or short circuit caused voltage drops in the operating voltage electronic Devices that share a common power supply with other consumers and / or are supplied via a common line, by a current limiter circuit with To avoid short-circuit shutdown. The power loss should be kept very small. After switching off a short circuit, should the restart takes place automatically.

This object is achieved according to the invention in that one of the Collector-emitter path of the transistor, current limiting resistor connected in parallel with a temperature-dependent resistor as part of a thermal shutdown stage is coupled in such a way that a time-delayed interruption of the load circuit he follows.

As a temperature-dependent resistor, NTC thermistors or cheaper PTC thermistors with a sharp kink in the characteristic curve can be used. The switching delay can be done by selecting the temperature-dependent resistor and the implementation the thermal coupling determined and in particular carried out so that the Inrush currents do not lead to an interruption of the load circuit.

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 can. Accordingly, the current limiting resistor has a small design sufficient.

Further details of the invention will become apparent with reference to FIGS explained in more detail.

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

The circuit of Fig. 5 shows an embodiment with a Time switch for limiting the duty cycle of a consumer, the time switch also takes over the function of the deactivation stage.

The circuit arrangement according to FIG. 1, which consists of a current limiter circuit with a control transistor T1 and a switch-off stage S is on the input side with a power supply device, not shown, and on the output side with one connected by the resistance RL indicated strongly fluctuating load.

The current limiter circuit is dimensioned so that there is a characteristic curve results, which in the range of the load current from J = 0 to J = Jmax is largely horizontal Part of the characteristic curve, i.e. that there is only a small voltage drop in this area occurs. The collector-emitter path of the control transistor in the load circuit T1 is connected in parallel to a limiting resistor R1. In series with this one Parallel connection and through which the load current flows, a current measuring resistor R2 is indicated, at the same time the control voltage in the base-emitter circuit of a control transistor T2 delivers. The series connection of the measuring resistor R2 and the collector-emitter path of the control transistor T2 form a shunt to the base-emitter path of the control transistor T1. The control transistor Ti is in the horizontal part of the current-voltage characteristic controlled by the current flowing through a base resistor R3 and thus the limiting resistor R1 ineffective. Between the maximum permissible current Jmax and the short-circuit current JK is determined by the voltage drop occurring at the measuring resistor R2 the Control transistor T2 conductive and blocks control transistor T1. The limiting resistor R1 takes over the current limitation. Becomes the limiting resistor R1 dimensioned so that the short-circuit current JK is always greater than the maximum permissible Load current is Jmax, it is ensured that in the event of a short circuit no or only one low current flows through the control transistor T1 and this transistor thermally claimed. As a result, a type with a lower power loss can be used for the control transistor be used. So that the limiting resistor R1, however, in the event of a short circuit does not need to absorb large occurring power loss as a continuous load, is the Current limiter arrangement is preceded by a disconnection stage S, which this in the event of a short circuit disconnects from the supply voltage by a contact r of the relay R. The relay R is connected in series with a Zener diode and a temperature-dependent resistor Rt connected to the supply voltage. The switching state of the relay is from controlled by the temperature-dependent resistance, the one with the limiting resistance R1 is thermally coupled. In normal operation, the control transistor T1 is turned on is, the limiting resistor remains cold and thus a temperature-dependent Resistance of the thermistor used is high. This ensures that the Relay not energized and the associated break contact r is closed. So short-term Inrush currents do not trigger the shutdown stage, is the thermal coupling of limiting resistance and temperature-dependent resistance designed so that it has a sufficiently large time constant.

In the event of a short circuit, the limiting resistor R1 is reduced by the power loss strongly heated, as a result of which the thermistor Rt becomes low-resistance. As soon as the relay responds, the short-circuit current is interrupted by opening the normally closed contact r. Are the limiting resistor and the NTC thermistor open again after a certain time cooled down a certain temperature, then the relay drops out and closes the consumer circuit automatically. If the short circuit is still present at this time, it will heat up Limiting resistor in turn and the relay interrupts the short-circuit current again. This process is repeated until the short circuit is removed in this The NTC thermistor can switch more cheaply by using a PTC thermistor with a sharp kink in the characteristic curve be replaced if the relay contact r is designed as a normally open contact at the same time is. To avoid a gradual restart after the PTC thermistor has cooled down, a diode Dl is provided which, when the normally open contact is closed, it r the Zener diode Z1 short-circuits, and thereby the.

Relay current increases by leaps and bounds.

In the exemplary embodiment according to Sig. 2, the disconnection stage S also works a transistor-controlled relay. The relay R is in series with the collector-emitter path of the switching transistor T3 and a Zener diode Z2 at the supply voltage. The base of the switching transistor 23 is connected to the tap of a. Voltage divider connected, that of a thermistor as a temperature-dependent resistor Rt and a resistor R4 is formed. In the working state, the setting transistor T3 is via the resistor R4 activated and thus the relay contact r closed. Heated in the event of a short circuit the limiting resistor R1. This becomes the temperature-dependent resistance low resistance, diverts the current flowing through resistor R4 to ground, blocks the control transistor T3 and opens the relay contact r. After the limiting resistor has cooled down R1 and the temperature-dependent resistor Rt, the control transistor T3 becomes conductive again and the Relay contact r closes again. When performing this circuit with a PTC thermistor, a normally closed contact must be used instead of a working coritact will.

In the circuit according to FIG. 3, the relay is in the disconnection stage S of the previous switching examples replaced by a switching transistor T6. the The control circuit is designed as a Schmitt trigger in order to switch over by quickly switching the transistor T6 not to put an unnecessary thermal load on it. The current limiter arrangement and the thermal coupling from the limiting resistor R1 and temperature-dependent resistor R6 are unchanged.

The transistors T4, T5, the temperature-dependent resistor Rt and the resistors R4 to R7 form a Schmitt trigger, its respective switching state is determined by the resistance value of the temperature-dependent resistor. in the normal operating condition is ensured by the dimensioning of the circuit, that the transistor T5 blocks and the current flowing through the resistor R6 denotes Transistor T4 turns on, which via the resistor R7 the switching transistor T6 controls the conductive state.

The thermistor Rt, which is low-resistance due to heating in the event of a short circuit, tips over the Schmitt trigger in its rest position. The transistor T5 becomes conductive. The transistors T4 and T6 are then blocked and the short-circuit current is interrupted. Since the Switching transistor T6 is switched quickly by the Schmitt trigger, this can Transistor can also be of a type with relatively low power dissipation. The resistance R7 is dimensioned so that the switching transistor T6 is still in the saturation is. At higher currents, transistors T6 and T1 in Darlinton circuit coupled transistors are used.

4 shows a modified exemplary embodiment for the shutdown stage S of the circuit of FIG. 3. The Switching transistor T6 is through Relay R replaced, the mode of operation is unchanged.

In the. Switching examples according to Fig. 2 and 4, it would also be possible to use a normally closed contact as relay contact r instead of a normally open contact. In this case the resistor R4 should have the temperature-dependent resistor Rt interchanged and the circuit redimensioned accordingly.

Are consumers, e.g. lamp fields, when a message changes switched to the power supply via a time switch only for a certain time, then the time switch as in the embodiment of FIG. 5 in addition to Short circuit protection can be used. The duty cycle determined by the timer can by supplementing the control circuit of a transistor controlling a cut-off relay Rz T7 terminated prematurely by a temperature-dependent resistor Rt in the event of a short circuit will.

In Fig. 5, the shutdown stage S is replaced by the timer. The transistor T7, which can be switched off as a function of an impulse prayer I, is also present its collector-emitter path in the circuit of the cut-off relay Rz. The transistor T7 is part of a bistable multivibrator that is switched on via a pulse at input E. will. The control circuit des.Transistor T7 is supplemented by the thermistor Rtl, the is thermally coupled to the limiting resistor R1 of the control transistor T1.

11 claims 5 5 figures

Claims (11)

P a t enta n p r ü c h e 1. Circuit arrangement for short-circuit shutdown and current limitation for consumers with high inrush current and / or with strong fluctuating load current using a current control circuit with one-in from Controlled transistor through which the load current flows, c a -d u r c h g e k e n n z e i c h n e t that one of the collector-emitter path of the transistor (Ti) is parallel Switched current balancing resistor (R1) with a temperature-dependent resistor (Rt) is thermally coupled as part of a shutdown stage (S) in such a way that a time-delayed The ì «branch circuit is interrupted. 2. Circuit arrangement according to claim 1, d a d u r c h g e k e n n notices that the switching delay is due to the selection of the temperature-dependent: gen Resistance (Rt) and the implementation of the thermal coupling is determined. 3. Circuit arrangement according to claim 1 or 2, d a -d ur c h g e k It is noted that the thermal coupling between the current limiting resistor and temperature-dependent resistor is designed so that inrush currents do not by interrupting the load circuit. 4. Circuit arrangement according to one of the preceding claims, d a d u r c h g e k e n n n z e i c h n e t that as a temperature-dependent resistance NTC thermistors can be used. 5. Circuit arrangement according to one of the preceding claims, d a d u r c h g e k e n n n z e i c h n e t that as a temperature-dependent resistance PTC thermistors with a sharp kink in the characteristic curve can be used. 6. Circuit arrangement according to one of the preceding claims, d a d u r c h e k en n z e i c h n e t that the cut-off stage (S) consists of a A series circuit connected to a voltage source, consisting of a Zener diode (Z), a relay (R), its normally open contact (r) between voltage source and transistor (T1) is arranged in the main circuit and a temperature-dependent resistor (Rt) is formed. 7. Circuit arrangement according to one of claims 1, 2, 3 and 6, d a it is indicated that the Z-diode (Z) via the relay contact (r) a diode (D) polarized in the forward direction is connected in parallel. 8. Circuit arrangement according to one of the preceding claims, d a d u r c h g e k e n n z e i eh -n e t that the switching stage (S) consists of a relay (R) with a normally open contact (r) and a switching transistor in the circuit of the relay (T3), in the base-emitter circuit of which there is a Zener diode (Zi) and the temperature-dependent one Resistor (Rt) are arranged as part of a base voltage divider. 9. Circuit arrangement according to one of the preceding claims, d a d u r c h g e k e n n n z. e i c hn e t that the cut-off stage (S) is a temperature-dependent Has resistance-controlled Schmitt trigger (T4, t5), which the relay (R) with the normally open contact (r) controls. 10. Scarf device arrangement according to one of the preceding claims, d a d u r c h e k e n n n z e i c h -n e t that the cut-off stage (S) one of the temperature-dependent resistance controlled Schmitt trigger (T4, T5), the a switching transistor (T6), whose emitter coil section is connected to the load current circuit is switched on, controls. 11. Circuit arrangement according to one of the preceding claims for Consumers consisting of lamp fields with a periodic timer Limitation of the duty cycle, that is to say the timer by using a with the current limiting resistor (R1) thermally coupled temperature-dependent resistance (Rt) in its controls circuit also serves as a short-circuit breaker. Blank page