DE2646126A1 - Automatic control circuit for electric devices - has triac whose control electrode is connected to output of voltage divider with PTC resistor - Google Patents

Abstract

The devices are e.g. electric motors whose speed is to be regulated or lamps whose brightness is to be controlled. The automatic control circuit comprises a phase shifting control with a power switch such as a triac which is controlled during each half-period of the applied A C voltage through a variable resistor, a capacitor and a diac. The control wire (7) of the electronic power switch (Tr) is connected to a point (6) between a resistor (R1) and a temp. sensitive resistor (+V1). The temp. sensitive resistor has a high positive temp. coefficient. These two resistors operate as a voltage divider.

Description

Password: "altleiter"

Circuit arrangement for controlling electrical power consumers The invention relates to a circuit arrangement for controlling electrical devices, For example, speed control of motors, elligkeitssteuerung of lamps or. Like. With a phase control that has an electronic circuit breaker, like Triac, which has in each half-wave of the applied alternating voltage an adjustable resistor, a rechargeable capacitor and a diac depending on the time is controllable. Such circuit arrangements are for the most varied Purposes used.

It has now been shown that such circuit arrangements are a Have a number of disadvantages. In particular during the switch-on process there is a too high current load for the network, so that the fuses can easily blow. In addition, the control range is relatively narrow, since the Motors or low brightness of the lamps already have minor disturbances in the network Bring the motor to a standstill or the lamps go out. Finally, for example If the motors are overloaded, individual components of the circuit arrangement are easily destroyed. There are already current start-up limits or fuses for individual switching arrangements mechanical or electronic design provided. However, these are in view too expensive at their expense or in terms of their structural size.

The object of the invention is therefore to provide a circuit arrangement of the initially mentioned to create the type mentioned, which is extremely reliable and especially during the switch-on process Too much load on the power grid and thus destruction of fuses prevented, such a circuit arrangement a simple, in particular has a space-saving structure and can be produced easily and cost-effectively target. This is achieved according to the invention in that the connection point of the control line of the electronic circuit breaker between as a resistor and a / PTC thermistor formed temperature-dependent resistance is, the series circuit consisting is formed from resistor and PTC thermistor as a voltage divider. By using and such an arrangement of the PTC thermistor ensures that when switched on of the power consumers of the circuit breakers relatively late in each half-wave is controlled through and thus the power consumer only has a low output Network removes. As soon as the PTC thermistor is heated up and a considerably higher one Assumes resistance, the power consumer gives according to the setting of the a variable resistor designed as a potentiometer. It is advantageous here if the series connection consists of a resistor and PTC thermistor Connected in parallel to the series consisting of power consumers and circuit breakers is.

To now at low speed of motors or low brightness To ensure proper operation of lamps, it is recommended that the The adjustable resistor designed as a potentiometer forms a voltage divider, the one with one end to the connection point of the control line and with his the other end has a much higher resistance than the first resistor exhibiting second "resistance at the mains connection or between the power consumer and Circuit breaker lies, while the connection point for the adjustable Resistance of the potentiometer on the control line to the side of the circuit breaker is arranged towards. It is also beneficial if parallel to the electricity consumer and the circuit breaker or a series circuit in parallel with the circuit breaker consisting of the second resistor and a capacitor is connected, wherein the junction of the potentiometer between the resistor and the capacitor connected.

The timing element formed from the second resistor and the capacitor ensures that the power consumer operates properly even with low power output, without having to fear that the circuit breaker will no longer be activated in the event of sudden voltage changes occurring in the power supply system. l) In addition, the adjustable resistance can be used in its entire locking area for control purposes. It is advantageous if the second resistor is an adjustable resistor recreated istium so that the circuit arrangement can be easily adapted to different power consumers.

In a particular embodiment of the invention is in Control line for the electronic circuit breaker, a PTC thermistor installed, the one in thermal contact with the power consumer and / or electronic circuit breaker stands. This is the thermal contact between the PTC thermistor and the power consumer given that either the PTC thermistor is the power consumer, for example touches an engine block, or in the heated one coming from the electricity consumer Cool air is arranged. This PTC thermistor causes the power consumer to overheat or the circuit breaker, since overheating also causes warming of the Raltleiter and thus an increase in its resistance occurs.

This has the consequence that the ignition timing of the circuit breaker in every half-wave occurs later and the electricity consumer does not more gives so much power. In addition, a sudden shutdown of the Electricity consumers avoided, because by increasing the resistance value of the PTC thermistor only the ignition timing of the circuit breaker is shifted. Any for cooling The fans serving the electricity consumer can continue to run because the Power grid is not interrupted.

The PTC thermistor "self-regulates" the Power consumer on, because when the PTC thermistor or

of the power consumer or the circuit breaker automatically controls the power output of the electricity consumer is increasing again. It is particularly recommended if A resistor is connected upstream of the PTC thermistor in the control line, both between the potentiometer and the connection for the ignition pulse for the circuit breaker supplying capacitor.

In another embodiment of the invention is parallel a series connection to the capacitor supplying the ignition pulse for the circuit breaker consisting of a resistor and a bridge rectifier arranged and parallel to the DC outputs of the bridge rectifier a capacitor and a high resistance is provided, in the control line of the circuit breaker a PTC thermistor in thermal contact with this and / or the power consumer lies.

In this circuit, too, there is a current start-up limitation in a simple manner as well as a temperature overload protection for the electricity consumer is given on the In the drawing, the subject matter of the invention is shown in several exemplary embodiments namely show: FIG. 1 a circuit arrangement with a current start-up limiter, Fig. 2 shows a circuit arrangement like FIG. 1 with an overload protection device and FIG. 3 a Another exemplary embodiment of a circuit arrangement with current start-up limitation as well as overload protection for a power consumer.

In the circuit arrangement shown in Fig. 1, the two are Network connections 4, 5 via a power consumer M and a circuit breaker Tr connected with each other. The circuit breaker is designed as a triac. Parallel A voltage divider is connected to the power consumer M and the circuit breaker Tr consisting of a resistor R 1 and a PTC thermistor # 1, with between these two resistors a connection point 6 for the control line 7 of the circuit breaker Tr lies. In the control line 7 there is a resistor designed as a rotary potentiometer P1 and a diac Di built in. Between the rotary potentiometer P1 and the diac Di there is a connection 8 of a capacitor which supplies the ignition pulse for the circuit breaker Cl whose other connection 9 is connected to the network connection 5. In parallel with the circuit breaker there is a timing element consisting of a resistor R 2 and a capacitor C 2, where resistor R2 has a much higher resistance than the already mentioned resistor R1. Between the resistor R2 and the capacitor C2, there is a connection point lo for the rotary potentiometer P 1, with between the Connection point 6 and lo the rotary potentiometer forms a fixed resistor. By this arrangement avoids a "hysteresis effect", which is on the one hand through the setting of the DrehpoteXffDmebrs at the beginning of the rotation of the motor and for other results from the setting when the rotation is stopped.

The operation of the circuit arrangement is as follows: As soon as the Mains connections 4.5 are connected to the mains voltage, flows through the Resistances R1 and) 1 a stream. Because initially the resistor has a lower resistance value occupies, there is only a slight voltage drop. So it takes in everyone Half-period relatively long before the capacitor C1 reaches the breakdown voltage of the Diacs Ds is charged via the rotary potentiometer P1. The circuit breaker will so controlled relatively late in each half-wave and if the electricity consumer is a motor, it will have a low speed. As soon as the PTC thermistor 2 1 heats up as a result of the current flow, its resistance value increases rapidly, so that the circuit breaker is activated earlier and earlier and the required performance or speed outputs. By changing the resistance value of the rotary potentiometer P1 can be the desired speed for a motor or the required speed for a lamp can be adjusted.

The circuit arrangement according to FIG. 2 has a structure similar to that in Fig. 1. In addition to Fig. 1 is now in the control line 7 for the circuit breaker between the terminal 11 of the rotary potentiometer P 1 and the terminal 8 for the capacitor C1 another PTC thermistor # 2 with a series resistor R3. This PTC thermistor is in thermal contact with the power consumer M and / or the electronic circuit breaker. As soon as the power consumer or the circuit breaker is overloaded and thus over If a certain temperature is heated, the PTC thermistor) 2 takes a considerable amount higher resistance, so the capacitor will always be charged later and the ignition timing of the circuit breaker shifts backwards and the speed or the brightness of the power consumer M decreases, so that power consumers and the PTC thermistor J 2 can cool down again. In such an arrangement is used the PTC thermistor, so to speak, as a self-healing fuse.

In the event of overheating, the power consumer is slowly switched off while When the power consumer has cooled down, it is slowly switched on again.

A further reduction compared to FIG. 1 is in the circuit arrangement According to Fig. 2, the resistor R 2, a trimmer resistor T1 upstream so the To be able to adapt the circuit arrangement to different power consumers and in order to obtain a maximum control range.

Finally, there is also a series circuit in parallel with the circuit breaker Tr consisting of a resistor R4 and a capacitor C3. This RC element ensures that the voltage changes at the circuit breaker remain finite.

In the circuit arrangement according to FIG. 3, the power consumer is again located M and the circuit breaker Tr in series with the power grid connections 4,5. Parallel to the circuit breaker Tr is an RC element consisting of the resistor R 4 and the capacitor R3.

In contrast to the first exemplary embodiments, the connection point is located 6 for the control line of the circuit breaker between the power consumer and the Circuit breaker. In the control line 7 there is a series resistor R5 as an overload 7 Protective PTC thermistor v 3, a parallel connection, consisting of a rotary potentiometer P2 and a trimmer T2 and a diac Di.

Between the parallel connection of rotary potentiometer P2 and trimmer T2 is the one terminal 8 of the supplying the ignition pulse for the circuit breaker Capacitor C4. The other connection 9 of which is connected to the mains connection 5. Parallel A series circuit consisting of a resistor R6 is connected to the capacitor C4 and a bridge rectifier G. In parallel with the DC outputs of the bridge rectifier there is both a capacitor C5 and a resistor R7. As soon as now at the mains connections 4.5 voltage is applied, a charging current flows through connection point 6 of the control line 7 to capacitor C4. However, the current also continues to flow through the resistor R6 and the bridge rectifier G to Capacitor C5. First, in each half cycle the capacitor C4 is slowly charged resulting in a low speed or E-brightness of the power consumer. Capacitor C5 will also charged. As soon as this is charged, the charging current charges the capacitor C4 alone so that the ignition point of the circuit breaker is brought forward, the electricity consumer adopts the desired speed or brightness. via the rotary potentiometer P 2, the speed or the brightness of the power consumer can be regulated again. The PTC thermistor t3 is in turn thermal with the power consumer or the circuit breaker coupled. In the event of an overload, the charging current is automatically reduced for the capacitor C4.

The capacitor C5 has the task of preventing that in the switch-on phase too much electricity is withdrawn from the grid. It should be said here that the capacitor C 5 also slowly discharged via the high-resistance resistor connected in parallel If there is an overload due to the PTC thermistor, the charging current is less so discharged slowly via R7 the capacitor C5. If the PTC thermistor then cools down again, so the capacitor C5 must first be fully charged again until the ignition point of the circuit breaker is moved forward again in each half-wave, so that overall a smooth start-up behavior is given again.

As already mentioned, the circuit arrangements shown are only example implementations of the invention. This is not limited to this. Many modifications and uses are still possible. So can with the circuit arrangement not only motors are regulated in their speed and lamps in their brightness It is also possible to regulate transformers. Be further said that the series arrangement consists in the first two circuit arrangements from the resistor R 2 if necessary. Trimmer 1 and capacitor C2 also parallel to the power consumer M. and circuit breaker Tr can be switched.

In the third exemplary embodiment, the connection point 6 be the control line 7 before the power consumer.

Furthermore, the electricity consumer could also have a mechanical input and an off switch must be connected upstream.

LIST OF REFERENCE NUMERALS: 4.5 mains connections 6 connection point of 7 7 control line of Tr 8 connection of C1 9 connection of C1 10 connection point of P 1 11 connection point from T 1 Tr circuit breaker M current consumer G bridge rectifier Di Diac R15k # R2 100k # R3 27k # R4 100 # R5 14k # R6 1k a R7 180k # C1 0.022 µF C2 0.047 µF C3 0.1 µF C4 0.068 µF C5 1-2.2 gF P1 1M # Potentiometer P2 500k # Potentiometer T1 500K # Trimmer T2 2.2 M # Trimmer # 1 (80 °) PTC thermistor # 2 (60 ° C) PTC thermistor # 3 (80 ° C, 60 ° C) PTC thermistor

Claims (8)

A nspr ü che 1. Circuit arrangement for controlling electrical devices, for example speed control of motors, 11elligkeitssteuerung of lamps or the like Resistor, a chargeable capacitor and a diac can be controlled time-dependently, characterized in that the connection point (6) of the control line (7) of the electronic circuit breaker Tr between a resistor (R 1) and an Xalt conductor (J1) formed temperature-dependent resistor, the series circuit consisting of resistor (R1) and PTC thermistor (# 1) is designed as a voltage divider. 2. Circuit arrangement according to claim 1, characterized in that the series circuit consisting of resistor (R 1) and PTC thermistor (1) parallel to the Series consisting of power consumers (M) and circuit breakers (Tr) is switched. 3. Circuit arrangement according to claim 1 or 2, characterized in that the adjustable resistor formed as a potentiometer (P 1) forms a voltage divider which has one end at the connection point t6) and its other end (10) via a considerably higher one Resistance value as the resistor (R1) having the resistor (R2) at the mains connection (4) or between the power consumer (M) and the circuit breaker 249 (Tr) Cn the connection point (11) for the adjustable resistance of the potentiometer 1) is arranged on the control line (7) on the side of the circuit breaker (Tr). 4. Circuit arrangement according to one or more of claims 1 to 3, characterized in that in parallel with the power consumer and the circuit breaker or a series circuit consisting of the resistor (R 2) and a capacitor (C2) is connected, the connection point (lo) of the Rotary potentiometer connected between the resistor (R2 'and the capacitor (C2)) is. 5. Circuit arrangement according to one or more of claims 2 to 4, characterized in that the resistor (R2) is an adjustable resistor (T1) is downstream. 6. Circuit arrangement according to one or more of claims 1 to 5, characterized in that in the control line (7) for the electronic circuit breaker (Tr) a PTC thermistor # 2 is installed, the üa thermal contact with the power consumer (t-1i and / or electronic circuit breaker (Tr) is available. 7. Circuit arrangement according to claim 6, that the one in the control line (7) lying PTC thermistor (# 2) is preceded by a resistor (R3), both of which between the potentiometer CP 11 and the connection for the ignition pulse for the Circuit breaker supplying capacitor (C1) lie. 8. Circuit arrangement in particular according to claim 6, characterized in that a series circuit consisting of a resistor (R2) and a bridge rectifier (G) is arranged parallel to the capacitor (C4) supplying the ignition pulse for the circuit breaker (Tr) and parallel to the DC outputs of the bridge rectifier (G) a condenser Sator (C5) and a high-resistance resistor is provided, with a PTC thermistor (# 3) in thermal contact with this and / or the current smoker M in the control line (7) of the circuit breaker Tr.