DD273922A1 - PROCESS FOR DISABLING THE END PULSE - Google Patents

Abstract

The invention relates to a method which is used in phase control control IC with tacho or load current controlled control. The object of the invention is to find a method for blocking the ignition pulses, which makes it possible to realize a universally usable simple Zuendimpulssperre either with or without restart interlock both in tacho - as well as in power-current controlled and eliminate the disadvantage of the known pulse lock. According to the invention, the object is achieved in that a programmable logic unit is programmed by an external input circuit and controls a subsequent operating voltage monitoring with pulse inhibit. When the logic switch of the external input circuit is closed, the programmable logic unit operates as a threshold value switch with hysteresis and, if the logic selector switch is open, as quasi RS - FF with latching, so that once again no restart interlock occurs after the end of the accident.

Description

Also in view of the fact that it is obvious for economic reasons to produce all phase control - IS for tacho and load current controlled control with a single basic layout, it is very disadvantageous not to have a universally applicable method for blocking the ignition pulses with or without restart interlock.

Object of the invention

The aim of the invention is to provide a universally usable method for blocking the ignition pulses with integrated phase control IS, which allows the optional realization of a Zündimpulssperre with or without restart interlock without capacitive external wiring both in tacho - as well as in power control.

Explanation of the essence of the invention

The invention has for its object to find a method for blocking the ignition pulses, which makes it possible to realize a universally usable simple Zündimpulssperre either with or without restart interlock both in the tacho - and in the load current controlled and the disadvantage of the known pulse lock remove. According to the invention the object is achieved in that a programmable logic unit controls the operating voltage monitoring with pulse lock. The programmable logic unit is programmed by the external input circuit in such a way that when the logic selector switch is closed, the programmable logic unit operates as a threshold value switch whose hysteresis is determined by the external input circuit and when the logic selector switch is open, as a quasi-RS self-latching flip-flop Logic unit plays the function of the set input. Resetting is only possible in this case by switching the mains voltage off and on again.

The programmable logic unit controller is activated by a low input current and turns on the two controlled constant current sources. The first controlled constant current source acts on the input of the programmable logic unit and thus supports the rapid activation of the control element. The first controlled constant current source further provides when closed logic selector in conjunction with the thermistor for the formation of a hysteresis and open logic selector in conjunction with the base resistor and the thermistor for latching. The second controlled constant current source operates on the resistor, which is used to generate potential at the output of the programmable logic unit, which is also the input of pulse-blocked operating voltage monitoring. The output of the programmable logic unit is approximately at ground potential when the second controlled constant current source is switched on and at the internal reference voltage when the second constant current source is switched off.

embodiment

The invention will be explained in more detail below using an exemplary embodiment. 1 shows a block diagram for blocking the ignition pulses with and without a restart interlock.

The operating voltage monitoring with pulse inhibit 4 has an internally fixed hysteresis and is input side controlled by the voltage applied to the integrated circuit IS - U _cc and the other by the output of the programmable logic unit 1 such that _{falls below} a certain minimum operating voltage-и _сс and / or when switched on the second controlled constant current source K2, the clock flip-flop 5 is reset. The set by the reset of the clock FF's 5 to Η signal output Q turns off the pulse output stage 6, so that the gate of the triac Tr no longer energized and the load resistor R _{L is} de-energized.

The integrated circuit IS further includes the programmable logic unit 1, which consists of the control element 3, which controls the two controlled constant current sources K1 and K2, and the resistor R4. The control member 3 has a transistor input. Upon reaching the base-emitter flux voltage Ube, the control element 3 is activated and switches the two controlled constant current sources K1 and K2 in the conductive state. U e _B is not reached, the control member 3 becomes inactive, and switches K1 and K2 from. The first controlled constant current source K1 acts on the input of the programmable logic unit 1, which is also the input of the control element 3 and the output of the external input circuit 2, the second controlled constant current source K 2 operates on the resistor R 4, which is used for potential generation at the output of the programmable logic unit 1, which is also an input of the operating voltage monitoring with pulse inhibit 4, is used. R4 is dimensioned so that when switched on the second controlled constant current source K2 at the output of the programmable logic unit 1 is applied approximately ground potential. When K2 is turned off, the output of the programmable logic unit 1 is at the internal reference voltage-Ur ,, = 9 V and is for the operating voltage monitoring with pulse lock 4 without influence. Whether the programmable logic unit 1 operates as a threshold value switch with hysteresis or as quasi RS - FF depends on the type of external input circuit 2. The mode of operation is to be represented by a circuit for monitoring the winding temperature of a universal motor.

Enclosed logic selector switch S is the basic resistor R1, which may be about 10ΚΩ, shorted. Upon reaching the critical winding temperature of the motor of the thermistor R3 is high impedance, so that builds up by the voltage divider R2 / R3 at the input of the programmable logic unit 1, the base-emitter flux Ube, which is used to activate the control member 3 and thus to turn on the two Constant current sources K1 and K2 leads. The output of the programmable logic unit 1 switches to approximately ground potential and ignition pulse generation is disabled.

The switched-first controlled constant current source K1 causes by their feedback a quick and safe switching of the control member 3 and provides in conjunction with R3 for the necessary hysteresis of an accurate and unique switching.

After cooling the motor winding of the thermistor R 3 is quickly low impedance and Übbe breaks down. As a result, the controller 3 becomes inactive and turns off the two controlled constant current sources K1 and K2.

When the logic selector switch S is open, the basic series resistor R1 provides latching when the first controlled constant current source K1 is switched on, and the programmable logic unit 1 operates as a quasi RS-FF. For a given constant current of K1, R1 must be designed so that even at low resistance of the thermistor R3, i. when the motor winding is cooled, the voltage Ube at the input of the control element 3 is maintained. The thus realized restart interlock after cooling of the motor winding reliably prevents the starting of the motor after the accident. The resetting of the programmable logic unit 1 operating as quasi RS - FF can only take place by switching the mains voltage Un off and on externally.

By appropriate variation of the external input circuit 2 in addition to the thermal control of the winding even more control and safety functions can be realized.

Claims (1)

Method for disabling the ignition pulses consisting of the pulse-train operating voltage control which controls the reset input of the clock FF, whose Q output drives the pulse output stage and whose output leads to the gate of the triac which controls the load resistor, characterized in that Programmable logic unit (1) controls the operating voltage monitoring with pulse inhibit (4) and the programmable logic unit (1) from the external input circuit (2) is programmed such that the programmable logic unit (1) with the logic selector switch (S) closed as a threshold, its hysteresis is determined by the external input circuit (2) and works with the logic selector (S) open as quasi RS - FF with latching, wherein the input of the programmable logic unit (1) has the function of the set input and resetting only by switching off and on again Mains voltage (U _n ) is possible and there the control element (3) of the programmable logic unit (1) is activated by a base-emitter flux voltage (U _B e) and simultaneously switches on the first and second controlled constant current sources (K 1) and (K2), the first controlled constant current source ( K 1) on the input of the programmable logic unit (1) acts, the quick and safe switching of the control member (3) supports, with closed logic selector (S) in conjunction with the thermistor (R3) the formation of a switching hysteresis and with open logic selector switch (S ) in connection with the base resistor (R 1) and the thermistor (R3) provides latching, and the second controlled constant current source (K2) operates on the resistor (R4) which is used to generate potential at the output of the programmable logic unit (1) is simultaneously an input of the operating voltage monitoring with pulse inhibit (4), is used, so that the output of the programmable logic unit (1) is turned on the second controlled constant current source (K2) leads approximately to ground potential and, when the (K2) is switched on, the potential of the internal reference voltage (-U _Re f). For this 1 page drawing Field of application of the invention The invention is used in integrated circuits for phase-angle control, in particular in load-current-guided phase control IS. Characteristic of the known state of the art Are known circuits for controlling or regulating universal electric motors such. For example, in DE-PS 2629831 or in the Telefunken Catalog, Industrial Electronics, 1986/87, shown. The ignition pulses generated in the integrated circuit according to the desired phase position for the control of the external triac must be able to be suppressed or disabled under certain conditions. For example, it is customary to suppress the ignition pulse generation by means of an integrated operating voltage monitoring during the build-up of the operating voltage or in the event of short-term mains interruptions. But even in case of accidents or thermal overload of the winding, it is necessary to block the motor control. This is done via a pulse lock with hysteresis integrated in the circuit. In normal operation, the input of the internal negative reference voltage is -UR _af and is ineffective. However, if one sets the input of the pulse lock to ground potential, the Zündimpulserzeugung is blocked. So you can monitor the winding temperature, for example by means of a thermistor and lock the motor control when reaching the critical temperature on the input of the pulse lock. After cooling the motor winding, the pulse lock releases the ignition pulse generation and the motor restarts. In order to realize a so-called restart interlock after disabling the Zündimpulserzeugung for the engine, the input of the pulse lock is internally connected to an output of the frequency-voltage converter in the known Phasenanschnittsteuer- IS for the tacho-guided motor control. When the motor is running, the input of the pulse inhibit is pulse-locked with the internal reference voltage - UR _e f according to the speed. When connecting the input of the pulse lock with an RC element, the capacitor is discharged in pulses with the engine running. With a mechanical overload of the motor (blocking), the external capacitor can not be discharged by the one output of the frequency-voltage converter so that it charges up to ground potential and the pulse lock prevents Zündimpulserzeugung. The motor can not start again until the external capacitor is discharged by briefly switching the mains voltage off and on again. In the known phase control IC with pulse inhibit input, however, there is no possibility of realizing a restart interlock with reasonable external effort for the majority of possible accident cases, so that many safety requirements can not be met. The phase control IC with load-current-controlled control have no possibility of realizing a simple restart interlock due to the missing frequency-voltage converter.