DD264097A1 - PROCEDURE FOR AUX PULSE CONTROL - Google Patents

Abstract

The invention relates to a method which finds application in integrated circuits for phase control or zero crossing control. The object of the invention is to find a method for Zuendimpulssteuerung, which makes it possible to realize a single basic layout by slight variation of the Leitbahnebene a phase control or a zero-crossing control and eliminate the disadvantage of the known phase control. According to the invention, the object is achieved by the fact that during the switching on of the entire duty cycle and during the switching off of the operating voltage monitoring or pulse inhibit the Q output of the RS-FF must constantly carry an H signal, even during the zero crossings. Only after switching off the operating voltage monitoring or pulse inhibit is the RS-FF reset by the zero crossing detector and the IS current sink is switched on.

Description

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Field of application of the invention

The invention is used in integrated circuits for phase control or zero-crossing control, in particular zero-voltage switches

Characteristic of the known state of the art

Are known circuits for controlling or rule mg of electrical loads according to the principle of phase control, as it be'.pielsweise described in the L) E-PS 2629831.

The phase shift of the ignition pulse and its pulse width weMjn derived from a single capacitor C _{s / 1} .

The operating voltage limitation obtained in the integrated circuit enables a direct supply from the network via diode, series resistor and smoothing capacitor.

An operating voltage monitoring prevents uncontrolled output pulses during the build-up of the operating voltage and after short mains interruptions.

A pulse inhibit allows the implementation of various safety functions, such as speedometer monitoring, thermal overload protection, etc.

The control amplifier with differential input compares the setpoint with the instantaneous actual value and generates at its Ausganrj a control voltage that tries to keep the actual value always at setpoint level.

The phase position of the ignition pulse is determined in the known form of the comparison of a network-synchronized by the zero-crossing detector ramp voltage of the predetermined control voltage. The slope of the ramp is determined by the size of the capacitor C _s , i and its charging current. The charging current is set by means of an external resistor, which simultaneously sets the maximum control angle L ₁₁₁₀ ,,. The Dauei tp of the ignition pulse results from the value of C _S / t · reaches the potential at the capacitor C _St the predetermined by the control voltage ignition threshold, so ignites with the function eii.es comparator receiving internal thyristor and sets the subsequent clock flip-flop , The set to L signal output Q of the clock FF's is the Impulsausgnngsstufe free (leading edge of the triac Zündimpiiisb "), the output Q switches the I, _p -Stromsenke to C ₅ ,, and Hon set input of the RS-FF's I _s -S: i jnisenke out and over the OR gate the 'reference voltage switch output side to an internal reference.The switched I, _p -Stromsonke now loads Cs / _t very quickly.The duration of this charging time corresponds to the output pulse duration Tp.

Reach; Jas potential at C _s , t the value specified by the internal reference, the thyristor fires again and resets the clock FF back to the initial state. This will stop the output pulse. The clock FF switches off the Ι, μ current sink again.

The switching state of the RS-FF does not change, so that the I _s current sink remains switched off and the gate of the thyristor is kept at the internal reference. In this way it is reliably prevented that more than one Flußausgangsimpuls is generated in the relevant half-wave of the mains voltage.

In the next zero crossing of the voltage, the zero-crossing detector ensures the ground state of the clock FF and resets the RS-FF. Resetting the RS-FF resets the I _s current sink. However, the capacitor C _{s / t} can not be charged because the synchronizing switch keeps the capacitor Cs / t at the starting voltage during the zero crossing.

After completion of the zero crossing of the described process runs again.

For inductive loads, a current detector takes into account the phase shift between current and voltage. The known circuits for phase control have the disadvantage that when the operating voltage monitoring or pulse inhibit, the RS-FF is reset, so that the switched Is-current sink the capacitor Csa charges continuously. The consequence of this is a continuous ignition of the thyristor with the associated higher power loss at the series resistor of the circuit.

After being released by the operating voltage monitoring or pulse inhibit, an uncontrolled output pulse may occur. The known circuit for the phase control is therefore not suitable for the principle of zero-crossing or wave packet control. For a given basic layout of a phase control circuit, however, it is reasonable for economic reasons to realize the similar zero crossing control by slight circuit variation in order to produce a simple and inexpensive zero voltage switch.

Object of the invention

The aim of the invention is to provide a method for ignition pulse control, which allows the selective realization of a phase control or zero-crossing control.

Explanation of the essence: the invention

The invention has for its object to find a method for Zündimpulssteuerung, which makes it possible to realize with a single basic layout by slight variation of the Leitbahnebene either a phase control or a zero-crossing control and eliminate the disadvantage of the known phase control. According to the invention the object is achieved in that the Betriebsspannungsüherwachung and pulse lock has two galvanically isolated and in a certain fixed current and time related Stromquellenausgange Ableitwiderötänden in such a way that the currents of the first and second outputs in the ratio 1: 2.5 stand and synchronized in time. The first output of the Beiriebsspannungsüberwachung and pulse lock, which is in galvanic connection with the first output of the zero crossing detector, whose output current is smaller than the output current of the first output of the operating voltage monitoring and pulse inhibit, controlled via series resistors, the R inputs of the clock and RS-FF's. The second output of the operating voltage monitoring and pulse inhibit controls the inverter, which has two galvanically isolated open-collector outputs that run synchronously with each other. With the first output of the inverter the R-input of the RS-FF's is controlled directly, with the second output of the inverter the Q-output of the RS-FF's The input of the inverter and the R-input of the RS-FF have the same switching sensitivity. The temporal switching behavior of the inverter is chosen so that it has a very low on-time and a relatively large off-time. By this control of clock FF, inverter and RS-FF is achieved that both during power-up and the entire duty cycle as well as during switching off the operating voltage monitoring or pulse inhibit the Q output of the RS-FF's always Η signal leads, even during of the mains supply voltage, because the first output of the inverter prevents the reset of the RS-FF. Only after switching off the operating voltage monitoring or pulse inhibit, the RS-FF is reset by the zero crossing detector in the following zero crossing of the mains voltage and the I _s -Stromsenke turned on again. To reduce the burden of external circuitry, the emitter-side output of the I _s current sink is provided with an emitter resistor.

embodiment

The invention will be explained in more detail below using an exemplary embodiment. It shows:

Figure 1: Block diagram of a circuit for Zündimpulssteuerung at zero crossing control

The zero-crossing detector 1, which functions as a pulse shaper, supplies a pulse at each of its two current source outputs at each zero crossing of the mains voltage. The first output of the zero-crossing detector 1 is connected to the first output A1 of the operating voltage monitor and pulse damper 3 and provides a lower current than the first output Al of the operating voltage monitoring and pulse lock 3. The second output of the zero crossing detector 1 is connected to the input of the synchronizing switch 2. Through the zero crossing detector 1 is at zero crossing the mains voltage via the synchronizing switch 2, the capacitor C _{s / t} to start voltage (- 2.2 V) discharged and the clock FF 9 and the RS-FF 10 is reset to the initial state. The set to L signal Q output of the RS-FF's 10 turns on the I _s power source 7 a.

The gate of the thyristor 6 is constantly on the internal reference 5. After completion of the zero-crossing pulse, which is determined by the size of the synchronizing resistor R _Syn , the synchronizing switch 2 opens and releases the capacitor C _{s /} i. The already switched Is current sink 7 charges the capacitor C _S / _t . The charging time results from the values of C _{s /} , and R 5. When the voltage U _C sa reaches the value -8.1 V, the thyristor 6 ignites. The steep current edge at its current source output sets the Q output of the clock FF's 9 to L signal, so that the pulse output 12 becomes conductive and ignites the external triac Tr. The Η-signal at the Q-output of the clock FF's 9 turns on the I, _p -Stromsonke 8 and this in turn controls the S input of the RS-FF's 10. The set to Η signal Q output of the RS FF switches the I _s current sink 7 off. The capacitor C _{s / I} is now charged solely by the I, _p current sink 8. When its voltage reaches the value of -8.1 V, the thyristor 6 ignites a second time and sets the output Q of the clock FF's 9 back to Η signal, so that the pulse output 12 is disabled. The Aunddezeit of C _{s / 1} given by the Ι, ρ-current sink 8 corresponds to the output pulse duration tp. The L-signal leading Q output of the clock FF's 9 now turns off the I, _p current sink 8. Nothing changes in the state of the RS-FF 10, ie the I _s current sink 7 also remains switched off and the capacitor C _S / i remains at the thyristor cutoff voltage, which is approximately -3.2 V. Thus no further output pulse can be generated in the respective half-wave of the mains voltage. In the following zero crossing of the mains voltage, the process described begins again. The interconnection of control amplifier 4 and pulse lock 3 results in a threshold with hysteresis. The operating voltage monitoring and pulse inhibit 3 has two galvanically isolated and in a fixed fixed current υ nc 'temporally related current source outputs with bleeder resistors R1 and R 2 in such a way that the currents of the first output A1 and the second output A2 of the operating voltage monitoring and pulse lock third at least in the ratio 1: 2.5 and are synchronous in time. The first output A1 is connected to the first output of the zero crossing detector 1 and leads via the series resistor R3 to the R input of the clock FF's 9 and via the resistor R4 to the R input of the RS-FF's 10. The second output A 2nd is connected to the input of the inverter 11. The inverter 11 has two galvanically separated and mutually synchronous open collector outputs. The input of the inverter 11 and the R input of the RS-FF 10 are dimensioned to have the same switching sensitivity. The timing behavior of the inverter 11 is designed to achieve a very short on-time and a relatively long off-time. The first output of the inverter 11 is connected directly to the R input of the RS-FF 10, the second output to the Q output of the RS-FF 10. With the solution according to the invention of the interaction of operating voltage monitoring and pulse inhibit 3, clock FF 9, RS-FF 10 and negator 11 ensures that both during power-up and the entire duty cycle and during switching off the operating voltage monitoring or pulse lock 3, the Q output the RS-FF's 10 constantly Η signal leads, even during the zero crossings of the mains voltage, because the two outputs of the inverter 11 absolute priority before the output signals of the first output A1 of the operating voltage monitoring or pulse inhibit 3 or the first output of the zero crossing detector 1 and have the reset Prevent the RS-FF's 10. Only after switching off the Betriebssoannungsüberwachung or pulse inhibit 2 , the RS-FF 10 is reset by the Nulldurchganysdetektor 1 in the subsequent zero crossing of the mains voltage and the Is-current sink 7 is turned on. With the solution according to the invention, a method for T.U.F pulse control is specified, which can be used universally both for Phasenanschnitt- alc and for zero crossing stirrups. It eliminates the disadvantage of the known phase control and prevents zero-crossing control that 3 uncontrolled ignition pulses are generated after switching off the operating voltage monitoring or pulse lock. Because the tolerance requirements are of secondary importance at a zero voltage switch to the charging current of I _s -Stromsenke 7, can be used for setting the charging current of the internal emitter resistance RS, which is about 1.4 kOhm. In this way, external sound can be saved.

A produced according to the invention zero-voltage switch IC can be mounted in 8-pin housing. The mode of operation of a phase control according to the invention results in a simple manner from the statements of the embodiment and the prior art.

Claims (2)

Claim: \ 1. A method for Zündimpulsfifeuerung, characterized in that the operating voltage monitoring and pulse lock (3) has two galvanically isolated and in a certain fixed current and time relative to each other Stromquellenausgänge with bleeder resistors (R 1) and (R 2) in the way that the currents of the first output (A 1) and of the second output (A 2) are at least 1: 2.5 and are synchronous in time, and in that the first output (A 1) is in galvanic connection with the first output of the zero-crossing detector (A 1). 1) whose output current is smaller than the output current de-s first output (A 1) via the series resistor (R3) the R input of the clock FF's (9) and the series resistor (R4) the R input of the RS -FF's (10) controls, and that the second output (Ai) controls the negator (11), which has two galvanically separated and mutually synchronous open collector outputs, and that the first output of the Negat ors (11) directly controls the R input of the RS-FF (10) and the second output of the RS-FF (10) controls the Q output of the RS-FF (10) and that the input of the inverter (11) and the R-input of the RS-FF's (10) have the same switching sensitivity and that the timing of the inverter (11) is selected so that it has a very low on-time and a relatively large off time, so that during the switching of the entire duty cycle and during the Q-output of the RS-FF (10) constantly Η signal, even during the zero crossings of the mains voltage, and that only when switched off operating voltage monitoring or pulse inhibit (3) the RS-FF (10 ) is reset by the zero-crossing detector (1). 2. The method according to item 1, characterized in that the emitterseitiqe output of the Is current sink (7) includes an emitter resistor (R 5), with which the charging current of the I _s current sink (7) is set.