DE4019592A1 - Inrush alternating current limitation for inductive load switching - Google Patents

Abstract

An AC switching triac (302) is wired with a measuring shunt (304) in series with the primary winding (310) of the transformer (301). The firing phase is adjusted from zero at the instant of switching-on until the current attains a predetermined threshold, by a control circuit (306) including a comparator (307) and firing logic (308) in command of a phase angle control (303). After near-saturation of the core, its magnetisation is synchronised by voltage of opposite polarity.

Description

The invention relates to a device for changing current turn-on limit one with an alternating current switches connected in series with inductance Power supply device with a leading edge scarf device through which the connection of the inductance Teten power supply with the AC power voltage starting with the starting torque with monotonically increasing Phase angle is adjustable.

Such a device is from DE PS 27 46 845 known, with the constant phase control during a start time the transmission angle of the voltage of small values are slowly shifted towards large ones. This device has the disadvantage that the Remanence of the transformer in the idle state at the same like polarity of the remanence and the voltage signal shifts more and more into saturation, so that over successive cut half-waves Peak inrush current added up.

A similar wiring arrangement is from the ELV Journal 45, pages 1-4. Here in one switching torque from a relatively small control angular and accordingly low start-up power assumed and this leading edge angle increased then in a typical time of 0.5 to 2 seconds that up to 180 degrees before the zero crossing of each network half wave, which corresponds to full power.  

Such known circuits are particularly for Welding transformers or similar to resonances tending power supplies unusable because of very fast and unavoidable inrush currents, so-called inrush currents, which integrate the Can destroy circuits and the upstream Trigger fuse element. Transformers too high induction density, such as B. special toroidal core fos are not possible with the simple dimming process Switch on without switching on.

Furthermore occur in the known circuits Circuit loading or even destructive on peak currents when switched on on the secondary side Loads that are asymmetrical in their polarity.

The Erfin is based on this state of the art based on the task of a device of a initially mentioned type that allows a Power supply device with inductance to feed cut and half ensure that a fuse is destructive and the inrush peak current which is hazardous to the circuit is avoided. The circuit does not just provide Inrush current limitation, it prevents the on switching current peak completely.

This object is achieved in that the phase control circuit said connection first produces only with unipolar phase gates, that one in line with the inductive Power supply device switched comparator circuit is provided, the output of which with the leading edge circuit is connected that the leading edge scarf  in the event of exposure to one of the com parator circuit generated primary circuit overcurrent signal the control electrode of the AC switch for the immediately opposite polarity Half wave with an ignition signal of 150 to 180 degrees acted upon and that in the phase control circuit in the following half-waves an ignition signal at the predetermined phase gating angle can be generated, which after the first 180 degrees half wave and some subsequent full waves.

By using each other at periodic intervals following unipolar cut half waves, whose Angle value is either kept constant or the grows slowly, becomes inductive Power supply device regardless of the original Switch-on phase position and position of the remanence in the transformer. slowly into a defined position known to the circuit brought the remanence, so that after one of the type of the power supply dependent number of cut half waves a small, the circuit Inrush peak inrush current as response the transformer that its remanence is set correctly occurs in the gate control circuit an ignition voltage can be generated with which the change power switch of the supply voltage buffered Gating circuit for the immediately following following, oppositely polarized half-wave ignitable is. Through this to a small overcurrent pulse The following first fully switched half-wave is the Normal operation of the transformer initiated. The induction density ratios correspond to that time point of those of stationary operation. After a few The circuit provides periods of full-wave operation  then the selected phase angle for dimming automatically, with a smooth transition.

Further advantageous embodiments of the invention are characterized in the subclaims.

The following are exemplary embodiments of the invention explained in more detail by way of example with reference to the drawings. It demonstrate:

Fig. 1 waveforms of the mains voltage and the mains current in turning on a Trans formators with a known dimmer,

Fig. 2 is a block diagram of a device for limiting inrush current peaks on the primary side of the transformer when Dimmbe operated according to an embodiment of the invention, and

Fig. 3 shows signal curves of supply voltage and the mains current in turning on a Trans formators with a device according to FIG. 2.

Fig. 1 shows waveforms of the line voltage 10 and the primary-side stream 26 when switching of a transgene formators 1 with a dimmer. 2 The transformer 1 is a possible inductance Stromver supply device, which, for. B. can also be formed by an inductive load.

The dimmer 2 has a ramp circuit shown by the diagram 3 , through which the voltage 5 is increased from a value of zero to a predetermined target value in the time 4 . Such known dimmer circuits are used in connection with transformers 1, especially in low-voltage halogen lighting devices. in which a mains voltage 5 of, for example, 220 volts is transformed via the transformer 1 to, for example, 24 volts on the secondary side.

The dimmer 2 is usually e.g. B. with a slow-blow 1.5 amp fuse 7 and the transformer 1 connected in series, a current measuring device 8 being integrated in series for measuring the measurement curves shown in FIGS . 1 and 3 and a voltage measuring device 9 being the mains alternating voltage or the primary-side transformer voltage detected.

The sinusoidal curve 10 shows the line voltage, which is switched off at any point in time 11 , which in particular does not have to coincide with the end of a half-wave. In Fig. 1, the hatching between the abscissa and the curve 10 means that the mains voltage is detected by the voltage power supply 9 and is therefore applied to the primary winding of the transformer 1 .

After the random point in time 11 of switching off the mains voltage, the transformer 1 is switched on before the end of the positive half-wave 14 of the mains voltage, which begins at a point in time 13 .

The hysteresis curve 15 of the transformer 1 . ie the induction density-field strength diagram has a point 15 which indicates the remanence resulting from the switch-off 11 . In the case shown in FIG. 1, the transformer 1 has a positive remanence 16 . The ramp circuit 3 in the dimmer 2 switches in the switched-on half-wave 14 to a small cut angle 17 on the transformer 1 . The gate angle 17 is arranged before the transition of the positive half-wave 14 into the negative half-wave 18 . As a result, the remanence 16 of the transformer 1 is shifted further into the positive saturation 19 . so that a small inrush current 20 occurs. Due to the occurring in the negative half-wave 18 and compared to the gating angle 17 slightly larger to the cutting angle 21 , the remanence is moved back to the point 22 of the hysteresis curve 15 . The angular value in the next positive half-wave 14 'further increasing and thus in total asymmetrical to cut angle 23 drives the transformer 1 in the next positive half-wave 14 ' in the saturation of the remanence 24 , so that a large inrush or switch-on peak current 25 occurs . After two more half-waves 18 'and 14 ''again there is an excess of positive phase angle from the sum of the angles 21 ' and 23 ', so that an even larger inrush 25 ' occurs, which disturbs the fuse 7 of the transformer 1 zer. This triggering of the fuse occurs in a transformer 1 with or without a load connected, because the inrush current is a reactive current.

Fig. 2 shows a circuit to avoid inrush current peaks 25 when turning on a power supply device with a fixed, predetermined gate angle, for. B. when dimming a low-voltage halogen lighting system or turning on a welding transformer, according to an embodiment of the invention.

The mains voltage 5 feeds an advantageously iron-less power supply unit 31 , which provides the positive operating voltage 32 for the circuit shown in FIG. 2. A plug contact 27 is connected to circuit ground 34 . while the other plug contact 28 leads on the one hand via a power switch 35 to the power supply 31 and on the other hand to the primary winding 36 of the transformer 1 , to which a load 37 is connected on the secondary side.

The second primary-side plug contact of the transformer 1 is via an AC switch 38 in Ge shape of a triac. in its place two Thyri can be used, and a measuring shunt 39 , the z. B. has a value of 0.01 to 0.1 ohms, applied to circuit ground 34 .

The power supply 31 generates a fast and dynamic power-on detection signal, which is present at the base of a transistor 40 ', which quickly discharges a capacitor 41 connected in parallel to the emitter and collector between positive operating voltage 32 and circuit ground 34 . The power-on detection signal, which ensures that the AC switch is only turned on when all circuit components have a secured power supply, is also a level one signal when the voltage comparison device of the power supply 31 detects a supply undervoltage.

The positive supply voltage 32 generated by the power supply 31 charges the capacitor 41 via the resistor 40 , for. B. in 200 milliseconds, against the circuit ground 34 . A level zero signal is thus present on line 42 for the charging time of capacitor 41 . The level zero signal is converted by an inverter 43 into a power-on signal 44 . The power on signal 44 is present via an inverter 52 at an enable and disable input 45 of a gate control circuit 46 .

The gate control circuit 46 can be implemented, for example, by the TCA 785 integrated circuit from Siemens. The gate control circuit 46 is connected via line 47 to the circuit ground 34 and via line 47 'to the positive operating voltage 32 . The plug contact 28 is connected via the main switch 35 and an RC circuit 48 to the synchronization input 69 of the gate control circuit 46 .

The RC circuit 48 , which is constructed in particular from a parallel connection of a resistor 48 'and a capacitor 48 '', simulates a line voltage leading a few angular degrees at a synchronization input 69 of the gate control circuit 46 so that the thyristor release time at the end of each line half-wave is compensated for and therefore the ignition signal ends somewhat before the actual network half-wave.

A ramp generator is provided in the gate control circuit 46 . The maximum voltage and the drop behavior of the z. B. present in sawtooth shape signal is adjustable with the ramp resistor 49 and the ramp capacitor 49 '.

In the gate control circuit 46 , a comparator is also provided, in which the ram voltage signal is continuously compared with a voltage control signal applied to the control line 50 .

This comparison takes place when a level one signal is present at the enable input 45 . As soon as the the gate control circuit 46 50 acting on external voltage signal is smaller on the control line than the monotonically increasing ramp or sawtooth voltage, in a positive half cycle 14 of the network alternating voltage 10, a switching pulse on the positive switching line 53 and in a negative half cycle 18 of the mains alternating voltage 10 a switching pulse is output on the negative switching line 54 .

The pulse duration is defined by the wiring of the pulse duration control line 55 with circuit mass 34 such that the pulse length is always extended to the zero crossing of the half wave 14 or 18 present . Since the switching pulses on lines 53 and 54 ignite triac 38 and it must be prevented that a pulse on lines 53 and 54 , which is still in the zero crossing of mains AC voltage 10, can ignite triac, the leading mains voltage 10 is RC simulating - Circuit 48 has been arranged in front of the synchronization input of the gate control circuit. Thus the pulse present on lines 53 and 54 surely ends a few degrees before the respective zero crossing of the AC mains voltage 10 .

The negative switching line 54 of the gate control circuit 46 is connected to an input of an OR gate 56 , the output of which via a resistor 57 and / or z. B. an optocoupler is connected to the control and ignition electrode 58 of the triac 38 .

The power-on signal 44 described above also acts on a set switch 61 , which is connected with its one switch contact to the positive supply voltage 32 . The other contact is connected via a charging resistor 62 and a capacitor 63 to circuit ground 34 . The for a period of z. B. 0.1 second power on signal closing switch 61 loads on the charging resistor 62 to the capacitor 63 , which is then resisted again by the discharge 64 discharges. The time constant of the RC element 63 , 64 is z. B. about 0.5 seconds. Thus, shortly after the power supply 31 is switched on, a positive voltage is present on the control line 50 via the line 66 . whose signal is compared in the gate control circuit 46 with the ramp voltage signal.

Thus, after release 45 of the gate control circuit 46, the triac 38 is ignited with ever increasing negative gates in its angle, so that the inductive power supply device 1 is slowly driven into saturation with the asymmetrical, only negative gates. The gates could also have a constant angle value. This simpler circuit structure may not guarantee that certain low-loss peak currents 25 causing saturation 24 are reliably reached in certain lossy transformers 1 .

The output signal of the sawtooth generator has a positive slope, which runs from the voltage value zero volts at the start of the ramp to a predetermined maximum voltage at which it is reset again by the next zero crossing of the AC mains voltage 10 , which is somewhat ahead at the synchronization input 69 of the Gating control circuit 46 is present. The capacitor voltage signal present on line 66 drops over several periods. In the analog comparator, the voltage of the capacitor 63 is compared with the respective voltage of the ramp of the sawtooth generator and, if the voltage of the sawtooth generator is greater, a level one signal is output on line 54 , which leads to an ignition signal via the OR gate 56 leads to the control electrode 58 for the triac 38 , so that a steadily growing gate occurs before every second zero crossing of the mains AC voltage 10 .

When the saturation 19 of the transformer 1 is reached , a switch-on peak current 25 occurs after the next cut negative half-wave, which can be recognized by a voltage measurement across the measuring shunt 39 in the negative current transformer 88 .

The output of the negative current transformer 88 is connected via a resistor 89 to an input of an analog comparator 92 . The other input 90 is connected via a voltage divider resistor 91 to the positive operating voltage 33 and via a voltage divider resistor 91 'to circuit ground 34 . The analog comparator 92 only generates a positive output signal if the negative current converter 88 outputs a sufficiently large positive signal. This threshold len signal level depends on the predetermined ratio of the resistors 91 and 91 'to each other. Preferably, the reference voltage signal applied to the input 90 of the analog comparator 92 is set in such a way that at the output of the analog comparator 92 there is a positive output signal indicating a small inrush current when the primary circuit of the transformer 1 has a value between 2 times and 10 times that Nominal current 26 are the current occurs.

The output 92 'of the analog comparator 92 is connected to the set input 93 of a flip-flop element 51 , which is switched by the rising signal edge. The output 94 of the flip-flop element 51 is connected to the control input of a switch 96 . The switch 96 connects the circuit ground 34 to the RC element 63 , 64 via a resistor 97 . with which the comparison control voltage can be set. By closing the switch 96 when an overcurrent occurs, the capacitor 63 is quickly discharged. whereby an ignition signal is present on the positive switching line 53 immediately at the beginning of the immediately following positive half-wave, which strikes an input of an AND gate 95 .

Simultaneously, the level-one applied output 94 of flip-flop 51 the other input of the AND Gat ters 95, whereby a level-one output signal of the AND gate 95 is applied to a second input of the OR gate 56, so that the through-connected level A signal that triac 38 can ignite in the positive half-wave 14 at an angle of 170 to 180 degrees.

In addition, the power-on signal 44 acts on the reset input 49 of the flip-flop element 51 , so that the remanence setting described above can be carried out after each power on or undercurrent detection signal of the power supply 31 .

At the inverted output of the flip-flop 51 , a luminescence diode 98 is connected to a circuit ground 34 via a protective resistor 98 '. The light-emitting diode 98 lights up as an indication to a user as long as the retentive setting has not taken place.

There can be another not shown in the drawing ter setpoint switch with its one contact connected to a potentiometer which is arranged between the positive operating voltage 32 and the circuit ground 34 . This additional setting switch is only closed via a delay element when the retentive setting has been carried out.

This additional dimming setpoint switch is connected via a resistor in series with the capacitor 63 and comprises a potentiometer ter adjustable by the operator, by means of which the voltage of the capacitor 63 between the positive supply voltage 32 and the circuit ground 34 is adjustable, so that one of the Operator specified plateau range in the voltage of the capacitor 63 results, so that in the following half-waves always the same predetermined and symmetri cal gate angle is used, which leads to the desired dimmed state of the transformer 1 and the load connected to it.

This circuit presented on a single-phase network transformer can be expanded to a multiphase inductivity-prone power supply device. wherein at least two further branches of the branches: R, S and T each further AC switches 38 are provided in the continuous lines. which are preferably controlled via potential-separating optocouplers, each with its own gate control circuit 46 .

FIG. 3 shows signal profiles when the transformer 1 is switched on with a device according to an exemplary embodiment of the invention. The mains voltage 10 has been switched off at any time 11 not shown in the drawing. The remanence 16 is thereby set arbitrarily positive or negative and is shifted into saturation by the negative gates 17 , 21 and 23 increasing monotonically in the angle value, so that the circuit shown in FIG. 2 reacts to the small switch-on peak current 25 since the Current has exceeded 2 times the nominal current and generates a large positive gate angle 198 , which can be followed by further large angles or by slow slow changes in the large angle. Instead of this, preset by the comparator 89 , 91 , 91 'and 92 threshold of 2 times the nominal current, for example, 5 times the nominal current can be used as a trigger threshold.

The transformer remanence 1 was set correctly in Fig. 3 in principle after the second negative gate 21 , the subsequent third negative gate 23 is used to generate the small switch-on peak current 25 , with the help of which in continuous operation to be able to switch constant gate angles 197 for positive and negative half-waves 199 .

The unipolar and larger gates 17 , 21 and 23 shown in FIG. 3 have a rapidly increasing asymmetry until he reaches the small switch-on peak current 25 . If the polarity of the first cut is opposite to the remanence polarity, the remanence is shifted in a defined number of cuts into the other direction of saturation, the slowly increasing angle values ensuring that the saturation is reliably achieved despite any power losses that may occur.

However, if the polarity of the remanence given by the time of switching off 11 and the first gate 17 is the same, the switching currents integrate immediately and quickly, so that after a given by the properties of the transformer 1 very small number of cuts the primary circuit current 26 exceeds the predetermined value of the nominal current and this inrush current 25 of z. B. twice the nominal current is understood as the message from the transformer that its remanence is now set in the direction of the current 25 . The immediately following gate with a large angle and opposite polarity then leads to continuous operation of the transformer. This gate angle 198 is greater than 150 ° and can also the whole positive half-wave, that is 180 °. include.

This pre-adjustable by a may be at the set switch 61 is switched potentiometer Anschnittwin angle 198 is used for the transformer 1 ty pisch.

Of course, the circuit of FIG. 2 can also be constructed in a correspondingly differently polarized manner, so that the first gate angle 17 occurs before a positive zero crossing of a negative half-wave 18 and a correspondingly differently polarized switch-on peak current 20 for addressing the comparator to generate the remanence-setting half-wave leads. This half-wave with the gate angle 198 is then switched on in a positive half-wave 14 . The AND gate 95 is then placed in the negative switching line 54 and the negative current transformer 88 is replaced by a positive current transformer.

The measuring shunt 39 can, for. B. have a resistance value of 0.1 ohms. The charging resistor 62 and the resistor 97 have a resistance of z. B. 12 ohms and the discharge resistor 64 over a resistance value of 1.2 kiloohms, so that at full load operation without gating there is no gap in the current 26 by a small gating.

Claims (7)

1. Device device for alternating current cut-in limitation of a switched with an AC switch (38) in series inductance-loaded power supply (1) having a phase control circuit (46, 56, 95) by the alternating voltage connection of the inductance affected power supply device (1) with the network ( 6 , 10 ) from the switch-on moment ( 17 ) with a monotonically increasing phase gating angle ( 17 , 21 , 23 ) can be set, characterized in that the phase gating circuit ( 46 , 56 , 95 ) only connects the said connection with unipolar angles ( 17 , 21 , 23 ) produces that a in series with the inductivity power supply device ( 1 ) switched scarf comparator circuit ( 88 , 92 ) is provided, the output ( 92 ', 94 ) is connected to the leading edge circuit ( 46 , 56 , 95 ) that the Phase gating circuit ( 46 , 56 , 95 ) when it is acted upon by a primary circuit generated by the comparator circuit ( 88 , 92 ) Ice-overcurrent signal ( 20 ), the control electrode ( 58 ) of the AC switch ( 38 ) for the immediately following oppositely polarized half-wave ( 198 ) and the immediately following subsequent full waves with an ignition signal of 150 to 180 degrees and that in the phase control circuit ( 46 , 56 , 95 ) of the half-wave ( 198 ) following half-waves ( 199 ), an ignition signal can be generated at the predetermined phase angle ( 197 ). 2. Apparatus according to claim 1, characterized in that the phase gating circuit ( 46 , 56 , 95 ) has a voltage storage circuit ( 63 , 64 ) which varies over time in the output voltage value and a function generator, the voltage value ( 66 ) of the voltage storage circuit ( 63 , 64 ) with a periodically changing ramp voltage of the function generator in a comparator is comparable to the mains alternating voltage ( 10 ), and that with the comparator, if the two voltage signals are identical, a control signal corresponding to the polarity of the mains alternating voltage ( 10 ) and the control electrode ( 57 ) acting switching lines ( 53 or 54 ) can be generated, wherein in one of the two switching lines ( 53 ) a logic circuit ( 51 , 95 ) is provided, which is connected to the output of the comparator circuit ( 88, 92 ) and with which this Signal line can be blocked until the comparator circuit ( 88 , 92 ) an overcurrent signal l ( 20 ) has detected. 3. Apparatus according to claim 2, characterized in that a continuous operation circuit is provided with which the voltage level of the voltage storage device ( 63 , 64 ) after a primary circuit overcurrent signal ( 20 ) can be set such that the ignition signal of the pre-determined phase angle ( 197 ) can be generated in the comparator of the gate control circuit ( 46 , 56 , 95 ). 4. Apparatus according to claim 3, characterized in that a measuring shunt ( 39 ) is connected in series with the power supply device ( 1 ) that the voltage drop across the measuring shunt ( 39 ) with the comparator circuit ( 88 , 92 ) can be detected, that in the comparator circuit ( 88 , 92 ) the actual current detected by the measuring shunt ( 39 ) is comparable to a maximum target current, when it is exceeded the voltage storage circuit ( 63 , 64 ) can be set to the phase angle ( 198 ) with a setting switch ( 96 ) and that after a few periods this leading edge angle ( 198 ) begins to transition smoothly to the leading edge angle ( 197 ). 5. Device according to one of claims 2 to 4, characterized in that a phase shifter circuit ( 48 ', 48 '') between the power supply ( 31 ) and the gate control circuit ( 46 ) is provided, with which the synchronization voltage of the control circuit ( 46 ) the mains voltage ( 10 ) can be set in advance. 6. Device according to one of claims 2 to 5, characterized in that for generating the over current signal ( 20 ), the maximum desired current between 1 times to 10 times the nominal current is adjustable ( 91, 91 ' ). 7. Device according to one of claims 1 to 6, characterized in that the power supply device ( 1 ) is a three-phase power supply device, and for each or at least two branches of the three-phase power supply device, a current changeover switch ( 38 ) is interposed between the network and the three-phase power supply device.