FR2631173A1 - SECURITY POWER VARIATOR - Google Patents

Abstract

A variator circuit comprises a triac (4) mounted in series with a load (1) to be controlled, and a CTR variable series phase-shifter circuit (8, 9, 10). The point (11) midway between the resistive element (8, 9) and the capacitive element (10) of said circuit (8, 9, 10) is connected to the gate (6) of the triac. Connected in series in the branch of the circuit comprising the resistive element and the connection of said midway point to the triac is a non-linear component (18) the resistance of which can change from a minimum value to a maximum value when the current flowing through it increases by a minimum value corresponding to the normal operating conditions of the phase-shifter circuit to a maximum value corresponding to a short-circuit condition of the triac between the gate and the power electrode, said minimum value of the resistance being a value which has no appreciable effect on the functioning of the phase-shifter circuit and said maximum value of the resistance being a value which limits the current in the resistive element to a value which prevents any destruction or deterioration of the latter. Said non-linear component may be a CTR resistor, a fast safety fuse or, very advantageously, the filament of an incandescent lamp, the characteristics of said filament, in particular its equivalent resistance under nominal operating conditions, being chosen so that it volatilizes in the event of a short-circuit condition of the triac between the gate and the power electrode.

Description

Safety power variator
The present invention relates to power dimming circuits, in particular light dimming circuits used for controlling the light intensity of incandescent lamps such as halogen lamps.

 Conventionally, these dimmer circuits include a triac mounted in series with a load to be controlled (the incandescent lamp, in the case of a light dimmer), and a variable series RC phase-shifter circuit whose midpoint between the element resistive and the capacitive element is connected to the triac trigger.

 More specifically, the resistive element generally consists of a variable resistance (used to adjust the light intensity by the user) connected in series with a fixed resistance of lower value, so that the total resistance of the set is never zero, even for the minimum setting of the variable resistance, thus avoiding excessive trigger current.

 The connection between the midpoint of the series RO circuit and the triac trigger is usually made by means of a diac forming a component with a triggering threshold, possibly in series with a Zener diode to allow the complete extinction of the power circuit. below a certain variable resistance setting threshold.

 Both for domestic and professional uses, these drives must meet a certain number of safety standards, in particular the CEI 65 standard (French standard NF C92-130) which impose a certain number of severe safety conditions as well as regards mechanical robustness (tensile strength on films, solidity of the housing, etc.) than electrical.

 In particular, among the electrical constraints, the various short-circuits which can occur between the electrodes of the triac must not cause harmful consequences following the production of sparks, excessive heating, etc.

 However, these short circuits, which result from manufacturing faults in components, are not uncommon and, statistically, may not appear for several tens of hours of operation only.

 Among the three possible short circuits between electrodes of the triac (which includes three electrodes, namely a trigger and two power electrodes), two of the short circuits will not have any harmful consequences: this is the short circuit between the two power electrodes (the lamp will then be supplied at full power, continuously, the dimmer having no effect) and the short circuit between the trigger and those of the power electrodes which is connected to the mains on the same side as the resistive element of the phase shifting circuit (the loop of the trigger control circuit will then short-circuit on itself, the triac will no longer be triggered, and the variator will also have no effect).

 On the other hand, the third short-circuit condition can, in certain cases, have serious damaging consequences.

 Indeed, in the event of a short circuit between the trigger and those of the power electrodes which is connected to the sector on the same side as the capacitive element of the phase-shifting circuit, the midpoint of the phase-shifting circuit between the resistive element and the element capacitive will be brought to the potential of the mains phase at the location of the short circuit, so that the resistive element of the phase shifting circuit will be subjected between its terminals to a voltage equal to the mains voltage.

 This mains voltage can induce an intense current in the variable resistance and in the fixed resistance, a current which will be all the more intense as the variable resistance will be positioned on a low value. The resulting current can cause destruction of the fixed resistance or of the variable resistance, or of these two elements, with a heating such that this destruction can be accompanied by an emission of smoke and flames by combustion of the printed circuit board supporting these circuit elements.

 The object of the present invention is to provide a power variator circuit of the aforementioned type which provides complete security against such an operating incident, thus ensuring total compliance with the aforementioned security standards.

 To this end, according to the invention, the power variator circuit comprises, in series in the circuit branch comprising the resistive element and the connection of said midpoint to the triac, a non-linear component whose resistance is liable to pass from a minimum value to a maximum value when the current flowing through it increases respectively from a minimum value corresponding to the normal operating conditions of the phase-shifting circuit to a maximum value corresponding to a triac short-circuit condition between trigger and power electrode, said minimum resistance value being a value without significant impact on the operation of the phase shifting circuit and said maximum resistance value being a value limiting the current in the resistive element to a value preventing any destruction or deterioration thereof.

 In a first embodiment, said non-linear component is a PTC resistor; in another embodiment, said non-linear component is a fusible element.

In a first variant of implementation of this second mode of
embodiment, the fuse element is a fast safety fuse; in
second variant of implementation - which is the preferred variant of implementation of the invention - the fusible element consists of the filament of an incandescent bulb, a filament whose characteristics, in particular its equivalent resistance under nominal conditions are chosen so that it volatilizes in the event of a triac short-circuit condition between the trigger and the power electrode.

 Other characteristics and advantages of the present invention will appear better on reading the detailed description of an exemplary embodiment, made with reference to the single appended figure, which represents the diagram of a power variator circuit implementing the teachings of the present invention.

 In this figure, the reference 1 designates the load to be controlled (typically, an incandescent lamp such as a halogen lamp), which is supplied by the two phases 2 and 2 ′, phase 2 being connected directly to the load, while that phase 2 ′ is connected with the interposition of a general fuse 3, of a triac 4 and of a switch 5, for example a foot control switch with two positions: a position where it switches the load via the triac, and a position where it disconnects it and simultaneously lights a neon indicator 6, with its associated limiting resistor 7, making it easier to find the switch in the dark.

 Conventionally, the triac 4 is controlled in phase by a phase shifting circuit comprising, in series, a resistive element 8.9 composed of a fixed resistance (for example, 2.7 kn) and a variable resistance 9 ( for example varying from 0 to 500 ka) which can be coupled to switch 5, which is then a limit switch corresponding to the position of maximum resistance. The fixed resistor 8 is chosen so as to limit the triac current of the triac at the time of priming of the latter.

 The phase shifting circuit comprises, associated with the resistive element 8.9, a capacitive element 10 (for example a condenser of 0.11 lF), so that the midpoint 11 between the resistor element and the capacitive element will have a variable phase shift relative to the power electrodes A1, A2 of the triac, thus making it possible to delay the initiation of the latter relative to the start of each half-period and thus to modulate the power delivered to the load 1.

 In a manner known per se, the connection between the midpoint 11 of the phase shifting circuit RC and the trigger G of the triac is carried out by means of a diac 12 allowing 4th; generate current peaks ensuring better priming of the triac.

 Preferably, a trigger circuit is also provided, in series with the diac, a Zener diode 13 (for example a diode at about 12 V), which ensures complete extinction of the load even if the actual maximum resistance value of the variable resistance 9 (for example 470kn) is less than the maximum nominal value (for example, 500kan) for which the circuit has been calculated; this mitigates the consequences of dispersions in the manufacturing characteristics of the variable resistance, dispersions which can be significant.

 Finally, a radio frequency suppression circuit is provided comprising an inductor 14 in series with the triac and the load, and a capacitor 15 in parallel on the branch formed by the inductor 14 and the triac 4.

 The assembly which we have just described is in itself classic.

As indicated above, the short circuit between the power electrodes A1 and A2 of the triac will have no harmful consequences, as will a short circuit between the trigger G and the power electrode.
A2; simply, in either of these two cases, it will no longer be possible to vary the power delivered to load 1.

 On the other hand, in the event of a short circuit between the trigger and the power electrode A1 (short circuit symbolized in 16), the trigger will be brought, via the load 1, to the potential of phase 2 and we will find this potential at midpoint 11, the diac 12 and the Zener diode 13 being both passers-by since they are polarized beyond their limit conduction threshold.

 The resistive circuit 8.9 will therefore receive between its terminals 11.17 a voltage substantially equal to the mains voltage, therefore considerably greater than that at which it usually operates (of the order of a few volts).

 If, at this time, the variable resistance is in a position corresponding to a high resistance value, this incident will not have any harmful consequence, since the effective current passing through the resistive element will remain low and compatible with the nominal power of variable resistance 9 (generally 0.5 W). On the other hand, for a range of resistance values between approximately 3 and 10 kn (for the values given here by way of example), the intensity passing through variable resistance 9 and the fixed resistance 8 will become much greater than what these two elements can dissipate, so that they will be very quickly destroyed, the heating even often producing the combustion of the printed card with emission of flames or fumes: Indeed, for a certain range of resistance values, the current will be low enough not to blow the general protection fuse 3 (which is calibrated on the nominal current passing through the load, which is several amps), but strong enough to cause combustion and destruction of the fixed resistor 8 and the variable resistor 9.

 To overcome this drawback, the present invention proposes to insert, in series in the trigger circuit (that is to say the branch between point 17 and the triac trigger) a non-linear component 18 protecting the circuit against such overcurrents.

 In a first embodiment, the non-linear component 18 is a resistance with positive temperature coefficient (PTC), the characteristics of which are chosen so that it can operate as a current limiter: when the overload resulting from the short circuit 16 occurs, the CTP heats up due to the sudden increase in intensity and reaches its Curie point; its resistance to> then rments very quickly, becoming much higher than that of: - the resistive element 8.9, thus ensuring the protection of the latter.

This embodiment has the advantage of total reversibility, which is interesting if it is possible to eliminate the cause of the short circuit 16; however, it has the disadvantage of requiring an expensive component (the
CTP) and have a relatively long response time, of the order of half a second, to heat up the CTP sufficiently.

 In a second embodiment, the non-linear element 18 is a fusible element.

 This fuse element can be a rapid safety fuse of the conventional type (cartridge, tubular, - to be welded, ... fuse). 11 has the advantage of simplicity. On the other hand, since the fuse must be calibrated at a very low current (typically, 10 mA), this component is relatively expensive and practice shows that the response time is relatively long even for a "fast" type fuse because the values commonly available commercially are limited to 10 mA, and such a value is still too high for the protection sought, for which a value of 5 mA or less would be desirable.

 Furthermore, very low current fuses could not be used in dimming circuits for relatively large loads, because they would then be calibrated at a value too close to the minimum average trigger current required (typically, the trigger current can reach 50 to 70 mA, depending on the manufacturing).

 In a variant - preferential - of implementation, the fusible element consists of an incandescent bulb, the characteristics of the filament of which are chosen so that it becomes volatilized as soon as an overcurrent appears in the trigger circuit.

 Thus, in the case of a circuit whose elements have the values indicated above by way of example, it has been found that a bulb of 5V / 15 mA (i.e. a hot resistance of 333 n under nominal conditions operating conditions) met these conditions.

 On the other hand, a bulb of the same type of 3 V / 8 mA (i.e. a resistance of 375 n under nominal operating conditions) did not fulfill its role as a fusible element: indeed, in the latter case, during a short circuit in the trigger circuit the filament was brought to a sharp glow but did not volatilize, so that the resistive element 8,9 was destroyed and caused the combustion of the printed circuit board.

 It is therefore important to make a selection of the bulb used, one of the important parameters being the hot resistance of the filament under nominal operating conditions: with the examples of numerical values given above, it has been found that 'an equivalent resistance greater than about 350 n prevented the lamp from properly fulfilling its role as a safety element, the latter operating in "incandescence" mode and not in "fuse" mode.

 In addition to its very low cost, such an element has the advantage of a very high response speed - greater than that of a CTP or of a "fast" conventional safety fuse.

 It thus ensures full compliance with the aforementioned safety standards of the variator according to the invention.

 Of course, the values given in the present description are only for information and can vary widely depending on the various values of components used.

 It will also be noted that, whatever the embodiment, the non-linear component 18 can be placed at any location of the trigger control circuit, that is to say at any location of the branch between common point 17 and the trigger G of the triac.

In addition to the position shown in the figure, the element 18 can also, as a variant, be placed for example in series at point 19 (between the midpoint 11 and the diac.12), or even in series at point 20 (just before trigger G).

Claims (5)

 1. A power variator circuit, comprising a triac (4) connected in series with a load (1) to be controlled, and a variable series RC phase shifter circuit (8, 9, 10) whose midpoint 11 between the resistive element (8,9) and the capacitive element (10) is connected to the trigger (G) of the triac,  characterized in that it comprises, in series in the circuit section comprising the resistive element and the connection of said midpoint to the triac, a non-linear component (18) whose resistance is liable to pass from a minimum value to a maximum value when the current flowing through it increases respectively from a minimum value corresponding to the normal operating conditions of the phase shifting circuit to a maximum value corresponding to a triac short-circuit condition between trigger and power electrode, said minimum value of resistance being a value without significant impact on the operation of the phase shifting circuit and said maximum resistance value being a value limiting the current in the resistive element to a value preventing any destruction or deterioration thereof.  2. The dimmer circuit of claim 1, wherein said non-linear component is a PTC resistor.  3. The variator circuit of claim 2, wherein said non-linear component is a fuse element.  4. The dimmer circuit of claim 3, wherein said fuse element is a fast safety fuse.  5. The dimmer circuit of claim 3, wherein said fuse element is constituted by the filament of an incandescent bulb, a filament whose characteristics, in particular its equivalent resistance under nominal operating conditions, are chosen so that it volatilizes in the event of a triac short circuit condition between trigger and power electrode