FR2662556A1 - DOUBLE POWER DIMMER, ESPECIALLY LIGHT DIMMER. - Google Patents

Abstract

A dual regulator circuit, particularly a light dimmer circuit, for controlling the brightness of filament lamps such as halogen lamps. It is characterized in that it consists of a low-power circuit and a medium-power circuit controlled via two cursors connected to a potentiometer, one of which controls a 220 volt, approximately 500 watt lamp while the other controls a low-voltage, low-power lamp via a 220 volt/ 6-12 or 24 volt transformer according to the kind of lamp, with a power of approximately 50 watts.

Description

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.
Traditionally, each dimmer circuit is associated with a control box, generally placed on the ground. The variation of the light intensity is obtained by action on a slider connected to a potentiometer.
The object of the present invention is to propose a double power variator circuit capable of controlling, by means of two sliders of the aforementioned type, the light intensity of two incandescent lamps
The present invention therefore relates to a power variator circuit, characterized in that it is associated with two sliders each mounted on a potentiometer and intended to control each a load respectively by means of at least one common sub-circuit. , said power variator circuit being associated with two phases simultaneously supplying said loads. Such a common sub-circuit is advantageously a radio frequency interference suppression sub-circuit of the RLC type.

 Preferably, a load is mounted between the two phases by being connected to one of them by means of a triac controlled by a phase-shifting circuit comprising a potentiometer associated with at least one capacitive element. The two loads can each be connected via a triac controlled by a phase shifting circuit with the same phase, said loads then being each connected, for example, directly or by means of a fuse to the other of the two phases.

 A diac can be mounted between a point on a phase shifting circuit and the trigger of the triac that is controlled by said phase shifting circuit. A Zener diode can be connected in series with a diac element.

More preferably, a load is an incandescent lamp, in particular of the halogen type. In particular each load can be a lamp, one being a medium power lamp, the other being a low power lamp
(safety voltage) associated with a step-down element.The step-down element can be a transformer of 220 volts / 6-12 or 24 volts depending on the type of lamp, with a power of about 50 watts, or a converter circuit, the medium power lamp being a 220 volt lamp with a power of about 500 watts.

 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 elements of index between 1 and 10 are common to the two assemblies, the elements of index between 11 and 30 relate to the low power assembly, the elements of index greater than 30 relate to the medium assembly power.

Analysis of the low power circuit.

The load referenced (11) is placed on the secondary of a transformer (12) 220/6 - 12 or 24 volts depending on the type of lamp power about 50 watts. An optional fuse (13) can be inserted in series in this circuit. The transformer primary is supplied by the two phases (1) and (1 '). Phase (1) being connected to the load via a fuse (13) while phase (1') is connected with the interposition of a choke (4) and a triac (14), the triac (14) is controlled in phase by a phase shifting circuit comprising in series a resistive element (15,16) composed of a fixed resistance (15 ) (for example 120 ohms) and a variable resistance (16) (for example varying from O to 270 kilos ohms) which is coupled to the switch (17) which is then a limit switch corresponding to the position maximum resistance.The switch is optional - the Zener (20) having a similar role
The fixed resistor (15) is chosen so as to limit the triac trigger current at the time of priming of the latter.

 The phase shifting circuit comprises, associated with the resistive element (15,16) a capacitive element (21) (for example a 0.12 micro Farad capacitor) mounted in series with a fixed resistor (22) so that the midpoint (18) between the resistive 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 modulate the power delivered to the transformer primary (12).

In a manner known per se, the connection between the midpoint (18) of the phase shifting circuit RC and the trigger
G of the triac is produced by means of a diac (19) making it possible to generate current peaks ensuring better priming of the triac.

 Preferably, there is also provided on the trigger circuit, in series with the diac, a Zener diode (20) (for example a diode at about 12 V), which ensures complete extinction of the load even if the actual maximum value of resistance of the variable resistor (16) (for example 470 kilos ohms) is less than the nominal value (for example 500 kilos ohms) for which the circuit has been calculated; the consequences of dispersions in the manufacturing characteristics of the variable resistances are thus overcome, dispersions which can be significant.

 A radio frequency interference suppression circuit is included. I1 includes an inductor (4) in series with the triac (14) and the transformer primary (12) associated with two RC networks, mounted in parallel on the branch formed by the inductor (4) and the triac (14), one is mounted in series (25,26) and the other in parallel (23) (24).

Analysis of the medium power circuit.

 The load (31) is here directly supplied by the two phases (1) and (1 ') via the triac (32). The phase (1) being connected to the load via a fuse (2) while the phase (1 ') is connected to the point (3) common with the low power circuit via the inductor ( 4) triac (32).

 The triac (32) is controlled in phase by a phase shifting circuit comprising in series a resistive element (33,34) composed of a fixed resistance (33) (for example 2.7 kg ohms) and a variable resistance (34 ) (for example varying from 0 to 270 kg ohms).

 The resistor (33) is chosen so as to limit the triac current of the triac when it is primed.

 The phase shifting circuit comprises, associated with the resistive element (33,34) a capacitive element (35) (for example a capacitor of 0.1 micro Farad). The midpoint (36) will have a variable phase shift relative to the power electrodes 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. (31).

In a manner known in itself the connection between the midpoint (36) of the phase shifting circuit RC and the trigger
G of the triac is produced by means of a diac (37) associated with a Zener diode (38) (for example a diode at approximately 12 volts).

 A radio frequency interference suppression circuit comprising the choke (4) already mentioned, in series with the triac (32) and the load (31), comprising in parallel on the branch formed by the choke (4) and the triac (32) a capacity (5) is provided.

Claims (9)

 l. power variator circuit, characterized in that it is associated with two sliders each mounted on a potentiometer (16, 34) and intended to control each a load (11,31) respectively by means of at least one common sub-circuit (4, 23, 24, 25, 26), said power variator circuit being associated with two phases (1,1 ') simultaneously supplying said loads (11,31).  2.Circuit according to claim l, characterized in that a common sub-circuit is a sub-circuit (4, 23, 24, 25, 26) of radio interference suppression of the RLC type.  3.Circuit according to one of claims 1 or 2, characterized in that a load (11,31) is mounted between the two phases (1,1 ') by being connected to one (1') of it via a triac (14,32) controlled by a phase shifting circuit (15,16, 21, 22; 33, 34, 35) comprising a po tentiometer associated with at least one capacitive element.  4.Circuit according to claim 3, characterized in that the two loads (11,31) are each connected by means of a triac controlled by a phase shifting circuit with the same phase (1).  5.Circuit according to claim 4, characterized in that the two loads (11,31) are connected to the other (1) of the two phases directly or by means of a fuse (2,13).  6.Circuit according to one of claims 3 to 5, characterized in that a diac (19,37) is mounted between a point of a phase shifting circuit and the trigger of the triac (14, 32) that controls said phase shifting circuit .  7.Circuit according to claim 6, characterized in that a Zener diode (20,38) is connected in series with a diac (19,37).  8.Circuit according to one of claims 1 to 7, characterized in that a load (11,31) is an incandescent lamp, in particular of the halogen type.  9. Circuit according to claim 8, characterized in that each load (11,31) is a lamp, one (31) being a medium power lamp, the other (l1), being a low power lamp associated with a tension lowering element (12).  lO.Circuit according to claim 9, characterized in that the step-down element (12) is a transformer of 220 volts / 6-12 or 24 volts depending on the type of lamp, with a power of about 50 watts, the medium power lamp being a 220 volt lamp with a power of about 500 watts.