FR2749450A1 - Optoelectronic power supply device for liquid crystal display - Google Patents

Abstract

The device includes a rectifying bridge connected to the drain and source of an NMOS transistor (T1) and a Zener diode (D3) which delivers a signal BV2(t). A second rectifying bridge (PT1), connected with its input to two resistors (R1,R2), generates a signal Av1(t) applied to the input of an optocoupler (OC1). A switch (I1) controls a resistor (R9) in parallel with a capacitor (C6) and a rectifying bridge (PT3) which generates a current applied to a relay (Re1). The current also supplies the input of a second optocoupler (OC2).

Description

Electronic feeding device for film
liquid crystal
The invention relates to an electronic power supply device for liquid crystal films producing a synchronous quasi-sinusoidal output voltage of 110 volts and controlled by the sinusoidal alternating input voltage of a 230 volt mains network, the control of starting of this output voltage is triggered simultaneously at the zero of one of the half-waves of the said resector.

Film supplies of known types with liquid crystals deliver for the major part of them an alternating voltage. This tension generates a known reaction having the effect of modifying the natural state of the crystals, generating either an opacity or a transparency of said films. These liquid crystal films are often mounted in glazing and used in space separation applications for the building; thus the glazing is opaque without supply and becomes transparent when it is supplied. We will call to simplify later LCD film, the liquid crystal film.

The characteristics of the voltage supplying these films
LCDs are fixed by the nature of the crystal used. In fact, the variations in amplitude, frequency, or starting at zero of the half-wave are themselves fixed for each nature and technology of crystal. The major part of the known type LCD films can be supplied by a sinusoidal alternating signal of maximum effective value 110 volts and frequency 50 hertz. It is very often imperative to respect the effective value of food under penalty of destroying the film
LCD. These LCD films are capacitive and must in general be imperatively supplied by a signal starting at the zero of the half-wave and discharged to zero volts when the supply stops.

This effective value of 110 volts requires on most European supply networks, set at 230 volts, the use of a transformer to lower the voltage, in order to use the mains voltages for 1 supply of said films. These transformers of known types are constituted by an input coil and an output coil connected by a ferromagnetic frame. These transformers are of course functional, but claim many disadvantages, in particular in terms of weight / power ratio, size, no-load consumption, conversion efficiency, phase shift between the input voltage and the output voltage.

Indeed, these heavy and bulky transformers are sometimes difficult to install, this is linked to their technology, all in all archaic. The empty consumption is penalizing because unnecessary, it can represent the consumption of an LCD film surface of one square meter. The conversion yield in the best of cases is only 90%. The phase shift generated by a coil transformer is very annoying if one wishes to view, through the LCD film, the video image coming from a television set connected to the sector because in this case the phase shift is materialized by a black bar on 1 In addition, these transformers must be equipped with a starting system at the zero of their secondary half-wave so as not to cause the destruction of the LCD film and with a system for discharging the capacitive energy thus stored.

The object of the present invention is to remedy these drawbacks by proposing a compact and light electronic power supply device delivering an output voltage controlled by the mains voltage of 230 volts, having a conversion efficiency of 99%, an empty consumption. very weak, synchronization to the network signal, start to zero of the half-wave, an automatic discharge system as well as protection for limiting the output voltage of the LCD film fixed at 110 volts.

According to FIG. 1 and over a period 0 to T, the electronic supply device for liquid crystal film is characterized, on a sinusoidal alternating mains network Ev4 (t) and with respect to a defined reference voltage Vref, in that it produces a signal
Cv4 (t) controlled by the signals Ev4 (t) and S2 (t) and defined by Cv4 (t) = Ev4 (t) -S2 (t) with S2 (t) = 0 for any lower value of Ev4 (t) at Vref and with S2 (t) = Ev4 (t) -Vref for any value of Ev4 (t) greater than or equal to Vref.

On the period 0 to T of the time axis are represented the references tl, t2, t3, t4 corresponding to the value Vref defined at 110 volts on the axis of the voltages.

During time 0 to tl, t2 to t3 and t4 to T: the signal
Cv4 (t) = Ev4 (t) -S2 (t) with S2 (t) = 0 so the result
Cv4 (t) is identical to the sector signal Ev4 (t).

During the time tl to t2 and t3 to t4: the signal
Cv4 (t) = Ev4 (t) -S2 (t) with S2 (t) = Ev4 (t) -Vref therefore the resultant Cv4 (t) = Ev4 (t) - (Ev4 (t) -Vref) or Cv4 ( t) = Vref the signal Cv4 (t) therefore has a constant value equal to Vref, ie 110 volts, over these time intervals.

To do this and according to FIG. 2, the stage (1) delivering the sector signal Ev4 (t) crosses the fuse Fl to be suppressed by the capacitor C1 before being sent to different main stages constituting the device according to the invention which are: stage (2) performing synchronization on the mains signal
Ev4 (t); The stage (3) carrying out the conversion to generate the signal Cv4 (t); the stage (4) making the connection of the signal Cv4 (t) to the output signal Cv5 (t) on a zero of the sector signal Ev4 (t) generated by the control switch forming the stage (5); the stage (6) producing the filtering and the discharge of the LCD film.

According to FIG. 3 the stage (2) is constituted by a direct collection of the mains voltage carried out by the current drop resistors RI and R2, to supply the rectifier bridge PT 1 which delivers the rectified double-wave signal Avl (t) , Figure 4, at the input (1, 2) of the optocoupler OC l and across the variable resistor R3. The signal Avl (t) is in fact perfectly synchronous to the sector signal Ev4 (t).

The adjustment of the value of the variable resistance R3 makes it possible to fix the maximum amplitude of the signal Av l (t) and consequently to fix the point of polarization of the transistorized output (4, 6) of the optocoupler OC 1, this state is also directly proportional to the value of the signal Avl (t) and therefore of the sector signal Ev4 (t). Let Avl (t) = nl.Ev4 (t), with nl representing the attenuation coefficient induced by resistances Rt, R2, and R3.

According to FIG. 3, stage (3) uses an alternation of the mains signal Ev4 (t) via the diode Dl, the current drop resistor R4 and the rectifier bridge PT2 to form a voltage of 12 volts ,
Bv2 (t) in Figure 4, regulated by the zener diode D3 and filtered by the filtering capacitor C2.

The signal Bv2 (t) feeds through the resistor R5 the gate (G) of the transistor Ti, the diode D2 and the capacitor C3 providing protection of the said gate, as well as the output (4, 6) of the optocoupler OCt, so transmit the value of 12 volts to the signal Bv3 (t).

The specific NMOS technology of the transistor Tt generates, between its drain (D) and its source (S), a specific resistance called Rds whose value is inversely proportional to the value of the voltage
Bv3 (t) between the grid (G) and the source (S). In fact, when the voltage Bv3 (t) is of the order of 12 volts, the resistance Rds is close to 0 ohm which corresponds to a closed switch between (D) and (S); on the contrary, the weaker the voltage Bv3 (t) the more the resistance
Rds increases.

The setting of R3 fixed allows the transistorized output (4. 6) of OC t to remain blocked for times 0 to tl, t2 to t3 and t4 to T. In fact, the voltage Bv3 (t) of Tl is l 'order of 12 volts and therefore generates a closed switch between (D) and (S) during these time intervals.

The setting of R3 fixed also allows the transistorized output (4, 6) of OC t to enter into conduction for the time intervals tl to t2 and t3 to t4. The saturation state of said output is directly proportional to the value of the signal Avl (t), and therefore generates a proportional decrease in this signal by the value 12 volts from the signal Bv2 (t) to form the signal Bv3 (t ). Consequently, Bv3 (t) = Bv2 (t) (n2.Avl (t)) with n2 representing the transmission coefficient induced by the OC1 optocoupler. In fact, the value of the resistance Rds over the intervals tl to t2 and t3 to t4 varies in proportion to the value of the signal
Avl (t) and therefore of the sector signal Ev4 (t).

The drain (D) and the source (S) of the transistor T l are respectively connected to the positive terminal (+) and to the negative terminal (-) of the rectifier bridge PT2.

The PT2 rectifier bridge is, in this assembly, used as a bidirectional switch, that is to say that the creation of a closed circuit between its positive terminal (+) and its negative terminal (-) gives rise to its alternative terminals a closed switch, the equivalent diagram of which can be represented by two beches head diodes; on the contrary, the creation of an open circuit between its positive terminal (+) and its negative terminal (-) generates, with respect to its alternative terminals, an open switch.

One of the alternative terminals of the rectifier bridge PT2 is connected to the mains line E, while the other is connected to the output C of the device according to the invention.

During times 0 to tl, t2 to t3 and t4 to T, the transistor
TI forms a closed switch (Rds = 0) between its drain (D) and its source (S) which generates for the AC terminals of the rectifier bridge PT2 a closed switch and therefore for the voltage Cv4 (t), Figure 4, a perfect similarity with the sector signal Ev4 (t).

During times tl to t2 and t3 to t4, the value of the resistance Rds of T1, arranged between the terminals (+) and (-) of the rectifier bridge PT2, varies in proportion to the value of the signal Av l (t) and of the sector signal Ev4 (t).

This synchronous variation in the sector signal Ev4 (t) generates a reduction in this same signal proportional to the value of the signal Avl (t) and therefore proportional to the value of the sector signal Ev4 (t).

This effect makes it possible to create, between lines C and v4, the signal Cv4 (t) enslaved by the sector signal Ev4 (t) and having over the intervals tt to t2 and t3 to t4 a constant value equal to Vref fixed by the resistance variable R3.

The resistor R6 and the capacitor C4 connected in parallel on Cv4 (t) make it possible to improve the shape of this signal while the varistor VRt and the fuse F1 form the safety elements limiting the voltage
Cv4 (t) at 110 volts. In the event of an overvoltage problem, the varistor VR 1 short-circuits and trips the fuse Fl placed in series and upstream on the mains line v4.

According to FIG. 3, the stage (4) makes it possible to generate the signal Cv5 (t) by its connection to the signal Cv4 (t) made by the triac T2 connected to the mains line v4 to form a serial switch, between the line v4 and line v5, and controlled, via resistor R8, by the output (4, 6) of the OC2 optocoupler. The OC2 optocoupler has an internal alternating start system.

According to Figure 3, the stage (5) realizes the control switch I1 of the stage (4). The switch It connects to the mains signal Ev4 (t) the capacitor C6 in parallel with the resistor R9 constituting a current source rectified by the rectifier bridge PT3 and filtered by the capacitor C 7 to create the voltage Dv6 (t), figure 4 , used to supply in series the relay Re 1, fitted with a freewheeling diode D4, and the input (t, 2) of the opotocoupler OC2. When the switch Il closes, the optocoupler OC2 controls the triac T2 which connects the signal Cv4 (t) to the output signal Cv5 (t) on a zero of an alternation of the sector signal Ev4 (t).

According to FIG. 3, the stage (6) the capacitor C5 is used to filter and maintain the output signal CvS (t) during a no-load operation. The coil of Rel relay is energized by the closing of switch II to disconnect the resistor R7 for discharging the LCD film.

Conversely, when the switch I1 is open, the relay Re 1 connects the resistor R7 to discharge the film LC D of the stored energy and thus prevent its destruction.

FIG. 4, cited above, describes the timing diagrams of the various signals identified in FIG. 3.

The succession of the different stages (t, 2, 3, 4, 5, 6) generates a synchronization of the alternating signals
Avl (t), Bv3 (t), Cv4 (t) and Cv5 (t) on the mains signal
Ev4 (t) whether at the instant of control by the switch I1 or during the continuous operation of the device.

The efficiency of the device according to the invention is of the order of 99% since the output power comes directly from the mains network.

At equivalent power, the weight and compactness of the device according to the invention are far better than all types of conventional transformers.

The elements shown in Figure 3 have the following values.

R1 47 KH W
R2 47 KH W
R3 10 KH adjust 10 T
R4 39 KH W
R5 100 KH 1/4 W R6 1 MH W
R7 2.2 KH 5 W
R8 180 HW R9 1 MH W
C1 1, uF 400 V
C2 22 F 25 V
C3 5.6 nF 56 V
C4 1 pF 400 V
C5 100 nF 400 V
C6 470 nF 400 V
C7 22 pF 50 V
Dl 1N4004
D2 1N4148
D3 BZX 55 C 12 V
PTI B380 C1500
PT2 B380 C5000
PT3 B380 C1500
OC1 4 N 25
OC2 MOC 3041
T 1 IRFP 450FI
T2 BTA 08 400B
Rel JW1FSN12V
F1 3.15 A 250 V
VR1 1305

Claims (8)

 1. Electronic power supply device for liquid crystal film characterized on an alternating sinusoidal mains network Ev4 (t) and with respect to a defined reference voltage Vref, in that it produces a signal Cv4 (t) controlled by the signals Ev4 (t) and S2 (t) and defined by Cv4 (t) = Ev4 (t) -S2 (t) with S2 (t) = 0 for any value of Ev4 (t) less than Vref and with S2 (t) = Ev4 (t) -Vref for any value of Ev4 (t) greater than or equal to Vref. 2. Device according to claim 1, characterized in that the rectifier bridge PT2 connects an alternative terminal to the sector line E, its other alternative terminal delivering the line C to form with the sector line v4 the signal Cv4 (t), also characterized in that it connects respectively its positive terminal (+) and its negative terminal (-) to the drain D and to the source S of the transistor T1 of the NMOS type forming together a bidirectional resistive switch in series of the mains signal Ev4 (t) of which the resistance value is inversely proportional to the signal Bv3 (t) itself characterized in that it is a function of the mains signal Ev4 (t). 3. Device according to claim 2, characterized in that the signal Bv3 (t) is defined by the relation Bv3 (t) = Bv2 (t) - (n2.Avl (t)) with n2 representing the transmission coefficient of l optocoupler Oct also characterized in that the signal Bv2 (t) is a stabilized signal of constant value, and that the signal Avl (t) is defined by Avl (t) = nl.Ev4 (t) with nl representing the attenuation coefficient induced by the resistors Rl, R2 and R3. 4. Device according to claim 3, characterized in that the signal Bv2 (t) comes from an alternation of the sector signal Ev4 (t) attenuated by the current drop resistance R4 then rectified by the diode Dl and the rectifier bridge PT2, to form a voltage of 12 volts, regulated by the zener diode D3 and filtered by the capacitor C2; further characterized in that the signal Avl (t) comes from the voltage of the mains signal Ev4 (t) attenuated by the resistors Rl and R2 then rectified in full alternation by the rectifier bridge PT t to be applied to the resistor R3 and supply the input (1, 2) of the optocoupler OC l. 5. Device according to claim 3 or 4, characterized in that the switch I1 controls the resistor R9 in parallel with the capacitor C6 to produce a current generator rectified by the rectifier bridge PT3 and filtered by the capacitor C7 to excite the coil of the Rel relay fitted with a freewheeling diode D4 and supply the input (t, 2) of the optocoupler OC2 and thus trigger on a zero of the alternation of the mains signal Ev4 (t), via the resistor R8 and triac T2, signal connection Cv4 (t) to the signal Cv5 (t) producing the device output signal. 6. Device according to claim 5, characterized in that the relay coil Rel generates, in the rest state, the connection of the discharge resistor R7 to the output signal CvS (t) and generates, during an excitation, the discharge resistance disconnection R7 of the output signal Cv5 (t). 7. Device according to any one of the claims characterized in that the fuse Fl is connected in series and upstream of the line v4 and that the varistor VR 1 is arranged in parallel on the signal Cv4 (t) to protect the value of the Cv4 (t) signal. 8. Device according to any one of the claims, characterized in that the capacitor CI forms an interference suppression of the sector signal Ev4 (t) as well as the capacitor C4 associated with the resistor R6 improve the shape of the signal Cv4 (t), likewise that the capacitor C5 filters and maintains the signal Cv5 (t) during a no-load operation.