FR2830697A1 - Electric power supply for vacuum fluorescent display (VFD), uses a regulator producing a continuous regulated voltage - Google Patents

Abstract

Includes a regulator (28), producing a regulated continuous voltage, having an input terminal (39) connected to an output (36) of one (14) of the secondary windings of a transformer (8) and by a connection (35) including a switch (33) to a terminal (4) of a direct voltage source. The switch (33) has a control input (31) connected to a control circuit (34) for the switch. The circuit (34) has an input (37) connected to a direct current supply. Electrical supply with terminals (2,4) connected to a continuous voltage source. Includes: (a) a transformer (8) with magnetic circuit (16) and primary (6) and secondary (10,12,14) windings, a switching and regulating circuit (18) controlling the time passage of current from the continuous voltage source in the primary winding (6). One of the transformer secondary windings (12) has a central tapping (7) connected to a terminal (4) of the continuos voltage source and to outputs (13,15) delivering voltages in phase opposition.

Description

<Desc / Clms Page number 1>

ELECTRICAL SUPPLY FOR A VFD
DESCRIPTION Technical area
The present invention is in the field of electrical power supplies intended to supply one or more fluorescent vacuum display means.

These are flat triode tubes known in the state of the art under the name of VFD, (Vacuum Fluorescent Display).

VFDs are used in particular for displaying information on dashboards, for example automobile dashboards. The invention also relates to a circuit comprising said supply and the VFD, and to a use of this supply for supplying a VFD.

Technological background
VFDs are used as a means of display on a large number of types of devices, in particular consumer electronic devices and for automobile dashboards. They have a filament, which when heated emits electrons, a grid and an anode. The grid and the anode brought to a positive potential with respect to the potential of the filament make it possible to accelerate the electrons towards the anode. The anode has an electroluminescent coating which becomes bright when struck by electrons. As a standard, VFDs are available as segments arranged so that they can produce alpha numeric characters or other patterns. In operation, the

<Desc / Clms Page number 2>

 filaments are heated continuously, and the segments are lit or not depending on the value of lighting voltages applied or not both on the grid and the anode. The application of the lighting voltages is controlled by control means. In the absence of positive lighting voltages, a residual luminescence of the segments is caused by electrons having a high thermal energy. To avoid this remanent luminescence, the filament is polarized by a positive potential called extinction. Thus, when the anode does not receive a lighting voltage, the filament is at a positive potential with respect to the anode and the thermal electrons are subjected to an electric field which brings them back to the filament. Of course, the values of the gate and anode lighting potentials are fixed at a higher value than the value of the extinction potential. The polarized filament is heated by an alternating current applied to its ends. In general, the means for controlling the lighting potentials of the different segments of the VFD are constituted by a microcontroller.

 Thus, it can be seen that the electrical supply of a VFD requires positive supply voltages for the anode and the grid, a different positive voltage for the polarization of the filament and an alternating voltage for heating the filament.

In addition, a voltage is required to supply the microcontroller.

 The present invention relates to an electrical supply capable of producing in particular all the voltages necessary for supplying and controlling the VFD, a circuit comprising the supply

<Desc / Clms Page number 3>

 and the VFD, and finally a use of the power supply to supply one or more VFDs.

 In automotive technology, these different voltages are produced individually by circuits independent of each other, each circuit receiving the voltage delivered by the battery and producing one of the necessary regulated voltages. These voltages are produced by conventional power supplies which do not have the facilities for adapting the power consumed by the user circuits to the power delivered and consumed by the power supply.

Brief description of the invention
The object of the present invention is to simplify the circuits intended to produce the various voltages necessary in particular for supplying and controlling VFD. De la'sorte, we reduce the mass of circuits, their manufacturing time and therefore their cost. Another object of the present invention is also to reduce the electrical consumption by a better adaptation of the power delivered by the power supply to the power consumed by the user circuits. Finally, it aims to reduce consumption in standby modes.

 For all these purposes, according to the invention, a switching power supply receiving a voltage from a DC voltage source, for example a battery, is used to produce the different voltages necessary for the electrical supply of VFD.

<Desc / Clms Page number 4>

 In itself known manner, a switching power supply comprises one or more primary windings coupled to a DC power source, through a switching circuit which establishes or interrupts the flow of current between the source and the or the primary windings so that a pulsating regime is established in the primary windings. The power supply also includes several secondary windings delivering voltages at different values directly, or preferably after filtering by filtering circuits. A regulation makes it possible to adapt the durations of current flow to the consumption of the user circuits.

 Compared to the switching power supplies known from the prior art, an improved switching power supply according to the invention, to adapt it in particular to the power supply of a VFD, has advantageous characteristics which, compared to the prior art, have will be specified below.

 In known manner, the secondary windings are connected to rectifiers making it possible to obtain a rectified current which after filtering, supplies a stabilized voltage at a desired value. It may happen that in such a supply, one of the secondary windings has a midpoint connected to ground so that the voltages at each end of this secondary winding are in phase opposition.

 According to an advantageous characteristic of the invention, a midpoint of one of the secondary windings is connected to a voltage source

<Desc / Clms Page number 5>

 of fixed value, for example a battery. Thus the voltages at each end of this secondary winding are in phase opposition.

 This winding is dedicated to supplying alternating current to the heating filaments of the VFDs.

Thus the filament of the VFD is brought to the positive voltage of the voltage source of fixed value, which ensures its polarization to a positive value, and moreover the ends of this filament receive alternating voltages in phase opposition, which ensures a heating current in the filament.

 Thus, the invention relates to a switching power supply comprising: - terminals for connection to a DC voltage source, - a transformer having a magnetic circuit coupling a primary winding and secondary windings of said transformer, - a regulation circuit and switch regulating current passage times from said DC voltage source in the primary winding of the transformer, characterized in that a first secondary winding of the transformer has a central point coupled to a terminal of the power source in direct current and outputs delivering voltages in phase oppositions.

 The coupling can be direct or via, for example, a voltage divider bridge making it possible to adapt the value of the bias voltage of a heating filament supplied by said secondary winding.

<Desc / Clms Page number 6>

According to another advantageous characteristic, the DC voltage source has an output voltage of fixed value whose value is equal to the bias voltage of the heating filaments of the VFDs. Thus, by connecting the midpoint of the secondary winding dedicated to the alternating current supply of the heating filaments of the VFDs to said source, a particularly simple supply of said filament of each VFD is obtained.

In an automobile use where the DC voltage source which will be connected to the switching power supply is the battery fitted to the automobile, the voltage of this battery also constitutes the voltage of fixed value whose value is equal to the bias voltage . Thus, for example, if the battery is a 12-volt battery, a terminal of the battery at the positive voltage of 12 volts will be connected to the midpoint of the secondary winding dedicated to the supply of alternating current to the heating filaments of the VFD. Thus no additional circuit is necessary to produce the bias voltage of the heating filaments of the VFDs. Naturally, the value of the anode and gate voltages of the VFD, delivered by other secondary windings of the power supply will have to be adapted to this value of bias voltage to produce an electric field sufficient for the acceleration of the electrons.

Thus, the invention also relates to a supply circuit for a fluorescent vacuum display means (VFD), said display means comprising a heating filament having two

<Desc / Clms Page number 7>

extrémités, une grille et une anode, caractérisé en ce qu'il comporte une alimentation selon l'invention, l'enroulement secondaire du transformateur dont le point milieu est couplé à la source de courant continu ayant des sorties délivrant des tensions en opposition de phase connectées l'une, à une extrémité du filament de chauffage et l'autre à l'autre extrémité dudit filament de chauffage.

ends, a grid and an anode, characterized in that it comprises a supply according to the invention, the secondary winding of the transformer whose midpoint is coupled to the DC source having outputs delivering voltages in phase opposition connected one at one end of the heating filament and the other at the other end of said heating filament.

Brief description of the drawings An exemplary embodiment of the invention will now be commented on in conjunction with the appended FIG. 1 which represents a diagram of an electrical supply in accordance with the invention, this supply being connected to a VFD.

Description of a particular embodiment An exemplary embodiment of the invention will now be described in connection with FIG. 1.

Since switching power supplies are known per se, only a few advantageous characteristics of the power shown will be discussed.

The switching power supply, comprising the advantageous characteristics according to the invention, comprises a connection 2 for connection to a first terminal of a car battery not shown, and a connection 4 for connection of the power supply to a second terminal for that same battery. Preferably the terminals 2 and 4 of the battery are connected, as shown in FIG. 1, to the power supply via a regulation circuit 40 having

<Desc / Clms Page number 8>

 2 ', 4' output terminals. In the following description, the references 2,4 may also symbolize the terminals 2 ′ and 4 ′ of a power supply equipped with a circuit 40 for regulating the battery voltage. The positive terminal for example 4 is connected in series with a primary winding 6 of a transformer 8. The transformer 8 comprises, in addition to the primary winding 6, secondary windings 10, 12, 14 coupled to the primary winding 6, at through a saturable magnetic circuit 16 represented schematically in a conventional manner, by a line.

The primary winding 6 is connected in series with a regulation and switching circuit 18 comprising switching means 5. The regulation and switching circuit 18 receives, through a divider bridge 22, a voltage value representative of the value of one of the regulated voltages delivered from one, 14, of the secondary windings. The divider bridge 22 is connected to the winding 14 on an outlet 24 of the said winding. Other elements of this supply in itself known are shown for a better understanding of the invention but not commented on or referenced.

 The operation of this supply of known principle has been recalled above. The voltage value received across the divider bridge 22 is compared in circuit 18 to a reference voltage.

The difference between this voltage value and the reference voltage is used in circuit 18 to modulate in width the current pulses created in the primary circuit by opening and closing of the primary circuit by the switching means 5.

<Desc / Clms Page number 9>

 According to an advantageous characteristic of the invention, one, 12, of the secondary windings has a midpoint 7 connected to the positive terminal 4 of the battery by a conductive link 11. Outputs 13, 15 in phase opposition of said secondary winding 12 are each connected respectively to one end of a heating filament 17 of a VFD 19. Said heating filament 17 is thus biased at the voltage delivered by the battery and is traversed by an alternating current created by current pulses since the voltages at the outputs 13.15 of the winding 12 and therefore of the filament 17 are in phase opposition. Another secondary winding, winding 10, delivers the voltage required to supply the grids 23, and anodes 25, of the VFDs 19. The effective application of this voltage to the anode and to the grid of a particular segment is effected by switching means 21, known in themselves, controlled by a microcontroller not shown.

 In FIG. 1, only one VFD1 circuit 19 has been shown. In general, there is a plurality of VFDs on a vehicle, each receiving the bias voltage of the filament 17 and the heating current, and through the switching means 21 the gate and anode voltages. Each of the VFDs is connected to the power supply in the same way as the VFDs 19. This possibility of a plurality of VFDs is expressed in FIG. 1 by arrows at the output of the switching means 21.

 According to another advantageous characteristic of the invention intended to reduce consumption during standby periods, a voltage regulator 28 is

<Desc / Clms Page number 10>

 supplied on an input 39, by two voltage sources. The input 39 of the voltage regulator 28 is connected on the one hand to an output 36 of the secondary winding 14 and on the other hand, by a link 35 comprising a switch 33 to the positive terminal 4 of the battery. A circuit 34 for controlling the switch 33 has a first input 45 receiving a control signal from a microcontroller not shown, and a second input 37 connected to the terminal 4 of the battery. An output 31 of the circuit 34 is connected to an input for controlling the switch 33. The voltage regulator 28 has an output 41 connected by a link 42 to circuits not shown, supplied in the standby state and by a link 43 to circuits not shown which are not supplied in the standby state. A switch 32 having a control input 44 is intended to cut the supply of said non-supplied circuits.

 The operation is described below. In the standby state, the regulator 28, delivering for example a regulated voltage of 5 volts, supplies a microcontroller not shown. The microcontroller has a part of its circuits which are not powered. Only circuits are supplied making it possible, for example, to maintain clock information for an on-board watch, circuits for detecting the end of the standby state or even for detecting an alarm, for example theft. The functions and circuits not supplied with the standby state are cut by the opening of the switch 32 receiving for this purpose a command on its control input 44. During the standby state the switching power supply is not not activated. The

<Desc / Clms Page number 11>

 regulator 28 is supplied in this standby state directly by the battery, and the input 39 is connected for this purpose, to terminal 4 via the link 35, the switch 33 of which is controlled in the on state by the circuit 34 for controlling said switch 33.

 When going from standby to normal operating state, the power supply and all circuits are activated. The switch 32 at the output of the regulator 28 is controlled in the on state. Under these conditions the power delivered by the regulator 28 increases considerably. In order to reduce the dissipation in this regulator 28, the latter is supplied on its input 39 by a connection 36 to the secondary winding 14. This winding delivers a voltage different from the voltage of the battery.

This voltage is better suited to the delivery by the regulator 28 of the average power necessary under these operating conditions.

 When the voltage delivered by the battery drops below a threshold value, this drop is detected by the control circuit 34 of the switch 33 which receives this voltage value on its input 37. The control circuit 34 then controls l 'switch 33 in the on state. In addition, the power is cut in this case. The supply from the battery is superimposed for a transitional period on the supply from the winding 14 and then replaces this latter supply.

 Thus, according to this embodiment, the power supply includes a production regulator 28

<Desc / Clms Page number 12>

 of a regulated DC voltage, supplied during the standby periods by the DC voltage source and during the operating periods by a secondary winding of the power supply. To this end, the regulator (28) for producing a regulated DC voltage has an input terminal 39 coupled by a link 35 comprising a switch 33 to a terminal 4 of the DC power source and by a connection 36. to one of the secondary windings of the transformer 8.

 In the example here commented on, the battery delivers a voltage of 12 volts and the connection 36 to the winding 14 delivers a voltage of 7 volts. The regulator 28 is designed to deliver a voltage of 5 volts. Thus in this example the voltage delivered by the winding 14 is a voltage of value lower than the voltage delivered by the DC power source but higher than the voltage value delivered by the regulator 28.

Claims (8)

1. Switching power supply comprising: terminals (2,4) for connection to a DC voltage source, - a transformer (8) having a magnetic circuit (16) coupling a primary winding (6) and secondary windings (10, 12, 14) of said transformer (8), - a regulation and switching circuit (18) regulating times of current flow from said source of direct voltage in the primary winding (6) of the transformer (8), characterized in that a first secondary winding (12) of the transformer (8) has a central point (7) connected to a terminal (4) of the DC voltage source and of the outputs (13,15) delivering opposing voltages phase.  2. Switching power supply according to claim 1 characterized in that it comprises a regulator (28) for producing a regulated direct voltage having an input terminal (39) coupled to an output (36) of one ( 14) secondary windings of the transformer (8), and by a link (35) comprising a first switch (33) to a terminal (4) of the DC voltage source.  3. Switching power supply according to claim 2 characterized in that the first switch (33) has a control input (31) <Desc / Clms Page number 14>  connected to a control circuit (34) of said switch (33), said control circuit (34) having an input (37) connected to a terminal (4) of the DC power source.  4. Switching power supply according to claim 3 characterized in that a voltage value delivered from the output (36) of said one (14) of the secondary windings of the transformer (8), has an intermediate value between a voltage value delivered by the DC voltage source and a voltage value supplied by said regulator (28).  5. Switching power supply according to one of claims 1 to 4 characterized in that the DC voltage source is an automobile battery.  6. Supply circuit of a fluorescent vacuum display (VFD) means (19), said display means (19) comprising a heating filament (17) having two ends, a grid (23) and an anode. (25), characterized in that it comprises a supply according to one of claims 1 to 5, the first secondary winding (12) of the transformer (8) having one of said outputs (13,15) in phase opposition connected to one end of the heating filament (17) and the other of said out of phase outputs (13,15) connected to the other end of said heating filament (17).  7. Supply circuit of a fluorescent vacuum display (VFD) means (19) according to the <Desc / CRUD Page number 15>  claim 6 characterized in that the grid (23) and the anode (25) of said display means (19) are coupled to a second secondary winding (10) of said transformer (8).  8. Use of a switching power supply according to one of claims 1 to 5 for the supply of a means (19) of fluorescent vacuum display (VFD), said means (19) of display comprising a filament (17) heating having two ends, a grid (23) and an anode (25), the first secondary winding (12) of the transformer (8) having one of said outputs (13,15) in phase opposition connected to one end of the heating filament (17) and the other of said phase opposition outputs (13,15) connected to the other end of said heating filament (17).