ITTO950383A1 - IGNITION CIRCUIT FOR IGNITING DEVICES. - Google Patents

Abstract

Trigger circuit (21) for ignitor devices, comprising a capacitive transformer (1) formed as a single component including a first and a second sheet of conductive material (15, 16) wrapped around a magnetic core (13) and magnetically coupled to a secondary winding (14) so as to form a primary winding (3) and a secondary winding (4) of the transformer (20) and a capacitor (5) in series with the primary winding. The capacitor is connected to a controlled voltage generator (8, 6) so as to initially allow the charging of the capacitor (5) and then the discharge of the capacitor (5) itself and the induction of a high voltage in the secondary (4 ) for the ignition of an igniter (7) connected to the secondary itself Figures 1, 2 and 5

Description

DESCRIPTION

The present invention relates to an ignition circuit, for example spark plugs or igniters of internal combustion engines.

As is known, current ignition circuits of the indicated type comprise a transformer in series to the primary of which a capacitor is connected and in parallel to the secondary of which a spark plug of an internal combustion engine or an igniter of a turbine engine is connected. The circuit also includes a switched voltage generator which initially allows the medium voltage capacitor to be charged and is subsequently short-circuited to allow the capacitor to discharge through the transformer primary. On the primary there is therefore a very rapid increase in voltage which induces a corresponding increase in voltage on the secondary, such as to cause a discharge in the spark plug or igniter.

The circuit described above has the disadvantage that its components are made by means of discrete elements, so that it has a considerable size and is affected by losses which limit its efficiency.

The object of the present invention is to improve an ignition circuit of the type indicated so as to reduce its overall dimensions and improve its efficiency.

According to the present invention, an ignition circuit is provided for igniter devices, comprising at least a first and a second inductive element magnetically coupled to each other and to a magnetic core, and a capacitive element connected to said first inductive element, said second inductive element being connected to an igniter device, characterized in that it comprises a capacitive transformer including at least a first and a second sheet of conductive material wound around said magnetic core and magnetically coupled to a secondary winding so as to form said first and second inductive elements and said capacitive element.

The invention will now be described with reference to the attached drawings, which illustrate non-limiting examples of embodiment, in which:

Figure 1 presents a top view of a capacitive transformer used in the present ignition circuit;

figure 2 shows an interrupted side perspective view of the capacitive transformer of fig. 1;

figure 3 presents a first simplified electric diagram with four terminals of the transformer of fig. 1;

figure 4 presents a second simplified electric diagram with six terminals of the transformer of figs. 1 and 2;

figure 5 shows a first embodiment of the priming circuit according to the invention, incorporating the transformer of figs. 1 and 2, as per the wiring diagram of fig. 3;

figure 6 illustrates a first variant of the ignition circuit according to the invention, using the capacitive transformer as per the electrical diagram of fig. 3; And

figure 7 shows another variant of the present ignition circuit, use the capacitive transformer as per the electrical diagram of fig. 5.

According to an aspect of the present invention, the present trigger circuit comprises a capacitive transformer made by means of a single component 1 having capacitive-inductive characteristics (capacitive transformer). The capacitive transformer 1, shown in Figures 1 and 2, comprises a core 13 of ferromagnetic material around which a conductor wire 14 constituting the secondary of the transformer is wound. Two conductive foils or sheets 15, 16, typically of metal, are spirally wound around the secondary 14, forming a pair of plates mutually separated by a dielectric 17. The plates 15 and 16 have end sides (corresponding to the ends of the two visible spirals in the top view of Fig. 1) defining terminals A, C and, respectively, D, B, while the ends of the conductor wire 14 (secondary) are indicated with L and H.

The capacitive transformer 1, which constitutes a variant of a capacitive-inductive element object of a copending patent application filed on the same date and entitled "Inductive capacitive element", in case terminals C and D are not used, has an equivalent circuit simplified 20 with four terminals shown in fig. 3. The equivalent circuit 20 comprises an ideal transformer 2, formed by a primary 3 and a secondary 4, and a capacitor 5 arranged in series with the primary 3, interposed between this and terminal A. The primary 3 also defines terminal B , while the secondary defines the terminals L, H; in which the terminals A, B, H, L correspond to the homonyms of fig. 1. The node between capacitor! 5 and primary 3 corresponds to terminal D, shown here, but not used.

The armatures 15, 16 can be mutually insulated from any dielectric material suitable for the purpose. Furthermore, instead of two single plates, for each weave there can be provided several plates or sheets connected to comb and interdigital, or arranged in such a way that between two adjacent plates of a framework a plate of the other reinforcement is interposed, as described in more detail. in the aforementioned co-pending patent application.

In practice, the capacitive transformer 1 according to figs. 1 and 2, also has a primary integrating the capacitor 5, thus allowing to obtain a very compact device, a reduction in manufacturing costs and a greater efficiency of the component.

Considering also the terminals C and D of the capacitive-transformer 1, it is possible to schematize the transformer 1 itself as shown in fig. 4 through the circuit 22. In detail, the circuit 22 of fig. 4 has six terminals A-D, H # L, similar to the corresponding terminals of fig. 1; between terminals A and c: an inductor 23 is arranged; a capacitor 24 is arranged between terminals A and D; a capacitor 25 is arranged between terminals C and B; an inductor 26 constituting the primary of the transformer is arranged between terminals D and B and between terminals H and L there is an inductor 27 magnetically coupled to the inductor 23 and to the inductor 26 and thus forming the secondary of the transformer.

According to the invention, the capacitive transformer 1 is used in an ignition circuit for igniter devices, an embodiment of which is shown by way of example in fig. 5. The priming circuit 30 of FIG. 5 comprises a direct voltage generator 8 connected to the terminals A and B of the capacitive transformer 1, in parallel with a switch 6. The equivalent circuit 20 of fig. 3 comprising the primary 3 and the secondary 4 and the capacitor 5. In parallel with the secondary 4 of the capacitive transformer 1 a spark plug 7 or other igniter device is connected.

The operation of the circuit 30 is as follows. Initially, the switch 6 is open and the voltage generator 8 charges the capacitor 5 to an average voltage (typically 100-600 V). When the switch 6 is closed, the capacitor 5 discharges through the primary 3 of the transformer 2, inducing a potential difference on the secondary 4 such as to cause the discharge in the spark plug (or igniter) 7.

In fig. 6 shows an application based on the principle of supplying, through the discharge of a capacitor on the primary 26 of the transformer, the energy necessary for the start of the discharge in the spark plug and, through the opening extravoltage of an inductive circuit coupled to the secondary , the energy for maintaining the discharge itself over time.

The circuit 34 of fig. 6 comprises the capacitive transformer 1 between the terminals H and L of which the spark plug 7 is arranged. A direct voltage generator 35 is connected to terminals A and B, in parallel with a switch 36; between terminals D and B there is a branch 37 comprising the series connection of a resistor 38, a switch 39 and a direct voltage generator 40.

The circuit 34 of fig. 6 operates as follows. Initially the switch 36 is open and the switch 39 is closed. When the circuit is switched on, the capacitor 5 is charged by the voltage generator 35 to a predetermined voltage and a current i is induced in the primary 3 of the transformer, through the branch 37. When the switch 36 closes, the capacitor 5 discharges into the primary 3. Consequently, a high voltage is induced in the secondary 4 of the transformer, capable of allowing the spark plug 7 to ignite. At the end of the discharge of the capacitor 5, or shortly before, the switch 39 is opened. This opening leads to the availability of the magnetic energy induced in the core 13 of the transformer by the current i; this energy can then be used to maintain the discharge of the spark plug 7 for a certain time.

Figure 7 shows an embodiment in which the equivalent scheme 22 of fig. 4 in which, through the terminals B and D, a current is induced in the inductance 26 and, through the terminals A and B, the capacitors 24 and 25 are charged.

The circuit 45 of fig. 7 comprises the capacitive transformer 1, represented by its components 23-27; a direct voltage generator 46 V1 is connected to terminal D of the capacitive transformer 1 through a resistor 47 and a diode 48. The diode 48 is connected with the cathode to the terminal D. The circuit 45 further comprises a switch 49 disposed on a bypass line 51 which connects the terminals A and B; terminal B is also connected to ground through a switch 50. Terminal A defines a terminal for applying a voltage V2 obtained by means of a voltage generator not shown. In the circuit 45, the terminal H of the secondary 27 is connected to the terminal D and the terminal L is connected to a terminal of the spark plug 7, the other terminal of which is connected to ground.

The circuit 45 of fig. 7, described in detail in a previous patent application No. T091A000021 filed on 15.1.91 entitled '"Control system for electronic ignition in an internal combustion engine of a vehicle", operates as follows. switch 50, keeping switch 51 open. The voltage generator 46 induces a current i in the inductor 26, while the voltage V2 allows the capacitors 24 and 25 to be charged. When the switch 49 is closed, the discharge of the capacitors begins 24 and 25 in the primary 26. A high voltage is then generated on the secondary 27, which triggers the spark plug 7. At the end of the discharge of the capacitors 24, 25 or shortly before, the switch 50 is opened, causing the release of the magnetic energy accumulated in the primary 26. This release therefore allows the discharge of the spark plug 7 to be maintained.

The use of the capacitive transformer 1 in the circuit 45 therefore allows to obtain an ignition circuit having lower costs than the realization with discrete components, thanks to the use of a single component for the implementation of several elements. The described circuit also has increased effectiveness, thanks to the reduction of losses due, in the known circuit, to the wiring of the components.

Finally, it is clear that modifications and variations can be made to the trigger circuit described and illustrated here without thereby departing from the protective scope of the present invention. In particular, it is emphasized that the armatures of the capacitor or capacitors (foils 15, 16) can be made of any conductive material and be insulated from any dielectric material. The magnetic circuit can have any shape and be made of any material (even non-magnetic); with primary internal or external to the secondary. Terminal L of the secondary in circuits 30 and 34 can be connected directly to the earth of the spark plug 7 or indirectly; alternatively each of the terminals L, H of these circuits 30 and 34 can be connected to a terminal of a respective spark plug whose other terminal is connected to ground (discharge lost).

The ignition circuit can be used for the ignition of internal combustion engines of various kinds, four or two-stroke, Diesel, for automotive, motor vehicles, airplanes, etc. or as an igniter in turbine engines and the like. Furthermore, it can be used as an igniter for fuel burners (ovens, stoves, heating systems); as a trigger system for discharge lighting devices; as a driving and control circuit integrated (even partially) in the component. Finally, it is possible to combine one or more primary or secondary windings of the same foil type shown or of a conventional type to the same magnetic circuit in order to decouple the generation functions of the first ignition discharge and generation of the maintenance energy of the discharge itself. For example, it is possible to realize the circuit 34 so that the capacitive transformer 1 has three foil windings around the same core, of which the innermost winding defines the capacitive winding (first primary) connected to the direct voltage generator 35 and at the switch 36, the middle winding defines the second primary, connected to the holding branch 37 and the outermost winding defines the secondary.

Claims (11)

R I V E N D I C A Z I O N I 1. Triggering circuit (21; 34; 45) for igniting devices, comprising at least a first and a second inductive element (3, 4; 26, 27) magnetically coupled to each other and to a magnetic core (13), and an element capacitive (5; 24, 25) connected to said first inductive element, said second inductive element being connected to an igniter device (7), characterized in that it comprises a capacitive transformer (1) including at least a first and a second sheet of material conductor (15, 16) wound around said magnetic core (13) and magnetically coupled to a secondary winding (14) in such a way as to form said first and second inductive element and said capacitive element. 2. Circuit according to claim 1, characterized in that said secondary winding (14) is a wire winding. 3. circuit according to claim 1, characterized in that said secondary winding (14) is formed by a sheet of conductive material wrapped around said magnetic core (13). 4. Circuit according to any one of the preceding claims, characterized in that said sheets of conductive material (15, 16) are wound in a spiral. 5. Circuit according to any one of the preceding claims, characterized in that said two sheets of conductive material (15, 16) comprise respective first and second end sides (A-D), said first end sides of said two sheets of conductive material being mutually side by side and forming respectively a first and a second terminal (A, D), said second sides of said two sheets of conductive material being mutually side by side and forming respectively a third and a fourth terminal (C, B), and by the fact of comprising switched voltage generating means (35, 36; V2, 49) connected between said first terminal (A) and said fourth terminal (B). 6. Circuit according to claim 5, characterized in that said switched voltage generating means comprise a direct voltage generator (35) in parallel to a controlled switch (36). 7. Circuit according to claim 5 or 6, characterized in that it comprises an energy storage control branch (37) arranged between said first (A) and said fourth terminal (B). 8. Circuit according to claim 7, characterized in that said energy storage control branch (37) comprises the series connection of a direct voltage generator (40), of resistive means (38) and of a switch (39) . 9. Circuit according to claim 5 or 6, characterized in that it comprises a voltage generating element (46) connected to said first terminal (A), a bypass line (51) arranged between said first (A) and said fourth ( B) terminal, a first switch element (49) interposed along said bypass line and a second switch element (50) interposed between said fourth terminal (B) and a reference potential line. 10. Circuit according to claim 9, characterized in that said second terminal (D) is connected to a first terminal (H) of said secondary winding (14, 27), and in that said secondary winding is connected to said igniter device (7) with its own second terminal (L). 11. Triggering circuit for igniter devices, substantially as described with reference to the attached figures.