FR2568742A1 - Adjustable inductance, in a printed circuit, and filter including such an inductance - Google Patents

Abstract

The present invention relates to the field of adjustable inductances. The inductance is constituted by a single-sided or double-sided printed circuit including a conductor 3 deposited on the substrate 1 and wound flat in order to form turns 7, 8, 9, and terminals 11-26 which are intended to enable certain length portions of the turns to be short circuited by jumpers. Application to meter-wave (VHF) and decimetric-wave (UHF) filters.

Description

Adjustable inductance, in printed circuit and
filter comprising such an inductance.

 The present invention relates to an adjustable inductance, usable, more particularly, in VHF (30-300 MHz) and in the part of UHF ranging from 300 MHz to approximately 500 MHz.

 It is known, to obtain an inductance of optimal value, to use a wound inductance, adjustable either by slider or by plunger core; such inductors have a high cost price and require that a measurement be made to bring them to the desired value. It is also known, in order to obtain a very precise and non-standardized inductance value, to specially manufacture the inductor for this purpose; for small or medium series the cost per inductor is then very high.

 The present invention aims to avoid or, at least, reduce the aforementioned drawbacks. For this, the invention aims to eliminate the winding operations while ensuring very good reproducibility of the inductor in order to avoid any development of the inductor during, for example, the mass production of a filter whose inductances will have been determined with precision during preliminary studies.

 This is mainly obtained by the combination of flat-wound turns, predetermined short-circuit points and an embodiment in printed circuits.

 According to the invention an adjustable inductor, is characterized in that it is constituted by a printed circuit on one of the faces of which are deposited: a conductor forming n turns (n: number greater than 0) planar, concentric, successive and m terminals (m whole at least equal to 2) in electrical contact with m distinct points of the conductor, these m terminals being intended to receive the ends of short-circuits in order to reduce the value of Minductance.

 The present invention will be better understood and other characteristics will appear with the aid of the description below and of Figures I and 2 relating to it - which represent two views of the same inductor according to the invention.

 Figures 1 and 2 show the two sides A and B of a double-sided printed circuit. This circuit is composed of a substrate 1, two conductors 2, 3 and two accesses E, S and sixteen terminals -11-26, associated with the conductors.

 The substrate 1 has a thickness of 1.6 mm, a width of about 21 mm and a length of about 23 mm.

 The conductor 2 forms a flat winding, deposited on the side A of the substrate 1 (FIG. 1); it comprises three concentric, successive and substantially rectangular turns 4, 5, 6. Seen from its outer end at the three turns, the conductor 2 rotates clockwise and is associated with an access, E, and four terminals, 23, 24, 21, 22 in contact respectively with the outer end of the conductor 2, with a point located at the start of the first turn, 4, i.e. at the start of the outer turn, with a point located at the connection between the first turn, 4, and the second, 5, with a point located at the start of the third turn, 6, and with a point located at the end of the third turn, i.e. inner end of the conductor 2. This access and these four terminals each consist of a first conductive plate deposited on the side A and in contact with the conductor 2, by a second conductive plate deposited on the side B (FIG. 2) at l plumb with those of side A and by the walls of a metallized hole which crosses the substrate and opens through the two plates of the access or the terminal.

In the same way the conductor 3 forms a flat winding, deposited on the side B of the substrate 1 (FIG. 2); it comprises three concentric, successive and substantially rectangular turns 7, 8, 9. Seen from above the face B and from its inner end at the three turns, the conductor 3 rotates anticlockwise and is associated with thirteen terminals, 22, 19, 17, 15, 13, 11, 12, 14, 16, 18, 20, 25, 26, and an access, S. These thirteen terminals and this access are in contact with fourteen distinct points of driver 3:
- terminal 22 with the end of the conductor 3 inside the turns,
- terminals 19, 17, 15, 13, Il, 12, 14, 16, 18, 20 with points distributed regularly along the long sides of the rectangle formed by the first turn, 7, that is to say the internal turn of side B,
- terminal 25 with a point located at the connection between turns 8 and 9,
- terminal 26 with a point located at the end of the third turn, 9, that is to say at the end of the largest turn,
- and access S with a point located at the end of the conductor 3 outside the turns 7, 8 and 9.

 These thirteen terminals and this access each consist of a first conductive plate deposited on the side B and in contact with the conductor 3, by a second conductive plate deposited on the side A (FIG. 1) directly above that of the face. B and by the metallized walls of a hole which crosses the substrate and opens out through the two plates of the terminal or of the access.

 Among the terminals 11 to 26 which have been described above, the terminal 22 plays a particular role since it electrically connects the end of the conductor 2 located inside the turns 4, 5, 6 to the end of the conductor 3 located inside the turns 7, 8, 9 and therefore puts the conductors 2 and 3 in series. The terminals all constitute, even the terminal 22 of the intermediate terminals between the accesses E and S of the inductance; they are intended to receive two by two the ends of conductive jumpers.

These jumpers, one of which, 10, is shown in FIG. 1, laid flat on side A of the printed circuit, are formed of wires of 0.5 mm in diameter bent in a U and all of the same size (width 2.5 mm and height 2 mm). These jumpers, which are soldered in the terminals, make it possible to adjust the value of the inductance by eliminating, by short-circuit, part of the turns of the conductors 2 and 3; it is thus possible to eliminate
- fractions of the internal whorl, 7, of side B: terminals 11 to 20,
- the internal turn, 6, of side A: terminals 21 and 22,
- the external turn, 4, of face A: terminals 23 and 24,
- the external turn, 9, of face B: terminals 25 and 26.

 By using four jumpers, all of the same size, it is thus possible to obtain sixty-one inductance values from the maximum value without jumper which is 420 nH to the minimum value of 30 nH which is obtained by placing the jumpers respectively between the intermediate terminals 19-20, 21-22, 23-24 and 25-26.

 It should be noted that, provided that jumpers of different widths are used, it is possible to also make other short circuits, for example between the intermediate terminals 22 and 25.

 The present invention is not limited to the example described, thus the number of turns per side can be different from three, may not be an integer and, even, the printed circuit may not include turns only on one of its faces; the latter case could be represented by the drawing in FIG. 2 without the terminals 23 and 24, the access E then being able to be replaced by the terminal 22 or else the access E being able to be joined together, by a conductive deposit on the face A , at terminal 22.

 Similarly, the number of bounds can be any whole number greater than 1, at least within the limit of reasonableness. As for the accesses (E and S in Figures 1 and 2) they can be used on one side for connecting the inductor and on the other side as terminals for lamia in place of a jumper.

 It should also be noted that, with a double-sided printed circuit with two conductors, it may be advantageous, in certain cases, not to have a permanent serial link between the conductors of the two faces as is the case with terminal 22 example described; the connection of the two conductors can then be made, for each conductor, not at the end of the conductor but at an intermediate point.

 The invention also relates to the use of the inductors which have been discussed above in passive or active filters in order to reduce the cost price and to avoid the problems of adjusting inductors in mass production.

Claims (6)

 1. Adjustable inductance, characterized in that it is constituted by a printed circuit on one of the faces (B) from which are deposited: a conductor (3) forming n turns (7, 8, 9) (n: higher number at 0) planes, concentric, successive and m terminals (11-20, 22, 25, 26) (m integer at least equal to 2) in electrical contact with m distinct points of the conductor, these m terminals being intended to receive ends short circuits (10) in order to reduce the value of the inductance.  2. Inductor according to claim 1, characterized in that the printed circuit is a double-sided circuit (A, B), on the other face (A) of which is deposited a conductor (2) forming n 'turns (4.5 , 6) (n ': number greater than 0) flat, concentric, successive and in that it comprises at least one connection means (22) to allow an electrical connection between the conductors of each of the faces (2, 3) .  3. Inductor according to claim 2, characterized in that the connecting means is a metallized hole (22) forming a short circuit between one of the ends of the conductor (2) forming n turns and one of the ends of the conductor ( 3) forming n turns.  4. Inductor according to claim 2, characterized in that, on the other face (A) are deposited m 'terminals (21-24) (m' integer at least equal to 1) in electrical contact with m 'points distinct from the conductor forming n 'turns, these m' terminals being intended to receive the ends of short-circuits (10) in order to reduce the value of the inductance.  5. Inductor according to claim 4, characterized in that at least part of the m + m 'terminals (11-26) comprise two conductive plates deposited respectively on the two faces (A, B) and connected by the walls of a metallic hole.  6. Filter for VHF and / or decimetric waves, characterized in that it comprises at least one inductor according to any one of the preceding claims.