FR2514190A1 - PRINTED TAPE INDUCTOR AND TRANSMITTER COMPRISING SUCH AN INDUCTANCE - Google Patents

Abstract

THE PROPELLER-SHAPED CONDUCTOR 2 CONSTITUTING THE INDUCTANCE IS A PRINTED TAPE OBTAINED BY THE USE OF PRINTED CIRCUIT TECHNIQUES. THE INDUCTANCE IS MADE ADJUSTABLE BY A SLIDING RING 5 INCLUDING MULTICONTACT CROWNS 6, 7. THIS RING IS DRAWED IN A BALANCED MANNER ALONG THE INDUCTANCE SO AS TO OBTAIN ITS QUICK POSITIONING. APPLICATION ESPECIALLY IN MEDIUM POWER TRANSMITTERS.

Description

2 5 1 4 1 9 0

  INDUCTOR WITH PRINTED RIBBON AND TRANSMITTER

COMPRISING SUCH AN INDUCTANCE

  The invention relates to an inductor mainly used in

  circuits tuned to medium power transmitters.

  Such inductances are usually made by winding a conductor in a helix defined by its pitch and its number of turns traced on a generator cylinder. In the case of a variable inductance, this variation can be ensured by jumps, by switching outlets arranged on along the helix which makes it possible to change the number of turns contributing to the value of the inductance When the transmitter has a remote control or an automatic tuning system a continuous variation of the value of the inductance is necessary In this case case, this variation is obtained by the displacement of the point of support of a cursor on the driver by a screwing movement around the axis of the helix The cursor is usually placed inside the helix It is in mechanical and electrical connection with a rotary conductor arranged along the axis of the propeller, on which it can move longitudinally A motor ensures the rotation of the axial conductor c e which causes the variation

desired inductance.

  Such devices have electrical drawbacks such as the series presence of three contacts by friction, one on the slider in contact with the helical conductor, a second allowing sliding on the rotating axial conductor, a third to ensure the connection of this axial conductor with the fixed elements of the circuits associated with the device On the other hand, the unused turns of the helix, have a "dead end" effect likely to create resonances

parasites.

  On the mechanical level, a variation between the extreme values of the inductance, imposes on the cursor the course of the developed length of the helical conductor The speed of the positioning of the cursor on this course is limited by considerations such as the inertia of the masses rotating set and wear due to the high speed slider sliding on the driver and the pressure required to get

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  a minimum contact resistance between the slider and the driver.

  These drawbacks usually find their solution through the use of

  the use of powerful servo devices, thus dissipating

  of energy, associated with expensive mechanical achievements.

  The inductor according to the present invention, by its technological design, makes it possible to remedy these drawbacks while having a

cost price decreased.

  According to the invention, an inductor comprising a conductor

  a cylindrical helix, is characterized in that this conductor is

  consisting of a ribbon printed on the surface of an insulating cylinder.

  The invention will be better understood and other characteristics

  will be described using the following description of an embodiment of

  the invention and related figures: FIGS. 1, 2, 3, 4, 5 illustrate the manufacturing steps of

the inductor according to the invention.

  Figure 6 shows the essential elements of the completed inductance. The printed circuit techniques usually used in industry, make it possible to have insulating supports presented in the form of plates of various thicknesses, rigid or flexible, metallized copper over the entire surface of one of their faces (single-sided circuit) or both sides (double-sided circuit) The desired circuit is obtained by chemical etching of the copper on the parts of surfaces left free after printing by screen printing, using a protective ink, the

desired drawing.

  Such means can be used to carry out the construction of a helical conductor on a cylindrical surface. FIG. 1 shows a printed flexible support surface 1 on which strips

  2 inclined copper are obtained by the method indicated above.

  The winding of this support on an insulating cylinder 3, shown in FIG. 2, superimposes the lines A and B of FIG. 1, which reconstitutes the continuity of the helical conductor. This continuity is physically produced in a C-band which extends the width. the support beyond line A and which constitutes a recovery zone after winding

  of the support on the insulating cylinder 3.

  FIG. 3 represents, in section, the elements which ensure, in this area of overlap, the electrical continuity at the level of a copper strip 2 of the printed support and the mechanical fixing of this flexible support on the insulating cylinder 3 The flexible support 1 used is a double-sided circuit The coppered parts of the first face form the turns 2 of the inductor The coppered part of the second face is limited to the surfaces facing the coppered parts of the first face at the level of the cover strip C , to form weld fixing zones with the corresponding copper parts of the first face, in order to ensure the mechanical strength and to facilitate the

  wetting, by welding, rivets 4 ensuring electrical continuity.

  This process results in the construction of a valuable inductance

  fixed and usable as is This inductance, according to one of the characteristics

  This slider is made adjustable by the introduction of a slider according to Figure 4 This slider is constituted by a copper ring diameter slightly greater than that of the printed cylinder; At each end of this ring is fixed a ring, 6 and 7, composed of about fifty elastic contacts pressing the cylinder along a circumference in a plane perpendicular to the axis of the cylinder These crowns are made of bronze beryllium from a strip 8 in FIG. 5 cut in the form of a comb with large teeth 9 These teeth are then preformed so that each forms one of the contacts of a crown, which consists of a strip length secured by rivets by its unformed portion at one end

  of the slider ring, over the entire length of its inner circumference.

  One of these rings 6 ensures the connection between the slider ring and the printed turns, by a number of contacts in parallel, all the higher as the width of the printed part is large and the space between

  turns is narrow The ring is dimensioned in length so, short

  circuit, through the two crowns mounted at its ends.

  the unused turns, whatever their position, between those

  giving the maximum and minimum values of the inductance.

  Another characteristic of the construction of the inductor from printed circuits according to the invention allows the implementation

  a further improvement in the case of an inductance va-

  The width and pitch of the helical conductor can vary along the cylinder. The conductive strips 2 of FIG.

example of this Improvement.

  The increase in the width of the conductive strip in the region which remains alone used at low values of inductance makes it possible to improve the overvoltage of the inductance for these low values. On the other hand the increased copper surface in this region, allows an improved evacuation of the calories due to the high frequency losses of the device, these losses being concentrated on the only turns remaining

  used for low inductance values.

  The variation of the pitch of the helix formed by the conductive ribbon also makes it possible to improve the device by choosing a law of optimized variation of the inductance as a function of the displacement of the

  ring along the printed cylinder.

  The electrical connection between the slider ring and the fixed elements of the circuits associated with the inductor is provided by a wiper 10 in FIG. 4, integral with the ring, which establishes a permanent contact with a

  silver-plated brass rail 11 arranged parallel to the axis of the insulating cylinder.

  FIG. 6 shows the inductance terminated with the drive means of the slider ring. For the convenience of reading the drawing, only the elements necessary for understanding the invention are shown. The printed medium 1 is shown in FIG. propeller 2, the slider ring 5 and its contact rings 6 and 7 The positions of the

  -cursor 10 and rail It is recalled in the middle of the ring.

  Sliding of the slider ring along the cylinder carrying the printed inductance is ensured by two threaded rods 12, 13 arranged

  parallel and symmetrically with respect to the axis of the printed cylinder.

  These rods have a thread constituted by a groove of square section whose pitch is determined according to the friction and the desired speed of the displacement of the ring These rods act by screwing in a balanced manner on two nuts 14-15 made integral with the ring using insulating spacers 16, 17 The rotation of the rods is provided by gears 18, 19 integral with these rods and placed in a plane perpendicular to the axis of the cylinder printed at the end thereof These gears are themselves driven in a synchronous way by a

  intermediate gear 20 itself driven by a servo motor

  not shown -on the figure The symmetrical action of the system

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  of the ring allows precise positioning of the ring

  during the inductance value changes by maintaining the codenumber

  This prevents any jamming effect and excessive crushing of the crown contacts, which could result from an asymmetrical drive of the ring. The variable inductance just described is particularly

  applicable to the tuners circuits of transmitters In one embodiment of

  for the girl from 1.5 to 30 M Hz, a maximum value of 11 micro henry is obtained with 22 turns imnprineated on a cylinder diameter of

  70 mmin and 280 mm in length The admissible current is 10 am-

  The power dissipated is approximately 15 watts. The printed circuit used to obtain these performances has a copper thickness greater than 200 watts.

microns.

  The mechanical drive described, allows a positioning time-

less than 1.5 seconds.

  The invention is not limited to the embodiment specifically described and realized. In particular the various techniques of printed circuits can provide alternative embodiments. The use, for example, of metallized holes can eliminate the use of rivets on the zone. cover C of Figure 3 The support cylinder can in another

  variant to be made of insulating material treated to receive, direct-

  metallization of copper, the inductance design according to the known screen printing method, this avoiding the winding operation

previously described.

  The electrical connection of the slider ring to the fixed elements of the associated circuits via the wiper 10 and the rail It may be replaced in another embodiment by a semi-rigid connection such as a copper strip, which eliminates a contact by

  if the mechanical and electrical stabilities are considered sufficient

  The realization then has only one contact by friction in

series with inductance.

Claims (8)

  Inductance comprising a conductor forming a cylindrical helix, characterized in that this conductor is constituted by a   printed tape (2) on the surface of an insulating cylinder.   2 inductor according to claim 1, characterized in that it comprises a printed circuit on a flexible support (1) wrapped around an insulating cylinder (3), a covering area (C) ensuring the mechanical strength and electrical continuity of the circuit board that reconstitutes thus the ribbon printed in a helix.   3 inductor according to claim 1, characterized in that it comprises an insulating cylinder on which the conductive strip is directly imprinted.   Inductance according to one of Claims 2 or 3, characterized   in that it is variable by sliding, along the axis 17 of the insulating cylinder of a slider (5) comprising at least one ring of contacts (6) mounted on a conductive ring (5) of slightly diameter greater than that of the cylinder.   Inductor according to claim 4, characterized in that the ring is equipped with a ring at each of its ends and is of such length as to constitute, with the rings, a short-circuit for the unused turns of the spiral ribbon, whatever the position of the ring. Inductor according to Claim 5, characterized in that the helical ribbon is of variable width along the cylinder, the turns constituting the inductance set close to its minimum value being greater width.   Inductance according to one of Claims 5 or 6, characterized   in that the helical ribbon has a variable pitch along the cylinder.   Inductor according to Claim 7, characterized in that   comprises means for balanced drive of the com-   carrying two threaded rods - (12, 13) positioned parallel and symmetrically   only with respect to the axis of the cylinder on which are engaged two nuts (1-4, 15) integral with the: slider ring (5), these two rods, free in rotation, being integral with two gears (1 S, 19 ) mounted in a plane   perpendicular to the axis of the cylinder at the end thereof, these meshes 2514 1 90   being coupled together by a third intermediate gear itself.   even coupled to a servo motor.   9 Transmitter, characterized in that it comprises at least one   inductor according to one of the preceding claims.