DE3046944A1 - Variable hybrid inductance coil mfr. - uses second insulating layer applied to core acting as carrier for second set of winding sections - Google Patents

Abstract

The variable hybrid inductance coil is made by screen printing conductor paths on a substrate (SU) for form initial sections (F) of the inductance winding and contact (KF1,KF2) at each end of each section (F). The latter are at least partially covered by an insulating coating applied via a further printing process, with a magnetic core adhered to this insulating layer. A carrier (Is2) acting as a second insulating layer and provided with the remaining sections (A) of the winding is adhered or applied in the form of a subsequently hardening insulating paste. The remaining sections (A) are additionally pressed down onto the substrate (SU). The coil is used for a frequency filter in a digital telephone system.

Description

Method for producing a variable inductive

hybrid coil.

Addition to P 30 39 163.0 = VPA 80 P 6189 DE The invention relates to a process, namely measures in the production of the in the main patent / main application P 30 39 163.0 = 80 P 6189 DE described, i.e. older, special electrical and magnetic hybrid coil.

The invention was used for frequency filters in connection with the so-called. CODEC of a digital telephone switching system. The invention is suitable but beyond that, it is absolutely ideal for subsequently tunable solenoids Telecommunications, especially when these solenoids are used in large numbers Mass production are to be produced.

The invention is based on a method for producing the in the older DE-PS / DE-OS / P 30'39 153.0 specified, a variable inductance having hybrid coil with - substrate, - attached to the substrate, e.g. printed and burned-in, conductor tracks, which are at least largely between each with the relevant interconnects conductively connected contact pads, so between each a first and a second contact pad, and fragments of each to represent twists - as attached to these fragments, by a first Insulating layer magnetic core isolated from the fragments, that --- its existing magnetic field lines in operation, at least partially, run in a plane parallel to the substrate surface and along one side of the magnetic core the first contact pads and along the opposite side of the magnetic core, the second contact pads lie, - through a second insulating layer sections of conductor tracks isolated from the magnetic core, which form the rest of the windings form, and - conductive connections in each case between first ends of these sections with respectively associated first contact pads and between the other second Ends of these sections with respectively assigned second contact pads, where - one or more of the fragments and / or one or more sections, in - at least during an operating phase and / or manufacturing phase after the application of the conductive Connections - in an accessible manner, each with at least one single loop having a network of lines.

The invention has essentially all the advantages of the older ones Hybrid coil; it therefore allows - the turns no longer, often very carefully placed, to have to wind up by hand, but time-saving, at least largely, to be able to apply by machine, - the high tolerances for the thickness or flatness Avoid the hand-wound windings by keeping a high level of evenness the windings are more easily secured, - the manually wound heavy magnet coils, which are connected to the substrate via only a few wires, to avoid by the magnetic core is connected to the substrate via a large number of lines, whereby the Hybrid coil is less sensitive to shock and therefore even, often without subsequent complete potting with plastic, even at high accelerations exposed systems can be used, - the magnetic core, even before the Connect the sections with the fragments, on the substrate or

to be able to attach to its fragments without connecting the To complicate winding to the conductor tracks of the substrate - what the shock insensitivity and spatial tolerance accuracy further increased - the often high difficulties when positioning and individually soldering individual wires to connect with to avoid contacts made on the substrate, although now a much higher one Number of such connections is to be made, - the tolerances of the distances of the Winding sections in the hybrid coil known from US 4103267 by individual wires are formed to improve so significantly that the previously possible short circuits between these sections can be safely avoided - regardless of the length of each To be able to choose sections of almost any size if necessary, so that also very wide Magnetic cores can be used without further ado and thus also correspondingly high inductances are achievable, instead of the maximum length of approx. 3 mm, that for bonded individual wires are permitted, see US 4 103 267, - instead of connecting the sections one after the other having to put all of the sections, at least one at each end, into a single one Work step, preferably by machine, at the same time with largely uniformly high To be able to connect quality with the assigned contact surfaces, which is particularly noteworthy saves a lot of time and money, - also cheaper material, e.g. copper compounds, for the sections instead of the individual wires, which are preferably made of gold (see also e.g. Electronics, July 20, 1928, figure on p. 107) - tearing off of the individual wires when placed on the Magnetic core and when bonding and thus to be able to avoid a corresponding amount of rejects - because of the Replacement of the bonding of individual wires, which generally requires gold, now other, often more reliable, connection types to be able to allow, which is why the invention no more ceramic as substrate, as in the hybrid coil known from US Pat. No. 4,103,267 necessary, absolutely presupposed; the invention also includes, for example, an oxide resin or hard paper as a substrate permitted, - without major difficulties regarding spatial tolerances and with regard to mutual isolation and positioning, If necessary, even several layers of turns, even with very small distances between the Sections from each other, to be able to attach and thus quickly and easily high inductances to achieve, and - to require only a small amount of space on the substrate, and above all, - a subsequent adjustment of the inductance of the hybrid coil to enable, even in small steps, even if the magnetic core is not shifted or otherwise changed, so that the hybrid coil is also suitable for use is suitable in frequency filters; so that overall because of these advantages in the result by the invention - the cost of manufacturing the hybrid coil in comparison significantly reduced compared to the hybrid coils with massive, genuinely wound magnet coils and - nevertheless, the small size, operational reliability and adjustability of the hybrid coil can be improved while maintaining close spatial tolerances.

The invention also has the task or the additional Advantage, - especially the effort for mass production to keep low, namely - the hybrid coil largely, at least with essential Manufacturing process steps, produce by printing, e.g. in the screen printing process to be able to.

The invention allows these advantages to be achieved by means of two different variants of measures that can be used alone or in combination with one another can by, roughly speaking, - firstly, the sections on which the magnetic core, respectively.

the magnetic core leg, covering carrier, e.g. by means of screen printing, are printed, and / or - secondly, the magnetic core itself or the magnetic core leg is printed on itself, e.g. by means of screen printing.

To put it more precisely, the invention allows its advantages to achieve thereby, see. The characterizing part of claim 1 that according to the first variant in successive steps conductor track - on a substrate, e.g. by screen printing Vpaste and baking the same, the fragments and the with them connected contact pads are formed - at least partially the Fragments covered with protective insulation, e.g. by printing with insulating paste) - the magnetic core is attached to the protective insulation, e.g. by means of an adhesive - the carrier that will later support the sections, e.g. by means of glue or in the form a hardening insulating paste, is applied to the magnetic core so that it Carrier as insulation between the magnetic core and the sections produced later and - the sections on the relevant carrier, e.g. by means of screen printing means, possibly also partially on the Substrate to be printed; and or to achieve thereby, see. The characterizing part of claim 3 that according to the second variant in successive steps conductor track - on a substrate, e.g. by screen printing of nyrpaste and burning it off, the fragments and the with them connected contact pads are formed - at least partially the Fragments covered with protective insulation, e.g. by printing with insulating paste and - the magnetic core as a highly permeable paste material on the protective insulation is printed.

Allow the additional measures specified in the subclaims additional advantages, namely the measure according to claim 2, also a relative thick magnetic core or magnetic core leg through, preferably by means of screen printing, printed Cover sections by then making the sections also in the area of the sloping outer edges can be produced with a relatively low reject rate, 4, a relatively high one Thickness of the printed magnetic core or magnetic core leg with flat outer edges to be able to achieve, 5, a particularly high permeability of the printed magnetic core to be able to achieve, 6, not only the magnetic core or magnetic core leg, but also the sections, even if necessary also the intermediate girders, in to be able to produce particularly favorable printing technology for mass production, 7, a to enable subsequent coarse adjustment of the inductance of the hybrid coil in the the value of the inductance is usually greater than before the adjustment, 8, this Carry out rough adjustment in a favorable way, especially for mass production, 9, to offer another possibility for later adjustment of the inductance in order to to be able to make the value of the inductance smaller or larger during adjustment, 10, to allow a final fine adjustment of the inductance at which the Value of the inductance, depending on the type of separation of the network, in general becomes slightly larger, depending on the paths that eventually the hybrid coil currents have to take.

The invention is shown schematically on the basis of the figures Embodiments further explained, with Figures 1 and 2 a cross section through the here rectangular, relatively thin magnetic core leg, 3 and 4 a cross section due to the relatively thick magnetic core leg, which is printed from several layers with flat, i.e. oblique, outer edges, and FIG. 5 shows a plan view of the in FIGS. Figures 2 and 4 show embodiments shown.

The embodiments shown in Figures 1 to 4 are according to the first variant of the measures produced in successive steps, that on the, e.g.

made of epoxy resin, substrate Su, e.g. by means of screen printing from Conductor paste in, braersnelb ,,, first the fragments F or F1 and the ones with them Conductively connected contact pads KF1, KF2 are formed. Then, at least below part of the later magnetic core leg MK, the fragments F or F1 covered with protective insulation Is1, e.g. by means of printing with insulating paste. Then the, e.g. massive, here relatively flat magnetic core or its legs MK, e.g. by means of an adhesive, firmly attached to the protective insulation Is1. Thereafter will be the one that will later carry sections A. Carrier Is2, e.g. by means of Glue or in the form of a hardening insulating paste, so on the magnetic core or Magnetic core leg attached that this carrier Is2 as insulation between the Magnetic core or magnetic core leg MK and the sections A produced later lies. Finally, the sections A are placed on the carrier Is2, e.g. by means of screen printing means, printed. - The fragments of these figures are for better illustration F shown by cut surfaces F1, although they are actually in the relevant cross-section II / IV, see Fig. 5, are not sectioned; in truth, then, F would be at these cross-sections II / IV actually covered by the insulating layer Is1, as is the contact patch KF1 would be covered, see FIG. 5.

As an alternative to this or in addition to this, the magnetic core or magnetic core leg can be used MK, instead of e.g. being solid or made of magnetizable foil, also made by this be that - after attaching the fragments F and the associated contact pads KF1, KF2 and after the subsequent covering of the fragments F with protective insulation Is1, e.g. by printing with insulating paste, - the magnetic core or its leg MK printed onto the protective insulation Is1 as a highly permeable hardening paste material will. A suitable paste material is, for example, a hardening binder, permalloy chips and / or contains particles of other highly permeable substances. It turned out that often a particularly high resulting permeability of the magnetic core or its leg, MK is achieved when an external magnetic field occurs during the hardening of the binder is applied, the direction of which is approximately the direction of the later existing magnetic Corresponds to field lines during later operation as a coil.

In the embodiments shown in FIGS. 2 and 4, the Network N, see FIG. 5, preferably together with the sections A in a common Process step produced on the substrate Su, incidentally also together with the Short-circuit bars KS, cf.

FIGS. 2, 4 and 5. In the exemplary embodiments shown in FIGS. 1 and 3 however, the network N is preferred together with the fragments F in a common Process step produced on the substrate Su, in these examples also together with the short-circuit bars KS, see Fig. 1 and 3, which in turn, electrically equivalent to the short-circuit bars KS shown in FIG. bridge second aontalrtflecken KF1, KF2. On the short-circuit bars KS is below entered further.

The magnetic core or its leg MK can each have flat outer edges 3 and 4, this leg MK is attached with its broad side on the protective insulation 1s1.

This will remove the parts attached over the flat outer edges the sections A are also shallower than those shown in FIGS Embodiments, whereby the reject rate decreases, if (also) the sections A can be printed.

The insulating layer 1s1 and the carrier Is2 can each also be be printed in a way that is favorable for mass production, so preferably in the form of a hardening insulating paste, with the carrier Is2 as insulation between the magnetic core or its leg MK on the one hand, tmci the ss ter hergestei 1 th sections A on the other hand.

Particularly thick magnetic cores or legs S can be achieved by that the magnetic core or leg MK in the form of several printed one above the other highly permeable len layers K1 to K4, see FIGS. 3 and 4, are printed on will. Here you can also find flat outer edges of this leg particularly easily MK, as these figures show, when the width of the printed layers, here K1 to K4, decreasing more and more towards the top. So in this case too the parts of the sections A lying above these flat outer edges are particularly flat and therefore printable with a correspondingly small reject rate.

The network N serves as already explained in the main patent application is for subsequent fine adjustment of the inductance of the hybrid coil. To before This fine adjustment initially enables a rough adjustment all embodiments shown in the figures, together with the fragments or sections A, N, between the fragments F and between the sections A, respectively or between the contact patches KF1, KF2, during the adjustment of the inductance, so after making the conductive connections VS accessible way, on both sides each short-circuit webs KS are also printed, see FIGS rough adjustment, namely increasing the inductance can be achieved by namely, preferably by means of a step-wise, e.g. 5 moved Laser beam, one or more of the short-circuit bars with measurement of the respective inductance KS, until the intended inductance is almost reached, allfr, separate become T. Such nuitromibare short-circuit webs KS for adjustment are already in themselves in DE-OS 30 39 113, which was not previously published.

An adjustment of the inductance, namely reduction and enlargement the same, is made possible by the magnetic resistance of the magnetic core MK and so the inductance is changed after the production of the sections A, N, by attaching another Magnet body, by moving the same up to the approximate achievement of the intended inductance and through Fixing the same, e.g. with glue. Such a 7 the leakage flux of the magnetic core Adjustment of the inductance influencing MK is not in itself already in the previously published DE-OS 30 36 704 described.

A fine adjustment of the inductance is, preferably afterwards, this makes it possible that1 again preferably by means of a laser beam, with measurement of the respective inductance one or more of the loops of the network N bis be separated to approximate the intended inductance. This The adjustment procedure is already described in the main patent / main application.

10 claims 5 figures Blank page

Claims (1)

Claims, method for producing a variable Hybrid coil having inductance with - substrate, - attached to the substrate, e.g. printed and burned-in, conductor tracks, at least largely each between contact patches conductively connected to the conductor tracks in question, that is between each of a first and a second contact pad, lie and each Represent fragments of turns, - as attached to these fragments, through a first insulating layer isolated from the fragments magnetic core that --- its magnetic field lines present in it during operation, at least partially, in a plane parallel to the substrate surface and along one side of the magnetic core the first contact pads and along the opposite side of the magnetic core, the second contact pads lie, - through a second insulating layer sections of conductor tracks isolated from the magnetic core, which form the rest of the windings form, and - conductive connections in each case between first ends of these sections with respectively associated first contact pads and between the other second Ends of these sections with respectively assigned second contact pads, where - one or more of the fragments and / or one or more sections, in - at least during an operating phase and / or manufacturing phase after the application of the conductive Connections - accessible white se, one at least one each Forms a single loop network of lines, according to patent / application P 30 39 163.0, used in particular as a hybrid filter coil in a subscriber speech signal frequency filter of a PCM telephone switching system, d u r g e k e n n z e i c h n e t that in successive steps - on a substrate (Su), e.g. by means of Screen printing of conductor paste E pbve welben, the fragments (F) and those with them connected contact pads (KF1, KF2) are formed - at least partially the Fragments (F) with protective insulation (is), e.g. covered with insulating plastic by means of printing - the magnetic core (MK), e.g. by means of an adhesive, on the protective insulation (Is1) is attached, - the beam (Is2) later carrying sections (A), e.g. by means of glue or in the form of a hardening insulating paste, see above on the magnetic core (MK) is attached that this carrier (Is2) as insulation between the magnetic core (MK) and the later carried sections (A), and - the sections (A) on the relevant carrier (Is2), e.g. by means of screen printing means, possibly partially (N) additionally printed on the substrate (Su). 2. The method according to claim 1, d a d u r c h g e k e n n z e i c h n e t that - a magnetic core with flat outer edges is used as the magnetic core (MK) and - this is attached with its broad side on the protective insulation (ins1) (Fig. 2 and 4). 5. Method of making a variable inductance having hybrid coil with - substrate, - attached to the substrate, e.g. printed and burned-in, conductor tracks, which are at least largely between each with the relevant conductor tracks conductively connected contact patches, that is, between each a first and a second contact pad, and fragments of each Represent turns, - as attached to these fragments, by a first Insulating layer from the fragments isolated magnetic core that --- its in it im Operation of existing magnetic field lines, at least partially, in one plane run parallel to the substrate surface and along one side of the magnetic core the first contact pads and along the opposite side of the magnetic core the second contact pads are - - through a second insulating layer from the magnetic core isolated sections of conductive traces that make up the remainder of the turns, and - Conductive connections between first ends of these sections with each associated first contact pads and between the other second ends of these Sections each with associated second contact pads, wherein - one or more of the fragments and / or one or more sections, in - at least during one Operating phase and / or manufacturing phase after the conductive connections have been made - accessible white se, each with at least one single loop having a network of lines, according to patent / application P 30 39 163.0, d a d u r c h e k e n n n z e i c h n e t that in successive steps - on a substrate (Su), e.g. by means of screen printing of conductor track paste and inserting the same, the fragments (F) and the contact pads (KF1, KF2) connected to them are formed - at least partially the fragments (F) with protective insulation (Is1), e.g. by printing with insulating paste, - the magnetic core (MK) as Highly permeable paste material (K1 to K4) printed on the protective insulation (Is1) will. 4. The method according to claims 2 and 3, d a d u r c h g e it is not possible to say that - the magnetic core (MK) in the form of several on top of one another printed highly permeable layers (K1 to K4) is printed (Fig. 3 and 4). 5. The method according to claim 3 or 4, d a d u r c h g e k e nn z e i c h n e t that - during the curing of the printed highly permeable Paste material (K1 to K4) an external magnetic field, the direction of which will be determined later in the Operation corresponds to the usual field line direction in the magnetic core (MK) on this paste material (K1 to K4) acts. 6. The method according to claim 3, 4 or 5, d a d u r c h g e k It is noted that - the beam (Is2) later carrying sections (A), e.g. by means of glue or in the form of a hardening insulating paste, see above on the magnetic core (MK) is attached that this carrier (Is2) as insulation between the magnetic core (MK) and the later carried sections (A), and - the sections (A) on the relevant carrier (Is2), possibly partially (N) additionally on the substrate (Su), e.g. by means of screen printing media. 7.Verfahren according to any one of the preceding claims, d a d u notices that - together with the fragments (F) and / or Sections (A, N) between several fragments (F) and / or between several sections (A), in - at least during an operating phase and / or manufacturing phase after attaching the conductive connections (V) - accessible way, at least one Short-circuit bar (KS) attached, e.g. printed1 (Fig. 5). 8. The method according to claim 7, d a d u r c h g e k e n n z e i c h n e t that - by means of a laser beam, while measuring the respective inductance, one or more of the short-circuit webs (KS) until the intended one is approximately reached Inductance can be separated. 9. The method according to any one of the preceding claims, d a d u r c h e k e n n n n z e i c h n e t that - the magnetic resistance of the magnetic core (MK) and thus the inductance, after the production of the sections (A, N) through --- Attaching another magnetic body, --- moving it up to the approximate Achieving the intended inductance and fixing it, e.g. by means of Glue, is changed. 10. The method according to any one of the preceding claims, d a d u r c h e k e n n n n n e i c h n e t that - by means of a laser beam, under measurement the respective inductance, one or more of the loops of the network (N) be separated until the intended inductance is approximately reached.