DE3036704A1 - Hybrid coil for use as frequency filter in PCM telephony - uses variable reluctance magnetic core inserted between two insulation layers - Google Patents

Abstract

The Hybrid coil partic. for use as a frequency filter for PCM telephone communication system sub-scriber speech signals has advantages such as partic-compact design and additional chosen and precise adjustment forthe inductance of the coil which enables the latter to be used as a frequency filter. The magnetic reluctance of the magnet core (MK) can be varied at least during one operational phase during mfr. utilisation of the hybrid coil. The magnetic core (MK) can be inserted to different depths into the pocket (IS1-IS2) formed by the gap between the first insulation layer (Is1) and the second isolation layer (Is2).

Description

Hybrid coil and process for their manufacture.

The invention relates to an electromagnetic component namely a special coil that is used in particular for frequency filters for subscriber speech signals a PCM telephone switching system was developed. The invention is suitable but beyond that, it is absolutely ideal for coils in communications technology, especially when these arrangements are produced in large numbers in mass production should and / or especially if these arrangements to be flat and insensitive to shock should.

As is also indicated in the preamble of claim 1, goes the invention from a known hybrid coil with - substrate, - on the substrate attached, e.g. printed and fired, conductor tracks, the at least largely in each case between conductively connected to the respective conductor tracks Contact patches, i.e. between a first and a second contact patch, and each represent fragments of turns9 and - so on these fragments attached flat, isolate from the fragments by a first insulating layer th magnetic core that --- its magnetic field lines present in it during operation, in any case largely 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 patches lie, is isolated from the magnetic core by a second insulating layer lated sections of conductor tracks, which form the rest of the turns, and - conductive connections each between first ends of these sections with each associated first Contact pads and between the other second ends of these sections with each associated second contact pads.

A plurality of variants of such hybrid coils are in older ones Applications described, see. The unpublished - DE-OS 30 16 067 and - DE-OS 30 35 8ff.

This ^ 'Lbeerc hybrid coil has a toroidal core coil there and already has the advantages given in the invention that - the turns no longer have to be placed or rolled up by hand, often very carefully, but time-saving, at least largely, mas.chinell with particularly little effort - the high tolerances for the thickness or flatness of, e.g.

Hand-wound windings can be avoided by using a high uniformity of the windings is ensured, - heavy wound magnet coils, which are connected to the substrate via only a few wires are avoided by the magnetic core; is attached to the substrate by a multitude of leads, as a result, the hybrid circuit is less sensitive to shock and therefore even, often without any subsequent action Complete potting with plastic, even in systems exposed to high accelerations - the magnetic core, even before the sections are joined with the fragments, if necessary, glued onto the substrate or its fragments can be without connecting the winding to the conductor tracks of the Substrate to complicate - what the shock insensitivity and spatial tolerance accuracy further increased, - the often high difficulties in positioning and individual soldering of individual wires for connecting to the substrate are largely eliminated, though now a much higher number of such connections has to be made - the tolerances the distances between the winding sections can be maintained so that short circuits between these sections can be safely avoided - regardless of the length of each Sections can be enlarged almost arbitrarily if necessary, so that e.g. thick magnetic cores are readily applicable, so that correspondingly high inductances can also be achieved are, instead of the maximum length of approx. 3 mm, permissible for bonded individual wires are, - instead of having to connect the sections one after the other, all sections, at least at one end, preferably in a single operation mechanically, at the same time with largely uniformly high quality with the assigned Contact surfaces can be connected, which in particular takes a lot of time and costs saves, - also cheaper material, e.g. copper mass, for the sections instead of the preferably single wires made of gold (see e.g. Electronics, July 20, 1928, Figure on p. 107) can be used, - sufficient operational safety even with more or less good electrical conductivity of the magnetic material is given, - The tearing off of the individual wires when they are placed on the magnetic core and when they are bonded and so that a corresponding amount of rejects can be avoided - because of the replacement the bonding of single rates, which generally requires gold, also others, often more reliable, connection types, e.g. 3. so-called flow soldering with ZinnS is allowed can, which is why the finding no more ceramics as a substrate absolutely presupposes; The invention also includes, for example, an oxide resin or hard paper permitted as substrate; and - without major spatial difficulties Tolerances and with regard to mutual isolation and positioning Even several layers of turns are required, even with very small distances between the sections from each other, can be attached and thus quickly and easily high inductances can be achieved, so that overall because of these advantages in the result - the Costs for the production of the arrangement compared to the hybrid circuits with massive wound magnet coils and - nevertheless, the smallness and the operational reliability of the hybrid circuit in compliance with tight spatial conditions Tolerances are improved.

The invention also has the additional advantages that - it requires very little space and, above all, - a subsequent one any exact adjustment of the inductance of the hybrid coil is possible, so that - it also allows the use of the hybrid coil for frequency filters.

The measures specified in the subclaims relate to the essential the same additional benefits; namely, they allow the measures according to the patent claim 2 to 4, the inductance can be adjusted relatively easily by moving the magnetic core 5, the inductance can be adjusted relatively easily even when the magnetic core is stationary, 6 to manufacture the hybrid coil in larger series, at least largely automatically and 7 to 9, depending on the type of magnetic core, the inductance afterwards to adjust.

The invention and its developments are illustrated in the figures schematically shown embodiments further explained, with Figure 1 a Cross section through an exemplary embodiment parallel to a winding turn, FIG a plan view of the embodiment shown in Figure 1, and 3 and 4 again the exemplary embodiment shown in Figures 1 and 2, but with an additional magnet body for adjustment by influencing the stray field of the hybrid coil.

The substrate Su of the hybrid coil can be seen in all four figures. On the substrate Su there are in each case the fragments, e.g. printed and burned-in F of conductor tracks attached, at least largely between each with the relevant interconnects F conductively connected pads KF, that is, between in each case a first and a second contact pad KF, and each Represent fragments F of turns of the hybrid coil.

On each of these fragments F is the flat one, covered by a first insulating layer Is1 attached magnetic core MK isolated from the fragments, in such a way that its the magnetic field lines present in the magnetic core MK during operation, at least largely, extend in a plane parallel to the substrate surface Su and that along the one Side of the magnetic core MK the first contact patches KF and along the opposite one Side of the magnetic core MK are the second contact pads KF.

The insulated from the magnetic core MK by the second insulating layer Is2 Sections A of conductor tracks each form the remainder of the turns of the hybrid coil, see in particular FIGS. 1 and 2, with part of the upper components in FIG. 2 / left of the exemplary embodiment to clarify the structure thereof has been omitted. There are conductive connections V between the first ends of these sections A with respectively assigned first contact pads KF and between the other second ones Ends of these sections A with respectively associated second contact pads KF attached.

The second insulating layer ts2 can, for example, by printing a Isolierla kes can be achieved, with the sections A itself also e.g. in thick film technology can be made on a carrier, what for itself in the older, not pre-published - DE-OS 30 16 067 is described. Instead, however, the second insulating layer can also be used Is2 must be identical to the carrier on which the sections A, e.g. in thick film technology are attached, with free-standing ends of these sections A over the beam Is2 protrude, see in particular the exemplary embodiment in FIGS. 1 and 3, and where these ends of the sections A are conductively connected at V to the contact pads KF. This variant of the production of the second insulating layer Is' and the sections A is described in the older, not previously published - DE-OS 50 35 g61.

To enable the subsequent adjustment of the inductance of the According to the invention, the hybrid coil is the magnetic resistance of the magnetic core EK, at least during an operating phase in the manufacture and / or application of the Hybrid coil, changeable. The "magnetic resistance", which in English is "reluctance" and in French t'Réluctance "is called, namely sets the size of the inductance of coils with magnetic cores, see e.g.

- Rint, Lexicon d. HF, NacE * straightening and electrical engineering, Volume 3, 1959, Pages 397 to 399, in particular paragraph 51, and - Schumann, Elektromagnetische Basic concepts, Oldenbourg Verlag 1950, pp. 94 to 110, in particular pp. 96 and 97.

In the invention, this magnetic resistance can be changed, for example, see Fig. 2, by moving the magnetic core MK and / or by Changing the shape of the Maznetkernes MK and / or by changing the stray field of Hybrid coil, in particular by means of an additional attached, displaceable on the outside Magr.etkö-pers MKz, which e.g. consist of iron or ferrite ceramic and the like can, see Fig. 3 and 4 ..

Dcmnacli can e.g., see Fig. 2, to enable adjustment, the magnetic core MK different depths in the pocket 1s1 - Is2, which through the gap formed between the first insulating layer Is1 and the second insulating layer Is2 will be plugged. This plugging as well as the change in the magnetic resistance succeeds particularly easily if the magnetic core MK, viewed perpendicular to the substrate surface Su, a non-parallel outline in the area of the fragments F and the sections A, in particular has a wedge-shaped outline, cf.

the wedge-shaped outline in Fig. 2. This stick of different depths then also slightly changes the magnetic resistance and thus the inductance, when the magnetic core MK, viewed parallel to the fragments F and the sections A, in the area of the fragments F and the sections A, a non-parallel outline, in particular has a stepped outline.

As indicated above, is the inductance the hybrid coil can also be adjusted by the fact that outside the pocket Is1 - Is2, the through the gap Z.fishing the first insulating layer Is1 and the second insulating layer Is2 is formed, an additional one which influences the leakage flux of the hybrid coil Magnet body MKz is attached, see Fig. 3 and 4. In this way, a subsequent Adjustment is particularly easy to achieve, especially because of this additional magnetic body MKz cannot only be moved back and forth slightly on the surface of the hybrid coil can, but because this can also be exchanged for another additional one Magnetic body MKz, e.g. larger or smaller as well as thicker or thinner as well Additional magnetic bodies MKz made of other magnetizable material. This allows you to set the range of values within which the inductance values are set can be made very large and still achieve a very precise adjustment.

The embodiments shown in the figures are e.g. a process can be largely produced with automatic machines, the following steps as successive ones Steps includes: - The substrate Su is made with the fragments F and with the contact pads KF, which are connected to the fragments F, covered, e.g. in thick-film technology.

- The fragments F are, at least partially, with the first insulating layer Is1 covered.

- The second insulating layer Is2 to be applied over the magnetic core MK is attached, for example, in the form of a beam Is2, which carries sections A.

- The sections A or the carrier Is2 is at least two places, e.g. left and right of the later position of the magnetic core MK, with regard to the Position adjusted to the contact patch.

- All connections V of the inden of sections A with the contact pads KF are in a single operation, while pressing all of these Ends on the assigned Kontaktxlecken KF, produced at the same time.

The magnetic core MK can then be adjusted under observation of the respective inductance, move in the pocket 1s1 - Is2: rnd it finally in fix the final position with an adhesive.

For adjustment you can, for example, also use the additional magnetic body MKz use this in the area of the stray field of the hybrid coil, especially above of sections A, while observing the respective inductance of the hybrid coil, in particular parallel to the substrate surface Su, move and this finite in the fix the final position with an adhesive.

Especially if you use the additional magnet body MKz for adjustment is used, the magnetic core MK itself may even be immobile. So you can Hybrid coil then also produce in that the magnetic core MK, cf.

Fig. 2, after covering the fragments F with the first insulating layer Is1 and before covering with the second insulating layer Is2, e.g. made of magnetizable Paste, is immovably applied to the first insulating layer Is1, e.g. is printed by means of screen printing. After conductively connecting the ends of the sections A with the contact patches KF, the additional magnet body MKz is finally placed, until the intended inductance is reached and moved into this position fixes the glue.

9 claims 4 figures

Claims (9)

Claims. c 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 Represent turns, and - so on these fragments attached flat, through a first insulating layer isolated from the fragments magnetic core that --- its magnetic field lines present in it during operation, at least largely, 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 the water sections with respectively associated second contact pads, in particular used 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 - the magnetic resistance of the magnetic core (MK), at least during an operating phase in the manufacture and / or use of the hybrid coil, changeable is (Figs. 2 and 4). 2. Hybrid coil 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 - the magnetic core (MK) different depths into the pocket (Isi - Is2) through the gap between the first insulating layer (Isi) and the second Insulating layer (Is2) is formed, can be plugged in (Fig. 2). 3. Hybrid coil according to claim 2, d a d u r c h g e k e n n z e i c h n e t that - the magnetic core (MK), viewed perpendicular to the substrate surface (Su), in the area of the fragments (F) 0111d of the sections (A) a non-parallel Outline, in particular a wedge-shaped outline (Fig. 2). 4. Hybrid coil according to claim 2 or 3, d a d u r c h g e k e n n z e 1 c h n e t that - the magnetic core (MK), seen parallel to the fragments (F) and the sections (A), in the area of the fragments (F) and the sections (A) has a non-parallel outline, in particular a step-shaped outline. 5. Hybrid coil according to one of the preceding claims, d a d u r c h g e k e n n z e 1 c h n e t that - outside the pocket (ins1 - Is2), through the gap between the first insulating layer (ins1) and the second insulating layer (Is2) is formed, an additional factor influencing the leakage flux of the hybrid coil Magnet body (MKz) is attached (Fig. 3 and 4). 6. Method for making the hybrid coil according to one of the preceding Claims, d a d u k h e k e n n z e i c h n e t, that in successive Steps - the substrate (Su) with the fragments (F) and with the with the contact patches (KF) connected to the fragments (F) are covered, - the fragments, at least partially covered with the first insulating layer (Is1) - the Second insulating layer (Is2) to be applied over the magnetic core (MK), e.g. in the form of a carrier (Is2) carrying the sections (A) is attached, - the sections (A) or the Carrier (Is2) in at least two places, e.g. left and right of the later layer Adjusted the magnetic core with regard to the position to the contact spots (KF) becomes and - all connections (V) of the ends of the sections (A) with the contact: spots (KF) in a single operation, while pressing all of these on at the same time Ends on the assigned contact pads (KF), are made at the same time. 7. Method of manufacture, namely adjusting the inductance, the Hybrid coil according to one of the claims 2 bi; 4, after manufacturing is complete according to patent claim 6, d u r c h g e n n n z e i c h n e t that - the magnetic core (MK) moves while observing the respective inductance in the pocket (Is1 - Is2) and - the magnetic core (MK) is fixed in its final position with an adhesive will. 8. Method of manufacture, namely adjusting the inductance, the Hybrid coil according to patent claim 5, d a d u r c h e k e n n n z e i c h n e t that - The magnetic body in the area of the stray field of the hybrid coil, in particular above of the sections, while observing the respective inductance of the hybrid coil is moved to the substrate surface and - the magnetic body in the final position is fixed by an adhesive. 9. The method according to claim 6 and 8 for production including Adjustment of a hybrid coil according to claim 5, d a d u r c h g e k e n n z e i c h n e t that - after covering the fragments (F) and before covering with On the second insulating layer (Is2) the magnetic core, e.g. made of magnetizable paste the first insulating layer (Is1) is attached immovably and - after connecting (V) the ends of the sections (A) with the contact pads of the additional magnetic body (MKz) placed, shifted until the intended inductance is reached and is fixed in this position by the adhesive.