EP4032108A1

EP4032108A1 - Inductive component and method for setting an inductivity value

Info

Publication number: EP4032108A1
Application number: EP20775254.4A
Authority: EP
Inventors: Oleg FURSA; Andreas Michael ROSSOLL; Enrico Stura; Stefan Weber
Original assignee: Philip Morris Products SA
Current assignee: Philip Morris Products SA
Priority date: 2019-09-20
Filing date: 2020-09-17
Publication date: 2022-07-27
Also published as: KR20220062644A; CN114450764A; BR112022001853A2; US20220336150A1; JP2022548926A; IL291399A; WO2021053068A1

Abstract

The invention relates to a component (1) comprising a wire winding (3) surrounded by a magnetic foil (2). According to the method for setting an inductivity value, a magnetic foil (2) is wound around wire winding (3). The number of layer of the wound film (2) can be selected in accordance with the desired value of the inductance (L).

Description

description

Inductive component and method for setting an inductance value

The present invention relates to an inductive component having a wire winding. It can be a coil with a magnetic core within the wire winding or without a magnetic core within the wire winding. For example, the inductive component is used in a stereo system.

For many applications, a precise setting of the inductance value of the component, at least in the statistical mean for a group of inductances (lot), is desirable. A high-precision setting of the inductance is necessary, especially for resonance applications. The component is designed in particular for use in the high frequency range.

The geometric dimensions have a strong influence on the inductance of electrical components, especially in the case of air-core coils. Highly precise inductance values can only be produced within certain physical limits and require precise control of the geometry. Variations in the material properties and the operating temperature also lead to a variation in the inductance value in the case of inductors with or without a magnetic core. The correction of deviations in the inductance value of a finished component from a desired target value is referred to as "adjustment" or "tuning".

The publications DE 3618 122 A1, DE 3926 231 A1, DE 199 52 192 A1 and DE 102 008 063 312 A1 describe adjustable inductive components. An adjustment is mostly accomplished by pushing in or out a core made of soft magnetic material into the interior of the winding or by pulling apart or compressing the winding.

It is an object of the present invention to specify an improved inductive component and a method for setting an inductance value of an inductive component.

According to a first aspect of the present invention, an inductive component has a wire winding. The wire winding is wrapped in a magnetic film. In particular, the magnetic film can be in direct contact with the wire winding. An insulating layer can also be arranged between the magnetic film and the wire winding.

The inductance of the component can be precisely adjusted through the film after the wire winding has been produced.

Depending on the desired nominal value of the inductance, the film can be wound around the wire winding in a suitable number of turns. With an increase in the number of turns, the magnetic thickness of the film roll can be increased. Thus, the film creates a magnetic body outside the winding, which influences the inductance of the component. For example, depending on the magnetic thickness of the film, the inductance of the component can be changed in the range of nH.

The wire winding has, for example, as a winding wire a metallic wire, for example copper, aluminum or silver wire.

The component can have a carrier body for the winding wire. In one embodiment, the carrier body is formed from a non-magnetic material. For example, it is a plastic material. There can be no magnetic core inside the winding wire. The carrier body thus functions purely as a carrier for the winding wire, but not for guiding the magnetic flux. In such an embodiment, the inductance is particularly dependent on the geometry, in particular the diameter of the coil, so that the inductance can be strongly influenced by applying the film in the outer region of the wire winding.

In an alternative embodiment, the carrier body can be formed from a magnetic material. For example, it can be a ferrite core. It is also possible for a magnetic core to be arranged within a non-magnetic carrier body.

The magnetic foil can surround the wire winding over the entire length of the winding. The film can also surround the wire winding in one direction around the winding axis. For example, the wire winding is completely covered on the outside by the film. For example, the wire winding is wound helically. The wire winding can have the basic geometry of a tube. The magnetic film, for example, also has the basic geometry of a tube in which the wire winding is received. It is also possible that the foil does not completely cover the wire winding. Preferably covered the film at least three quarters of the outer surface of the

Wire winding. This does not include the ends of the wire that may protrude from the coiled shape.

The magnetic film can be designed to be self-adhesive. This enables the film to be attached particularly easily.

Alternatively, the film can be designed to be non-self-adhesive and can be fastened with an adhesive or by heating and pressure.

For example, the film is provided in the form of a roll before application and can then be unwound from the roll and applied to the wire winding. The film can, for example, also be provided in the form of a strip.

The film can be wrapped around the wire winding in one or more layers. For example, the film has 1 to 10 layers. For example, the film has more than one layer, in particular at least two layers. By increasing the number of layers, the magnetic thickness of the film roll can be increased and thus the inductance can be increased. The layers of the film can be in direct contact with one another. In the case of a self-adhesive design of the film, the layers can be attached to one another in a simple manner.

The film can also be wrapped around the wire winding in just a single layer. It is also possible for the film to be wound around the wire winding with a non-integer number of windings, for example having 2.5 layers. The film, corresponding to a layer of the film in wound form, has, for example, a maximum thickness of 100 μm.

The film can have one or more layers. In particular, one layer of the film roll can be configured in one or more layers. The film can be designed as a laminate of several layers. The layers can be connected to one another by an additional adhesive or without an additional adhesive.

For example, the film has at least one magnetic layer. The film can also have several magnetic layers. The magnetic layer comprises a magnetic material. The magnetic material can be a ferrite material, for example. It can also be pure iron or an amorphous or nanocrystalline iron alloy. In particular, they can also be highly permeable materials, for example with a permeability of m> 1000.

The magnetic material can be embedded in particle form in a non-magnetic material, for example a plastic. In particular, the particles are distributed in the non-magnetic material. The non-magnetic material can also be designed as an adhesive. The required strength and flexibility of the film can be guaranteed by the non-magnetic material. For example, such a film is provided in cured form, wound around the wire winding and then fixed by heating. An additional adhesive can also be applied. Alternatively, the magnetic layer can also consist of the magnetic material. In this case, there are no magnetic particles embedded in a non-magnetic material, but the layer is formed entirely from the magnetic material. For example, it is an iron band. The other materials mentioned above can also be used here.

In one embodiment, the film has a carrier layer in addition to the magnetic layer. The carrier layer is, for example, non-magnetic. The carrier layer has, for example, plastic or consists of plastic. The carrier layer can also have an adhesive, in particular a cured adhesive. The magnetic layer is attached to the carrier layer, for example by heating and applying pressure. Alternatively, the magnetic layer is glued to the carrier layer.

The properties of the film, in particular the strength and flexibility of the film, can be improved by the carrier layer. In the case of brittle magnetic layers in particular, the carrier layer can ensure that the film can be processed. Alternatively, an adhesive that attaches the film to the component can also ensure that the film is held together if cracks develop in the magnetic layer. The adhesive on the component thus takes on the function of the carrier layer. In this case, the film is provided, for example, without a carrier layer, an adhesive is applied to the film and the film is wrapped around the wire winding.

There can also be several carrier layers. For example, a magnetic layer is arranged between two carrier layers.

The inductance of the component is between 1 and 1000 nH, for example. Depending on the design, by varying the number of turns in the film, it is possible, for example, to adjust the inductance in a range of up to 10% of the inductance in 0.1% steps.

An insulating layer can also be provided between the wire winding and the magnetic film. The insulating layer is designed in particular to be non-magnetic and non-conductive.

Furthermore, an electrical shield, in particular in the form of an electrically conductive material, can be applied to the foil winding. The electrical shield can surround the wound magnetic film. The shield is in the form of a further film or a coating, for example. The shield can comprise a conductive material, for example a metal. For example, a metallic foil such as copper foil, aluminum foil or tinned copper foil can be applied to the magnetic foil. The metallic foil can have one or more layers. In this way, the electrical shielding of the inductive component can be ensured. Optionally, an additional non-conductive film for fixing can be arranged over the shield.

According to a further aspect of the present invention, a method for setting an inductance value of an inductive component is specified. It becomes a wire wrap provided and wrapped with a magnetic film.

The inductance value of the component obtained is influenced by the magnetic film. For example, a number of layers of the film can be selected as a function of a nominal value for the inductance.

It is also possible, as an alternative or in addition to this, to choose the thickness of a magnetic layer of the film as a function of a desired target value. For example, several foils with different thicknesses of a magnetic layer can be provided and one of the foils is then selected as a function of a desired target value.

The foil, the wire winding and the inductive component can have all of the properties described above. For example, a magnetic core can be arranged within the wire winding or no magnetic core can be arranged within the wire winding.

For example, the inductance of the component is measured before or after the film is wrapped around it and the number of layers of the inductive component or of a further inductive component is changed depending on the deviation of the measured value from a target value. The inductance can also be measured indirectly, i.e. a measured value can be determined that represents a measure of the inductance.

During the measurement, the film can still have a part that is not wound around the wire winding and protrudes from the wound part. Depending on the measured value, the film can either be further wound around the wire winding or the protruding part can be separated. Alternatively, the non-wound part can be separated after winding and another film can be wound up after the measurement.

The number of layers can be increased step by step until the desired target value is reached. Incomplete layers can also be applied. For example, the number of layers is increased step by step until the desired target value is reached. Depending on the type of fastening, the number of layers can also be reduced. For example, the number of layers is changed in a range from 1.00 to 10.00 turns.

Overall, the inductance value can be adjusted in a simple form by applying the magnetic film. In particular, a comparison can also take place after or even during the measurement.

After the film has been wound on, that is to say when the setpoint is reached, an electrical shield, in particular in the form of an electrically conductive material, can be applied to the film winding. The electrical shield can surround the wound magnetic film. The shield is in the form of a further film or a coating, for example. The shield can comprise a conductive material, for example a metal. For example, a metallic foil, such as, for example, copper foil, aluminum foil or tinned copper foil, can be applied to the magnetic foil. The metallic foil can have one or more layers. In this way, the electrical shielding of the inductive component can be ensured. Optionally, an additional non-conductive film can be placed over the shield for fixing to be ordered.

The description of the subjects specified here is not restricted to the individual specific embodiments. Rather, the features of the individual embodiments can be combined with one another, insofar as it is technically sensible.

In the following, the subjects described here are explained in more detail with the aid of schematic exemplary embodiments.

Show it:

Figure 1 shows an embodiment of an inductive component in a side view,

FIG. 2 shows a base body of the component from FIG

1,

FIG. 3 shows a film for wrapping around the base body from FIG. 2,

FIGS. 4A to 4D show a method for setting an inductance in a schematic representation.

In the following figures, the same reference symbols preferably refer to functionally or structurally corresponding parts of the various embodiments.

FIG. 1 shows an inductive component 1 having a magnetic film 2 for balancing the inductance of component 1. FIG. 2 shows, for illustration, a base body 6 of component 1 from FIG. 1, that is, without the film 2 being wrapped around it. The component 1 has a winding 3 (see FIG. 2) of a wire 4. The winding 3 is wound around a carrier body 5.

The carrier body 5 can for example be designed as a magnetic core. For example, the carrier body 5 can be designed as a ferrite core. The carrier body 5 can also be designed to be non-magnetic. In this case, a magnetic core can be arranged within the carrier body 5.

Alternatively, the base body 6 can be designed as an air-core coil. In this case, the carrier body 5 is non-magnetic and there is also no magnetic core in the carrier body 5.

The carrier body 5 can also be referred to as a coil body, the inductive component 1 as a coil.

The carrier body 5 has, for example, plastic. The carrier body 5 is produced, for example, in an injection molding process.

The wire 3 is designed as a copper wire, for example.

It can also be an aluminum, silver or gold wire, for example. The wire can be insulated, for example with a varnish. In order to improve the solderability and / or tendency to oxidize, the wire, in particular in the case of aluminum or copper, can be coated with other metals such as tin, silver, nickel or gold.

In the present case, the carrier body 5 has a circular cylindrical shape Shape on. The carrier body 5 can also have a different shape, for example a cuboid shape. The carrier body 5 can also be part of a larger body, for example an annular body.

The carrier body 5 is shown here as a hollow body, but can also be designed as a solid body. When designed as a hollow body, a magnetic core can also be inserted in the carrier body 5.

To adjust the inductance of the component 1, the wire winding 3 is surrounded by a magnetic film 2. The film 2 is wound into a film roll 13. The film 2 has a magnetic material. In particular, the film 2 is not or only slightly electrically conductive. An insulating layer can optionally be arranged between the film 2 and the wire winding 3. The insulating layer can have a plastic, for example.

By means of the film 2, the inductance of the component 1 can be set precisely after the wire winding 3 has been produced. Depending on the desired nominal value of the inductance, the film 2 can be wound around the wire winding 3 in a suitable number of turns. In the present case, the foil winding 13 has four complete turns, so that four layers 18, 19, 20, 21 lie on top of one another. The film 2 can also have a different number of layers, for example between 1 and 10 layers. It is also possible for the film to have more than 10 layers. In particular, the film 2 is already in its basic form before the component 1 is wrapped around it. For example, the film 2 is provided in the form of a roll, unwound and wrapped around the base body 6. The film 2 can also, for example be provided in the form of a strip.

The film roll 13 forms a magnetic body outside the winding. The number of turns determines the magnetic thickness of the film roll 13. The film roll 13 can also be referred to as a shield winding due to its magnetically shielding effect.

The film roll 13 has, in particular, the shape of a tube arranged around the base body 6. The film roll 13 completely covers the wire winding 3 towards the outside, in particular in a direction radially outward as seen from a winding axis. Wire ends 14, 15 of the wire 4 protrude from the wound film 2. The film roll 13 does not completely cover the length of the carrier body 5, for example.

The film roll 13 can be surrounded on the outside by an electrical shield 16. The shield 16 is in the form of a further film or a coating, for example. The shield 16 comprises a conductive material, for example a metal. Optionally, an additional non-conductive film for fixing can be arranged over the shield 16.

FIG. 3 shows an example of a magnetic film 2 for adjusting the inductance. The basic shape of the film 2 is present before and after the wrapping of the base body 6. The film 2 is provided, for example, as a roll or as a strip before being wrapped around it.

In the present case, the film 2 has two carrier layers 7, 8 and a magnetic layer 9 arranged between them. The Foil 2 has a multilayered structure

Instead of two carrier layers 7, 8, only one carrier layer or no carrier layer can be present. The use of only one carrier layer or no carrier layer has the advantage that the overall thickness of the film 2 is less.

The carrier layers 7, 8 are, for example, non-magnetic and serve to stabilize the magnetic layer 9. In particular, the carrier layers 7, 8 can have plastic or consist of plastic. The carrier layers 7, 8 can also have an adhesive, in particular a cured adhesive.

The magnetic layer 9 has, for example, a non-magnetic material 12 filled with magnetic particles 11. For example, the non-magnetic material 12 can be a plastic. The magnetic material 12 can also be an adhesive. The thickness d of the magnetic layer 9 is also referred to as the magnetic thickness of the film 2. The total thickness D of the film is derived from the thickness of the carrier layers 7, 8 and the

Thickness d of the magnetic layer 9 is formed. For example, the thickness of the film 2 is a maximum of 100 μm.

Ferrite, for example, is suitable as the material for the magnetic particles 11. Depending on the desired properties, pure iron or an amorphous or nanocrystalline iron alloy can also be used. The material can be in powder form. In particular, it can also be a highly permeable material, for example with a permeability of m> 1000. Alternatively, the magnetic layer 9 can also consist entirely or mainly of a magnetic material. In particular, the magnetic layer 9 can only have the magnetic material and no non-magnetic carrier material. In particular, the magnetic material is not present in the form of individual particles, but rather as a continuous layer. For example, the magnetic layer 9 is in the form of an iron tape. For example, the band can have ferrite, pure iron or an iron alloy as material.

The carrier layers 7, 8 are particularly advantageous when using brittle magnetic layers 9, for example an iron strip. In particular, some highly permeable materials have a high degree of brittleness. Due to the carrier layers 7, 8, the shape and the magnetic properties can be retained in the event of cracks in the magnetic layer 9. In the case of less brittle magnetic layers 9, a film 2 without a carrier layer can also be used. It is also possible that an adhesive, which can simultaneously serve to attach the film 2 to the component 1, ensures the stability of the film 2 in the event of cracks. In this case, too, the film 2 can be formed without an additional carrier layer 7, 8 even if a brittle magnetic layer 9 is used.

The magnetic layer 9 can also be made up of several sub-layers. Each of the partial layers can have the structure of the magnetic layer 9 described above. The partial layers are, for example, glued to one another. In this way, the thickness d of the magnetic Layer 9 in the film 2 can be set.

Thus, with the choice of the thickness d of the magnetic layer 9, it can be determined how much a turn of the film 2 around the base body 6 influences the inductance of the component 1.

For example, in the case of a thick design with many partial layers of the magnetic layer 9, for example 20 partial layers, when a single turn is applied, the same magnetic thickness can be achieved as in an embodiment with a single-layer magnetic layer 9 with many turns, for example 20 turns. The total thickness of the film roll 13 can then differ greatly depending on the number of carrier layers 7, 8.

The magnetic layer 9 is connected, for example, to the carrier layers 7, 8 by means of an adhesive, for example an adhesive. The magnetic layer 9 can also be connected to the carrier layers 7, 8 via a purely thermal process.

The film 2 has, for example, an adhesive 10, in particular an adhesive, on one surface. The adhesive 10 can also be applied to both surfaces. The film 2 can thus be attached to the base body 6 in a self-adhesive manner. Alternatively, the adhesive 10 can also be applied subsequently to the base body 6 and / or the film 2. The layers 18, 19, 20, 21 can also be attached to one another by the adhesive 10. The film 2 can be processed flexibly like an adhesive tape, for example. FIGS. 4A to 4D show method steps when setting an inductance of an inductive component, for example the inductive component 1 according to FIG. 1.

According to FIG. 4A, a base body 6 having a winding 3 of a wire 4 is provided. The base body 6 can be designed according to FIG. The inductance L of the basic body 6 can be determined by measurement.

According to FIG. 4B, a film 2 is provided. The film 2 has the structure according to FIG. 3, for example. The film 2 can also have a magnetic layer which is formed over its entire volume by a magnetic material. The film 2 can be designed with or without carrier layers.

The film 2 is provided in the form of a roll 17, for example. The film 2 can be designed to be self-adhesive. In the case of a self-living film 2, a protective film can be present to cover the adhesive surface, which is then removed before sticking on. In the case of a non-self-adhesive film 2, an adhesive, in particular an adhesive, can be applied.

According to FIG. 4C, the film 2 is wrapped around the base body 6. The number of turns of the film roll 13 obtained is determined, for example, as a function of the deviation of the measured inductance from a nominal value of the inductance. In the present case, two turns, corresponding to two layers 18, 19, are applied in a first step. Optionally, an insulating layer can also be applied to the wire winding 3 before the film 2 is applied. The film 2 can be cut to the desired length before or after being wrapped. As shown, a part of the film 2, in particular the roll 17, can also protrude from the film roll 13 and only be cut off later, as soon as the nominal value of the inductance has been reached.

After or during the winding process, the inductance L of the component 1 can be determined. If the inductance value corresponds to the target value, if a part of the film 2 is still protruding, this part of the film 2 is cut off. The number of windings can now be specified for a group of identical components, so that no measurement is required for these components during manufacture.

If the measured value is below a target value, the film 2 is wound further around the base body 6 or a separate film 2 is wound around the base body 6.

Overall, by adding further turns to the film roll 13, the magnetic thickness and thus the inductance can be set very precisely. For example, depending on the required thickness of the film roll 13, the thickness can be varied in small steps, for example in 2.5% steps.

It is also possible to apply partial turns. For example, the film can be wrapped around the base body 6 in 1.5 turns.

If the measured value is above the target value, the number can of the turns can be reduced or a film 2 with a smaller thickness of the magnetic layer 9 can be used.

In the present case, the measured inductance is not yet sufficiently close to the target value, so that the film 2 continues to be wrapped around the base body 6.

According to FIG. 4D, two further turns, corresponding to two further layers 20, 21 of the film 2, are now wound around the base body 6. The inductance can then be measured again. Since a target value has now been reached, the rest of the film 2 is separated. If the desired inductance has not yet been achieved, the winding process can be continued.

Finally, according to FIG. 4E, an electrical shield 16 can optionally also be applied to the film roll 13.

For example, the foil roll 13 is wrapped with one or more layers of a further metallic foil or coated with a metallic material. For example, a metallic foil such as copper foil, aluminum foil or tinned copper foil is applied to the magnetic foil.

For example, an additional film is arranged on the outside for improved fixation (not shown). List of reference symbols

1 component

2 slide

3 winding

4 wire

5 carrier bodies

6 base bodies

7 carrier layer

8 carrier layer

9 magnetic layer

10 adhesives

11 magnetic particles

12 non-magnetic material

13 foil wraps

14 end of wire

15 end of wire

16 electrical shielding

17 role

18 position

19 location

20 position

21 layer d thickness of the magnetic layer D thickness of the foil

Claims

1. An inductive component comprising a wire winding (3) which is wrapped by a magnetic film (2), and an electrical shield (16) which surrounds the wound magnetic film (2).

2. Inductive component according to claim 1, wherein the magnetic film (2) is self-adhesive.

3. Inductive component according to one of the preceding claims, wherein the magnetic film (2) is wound around the wire winding in several layers (18, 19, 20, 21).

4. Inductive component according to one of the preceding claims, which has a magnetic core which is arranged within the wire winding (3).

5. Inductive component according to one of the preceding claims, which has no magnetic core within the wire winding (3).

6. Inductive component according to one of the preceding claims, wherein the magnetic film (2) has a non-magnetic carrier layer (7, 8) and a magnetic layer (9).

7. Inductive component according to one of the preceding claims, wherein the magnetic film (2) has ferrite, pure iron or an amorphous or nanocrystalline iron alloy as the magnetic material.

8. Inductive component according to one of the preceding claims, wherein a magnetic material of the film (2) is in the form of particles (11) which are embedded in a non-magnetic material (12).

9. Inductive component according to one of the preceding claims, wherein the magnetic layer (9) is completely formed by a magnetic material.

10. Inductive component according to one of the preceding claims, wherein the magnetic film (2) has a maximum thickness of 100 μm.

11. A method for setting an inductance value of an inductive component, wherein a wire winding (3) is provided and wrapped with a magnetic film (2), and wherein after the winding of the magnetic film (2) an electrical shield (16) is placed on the wound magnetic Foil (2) is applied.

12. The method according to claim 11, wherein a number of layers of the wound film (2) or a thickness of a magnetic layer of the film (2) is selected as a function of a nominal value of the inductance (L).

13. The method according to any one of claims 11 or 12, wherein the inductance (L) of the component (1) is measured before and / or after the wrapping with the film (2) and the number of layers of the wound film (2) depending on the deviation of the measured value is changed from a setpoint.

14. The method according to claim 13 in which part of the length of the film (2) is wrapped around the wire winding (3) during the measurement and a further part of its length protrudes from the wound shape and after the measurement the film (2) continues onto the wire winding ( 3) is wrapped.

15. The method according to any one of claims 11 to 14, wherein after the application of the film (2) a protruding

Part of the film (2) is separated.