DE202016004405U1 - Inductive component - Google Patents

Abstract

An inductance component comprising a ferrite core (8) and a coil, wherein the ferrite core (8) has a through-opening and wherein the coil is formed from a band-shaped metal strip (18) extending through the through-hole and whose ends extend respectively from the Passage opening to an underside of the ferrite core (8) and there form at least two terminal contacts, characterized in that the band-shaped metal strip (18) is formed of a plate-shaped resistor element and two separated by the resistor element connecting elements made of high conductivity metal.

Description

The invention relates to an inductive component having a ferrite core and a coil, wherein the ferrite core has a through opening and wherein the coil is formed from a band-shaped metal strip which extends through the through opening and whose ends extend from the through opening to a bottom of the respective Ferrite core extend and form there at least two connection contacts.

From the European patent application EP 2 722 858 A2 is an inductive component with a ferrite core and a coil known. The ferrite core is made in one of the illustrated embodiments of a solid block with a through hole. The coil consists of a band-shaped metal strip which extends through the passage opening. The ends of the metal strip are respectively bent at the two opposite ends of the passage opening and extend to a lower side of the ferrite core. On this underside, the ends of the metal strip form a total of four connection contacts. Two of the connection contacts are provided for a resistance measurement and two of the connection contacts for a connection of the coil. The inductive component described is used for example in power supplies and serves as an inductive component and on the other hand as a measuring resistor in order to determine the voltage across the measuring resistor can.

With the invention, an improved inductive component is to be provided.

According to the invention, an inductive component with a ferrite core and a coil is provided for this purpose, the ferrite core having a passage opening and wherein the coil is formed from a band-shaped metal strip which extends through the passage opening and whose ends extend from the passage opening to an underside extend there of the ferrite core and form there at least two terminal contacts, wherein the band-shaped metal strip is formed of a plate-shaped resistor element and two by the resistor element separate terminal elements made of high conductivity metal.

By forming the coil from a metal strip whose DC resistance value is for the most part determined by the resistance element, the DC resistance value of the coil can be set within very narrow limits. In addition, a very high resistance value can be set compared to a pure copper strip. A very closely tolerated DC resistance value of the coil has enormous advantages for the measuring function of the inductive component, that is, if, for example, the voltage value to be measured, which is applied to the inductive component. The resistance element may for example consist of a special metal alloy, for example Zeranin or manganin from Isabellenhütte Heusler GmbH. A method for producing a band-shaped metal strip from a plate-shaped resistance element and two connecting elements made of high-conductivity metal separated from one another by the resistance element is described, for example, in the European patent specification EP 0 605 800 B1 described.

In a development of the invention, the resistance element is formed from a material with a very low temperature dependence of the resistance value, such that a resistance value of the resistance element changes between a temperature of 20 ° C. and 60 ° C. by less than 50 ppm / ° C.

When using the alloy manganin, resistance values from about 1 mOhm with low temperature dependence can be realized.

In a further development of the invention, a resistance value of the resistance element between a temperature of 20 ° C and 60 ° C changes by less than 20 ppm / ° C.

When using the alloy Zeranin for the resistive element, an even lower temperature dependence can be realized. In practice, resistance values of up to about 0.5 mOhm can be achieved.

In a further development of the invention, a ratio of the resistance value to the resistance value at 20 ° C between a temperature of the resistive element changes from -40 ° C to 170 ° C by less than 0.3%, in particular between a temperature by -40 ° C to 140 ° C less than 0.1%.

Using manganin as a resistive element allows a change of less than 0.3%, a use of zeranine as a resistive element even a change of less than 0.1%.

In a further development of the invention, the ferrite core consists of a ferrite material containing manganese and zinc or nickel and zinc.

In a further development of the invention, the ferrite core consists of two, in particular substantially cuboid, elements which are glued together.

In a further development of the invention, at least one of the, in particular cuboidal, elements has a groove, which forms a portion of the wall of the passage opening in the connected state of the elements.

After bonding the two parallelepiped elements thereby automatically creates a through hole for the band-shaped metal strip, which forms the coil. Such a passage opening can be produced for example by gluing together two L-shaped elements.

In a further development of the invention, there is in each case a gap with a predefined gap width between the two, in particular cuboid, elements in the area of the splices, wherein the gap is at least partially filled with adhesive.

By means of a gap with predefined gap width between the two cuboidal elements, the electromagnetic properties of the inductive component can be set very precisely.

In a further development of the invention, a spacer, in particular an insulated or non-conductive wire with a predefined thickness, is arranged in each gap.

By inserting a wire, a gap width can be set very precisely. Wires are available with extremely low thickness tolerances. By inserting a wire, a predefined gap width can be reproduced very precisely in a very simple manner. The wire is formed as insulated wire or non-conductive wire, so that it does not change the electromagnetic properties of the inductive component. Instead of a wire, for example, plastic parts or glass beads can be used as spacers.

In a further development of the invention, the plate-shaped resistance element and the connecting elements are connected to each other by means of a weld.

For example, the plate-shaped resistance element and the connection elements can be connected to one another by means of electron beam welding.

In a further development of the invention, a width of the weld is not greater than the material thickness of the resistive element.

In this way, the material structure of the metal strip is changed only in a very small length range of the metal strip. The resistance value of the resistance element and thus also the resistance of the entire metal strip is thereby influenced only negligibly by the weld.

In a development of the invention, a width of the weld corresponds to approximately one third of the material thickness of the resistance element.

By performing such a narrow weld, the resistance of the metal strip is affected only very slightly.

Further features and advantages of the invention will become apparent from the claims and the following description of a preferred embodiment of the invention taken in conjunction with the drawings. In the drawings show:

1 a view of an inductive component according to the invention obliquely from below,

2 the inductive component of 1 from a different angle,

3 the inductive component of 1 from a different angle,

4 the inductive component of 1 , wherein a part of the ferrite core has been omitted and

5 the metal strip of the inductive component of 1 ,

1 shows an inductive component 10 according to the invention in a view obliquely from below. The inductive component has a ferrite core 8th on, consisting of a first cuboidal element 12 and a second cuboidal element 14 is formed. The cuboidal elements 12 . 14 each consist of a ferrite material containing manganese and zinc. The ferrite core 8th is therefore also referred to as Mn-Zn ferrite. Alternatively, a ferrite containing nickel and zinc may be used.

The first cuboidal element 12 has a larger footprint than the second cuboidal element 14 , Specifically, the depth of the first cuboidal element 12 greater than the depth of the second cuboidal element 14 , The second block-shaped element 14 is centered on the first block-shaped element 12 placed. The width and height of the two cuboid elements 12 . 14 is equal to.

The first cuboidal element 12 has a groove 16 on, extending in the depth direction of the first cuboidal element 12 extends. In the connected state of the two cuboidal elements 12 . 14 has the ferrite core 8th thus one Through opening, wherein a portion of the wall of this passage opening through the groove 16 is formed.

A coil of the inductive component 10 is by means of a metal strip 18 formed, extending through the passage opening in the ferrite core 8th extends through. At both ends of the passage opening is the band-shaped metal strip 18 bent at right angles and extends towards an in 1 overhead underside of the ferrite core 8th , The band-shaped metal strip is then bent at both ends again by 90 °, so that on the underside of the ferrite core 8th a total of four connection contacts 30 . 32 . 34 . 36 are formed. The total of four connection contacts 30 . 32 . 34 . 36 arise from the fact that both ends of the metal strip 18 with a slot 38 are each provided a little way into the metal strip hineinerstreckt. The slots 38 are off-center to the metal strip 18 arranged so that the two connection contacts 30 . 32 are formed substantially wider than the two terminals 34 . 36 , The two wide connection contacts 30 . 32 are used to connect the inductive component with an electronic circuit, especially a power section of an electronic circuit, and are intended to be acted upon by alternating current to the inductance of the inductive component 10 to use.

The two narrower connection contacts 34 . 36 are used as connection contacts for the measurement of a DC resistance of the metal strip 18 intended.

The inductive component 18 will be with his in 1 the underside placed on top of a printed circuit board and in this way, the four terminals 30 . 32 . 34 . 36 each connected to the provided terminal contacts of a printed circuit board.

Between the two cuboidal elements 12 . 14 is each a gap 20 . 22 provided, which is bridged by means of adhesive. As an adhesive, for example, an epoxy resin is used. To the gap width of the column 20 . 22 To set high precision, is in the respective gap a piece of wire 24 . 26 inserted with predefined thickness. The thickness of the wire pieces 24 . 26 is chosen so that the desired electromagnetic properties of the inductive component 10 be achieved.

The presentation of the 2 shows the inductive component 10 of the 1 from a different angle, just like the presentation of the 3 ,

4 shows the inductive component 10 , in the representation of the 4 the cuboidal element 14 was omitted. It can be seen now that the section of the metal strip 18 that is inside the groove 16 of the first cuboidal element 12 is about as high as the groove 16 is deep. The second block-shaped element 14 therefore does not necessarily have to be provided with a groove to the predetermined distance, namely the gap width of the column 20 . 22 to be placed on the first block-shaped element.

In the presentation of the 4 are the two pieces of wire 24 . 26 to recognize. On the in 4 right side is just the piece of wire 24 shown. On the in 4 left side is the piece of wire 26 already in a shift 40 embedded in epoxy resin.

The presentation of the 5 only shows the metal strip 18 , The metal strip 18 is made of a plate-shaped resistor element 42 and two connection elements 44 . 46 formed by the resistance element 42 are separated from each other. The two connection elements 44 . 46 are with the resistance element 42 each by a in 5 indicated by dashed lines weld 48 respectively. 50 connected. The resistance element 42 consists of a material, for example a metal alloy, which has a very low temperature dependence of the DC resistance value. For example, zeranin is used by Isabellenhütte Heusler GmbH. The two connection elements 44 . 36 consist of a metal of high conductivity, such as copper or a copper alloy. The DC resistance value of the metal strip 18 operating in between the two narrower connection contacts 34 . 36 is measured by the predominant part of the resistance element 42 certainly. The DC resistance value of the metal strip 18 can be set to a very exact value. The metal strip 18 can due to the very low temperature dependence of the resistance value of the resistive element 42 can also be used as a high-precision measuring resistor.

The welds 48 . 50 are manufactured by electron beam welding and have a width which is only about one third of the material thickness of the resistive element 42 equivalent.

The metal strip 18 will be in the in 5 prepared form and then subsequently with the ferrite core 8th combined.

For producing the inductive component 10 then first the second cuboidal element 14 in the C-shape metal strip 18 inserted. Thereupon, the second cuboidal element becomes together with the metal strip 18 placed on the prepared first cuboidal element. The second cuboidal element 12 this is already with the pieces of wire 24 . 26 provided, see 4 , in which case both pieces of wire 24 . 26 in an adhesive layer 40 are embedded. The first cuboidal element 14 with the metal strip is then on the first cuboid component 12 pressed until another movement of the cuboidal elements 12 . 14 towards each other through the pieces of wire 24 . 26 is stopped. After curing the adhesive 40 is the inductive component 10 then finished, see 1 , The gap width of the column 20 . 22 is then exactly the same and by the thickness of the wire pieces 24 . 26 specified.

This also allows the electromagnetic properties of the inductive component 10 , especially the inductance of the inductive component 10 , set in very small tolerances.

The invention thus provides an inductive component which has extremely precise and very narrow tolerances both in terms of its inductance and in terms of its DC resistance value.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 2722858 A2 [0002]
• EP 0605800 B1 [0005]

Claims (12)

Inductive component with a ferrite core ( 8th ) and a coil, wherein the ferrite core ( 8th ) has a through opening and wherein the coil of a strip-shaped metal strip ( 18 ), which extends through the passage opening and whose ends extend in each case from the passage opening to an underside of the ferrite core (FIG. 8th ) and form there at least two terminal contacts, characterized in that the band-shaped metal strip ( 18 ) is formed from a plate-shaped resistance element and two connecting elements made of high-conductivity metal which are separated from one another by the resistance element. Inductive component according to claim 1, characterized in that the resistance element ( 42 ) is formed of a material with very low temperature dependence of the resistance value, so that a resistance value of the metal strip ( 18 ) changes between a temperature of 20 degrees Celsius and 60 degrees Celsius by less than 50 ppm / degree. Inductive component according to claim 2, characterized in that a resistance value of the metal strip ( 18 ) changes between a temperature of 20 degrees Celsius and 60 degrees Celsius by less than 20 ppm / degree. Inductive component according to claim 2 or 3, characterized in that a ratio of the resistance value of the metal strip ( 18 ) to the resistance value at 20 degrees Celsius between a temperature of the metal strip ( 18 ) changes from -40 degrees Celsius to 170 degrees Celsius by less than 0.3%, especially between a temperature of -40 degrees Celsius to 140 degrees Celsius by less than 0.1%. Inductive component according to at least one of the preceding claims, characterized in that the ferrite core ( 8th ) consists of a ferrite material containing manganese and zinc or nickel and zinc. Inductive component according to at least one of the preceding claims, characterized in that the ferrite core ( 8th ) of two, in particular substantially cuboid, elements ( 12 . 14 ), which are glued together. Inductive component according to claim 6, characterized in that at least one of the, in particular cuboid, elements ( 12 ) a groove ( 16 ), which in the connected state of the elements ( 12 . 14 ) forms a portion of the wall of the through hole. Inductive component according to claim 6 or 7, characterized in that between the two, in particular cuboid, elements ( 12 . 14 ) in the region of the splices each have a gap ( 20 . 22 ) with a predefined gap width, the gap ( 20 . 22 ) at least partially with adhesive ( 40 ) is filled out. Inductive component according to claim 8, characterized in that in each gap ( 20 . 22 ) a spacer, in particular an insulated or non-conductive wire ( 24 . 26 ) of predefined thickness. Inductive component according to at least one of the preceding claims, characterized in that the plate-shaped resistance element ( 42 ) and the connection elements ( 44 . 46 ) by means of a weld ( 48 . 50 ) are interconnected. Inductive component according to claim 10, characterized in that a width of the weld ( 48 . 50 ) is not greater than the material thickness of the resistive element ( 42 ). Inductive component according to claim 11, characterized in that a width of the weld ( 48 . 50 ) about one third of the material thickness of the resistive element ( 42 ) corresponds.

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