DE202015105768U1 - Inductive component for high current applications - Google Patents

Abstract

Inductive component for high-current applications with a winding (2) of a conductor wire (3) wound axially about a coil longitudinal axis (A) and with a height (HS) extending in the coil longitudinal direction (RA) and a diameter extending perpendicular to the coil longitudinal direction (RA) ( DS), characterized in that the height (HS) is smaller than the diameter (DS).

Description

The present invention relates to an inductive component for high-current applications having a winding of a conductor wire wound axially about a coil longitudinal axis and having a height extending in the coil longitudinal direction and a diameter extending perpendicular to the coil longitudinal direction.

Such inductive components may, for example, be throttles, which are used in particular in the range of high electrical currents. Exemplary fields of application are, for example, EMC applications for radio interference suppression, in DC / DC converters, for decoupling in HF and IF circuits, in safety systems, in automotive electronics or the like. The high currents through the inductive component can be greater than 20 A, but also reach up to 500 A and more.

In order to keep the ohmic losses and thus the heating low at such high electric currents, the ohmic resistance of the component must be small. This makes it necessary for inductive components for large currents to use large conductor cross sections. In particular, inductive components with a large inductance and a low DC resistance therefore require a large amount of space required.

In order to reduce at least the required height, the usual inductive components are therefore designed as horizontal arrangements. This means that the coil longitudinal axis extends in the horizontal direction parallel to a printed circuit board. Although then a low height is given, but then only a small diameter of the conductor of the device is possible, so that the length of the device is much larger than the diameter. In that regard, many turns and a long core are needed.

Although such inductive components have proven themselves in practice, it has been shown that due to the design of the inductive component, a large overall height is still required.

Against this background, the invention has the object to provide an inductive component available by means of which high electrical currents can be realized at the same time low overall height.

In an inductive component of the type mentioned, the object is achieved in that the height is smaller than the diameter.

By an inductive component, in which the height is smaller than the diameter, this can also be used in applications in which the space limited in height and the current load is high. In this way, inductive components with large inductances and a low DC resistance can be realized without having to provide for this large open spaces. Due to the larger diameter in relation to the height, the inductive component can nevertheless achieve high inductances with high current-carrying capacity. Further, at the same time, minimization of the resistance can be achieved by using a conductor having a large cross section.

In an advantageous embodiment, the diameter is greater than twice the height, in particular greater than three times the height and in particular greater than four times the height. By choosing a larger diameter in relation to the height of the inductive component, the height can be further reduced.

According to a structural embodiment, a vertical arrangement of the coil longitudinal axis is proposed on a printed circuit board on which the component can be arranged. In this case, the horizontal extent of the device is greater than the height. It is not necessary to provide many turns of the winding, since the diameter is relatively large. The component is realized with a few turns, in particular less than 10 turns, in order to keep the overall height low.

The inductive component forms an assembly with the printed circuit board.

In this context, it is particularly advantageous if the coil longitudinal axis is at an angle, in particular perpendicular, on the circuit board. Preferably, an angle between the coil longitudinal axis and the printed circuit board between 60 ° and 90 °, more preferably between 80 ° and 90 °. However, it is particularly preferred if the coil longitudinal axis is arranged perpendicular to the printed circuit board, that is at an angle of 90 °, on the printed circuit board. Instead of a printed circuit board, other reference surfaces can also be used.

It is preferred if the winding of the conductor wire is formed in one layer. In a single-layer configuration of the winding, the turns formed by the conductor wire extend adjacent in the coil longitudinal direction and are not arranged in a layered manner in the radial direction. By a single-layer winding, a small self-capacitance can be achieved, which is why corresponding inductive components are also suitable for very high frequencies. Air coils, which are wound in one layer, also have a particularly small parasitic Capacity, so that they can also be used for example in high-frequency circuits. They are also suitable for high voltages, as the insulation strengths between the turns add up. Inductive components with a single-layer winding can be used in particular for higher magnetization field strengths.

Advantageously, the winding of the conductor wire is designed as an air coil or wound around a coil extending in the coil longitudinal direction. Air coils may preferably be used for very high frequencies. In such air coils, the core of the inductor is free of ferromagnetic materials or the like. In this way, the onset of saturation and / or the occurrence of eddy current losses and hysteresis losses can be reduced.

However, since air coils require a larger number of turns than coils with a core to achieve the same inductance, the winding of the conductor wire may be wound around a core, such as iron or ferrite, for additional reduction in height. As a result, the ohmic resistance of the coil winding can be reduced.

In this context, it is particularly advantageous if the core is cylindrical and / or rod-shaped. In this way, a rod core coil can be realized with an open magnetic circuit, whereby a lower self-capacitance of the inductive component can be achieved. Particularly preferred is an embodiment of the core as a hollow cylindrical coil core, such as a pipe or the like. In this case, the hole in the hollow core can serve as a mechanical fastening possibility of the inductive component, in particular on a printed circuit board.

Preferably, the core consists of a magnetic, in particular a soft magnetic material. Particularly preferred is an inductive component in which the core is formed of a ferromagnetic material. In this way, the inductive component can be realized with fewer turns with the same inductance than is required in an air coil, since the magnetic field is amplified by the core. By means of a core of a magnetic, in particular soft magnetic and / or ferromagnetic material, eddy current losses can additionally be reduced. Such inductive components can then be used for very high frequencies.

A preferred embodiment provides that the height of the core is smaller than the diameter of the core. In particular, it is preferred if the diameter of the core is greater than twice the height, in particular greater than three times the height and in particular greater than four times the height of the core. The core may particularly preferably have a diameter which corresponds to the inner diameter of the winding of the conductor wire. In this way, the core can be arranged directly or only a small distance from the winding.

The core may have an external thread. This may be formed according to the shape of the coil. The external thread may be provided in the manufacture of the core or cut into the core. The core can then be screwed into the coil during manufacture. This can increase the stability. The coil and the core can be better connected together and the core can not fall out even if the connection fails. In addition, such a core can keep the individual turns of the coil at the desired distance. The turns can not slip during operation, so that heat dissipation properties are maintained.

The depth of the thread may be smaller than the width of the conductor to obtain the cooling property. The edges may be rounded to prevent damage to the coil's paint during installation. The flanks of the thread may be inclined to conform to the shape of the conductor or to compensate for tolerances. The thread may be continuous or have breaks, e.g. to allow surfaces for the ejector or injection points.

It is also possible that the height of the core corresponds to the height of the winding. In this case, the core does not protrude beyond the winding of the conductor wire so that there is no additional increase in the overall height. In this way, the height can be kept small.

According to a further advantageous embodiment of the invention, the conductor wire has a rectangular cross-section. The conductor wire may be particularly preferably formed as a flat ribbon wire. It is possible that the edges of the conductor wire are rounded. Preferably, the cross section can be made large, so as to obtain a lower resistance. So also large currents can be realized. The conductor wire should be made of a conductive material such as copper or aluminum or an aluminum alloy.

It is advantageous if the width of the conductor wire is greater than the height of the conductor wire. Preferably, the width can be at least two times, more preferably three times, and more preferably five times the height. It is also advantageous if the conductor wire with the smaller side surface, in particular with the height side, wound inwardly. In this way, the height of the inductive component can be further reduced, since there is a flat structure of the winding. Furthermore, a large surface is also advantageous for the cooling. A larger aspect ratio provides more surface area for the same cross section.

A further embodiment provides that the conductor wire for cooling has one or more profiles. The profiles are used to increase the surface. This is particularly advantageous when the coil is wound at a distance between the turns. The profiles can be formed, for example, in the form of rectangular, U-shaped or other recesses in the surface of the conductor wire. The profilings are preferably arranged on the larger sides of the conductor wire, in particular on the width side. The profilings can be arranged as required on one side or on two sides of the conductor wire. By such a profiling of the conductor wire, the surface can be increased, so that the heat generated by the current flowing in the conductor wire heat can be dissipated better.

It is further preferred if the conductor wire has insulation. The conductor wire can be provided for this purpose, for example, during the manufacturing process with an electrically insulating paint layer. The thickness and the weight of such a paint insulation can be very low compared to other insulating materials with the same effect. Depending on requirements, the choice of composition and choice of materials can provide the insulation with different thermal, mechanical and dielectric properties. As materials for the isolation, for example, polyesterimides, impregnating varnishes or the like can be used.

The current flow through the conductor wire can lead to a heating, which can cause damage to the inductive component by overheating. Due to this, it may be necessary to sufficiently cool the inductive component.

In a further development of the invention, it is therefore proposed that the windings of the winding are separated from each other for cooling by an air gap. Through the air gap between the windings, the air can flow between the windings. The turns of the winding can serve as cooling fins in this way. It is therefore not necessary, in addition to cool the inductive component by a separate heat sink. Also, this can be achieved a reduction in size. Alternatively, however, embodiments are also conceivable in which no gaps in the form of air gaps are provided between the turns of the winding. But then it may be useful to provide additional cooling of the device.

In this context, it is preferred if the windings of the winding extend at an angle to the coil longitudinal axis. By winding the individual turns of the winding with a pitch air gaps can be generated between the individual turns, so that the winding itself can act as a cooling element. Preferably, when the distance between the turns is less than twice the wire height in the axial direction, preferably smaller than the wire height in the axial direction.

A further embodiment provides that the winding is enclosed by a cooling medium. As the cooling media, for example, materials such as air, oil, water or the like can be used which are capable of sufficiently dissipating the heat.

For arranging the inductive component on a printed circuit board or the like, the ends of the conductor wire are advantageously designed as contact elements for connecting the component to the printed circuit board. The inductive component may preferably be an SMD component, which may be connected to the circuit board, for example by soldering. For this purpose, the ends of the conductor wire can preferably be designed as SMD contacts (surface-mounted device) or THT contacts (through-hole technology).

The invention further relates to an assembly with a printed circuit board on which the inventive inductive component of the described manner is arranged. Of course, other components can be arranged on the circuit board.

Further details and advantages of the invention will be explained below with reference to the embodiment shown in the drawings. Herein show:

1 a perspective view of a first embodiment of an inductive component,

2 a schematic plan view of a first embodiment of an inductive component,

3 a side view of a first embodiment of an inductive component,

4 a side view of a second embodiment of an inductive component and

5 a schematic sectional view of a conductor wire of an inductive component.

In the 1 is an inductive component 1 shown, which is formed in the embodiment as a ribbon inductor. Such inductive components 1 are particularly designed to be able to carry high electrical currents greater than 20 A.

Used are such inductive components 1 For high-current applications, such as for the radio interference suppression of small motors and electrical contacts, as well as for decoupling in electronic circuits. In addition, these inductive components 1 also be used in other areas, such as EMC applications or in DC / DC converters.

Like this the 1 shows, the inductive component extends 1 along a coil longitudinal axis A, which is preferably at an angle, in particular substantially perpendicular, on a printed circuit board or other reference surface, not shown. Such an arrangement of an inductive component 1 on a printed circuit board, not shown, of an assembly is usually referred to as a vertical arrangement.

The inductive component 1 has an axially winding about a coil longitudinal axis A, continuous winding 2 a conductor wire 3 on, which is formed in the present case as a ribbon wire winding. The individual turns 2.1 . 2.2 . 2.3 . 2.4 . 2.5 . 2.6 the winding 2 are arranged layered in the axial direction R _A. The winding 2 is also single-layered, that is, there is only one winding layer in the radial direction.

How this continues 1 can be seen and in addition also again in detail in the 5 is shown, the conductor wire 3 a rectangular cross section. In this case, the width B _{L of} the conductor wire 3 greater than the height H _{L of} the conductor wire 3 , In the embodiment, the edges of the conductor wire 3 rounded. However, this is not mandatory. However, there are advantages in the production of the conductor wire 3 or when using prefabricated wires 3 , The cross section of the conductor wire 3 has been chosen to be large, to the ohmic resistance of the inductive component 1 to reduce. In this way it is possible that even large currents can be realized. The conductor wire 3 is made of a conductive material, such as copper or aluminum.

The width B _{L of} the conductor wire 3 may be at least two times, more preferably three times, and most preferably five times the height H _L. Like this the 5 shows, in the embodiment, a ratio of the width B _L to the height H _L of about 3.5 is selected. The side surface of the conductor wire 3 which is smaller, in particular, the core 4 or the inside of the winding 2 to be facing. The height H _L then extends in the coil longitudinal direction R _A and the width B _L in the radial direction. In this way, a compact design of the inductive component 1 be achieved because of a flat structure of the winding 2 results.

The inductive component 1 has in the coil longitudinal direction R _A a defined height H _S and a perpendicular to the coil longitudinal direction R _A extending diameter D _S on. The height H _S is inventively smaller than the diameter D _S. This allows a low overall height can be achieved with high current carrying capacity. Such an inductive component 1 has a low DC resistance. The diameter D _S may in particular be greater than twice the height H _S and in particular greater than three times the height H _S and in particular greater than four times the height H _S.

In the first embodiment, the winding is 2 of the inductive component 1 around a coil in the longitudinal direction R _A extending cylindrical core 4 wound. Alternatively or additionally, the core 4 also be rod-shaped or formed as a hollow cylindrical spool core. Also other embodiments of the core 4 are conceivable.

The core 4 is preferably made of a magnetic, in particular a soft magnetic or ferromagnetic material. Becomes such a core 4 used, there is the advantage that the winding 2 much less turns 2.1 . 2.2 . 2.3 . 2.4 . 2.5 . 2.6 needed for the same inductance as air coils. However, the core can 4 saturated with strong currents, which can lead to distortion of the current flow and to a strong reduction of the inductance. However, eddy current losses can be reduced in this way, so that the inductive components 1 can also be used for very high frequencies. The core 4 can be one of the winding 2 have corresponding external thread.

Alternatively, the winding 2 of the ladder wire 3 be designed as an air coil. Air coils are inductive components 1 without a core 4 , Air coils have compared to inductive components 1 with core 4 relatively small inductances. Due to the lack of a magnetic core 4 the magnetization characteristic is linear and the coil 1 indicates as essential property, and unlike the coil 1 with magnetic core 4 , no magnetic saturation and less eddy current and hysteresis losses. Without a kernel 4 However, the magnetic flux can not be targeted, whereby the magnetic leakage flux is high. In addition, require air throttles 1 for the same inductance more turns than inductive components 1 with core 4 What the ohmic resistance of the winding 2 increased. Are air coils 1 Wrapped in one layer, they have a particularly small parasitic capacity. Such inductive components 1 are often used in high-frequency circuits.

Like this, for example 3 and 4 can be taken, the height H _{K of} the core 4 smaller than the diameter D _{K of} the core 4 , wherein the height H _K also the height H _{S of} the winding 2 equivalent. The core 4 does not protrude over the winding 2 addition, whereby the height can be kept small. The diameter D _{K of} the core 4 corresponds to the inner diameter of the winding 2 so that the conductor wire 3 right at the core 4 is present or only a small distance between the conductor wire 3 and the core 4 given is.

Due to the high current flow through the conductor wire 3 this is heated. Especially at high current densities and the so occurring heating is large. To damage the inductive component 1 By avoiding overheating, it makes sense to warm it. In particular, cooling methods are suitable for dissipating the resulting heat.

In the in the 4 illustrated second embodiment of the invention is therefore the winding 2 of the inductive component 1 wound with gradient. This means that the turns 2.1 . 2.2 . 2.3 . 2.4 . 2.5 . 2.6 the winding 2 spaced apart from each other and separated by an air gap. In this way it is possible that the winding 2 surrounding air between the turns 2.1 . 2.2 . 2.3 . 2.4 . 2.5 . 2.6 can flow through it. This is how the turns serve 2.1 . 2.2 . 2.3 . 2.4 . 2.5 . 2.6 even as cooling fins. The distance between the turns 2.1 . 2.2 . 2.3 . 2.4 . 2.5 . 2.6 is smaller than the wire height H _L.

The core 4 may have an external thread with a pitch that is the slope of the winding 2 equivalent.

The turns 2.1 . 2.2 . 2.3 . 2.4 . 2.5 . 2.6 the winding 2 run in particular at an angle to the coil longitudinal axis A and with respect to the horizontal reference surface. Instead of air, the winding can 2 are also enclosed by a cooling medium, such as oil, water or the like, which are adapted to dissipate the heat sufficiently.

Like this in the 3 The turns can be shown 2.1 . 2.2 . 2.3 . 2.4 . 2.5 . 2.6 the winding 2 even without spacing between the turns 2.1 . 2.2 . 2.3 . 2.4 . 2.5 . 2.6 be wrapped to a large ratio of turns 2.1 . 2.2 . 2.3 . 2.4 . 2.5 . 2.6 to reach construction height. In this case, it makes sense laterally on the inductive component 1 or in addition to this around a heat sink, for example, an aluminum profile with cooling fins to arrange. By convection or active ventilation, the air can then flow through the cooling fins and thus absorb the heat.

As additional cooling possibility, the conductor wire 3 profiles 7 have, as these suggestively in the representation in the 5 are shown. The profiles 7 are in the embodiment in the form of rectangular recesses in the surface of the conductor wire 3 realized. Alternatively, however, different recesses may also be used. The profiles 7 are on the larger sides of the ladder wire 3 arranged. In this way, the surface of the conductor wire 3 be enlarged, so that by the through the conductor wire 3 flow of electricity generated heat can be dissipated better.

For contacting the inductive component 1 with the circuit board can the ends 5 . 6 of the conductor wire 3 bent over, as for example the 1 shows. The ends 5 . 6 of the ladder wire 3 then serve as contact elements, such as SMD contacts, for connecting the device 1 with the circuit board. The contacts could also be designed as THT contacts. The inductive component 1 in the figures is formed as an SMD component, which can be connected by soldering or the like to the circuit board. This results in a component which can be equipped automatically and is also suitable for reflow and vapor phase soldering. The conductor wire 3 In this case, it may additionally have an insulation, for example in the form of an electrically insulating lacquer layer. In this way, the conductor wire 3 be equipped by choosing the composition and choice of materials of insulation with different thermal, mechanical and dielectric properties.

With an inductive component according to the invention 1 can be achieved by the fact that the height H _{S is} smaller than the diameter D _S , a compact design with low overall height with high current carrying capacity and heat dissipation.

LIST OF REFERENCE NUMBERS

1

inductive component

2

winding

2.1

convolution

2.2

convolution

2.3

convolution

2.4

convolution

2.5

convolution

2.6

convolution

3

conductor wire

4

core

5

contact element

6

contact element

7

profiling

A

coil longitudinal axis

B _L

Width of the conductor wire

D _K

core diameter

D _S

Diameter of the inductive component

H _K

Height of the core

H _L

Height of the conductor wire

H _S

Height of the inductive component

R _A

Coils longitudinally

Claims (15)

Inductive component for high-current applications with a coil winding axially around a coil longitudinal axis (A) ( 2 ) of a conductor wire ( 3 ) and with a in the coil longitudinal direction (R _A ) extending height (H _S ) and a perpendicular to the coil longitudinal direction (R _A ) extending diameter (D _S ), characterized in that the height (H _S ) is smaller than the diameter (D _S ) is. Inductive component according to Claim 1, characterized in that the diameter (D _S ) is greater than twice the height (H _S ), preferably greater than three times the height (H _S ), particularly preferably greater than four times the height (H _S ) , Inductive component according to one of the preceding claims, characterized by a vertical arrangement of the coil longitudinal axis (A) on a printed circuit board on which the component ( 1 ) can be arranged. Inductive component according to claim 3, characterized in that the coil longitudinal axis (A) is at an angle, in particular perpendicular, on the circuit board. Inductive component according to one of the preceding claims, characterized in that the winding ( 2 ) of the conductor wire ( 3 ) is formed in one layer. Inductive component according to one of the preceding claims, characterized in that the winding ( 2 ) of the conductor wire ( 3 ) is formed as an air-core coil or around a core extending in the coil longitudinal direction (R _A ) ( 4 ) is wound. Inductive component according to claim 6, characterized in that the core ( 4 ) has an external thread. Inductive component according to claim 6 or 7, characterized in that the height (H _K ) of the core ( 4 ) smaller than the diameter (D _K ) of the core ( 4 ). Inductive component according to one of the preceding claims, characterized in that the conductor wire ( 3 ) has a rectangular cross section, in particular with rounded edges. Inductive component according to claim 9, characterized in that the width (B _L ) of the conductor wire ( 3 ) is greater than the height (H _L ) of the conductor wire ( 3 ). Inductive component according to one of the preceding claims, characterized in that the conductor wire ( 3 ) one or more profiles ( 7 ) for cooling. Inductive component according to one of the preceding claims, characterized in that for cooling the turns ( 2.1 . 2.2 . 2.3 . 2.4 . 2.5 . 2.6 ) of the winding ( 2 ) are separated by an air gap. Inductive component according to one of the preceding claims, characterized in that the winding ( 2 ) is enclosed by a cooling medium. Inductive component according to one of the preceding claims, characterized in that the ends ( 5 . 6 ) of the conductor wire ( 3 ) are formed as contact elements for connecting the device to a printed circuit board. Assembly with a printed circuit board on which an inductive component ( 1 ) is arranged according to one of the preceding claims.

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