EP2274755A1

EP2274755A1 - Coil arrangement

Info

Publication number: EP2274755A1
Application number: EP09729991A
Authority: EP
Inventors: Andreas SCHÖNECKER; Detlef H. Schenk
Original assignee: Hydrotech International Ltd; Fraunhofer Gesellschaft zur Forderung der Angewandten Forschung eV
Current assignee: Hydrotech International Ltd; Fraunhofer Gesellschaft zur Forderung der Angewandten Forschung eV
Priority date: 2008-04-08
Filing date: 2009-04-08
Publication date: 2011-01-19
Also published as: DE102008017762A1; WO2009124783A1

Abstract

The invention relates to a coil arrangement (9) for generating magnetic alternating fields, having at least two conductor loops (1, 2) that are associated with each other and are galvancially isolated, but capacitatively coupled. The first conductor loop (1) has a connection (3) for the power supply, and the second conductor loop (2) has a connection (4) for the power discharge. The ends of the associated conductor loops (1, 2) opposite the connections are open. Preferably, the coil arrangement (9) is configured in a planar design.

Description

coil assembly

Current-carrying conductors are accompanied by a magnetic field. The arrangement is known as a coil, which results from repeated winding of individual conductor loops. The generated magnetic flux density B is of the geometric structure of the coil, ie their windungszahldichte n = N / l (N-turn number, 1 - length or height of the coil), the magnetic properties of the filler (permeability μ ₀ μ _r ) _/ and the Current I given,

B = μ _o μ _r - In

Structural designs of magnetic coils in wire winding technology as well as in planar technology are known. The dimensioning equations are known from the specialist literature, for example the inductance L for the planar coils shown in FIG. 8 is proportional to the square of the number of turns, L = C n "

where c represents a constant describing the geometry and magnetic properties of the filler.

The connection of the coils to an external voltage source happens at both ends of the windings. Possible layouts for planar coils are shown in Figures 9 and 10. The lead out of the inner conductor is complex and prone to failure in a planar design. Connection via a bonding wire (FIG. 9) requires additional technological effort. Bridge pressure (Figure 10) requires an additional insulating layer.

Coils are operated in a known manner with DC and AC. When using an electrical see alternating field results from the coil inductance L of the known constructions an inductive reactance X _L , whose size increases linearly with the frequency.

X _L = jU) -L

with U) - angular frequency, L - inductance of the coil, j - imaginary unit

For a given drive voltage, the current is therefore reduced. As a result, the generated magnetic induction B decreases.

The decrease in magnetic induction with increasing frequency at a given voltage is a general disadvantage of known magnetic coils. The invention has for its object to provide a coil assembly which has a high efficiency and high magnetic induction at the desired frequency use and generates a sufficiently large magnetic field even at high frequencies (> 1 kHZ). Furthermore, it is necessary to specify designs which can be realized in planar technology in a simple manner.

The invention relates to an arrangement of magnetic coils of increased effectiveness. According to the invention, at least two mutually associated conductor loops are designed as double conductors, which are galvanically separated from one another, but are capacitively coupled according to their arrangement, ie between the first and second conductor loops of the associated conductor loops, which are arranged alternately to one another or nested generates an electric field. The current is coupled in a conductor loop and coupled out of the other associated conductor loop, wherein the ends of the conductor loops, which have no connections for the coupling or decoupling, are open or formed as a free end. Under "open" is understood that the ends are not connected to electrical components, terminals or electronic lines, but the turns or conductor loops open ends. This arrangement has a natural resonant frequency at which the reactance largely disappears and the total resistance reaches a minimum, which is determined by the ohmic resistance of the conductor loops. At a given voltage, the current reaches a maximum value. Accordingly, the generated magnetic field strength also becomes maximum. Preferably, therefore, is an operating point At approximately a phase angle of about φ = O ° strive, but also an operating frequency above the resonant frequency, for example up to twice the resonant frequency and about φ = 30 ° makes sense.

The technical implementation can be carried out in an advantageous manner by applying technologies of construction and connection technology, polymer electronics and ceramic multilayer technology.

According to the invention, the magnet coil arrangement is designed in planar design on a plane in concentric arrangement of the associated conductor loops or double conductors and / or of a plurality of superimposed planes in each case in superposition of the conductor loops or double conductors. In this case, several associated conductor loops can be provided concentrically and alternately to each other in the respective levels. The conductor loops are separated by a dielectric. The respectively assigned conductor loops are embodied in an electrically insulated manner by the substrate material and / or the dielectric both in the single-plane arrangement and in the stack arrangement of the planes, wherein the associated conductor loops, which of course can also have several turns, can be formed as separate magnetic coils being stacked. Due to the concentric and / or superimposed, preferably congruent superimposed arrangement of the associated conductor loops takes place a superposition and thus an amplification of the individual magnetic fields.

Preferably, the conductor loops are arranged around a core of magnetic material, wherein the material ferrite but also polymer-bound magnetic Materials can be. In this case, a high permeability should be selected and the dielectric should have a high dielectric constant. This facilitates, among other things, miniaturization.

In a preferred embodiment, for use as a current and voltage converter, transformer or transformer two arrangements of at least two associated conductor loops, each with a connection for the power supply or for

Stromabfuhr and two open ends associated with each other but not connected to each other, wherein between the respective terminals of the arrangements, a first voltage can be applied and a second voltage is removable. In this case, the associated conductor loops of the two arrangements have different turns corresponding to the desired transmission ratio.

Embodiments of the invention described above are explained below with reference to the figures. Show it:

1 shows a magnetic coil arrangement according to a first embodiment on a plane in a plan view,

2 shows the magnet coil arrangement on a plane corresponding to FIG. 1 in a side view, FIG.

3 shows a magnetic coil arrangement according to a second exemplary embodiment on a plane with multiple or multiple printed conductors in a plan view,

4 shows the magnetic coil arrangement according to FIG. 3 a plane with multiple or multiple tracks in a side view,

5 shows a side view of a magnet coil arrangement according to a third exemplary embodiment with several levels, where on one level only the conductor tracks 1 and 2 are located and they are through-contacted from plane to plane.

6 shows the magnetic coil arrangement according to FIG. 5 with several levels in a perspective and schematic top view, FIG.

7 shows a coil arrangement current and voltage transformers, each with two associated conductor loops in a perspective plan view,

8 planar coils in rectangular (a) and circular spiral form (b) according to the prior art,

Fig. 9 contacting the inner conductor of a coil by bonding according to the prior art, and

Fig. 10 contacting the inner conductor of a coil with Brückenisolierschicht according to the prior art.

In the Fign. 1 and 2, a solenoid assembly in planar design is shown in plan view. The magnetic coil arrangement consists in the embodiment of two associated conductor loops 1 and 2, which are each connected to a terminal pad 3 and 4 for coupling or decoupling an electric current. The conductor loops 1 and 2 form a double conductor or double conductor tracks. They are applied to an insulating substrate 5 by known planar techniques. The conductor loops 1, 2 are completely covered with a capacitive layer or a dielectric 6. As can be seen from FIG. 1, the ends of the conductor loops which are not connected to the connection pads 3, 4 are open, ie they end without any further connection possibility.

Centered is a ferrite core 7. The core may also be made of other suitable materials capable of establishing a magnetic field and operating in each frequency range.

In Fig. 2, the coil assembly of FIG. 1 is shown in section.

FIG. 3 shows in FIG. 1, wherein the magnetic coil arrangement is designed in a concentric configuration, ie the double conductors consisting of the mutually associated conductor loops 1 and 2 are connected in parallel to conductor loops 1 'and 2' and executed radially alternately. The arrangement is exemplary. Depending on the defined magnetic power further double conductors with the conductor loops 1, 2, I ¹ , 2 ', as described above, placed on one and the same plane, wherein the terminal ends are connected in parallel with the connection pads 3, 4. In each case between the interconnects is the capacitive layer, ie the dielectric 6, preferably the interconnects 1, 2, I ¹ , 2 ¹ , as can be seen in the section of FIG. 4, completely embedded in the dielectric.

In the Fign. 5 and 6 is an embodiment of this in which the coil assembly of FIG. 1 is used. Several coil arrangements or units 9 according to FIGS. 1 and 2 are stacked or stacked in different planes, on which the double conductors with the conductor loops 1, 2, which are separated by the dielectric and optionally a capacitive layer 8, are located. The various coil units 9 can also be provided at a distance (instead of the layer 8) from one another, but they can also lie directly above one another. The

Connections of the associated conductor loops 1, 2 via the connection pads 3, 4 are also in each case parallel to each other, via which the circuit is closed. The number of levels depends on the defined magnetic field strength, which must be generated for each application. FIG. 6 shows a greater distance between the coil arrangements 9, this being provided only for clarity of drawing, the coil units can be stacked one above the other with and without spacings.

The magnetic coil arrangement consists, as already stated, of a double conductor with the arranged conductor loop 1 and 2 (FIG. 1, 2) or a plurality of double conductors, the conductor loops each being connected to the same terminal polarity (FIGS. 3, 4). The conductor loops 1, 2 are separated from each other by the capacitive layer or the dielectric. Between the conductor loops 1, 2 with different polarity of the current flows at low frequency to high frequency, depending on the specified application. The number of associated conductor loops 1, 2, which can also be implemented in several turns, depends on the application case and the target value of the magnetic induction. The Arrangement of the conductor tracks according to FIG. 4 takes place parallel to the surface in succession on a plane, specifically in such a way that a conductor loop is electrically separated from one another by an insulating substrate and / or a dielectric layer.

For the Fign. 1 to 6, the current input coupling and current output coupling are respectively connected to the first and the second of the associated conductor leads 1 and 2, but all the first conductor loops and all the second conductor loops are viewed from the phase terminal in the concentric magnet coil arrangement and in FIG the multilayer magnet coil assembly connected in parallel.

In Fig. 7, a current and voltage converter 10 is shown with the previously described magnetic coil assemblies in the same arrangement as Figs. 1 to 6, but with the proviso that there is no via between the levels.

The solenoid assembly 1 of the lower level shows the current input Ul and II, wherein the associated conductor loops 1, 2 are also separated from each other galvanically and capacitively.

Via the magnet coil arrangement 12 of the second, ie the output plane, which is not directly connected to the first plane by a through-connection, but only via the electrical fields that build up, the output with voltage U 2 and current 12 is connected to the technical connections. The current and voltage conversion is realized in the capacitive range, ie the electrical resistances (reactances) are also very low. There are no ne electrical components such as capacitors, resistors and wire coils in the conventional sense needed. The input level can be provided in accordance with the technical and / or electrical specifications with a plurality of double conductors, which in turn are connected in parallel with each other. The same applies to the magnet coil arrangement 12 of the second level. In the illustrated embodiment, the transmission ratio is 1: 1 because the first and second level arrangements are identical. Depending on the desired transmission ratio, the number of associated conductor loops and / or the turns of the associated conductor loops of the magnet coil assemblies 11 and 12 are selected differently.

The magnet coil arrangement according to the invention can be used in a wide variety of fields, for example for mini-motors, miniature electromagnets, drive systems and acoustic converters and their use in nanoelectronics and microelectronics. Furthermore, it can be used as a magnetic field source, as a filter and sensors and used in ceramic multilayer technology and polymer electronics.

example

A magnet coil according to the invention is produced in a two-level arrangement. The two levels are separated by a dielectric layer. First, a planar coil of right-handed Cu shape is deposited on an aluminum support substrate by screen printing and subsequent burn-in. The spiral is provided at one end with a connection pad for further contacting. A dielectric paste is printed on the Cu rectangular spiral and then baked. In the following manufacturing step a second Cu rectangular coil is applied to the dielectric layer by screen printing and firing. This also has a connection pad. This second rectangular spiral coil is congruent with the first rectangular spiral coil, with the exception of the connection pads, which remain exposed for soldering the leads exposed.

The geometric data as well as the properties of the magnetic coil are summarized in Table 1 for a coil of the geometry according to FIG. 8a. For comparison, the properties of a coil with identical geometry without dielectric interlayer and contacted at the two ends of the conductor loop, in conventional mode, indicated.

geometry data

Electrical characteristics of the coil

Table 1

In the coil according to the invention flows at the operating frequency 177 kHz and a drive voltage of 1 V, a current of 0.3 A. This value is greater by a factor of 10 compared to a coil of the same geometry according to the prior art. Thus, according to the invention, at the same time a higher by a factor of 10 magnetic induction can be achieved.

Claims

claims

1. coil arrangement for generating alternating magnetic fields with at least two mutually associated conductor loops, which are galvanically isolated, but capacitively coupled, wherein the first

Conductor loop a connection for the power supply and the second conductor loop has a connection for the power drain and each of the terminals opposite ends are open.

2. coil assembly according to claim 1, characterized in that the associated conductor loops are arranged around a core of magnetic material around.

3. coil arrangement according to claim 1 or claim 2, characterized in that the associated conductor loops are applied side by side or one above the other on a substrate carrier as conductor tracks.

4. coil arrangement according to one of claims 1 to

3, characterized in that a plurality of pairs of associated first and second conductor loops are provided, wherein the respective first conductor loops are connected to the connection for the power supply and the respective second conductor loops to the connection for the current drain.

5. coil assembly according to claim 4, characterized in that the conductor loops are arranged concentrically with each other, wherein the first and second conductor loops of the pairs are alternately to each other.

6. coil assembly according to claim 4 or claim 5, characterized in that the conductor loops are arranged one above the other and the first and second conductor loops of the pairs are alternately to each other.

7. coil arrangement according to one of claims 1 to

6, characterized in that between and / or on the conductor loops, a dielectric is provided.

8. coil arrangement according to one of claims 1 to

7, characterized in that the associated conductor loops have a plurality of turns, which are preferably covered by a dielectric and / or separated by a dielectric.

9. coil arrangement according to one of claims 3 to

8, characterized in that the substrate carrier is designed as a ceramic carrier.

10. coil arrangement according to one of claims 3 to

9, characterized in that the conductor loops are made of copper, silver and / or aluminum in pure metal form or as an alloy.

11. Coil arrangement according to one of claims 1 to

10, produced in multi-layer technology.

12. Coil arrangement according to one of claims 1 to 10, manufactured in printed circuit board technology

13. coil arrangement according to one of claims 7 to

12, characterized in that the dielectric is formed as a dielectric ceramic layer and / or as a dielectric layer of polymer-bonded capacitor materials.

14. Coil arrangement according to one of claims 1 to

13, characterized in that at least two arrays of associated conductor loops each having a connection for the power supply and a connection for the power drain and two open ends are associated with each other and between the respective terminals of the arrangements, a first voltage can be applied and a second voltage is removable.

15. Coil arrangement according to one of claims 1 to

14, characterized in that the at least two conductor loops, the core and the dielectric are designed and selected so that at a predetermined frequency of reactance is largely compensated.