EP2489095A1 - Antenna coupler - Google Patents

Abstract

The invention relates an antenna coupler (1) for connecting a high-frequency antenna to a device to which a high voltage can be applied galvanically during operation, wherein a multi-layer circuit board (2) that has conductor planes that are electrically insulated from each other in the depth direction (z) of the multi-layer circuit board (2) is provided. A first high-frequency line (3a, 3b) coupled or to be coupled with the high-frequency antenna is arranged in a first conductor plane, while a second high-frequency line (4a, 4b) coupled or to be coupled on the device side is arranged in a second conductor plane of the multi-layer circuit board (2). The multi-layer circuit board (2) has an electrically insulating circuit board core layer (6), wherein the first and second conductor planes extend on the same of the two faces of the circuit board core layer (6), and wherein the second high-frequency line (4a, 4b) coupled or to be coupled on the device side is arranged at a larger distance from the circuit board core layer (6) than the first high-frequency line (3a, 3b), and furthermore the second high-frequency line (4a, 4b) is arranged on an outer surface of the multi-layer circuit board (2). The antenna coupler (1) comprises an electrically conductive shielding structure (5), which extends partially on the opposite other of the two faces of the circuit board core layer (6) and is designed to shield the first high-frequency line (3a, 3b) and metal parts on the device side that are not part of the antenna coupler (1) from an interaction while high-frequency signals are conducted.

Description

 antenna

 FIELD OF THE INVENTION

 The present invention relates to the field of radio frequency line technology; It relates to an antenna coupler for connecting a high-frequency antenna according to the preamble of claim 1.

BACKGROUND OF THE INVENTION

 In many technical devices that contain a high-frequency transmitter or receiver and at the same time are galvanically exposed to an earth-related high voltage (mains voltage), an antenna is to be connected via a coaxial cable. The corresponding antenna and the coaxial cable must be galvanically isolated from the device, otherwise there is danger to life when touched.

The problem has been solved for example by two parallel arranged dipole antennas in the device, in which, however, by the unwanted radial radiation, a high transmission loss of at least 6dB for the useful signal. The decoupled power was fed into a coaxial cable to be routed to a remote antenna.

A known decoupling via capacitors (US4987391) has either a low withstand voltage (1 kV) or a high transmission loss, since high capacitance of the capacitors requires a large design, which has a negative effect on the damping due to high inductive reactance and unwanted radiation.

CONFIRMATION COPY It is known from document US7545243 that line structures are suitable for galvanic decoupling. However, a disadvantage of this known solution is also the low dielectric strength.

PRESENTATION OF THE INVENTION

 It is therefore an object of the invention to further develop an antenna coupler for connecting a high-frequency antenna to the effect, wherein the above-mentioned disadvantages can be solved.

The object underlying the invention is achieved by the totality of the features of claim 1. Further embodiments are the subject of the dependent claims 2 to 10.

The antenna coupler according to the invention for the galvanic separation of the antenna from the transmitter / receiver achieves a high insulation voltage of up to 1 2kV DC and AC line voltage, but at the same time also an extremely low transmission loss for the radio frequency useful signal. The antenna coupler according to the invention can achieve a particularly low transmission loss within desired frequency limits, since the coupling lines, so the first and second high-frequency line, can be arranged with a very small distance from each other in the depth direction of the multilayer printed circuit board. The commonly used layer thickness of the multilayer printed circuit board can be used as the distance between the coupling lines. A distance of 0.3 mm, for example, can be realized.

There is a large usable high-frequency bandwidth can be more than one octave, for example, from 800 MHz to 2200 MHz. It can be produced inexpensively by using multilayer printed circuit boards, for example 2-fold or 4-fold multilayer printed circuit boards. The antenna coupler is thus preferably designed as a multilayer printed circuit board. The coupler is formed of two appropriately coupled high frequency lines. The geometric arrangement of the metal surfaces (in particular copper surfaces) of the high-frequency lines forms the coupler. The distances between the copper surfaces and the electrically insulating carrier material of the multilayer printed circuit board provide the necessary insulation voltage strength.

In the present case, the high-frequency lines are two coplanar lines which are embedded in two different layers of the multilayer printed circuit board one above the other. These lines preferably each consist of at least one strip line for the inner conductor and at least two strip lines for the outer conductor.

These two times three conductors are selected in a preferred embodiment in the distance and in the width of the lines so that the resulting line has a characteristic impedance of 50 ohms. This allows a shock-free and thus low-loss forwarding of high-frequency power from the coaxial cable to the transmitter / receiver inside the device.

The thickness of the dielectric (dielectric material) is preferably selected such that a voltage resistance required in the respective application is achieved.

In preferred embodiments, the terminals of the coplanar leads to the surface of the circuit board hold a required for the desired dielectric strength leakage current path. For this purpose, in one embodiment, located in the inner layer of the circuit board (typically antenna side) coplanar line beyond the coupling zone with changed geometry, eg changed conductor width and / or conductor distances extended before contacting the surface is made. The preferred embodiment of the inventive antenna coupler is designed as a one-sided shielded coupling structure. The device-side coplanar line is supplemented by an additional shielding surface connected to PCB vias. The shielding surface is preferably arranged so that they co-conductor with the stripe of the device-side coplanar line, the coaxial line, so antenna-side coplanar partially sheathed. In this way, at least the screen side is less sensitive to interference from metal parts inside the device.

To achieve a high dielectric strength is suitable as insulating support material of the multilayer printed circuit board, for example, the known material FR-4, a glass fiber reinforced, epoxide-based material having a dielectric strength of more than 30kV / mm.

It is necessary to ensure sufficiently large leakage current paths on the surface of the printed circuit board between the galvanically isolated parts. For a dielectric strength of 1 2kV, for example, a creepage distance of just over 10mm is needed.

The antenna coupler according to the invention will be described below with reference to the figures. Only a section of the antenna coupler, namely the coupling region in the multilayer printed circuit board is shown in each case.

BRIEF DESCRIPTION OF THE FIGURES

The invention will be explained in more detail with reference to embodiments in conjunction with the drawings. The following color coding of the illustrated structural elements is used in the figures: Light blue: air

Orange-red and yellow-green: metal surfaces of strip lines. Dark blue and dark green sections at ends of strip lines (center conductors) are to be read as orange-red sections, so to understand as integral parts of the respective stripline, and have these structural elements, despite their different colors no deviating from an orange-red or yellow-green color meaning.

Darkgreen: Dielectric layer insulation

Light green: cover insulation or core layer (core) of the multilayer PCB. Show it:

1 is a perspective view of an antenna coupler according to the present invention having two coplanar lines spaced apart from each other by a layer isolation on one side of a circuit board core layer and having an electrically conductive shield structure extending in part on the opposite other of the two sides of the circuit core layer to shield the first radio-frequency line and device-side metal parts, which are not part of the antenna coupler, from interference in the conduction of radio-frequency signals; enlarged perspective view of a device-side end portion of the antenna coupler according to FIG. 1; enlarged perspective view of the opposite antenna-side end portion of the antenna coupler according to Fig. 1; Fig. 4 sectional view of the input-side portion -shown: yz-plane of the

Antenna coupler; and a

Fig. 5 further sectional view-shown: xz-plane of the antenna coupler.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

 1 shows a perspective view of an antenna coupler 1 according to the invention with two coplanar lines 3a, 3b, 4a, 4b spaced apart from each other by a layer insulation 1 3. Since the one first coplanar line 3a, 3b is consequently concealed by the second coplanar line 4a, 4b in this illustration, FIG. 4 is to be used for the arrangement of the two coplanar lines 3a, 3b, 4a, 4b with respect to one another.

The coplanar lines 3a, 3b, 4a, 4b are disposed on one side of a circuit board core layer 6 and shielded with an electrically conductive shielding structure 5, this shielding structure 5 extending in part on the opposite one of the two sides of the circuit board core layer 6 and formed so that the first high-frequency line 3a, 3b and not shown here, device-side metal parts that are not part of the Antennenkopplers, do not interact in the conduction of high-frequency signals.

In Fig. 1, both coplanar lines 3a are in the y-direction of the illustrated coordinate system. 3b, 4a, 4b respectively in the sequence outer conductor 3b, 4b- inner conductor 3a, 4a-outer conductor 3b, 4b arranged. In the z-direction of the coordinate system follow one another metal surface or screen surface 9 - an intermediate layer of dielectric material 8 - antenna side, (first) coplanar 3a, 3b - layer insulation 1 3 - device side (second) coplanar 4a, 4b. The coplanar lines 3a, 3b, 4a, 4b extend parallel to one another in the longitudinal direction x in the multilayer printed circuit board (2); Apart from short antenna-side and device-side longitudinal sections (strip lines 10a, 10b, IIa, IIb), the coplanar lines 3a, 3b, 4a, 4b completely overlap in the longitudinal direction and completely overlap in their transverse direction y perpendicular to the longitudinal direction x.

As an example of mass for the embodiment of the inventive antenna coupler shown here, the following values are helpful, whereby the values of the width given here in the y direction are to be considered, the length values in the x direction and the thickness values in the z direction:

- Wide inner conductor 3a, 4a: 3mm

 - Wide outer conductor 3b, 4b: 2mm

 Length of coplanar lines 3a, 3b, 4a, 4b: 25mm

 - Thick layer insulation 1 3: 0.3mm

Relative permittivity of the layer insulation 1 3: ε _Γ = 4.5

 - lateral distance inner conductors 3a, 4a and outer conductors 3b, 4b: 1, 2mm

Strip lines 10a, 10b are likewise visible in FIG. 1, which project in the longitudinal direction x of the first coplanar line or the first high-frequency line 3a, 3b via the second coplanar line or second high-frequency line 4a, 4b for connection to a coaxial line, not shown here, to an antenna ; in the following synopsis with Fig. 3, this fact becomes even clearer.

7, air is shown in FIG. 1 as the medium surrounding the antenna coupler 1; In addition to insulating properties, the air has no other function.

FIG. 2 shows an enlarged perspective view of a device-side end section of the antenna coupler according to FIG. 1. Here it becomes clear that the second high-frequency line 4a, 4b with strip lines II a, 1 lb projecting in the x-direction over the first high-frequency line 3a, 3b for the purpose of connection to a device not shown here closer.

As already indicated for Fig. 1, Fig. 3 shows an enlarged perspective view of the antenna-side end portion of the antenna coupler with the strip lines 10a, 10b to the first high-frequency line 3a, 3b.

FIG. 4 shows in a sectional view to the yz plane visible, as the second high-frequency line 4a, 4b with its outer conductor 4b, but not with its inner conductor 4a, electrically conductive through the PCB core layer 6 with the metal surface 9 on the opposite other the two sides of the PCB core layer 6 is connected for the purpose of shielding. Another sectional view in FIG. 5 shows the xz-plane of the antenna coupler. It becomes clear that a large number of connections or printed circuit board plated-through holes 1 2 hold the outer conductor 4 b with the metal surface 9 at the same potential.

Of course, the invention presented here is not limited to the embodiments shown; Without departing from the spirit of the invention, the second high-frequency line 4a, 4b can of course also be coupled on the antenna side, while the first high-frequency line 3a, 3b can be coupled on the device side.

LIST OF REFERENCE NUMBERS

1 antenna coupler

 2 multi-layer printed circuit board

 3a, 3b first radio-frequency line with inner conductor and outer conductor, first coplanar line

 4a, 4b second high-frequency line with inner conductor and outer conductor second Koplanarleitung

 5 shielding structure

 6 PCB core layer

 7 air

 8 dielectric material

 9 metal surface, screen surface

10a, 10b stiffening line to 3a, 3b

I I a, I I b stripline to 4a, 4b

 1 2 Connection, printed circuit board vias

 1 3 layer insulation

Claims

1 antenna coupler (1) for connecting a high-frequency antenna to a galvanic in operation with a high voltage acted upon device, comprising

 a multilayer printed circuit board (2) having conductor planes electrically insulated from each other in the depth direction (z) of the multilayer printed circuit board (2),

 at least one first radio-frequency line (3a, 3b) to be coupled or coupled to the radio-frequency antenna in a first conductor plane,

 at least one second high-frequency line (4a, 4b) to be coupled or coupled to the device in a second conductor plane of the multi-layer printed circuit board (2), characterized in that

 the multilayer printed circuit board (2) has an electrically insulating printed circuit board core layer (6),

 the first and second conductor planes extend on the same of the two sides of the circuit board core layer (6),

 wherein the device side to be coupled or coupled second

 High-frequency line (4a, 4b) is arranged at a greater distance from the circuit board core layer (6) than the first high-frequency line (3a, 3b),

 - Wherein the second high frequency line (4a, 4b) on an outer surface of the

 Multilayer printed circuit board (2) is arranged

 and wherein said antenna coupler (1) has an electrically conductive shielding structure (5) extending in part on the opposite one of the two sides of the circuit board core layer (6) and being formed, the first one

 High frequency line (3a, 3b) and device-side metal parts, which are not part of the antenna coupler (1), against an interaction in the line of

Shield high-frequency signals. Antenna coupler (1) according to claim 1, characterized in that the first and second high-frequency line (3a, 3b, 4a, 4b) in the multilayer printed circuit board (2) in the longitudinal direction (x) of the first and second high-frequency line (3a, 3b, 4a, 4b ) parallel to each other.

Antenna coupler (1) according to claim 1 or 2, characterized in that the high-frequency lines (3a, 3b, 4a, 4b) - apart from short antennseitigen- and device-side longitudinal sections of the high-frequency lines (3a, 3b, 4a, 4b) - in the longitudinal direction completely cover.

Antenna coupler (1) according to one of the preceding claims, characterized

in that the spaced-apart high-frequency lines (3a, 3b, 4a, 4b) completely cover one another in their transverse direction (y) perpendicular to the longitudinal direction.

Antenna coupler (1) according to one of the preceding claims, characterized

characterized in that the high-frequency lines (3a, 3b, 4a, 4b) as

Coplanar lines are formed.

Antenna coupler (1) according to one of the preceding claims, characterized

in that the shielding structure (5) has a metal surface (9) which partially encloses the first high-frequency line (3a, 3b).

Antenna coupler (1) according to one of the preceding claims, characterized

characterized in that in each conductor plane at least one strip line (10a, 1 l a) for coupling to an antenna-side or device-side inner conductor and at least two strip lines (1 Ob, I I b) for coupling to a

antenna-side or device-side outer conductor have. Antenna coupler (1) according to claim 7, wherein the strip lines (10a, 10b, 1 la, 1 1 b) of the first and second high frequency lines (3a, 3b, 4a, 4b) a respective lateral, ie perpendicular to the longitudinal direction (x) of Strip lines (10a, 10b, 1 la,

1 1 b) distance to be measured from one another in the relevant plane of the ladder, and a respective width to be measured in the relevant plane of the ladder in the lateral direction (y), which, in combination, has a characteristic impedance of the relevant

High frequency line of 50 ohms effect. Antenna coupler (1) according to claim 6 or 7, wherein the second

High frequency line with its outer conductor (4b), but not with its inner conductor (4a), electrically conductive through the PCB core layer (6) through with the metal surface (9) on the opposite other of the two sides of the

PCB core layer (6) is connected. Antenna coupler (1) according to one of the preceding claims, characterized

characterized in that it has a dielectric strength of up to 1 2 kV between the first and second conductor level.