EP0540899A1 - UHF Yagi antenna - Google Patents

Abstract

The director elements and/or the dipole consist(s) of conductor tracks which are printed onto a dielectric board (1). A UHF amplifier circuit is fitted in the immediate vicinity of these conductor tracks, on the same circuit board (1), so that the entire arrangement is of compact construction and has good electrical characteristics as a result of the relatively short connecting paths between the antenna and the amplifier circuit. <IMAGE>

Description

The invention relates to a UHF-Yagi antenna consisting of director elements, a reflector and a Cipol.

A Yagi antenna is already known from German Offenlegungsschrift No. 21 38 384, the known antenna being implemented in the manner of printed circuit technology and in particular in stripline technology.

A room antenna for different frequency ranges is already known from German Offenlegungsschrift No. 24 53 164 and from the catalog "Kathrein receive antenna 1990", (page 29, antenna BZX 20).
This antenna is used to receive UHF and VHF, the UHF antenna being designed as a Yagi antenna. In the lower part of the antenna housing, a dielectric circuit board is arranged, which receives an amplifier, switches and other electronic components. The amplifier is thus separated from the Yagi antenna by a distance that corresponds to the height of the standpipe of the Yagi antenna.

A miniature television antenna is already known from German Offenlegungsschrift No. 2 146 182 (corresponding to US Patent 3, 707, 681). This known antenna has a first insulating substrate (11) on which the electrical components of the antenna are printed and a second insulating substrate (77) on which the components of the amplifier (40) are attached.

The insulating substrate (77) with the components of the amplifier is held by a holder arm (76) which rigidly attaches the amplifier circuit to the lower housing part (62). The antenna and amplifier are therefore not arranged on the same substrate (circuit board); rather, in the vicinity of the substrate (11) on which the electrical components of the antenna are printed, the substrate (77 is fastened via the holding arm 76), the substrates (11) and (77) being separated from one another by a space. These constructive measures are apparently aimed at electromagnetically decoupling the antenna and amplifier. Electromagnetic decoupling proves to be critical, especially with Yagi antennas, because of the possible interaction between amplifier and antenna reflector.
This arrangement known from German Offenlegungsschrift No. 2 146 182 is initially associated with the disadvantage that two different substrates, namely the substrate (11) for the actual antenna and the substrate (77) for the amplifier circuit, are used. This means that the manufacture of the antenna and amplifier (including the preparation of the substrates, printing of the conductor tracks, drilling of contact holes, assembly with components) must be provided for two substrates, that is to say separately from one another. This means a comparatively large amount of work.
In addition, a separate attachment of the substrate 77 (by means of the holder arm 76) is to be provided in this known antenna.

The invention lies opposite this prior art Task based on specifying a UHF Yagi antenna that enables a more compact structure.

The object of the invention is achieved with the features of patent claim 1.

The antenna according to the invention has a number of advantages. First of all, only one circuit board is provided, on which both the conductor tracks forming the antenna and the amplifier circuit are arranged. This has the further advantage of simpler manufacture of the antenna and substrate. For example, the conductor tracks for the antenna and amplifier can be applied to the circuit board in the same steps.

The need to fix a second substrate for the amplifier in relation to the first substrate for the antenna is eliminated.

In addition, the length of the connecting path between the antenna and amplifier can also be made shorter in the antenna according to the invention than, for example, in the arrangement known from German Offenlegungsschrift No. 2 146 182, whereby improved electrical properties are also achieved. In particular, almost the maximum energy absorbed by the antenna is used. Mismatches and switch-on or fade-in losses are avoided, which result when using a longer connection between antenna and amplifier.

The antenna according to the invention with the integrated amplifier circuit has a gain of 31 ± 2 dB.

Another advantageous embodiment is that the circuit board is arranged in a housing and that the housing receives an antenna for receiving VHF signals, so that the reception of UHF and VHF signals is made possible with a single device.

This antenna for receiving VHF signals can consist of two rods which can be inserted into two openings arranged in the housing; this adds a VHF antenna to the existing UHF antenna. The latter antenna is installed by simply inserting the rods into openings in the housing and can be carried out by the consumer without the need for any additional assembly tools.

It is also provided that a second VHF amplifier is arranged on the circuit board, so that the circuit board assumes an additional function, namely to accommodate the second amplifier circuit.

It should be noted that in the antenna according to the invention, the amplifiers for the UHF and VHF antennas are arranged in the immediate vicinity of the respective antenna, so that neither a cable for connecting the VHF amplifier and the VHF antenna nor a cable for connection of UHF antenna and UHF amplifier is required.

With regard to the electromagnetic decoupling of amplifier and antenna, it proves advantageous that the first and / or second amplifier circuit has coils, at least some of which are implemented in printed circuit technology.

It also proves advantageous with regard to the electromagnetic decoupling of amplifier and antenna that a metallic ground layer with a large area related to this area is arranged on the circuit board in the area of the first amplifier circuit.

An antenna according to the invention, in which the circuit board can be rotated, enables the antenna to be perfectly aligned in the directions of the signals to be received.

Another embodiment of the antenna according to the invention, in which the first and second amplifier circuits are followed by a mixer circuit which mixes UHF and VHF signals, is distinguished by the advantage that the UHF and VHF signals are provided in mixed form at the output thereof, whereby only one cable has to be provided for both the UHF antenna and the VHF antenna.

In this connection, the mixer circuit can be arranged on the circuit board, with which the advantages mentioned of reducing the dimensions of the overall arrangement and simplifying its assembly can be achieved to a greater extent.

Significant advantages are achieved with an antenna in which the circuits arranged on the circuit board are at least partially implemented in stripline technology and / or in SMD technology. This facilitates the manufacture of the overall arrangement from antenna and associated electronic circuits, by printing the conductor tracks of the antenna and simultaneously printing the circuit structure of the circuits in a single process.

The advantage of a larger antenna gain is obtained if the reflector consists of a double, metallic rod which forms a plane which is arranged approximately at right angles to the circuit board.

Figur 1

einen Schnitt durch die in einem Gehäuse angeordnete erfindungsgemäße Antenne,

Figur 2

die Antenne in Verbindung mit einer ersten Verstärkerschaltung,

Figur 3

eine Ausgangsauswahlschaltung und eine Speiseschaltung für die erfindungsgemäße Antenne,

Figur 4

eine perspektivische Ansicht einer möglichen Gestaltung des Antennenreflektors,

Figur 5

die Ausgestaltung eines Teils der Schaltungsplatte im Bereich der Verstärkerschaltung(en) auf der den Verstärkerbauelementen bzw. den Antennenleiterbahnen zugewandten Seite der Schaltungsplatte,

Figur 6

die Ausgestaltung dieses Teils der Schaltungsplatte auf der den Verstärkerbauelementen bzw. den Antennenleiterbahnen abgewandten Seite der Schaltungsplatte,

Figur 7

ein System zur Anschaltung der VHF-Antenne, und

Figur 8

die perspektivische Darstellung der erfindungsgemäßen Antenne mit einer weiteren Ausführungsform des Reflektors.

The invention is described below by way of example with reference to the drawings.
It shows

Figure 1

2 shows a section through the antenna according to the invention arranged in a housing,

Figure 2

the antenna in connection with a first amplifier circuit,

Figure 3

an output selection circuit and a feed circuit for the antenna according to the invention,

Figure 4

1 shows a perspective view of a possible design of the antenna reflector,

Figure 5

the design of part of the circuit board in the area of the amplifier circuit (s) on the side of the circuit board facing the amplifier components or the antenna conductor tracks,

Figure 6

the configuration of this part of the circuit board on the amplifier components or the antenna conductor tracks opposite side of the circuit board,

Figure 7

a system for connecting the VHF antenna, and

Figure 8

the perspective view of the antenna according to the invention with a further embodiment of the reflector.

FIG. 1 shows the position of a dielectric plate or circuit board 1 within a housing 2. The dielectric plate is in an inclined position of 2 degrees with respect to the horizontal plane defined by the foot part 21 of the housing 2. Director elements and the dipole of a UHF-Yagi antenna are arranged on the plate 1.
The director elements and / or the dipole are formed by conductor tracks 11 which are printed on the plate 1.
The plate 1 with the conductor tracks 11 either faces the upper part 22 of the housing 2 or the lower part 21 of the housing 2. In FIG. 1, the first three conductor tracks 111, 112 and 113 form the director elements and the two following conductor tracks 114 and 115 form the dipole.
The reflector of the antenna is formed by a metal band 12 which is arranged in a plane perpendicular to the plane in which the conductor tracks 111, 112, 113, 114 and 115 are arranged.

The reflector can also be formed by a conductor track which is printed on the plate 1 (FIG. 2). At least one UHF amplifier circuit is arranged between the printed conductor tracks 11 and the reflector 12, as will be described with reference to FIG. 2.

The housing 2 consists of a lower part 21 and an upper part 22. The shape of the housing 2 is slightly curved. Both parts 21 and 22 of the housing have mechanical connecting elements such as, for example, fastening pins, which enable the housing to be opened and closed easily.

The plate 1 can be rotated in a plane parallel to the antenna base. The housing 2 can be connected to a carrier system 3, which is formed, for example, by a ball socket, the upper edge 31 of which is inserted into a circular groove 221 which is arranged in the lower part 21 of the housing 2 and which rotates with respect to the fixed carrier 3 allowed.

The housing 2 is fastened to the carrier 3 by means of a screw which is inserted into an opening 32 in the base of the carrier 3, engages in a thread in a tube 212 arranged in the part 21 of the housing and extends up to within the carrier 3 whose lower base extends.
In the upper part 22 of the housing 2 there are two openings 221 into which a VHF antenna can be inserted. This consists of two rods, for example telescopic rods, which are described with reference to FIG. 7.

The entire supply system can be arranged in the carrier 3, while a first amplifier circuit and optionally a second amplifier circuit are arranged on the plate 1 (FIG. 2).

Figure 2 shows a schematic representation of the antenna and the associated electronic circuits. It should be noted that Figure 2 does not show the actual dimensions. In the specific embodiment, the electronic circuit arrangements shown in FIG. 2 are at least partially implemented in microstrip technology and / or in SMD (Surface Mounting Devices) technology, so that the dimensions can be reduced very much, with an area of 75 mm in the specific embodiment x 35 mm is claimed.

The conductor tracks 111, 112, 113 and 114 have a width of approximately 3.5 mm; the conductor track 115 has a width of approximately 5 mm. The conductor track 111 has a length of approximately 107 mm; Conductors 112 and 113 have a length of approximately 122 mm and conductors 114 and 115 have a length of approximately 92 mm and 76 mm, respectively.
The approximate distances between the conductor tracks are as follows: the distance between the conductor tracks 111 and 112 is approximately 35 mm, the distance between the conductor tracks 112 and 113 is 16 mm and the distance between the conductor tracks 113 and 114 is 35 mm. The angle between tracks 114 and 115 is approximately 20 degrees.

The reflector 12 has a parabolic shape and consists either of a conductor track which is arranged on the plate 1 (FIG. 1) or of a metal strip 12 which is in a plane perpendicular to the plane of the conductor tracks 111, 112, 113, 114, 115 is arranged.

The conductor track has a width of approximately 3.5 mm, while the metal strip has an approximate height of 10 mm and a thickness of 0.4 mm. The length of the reflector (points E and F) is approximately 280 mm.

The distance between the center of the dipole (conductor tracks 114, 115, point C) and the vertex of the parabola of the reflector (point D) is approximately 80 mm.
The conductor tracks are made of copper, which is printed on a plate made of fiberglass.
Another embodiment of the reflector is shown in FIG.

FIG. 2 shows a first amplifier circuit which amplifies the UHF signals received by the antenna.

At the input of this amplifier, which is directly connected to the antenna (point G), a bandpass filter is arranged, which for example consists of the capacitors C23, C24, C25, C26 and C27 with 18 pF, 470pF, 1pF, 33 pF and 2.7 pF and coils L1 and L3 with 20 nH and 18 nH. This bandpass filter matches the impedance of the UHF antenna to the impedance of the first stage of the first amplifier circuit.
The antenna impedance is approximately 300 ohms.

The first amplifier consists of two transistors T1 (type NE68133 NEC) and T2 (type BFR 93A Philips). These transistors form two stages, which are matched and tuned to one another in a frequency range from 470 to 860 MHz, and cause an increase in the gain within the desired frequency band (470-860 MHz), whereby the signals are suppressed outside the frequency band.

The first stage of the UHF amplifier is not powered with the aim of not degrading the noise characteristic, which noise characteristic is less than 2 dB. The second stage of the UHF amplifier, on the other hand, is fed in order to compensate for the difference in gain as a function of the frequency generated in the first stage.
This achieves a flat characteristic in the entire useful frequency range (470 - 860 MHz).

The first amplifier circuit consists, for example, of the following components: a circuit for polarizing the transistor T1, which consists of the resistors R10, R14 and R15 with 560 ohms, 37 kiloohms and 3.3 kilohms, from a circuit for polarizing the transistor T2, which consists of resistors R7, R8, R9 and R12 with the values 470 ohms, 470 ohms, 18 kilohms and 10 kilohms; from a feedback circuit to transistor T2, which consists of resistors R11 and R13 with the values 220 ohms and 15 ohms and from capacitors C14 and C17 with 22 pF and 470 pF, from high-pass filters consisting of capacitor C9 and the coil L8 with 180 pF or 11nH, consists of the capacitor C13 and the coil L7 with 4.7 pF or 10 nH and finally a high-pass filter which is formed from the capacitor C21 and the coil L5 of 10 pF or 6 nH; a low-pass filter, formed from the capacitor C18 and the coils L4 and L6 with 1.5 pF or 10 nH each; from between the steps switched coupling capacitor C19 with 100 pF and the supply decoupling capacitor C15 with 470 pF.

The first (UHF) amplifier has the following properties: Profit 24 ± 2 dB Noise characteristic 2 dB Loss of feedback 9.5 dB V out 105 dBuV (DIN 450043)

FIG. 2 also shows a second amplifier circuit which amplifies the VHF signals received by the VHF antenna (FIG. 7).
At the input of this amplifier, which is connected directly to the VHF antenna (point I), there is a notch filter that blocks FM signals (87-108 MHz) and a low pass. The notch filter consists of the capacitors C29, C22, C30, C31 and C32 with the values 3.9 pF, 15 pF, 120 pF, 120 pF and 1.5 pF and the low-pass filter consists of the coil L2 with 32 nH and the capacitor C33 at 8.2 pF.
This low-pass filter enables the impedance of the VHF antenna to be matched to the impedance of the second amplifier.
The impedance of the VHF antenna is approximately 300 ohms.

The second amplifier consists of a transistor T3 (type BFR93A Philips). This transistor is fed back in order to obtain a flat characteristic in the frequency range of 47-230 MHz.

The second amplifier circuit consists of the following components: a polarization circuit consisting of resistors R4, R16, R2 and R1 with 470 ohms, 470 ohms, 22 kilohms and 10 kilohms, a feedback circuit consisting of resistors R3, R5 and R6 with 2.2 kilohms, 47 ohms and 10 ohms, and from the capacitors C2, C3 and C4 with 470 pF, 270 pF and 680 pF and from a high-pass filter consisting of the capacitor C6 with 34 pF.

The second (VHF) amplifier has the following properties: Profit 18 ± 1 dB Noise characteristic 2 dB Loss of feedback 9.5 dB V out 100 dBuV (DIN 450043)

FIG. 2 also shows a VHF / UHF mixer circuit which consists of two printed filters, a high pass at the output of the UHF amplifier (point J), consisting of the capacitors C10 and C11 with 3.3 pF and 4.7 pF and from the coil L9 with 6 nH and from a low pass at the output of the VHF amplifier (point K), consisting of the coils L11 and L10 with 22 nH each and from the capacitors C5, C7, C28 with 18 pF, 22 pF and 1.8 pF.

The output of the mixing circuit (point L) is connected to a low-loss cable (not shown in FIG. 2), via which the VHF and UHF signals are routed to an output selection circuit which is arranged inside the carrier 3 (FIG. 1) is. The VHF and UHF amplifiers are also supplied via this cable.

In Figure 2, a Balum or symmetry circuit is also shown, which consists of a coil L1.
This circuit simulates a transmission path of λ / 2 and transforms the symmetrical impedance of the dipole into the asymmetrical impedance inherent in the first amplifier. The circuit is made of printed copper on the plate of the UHF antenna itself and implemented together with the other circuits (amplifier, mixer circuit) between the dipole and the reflector of the antenna. It has an impedance transformation ratio of 1/4.

The input point 0 of the first amplifier (base of the transistor T1) is arranged in the immediate vicinity of the point G of the output of the UHF antenna. This distance depends only on the geometric dimensions of the possible electronic components that are connected between the points G and O. In the present embodiment, this distance depends on the dimensions of the capacitors C26 and C24 and the coil L2. In the specific embodiment, the capacitors are implemented using SMD technology and the inductance L2 is printed on the circuit board in such a way that the geometric dimensions of the overall arrangement (C26, C24, L2) are reduced to a few millimeters.

In the antenna according to the invention, the first amplifier circuit and the arrangement of the other electronic circuits (second amplifier, mixed circuit, balun switch) are arranged between the dipole (conductor tracks 114, 115) and the reflector 12.

This reduces the dimensions of the overall arrangement comprising the antenna and electronic circuits and the housing. Likewise, the electrical properties of the overall arrangement of antenna and electronic circuits are improved by the spatial proximity of electronic circuits and antenna and the correspondingly short connection path. Amplifier and reflector are electromagnetically decoupled in the arrangement structure described.

FIG. 3 shows an output selection switch and a power supply part. Both are arranged inside the carrier 3 (Figure 1). Both circuits as well as the carrier 3 are merely additional elements in one embodiment of the invention.
The output selection switch consists of a switch INT, with which the signals are carried out, which are supplied by the UHF and VHF antennas (point L), and the signals which come from a possible external antenna (point M) via a in the carrier 3 (Figure 1) arranged connecting element, are supplied.
The output selection circuit includes diodes D2, D3, D4 and D5, each type 1N4148. By means of the switch INT in the "Y" position, the diodes D2, D4 and D5 are turned on, while the diode D3 is blocked. In this switching situation, the signal at the "RF out" output (point N) is that coming from the indoor antenna (point L). In the switch position "Z" of the switch, the diodes D2, D4 and D5 are blocked, while the diode D3 conducts. In this switching situation, the signal at the "F out" output (point N) is that coming from the external antenna (point M).

The connection to a terminal (television set) is established via the "RF out" output (point N).

The power supply source consists of a transformer TRF 137218, a diode bridge PD (diodes type B125) and capacitors C1, C2, C3, C4 and C5 with the values 47 nF, 47 nF, 1000 uF, 47 nF and 47 nF and through the diode D1 (type IN4001). The power supply source has an input for 220 volts AC or 12 volts DC.

This feed source feeds the electronic circuits shown in FIG. 2. From point L (FIG. 2) to point L (FIG. 3) the supply takes place by means of a connecting cable not shown in the figures. In particular, the same connecting cable is used for this purpose, which is used for the transmission of the VHF-UHF signals coming from point L (FIG. 2).

In Figure 4, the plate 1 with the printed conductor tracks 11, 112, 113, 114 and 115 is shown in perspective. The figure also shows the configuration of the reflector 12, which in the present embodiment consists of the metallic tape which is arranged in a plane perpendicular to the plane which has the conductor tracks 111, 112, 113, 114 and 115.

FIGS. 5 and 6 show configurations of the circuit board (1) in the area of the electronic circuits, in particular the amplifier, in FIG. 5 this area of the circuit board on the side facing the components or the antenna conductor tracks (= side of the circuit board which is used in the Figure 1 Embodiment shown facing the lower housing part 21) is shown and in FIG. 6 this area of the circuit board on the side facing the components or the antenna conductor tracks (= side of the circuit board which in the embodiment shown in FIG. 1 faces the upper housing part 22) ) is shown.
The side of the circuit board 1 shown in FIG. 5 is connected to the lower housing part 21 (FIG. 1) and the side of the circuit board 1 shown in FIG. 6 is connected to the upper housing part 22 (FIG. 1).
The black area shown in FIGS. 5 and 6 represents the relatively large areal design of the mass (Ms) with respect to the dimensions of the circuit board. The part of the circuit board shown in FIGS. 5 and 6 has, for example, an area of 75 mm × as already described 35 mm. This configuration of the grounding mass (Ms) helps to keep the impedance between the different ground points (FIG. 2) of the circuits essentially constant with regard to the frequency range used. By avoiding currents induced via the mass, the risk of oscillations of the amplifier or amplifiers arranged between the dipole and the reflector is reduced.

In addition, the coils L1-L12 (cf. also FIG. 2) are shown in FIG. 5, which are implemented in printed circuit technology. These coils realized in the plane of the circuit board generate an electromagnetic field arranged in such a way as to the reflector, which leads to an electromagnetic decoupling of the amplifier and reflector contributes and reduces the risk of oscillations of the amplifier.

This danger is further exacerbated by the filters already described with reference to FIG. 2 (C23, C24, C26, C27, L1, L3; C9, L8, C13, L7, C21, L5, C18, L4, L6) and the realization of the coils ( L1, L3; L4, L6) reduced.

FIG. 7 shows a possible system for the plug-in connection with the VHF antenna consisting of two telescopic rods.

In the circuit board 1 in point I and in a point connected to ground there is an opening and on the underside of the plate 1 there are screw nuts 13. The rods are inserted through the openings 221 of the housing 2 (Figure 1), run in the openings of the circuit board 1 and are screwed to the nuts 13 which are arranged for this purpose.

In this way, the assembly of the VHF antenna is reduced to the simple insertion of the rods into the housing openings and can be carried out by the consumer without the need for knowledge and assembly tools.

FIG. 8 shows a further embodiment of the antenna according to the invention. This also consists of director elements 109A, 110A, 111A, 112A, 113A, a reflector 12A and a dipole 114A, 115A.
As in the embodiment described with reference to FIG. 4, the director elements consist of those shown in FIG Embodiment of conductor tracks 109A, 110A, 111A, 112A, 113A, which are printed on a circuit board 1A. The dipole of this embodiment consists of both traces 114A printed on the circuit board 1A and a metallic bar 115A arranged in a plane perpendicular to the plane of the circuit board 1A with the dipole traces. This metallic rod 115A is bent by approximately 90 degrees at its end regions and is connected to the dipole conductor tracks 114A at points D '.

The reflector consists of a double metal rod 12A, which is arranged in a plane perpendicular to the plane of the circuit board 1A. This reflector fulfills a double function; it forms the reflector of the UHF antenna and at the same time the dipole of the VHF antenna. A UHF amplifier is in turn arranged on the circuit board 1A between the dipole and the reflector. A VHF amplifier is also located on the circuit board 1A and connected to the reflector 12A at points G '. With this arrangement, the UHF reflector also takes on the function of the VHF dipole.

Claims (10)

UHF-Yagi antenna, consisting of director elements (111, 112, 113), reflector (12) and dipole (114, 115), the director elements (111, 112, 113) and the dipole (114, 115) made of conductor tracks ( 11, 111, 112, 113, 114, 115), which are printed on a dielectric circuit board (1), and wherein a first amplifier circuit (UHF) is connected to the conductor tracks (11, 111, 112, 113, 114, 115) is
characterized by
that the first amplifier circuit (UHF) and the conductor tracks (11) on the same circuit board (1) are arranged in close proximity to one another and that the first amplifier circuit (UHF) is arranged between the Cipol (114, 115) and the reflector (12). Antenna according to claim 1,
characterized by
that a second amplifier circuit (VHF) for amplifying VHF signals is arranged on the circuit board (1). Antenna according to claim 1 or 2,
characterized by
that the first and / or second amplifier circuit (UHF, VHF) has coils (L1, .., L12), at least some of which are implemented in printed circuit technology. Antenna according to one of claims 1 to 3,
characterized by
that on the circuit board (1) in the area of the first amplifier circuit a metallic ground layer (Ms) is arranged with a large area related to this area. Antenna according to one of the preceding claims,
characterized by
that the circuit board (1) is arranged in a housing (2) and that the housing (2) receives an antenna for receiving VHF signals. Antenna according to claim 5,
characterized by
that the antenna for receiving the VHF signals consists of two rods which can be inserted into two openings arranged in the housing (2). Antenna according to one of the preceding claims,
characterized by
that the circuit board (1) is movably mounted in the housing (2). Antenna according to one of claims 2 to 7,
characterized by
that the first and second amplifier circuit (UHF, VHF) is followed by a mixer circuit which can be arranged on the circuit board (1) and which mixes the UHF and VHF signals. Antenna according to one of the preceding claims,
characterized by
that the circuits arranged on the circuit board (1) are at least partially implemented in strip line technology and / or in SMD technology. Antenna according to one of the preceding claims,
characterized by
that the reflector (12) from a conductor track, from a metal strip which is arranged in a plane which is perpendicular to the plane in which the conductor tracks (11, 111, 112, 113, 114, 115) are arranged, or from a double metal rod (115A), which forms a plane which is arranged approximately at right angles to the circuit board (1).

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