EP1329005A1 - Surge protection filter and lightning conductor system - Google Patents

Abstract

The system ( 1 ) is installed in a coaxial line for the transmission of high-frequency signals. It serves for the purpose of protecting apparatus or installations against electromagnetic pulses, overvoltages and/or lightning strokes. The system ( 1 ) comprises shortcircuit lines ( 5, 6 ), which are disposed approximately parallel to the inner conductor ( 3 ) of the coaxial line. This disposition makes possible to develop the housing ( 2 ) of the system ( 1 ) concentrically to the longitudinal axis ( 9 ) and the housing ( 2 ) has no projecting elements.

Description

Interference protection filter and lightning current arrester device

The invention relates to a noise protection filter and lightning current arrester device in a coaxial line for transmitting high-frequency signals, comprising a housing with two connectors, the housing forming an outer conductor connected to ground, an inner conductor guided through the housing and a short-circuit connection between the inner conductor and the housing.

Noise filter and lightning arrester devices of this type are known. They are used to assemble assemblies, devices or systems that are connected to cables, e.g. To protect coaxial lines of telecommunication devices against electromagnetic impulses, overvoltages and / or lightning currents. Artificial electromagnetic pulses can be generated, for example, by motors, switches, clocked power supplies or also in connection with nuclear events, and pulses of natural origin can arise, for example, as a result of direct or indirect lightning strikes. The known protective circuits are arranged on the input side of the assemblies, devices or systems, which can be dissipative or reflective systems.

An EMP arrester of this type is known from EP 938 166. This EMP arrester has a housing which serves as an outer conductor and is connected to the ground. An inner conductor is guided in a first part of this housing, which runs in the direction of the insertion axis of a coaxial cable. A λ / 4 short-circuit conductor is arranged in a second housing part, which projects at a right angle from the first housing part, and connects the inner conductor to the housing. binds. With this known T arrangement, very good protection of the connected devices, assemblies or systems can already be achieved with suitable, known geometric arrangements and configurations. EMP arresters of this type must comply with international standards and, for example, meet the test conditions in accordance with the IEC standard. In spite of the good effectiveness per se, arresters of this type have the disadvantage that a residual pulse and thus also a residual energy is released via the inner conductor to the connected assemblies, devices or systems. Another disadvantage is that the housing part, which is arranged at right angles to the inner conductor and which receives the λ / 4 arrester, is relatively large and leads to a bulky size of these arresters. The installation of such arresters often presents considerable difficulties due to the λ / 4 component protruding at right angles, and corresponding distances between adjacent components must also be maintained. This type of construction can also not be covered with a shrink tube against environmental influences, but is wrapped in practice with corrosion protection tapes. This causes higher costs.

It is therefore an object of the present invention to provide a noise protection filter and lightning current arrester device in which the remaining residual pulses and residual energies are additionally reduced, the housing does not have any additional components protruding at right angles, and the entire device is to be compact and largely axially symmetrical ,

This object is achieved by the features defined in the characterizing part of patent claim 1. Advantageous developments of the invention result from the features of the dependent claims.

In the solution or device according to the invention, the longitudinal axis of the inner conductor and the longitudinal axis of the short-circuit connection between the inner conductor and the housing are arranged approximately parallel to one another. At the same time, the longitudinal axes of the inner conductor and the short-circuit connection run approximately parallel to the longitudinal axis of the device or the housing. All essential Components of the device are arranged around the longitudinal axis of the housing in such a way that the housing can be formed concentrically to the longitudinal axis. This arrangement leads to a compact cylindrical configuration of the device, in which the input and output for the cables or the corresponding connectors lie on the same axis and this coincides with the longitudinal axis of the device. The arrangement of two mutually directed short-circuit lines, which form the short-circuit connection between the inner conductor and the outer conductor, results in further advantages. If interference pulses, which are caused by a lightning strike or another electromagnetic event, are diverted to ground via the two short-circuit lines directed towards each other, the voltages generated in the process are partially canceled out by induction. The consequence of this is that the residual pulses and the residual energies which occur at the outlet of the device are considerably reduced. Comparative measurements compared to a traditional device with a λ / 4 arrester protruding at a right angle for the same power range show that in the solution according to the invention the residual voltage pulse can be reduced by a factor of 4 and the residual energy by a factor of 30, for example. These factors can vary within a wide range depending on the design and material selection of the individual components, but in any case there is a significant reduction in the residual pulse and the residual energy.

Further advantages of the solution according to the invention result from the fact that the two short-circuit lines do not have the length of normal λ / 4 arresters, but rather, due to the arrangement according to the invention and the design of the connection areas between the inner conductor and the two short-circuit lines at their outer ends, the geometric length the short-circuit lines can be shortened. So-called electrically extended λ / 4 short-circuit lines are formed. In an equivalent circuit diagram, each short-circuit line has a capacitance and an inductance, which act in parallel. This configuration results in a broadband range of action for the device, for example for high-frequency signals in the range from 1.7 to 2.5 GHz. adjustments Other frequency ranges are possible in a wide range by changing the capacitances and inductances on the inner conductor and on the short-circuit lines in a manner known per se. By installing an additional high-pass filter in the inner conductor, on the connection side to the device part, the already considerably reduced residual energy can be reduced even further. The considerable reduction in the residual pulse due to the solution according to the invention makes it possible to dispense with the fine protection circuits that are necessary in other known solutions.

In addition to the compact and concentric design, the solution according to the invention enables the installation of additional pulse-diverting elements between the mutually directed ends of the short-circuit lines and the housing. Gas discharge arresters or varistors or diodes, for example, can be used as additional pulse-diverting elements, these elements being decoupled in the operating frequency range of the device. This arrangement enables the transmission of supply voltages. The device can thus also be used for RF decoupling of corresponding additional pulse-diverting elements without the intermodulation behavior being impaired.

The invention is explained in more detail below on the basis of exemplary embodiments with reference to the accompanying drawings. Show it:

1 shows a longitudinal section through a device according to the invention, FIG. 2 shows a cross section along the line I-I in FIG. 1, FIG. 3 shows a cross section along the line II-II in FIG. 1

4 shows an equivalent circuit diagram for the device according to FIG. 1

5 shows an equivalent circuit diagram for a device according to FIG. 1 with an additional high-pass filter, and FIG. 6 shows an equivalent circuit diagram for a device according to FIG. 1 with an additional high-pass filter and an additional diverting element and a DC feed. Fig. 1 shows a longitudinal section through an interference filter and lightning current arrester device 1 according to the invention with connectors 7, 8 on both sides for coaxial cables. The coaxial cable is not shown and is used, for example, as a connection between an antenna and a transceiver with corresponding devices. The connectors 7, 8 are known, partially standardized components and have both on the input side 19 and on the output side 18 connecting elements, on the one hand the inner conductor of the cable via elements 21 to the inner conductor 3 of the device 1 and on the other hand the outer conductor of the cable to be connected to the housing 2 via a mechanical connection 22. The housing 2 forms the outer conductor 4 of the device 1. The connecting elements 21 are both arranged on the longitudinal axis 9 of the device 1 or of the housing 2 and are supported in the housing 2 by means of insulator disks 23. An inner part 24 of the connecting elements 21 is electrically conductive, for example by screwing, soldering or crimping, each with a washer 25, 26. These disks 25, 26 are formed from an electrically conductive material, in particular metal, for example from brass. These two disks 25, 26 are arranged at a distance from one another in the direction of the longitudinal axis 9 of the housing 2 and form connecting points 12, 13 between the inner conductor 3 and two short-circuit conductors 5, 6. The inner conductor 3 is parallel to the longitudinal axis 9 of the housing 2 and at a distance arranged to this. In the example shown, the entire inner conductor of the device 1 consists of the connecting elements 21, parts of the disks 25 and 26, and the inner conductor 3. The inner conductor has different geometric deviations over its length, as a result of which different reactance values, inductances and capacitances are formed. the. The two short-circuit conductors 5, 6 are also arranged approximately parallel to and at a distance from the longitudinal axis 9 of the housing 2. The outer ends 10, 11 of these two short-circuit conductors 5, 6 are connected to the inner conductor 3 and to connecting elements 21 via the disks 25, 26. The inner ends 14, 15 of the two short-circuit conductors 5, 6 are directed towards one another and are connected to the housing 2 in an electrically conductive manner via a contact part 16. In the example shown, the two short-circuit conductors 5 and 6 and the contact part 16 are formed in one piece. The two short-circuit conductors 5, 6 and the associated Parts of the disks 25, 26 form the short-circuit connection between the inner conductor 3 and the housing 2. In a manner known per se, the frequency range and the bandwidth to the desired application range of the device can be determined by adapting the geometric dimensions of these elements and the choice of the dielectric 20 become. To improve the electrical property, the inner conductor 3 and the short-circuit conductor 5, 6 are at least partially surrounded by an insulation body 27. Air is present as a dielectric in partial areas between the housing 2 and the inner conductor 3, or the short-circuit conductors 5, 6 and the disks 25, 26. The housing 2 is equipped with a flange 28 and a screw connection 29 so that it can be inserted and fastened, for example, through a bushing in an electrically conductive device wall. The impulses are then diverted via this electrically conductive device wall against equipotential bonding.

FIG. 2 shows a cross section through the device 1 along the line I-I in FIG. 1. The disc 26 can be seen in which the inner part 24 of the connecting element 21 is inserted centrally and connected to it. Moved outwards, the outer end 11 of the short-circuit conductor 6 and the region 13 of the inner conductor 3 are also connected to the disk 26. The disk 26 is surrounded concentrically by the housing 2 and between the disk 26 and the housing 2 there is the dielectric 20, air in this area.

3 shows a further cross section through the device 1, specifically along the line II-II in FIG. 1. The inner conductor 3 and the short-circuit conductor 6 can be seen, which run approximately parallel to one another and parallel to the longitudinal axis 9. Both the inner conductor 3 and the short-circuit conductor 5, 6 are embedded in the dielectric 20, which is formed in this area by the insulation body 27 and is made, for example, of the material Teflon.

The interference protection filter and lightning current arrester device according to the invention, as shown and described as an example in FIGS. 1-3, has compact and minimal structural dimensions. It enables a high packing density the lines, and no protruding components are necessary. The housing 2 and thus the entire device 1 can be cylindrical and can therefore be inserted into round bores, and no orientation of the position has to be taken into account. Adjacent cable entries can be arranged close together without elements of the individual devices 1 interfering with one another or without damage. This design can be easily protected against environmental influences with a shrink tube. At the same time, the device 1 according to the invention has significantly reduced residual pulses and residual energies. If the noise protection filter and lightning current arrester device 1 shown as an example is subjected to a standardized surge current with a waveform of 8/20 μs, a voltage residual pulse of approximately 16 V and approx. 13 μJ remains at 25 kA. If a conventional device with a right-angled λ / 4 short-circuit conductor for the same frequency band is subjected to the same test, this conventional device has a residual voltage pulse of 70 V and approx. 430 μJ at 25 kA. At the same time, the device 1 according to the invention and shown as an example is designed broadband for a frequency range from 1.7 to 2.5 GHz. This broadband design can be used in the entire application range from approximately 400 MHz to the upper cut-off frequency of the connector. The outer diameter of the housing 2 of the example shown with these connectors is 29 mm and the total length of the device 1 via these connecting elements 21 is approximately 72 mm. Depending on the area of application and the connectors, or the high-frequency range to be transmitted, the dimensions change accordingly.

FIG. 4 shows an equivalent circuit diagram of the radio-frequency device 1 according to FIG. 1. The inner conductor 3 and the outer conductor 4 extend between the input side 19 and the output side 18. The input or output side 19, 18 is defined in accordance with the direction of the pulse , ie the input side 19 is directed, for example, against the antenna and the output side 18 against the device to be protected. The main path formed by the inner conductor 3 comprises a capacitance 30, an inductance 32, a capacitance 34, a Inductance 33 and a further capacitance 31. These have different reactance values. The short-circuit conductors 5, 6 are each represented in the equivalent circuit diagram by an inductor 35 and a capacitor 36 connected in parallel. The outer conductor 4 or the housing 2 is grounded.

FIG. 5 shows the same equivalent circuit diagram as in FIG. 4, but a capacitance 37 is additionally formed in front of the output 18 of the main strand or the inner conductor 3. This capacitance 37 forms a high-pass filter in a manner known per se and serves to further reduce the residual energies.

6 shows an equivalent circuit diagram for a device 1 according to the invention, in which a direct current feed 38 is provided. In addition to the replacement elements described for FIGS. 4 and 5, this arrangement has an additional pulse-deflecting element 39 and a further capacitance 40. A gas discharge arrester, a varistor or a diode can be used as an additional pulse-diverting element 39. This dissipative element 39 is connected between the output side 14, 15 of the short-circuit conductor 5 and 6 and the outer conductor 4, or the housing 2. This additional arrester device 39 is decoupled in the transferable frequency range.

The discrete replacement components shown in FIGS. 4 to 6 in the equivalent circuit diagrams can actually be present or are realized by different line lengths and impedances, as shown in the example according to FIG. 1.

Claims

1. interference filter and lightning current arrester device (1) in a coaxial line for the transmission of high-frequency signals, comprising a housing (2) with two connectors (7, 8), the housing (2) forming an outer conductor (4) connected to ground, an inner conductor (3) guided through the housing (2) and a short-circuit connection (5, 6) between inner conductor (3) and housing (2), characterized in that the short-circuit connection consists of two short-circuit lines (5, 6), which are approximately par - Allel to the inner conductor (3) are arranged, one end (10, 11) of these two

Short-circuit lines (5, 6) are connected to the inner conductor (3) at two spaced-apart areas (12, 13) and the two other ends (14, 15) of the two short-circuit lines (5, 6) are directed towards each other and via connecting elements ( 16, 17) are connected to the housing (2).

2. Interference filter and lightning current arrester device according to claim 1, characterized in that each short-circuit line (5, 6) comprises a capacitor (36) and an inductor (35) which form a parallel resonant circuit.

3. noise protection filter and lightning current arrester device according to claim 1 or 2, characterized in that in the area of the two connection points (12, 13), between the inner conductor (3) and the short-circuit conductors (5, 6), on the inner conductor (3) each a capacitance (30, 31) is formed and the inner conductor (3) between the two connection points (12, 13) has a further capacitance (34) and at least one inductance (32, 33).

4. noise protection filter and lightning current arrester device according to one of claims 1 to 3, characterized in that a high-pass filter (37) is arranged on the output side (18) on the inner conductor (3).

5. noise protection filter and lightning current arrester device according to one of claims 1 to 4, characterized in that between the mutually directed ends (14, 15) of the short-circuit lines (5, 6) and the housing (2) a capacitance (40) and in parallel an additional pulse-diverting element (39) is switched on.

6. interference protection filter and lightning current arrester device according to one of claims 1 to 5, characterized in that between the inner conductor (3) on the one hand and the short-circuit conductors (5, 6) and the housing (2) on the other hand, a dielectric (20) is arranged.

7. noise protection filter and lightning current arrester device according to one of claims 1 to 6, characterized in that with the exception of the connecting elements (16, 17) between the short-circuit conductors (5, 6) and the housing (2) all effective components concentric to the longitudinal axis ( 9) of the device (1) or parallel to the longitudinal axis (9) of the device (1).

8. Interference filter and lightning current arrester device according to one of the claims 1 to 7, characterized in that the short-circuit lines (5, 6) are electrically elongated λ / 4 short-circuit lines.

9. Interference filter and lightning current arrester device according to one of the claims 1 to 8, characterized in that the different

Line sections of the short-circuit conductors (5, 6) and the connecting elements (25, 26) determine the bandwidth and the frequency range of the RF transmission.

10. Interference filter and lightning current arrester device according to one of the claims 1 to 9, characterized in that the different

Line sections of the inner conductor (3) and the dielectric (20) determine the characteristic of the bandwidth of the RF transmission.

1. noise protection filter and lightning current arrester device according to claim 5, characterized in that the pulse-dissipating element (39) is a gas discharge arrester or a varistor or a diode and above this pulse-dissipating element (39) and the capacitance (40) a direct current Feed is arranged.