NL9201650A - CAPACITIVE SEPARATION PART. - Google Patents

Description

Capacitive separator.

The invention relates to a capacitive separating part with an electrically conducting housing, which on its outside has coaxial connecting elements for connecting two high-frequency koaxial cables to be connected to each other and on the inside two capacitors, one capacitor the inner conductor and the other capacitor. sator galvanically isolates the outer conductor of the two cables.

A capacitive separating part is known from DE-OS-2,410,543, which has two tube capacitors arranged axially one behind the other in a metal housing. The first capacitor galvanically separates the inner conductor and the second capacitor the outer conductor of the coaxial cables to be connected. The inner conductor of one cable terminates at the internal sheath of the first capacitor and the inner conductor of the other coaxial cable is insulated through the second tube capacitor and connected to the outer sheath of the first capacitor. Both capacitors are each surrounded by a tubular sleeve, one end of which is connected to the outer conductor of the associated coaxial cable and the other of which has a conically tapered end to the outer cover and the inner cover of the other capacitor, respectively.

The known capacitive separating part has the drawback that in order to achieve a high degree of protection of, for example, more than 75 dB, a large technical and economic effort is required and that the separating part takes up a relatively large amount of space.

The object of the invention is to further shape a capitive separating part, as mentioned in the preamble, such that the capacitive separating part fulfills the high requirements for degree of shielding with considerably reduced production effort.

For this purpose, a capacitive separating part of the type mentioned at the outset has the feature that the housing of the capacitive separating part is constructed of two koaxial housing parts connected to one of the outer conductors, between which an air gap meandering in cross section of the housing consists of the air gap Capacitors arranged in an annular manner with respect to the high frequencies are bridged, that the housing parts each have a conductor connected to the inner conductor of the coaxial cable, insulated relative to the housing parts and that the ends of these conductors are connected by a further capacitor. This brings together the advantage of a particularly simple and compact structure of the capacitive separating part with rational manufacturability and a high degree of shielding. Advantageous further embodiments of the capacitive separating part according to the invention are apparent from the subclaims. A capacitive separating part according to claim 3 is particularly advantageous, because the meandering air gap is thereby realized in a particularly simple manner. A further preferred embodiment according to claim 7 has the advantage that the capacitors placed annularly in the capacitive separating part can be mounted mechanically.

Examples of embodiments of the invention are shown in the drawing with reference to various figures and are explained in more detail below. Figure 1 shows a cross-section of a capacitive separating part according to a first embodiment, figure 2 shows a perspective view of aids for the manufacture of strip pairs equipped with capacitors, figure 3 shows a perspective view of a pair of strips with capacitors bent into a ring, figure 4 a cross-section of a capacitive separating part in a second embodiment and Fig. 5 shows a cross-section of a capacitive separating part in a third embodiment.

In Figure 1, 10 denotes a capacitive separating part, the electrically conductive housing 11 of which consists of two pan-shaped housing parts 12 and 13. The housing parts are shaped such that the cross-section of the housing has an approximately meandering air gap 14, 15, 15 between the two housing parts. In the example according to figure 1, the first housing part 12 is inserted with its open end into the second housing part 13 provided with a core 17, the air gap between the core 17 of the second housing part 13 and the inner wall of the first housing part 12 is filled by insulating material 18. The insulation can for instance be formed by a tube of insulating material. The diameter of the free end 20 of the core 17 and the opposite end of the insulating material 18 are indented in cross-section such that first capacitors 21 arranged in divided manner via the inner circumference of the first housing part 12 are placed therein, which preferred are tube capacitors or chip capacitors. Second air capacitors 24 are also arranged in an annularly distributed arrangement in the air gap 15, 16. Further insulating material 26 closes the air gap 16 "outwards. Here too, the insulation can consist of an insulating tube. The insulating material 18 and 26 can be dispensed with if the air gaps are dimensioned so wide that they guarantee the high voltage capability provided for the capacitive separating part 10. Resting elements 27 on the circumference of the first housing part 12 and on the inner wall of the second housing part 13 represent a mechanical connection only indicated schematically between the two housing parts 12 and 13. An arbitrary constructional design, which is familiar to those skilled in the art, can be selected for the connection.

The housing parts have axial connection elements 30 and 31 on their base surfaces, which serve for the preferably pluggable connection of two high-frequency koaxial cables 32 to be connected, of which only one is shown in Figure 1. The coaxial cables 32 each include a cable outer conductor 34 electrically connected to an outer conductor 33 of the connecting elements 30, 31 and in each case a cable inner conductor 37 connected to the inner conductors 35 and 36 of the connecting elements 30 and 31. The inner conductors 35 and 36 are axial through the housing parts 12, 13 are passed through and insulated from them by insulating parts 38, 39. Between the facing ends of the inner conductors 35 and 36 there is a further capacitor 41 in an axial elongated opening 40 of the insulating part 39. While the capacitors 21 and 24 galvanically separate the outer conductor 34 of the two coaxial cables 32 the further capacitor 41 galvanically separates the inner conductors 35 and 36 of the capacitive separating part 10 and the cable inner conductor 37 from the coaxial cables 32, respectively.

In Fig. 1, spring elements 42 symbolically indicate that the capacitors 21, 24 and 41 are axially resilient, so that any length tolerances of the housing parts 12 and 13, of the tubes 18 and 26 and of the capacitors 21, 24, 41 are neutralized . The spring elements can for instance be conductive rubber parts.

Figure 2 shows a band-shaped strip 50 of elastic conductor sheet material. Parallel cuts 53, 54, 55 transverse to the longitudinal dimension of the band-shaped strip 50 create two narrow strips 56 and 57, which are bridged by the capacitors 52 which are preferably automatically fed and soldered at equal distances during manufacture. For mounting the capacitive separating part 10, the narrow strips 56, 57 associated via the capacitors 52 are cut out and bent into the ring 51 (figure 3), which is inserted in the air gap 14 at the location of the individual capacitors 21 (figure 1). inserted. A similar ring 51 replaces the individual capacitors 24 in Figure 1. The ends of the narrow strips 56 and 57, like the surface carrying the capacitors 52, must be covered with electrically conductive material. Instead of the elastic guide plate for the strips 50, tinplate is particularly suitable.

In an alternative embodiment of a capitive separating part 60 according to the invention according to figure 4, two housing parts 61 and 62 have a similar shape as the housing parts 12, 13 in figure 1. In the middle region 64 of the meandering air gap 63, 64 65, an annular curved thin elastic conductor plate 66 with first and second chip capacitors 67, 68 is inserted. The first capacitors 67 are located on one end of the tubular curved conductor plate 66 on the inside and the second capacitors 68 on the other end on the outside. First terminals 72 of the first capacitors 67 are electrically connected with a conically-tapered free end 70 of a core 71 of the second housing part 62 and the second connections 73 with a conical contact surface 74 of the first housing part 61. It connects to a bottom 75 of the second housing part 62 added end of the core 71 merges into a cone 76. The inner wall at the open end of the first housing part 61 is provided with a conical area 77. The second capacitors 68 are in contact with an ear terminal 78 with the cone 76 of the core 71 and with their second terminal 79 in contact with the conical region 77 of the first housing portion 61. The contact is effected by conductive bridges 80 and 81, which engage the conductor plate 66 angularly and are soldered to the terminals 73, 78 of the capacitors 67, 68. A further capacitor 82 provided for separating the inner conductor from the capacitive separating member 60 is inserted between inner conductor ends 83 and 84 on the inside of the first housing portion 61 and at the free end of the core 71 of the second housing portion 62. The inner conductor ends are preferably conically or semi-spherically shaped so that they protrude slightly into the tube at a tubular capacitor 82.

In a variant of the capacitive separating part 60 according to Figure 4, two cap-shaped housing parts 91, 92 have a capacitive separating part 90 according to Figure 5 on the bottom wall, each with a wedge-shaped annular groove 93, 94 in cross-section, in which, when assembled housing parts 91, 92, a correspondingly curved figure 3 elastic conductor plate 95 with capacitors 96, 97 fits. Capacitors 96 and 97 are attached to the outside of the elastic conductor plate 95 in this example. Conductive bridges 98 connected to the terminals of capacitors 96 and 97 are formed and placed as the conductive bridges 81 in Figure 4. Further conductive bridges 99 represent an electrical connection between terminals of the capacitors 96 and a thickening edge 100 of a core 101 of the second housing portion 92. A further capacitor 102 is mounted between housing parts 91 and 92 in a similar manner to capacitors 82 in Figure 4.

Claims (12)

1. Capacitive separator with an - electrically conductive housing, which has coaxial connection elements on the outside for connecting. closing of two high-frequency cables to be connected together and having two capacitors on the inside, one capacitor of which the inner conductor and the other capacitor galvanically separates the outer conductor of the two cables, characterized in that the housing of the capacitive separating part ( 10) is constructed of two coaxial housing parts (11-, 12) connected to one of the outer conductors (34), between which an air gap (14, 15, 16) meandering in cross section of the housing consists of the air gap placed capacitors (23) with respect to the high frequencies, it is bridged that the housing parts (11, 12) are each insulated with the inner conductor (36) of the coaxial cable (32) insulated from the housing parts (11, 12) conductor (35, 38) and that the ends of these conductors are connected by a further capacitor (39). Capacitive separating part according to claim 1, characterized in that the air gap (14, 15, 16) in the area outside the capacitors (23) is at least partly filled with insulating material (18). Capacitive separating part according to claim 1 or 2, characterized in that the housing parts (12, 13) of the capacitive separating part (10) are shaped in a cap-like manner and are joined with their open sides and that the one housing part (13) is has a coaxial core (17). Capacitive separating part according to claim 1, characterized in that the capacitors (21, 24, 39) are kept axially resilient between the housing parts (12, 13). Capacitive separating part according to claim 1 or 4, characterized in that the capacitors (21) are tubular capacitors. Capacitive separating part according to claim 1 or 4, characterized in that the capacitors (67) are chip capacitors. Capacitive separating part according to any one of claims 1 to 6, characterized in that the capacitors (52) are arranged transversely to two parallel strips (56, 57) and the strips are bent into a ring (51). Capacitive separating part according to any one of claims 1 to 7, characterized in that the capacitors (67, 68) are placed at the ends of a tubular bent elastic conductor plate (66). Capacitive separating part according to any one of claims 1 to 7, characterized in that the capacitors (52) are disposed transversely to two parallel tubular curved strips (56, 57). Capacitive separating part according to claim 8, characterized in that the outer connections (73, 78) of the capacitors (67, 68) are connected to a conductive bridge (80, 81) which engages the elastic conductor plate (66) on the outside . Capacitive separating part according to claim 9, characterized in that the housing parts (61, 62) to be contacted with the capacitors (67, 68) have conical contact surfaces (74, 76, 77). Capacitive separating part according to any one of claims 1 to 10, characterized in that the housing parts (61, 62) are each insulated with respect to them and connected in each case to an inner cable conductor (37) of the coaxial cable (32). (35, 36) and that a further capacitor (39) is placed between the facing ends of the inner conductor (35, 36).