FI58999C - KOPPLING AV KOAXIALKABELAENDAR FOER CENTRALANTENNSYSTEM - Google Patents

Description

I ^ ga γβΙ m \ advertisement publication cqqqo m fl ·) utlAggningsskrift 5 8 9 9 9 C Patent granted 11 C5 1901 '' Patent meddelat ^ ^ (51) Kv.ik? /Int.ci.3 H 01 H 9/05, H 02 G 1/14 FINLAND —FINLAND <21) Ntunttlhukumu * - P »tu« C * i »6k« * lng 329/73 (22) Htkamltpilvf - Aittttknlnpdtg 05.02.73 (23) AlkupUvi — QMghttfdag 05.02.73 (41) ) Tullut (ulklMlcil - Bllvlt offantllg 09.08.73

Patent ·] a Registry Board Nihttvtiaip ^ j. kuijuHubun pvm._

Patant- OCh ragittartty rataan 'AnsiMun utlagd och utl.skrHtun publlcartd 30.01.81 (32) (33) (31) Requested «toikuu» —Begin! prlorltet 08.02.72

Holland-Holland (NL) 7201608 (71) N.V. Philips' Gloeilampenfabrieken, Eindhoven, Holland-Holland (NL) (72) Hubertus Johannes Josephus Gommans, Venlo, Josephus Gerardus Henricus Stikkelbroeck, Venlo, Holland-Holland (NL) (7I +) Oy Kolster Ab (5I +) Connection of coaxial cable ends for common antenna systems This invention relates to water-resistant electrical connections between two coaxial cable ends, each end comprising a center conductor (4), a solid insulator (3) surrounding the center conductor, a cylindrical overhead conductor (2) and a sheath (1), wherein the center conductors are electrically connected. (6) and the outer conductor with a sheath-like connecting piece (9) of electrically conductive material which overlaps with the outer conductors (2) of the cable ends.

This invention further relates to a method of making a water-resistant electrical connection between two coaxial cable ends. As a result of the increasing use of common antenna systems, especially for television viewing, there is a great need for reliable connections between the ends of a coaxial cable, which ends may still have the same or different diameters.

The most important requirement for such a connection is that there be no reflections that would degrade the signal being distributed through this cable. In addition, the joint must be water-resistant and must be able to withstand the tensile forces that occur during normal cable handling.

2 58999

In general, existing joints are complex and expensive in nature and easily cause errors. They can only be used with the help of specially trained staff and generally require time-consuming measures.

It is an object of the present invention to provide a joint which can be fitted quickly and flawlessly and using as few tools as possible and by untrained personnel after only a few instructions, this joint being relatively inexpensive.

A connection between two ends of a coaxial cable which satisfies this condition is characterized in that the sheathed connectors (9) are provided with inwardly projecting portions which engage the outer conductors of the cable ends and that the metal sleeve (6) into which the inner conductors (4) of both cable ends are inserted , is provided with a sheath (7) of electrically insulating material, the strength of which is chosen so that the impedance of the connectors is the same as that of the cable ends.

The connection according to the present invention can be obtained by removing parts of the sheath (1) of the two coaxial cable ends, part of the conductors (2) and part of the cable insulation (3) so that part of the outer conductor (2) protrudes outside the sheath (1), cable insulation (3) ) protrudes outside the conductor and part of the center conductor (4) protrudes outside the cable insulation, after which the center conductors (4) are connected by sliding a metal sleeve (6) provided with a sheath (7) of electrically insulating material over these ends to then the sheath portion (9) of electrically conductive material is placed on top of the part of the floating conductor (2) which protrudes outside the sheath (1) and comes into electrical contact therewith, which is obtained by pressing this connection with the aid of a pressing device and that the arrangement is provided with electrically insulating with protective cover (14). The insulation of the metallic sleeve is more preferably the same as that used as the dielectric material of this cable. This metal sleeve may be provided with one or more axial grooves and may be somewhat smaller in inner diameter than the diameter of the center conductor, so that a crimp connection is obtained. In order to realize in this range the ratio between the inner diameter (D) of the outer conductor and the diameter (d) of the inner conductor, which determines the impedance so that it is equal to the ends of the cable, it is necessary to do this under the influence of a slightly larger diameter of this inner conductor. an insulating sheath sheath of a metallic 58999 fitting somewhat greater than the dielectric portion of the cable ends and realizes this so that the ratio D / d is equal to that of the cable ends. If the diameters at the ends of these cables are different from each other, the diameter at each end of this insulating sheath is somewhat larger than the diameter in the dielectric part of the cable next to it. The diameter between the two ends then varies, for example, regularly with distance so as to obtain a conical shape, in which case, of course, it must be ensured that the impedance in this conical part is matched to the corresponding value of the cable ends. Yet another arrangement can be accomplished by equipping the sheath of this insulating material with Sol. In a preferred embodiment of the present invention, hollow cylinders of smaller length made of the same material and having a wall thickness equal to the difference between the thickness of the insulating sheath portion and the dielectric portion of the adjacent cable are supported at both ends of the insulating sheath portion at and at both ends. between. When the connection is then made, the dielectric parts of the ends of this cable are slid into these hollow cylinders. The purpose of these described cylinders is to extend the length of the moisture leakage path. Polyethylene wax or other viscous, anti-moisture agent can be placed on the inner walls of these cylinders so that water resistance is further better guaranteed. When using this embodiment, the length of these cylinders is most preferably selected so that the part of the dielectric material which is not covered by the outer sheath is thus surrounded. It has now been found that a satisfactory, moisture-tight connection can be achieved in this way, while the reflections caused in this area by the additional amount of this insulating material are still very small and can be kept within acceptable limits. The electrical connection between these cylindrical outer conductors is effected by means of sheath-shaped connecting pieces made of an electrically conductive material, e.g. copper, nickel-plated copper or brass.

These shell-shaped connectors can be compressed into a pile using compression rings on these outer conductors and on top of the dielectric material below. In order to achieve a satisfactory electrical and mechanical connection between the two cable ends, these connectors are at least as far as those parts located on the outer conductors are provided with ridges rising from their inner sides, e.g. with radially varying ridges. OF

* »5 8 9 9 9 These targets may take other forms provided that a satisfactory electrical and mechanical connection is thus feasible. The shell-shaped connectors are most preferably located at least in the connection area in the center conductors to which the adjacent shaped edges of the profile are connected so as to prevent outward radiation. The outer sheath can then be added, e.g., by flagging a heat-shrinkable tube of electrically insulating material, e.g., polyethylene, onto this structure or by using a vulcanizing sealing tape.

A preferred embodiment of the present invention and a method of making such a joint will now be described in more detail with reference to the accompanying drawings.

Figures 1 and 2 are longitudinal cross-sections of a cable in its various stages of manufacture in order to provide a joint according to the present invention.

Figure 3 shows a longitudinal cross-section of the connection of two cable ends with the same diameter.

Fig. U is a cross-sectional view taken along line IV-IV in Fig. 3.

Figure 5 shows a longitudinal cross-section of a joint between two cable ends having diameters of different sizes.

Figure 1 shows, partly in cross-section, the end of a coaxial cable, part of its sheath 1 and the copper well forming the outer conductor 2 and the copper-stranded conductor arranged over it with it removed, in preparation for making this connection. Thereafter (Fig. 2) a part of this dielectric material 3 is removed so that the central conductor 1+ protrudes outside the dielectric part 3. Those parts of the central conductors k which protrude outside the dielectric part 3 from these two cable ends are then flagged to the connecting piece 5. This connecting piece 5 consists of a metal fitting 6 which may have a somewhat smaller diameter than the central conductor k and may be provided with one or a plurality of slots located parallel to its axis so as to provide a compressible adhesion and provided with a shell of insulating material 7. Since the diameter (d) of the center conductors in these connectors is larger than that of the center conductors U by the action of the metal fitting 6, the thickness of the insulating sheath 7 is preferably made of the same material as the cable dielectric material 3, e.g. polyethylene, selected so that the ratio D / d is the same as at the ends of the cable (D is the inside diameter of the outer conductor). The insulating sheath 7 continues at both ends in the form of a thin hollow cylinder 8 and 8A, the thickness of this wall being equal to the difference in thickness between the shell part 7 and the dielectric part 3 of the cable, which surrounds the cable.

The dielectric portion at the portion from which the outer conductors 2 have been removed. The metal shells 9 are then provided (Figures 3 and U). As seen in Figure U, the two sheaths may form a cylindrical sheath. Of course, it is alternatively possible to form these sheaths so that three or more sheaths form a closed cylindrical sheath. In general, however, it should be preferred to limit the number of these shells so that the number of seams through which moisture may enter is also limited. In order to provide protection against radiation, the common tangent planes of this shell 9 are formed at least in the part surrounding the connecting piece 5 and this is realized e.g. the shell part, which depends on the diameter of this cable, is kept in stock. These shells 9 are provided with radially variable ridges on the inside. These shells 9 are fixed by compression rings 12 and 13. A shrinkable polyethylene tube is then fitted to the jacket IU. The connection of two cable ends with different diameters and shown in longitudinal cross-sections in Fig. 3 is not substantially different from the case according to Fig. U. The reference numerals have the same meaning as in the case of Fig. 5. It is obvious that in this case the shape of the conical sheath 7 made of insulating material must be chosen so that the impedance in this connection does not differ substantially from that acting at the ends of the cable. In order to provide a satisfactory closure against moisture penetration, a thin layer of an antifouling agent, e.g. polyethylene wax or silica grease, may be added between all parts in this joint.

A joint as shown in Figures 3 and 5 may resist tensile forces that are not too great so that there is no risk of a change in the electrical properties of the joint between the ends of this cable or a corresponding change in impedance in this range.

The connection according to the invention may be used, for example, when assembling a network and common antenna systems so as to connect all types of cables used for this purpose using fixed dielectric and compatible or sometimes different large diameters, which may be connected using the connections according to the invention.

These connections can be used for underground and air-suspended cables and the use of cable sheaths is generally not necessary.

Claims (2)

6 58999 Claims: A water-resistant electrical connection of two coaxial cable ends, each of which comprises a center conductor (* 0, a fixed insulator (3) surrounding the center conductor, a cylindrical outer conductor (2) and a sheath (1), the center conductors being electrically connected by a metal sleeve (6) and outer conductors , a connecting piece (9) of electrically conductive material which overlaps with the outer conductors (2) of the cable ends, characterized in that the sheath-like connecting pieces (9) are provided with inwardly projecting parts which engage the outer conductors of the cable ends and that the metal sleeve ( 6), into which the inner conductors (U) of both cable ends are inserted, is provided with a sheath (7) of electrically insulating material »the strength of which is chosen so that the impedance of the connectors is the same as that of the cable ends. A method of manufacturing a water-resistant electrical connection according to claim 1, characterized in that parts of the sheath (1) of the two coaxial cable ends, part of the outer conductors (2) and part of the cable insulation (3) are removed so that part of the conductor (2) protrudes ), the cable insulation (3) protrudes outside the outer conductor and part of the center conductor (¾) protrudes outside the cable insulation, after which the center conductors (U) are connected by dissolving a metal sleeve (6) provided with a sheath (7) of electrically insulating material. on top of these ends that the sheath part (9) of electrically conductive material is then placed on top of one part of the outer conductor (2) which protrudes outside the sheath (1) and comes into electrical contact therewith, which is obtained by pressing this connection with the aid of a pressing device and that the arrangement is provided with an electrically different protective cover (1 ^).