NO133469B - - Google Patents

Description

The invention relates to a tensile electrical connection between the ends of two coaxial cables, each of which has a central conductor surrounded by a solid dielectric, a cylindrical outer conductor and a sheath, where the conductors are electrically connected in the usual way, e.g.

by means of'clamp connections,'

As a result of the increasing use of common antenna systems, especially for television reception, there is a great need for reliable connections between the ends of coaxial cables that may have the same

or different diameter.

The most important conditions imposed on such connections are that they should not cause any disturbing reflections of the signals transmitted through the cable. In addition, the connection must be watertight and tensile-resistant without causing disturbances. -

Known connections are complicated and expensive and prone to errors and can only be performed by professionals.

In the case of certain known compounds, the tensile stress will yield. the central conductors are exposed to tension, which can lead to electrical disturbances. With other connections, the sheath is subjected to tensile stress so that it can be damaged and moisture can penetrate the cable.

The purpose of the invention is to provide a tensile phase. electrical connection of the type mentioned at the outset which can be carried out by non-professionals flawlessly following certain instructions and with a minimum of tools and which can be subjected to tension without electrical disturbances occurring in the cable.

According to the invention, this is achieved by the cable ends being mechanically connected. by means of connecting pieces of insulating material which are provided with parts projecting towards the central conductor which fit into recesses in the massive dielectric at each cable end. Preferably, the connecting pieces consist of shell halves, the inside of which is provided with at least two radially inwardly projecting parts that fit into grooves in the dielectric at the cable ends, from an electrical point of view it is necessary that the impedance at the connection point is the same as that of the cable. For this reason, a part of the dielectric corresponding to the thickness of the bowl halves or the thickness of the shell halves and the protruding parts thereof. In this way, it is achieved that the shell halves, when placed in place, have an outer diameter that corresponds to the original diameter of the dielectric in the cables.

In order to achieve a good electrical connection between the central conductors, these are exposed and surrounded by a metal boss which is surrounded by an insulating material. The metal bosses can be provided with one or more axial slots and have a somewhat smaller diameter than the central conductors so that a clamp connection is formed. The outer diameter of the insulating body is preferably equal to the reduced diameter of the outer ends of the dielectric. If the diameter of the cable ends is different, the outer circumference of the insulating body must be given a conical shape so that its diameters at the ends correspond to the diameters of the dielectric of the cable ends. An electrical connection between the outer conductors can e.g. happen by means of shell halves made of metal which overlap parts of the outer conductors and are held together by means of clamping means, e.g. clamping rings. A shrink sleeve made of jacket material can then be placed on top of the whole or supplied with self-vulcanising insulating tape.

, An embodiment of the invention will be explained in more detail below with reference to the drawings.

Fig. 1-3 show axial sections through the cable end for different working steps for placing the connection according to Isen's invention. Fig. 4 shows an axial section through the connection according to the invention. Fig.5 shows a radial section through a connection boss with the insulating body. Fig. 6 shows an axial section through a connecting piece in the form of a bowl half. Fig. 7 shows an end view of two assembled bowl halves. Fig. 8 shows an axial section through a finished connection according to the invention. Fig. 1 shows the end of a coaxial cable with a central conductor 1 of solid copper, a solid dielectric 2 of polyethylene, an outer conductor 3 of copper foil and/ or copper lace and an outer sheath 4 of polyethylene. As shown in fig. 2, a part of the mantle is removed, and

the outer conductor 3 while at 5 it is cut through the outer sheath to the outer conductor 3. Then a part of the dielectric 2 is removed so that the central conductor protrudes from the dielectric. Two annular parts 6 and 7 are then removed from the dielectric, of which part 6 has a smaller diameter than part 7 so that an annular groove is formed which serves to accommodate the inwardly projecting parts 9 of the shell halves 8. The part 7 serves to accommodate the thickness of the shell halves 8 so that as shown in fig. 4, the connection point has the same outer diameter as the dielectric originally had. Then the sheath parts 4^ are removed so that a part of the outer conductors is exposed. Next, the connecting boss 11 which has an inner diameter somewhat smaller than the diameter of the central conductors is pushed onto the ends of the central conductors with a snap fit. Bossingen 11 is surrounded by an insulating

body 12 whose outer diameter corresponds to the inner diameter of the bowl halves. The insulating body 12 preferably has the same dielectric constant as the dielectric, 2. If not, an adaptation can be made, e.g. arrangement of holes 13 as shown in fig. 5.

The bowl halves 8 are then placed as the edge parts 9 of these engage in the ring grooves 6.. The bowl halves. 8 can be of the same insulating material as the dielectric 2, e.g. polyethylene. It is clear that the connecting pieces 8 can be divided into more parts than two, with advantage the bowl halves can be provided with a tongue and groove as shown at 14 in fig. 7" To further prevent the ingress of moisture, a water-repellent compound can be placed between the parts, e.g. polyethylene wax or silicone grease. Two copper bowls 15 and 16 are then placed which overlap and form electrical contact with the outer conductors 3 and these are held together by means of clamping rings 18. Finally, a sleeve of elastic electrical insulating material 17 is placed, e.g. shrink sleeve made of polyethylene which is previously pushed over one of the cable ends, and which is then shrunk and covers the entire connection. The sleeve 17 serves as a jacket and prevents the penetration of moisture and it is therefore necessary that the sleeve 17 overlaps the jacket 4 as shown in fig. 8.

A connection of this nature can be subjected to tension without the risk of the electrical connection between the cable ends or the impedance changing. Such a connection can be wound onto a coil body and unwound from it again without risk of damage. The placement of cable sleeves is generally not necessary. With the construction according to the invention, a sufficiently watertight connection is achieved.

A compound according to the invention can fceks. used to connect cable ends with an outer diameter of 15 mm or more.

Claims (3)

1. Tensile electrical connections between the ends of two coaxial cables each having a central conductor surrounded by a solid dielectric, a cylindrical outer conductor and a sheath, where the conductors are electrically connected in the usual way, e.g. by means of clamp connections, characterized in that the cable ends are mechanically connected by means of connecting pieces of insulating material which are provided with parts projecting towards the central conductor - which fit into recesses in the massive dielectric at each cable end. 2. Electrical connection according to claim 1, characterized in that the connecting pieces consist of shell halves whose insides are provided with at least two radially inwardly projecting parts that fit into grooves in the dielectric at the cable ends. 3. Electrical connection according to claim 2, characterized in that the diameter.of. the dielectric between the traces and the cable ends plus the thickness of the sleeve in this area is equal to or approximately equal to the original diameter of the dielectric.