NO883172L - SHELF AND PROCEDURE FOR AA END A BOEYBAR COACIAL CABLE. - Google Patents

Description

This invention relates to a ferrule and method of using it to terminate a bendable microwave coaxial cable.

Semi-rigid cables, with their fixed inner and outer conductor diameters, have allowed simple termination methods that are very accurate and provide terminated cables with good electrical performance when applied to semi-rigid cable. In these terminations, the outer tubular metal shield and the heavy gauge solid wire signal conductor are rigid, strong and tightly and easily wedged into a standard connector sized for the particular cable using a simple termination tool by crimping the cable and the coupling member portion together to perform termination with a pincer-like pinching motion. Such methods are not suitable for terminating flexible coaxial cables which may contain flexible new materials with low dielectric constant, and the inner and outer conductor diameters may be small and varied, depending on the loss characteristics desired for a given cable dimension or impedance.

The invention provides termination for flexible coaxial cables, such as a microwave cable, by using standard semi-rigid type connectors in combination with a metal sleeve which is soldered to the cable's metal shields and optionally bonded to the cable's insulation.

According to the present invention, there is provided a sleeve for surrounding and supporting a flexible coaxial electric cable during manual or automatic termination to a connector comprising a concentrically fitting, cylindrical electrically conductive metal tube, including sections having diameters approximately equal to the outer diameter of corresponding sections of the coaxial cable being prepared for termination.

According to another aspect of the present invention, there is provided a method for terminating a rotatable electric coaxial cable consisting of the steps: a) trimming to selected length at one end of said cable layers with Insulating and protective jacket, metallic screen, insulation between the screen and the center leader, and said center leader to locate the end of said layer at spaced intervals from each other,

b) inserting the trimmed cable end into an electrically conductive metal sleeve having sections of stepped diameter

dimensioned to approximately fit the aforementioned casing and metal screen respectively,

c) soldering or otherwise conductively attaching said sleeve to said metallic shield, or alternatively tying

by means of adhesive said insulating jacket to said sleeve, and

d) to fashion a coupling member on said sleeve.

According to a further aspect of the invention, it is

provided a bendable electrical coaxial cable having an outer sheath, a metallic shield and center conductor insulated from said shield, and prepared for mounting on a connector, the cable having at one end thereof a rigid metallic sleeve comprising tubular portions of stepped diameter, one section fits snugly around the cable's sheath and another section fits around and makes contact with the exposed metallic shield.

The ferrule is made of an electrically conductive, rapidly malleable metal commonly used in electrical wire, cable and connectors, such as copper and its alloys, including brass formulations, plated aluminum or plated steel or other ferrous metal compositions, and formed to fit the connector selected for use on the cable. The end of the cable to be terminated is shaped to closely conform to the contour of the ferrule and to overlap a portion of the metal shield and usually the outer insulation or sheath, so that adequate bond strength can be obtained by soldering the ferrule to the metal shield and/or bonding if desired, such as by using epoxy or other suitable binder, glue or adhesive, to the insulation or jacket.

The invention will now be described in particular in the form of an example with reference to the attached drawings. Figure 1 is an exploded cross-section showing a coaxial cable, a sleeve and a connector. Figure IA shows a cross-sectional view of the parts in Figure 1 shown after completion. Figures 2 and 2A show a variant of Figures 1 and 1A, where the center conductor in the cable is small, the sleeve contains a center contact held by means of insulation at the end of the sleeve, and a standard connector. Figure 3 is a cross section through a terminated cable bounded within an angled sleeve to provide an angled connector. 1 Figure 1 is an end of a microwave coaxial cable shown with an outer insulating sheath 1 removed from a metal shielding layer 2, surrounding an inner insulating layer containing the central signal contact 3. These sections of the cable have been trimmed to the correct length and center- the contact 3 pointed for termination with a selected coupling member of the known semi-rigid type. The sleeve has a section 4 of larger diameter to fit over the Insulation 1, where it can be bonded by means of adhesive, and a section 5 of smaller diameter which is sized to fit over the metal screen 2 part of the coaxial cable and is soldered there by means of a common method known in the art, e.g. through the solder opening 6.

After the solder has hardened and any adhesive that is present has solidified, the now sleeved cable is inserted into a sleeve 10. A manual termination tool, which is well known in the art, is now used to grip the end of the sleeve after the cable and connector the parts are placed together and the end of the coupling member 9 between its jaws and the two parts forced together so that the end of the sleeve at termination rests against the insulation block 7 and the center conductor 3 which has penetrated and is firmly gripped by the coupling member pin 8 as shown in figure IA, and the pipe wall 10 crimped to the pipe wall 5. Figure 2 is similar to Figure 1, but the center conductor 3 is very small, smaller than standard semi-rigid, and its dimension requires an increase for adequate termination in standard connectors. This is done by equipping the sleeve with a center contact 12 of chosen suitable dimension fixed in the middle of an insulating block 11 which is mounted at the smallest end of the sleeve. Termination of the cable can then take place in a similar manner as described above with figures 1 and 1A to give a terminated cable as shown in figure 2A. Figure 3 illustrates one form of the invention where the length of the sleeve has been increased, terminated, and then shaped at an angle so that an angled connector can be provided.

This invention thus provides a simple economical way of terminating a flexible cable using methods not normally suitable for such cables - a simple, inexpensive method for semi-rigid cable converted to use for a small, soft, flexible cable by means of a sleeve which is anchored to the cable end to be terminated. The invention is suitable for automatic termination techniques as well as individual assembly.

Claims (10)

1. A sleeve for surrounding and supporting a flexible electrical coaxial cable during manual or automatic termination to a connector comprising a concentrically fitting cylindrical electrically conductive metal tube, characterized in that the sleeve comprises sections (4,5) having diameters closely corresponding to the outer the diameter of corresponding sections of the coaxial cable prepared for termination. 2. Sleeve as stated in claim 1, characterized by that the metal is copper, a copper alloy, steel, stainless steel or aluminium. 3. Sleeve as specified in claim 1 or 2, characterized in that a section (12) of said sleeve, for receiving therein the central conductor of a cable, is connected to the rest of the sleeve via an insulating connection (11). 4. Method of terminating a bendable electrical coaxial cable, comprising the steps of trimming to selected length at one end of said cable the layers of insulating and protective sheath, metallic shield, and insulation between the shield and the center conductor, and said center conductor to locate the ends of said layers at spaced intervals from each other, characterized by inserting the trimmed cable end into an electrically conductive metal sleeve having portions of stepped diameter sized to approximately fit said jacket and metal shield, respectively, soldering or otherwise conductively attaching said sleeve to said metallic screen, or alternatively to bind with the help of adhesive said insulating jacket to said sleeve, and to mount a coupling device to said sleeve. 5 . Method as stated in claim 4, characterized in that the step of mounting a connector to said sleeve comprises placing said sleeve-enclosed cable blank in position for termination within a connector, gripping said connector and said cable end in the operating jaws of a termination tool, and operating said tools for placing said cable in said connecting means to perform termination of said cable. 6. Method as stated in claim 4 or 5, characterized in that the termination tool is a hand-operated tool. 7. Method as stated in claim 4 or 5, characterized in that the termination tool is an automatic multi-termination machine for electric cables. 8. Method as stated in claim 4 or 5, characterized by additionally attaching the central conductor in a conductive manner in the cable to a part of the sleeve Isolated from the remainder, prior to fitting a connecting device to said cable. 9. Flexible electric coaxial cable having an outer sheath (1), a metallic screen (2) and a center conductor (3) which is insulated from the screen, and prepared for assembly to a connecting means (10), characterized in that the cable at one end thereof has a rigid metallic sleeve comprising tubular sections (4,5) of stepped diameter, one section (84) fitting snugly around the jacket (1) of the cable and another section (5) fitting around and making contact with the exposed metallic screen (2 ). 10. Coaxial cable as specified in claim 9, characterized in that the sleeve includes a further stepped tubular section (12) which is isolated from the rest of the cable by means of an insulator (11) and fits around and forms contact with the exposed center conductor (3).