CS207708B2 - Method of removing the piece of the predetermined length of the screening coaxial cable sheathing and device for executing the same - Google Patents

Abstract

In order to prevent damage to a coaxial cable during removal of a piece of its screen, the cable end (c, d, f) is initially passed through the hole of a cutting plate (1) and is subsequently pushed into or onto a tubular cutting die (2). The piece (L1) of the screening mesh (c) to be cut off at the same time comes to rest on the outer envelope surface of the cutting die (2), while the conductive and insulating components, which are located under the screening mesh (c) to be cut off, are inserted into the space inside the cutting die which is constructed as a blind hole. During the operation, the cutting die (2) is pushed together with the cable end thus placed on through the hole in the cutting plate (1), as a result of which the screening mesh is cut off. In this case, the force components which endanger the intactness of the said components of the cable are absorbed by the cutting die (2). <IMAGE>

Description

BACKGROUND OF THE INVENTION The present invention relates to a method for removing a predetermined length of a single-layer or multi-layer metal shielding sheath of coaxial cables and to an apparatus for carrying out the method which is provided along one axis with a cylindrical, tubular punch and die. its diameter, aligned with the outer diameter of the punch.

Coaxial cable is a special electrical conductor used in communication technology. It consists of an inner conductor, a single-layer or multilayer braided metal shielding sheath, one or more sheaths insulating each other from each other, and an insulating sheath surrounding all of these sheaths. The coaxial cable can be used in the field of high-frequency systems and multi-channel carrier current systems, as it is in this field. the width of the transmitted frequency band exceeds the area of application of the symmetric cable.

When separating a. the removal of certain parts of the individual sheaths leads to a number of harmful phenomena. The insulating sheath or insulating sheaths are often cut, whereby the insulation further tears at the point of cutting, since the coaxial cables are generally stressed by sagging loads. When separating the metal shielding sheath, the chip-blading knife forms needles on each cut metal fiber, which are pushed into the insulating sheath which is made of plastic and which cannot therefore be removed when radially displaced in the direction of the inner conductor. The insulating sheath and the inner conductor suffer from the action of alternating sense forces due to the action of the chip-removing knife (s), whereby they are heavily stressed, causing the inner conductor to deform and change its position. These harmful phenomena lead to changes and deterioration of the parameters of the coaxial cable and its functional reliability, in particular by decreasing the coaxial cable. mechanical strength, the insulation layer becomes thinner, which reduces insulation resistance, generates electrical peak effects and threatens breakdown. In addition, the position of the conductors breaks at the ends of the cable, the wave impedance changes and harmful reflections occur. Even with slight changes in dimensions, there are large changes in electrical quantities, as the ratio of their size to the geometry of the conductors and insulators follows the logarithmic function. Also the cable capacity is deteriorating, crosstalks are increasing and their size is proportional to the logarithm of the dimensions of the conductors and insulators.

Various solutions are known for removing shielding or insulating sheaths from coaxial cables. There is a known method according to which a predetermined piece of braided metal shielding or also an insulating sheath is removed by a chip-removing knife which rotates around the cable. Furthermore, a method is known in which the cutting rollers which rest against the outer sheath of the cable make a cut, regardless of whether this is done in the braided metal shielding sheath in the insulating sheath.

These damages are caused in conventional methods and devices by the chip-removing knives being arranged radially and thus exerting radial forces against which only a slight abutment is formed, consisting of a relatively low-strength plastic insulating sheath arranged under a separate braided metal shielding sheath. . The aforementioned damages are also caused by the fact that the blades are controlled by only a few relatively flexible or formable layers, essentially only by the envelope formed by the insulating outer shell.

These drawbacks are eliminated in the method of removing a piece of a predetermined length of a single or multilayer metal shielding sheath of coaxial cables by the method according to the invention, which consists in the insertion of a punch between the sheathed part removed and the guide and insulating part of the cable. and that the punch is then moved together with the cable by cylindrical bore of the punch, coaxial with the punch, thereby producing a shearing shielding sheath and causing a corresponding shear in which force components threatening the integrity of said cable portions are transmitted to the punch.

An apparatus for carrying out said method, having a cylindrical tubular punch and a punch along its axis, whose cylindrical bore concentric with the punch is aligned with the punch outer diameter, according to the invention, consists in the cylindrical punch body formed as a result of blind drilling, tubular, on the front side it is formed as a truncated cone whose smaller diameter equals the diameter of the blind drilling and forms the front edge of the tubular part and whose larger diameter equals the outer diameter of the punch and forms the cutting edge of the punch this cutting edge of the punch and the bottom surface of the bore is equal to the predetermined length of the shielding sheath being removed. The punching hole according to the invention is cylindrical according to the invention, in one part following the insertion plane for the punching hole, and in this part the bore diameter is aligned with the outer diameter of the punching hole and the other part of the borehole has the shape of an expanding truncated and the front face of the cutting die perpendicular to the longitudinal axis of the bore, which is the insertion plane for the punch, forms a cutting edge at the cutting edge that is the cutting edge of the cutting die.

The method according to the invention achieves that the individual cut fibers have neither radically external nor electrically or mechanically unfavorable properties radially away from the axis. The device for carrying out the method uses specially designed punching and punching tools, the arrangement of which provides a reliable support against the force exerted and the separating force on the separated piece of shielding sheath has a different direction than the known solutions. The conductive and insulating components placed under the braided metal shielding sheath are not damaged in the method and the exemplary embodiment of this method, since the metal cutting tools do not act on them. The operation of the device according to the invention is not associated with any rotary or rolling movements and can therefore be fixed to known machine parts for separating pieces of insulating jacket.

An example of a device for carrying out the method according to the invention is shown in the attached drawing, in which Fig. 1 is a longitudinal section of the device with the cable inserted into the die, Fig. 2 is the device according to Fig. of the entire device according to the invention. ‘

The coaxial cable consists of an inner conductor f, which may be solid or twisted, an inner insulating sheath d, a single-layer and multilayer braided shield sheath c, and an outer insulating sheath b.

The machine part according to the invention for removing a piece of shielding sheath c of a predetermined length consists of two main parts, the shape of which is shown in Figures 1 to 3. The die is made of a material suitable for cutting the material of which it is made. the nominal diameter Dii of the bore (Fig. 3) is about 0.2 to 0.3 mm larger than the prescribed largest diameter · outer sheath envelope c. Cylindrical · bore x section that ensures shape stability when grinding the blade, is 2 to 3 mm long. The apex angle α of the cone for insertion of the cable end is preferably equal to 30 °. This insertion cone makes it easier to insert the cable into the die 1 in a known manner.

The punch 2 is made of a material which is suitable for cutting the mass of which the sheathing c is. The nominal value of its outer diameter J corresponds to the nominal value of the bore diameter Di. The fitting of these diameters of the die 1 and the die 2 is made to accommodate H7 / 17. The insertion angle β is 60 °. The tapered insertion portion of the punch 2 facilitates insertion of the shielding c. The inside diameter d of the blind bore is about 0.15 to 0.25 mm. greater than the permissible outer diameter of the inner insulating sheath d. Dimension L is the length of the sheath sheath piece c to be removed. If the end of the cable is inserted into the punching hole 2, expanding the shielding piece c will reduce the length to Li, but the length of the exposed portion will, of course, remain L.

If it is desired that the length L of the sheathing piece to be removed is variable, the punch 2 is formed as a tube over its entire length and a stop piece adjustable in the longitudinal direction, which can be fastened in the desired position.

The apparatus works as follows: The end of the cable is fed through a punch 1 (see FIG. 1) and then further into the punch 2, which, as indicated, is cylindrical and is in part cone-shaped tube until the cable hits the bottom in blind bore. In this case, the shielding sheath c of the cable adjoins the outer surface of the punch 2, while the inner cable components are in blind bore. Thereafter, the punch 2 is moved in the direction shown in FIG. 2, and when this punch is moved through the punch 1, the shielding sheath C is sheared around at the desired location while the piece of shielding sheath c to be removed remains on the outer surface of the punch. The end of the cable separated therefrom can then be pulled out of the punch 2. The punch 2 is then moved back to the starting position, whereby the removed shielding piece c is removed from the outer surface of the punch 2, preferably by means of a spring sensing device. The nozzle 3 shown in FIG. 3 blows out of the working space.

The arrangement of the tools and the operating principle of the method according to the invention or the apparatus according to the invention permit both mechanical and pneumatic control, but it is possible to use a device made as a hand tool for carrying out the method.

Claims (3)

SUBJECT A method of removing a piece of a predetermined length of a single or multilayer metal shielding sheath of a coaxial cable, characterized in that the punch provided with a bore or in the form of a tube is inserted between the sheathed part removed and the guide and insulating part of the cable below it. then, together with the cable, it advances the cylindrical bore of the die, coaxial with the punch, thereby producing a shearing shear force and causing a corresponding shear in which the force components threatening the integrity of said cable portions are transmitted to the punch. 2. Apparatus for carrying out the method according to claim 1, provided with a cylindrical, tubular punch and a punch, whose cylindrical bore, concentric with the punch, is aligned with the punch outer diameter, characterized by its axis. in that the cylindrical body of the punch (2) formed by BACKGROUND OF THE INVENTION It is formed on the front side as a truncated cone whose smaller diameter is equal to the diameter of the blind bore and forms the frontal · edge of the tubular part · and whose larger diameter equals the outer diameter of the punch (2) and forms the cutting edge of the punch. (2) and the distance (L) between this cutting edge of the punch (2) and the bottom of the blind bore is equal to a predetermined length of the shielding piece removed c. Device according to claim 2, characterized in that the bore in the cutting die (1) is cylindrical in one part adjacent to the insertion plane for the punch (2) and in this part the bore diameter is aligned with the outer diameter of the punch (2j and others). a portion of this bore has the shape of an expanding truncated cone concentric to the first part and the front face of the punch (1) perpendicular to the longitudinal axis of the bore, which is the insertion plane for the punch, forms a cutting edge at the edge of the bore cutting edge of cutting die · (1).