TH3139B - Structural elements overhead cables for power and light transmission - Google Patents

Abstract

Structural elements overhead cabling for power and light transmission consist of a pipe, a layer of metal stranded along the conductor surrounding the outer circumference of the duct, attached to such external circumference. At least one layer and the optical fiber cables are fixed tightly inside and stretched along the length of that tube. The central part of the encapsulation consists of at least one double encapsulation layer of a non-metallic soft encapsulation layer and a hard non-metallic encapsulation layer. By providing the encapsulation of the optical fiber cable to be tightly fixed within the pipe by such encapsulation, the optical fiber cannot move in relation to the pipe. According to its structure, optical fiber cables are effectively shielded not only from bending or deforming as they occur, but also with extreme lateral load resistance. This leads to the danger of having to be remedied in such a way that the optical fibers will be damaged by stabilizing their optical power transmission properties.

Claims (7)

1. Structural elements for overhead cabling consists of: a tube of length and circumference, external wall and internal wall circumference. A layer of metal stranded along the conductor surrounds the circumference. At least one layer of the outer wall of the pipe is attached to the perimeter. Fiber optical cables which have external wall circumference and are fixed internally and stretched along the length of such pipes; And the encapsulation is fixed internally and stretched along the length of the longitudinal gap formed by the internal wall circumference of such pipe and the external wall circumference of the fiber optical cable; and Is placed on the outside circumference of the optical fiber cable. The encapsulation consists of a double encapsulation layer of a non-metallic soft encapsulation layer with a 0.01 to 5 kg / mm Young modulus and a hard non-metallic encapsulation layer with Young's modulus. 20 to 400 kg / mm2 is arranged according to this action, at least one such non-metallic hard-shell layer is adjacent to that non-metallic soft-encapsulation layer. The encapsulation has its innermost layer and its outermost layer consists of a non-metallic soft encapsulation layer and a hard non-metallic encapsulation layer, respectively; The innermost layer is firmly attached to its surface to the circumference of the optical fiber's external wall, and the outermost layer is firmly attached to its surface to the circumference of the duct's internal wall: The optical fiber cable is wrapped firmly in place within the said duct by such encapsulation. 2. Cable structure according to claim 1, where the encapsulation layer is in the form of a 3. Cable construction according to claim 1, where such a wrap layer is in the form of a strand, strand or tape or in the form of a layer. The tape overlaps over the length of the optical fiber cable. 4. Cable structure according to claim 1, where the hard encapsulation layer is in the form of an extruded coating. 5. Cable structure according to claim 1, where such rigid layer is in the form of stranded; Lines or tape, or in the form of a tape layer that is overlapped along the length of the optical fiber cable. 6. Cable structure according to claim 1, where the encapsulation consists of several soft wrap layers. And multiple rigid wrap layers arranged alternately. 7. Cable structure according to claim 1, where the optical fiber cable is in the form of optical fibers with impacts. The optical cable consists of a core and an enclosure and forms a protective coating there. 8. Cable structure according to claim 1, where such optical cable is in the form of an optical cable. Encapsulated optical fibers contain optical elements consisting of cores and enclosures and act there as follows: Collision coating and encapsulation 9. Cable construction according to claim 1, where such optical fiber is in the form of a stranded optical fiber. Each collision optical fiber has an optical class consisting of a core and an enclosure and a protective coating pattern there. 1 0. The cable structure according to the claim. Article 1 Where such optical fiber is in the form of a multilayer stranded optical fiber, each encapsulated optical fiber contains the element The optical class consists of a core and a enclosure and acts there by the following actions. Coating against collision and encapsulation 1 1.Cable structure according to claim 9, where the collision optical collision is wound around the center 1. 2.Cable construction according to claim 10, where such an encapsulated optical fiber is stranded along the center section 1. 3.Cable construction according to claim 9, where such a collision fiber is stranded into at least one line along the additions made of a material with a high tensile strength relationship. , Surrounded by the center part 1 4.Cable construction according to claim 10, where such an encapsulated optical fiber is stranded into at least one line along the additions made with correlated material in High tensile strength Surrounded by center part 1 5. Cable structure according to claim 1, where the optical fiber is in the form of a number of optical fiber units stranded around the center part. Each optical fiber unit consists of a large number of optical fibers that are stranded around the center axis. The collision forces that surround it as needed, do the following: Soft wrap layer and hard wrap layer Each fire-resistant optical fiber contains optical elements consisting of a soft core and enclosures and a anti-conflict coating pattern there.1 6. Cable structure according to claim 1, where the optical fiber is in the form of a multitude of optical fiber units stranded around the center. Each optical fiber unit consists of a large number of encapsulated optical fibers stranded, encircled along a central core and wrapped in the following manner. Soft wrap layer and hard wrap layer Each encapsulated optical fiber contains an optical component consisting of a core or enclosure and acts there as follows: Collision and encapsulation coating 1 7.Cable construction according to any of Claims 9 through 16, where the fiber optical cable forms a channel by straining at its circumference. Each cavity is filled with a section that is identical to that of the encapsulated layer inside. The position that is close to the optical fiber cable.