CA1194714A

CA1194714A - Composite overhead transmission line

Info

Publication number: CA1194714A
Application number: CA000406438A
Authority: CA
Inventors: Yasunori Saito
Original assignee: Sumitomo Electric Industries Ltd
Current assignee: Sumitomo Electric Industries Ltd
Priority date: 1981-07-07
Filing date: 1982-06-30
Publication date: 1985-10-08
Also published as: US4793686A; KR840000809A; IT8248755A0; GB2105059A; IT1149001B; DE3225228C2; JPS587607A; ZA824643B; HK48286A; GB2105059B; DE3225228A1

Abstract

ABSTRACT OF THE DISCLOSURE
A composite overhead transmission line includes a spacer formed with spiral grooves filled with a jelly-like material into which optical fibers are buried.
cover or sheath surrounds the spacer member to protect the internal components.

Description

7 1 ~

This invention r~lates to a composite overhead transmission line ob-tained by providing an optical fiber cable in an overhead transmission line formed by stranding a plurality of conductors, or in an overhead earth wire which is extended in parallel with such an overhead trans-mission line.
Optical Eiber eables have been extensively used as signal transmission media, and have specific features in that not only they are large in data transmission cap-acity, but they are also free from elec~romagnetic induc-tion. Accordingly, an optical fiber cable can be incorp-orated in an overhead transmission line or an ordinary powex line. That is, the optical fiber cable provides a great eeonomieal effect in that it is unnecessary to add-itionally install a eommunication cable.
Heretofore, in order to incorporate the optical fiber cable into an overhead line, some of the stranded eonductors forming the overhead line are replaced by an optieal fiber cable unit ~hereinafter referred to as "an optical fiber unit") which is obtained by incorporating a plurality of optical fibers in a metal tube. In the above-deseribed conventional construction, the wall thickness of the metal tube covering the optical fiber unit is gen-2S erally small beeause oE dimensional limitations. Accordin~ly,the metal tube is insufficient in mechanical strength and accordingly cannot suffieiently proteet the optical fibers '.~

7:1~

1 from damage. Thus, the outer cover is liable to be damaged and water may enter the op-tical fiber unit.
On the other hand, since it is difficult to in-crease the inside diameter of the metal tube, it is con-siderably difficult to increase the percentage of twist ofthe optical fiber cable itself, and accordingly it is impossible to form a cable with the optical fibers slackened.
SUMMARY OF THE INVENTION
This invention is intended to provide a composite overhead transmission line of novel construction which eliminates the above-described difficulties, and a method of manufacturing such a transmission line.
BRIEF DESCRIPTION OF THE DRAWINGS
This invention will be described with reference to the accompanying drawings, wherein-Figs~ 1 and 2 are sectional views showing a - composite overhead transmission line according to this invention;
Fig. 3 is an explanatory diagram illustrating a method of manufacturing the overhead transmission line according to the inventlon;
Figs. 4a-4e are sectional views of the overhead cable at various manufacturing steps; and Figs. 5a and 5b are explana-tory diagrams showing a collecting die of Fig. 3.

1 DETAILED DESCRIPT[ON OF THE PREFERRED E~BODIMENTSFig. 1 shows one example of a composite overhead transmission line~ An op-tical fiber unit 2 is disposed along the common axis of stranded conductors 1. The optical fiber unit 2 is made up oE a spacer 2-1 having spiral grooves 2-2 in its outer walls, a metal tube 2-3 which covers the outer wall of the spacer 2-1, and optical fibers 3. The splral grooves 2-2 are filled with a jelly-like material 4, which is fluidic or substantially fluidic at room temperature, such as an aqueous solution of petro leum jelly, polyisobutylene, non-brigde silicon resin, silicon oil or polyvinyl alcohol.
The optical fibers 3 are placed in the grooves cut in the spacer, and the spacer is covered with the metal tube 2-3. Therefore, the optical fibers are sufficiently protected from external forces, and are packaged in a sub~
stantially water-proof manner.
Since the grooves of the spacer are filled with the jelly-like material, the aerial cable is efficiently protected from the entrance of water even when the metal tube is damaged ! and the optical fibers are stably arranged in the grooves toward the outer wall of the spacer.
As the optical fibers are located in the grooves adjacent the spacer outer wall, they are maximumly stranded, which will substantially absorb ar~y elongation which may be caused when the composite overhead transmission line is installed.

: -3-1 Fig. 2 is ~ sectional view of a composite over-head transmission line which has been elongated when installed.
When the transmission line is installed, the optical fibers incorporated in the grooves are caused to move from the outer wall to substantially the middle points of the respective grooves, as a result of which the optical fibers are not elongated, i.e., the cable elongation is absorbed. The absorption of elongation depends on the out-side diameter D of the spacer, the groove depth h and thespiral pitch P. The absorption is as indicated in the following Table 1, with the outside d~ameter d of each optical fiber strand being 0.~ mm.
TAULE 1 (P = 150 mm) lS
D ~mm~ 4 6 h (mm) 1.0 1.2 1.3 1.0 1.2 1.5 Absorption of elongation ~.%) 0. 08 0.12 0.14 0.13 0. 21 0. 25 ~ = 2~2 (D - h~h - d) In the above-described composite overhead trans-mission line, the grooves in the spacer 2-1 are filled with jelly-like material. However, it should be noted that one 25 object of this invention i5 to allow the cable to be stretched during ins-tallation while ~voiding any elongation of the fibers, i.e., to Eorm the cable with slackening. In 7:~4 this connec-tion, the optical Eibers can be placed in the peripheral portions of the grooves without f:illing the grooves with -the jelly-like material 4. This can be achieved by applying a greater feed Eorce to the optical fibers 3 than that to the spacer 2-l to avoid any application to tension to the fibers during assembly, to position the optical fi~bers at radially outward portions of the grooves

2-2.
This arrangement is advantageous in the following points: Even if the thickness of the metal cover 2-3 lS
reduced, the cable is not collapsed nor broken because of the presence of the spacer 2-l. Therefore, the cable is maintained water-proof without filling the grooves with the jelly-like material.
In order to improve the stability of the optical - fibers in the grooves, the section of each groove 2-2 should be such that the inner part is equal to or larger - than the opening part thereof in si~e.
The outer cover of the optical fiber unit is a metal tube, as described above. The cover serves not only to protect the cable from external forces or moisture but also to improve the temperature characteristic of the optical fiber. An overhead transmission line often under-goes a high temperature of several hundreds of degrees centigrade (C~ because of an induction current or lightning current or short current. If the thermal expansion co-efficient of the optical fibers is larger than 71~

that of the spacerj then the optical fibers are brought into contact with the inner wall of the metal tube as shown in Fig. 1 when the temperature is increased, and are then moved back as shown in Fig. 2 when the temperature is decreased. On the other hand, if the thermal expansion coefficient o-f the optical fibers is smaller than that of the spacer, then the optical fibers are positioned as shown in Fig. 1 at low temperatures -for instance at night, and are positioned as shown in Fig. 2 at high temperatures, for instance during daytime. Although the optical fibers are thermally expanded and contracted as described, they are not slightly bent, because the plastic covers of the optlcal fibers are slidable on the surface of the metal tube. Therefore, the transmission loss variation is maintained at a minimum. According to the result of experimentation, it has been confirmed that, in the case where a material such as a coarsely wound tape or string is interposed between the spacer and the metal tube in order to hold the optical fibers in the grooves ln the spacer, the fibers cannot smoothly move when the temperature changes, and accordingly the transmission loss is greatly increased.
The spacer may be made of metal or non-metal. However, in order to maintain the charac~eristic of the optical fibers stable, it is desirable that the thermal expansion coefficient of the material of the spacer be substantially 7 1~L

1 equal to tha-t of -the ma-terial of the metal tube. It is adv~ntageous from the po:int of view of both the thermal expansion coeEficient and mechanical stxength tha-t the spacer be made of a metal material such as aluminum, iron or copper, or a non-metal material such as -fiber-re-inforced plastic.
Fig. 3 shows one example of a method of manufact-uring a composite overhead -transmission line according to the invention. The spacer 2-1 in which the spiral grooves have been cut is -fed from a supply reel 5. The spacer 2-1 thus fed is passed through a jelly-like material ~illing device 6, so that the grooves 2-2 thereof are filled with petroleum jelly 4. Thereafter, the optical fiber conductors 3 are supplied from rotary cages and are buried in the petroleum jelly 4 near the openings of the grooves. In this condition, the spacer is delivered to a metal tube covering device, where the spacer and the optical fibers in the grooves are covered by the metal tube. The metal tube 2-3 is formed by a conventional method in which a shaping device 9 is used to butt-joint a metal tape 8 to provide a butt-jointed cylinder, and the cylinder thus provided is but-t-welded. In Fig. 3, reference numeral 10 designates a weld-ing electrode.
Fig. 4 shows sections of the optical ~iber unit in various stages of the manufacturing process in the case where the unit is manufactured according to t~ above-described method. More specifically, Fig. 4a shows the petroleum jelly ~ filled in the grooves 2-~2 in the spacer 2-1 at the point $ A immediately after the filling de~ice 6, Fig. 4b shows the optical fibers being put on the petroleum jelly 4 near the openings of the grooves at the point B, and Fig. 4e shows the optical fiber unit at the point C immediately after a collect-ing die 7. Fig. 4d shows the optical fiber unit includingthe metal tube at the point D immediately after a cooling device 11, and Fig. 4e shows the optical fiber unit a-t the point E immediately after a diameter reducing device 12 arranged before a winding reel 13. In the manufacturing method, after the petroleum jelly or the like is filled in the grooves cut in: the spacer, the optical fibers are buried in the petroleum jelly in the grooves and near the periphery of the spacer. Under this condition, the spacer is covered with the metal tube, to form the optical fiber unit. Therefore, the method is advantageous in that the optical fibers can be stably and positively arranged in the grooves in the spacer and near the periphery of the latter.
In the above-described embodiment, the metal tube or :
cover is made according to a welding method; however, it goes without saying that it may be manufactured according to other conventional tube manufacturing techniques, such as for instance an extrusion molding method. It is desirable that the collecting die be designed so that it , as shown in Figs. 5a and 5bD includes an internal cavity 7-1 and a passage 7-2 extended outwardly from the cavity 7-1. In this case9 even if the petroleum jelly is partly pushed out of the grooves when the opticai fibers are buried in the grooves, the petroleum jelly thus pushed out can be removed, and the operation of incorporating the optical fibers in the grooves can be protected from being affected by excessive jelly.

Claims

The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows:

1. A composite overhead transmission line comprising:
at least one stranded wire layer which includes a plurality of conductor wires made of metal or metal alloys;
a central housing member formed with continuous spiral spaces each extending in a longitudinal direction of said housing member, said central housing member comprising a spacer formed with spiral grooves at its outer peripheral surface, and a thin metal cover disposed over said spacer in close contact therewith; and optical fibers housed in said spiral spaces and positioned at radially outer portions of said housing member.

2 A composite overhead transmission line as claimed in claim 1, wherein said spacer and said cover member have substantially equal coefficient of thermal expansion.

3. A composite overhead transmission line as claimed in claim 1, wherein said spacer is made of metal.

4. A composite overhead transmission line as claimed in claim 1, wherein said spacer is made of insulation material.

5. A composite overhead transmission line as claimed in claim 1, further comprising a jelly-like material filled in said grooves, said optical fibers being movable within said jelly-like material near the inner wall of said cover.

6. A composite overhead transmission line as claimed in claim 5, wherein said optical fibers are movable within said jelly-like material so as to migrate toward the center thereof when said transmission line is elongated.

7. A composite overhead transmission line as claimed in claim 5, wherein said jelly-like material is selected from the group comprising petroleum jelly, polyisobutylene, non-brigde siliconresin, silicon oil and polyvinyl alcohol.

8. A method of manufacturing a composite overhead transmission line comprising the steps of:
providing a spacer member with spiral grooves in an outer wall thereof, filling said grooves with a jelly-like material, burying an optical fiber in the jelly-like material of each of said grooves, and applying a cover member onto said spacer member.

9. A method of claim 8, wherein said optical fibers are buried in said jelly-like material by laying the optical fibers atop the jelly-like material and passing the spacer and the conductors through a collecting die.

10. A method of claim 8, wherein said cover member is applied by applying sheet in the form of a tape, and welding said tape to form a cylinder.