PL119772B2 - Method of laying of power and telecommunication cableson areas subjected to mining damagepodrabotannykh gornymi rabotami poverkhnostjakh - Google Patents

Description

The subject of the invention is a method of laying power and telecommunication cables in areas affected by mining damage resulting from the extraction of raw materials from underground mines. State of the art. The current methods of laying cables in areas affected by mining damage do not effectively protect against damage to these cables. Mining damage by damaging cables causes many failures in power supply and communication, with most of the cable failures occurring in couplings. Moreover, laying cables in a corrugated line in a horizontal plane on sand bedding does not ensure free movement of the cable in accordance with the displacement of the ground occurring in mining damage Purpose of the arite. The aim of the invention is to significantly reduce or even eliminate the occurring failures consisting in cable tearing during horizontal and vertical deformations of the soil on the surface, occurring during mining operations, thus reducing power failures and communication failures. To achieve this goal, the goal of reducing the possibility of damage was set. cables at the connection point and along the entire length of the route by ensuring free movement of the cable during land subsidence and the resulting stretching and compaction of the soil, causing elongation and shortening of the soil mass. The essence of the invention. In the method according to the invention, a power cable or a telecommunication cable was laid, a corrugated line in a vertical plane similar to the deflection line occurring during mining damage, and the cables are placed in a tight flexible sheath with a diameter approximately twice as large as the cable diameter, which ensures independent elongation and shortening of the cable. greater than the stretching and compaction of the soil occurring during mining damage. The cable couplings are secured by a steel structure with clamps that reduces the impact of the tensile and compressive forces of the coupler and a tight flexible sheath is secured, whereby the cable connections are located in the zones where the smallest tensile and soil compressive forces occur. The new method * of laying cables enables the use of narrow-space excavations and no sand padding. The advantage of the invention is that the cable is placed in a tight flexible cover and only linearly contacts with the cover, which makes the cable movements and displacements independent of ground movements and displacements. An additional advantage of the invention is that the cable connections (couplings) are protected against the direct influence of tensile and compressive forces by an independent steel element with clamps securing the connected cables. 2 IW 772 Explanation of figures. The subject of the invention is presented in the example of the embodiment in the drawings, in which fig. 1 shows the method of laying the cable in the field in a vertical plane and securing the cable couplings with an independent steel element with clamps, fig. 3 - laying the cable in the vertical section of the route in the zone and beyond the zone of the protective pillar before and after mining damage and establishing the cable connection points with couplings. Example of the invention implementation. The invention consists in laying the cable 1 under the surface of the ground 3 in a tight, flexible casing 2 applied in sections after the cable 1 has been unrolled previously, then laid in a narrow-space trench 4 and backfilled. The bottom of narrow spatial excavation 5 beyond the boundary of the protective pillar 6, i.e. the zone in which no raw materials are selected, runs in a wavy line, while in the zone of the protective pillar the bottom of the pit 5 runs horizontally. Cable connections with muffs 7 located at the boundary of the protective pillar 6 in the zone of the smallest tensions and soil compression 8 determined on the basis of the hottest deck 9 and the deepest deck 10. Connection 11 occurs in the zone of variable compression and tension of the soil. The cable connections, box 7, 8, 11 are secured by a steel structure 12 with clamps 13 fastening the connected cables 1 and a tight sheath 2. Line 14 shows the surface of the land against mining damage. On the other hand, line 15 shows the land surface after mining damage. The corrugated line 16 shows the cable routing before mining damage, while the line 17 shows the shape of the cable line after mining damage. Patent claims 1. The method of laying power and telecommunication cables in areas subject to mining damage, characterized by the fact that the cable (1) is laid in elastic tight cover (2) a wavy line in a vertical plane below the ground surface. Method of laying cables according to claim 1, characterized in that the cable couplings (7), (8), (11) are secured by the steel structure (12) and clamps (13) securing the connected cable (1) and the cover (2) ). 3. The method of laying cables according to claim A method as claimed in claim 1 or 2, characterized in that the connections of the cable (7), (8), (11) are preferably arranged in the zones of the occurrence of the lowest tensile and soil compressive forces. Fig. 1119 772 777777T, A A ± / F7777777 s ~ 1 k V A - Fig. 2 J V Fig. 3 EN

Claims (3)

Claims 1. Method of laying power and telecommunication cables in the areas subject to mining damage, characterized in that the cable (1) is laid in a tight flexible casing (2) in a wavy line in a vertical plane under the ground surface. Method of laying cables according to claim 1, characterized in that the cable couplings (7), (8), (11) are secured by the steel structure (12) and clamps (13) securing the connected cable (1) and the cover (2) ). 3. The method of laying cables according to claim A method as claimed in claim 1 or 2, characterized in that the connections of the cable (7), (8), (11) are preferably arranged in the zones where the smallest tension and soil compressive forces occur. Fig. 1119 772 777777T, A A ± / F7777777 s ~ a k V A - Fig. 2 J V