SU1435793A1 - Powered support section - Google Patents

Abstract

The invention relates to the extraction of minerals by the underground method, namely to the fastening of working faces with mechanized supports. The goal is to increase the reliability of maintaining an unstable roof under conditions of restless hypsometry. The section includes a base 7 and an overlap (P) 1 connected with a hydroresistant 12. 1. At the visor 3 P I connected to the top 2, there are set of closing. ///, /// ///////////// / x /// // Kf / I / / /, / f- 13 1 10 9 8 // cylinders (B ) 4. Each of B 4 is made in the form of a closed flexible shell with holes. In the latter, prismatic shbeky vessels with wear-resistant tips are placed. The ends of the flexible vessels obie dinene in two groups. Under the base 7 flexible tubes (GT) 13 are placed. At the ends, from the bulging side, the GT 13s are connected by a fixed sleeve 14, and from the bottomhole side by a movable sleeve 15. Through the pipeline 16, the GT 13s are connected to the rod end of the hydraulic head 8 of the movement. On both sides of the base 7 are located the lever systems of the movement mechanism, consisting of two shoulders. One end of the levers is attached to the base beam 11, and the other end is connected to the movable cage 15. Remaking the base beam S 11 causes the two shoulders to move, while the HT 13 are straightened and pressed against the base 7. The roof slump is held back by elastic elements (prismatic flexible vessels) and perceived B 4. 6 Il. (L 4; co. Oo 9ig.1

Description

The invention relates to the extraction of minerals by the underground method, namely to the fastening of working faces with mechanized supports.

The aim of the invention is to increase the reliability of maintaining an unstable roof under conditions of restless hypsometry.

FIG. 1 shows the mechanized support section, general view; in fig. 2 — an assembly for adjoining the toe of the base to the base beam (conveyor); in fig. 3 shows section A-A in FIG. one; in fig. 4 shows a section BB in FIG. one; in fig. 5 shows a section B-B in FIG. four; in fig. 6 — an assembly for adjoining the toe of the base to the base beam during the passage of the excavation machine.

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more strength and rigidity of the material of the container 4. The odd and even sleeves 25 are combined into two independent systems, which have supplies for the working fluid from the compressor or pump. In each row there is one or more safety valves 26 that cut off each row after the working fluid is supplied and the desired pressure is created. Structurally, the shells are made so that the flow of the working fluid between the flexible sheath 22 and cyanindric vessels 23 is absent.

Section mechanized lining works as follows.

After the passage of the excavation machine in front of the visor 3, a loose section is formed of the mechanized roof support section including 5 JQK roofs. To prevent destroying the overlap 1, consisting of hard

top 2, pivotally connected to the site, it is necessary to move the section to

visor 3 and two (or more) inform-breast slaughter. For this, in a rod stock of closed cylinders 4, a fence 10 of a jack 8 of movement from 5 with levers of a four-link 6, a rigid base 7, a hydraulic jack 8 of movement, having a piston 9 and rod 10 of the cavity, a base beam II and a hydroracks 12. Under the base 7 tightly one row in all its width placed connected each other

on the other side of the lateral forming flexible 25, temporarily in one of the groups of flexible vessels of the tube 13, combined at the ends with obstruction-23 (for example, in vessels located

on the fixed side 14, and with the downhole movable 15 clips and hydraulically connected by means of a pipe 16 to the rod cavity 10 of the hydraulic cylinder 8. The stationary holder 14 hydraulically and mechanically connects the tubes 13 and fixedly mounted on the base 7. The movable sleeve 15 also connects the ends of the tubes 13 hydraulically and me- tures. it has hinges 17. On both sides of the base 7 there are lever arms (counting from the chest the bottom) with a protrusion. With threads consisting of two shoulders 18, an increase in pressure inside the tube 3 with a flexure end attached to the base beam 11, and the second to the movable holder

The pine lining station is pressurized with working fluid, which creates a force in the jack 8 that pushes the base 7 to the base beam 11. Under the same pressure, the working fluid is supplied through the pipe 16 into the sleeve 13. In odd numbers, the pressure of the working fluid is partially released. The section begins to move toward the bottom, and the base 7 begins to rise onto the soil ledge. The double-shouldered lever 18, through the hinge 17, acts on the yoke 15 and transmits to the tubes 13 a longitudinal force that causes the tubes 13 to flex to the ground, filling up the empty space behind the bottom 7 at the bottom of the base 7. To the middle point of the two shoulders lever 18 is pivotally attached to a ha ha 19, ending with a slider 20 springed relative to the upper plane of the base of the section by an elastic element 21. Each of the cylinders 4 is represented as a closed flexible shell 22, made of their strong rigidity increases, they form an inverted arch and the greater the curvature of this arch, the greater the force (reaction) 40 is transmitted from the soil to the base of the support. The movable sleeve 15 all the time remains pressed against the lower plane of the base, as when lifting the base 7, the slide 20, spring-loaded by the elastic element 21, transferred to the flexible material, the lower surface 45 through the pull 19, rises upwards completely fixed on the upper 2 and I have a hinge 17. The bigger the bottom 7 is in the roof)

on the top (facing to the surface of the hole, the centers of which lie on the straight, parallel to the long side of the overlap, into which are inserted prismatic (cylindrical) flexible vessels 23, which have wear-resistant tips 24 on the ends facing the roof). vessels 23 are combined in each row by sleeve 25 and mechanically fastening with sheath 22. Cylindrical flexible vessels 23 are made of a material whose tensile strength and rigidity are 2-3 times

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Ditches under the conveyor, the closer the movable 15 and the fixed 14 cage and the greater the force raises the base. The force developed by the jack 8 moves through the four-arm arms 6 and the fence 5 is transmitted to the top to 2 and the visor 3, and through them to the flexible shell of the cylinder 4. When the displacement begins, the I vessels 55 are pressure-relieved the working fluid begins to deviate towards the dam, retaining the necessary backwater. by pressing the tips 24 to the roof.

more strength and rigidity of the material of the container 4. The odd and even sleeves 25 are combined into two independent systems, which have supplies for the working fluid from the compressor or pump. In each row there is one or more safety valves 26 that cut off each row after the working fluid is supplied and the desired pressure is created. Structurally, the shells are made so that the flow of the working fluid between the flexible sheath 22 and cyanindric vessels 23 is absent.

Section mechanized lining works as follows.

After the passage of the excavation machine in front of the visor 3, a loose part of the roof is formed. To prevent the destruction of the immediate roof on this

the jacking jack 10 is 8 from moving temporarily in one of the groups of flexible vessels 23 (for example, in vessels located

The pine lining station is pressurized with working fluid, which creates a force in the jack 8 that pushes the base 7 to the base beam 11. Under the same pressure, the working fluid is fed through the pipe 16 into the sleeves 13. Simultaneously in one of the groups of flexible vessels 23 (for example in vessels located

 vym (counting from the chest slap) protrusion. By increasing the pressure inside the tube (3 bends in odd rows), the pressure of the working fluid is partially relieved. The section begins to move toward the bottom, and the base 7 begins to rise onto the soil ledge. The double-shouldered lever 18 through the hinge 17 acts on the yoke 15 and transmits to the tubes 13 a longitudinal force that causes the tubes 13 to bend convexly to the soil, filling up the empty space behind the primer base, their stiffness increases, they form an inverted arch, and the greater the curvature of this arch, the greater the force (reaction) transmitted from the soil to the support base. The movable sleeve 15 all the time remains pressed against the lower plane of the base, as when lifting the base 7 together with it the slider 20, spring-loaded with the elastic element 21, rises, passing through the pull 19 upward for the hinge 17. The larger the base 7 in

Ditches under the conveyor, the closer the movable 15 and the fixed 14 cage and the greater the force raises the base. The force developed by the jack 8 moves through the four-link arms 6 and the fence 5 is transmitted to the top to 2 and the visor 3, and through them to the flexible shell of the cylinder 4. When the displacement begins, the I prismatic (flexible) vessels 23, in which the working pressure is not relieved bodies begin to deviate towards the dam, retaining the necessary backwater by pressing the tips 24 against the roof.

moreover, the pressing force remains in the process of further movement almost constant due to the constant pressure of the working fluid in the sheath 22. Prismatic flexible vessels 23, located in odd rows, when moving overlap I contact with the roof, almost without creating resistance to movement. After the completion of the movement into prismatic flexible vessels 23 located in odd rows, the working fluid is again supplied under pressure until they are completely pressed by the tips 24 to the roof. After that, the pressure in the prismatic flexible vessels 23, arranged in even rows, is relieved, the latter are pressed from the roof and in them again by means of the sleeves 25 the working fluid is supplied under pressure, after which they occupy a new position, adapting to the uneven roofing. In the case of large local roof irregularities (in the presence of dumps, etc.), a more rigid prismatic flexible vessel 23 can settle until the rigid part (2 or 3) is closed, in which case the pressure in the group of vessels 23 is controlled by valve 26.

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13 are straightened and pressed against the base 7. Next, the operations are repeated. The slump of the roof during the excavation cycle is restrained by elastic elements (22 and 23) of overlap 1, the rock pressure of the descending stratum of the roof is perceived by the cylinder 4, by hard parts of the overlap (2 and 3) and transmitted through the hydraulics 12 to the base 7 and the soil of the formation.

Claims (1)

Invention Formula The mechanized support section, comprising a base, connected with a hydro-resistant with overlap, on which a flexible-shell cylinder is installed, and a movement mechanism, connected with a hydraulic beam, with a base beam, characterized in that, in order to increase the reliability of maintaining an unstable roof under conditions of restless hypsometry, it is equipped with prismatic flexible vessels with wear-resistant tips, flexible tubes, the latter of which are installed under the base parallel to its longitudinal axis, mechanically and g dravlicheski All this time, the flexible tubes 13 remain with. connected with the downhole side in an arcuate state, unstressed between the soil and the base, partially relieving the protrusion of the soil under the toe of the base from excessive crushing. After idling the excavation mashina, the support base is extended. For this, the working fluid is supplied to the piston cavities 9 of the jacks of the movement of 8 groups of sections, which develop forces that cause the base beam 11 to move to the face. Moving base beam 11 by means of a movable cage, and with a scoop - by means of a fixed cage, the movement mechanism is made of double-arm levers installed on both sides of the base and fixed with one ends on the base beam, others on the movable casing, and the middle part with an upper cavity, with a flexible shell made with longitudinal rows of holes, in which prismatic gibs are installed, the two-shoulder 35 vessels are displaced, joined together in two levers 18, as a result of which the flexible tubular girders are. 13 are straightened and pressed against the base 7. Next, the operations are repeated. The slump of the roof during the excavation cycle is restrained by elastic elements (22 and 23) of overlap 1, the rock pressure of the descending stratum of the roof is perceived by the cylinder 4, by hard parts of the overlap (2 and 3) and transmitted through the hydraulics 12 to the base 7 and the soil of the formation. Invention Formula The mechanized support section, comprising a base, connected with a hydro-resistant with overlap, on which a flexible-shell cylinder is installed, and a movement mechanism, connected with a hydraulic beam, with a base beam, characterized in that, in order to increase the reliability of maintaining an unstable roof under conditions of restless hypsometry, it is equipped with prismatic flexible vessels with wear-resistant tips, flexible tubes, the latter of which are installed under the base parallel to its longitudinal axis, mechanically and guide evenly connected with the downhole side by means of a movable cage, and with a scoop - by means of a fixed cage, the movement mechanism is made of double-arm levers mounted on both sides of the base and fixed with one ends on the base beam, others on the movable casing, and the middle part is connected with a pull and a slider with the upper cavity, while the flexible shell is made with longitudinal rows of holes,  Rig.2 1 yy // 1 /// // /// P 15 1} w 9g.z 5-5 2 25 9g 9 games at