PL158723B1 - Method of and hydraulic roof support system for rearranging a packing dam - Google Patents

Abstract

1. A method of moving a filling barrier in the direction of an empty mined chamber and the face of a wall using hydraulic servomotors of sections of a mechanized mine lining holding the barrier regardless of movement, in particular for wet sand, wet dust or dry dust filling, characterized in that the filling barrier is suspended movably on the rear frame of the roof-bar of the hydraulic mechanized lining together with a filling pipeline, where cyclically, following extraction of coal by a combined machine, sections of the lining are moved, leaving the barrier in place, while following the third take of the combined machine the filling pipeline is detached at the point of connection with a pipeline situated in the under-wall gangway, and using hydraulic servomotors situated on the foot piece of the wall lining, the filling barrier is moved on the frame on the entire length of the wall in the direction of the face together with the wall filling pipeline, and further sections of the lining are lowered and moved to the face of the wall, while the resulting empty chamber is filled with filling with the barrier in any position, preferably in positions at the ends of the frame following the third or sixth take of the combined machine.4. Hydraulic mine lining assembly for moving a filling barrier, consisting of a typical lining section having in particular deflectable rear roof-bars on the side of the filling or roof fall, and also of foot pieces with the slider of a long-wall conveyor, and props for spacing the roof bars of the section between the floor and the roof, characterized in that the rear roof-bar (8) has a frame (1) with a slidable beam (2) with arms (3) [à]<IMAGE>

Description

The subject of the invention is a method and a set of a hydraulic mining support for shifting a backfilling dam in longwall mining excavations.

The hydraulic mining supports, known from the Polish People's Republic patents No. 71 202 and No. 66 266, are put together and cooperate with the backfilling dam. These solutions are characterized by the fact that individual sections of the casing are coupled to the conveyor by means of a hydraulic shifter. Also with the conveyor There is a backfilling dam. It is located in the rear part of the casing on the side of the selected coal cavity and consists of a metal scaffolding supported on the floor and poles connecting the scaffolding with the conveyor. Tetallic scaffolding It is extendable and can be lengthened or shortened depending on the height of the deck. From the side of the void filled with liquid support, a fabric is suspended on the scaffolding, separating the backfill from the working space of the casing. In the lower part of the metal scaffolding, the dam has a pole, resting on the floor and connected at its other end to the conveyor. The poles are located between the runners of two adjacent sections of the casing and have an inclined strut supporting the metal scaffolding halfway up its height. The assembly made up of the hydraulic casing and the filling dam is rhythmically moved into the Mara of the wall progress. As soon as the mining machine, for example a coal-mining shearer, has passed the casing section, the section is moved to the face of the wall. The shifting of the casing section takes place by means of a hydraulic shifter located in the floor and attached to the conveyor, which is supported by other adjacent stretched sections of the casing in this situation as a support. In the new position, the casing section is stretched between the floor and the floor and thus becomes a strong support for the conveyor to be moved. The piston of the hydraulic ram is pushed towards the face of the wall and thus pushes the conveyor. Along with the conveyor is a dam drawn by poles attached to the conveyor chute and the metal tarose frame. It follows that the backfilling dam moves each time a distance equal to the displacement of the conveyor, and thus the distance of the displacement of the casing section. The length of this section is essentially equal to the capacity of the cutting machine, i.e. equal to the width of the drum with which the combine is equipped.

The hydraulic mining supports, known from the Polish People's Republic patents No. 93 301 and No. 75 877, are directly connected with the backfilling dam. The metal scaffolding of the dam, located on the side of the void left by the selected coal and intended for backfilling with sand, is attached to the last support stand on the side of the post-exploitation void. In the casing according to the patent specification No. 93 301 the metal dam scaffolding comprises hydraulic props supporting the dam. These stands are hydraulically spread between the floor and the ceiling. They are attached to the housing stand by means of hydraulic sockets placed parallel to the floor. In this way, when the erection of the casing after being stolen is moved to a new position against the wall, the filling dam remains in place supported by the hydraulic props forming its metal scaffolding. The independence of the movements of the casing sections and the dam is made possible by horizontal cylinders. After the housing section is moved to a new place, it stretches between the floor and the ceiling. AIE is then released from the distraction of dams and hydraulic racks fully spread using the casing as a stable support is moved in the direction of backfilling dam face śMany ^for jp ^ OCA hydraulic sitownikćw Mcowsny ^ ^y ^ c tondraM to Mojaków ^of bud s ^head, ttoczyskami the rack dam. Depending on the working length of the hydraulic cylinders of the engine cylinders, the dam is shifted by a distance equal to the displacement of the casing or by a multiple of this section for appropriately longer cylinders.

A disadvantage of the known solutions from the cited patents is that the dams are displaced only by a gap equal to the displacement of the housing. This means that the distance from the face of the dam displaced mass doggie podsadzającego void is small because few tens of ^{meters which} nth etrćw. ^U elm ^{to zt} y ^ ^m jętośó space, t ^{k with} Ra as nai.eży jpodsadzić of Ca ^^ ^s e ^s a ^{n zp} iasku in ^{conjunction A j} e ^s t c ^o nieM.el.ka ^and szc ^of the ególnie niekorz tnty ^p ^ ^r estrzeń this ^thi t ^the ASKA. "It ± ^possibly sentences ^that asadiarie ^ ^p iaskiem mixed ^{with in} an ode ^j

158 723 of space does not provide an effective refilling. Sand deposited in this space, after draining off the water, forms an insufficiently compacted mass. It is insufficiently compacted. As a result, the roof rocks failing to meet sufficient support, crumble and crumble and settle beyond the permissible limit. Observations show that too narrow a backfill space results in too high a flow velocity of the proppant mixture, which does not favor sand settling in a manner ensuring that its thickness is sufficiently compact. According to the solution in patent No. 93 302, in order to achieve the shift of the dam every third shift of the casing, in order to provide a wider field of backfeeding, the actuators connecting the dam with the casing would have to reach as far as the conveyor area, i.e. partition the space under the canopies, and thus prevent communication along the longwall excavation. .

The backfill dam assembly of Patent No. 75,877 also does not provide the conditions necessary for an effective roof backing. The backfilling dam according to this invention coupled with the casing is adjusted by two cuts of the roadheader, so in practice it is shifted every one meer, while proper backfilling of the excavation with sand and water backfilling requires that the backfill space be nearly two times wider. In addition, known backfilling dams are associated with the movement of the conveyor housing or actuators, which limits their scope of use and shifting, and practically when individual sections of the housing move forward, the dams move partially or entirely to the end of the rear canopy, where they are backfilled with sand and water mix . When looting the lining down, the backfilling pipes must be dismantled or fully unfastened, and the backfilling cloth on the front dams is usually left partially with backfilling. When the casing moves forward, as a rule, the ceiling of the wall remains open, which, with the deck inclination, part of the void filled with a water-sand mixture always has the so-called zero backfilling, i.e. an unfilled void and the lack of ceiling support, which increases the exposure of the unsecured ceiling with each forward movement of the support, and thus creates a risk of partial or complete rock fall. The problem of obtaining a wide backfilling field with protection of the roof was obtained partially in accordance with the patent No. 126 301, but a large crowd of sections in the wall, rotated by a half-full angle relative to each other, prevents communication in the wall and does not ensure the full movement of the backfilling pipeline when leaving the casing section. The abovementioned defects from the known and cited patents make it impossible to prevent works related to blocking the filling field.

The object of the invention is to eliminate the widespread manual erecting of proppants there by mechanizing the wide damming of the proppant field independently of the casing movement and under the secured ceiling by the casing rear canopy by shortening the distance from the face of the face to the proppant.

The method of shifting the backfilling dam towards the post-exploitation void and the face of the wall according to the invention consists in the fact that the backfilling dam is slidably suspended on the frame of the rear canopy of the mechanized casing together with the backfilling pipeline, and then cyclically, after the coal cutter is prepared by the combine, the sections of the casing are moved dam in place. After the third harvest of Ιωιή ^ άΜ, the backfilling pipeline is stretched at the point of connection with the pipeline located in the sub-longwall sidewalk and, using telescopic hydraulic squirts located on the floor support floor, the backfilling dam is moved on the frame towards the face along with the longwall filling pipeline. It then lowers and moves the casing sections to the face of the wall. The post-exploitation void is flushed out with a water-sand, water-dust or dry dust filling in any position of the dam, preferably at the ends of the frame, after the third or sixth collection of cells. The displacement of the backfilling dams takes place simultaneously along the entire length of the wall. Fig. 3 shows the individual phases of the dam position on the canopy frame during coal mining.

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Depending on the length of the rear canopy of the longwall lining and the length of the barre situated downstream from it, the number of cyclic shifts of the lining forward can be increased with the dam and the backfilling pipeline left in place, thus obtaining any post-exploitation void intended for backing. It is preferable that the backfill process is started with the backfilling dam close to the base housing at positions I and III on the rear canopy frame. It is also preferable to start the prop-up at least after the fourth cycle of the whole frame advance, at position I on the canopy frame of the rear housing. Due to the fact that the dam is equipped with multi-layer filters, during the backfilling, water is partially drained and fine clay or dust fractions are retained on the dam. The filters are replaceable and can be rinsed with water after each damaging or depending on the needs. It is preferable that the filters take up only the necessary amount of water to run off the front sliding dam due to clay or dust contamination getting into the support sections, making it difficult to operate the powered supports.

The hydraulic mining support set for shifting a backfill dam according to the invention consists of sections of a typical support having, in particular, tilting rear canopies on the landing or cave side, floor runners with a wall conveyor slider and stands for expanding the canopy sections between the floor and the roof. The rear rafters sits on a frame equipped with a sliding beam with arms, to which the metal skeleton of the loading dam is attached, and the supporting pipeline is articulated. It is preferred that the individual sections of the proppant pipeline have known detachable flexible ball-and-art joints to allow the pipeline to be twisted at a connection by an angle. An elastic band, preferably rubber, is attached to the metal skeleton, with a width not greater than that of the rear canopy. <m ^^ tsce of rubber band, you can also use buckle fabric belts sewn several times. The elastic tapes of the individual sections are connected with each other by means of specially profiled H-shaped elastic connectors. These connectors, in the places of the protruding horizontal beams of the metal frame, are inserted into the cutouts of these beams. Connectors have holes in the central part with built-in filters for draining and filtering the water during filling the post-exploitation void. The metal skeleton of the dam has separable sections, allowing its height to be changed depending on the thickness of the deck. Instead of the sliding beam, a wheeled or ball sliding carriage can be used. ^^ The number of arms to which the metal scaffolding is attached must be at least equal to the beam pitch in the frame.

Elastic bands in the lower part have a foot bent to the top of the part of the supported excavation. The ends of the straps are attached to the withdrawable string placed in the spring floor. Hydraulic cylinders are also installed in the floor, two of which are articulated with the lower beam of the dam's metal scaffolding, and the third is connected with the metal frame of the dam above its central part.

The presented set of hydraulic mining support with an adjustable dam according to the invention, thanks to the hydraulic tee-shaft, allows the dam to be positioned at various angles with respect to the front of the supported part.

The subject of the invention is shown in the embodiment in the drawing, in which Fig. 1 shows the assembly in general view, and Fig. 2 shows a backfilling dam and cross-sections AA in the place of joining elastic bands at the projecting beams of the metal skeleton and BB of the elastic band connector with drainage of water. and Fig. 3.

The rear roof ridge 3 has a frame 1 equipped with a sliding beam 2 with arms 3, to which the mta ^ ι ^ z frame 5 of the filling dam and articulated support pipeline 4 are attached. The metal frame 5 is covered with an elastic band 6 with a width not greater than the width of the rear canopy 8. The elastic tapes of 6 individual sections are connected by means of special H-shaped H-shaped connectors 9, having

158 723 with openings in the central part with integrated filters 10 for draining and filtering the water. The ends of the elastic bands 6 fastened with the arm to the pull rod 11 of the spring 7 placed in the rear floor 12. The rear floor 12 also has hydraulic cylinders 13 and 14, of which two cylinders 13 are connected to the lower beam 15 of the metal skeleton 5 of the dam, and the third cylinder 14 connected jeet with the matte frame 5 above its middle part.

The metal skeleton 5 of the dam has separable sections 16, allowing the height to be changed during coal mining.

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Aj. 3

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Department of Publishing of the UP RP. Circulation of 90 copies

Price: PLN 10,000

Claims (4)

Patent claims 1. The method of shifting the backfilling dam towards the post-exploitation void and the face of the wall by means of hydraulic actuators holding the dam, regardless of the movement of the mechanized section of the mining support, especially for water-sand, water-dust or dry dust backfilling, characterized by the fact that the backfilling dam is the hydraulic roof support of the powered roof support is slidably suspended on the frame of the backfilling pipeline, and then cyclically, after coal is prepared by the kombjn, it moves the support sections, leaving the dam in place, and after the third collection of the kombjn, the backfill pipeline is stretched at the connection point with the pipeline in along the longwall sidewalk and with the use of hydraulic actuators located on the bottom of the longwall casing, the loading dam is moved on the frame along the entire length of the wall towards the face along with the longwall filling pipeline, and then the sections of the casing are lowered and moved to the face of the wall with the resulting void post-exploitation is flushed with a backfill in any position of the dam, preferably in positions at the ends of the frame after the third or sixth harvest of the roadheader. 2. The method according to p. A method as claimed in claim 1, characterized in that, depending on the length of the rear canopy of the wall lining and the length of the frame situated beneath it, the number of cyclic displacements of the housing forward with the dam with the pipeline left in place. 3. The method according to p. The method of claim 1, characterized in that a partial, controlled filtration of water during backfilling takes place, the post-exploitation void. 4. A set of hydraulic mining support for shifting a loading dam, consisting of sections of a typical support, especially having tilting rear canopies on the side of the filling or caving, floor conveyors with a wall conveyor shifter and stands for expanding the seccc canopy! between the floor and the ceiling, characterized in that the rear canopy / 8 / has a frame / 1 / equipped with a sliding beam / 2 / with arms / 3 /, with a height at least equal to the beam's pitch / 2 / in the frame / 1 / and fixed to them articulated with a proppant pipeline / 4 / with a sliding metal frame / 5 / dams, covered with a flexible tape / 6 / with a width not greater than the width of the rear canopy / 8 /, while the elastic bands / 6 / of individual sections are connected using the special H-shaped flexible connectors / 9 / with holes in the central part with inserted fibers / 10 / for draining and filtering water, and in places protruding horizontal beams of the main frame / 5 / embedded in extensions of these beams, and the ends of the elastic bands / 6 / are attached to the extendable strand / 11 / springs / 7 / located in the rear floor / 12 /, also having hydraulic cylinders / 13 /, / 14 /, of which two cylinders / 13 / are articulated with the lower b elka / 15 / of the metal frame / 5 / dam, and the third actuator / 14 / is connected to the metal glass / 5 / above its center parts. 158 723