SU1740666A1 - Ore deposit working method - Google Patents

Abstract

The invention can be used in the development of inclined, steeply dipping and flat ore deposits. Transport, ventilation and drilling rising embankments pass. The deposit is worked out by panels in a descending order with advanced development of the overlying panel. Ore extraction in panels is carried out by primary and secondary chambers. In the upper part of the deposit, the rock panel is formed by conducting the field work outside the deposit and sling it with the ventilation workout of the underlying ore panel with drilling revolving workings in the alignment of the primary chambers of the ore panel. Secondary chambers of the upper ore panel are worked in the alignment of the primary chambers of the lower ore panel. The clearing recess is started by working out the primary chambers of the upper ore panel. After mining of the primary chambers of the upper ore panel, rock cutting is performed in the chambers of the rock panel. In the alignment of the chambers of the rock and adjacent ore panels, fine filler of the bookmark is folded with the holding material and jumpers are installed on both sides of the folded material in the ventilation design. They form storage tanks and fill them with water. Repulsed rock from the chambers of the rock panel is transported by supplying water from the tanks to the stockpiled fine pollen, which is transferred with water energy to the rock and the waste primary chambers of the upper ore panel are filled with the formed mixture. Repulsed ore is issued for transport production of water supply to the bulk of the ore. The developed space is laid with a hardening mixture. During the hardening of the bookmark in the primary chambers of the upper ore panel, the primary chambers of the lower ore panel are worked out, after mining of which the secondary chambers of the upper ore panel are worked out and the primary chambers are laid in the lower ore panel, and the rock is broken in the secondary chambers of the upper ore panel and moved to the primary chambers of the lower ore panel alternately with ore blasting. The ore flow is separated from the rock flow by installing a jumper at the junction of the transport output with the primary chamber of the lower ore panel. In addition, rock movement in the primary chamber of the lower ore panel is carried out by flushing it with a stream of water. Moving the rock to the primary chambers of the lower ore panel is also carried out by mechanically moving it through the transport excavation. 2 hp ff, 13 ill. (L with XI O S Os O

Description

The invention relates to mining and is mainly used in the development of inclined, steeply dipping and gentle ore deposits.

A known method for the preparation and transportation of hardening bookmarks, used at the Central Kansai mine, which means that the rock extracted during the tunneling works is delivered to the ore pass and unloaded into it, sand-cement mortar is also fed there. on ore pass. Then the mixture is manually transferred to the place of laying and level.

The disadvantage of this method is the high cost of production of filling operations, since the operations of re-laying, laying and leveling the finished filling mixture are not excluded. Hence, the cost of bookmarks is high. In addition, small amounts of preparation and transportation of the filling mixture, as only large rocks are used as coarse aggregate, which are extracted during running work and do not provide for the extraction of large aggregate bookmarks in large quantities and in close proximity to the pledged chambers.

Closest to the invention is a method for developing inclined ore deposits, in which the excavation blocks are divided into two-adjacent panels located on the same horizon. The transport openings are located within two adjacent panels with a slope of 3-89 towards each other up to the border of the panels and a water collector is constructed in the place of their assembly. Ventilation openings in the area of adjacent panels are made with a reverse slope relative to the transport openings, from the common border to their flanks. At the junction of the ventilation workings with the drilling rising production (being worked out) chambers install collapsible water-guiding jumpers and water to the bulk of broken ore from a special tank is supplied through the fixed section of the ventilation workings. After the primary chambers have been worked out, they are laid down and, as the filling material of the standard strength is set, they start working out the secondary chambers.

The disadvantage of this method is the large material and labor costs for preparing the filling mixture and transporting it from the day surface to the developed space of the pledged chamber.

The aim of the invention is to reduce the cost of the bookmark by reducing the consumption of the traffic and the transportation distance of the large aggregate.

The goal is achieved in that according to the method, which includes carrying out transport, ventilation and drilling rising workings, mining deposits with ore panels, ore extraction in the panels with primary and secondary chambers, forming an accumulation tank, filling it with water, working out the ore in the chambers, feeding water from the tank to the bulk of broken ore and its issuance for transport generation and laying of the chamber’s spent space with a hardening mixture, the deposit is processed in panels in descending order with the leading working out the overlying panel, in the upper part of the deposit, decorate the rock panel by conducting outside the deposit of the field workings and assembling it with the ventilation output of the underlying ore panel by drilling revolving workings in the alignment of the primary chambers of the ore panel, the secondary chambers of the upper ore panel are working in the alignment of the primary chambers the lower ore panel, the clearing excavation begins by working out the primary chambers of the upper ore panel; after mining the primary chambers of the upper ore panel, the poro In the chambers of the rock panel, in the alignment of the chambers of the rock and adjacent ore panels, fine filling of the bookmark is folded with the burning material, and on both sides of the folding material, in the ventilation excavation, remarks are made, the broken rock from the chambers of the rock panel is transported by supplying water from the tanks to the stored fine aggregate, which is mixed with rock energy with the rock and the waste primary chambers of the upper ore panel are filled with the resulting mixture, during the hardening of the bedding in the primary chamber x upper ore panel, the primary chambers of the lower ore panel are worked out, after mining of which the secondary chambers of the upper ore panel are worked out and the primary chambers in the lower ore panel are laid, at the same time they beat rock in the secondary chambers of the upper ore panel and move it to the primary chambers of the lower ore panel alternately with ore blasting, with the ore flow being separated from the rock flow by installing a jumper at the junction of the transport output with the primary chamber of the lower ore panel.

Moving the rock in the primary chamber of the lower ore panel is carried out by flushing it with a stream of water.

Moving the rock to the primary chambers of the lower ore panel is carried out by mechanically moving it through the transport excavation.

The excavation of field workings in the upper part of the deposit beyond its borders, through the rock, and its alignment with the ventilation workout of the underlying ore panel by drilling reaming mines in the alignment of the primary chambers of this ore panel allows the formation of a rock panel and mining the waste rock from this panel to use it as a large filler of the bookmark in the immediate vicinity of the primary chambers to be laid below the ore panel, and the drilling of wells into the rock mass from the drilling rising workings of the overlying s pedigree panel and breaking rock after working chambers underlying primary ore panel allows blasting by coarse aggregate to prepare Bookmarks

This reduces the cost of crushing and delivering the aggregated aggregate from the surface separately or together with fine aggregate and in the sheeting material. In addition, the use of broken rocks as a coarse aggregate of the bookmark reduces the consumption of cement in proportion to the increase in the volume of coarse aggregate relative to the volume of the small aggregate with a binder. Installing jumpers in the ventilation hole on either side of the stored portion of the dry fine aggregate of the bookmark with the binder in the assembly of the overlying breeding chamber and the underlying ore chamber allows the overlying breeding chamber with the developed downstream ore chamber to be connected through the retractor section of the cover. and create a single channel for the passage of a hydrogen flow and its leakage to the stored portion of the dry fine aggregate of the bookmark material and preparation due to this filling mixture

Conducting clearing excavation with advanced development of the overlying ore panel and associated mining of large. The backfill of the bookmark (rock) from the soil or the roof of the secondary chambers by arranging the secondary chambers of the upper ore panel in the alignment of the primary pledged chambers of the lower ore panel and alternating the extraction of ore and coarse aggregate (rock) allows the use of hard rocks from the soil or roof of secondary chambers of the overlying ore panel as a coarse aggregate for laying the primary chambers of the underlying ore panel, because in the development of low and medium power ore deposits with strong and stable rocks, usually secondary tab is not

0 produced t. without any negative consequences for mining, you can increase the space generated by the secondary chambers in one panel, take part of the waste rock out of it and, accordingly, reduce the amount of space generated by the primary chambers to be filled with hardening mixture in the other panel. no bookmark filler required

It is necessary to carry out special workings, since rock cutting is made from the same uphole drilling excavation, which is used for ore breaking. This reduces the cost of extracting large

5, a bookmark filler (waste rock) in underground conditions.

The mechanical movement of a large filler (rock) delivered by the mudslide to transport production, to

0 upper part of the developed space of the pledged chamber of the underlying ore panel with admixing into the rock mass of a fine filling of the bookmark with a holding material and subsequent seletra5 with the filling mixture allows for laying the chambers of the underlying ore panel in any order and at any desired part of the panel. bookmarks make

0 in two steps.

Figure 1 shows a section aa in figure 2 (in the horizontal plane in the stage of testing and laying of the primary chambers); figure 2 - section bb in figure 1 (laid

5 primary chamber and overlying breeding chamber); in fig. 3-section bb in FIG. 1 — the panel in the horizontal plane. At the moment of cutting and washing the ore in the secondary chamber of the upstream panel; figure 5 - the same, at the moment of laying the primary camera of the underlying panel; Fig 6 is a section of GG in Fig.4; figure 7 - section dd in figure 5; on Fig - panel in

5 the horizontal plane in the stage of moving and storing the rock mass in the upper part of the worked-out space of the primary chamber to be laid, a section; Fig.9 is a section of the EE in Fig.8; in fig. 10 - panels in the horizontal plane in the stage of release of water to the bulk of the backfill material stored in the upper part of the open space of the primary chamber, section; FIG. 11 shows a section through ZHZH of FIG. 10, FIG. 12 shows a section 3-3 of FIG. 13; in fig. 13 is a section through an AND-fig in FIG. 12 (rock panel in the horizontal plane),

PRI me R 1. Workable inclined ore deposit is divided into twin panels located on different horizons. The panels, in turn, are divided into excavation chambers. In this case, the secondary chambers of the overlying panel are located in the alignment of the primary chambers of the underlying panel. The preparatory work consists in carrying out the ventilation opening 1, located in the upper part of the overlying panel, ventilation and transport opening 2, located on the intermediate horizon between the upper and lower panels, and transport output 3 in the lower part of the underlying panel (Fig. 4). and 5). The ventilation 1 and the transport outlets 2 and 3 are knocked down between themselves by rising drilling openings 4, passed along the axis of the primary chambers, and drill rising 5, passed along the axis of the secondary chambers. In the upper part of the deposit beyond its limits, according to the rock, parallel to the ventilation shaft 1, the field mine 6 passes (Fig. 1). In the alignment of the primary chambers of the underlying (with respect to field production 6) panel, between ventilation 1 and field 6 mine workings, drilling rising embrasures pass 7. On the flanks of the panels, storage tanks 8.9 and 10 and a water collector 11 and 12 are constructed. Water tanks 11 and 12 construct by sinking short inclined workings from transport 2 and 3 workings. To seal the walls of the water tanks, the sprayed concrete is covered. In order to avoid solid particles drawn in the flow into the water collectors 11 and 12, a cascade of drainage bridges 13 and 14 is erected in front of the openings of the water collectors 11 and 12. Recurrent openings 15 and 16 and 17 are placed in the water collectors. pipelines are installed connecting the catchment basins 11 and 12 with storage tanks 8, 9 and 10 and providing a closed water supply circuit.

After completion of the specified preparatory work, they start the cleaning works.

The clearing recess begins with working out the primary chambers in the upper panel (Fig. 1). The ore is broken by blasting.

explosive charges in fan sets of wells 18, drilled into the ore massif from the drilling production well 4 (Fig. 3). After breaking the ore in the chamber at the junction

a vent hole 1 with an overhead pit 4, a water guide rail 18 is installed (Fig. 1). Having filled the storage tank 9 with water, open the shutter door and direct

0 flow over the fixed section of the ventilation hole 1 and the drilling riser 4 to the bulk of broken ore in the primary chamber. As a result of the interaction of the water flow with the ore in bulk, it forms 5 s - the mine mudflow-ore flow, which, under the influence of gravitational forces, moves down the chamber along the sloping soil and through the outlet of the mudflow assembly 20 enters transport output 2, where the stoppage takes place mine mud flow ore mass. After stopping the mine mudflow, an outflow of water occurs, which flows down a slightly sloping

5 to the soil of the transport outlet 2 in the direction of the catchment basin 11, Passing a cascade of drainage bridges 13 and 14, the flow of water leaves the particles entrained by the solid, and then the purified water enters the water collection tank 11. The water remaining in the collector 11 is pumped at the right moment pipelines laid in rising mine 16 and ventilation mine 1 again into the accumulating tank 9. The delivered and dehydrated ore mass from transport mine 2 is moved using self-propelled loading and transport equipment Vani to capital ore

0 or directly to the trunk.

Simultaneously with the clearing dredging of the ore from the primary chambers, the chambers that have already been spent are laid. For this, from the vent generation 1, remove the water guiding jumper 19 and start transporting the dry sand-cement mixture coming from the surface through a special well of large diameter. Delivered to vent

0, the production of 1 dry sand-cement mixture is stored at the site of settling assemblies 22 and 23 (Fig. 1).

Having laid a predetermined portion of the dry sand-cement mixture in the alignment of the pipelines 5 of the knocks 22 and 23, on both sides of these knocks in the ventilation development 1, selector jumpers 24 and 25 are installed. Then, drilling 26 wells is drilled from the recovery well 7. .2) into the rock massif and after charging these wells, the rock is beaten off. Then, in the field excavation 6, in the place of its connection with the drilling reemerging 7, a water guide jumper 27 is installed. After filling the storage tank 8 with water, the shutter door is opened and the water flow is directed along the fixed section of the field development 6 and the drilling recovery output 7 to the bulk broken rocks in the chamber. As a result of the interaction of the water flow with the bulk of the broken rock, a mudflow mudflow stream is formed, which under the influence of gravitational forces on the inclined soil of the rock chamber moves downwards and through the muddy sludge 22 enters the frozen section of the ventilation output 1 and the muddled dredging 23 where flows on the previously stored portion of the dry sand-cement mixture. Due to the flow of water-rock flow to the stored mass of the sand-cement mixture, a movable backfill mixture is formed, which moves downwards and fills the developed space of the primary chamber.

Thus, all the primary cameras in the upper panel are bookmarked. And during the hardening of the filling mixture, the primary chambers are tested in the underlying panel.

After working out the primary chambers in the underlying panel, the secondary chambers in the overlying panel are started to be developed with the simultaneous laying of the primary chambers in the underlying panel (Figures 4 and 5).

The breaking of ore in the secondary chamber of the overlying panel is carried out by blasting explosive charges in fan sets of wells 28 drilled into the ore massif from the drilling production well 5 (Fig. 6). After the ore is crushed in the chamber, at the junction of the ventilation output 1 with the drilling recovery outlet 5, a water guide bridge 29 is installed (figure 4). At the same time, a lightweight waterproof jumper 31 is installed in the septic tank 30 connecting the worked-out space of the primary chamber to be laid with transport generation 2. A solid barrier jumper 32 is installed in front of the waterproof jumper. After filling the storage tank 9 with water, the door is opened the shutter 33 and direct the flow of water through the fixed section of the ventilation development 1 and the drilling recovery formation 5 to the bulk of broken ore in the chamber. As a result of the interaction of the flow of water with bulk ore

A mine mudflow is formed, which, under the influence of gravitational forces, moves downward and through the outlet opening through the inclined soil of the chamber.

The mudflow siding 34 enters transport output 2, where the ore mass transported by the mine mudslide stops. After stopping the mine mudflow

0 there is an outflow of water that flows through the slightly sloping soil of the transport output 2 in the direction of the sump 11. In this case, the previously installed waterproof jumper 31 will prevent water from flowing into the developed space of the underlying primary chamber of the underlying panel. Having completed a cascade of drainage bridges 13 and 14, the flow of water leaves solid particles

0 then the purified water enters the catchment basin 11. At the right time, the water in the catchment basin is pumped by the pump 21 through pipelines laid in the rising bed 16, again

5 into the storage tank 9. The delivered and dewatered ore mass from the transport output 2 is moved with the help of self-propelled loading and transport equipment to the main shaft or dump.

After shipment, the broken ore drilled from the secondary chamber of the overlying panel, fencing 32, and the waterproof 31 lintels are removed. Then, delivery of a dry sand-cement mixture coming from the surface through a special well of large diameter was carried out. Delivered sand-cement mixture is stored at the site of semiconducting

0 sboek 34 and 30 (figure 5). Having laid a predetermined portion of the sand-cement mixture in the alignment of selenopravlyushchikh glands 34 and 30, on both sides of these gangs in the transport excavation 2 install selentive pereklyuchki 36 and 35. Next, the rock layer is broken from the roof of the secondary chamber of the overlying panel. Rock cutting is performed by blasting explosives in fan sets of wells drilled into the overburden of the roof from an ascending production well 5 (Fig. 7). After the storage tank 9 is filled with water, the shutter door 33 is opened and the water flow is directed through the closed section.

5 of the ventilation development 1 and the drilling ascending development 5 to the bulk of the broken rock in the chamber. As a result of the interaction of the water flow with the bulk of the broken rock, a mudflow mud-water flow is formed, which under the action of gravitational forces moves down the chamber along the sloping soil and through the mudflow conduit 34 (ph (.5) goes to the bridged section of the transport output) 2 and the muddy coupling 30, where it flows over the previously stored portion of the sand-cement mixture. Due to the flow of water-rock flow onto the stored mass of the sand-cement mixture, a movable inlet mixture is formed, which moves down, filling the developed space of the primary chamber of the underlying panel, then cleaning the cross-linking bridges and installing a waterproof 31 and bridging 32 bridges.

The cycle of operations continues in alternately crushing the ore and rock layers in the secondary chamber of the overlying panel and flushing the broken ore into transport production, and the waste rock together with the sand-cement mixture mixed with it into the developed space of the primary chamber.

Thus, the excavation of field workings in the upper part of the reservoir beyond its borders, over the rock, and its assembly with the ventilation workout of the underlying panel by drilling, rising in the alignment of the primary chambers of this panel, allows the production of waste rock to be used as a large filler proximity to the pledged primary chambers of the underlying panel. And the drilling of wells into the rock mass from the drilling rioters that have been passed above and the breaking of the rock after the primary chambers of the underlying panel have been completed allows large-scale aggregate to be laid by drilling blasting. This reduces the cost of crushing and delivering coarse aggregate bookmarks and cement consumption for preparing the bookmark by a factor of 2-3 by increasing the volume of coarse aggregate relative to the volume of fine aggregate with the holding material.

Storing a portion of the shallow filling of the bookmark with the holding material in the alignment of planting failures of the overlying breeding chamber and the underlying primary (ore) chamber and the installation of selector bridges in the ventilation (transport) development on both sides of the village-conductive sdekok allow you to create a single channel for both chambers (upper pedigree and lower pledged primary chamber) and use the interleaved section of the ventilation (transport) excavation to pass the water-flow from the overlying chamber underlying lays chamber and simultaneously filling mixture for the preparation of inleakage due to flow vodoporodnogo stockpiled portion of fine aggregate with the binder material.

Conducting a clearing notch with paired panels located on different

The 0 horizons are ahead of the overlying panel relative to the underlying and the location of the secondary chambers in the alignment of the primary chambers of the underlying panel allows the use of broken portions of the roof or soil of the secondary chambers of the upper panel as a large bookmark filler for the primary chambers of the underlying panel. At the same time, for the extraction of coarse aggregate, the bookmark does not require any special workings, since rock cutting is made from the same uphole drilling that is used for ore blasting. This reduces the cost of mining large

5 placeholder (waste rock) in underground conditions

Alternating the blasting of ore in the overlying secondary chamber with blasting of the rock layer from the roof or soil of this chamber and

The installation of the fencing barrier at the junction of the transport excavation with the muddy conducting chamber of the underlying primary chamber makes it possible to separate the ore flow from the rock flow and use the transport output only to receive the broken ore delivered from the secondary chamber of the upper panel and thereby increase the intensity of refining operations,

0

PRI mme R 2. Workable inclined ore deposit is divided into twin panels located on different horizons. The panels, in turn, section 5 are on the excavation chambers. The preparatory work, as in the previous case (example 1), consists in carrying out ventilation generation 1, ventilation - transport generation 2 and

0 transport outlets 3, which knock down between themselves the drilling rigs 4 and 5. On the flanks of the panels they construct storage tanks for water 9 and 10 and water collectors 11 and 12, Before

5 water collectors 11 and 12 construct a cascade of drainage bridges 13 and 14, and to ensure a closed circuit of water supply next to the water collectors, revolving openings 16 m 17 are placed, in which pipelines connecting the

collectors 11 and 12 with accumulating tanks 9 and 10

After the completion of these preparatory works, they start the cleaning and filling works (Figures 8 and 10).

The rock breaking in the secondary chamber of the overlying panel is carried out by blasting explosives in fan sets of wells drilled into the overburden of the roof from an ascending drilling well 5 (Fig.9).

Repulsed rock is washed off with a stream of water supplied to the pile from the storage tank 9. To do this, in the ventilation hole 1 at the point of its connection with the drilling recovery hole 5, a dismountable water guide jumper 29 is installed (Fig. 8). After the storage tank 9 is filled with water, the shutter door is opened and the water flow is directed through the closed section of the ventilation development 1 and the drilling recovery excavation 5 to the bulk of the broken rock. As a result of the flow and the bulk formation, a water-rock flow is formed which, under the action of gravitational forces, moves down through the sloping soil of the chamber and through the outlet of the village - conductive shedding 34 enters the transport generation 2, where the stop is taken by the flow of LO.RODNAYA mass after stopping in before the rock flow, water flows out through the weakly sloping soil of the transport output 2 in the direction of the tank 11 Passing through a cascade of drainage bridges 13 and 14, the stream leaves solid particles drawn by it, and then the cleaned Veda enters the tank 11. water is pumped at the right time with the help of a pump 21 through pipelines laid in rebuilding excavation 16 to storage tank 9 (Fig. 8). The delivered and dewatered rock mass is transported using self-propelled loading and transport equipment. The equipment according to transport making 2 to the primary chamber of the underlying panel located next to it (Figures 8 and 11). The rock mass is delivered and stored in the upper part of the open space of the underlying primary chamber, the precipitated breed is siphoned from shedding 37, passed in a horizontal plane and connecting the developed space with transport output 2 (Fig. 11). Simultaneously with the movement of the rock mass, a dry sand-cement mixture is delivered to the underground workings from the surface through a special well of large diameter. The sand-cement mixture delivered is mixed into the rock mass. After the underlying primary chamber is delivered to the upper part of the developed space of all the components of the solid component of the filling mixture, the storage tank 10 is filled with water, and in the transport excavation 2 at the place of its connection with the horizontal

0, with the coupling 37 (FIG. 10), a collapsible water-guiding bridge 38 is installed. Then the door-shutter is opened in the storage tank 10 and along the locked section of the transport output 2

5, water is fed to the bulk of the solid component of the filling mixture stored in the upper part of the open space of the underlying primary chamber. After the water flow interacts with

0 in bulk, a movable backfill mixture is formed, which, under the action of gravitational forces, moves down the inclined soil of the primary chamber being laid down, filling the developed space

5 of this camera. And at this time, the layer of ore is blasted in the secondary chamber of the lining panel and washed away into transport making 2 (Fig. 10).

The work cycle continues in the alternate cutting of the ore and rock layers in the secondary chamber of the overlying panel, their washing into transport production and further transportation of broken ore to the discharging trunk, and broken

5 of the breed mass - into the developed space of the pledged chamber.

Thus, due to the mechanical movement of a large aggregate (rock) delivered by the mining mudflow to the transport production, to the upper part of the developed space of the laying chamber of the underlying ore panel with mixing1 into the rock mass of the small aggregate of the bookmark

5, it becomes possible to make the cameras of the underlying panel in any order and at any desired part of the panel.

0 PRI me R 3. Workable steeply dipping ore deposit is divided into sub-floors. Extraction chambers are located in the uprising and are divided into primary and secondary. In the sublevels, transport outlets 39 are made and from them drilling outlets 40 into each chamber being worked out. In the upper part of the deposit beyond its limits, ventilation openings 41 and transport openings 42 pass through the rock, which are knocked together by drilling.

rebellious workings 43 On the flank of the rock panel they construct a storage tank 44.

After completion of the specified preparatory work proceed to the cleaning and backfilling work.

Primary chambers within the block are mined by cutting ore from sublevel drilling workings 40 and releasing it in the bottom of the block.

After the primary chambers have been worked out, they are laid with a hardening mixture. To do this, from the rock chambers, a large aggregate of bookmark (rock) is mined. Rock cutting is carried out by blasting explosives in fan sets of wells drilled into the rock mass from a drilling production well 43 (Fig. 12). Then, in the ventilation development 41, at the place of its connection with the recovery riser 43, a water guide bridge 45 is installed. At the same time, delivery of the dry sand-cement mixture arriving from the surface through a special well of large diameter is performed. The sand-cement mixture delivered to trans-orbit production 42 is stored in the site of planting connections 46 and 47 (Fig. 12). Placing a predetermined portion of the sand-cement mixture in the alignment of plant-carrying connections 46 and 47, on both sides of these connections in transport excavation 42, selector-guiding jumpers 48 and 49 are installed. Next, the storage tank 44 is filled with water from the mine water pipeline laid in the ventilation excavation 41. After the storage tank is filled, the shutter door is opened and the water flow is directed through the closed section of the ventilation hole 41 and the drill lifting hole 43 to the rock of the broken rock in the chamber. As a result of the interaction of the water flow with bulk of the broken rock, a mudflow mud-water flow is formed, which, under the action of gravitational forces, moves down the chamber along the sloping soil and goes through the muddy junction 46 (Fig. 13) to the jumbled section of the transport excavation 42 and the muddy pipe 47, where it flows into the previously stored portion of the sand-cement mixture.

Due to the influx of water-flow into the stored mass of the sand-cement mixture, a movable filling mixture is formed, which, according to the coupling 47, enters the developed space of the underlying primary chamber. Then, the locating crosspieces 48 and 49 are cleaned.

The cycle of work continues in the breaking of the next layer of rock, storing a portion of the sand-cement mixture and launching water on the rock in the chamber.

After the laying of the primary chambers, the secondary chambers are started to work on the secondary chambers and, as necessary, to lay them out in a similar way.

Thus, the excavation of field workings in the upper part of a steeply dipping deposit beyond its limits, along the rock, makes it possible to form a rock panel and carry out

5 Extraction of waste rock from this panel for use as a large filler in the bookmark in the immediate vicinity of the pledged chambers. This reduces the costs of crushing and

0 delivery of coarse aggregate from the day surface In addition, the use of broken rocks as a coarse aggregate of the bookmark reduces the consumption of cement in proportion to the increase in the volume of the coarse aggregate relative to the volume of the small aggregate with loose material.

Installing jumpers in the transport development on both sides of the stocked portions of small bookmark filler

0 with a bridging material in a cross-section of interconnecting bridges allows the overlying breeding chamber to be connected with the developed ore chamber's space through the snapshot section of the transport development and create a single channel for passing the rock-borne flow and flowing it into the stored portion of the shallow fill bookmark. by the holding material and the preparation due to this

0 filling mixture.

Claims (3)

Claim 1 Method of development of ore deposits, including carrying out transport, ventilation and drilling rigs, mining deposits by ore panels, dredging in the primary and secondary chambers, forming an accumulating tank, filling it with water, working out the ore in the chambers, feeding water from 0 tank to the bulk of broken ore and its issuance to the transport output and laying of the chambers developed space with a hardening mixture, characterized in that. in order to reduce the cost of bookmark due to 5 decreasing the flow rate in the traveling and the transportation distance of the large aggregate, the mining of the deposits by panels is carried out in a descending order with the advanced development of the overlying panel; in the upper part of the deposit, the rock panel by carrying out field excavation outside the deposit and assembling it with ventilation excavation of the underlying ore panel with drilling reaming mines in the alignment of the primary chambers of the ore panel, the secondary chambers of the upper ore panel are worked out in the alignment of the primary chambers of the lower ore panel, the cleaning cavity is started by mining the primary chambers the upper ore panel, after mining of the primary chambers of the upper ore panel, rock is blasted in the chambers of the rock panel, in the alignment of saboks of the rock and adjacent ore panel put a small aggregate of the bookmark in the holding material and on either side of the folded material in the ventilation development, jumpers are installed, the broken rock from the chambers of the rock panel is transported by supplying water from the tanks to the stored fine aggregate, which is filled with waste energy with the energy of the rock and the formed mixture primary chambers of the upper ore panel, during the hardening of the bed 0 five In the primary chambers of the upper ore panel, the primary chambers of the lower ore panel are worked out, after mining of which the secondary chambers of the upper ore panel are worked out and the primary chambers are laid in the lower ore panel, while the rock is broken in the secondary chambers of the upper ore panel and transferred to the primary chambers the bottom ore panel alternately with ore blasting, and the ore flow is separated from the rock flow by installing a jumper at the junction of the transport output with a primary primary chamber Ery lower ore panel. 2. A method according to claim 1, characterized in that the movement of rock in the primary chamber of the lower ore panel is carried out by flushing it with a stream of water. 3. The method according to claim 1, characterized in that the rock is moved into the primary chambers of the lower ore panel by mechanically moving it along transport making .. A-A 27 Bb 2  fie. four rig Ј in-in P $ gpf 9990WJ # g / jf & dgpf J j 69901711 sixteen f4 "N WITH so to t ju v v p # &  JAVA - .M // - // / "five 3 . " / 47 iif  i-.-i ..-. q.V.i c / 3