SU1276761A1 - Water drainage installation for mine - Google Patents

Abstract

The invention relates to the field of water lowering, in particular to installations for pumping water from mines and other underground workings. The invention is aimed at improving efficiency and reducing costs when the pump station is buried. This is achieved by the fact that in the installation with a pumping chamber, branches of the sump, clarifier, viewing development and an additional settler located in the adjusting tank, the latter is made recessed to the bottom level of the sump wells and is located between them and the sump boxes. Sight production is located above the place adjoining an additional settling tank to the branches of the catchment basin. When filling the regulating tank, the water flow goes through the clarifier, where large particles of solid inclusions fall out. The flow is then directed to the additional settling tank and the regulating tank. The remaining inclusions precipitate here, while the reception wells (L wells do not flare. After the upper level is reached, the pumps are turned on and the water is pumped out to the lower level. The proposed placement of the workings ensures minimal costs for their implementation and maintenance, and the drainage efficiency is drained. 3 mud. 05 a

Description

The invention relates to water lowering, in particular, to installations for mine drainage and pumping water from mines and other underground and underground workings.

The purpose of the invention is to increase efficiency and reduce capital and operating costs when the pump chamber is buried.

FIG. 1 shows the installation, plan view; in fig. 2 shows section A-A in FIG. one; in fig. 3 shows a section BB in FIG. .

The mine drainage installation has a buried pump chamber 1 with pumps 2, the vsas 3 of which are brought to the suction wells 5 and 6 through sealed jumpers 4. The installation is equipped with an additional settling tank 7, made interl. reception wells 5 and 6 and branches 8 and 9 of the sump. The bottom of the settling tank 7 corresponds to the level of the bottoms, wells 5 and 6. The adjusting tank B is made of composite from wells 5 and 6, the settling tank 7 and the limited overflow bridge 10 of the branch 8 of the water collector, the transition from the bottom of the settling tank 7 to the branches m 8 is made in the form of a rising step 11 For jumper 10 in branch 8 there is a section G of the emergency water tank, connected by connecting pipe 12 with a normally closed valve 13 with a regulating tank B. A waterproof barrier 14 is placed between the sump 7 and the second branch 9 through which the inlet pipeline 15 passes with a normally open valve 16 and connected to the drain of the clarifier 17 installed in branch 9. At valve 18, the bypass valve 19 is closed, installed in jumper 14. Branch 9 is the second emergency section D a catchment basin separated from section D by a dividing lintel 20. Partially above the settling tank 7 and adjacent sections of branches 8 and 9 of the catchment basin there is a lookout 21.

In the sump 7, nozzles 22 are installed to create a buoyant flow through a conduit 23 connected to one of the pumps 2.

In the regulating tank B, lower (LOW), upper (DL) and emergency (AU) water levels are provided. In this case, the upper edge of the jumper 10 corresponds to the AU, and NU - below the bottom of the clarifier 17.

As an embodiment of the installation, the waterproofing peg 14 may be made of overflow, its upper edge exceeding the AC by an amount equal to or greater than the thickness of the water layer above bridge 10 when the water is overflowing at the maximum inflow.

Mine drainage installation works as follows.

After the water is pumped out to the NU, the pumps 2 are turned off and the next filling of the regulating tank B to the VU takes place. At the same time, the inflow passes through the clarifier 17, where most or all of the large particles fall out on its bottom, and the water freed from it with some content of inclusions, mostly fine particles, is sent to the inflow m pipe 15 to the regulating tank B. Flow from the pipeline 15 enters the initial part of the settling tank 7, adjacent to the well 6, and then spreads along the regulating capacitance B. At some distance from the pipeline 15, the flow takes on a calm character, which contributes to the precipitation of solid inclusions along the septic tank 7 and along the branch 8, step P. also contributes to this

As a result, wells 5 and 6 are maintained in the process of filling the regulating container B without being clipped.

After the VU is reached, the pumps 2 are turned on and the adjusting tank B is dried. Due to the inclined arrangement of the branch 8, when it is dried, it rinses off the axially swollen solid 1x particles and dispenses them in an agitated state by pumps 2 to the surface. At the same time, the part of inclusions deposited in the settling tank 7 will be removed.

After the position: of the adjusting capacitance B to NU, the pumps 2 are turned off and the cycle is repeated.

In the event of an emergency situation, when the water level is reached by the AC, the water is poured through jumper 10 into section G of the emergency catchment basin is almost clean, which eliminates the need to clean section G.

After the emergency situation is eliminated, the regulating capacitance B is drained first, as described earlier, and then the valve 13 of the pipeline 12 is opened, and as a result of a rapid flow, the solid inclusions 7 that are deposited in the excavation 7 are partially or completely exhausted by pumps 2 to the surface. After that, the valve 13 is closed again.

If it is not possible to liquidate the accident and after filling section G, the water further flows into section L of the emergency collection tank through jumper 20 and fills ei ;. After draining the adjustment tank C and section D, as described earlier, valve 19 opens, resulting in a turbulent flow, add to the disturbing inclusions in excavation 7 and wells 5 and 6. After drying the catchment tanks to the DU, valve 19 closes.

In the embodiment with the bridge 14 overflow (the separator bar 20 is absent), in the event of an accident, the water can also flow over it. In this case, water with a certain content of fine dispersed inclusions will enter the section D. Therefore, this option should be used when the bottom of the section D is not less than 0.01, which allows to flush solid inclusions deposited on the bottom, mainly in the area adjacent to the bridge 14.

For effective cleaning of the settling tank 7, nozzles 22 installed therein are used. In this case, the pressure flow is supplied by means of the pipeline 23 immediately after reaching WU when the pumps 2 are turned on. As a result, the turbulent inclusions will be delivered along with the inflow to the surface.

Periodically, simultaneously with or without water drainage, accumulations in the clarifier 17 of the inclusion 17 are removed by means of known means, for example arlifts or hydraulic elevators.

Such an installation simplifies the geometric shape of the elements of the vessel B, which contributes to a reduction in capital costs, and the placement of the waterproofing bridge 14 between the branch 9 and the settling tank 7 and the location of the viewing working 21 partially above the settling tank 7 and the adjacent branches 8 and 9 provide free access to all elements located in them, which reduces the cost of operational maintenance of the installation.

Claims (1)

Invention Formula A mine drainage installation, including a pumping chamber, pumps installed in it, sump wells, inclined branches of a water tank with an adjusting emergency tanks divided into sections, placed between the last bridge with a connecting pipe, separating one of the water tank branches from the adjusting tank with a waterproof bridge , installed in one of the branches of the water tank, the illuminator with the inlet pipeline, viewing development and additional information placed in the regulating tank A stand-up staff, characterized in that, in order to increase efficiency and reduce capital and operating costs when the pump chamber is buried, an additional sump is made buried to the bottom level of the sump wells and is located between the last and branches of the sump, and viewing output is located above the place of additional junction sump to the branch m of the sump. R