RU2691252C1 - Method of re-laying of rocks of hydraulic dumps with hydraulic monitor and suction dredger - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to the mining industry and can be used in the open development of mineral deposits. In method of re-laying of rocks of hydraulic dumps with hydraulic monitor and suction dredger, parameters of processes of water jet and dredging of rocks are first calculated using system of equations. Then, based on the performed calculation of parameters of jetting and dredging of rocks, dredge is selected, which is used to develop unconsolidated clay rocks of hydraulic dump, and hydraulic monitor, which is installed on upper ledge consisting of consolidated rocks, technically clean water is supplied to hydraulic monitor and washed out of consolidated rocks, thereafter, the hydraulic mixture is directed by gravity flow to the bottom of the dredge, which develops the rock and additionally increases the pulp concentration moved along the pressure pulp line to the new place of laying.

EFFECT: improving the efficiency and safety of mining operations in the redevelopment of rock dumps.

1 cl, 2 dwg, 1 tbl

Description

The invention relates to the mining industry and can be used in the open development of mineral deposits.

It is known that safety and efficiency are among the basic principles of open-pit coal mining. In this regard, it is advisable to carry out the commissioning of new areas of coal deposits, which are located in the immediate vicinity of the existing mine workings, where the mining of coal is completed, but the necessary infrastructure has already been created that is capable of ensuring the stable operation of the enterprise. Comparatively often an obstacle to the implementation of the specified direction of development of coal mining is the presence of hydraulic dumps on the surface of areas located near the existing workings.

One of the ways of re-laying rocks of hydraulic waste dumps is their erosion with the subsequent movement in the form of a slurry system of pipeline transport and laying in a new place. It should be noted that the main direction of the creation of energy- and water-saving hydromechanization technology is to increase the concentration of solids in the slurry [E. A. Kononenko, Opportunities and Prospects for Hydromechanization in Open Pits, Mining Information and Analytical Bulletin, 2004].

There is a method of hydro-mechanized development of fields (I.M. Yaltanets, S.A. Ivanov, Issues of organization of development of fields with submersible ground pumps, 2005), including the use of a dredger with a submersible groundwater pump and hydromonitor erosion. At the same time, according to a known method, a jetting erosion is used to lower the height of the surface part of the step developed by the dredger and is not a source of water supply for the dredger.

There is also known a method of hydromonitor-suction-sucking (A.P. 1742479, IPC E21S 41/00, 45/00, publ. 06/23/92, bull. No. 23) adopted for the prototype, which includes erosion of the rock by a hydromonitor in the bottomhole, gravity flow hydraulic transport of the slurry on the pulpwater ditch and pressure hydraulic transport of slurry with a high concentration of solid in the hydro dump.

The disadvantages of the known method adopted for the prototype: low efficiency of mining for the re-laying of rocks of hydraulic dumps due to the fact that the jet and the water pump do not fully realize their performance (due to the fact that they often stand idle) due to the performance of additional preventive and unscheduled repairs . This is because in the method adopted for the prototype, an increase in the concentration of solids in the slurry is achieved by organizing an internal water supply cycle in the bottom, which in turn leads to the fact that the water pump, which draws water from the sump surface layer, does not supply enough clarified slurry directly into the bottom of the jet. This circumstance leads to the fact that the hydromonitor and the water pump operate on an abrasive fluid, the use of which is not intended. This leads to accelerated wear of the nozzle of the water jet and the impeller of the water pump and, as a consequence, to more frequent downtime for performing scheduled and unscheduled repairs. It should be noted that equipment downtime is a particularly significant factor in reducing the efficiency of the method due to the seasonality of the application of hydromechanization in the quarries.

In addition, the method adopted for the prototype, is not safe. This disadvantage lies in the fact that the use of a jetting machine for erosion of unconsolidated rocks of the hydraulic dump is dangerous due to the possibility of the formation of landslides or bulges and, as a result, the occurrence of accidents and equipment failure.

The technical result of the proposed method is to increase the efficiency and safety of mining operations when re-laying rocks of hydraulic dumps.

This technical result is achieved by the fact that in the method of re-laying rocks of hydro dumps with a sprinkler and a sump pump, including erosion of the rock in the bottom with a sprinkler, gravity flow transport of the slurry in a pulp ditch and pressure flow transport of the slurry with a high concentration of solid into the dump, according to the claimed method method. Hydromonitor and dredger development of rocks using the system of equations:

where Q _TH is the productivity of the _jetting monitor by rock, m ³ / h;

Q _TЗ - productivity of the dredge by breed, m ³ / h;

Q _ГΣ - productivity of the soil pump of the dredge in slurry, m ³ / h;

q _З - specific water consumption when developing rocks with a dredge, m ³ / m ³ ;

q _G - specific water consumption at jetting washout, m ³ / m ³ ;

m is the porosity of the rock, in fractions of a unit;

then, based on the calculation of the parameters of the hydraulic and dredging rock development, a dredge is selected, which is used to develop unconsolidated clay rocks of the hydraulic mine dump and a hydromonitor, which is installed on the upper ledge consisting of consolidated rocks, the hydromonitor is supplied with technically clean water and the consolidated rocks are washed out, after which slurry gravity flow through the pulp ditch is directed to the bottom of the dredger, which develops the rock and further increases the concentration pulp moved along the pressure slurry line to the new installation location.

The claimed technical solution is illustrated by drawings, where in FIG. 1 shows a general sectional section of the hydraulic mine dump; in fig. 2 shows the mining plan for re-laying of the hydraulic dump.

The inventive method is as follows. First of all, determine the parameters of the processes of jetting and dredging development of rocks using a system of equations:

where Q _TH is the productivity of the _jetting monitor by rock, m ³ / h;

Q _TЗ - productivity of the dredge by breed, m ³ / h;

Q _ГΣ - productivity of the soil pump of the dredge in slurry, m ³ / h;

q _З - specific water consumption when developing rocks with a dredge, m ³ / m ³ ;

q _G - specific water consumption at jetting washout, m ³ / m ³ ;

m is the porosity of the rock, in fractions of a unit.

Then, based on the performed calculation of the parameters of the hydraulic and dredging development of rocks, the dredge 1 is selected according to its performance, the capacity of the ground pump installed in it and the specific water consumption in the development of rocks by dredger. Next, the selected dredger 1 is placed in the zone of unconsolidated rocks 2 and carry out their development. After that, on the basis of the performed calculation of the parameters of the jetting and dredging rock development, the jetting monitor 3 is selected according to the parameters of its performance and the specific water consumption during the jetting erosion. Then hydromonitor 3 is installed on the upper ledge in the zone of consolidated rocks 4. After that, it is supplied with technically clean water and erosion of the upper ledge consisting of consolidated rocks is made. After this, the hydraulic mixture is slurried along a pulp ditch 5 with a slope by means of a gravity hydrotransport. 1, where, as a result of his work, produce an additional increase in the concentration of solids in the slurry. Next, from the face 6 of the dredger 1, first, the floating slurry line 7, and then along the main line 8, by means of the transfer station 9, pressurized hydraulic slurry with a high concentration of solid into the new hydraulic dump is carried out.

As a result of the implementation of the proposed method, an increase in the concentration of solid in the slurry occurs due to the fact that after erosion of the consolidated rocks by means of a hydromonitor, the slurry in the pulp ditch is transported by gravity to the bottom of the dredger. Thus, the use of slurry from the jetting machine as a source of water supply in the bottom of the dredge and additional rock developed by the dredger, can increase the concentration of solids in the slurry transported to the new dump, it is important that stable and balanced operation of a pair of jetting-dredger is ensured account that the parameters of their joint work are pre-determined using the system of equations:

where Q _TH is the productivity of the _jetting monitor by rock, m ³ / h;

Q _TЗ - productivity of the dredge by breed, m ³ / h;

Q _ГΣ - productivity of the soil pump of the dredge in slurry, m ³ / h;

q _З - specific water consumption when developing rocks with a dredge, m ³ / m ³ ;

q _G - specific water consumption at jetting washout, m ³ / m ³ ;

m is the porosity of the rock, in fractions of a unit;

and further, using the obtained values, select a specific brand and model of the jetting machine and dredger.

When performing calculations using the system of equations, it is allowed to make a start from the parameters of the hydro-monitor available at the quarry and pick up a dredger in a pair, or on the parameters of the dredger available on the quarry and pick up a hydro-monitor in a pair, or on the performance of the ground pump, which is determined by the required intensity re-laying reservoir. The execution of the calculation in one sequence or another does not affect the achievement of the technical result and, therefore, is not an essential feature.

The invention implements such a mechanism for increasing the concentration of solid in the slurry, in which the jet is working on technically pure water and, unlike the known method, this does not lead to accelerated wear of the jet and the water pump impeller and, as a result, does not entail more frequent equipment downtime for additional preventive and unscheduled repairs.

Thus, it is shown that the inventive method provides an increase in the efficiency of mining operations when re-laying hydraulic waste dumps due to the fact that in the inventive method an increase in the concentration of solids in the slurry is provided, while the monitor and the water pump realize their performance fully and do not stand idle to perform additional preventive and unscheduled repairs.

Also, the inventive method allows to increase the safety of mining operations when re-laying rocks of a hydraulic mine dump. This is achieved due to the fact that according to the claimed method for the development of unconsolidated rocks, the jetting erosion is not used, but a dredger is used. In turn, the hydromonitor provides for the erosion of only consolidated rocks. This eliminates the risk of landslides or flooding and, as a result, the occurrence of accidents and equipment failure.

An example of a specific implementation method.

The proposed method is implemented for the redevelopment of already washed in Quaternary overburden rocks to a new place.

The total volume of shifted rocks was about 40 million m ³ .

The distance of the slurry transportation from the overflowing hydraulic dump to the new laying place was 4.5-5.8 km.

First, using the system of equations:

where Q _TH is the productivity of the _jetting monitor by rock, m ³ / h;

Q _TЗ - productivity of the dredge by breed, m ³ / h;

Q _ГΣ - productivity of the soil pump of the dredge in slurry, m ³ / h;

q _З - specific water consumption when developing rocks with a dredge, m ³ / m ³ ;

q _G - specific water consumption at jetting washout, m ³ / m ³ ;

m is the porosity of the rock, in fractions of a unit;

The joint operation parameters of the jetting machine and the dredger were calculated.

In the calculation they repelled from the fact that during the implementation of the example, there was a milling dredge with a pile driving course DFS 1900/58 with a rock capacity of 58 m ³ / h, a ground pump productivity of up to 2000 m ³ / h and a specific water flow of 22 m ³ / m ³ .

The calculation results are shown in the table.

As a result of the calculation, to ensure a stable and balanced operation of the hydromonitor-dredger pair, the performance of the hydromonitor for the rock should be 114.5 m ³ / h with a specific flow rate at 8.1 m ³ / m ³ (group of rocks IV) , with the value of t = 0.47.

Next, the existing DFS 1900/58 dredger was installed in the zone of unconsolidated rocks, where he carried out their development.

After that, on the basis of the performed calculation of the parameters of the hydraulic and dredging development of rocks, the hydraulic monitor GMD-250M was selected, which satisfies the calculated parameters. Then the selected hydromonitor was installed on the upper ledge in the zone of consolidated rocks. After that, technically clean water from the relocatable hydraulic waste dump by pump station 10, equipped with two parallel-running water pumps D 2000-100, was fed through a conduit 11 into a jetting machine and eroded consolidated rocks.

Further, by gravity hydrotransport, the slurry along the pulp ditch with a gradient of 4-6% was sent to the bottom of the dredger, where, as a result of its work, an additional increase in the concentration of solids in the slurry was made. After that, from the bottom of the dredger, first along the floating slurry line, and then along the main line, pressure hydraulic transport of the slurry with a high concentration of solid into the new hydraulic mine dump was carried out.

According to the results of the implementation of the proposed method did not arise the need to stop the production of mining operations to perform unscheduled repairs. Two water pumps D 2000-100 were disassembled and their wheels were inspected. The nozzle of the GMD-250M was also examined. As a result, the absence of accelerated wear of equipment was found. This indicates a higher efficiency of the proposed method in comparison with the known.

Also during the implementation of the proposed method, no accidents and equipment failure occurred due to the formation of landslides or bumps, since a dredger was used to develop unconsolidated rocks instead of a jetting erosion.

Based on the foregoing, it can be concluded that the claimed method provides an increase in the efficiency and safety of mining operations during the re-laying of rock dumps.

Claims (9)

Method refolding sawmills gidrootvalov jetting and suction dredger comprising scour rock at the bottom of jetting, gravity hydrotransport slurry of pulpovodnoy gutter and discharge hydrotransport slurry with a higher concentration of solids in the hydraulic dump, characterized in that the first carry computation process parameters jetting and zemsnaryadnoy development rocks using system equations:

where Q _tg - the performance of the jetting machine by rock, m ³ / h; Q _ts - the performance of the dredge on the breed, m ³ / h; Q _gΣ - the performance of the soil pump of the dredge in slurry, m ³ / h; q _z - specific water consumption in the development of rocks dredger, m ³ / m ³ ; q _g - specific water consumption at jet erosion, m ³ / m ³ ; m is the porosity of the rock, in fractions of a unit; then, based on the calculation of the parameters of the jetting and dredging rock development, a dredge is selected, which is used to develop unconsolidated clay rocks of the hydraulic waste dump, and a hydromonitor, which is installed on the upper ledge consisting of consolidated rocks, is fed to the hydromonitor with technically clean water and erode consolidated rocks, then the hydromix gravity through the pulp ditch is directed to the bottom of the dredger, which develops the rock and further increases the concentration pulp moved along the pressure slurry line to the new installation location.

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