RU2420659C2 - Development method of shallow permafrost terrace placers above flood-plain in conditions of repeated dragging - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: development method involves drilling of ditches with arrangement of removed peats in external dumps, melting of permafrost sands in natural way, movement of sands with excavating equipment, development of sands with a drag in longitudinal adjacent ways. Development of terrace placers above flood-plains is performed in steps in longitudinal strips with piling of peats in internal longitudinal dam constructed in the area of excavated sands. For rising the water level in drag section and flooding of sand molten in natural way, for the purpose of their being protected against season freezing, not only longitudinal transport dams, but also longitudinal dam built from removed sands and transverse dams built from overburden peats are used. Area of removed sands is created by driving advance longitudinal trench and by dragging sands with slanting (non-symmetrical) working face in adjacent area developed with primary travel of the drag.

EFFECT: invention allows increasing development efficiency of terrace placers.

9 cl, 3 dwg

Description

The invention relates to the mining industry, in particular to the development of alluvial mineral deposits.

There is a method of dredge development of a boulder placer with longitudinal adjacent passages when opening it with a foundation pit at a ridge [1]. There is also a method of developing separately occurring small terrace placers, simultaneously involved in the operation of a dredge developing a floodplain placer [2]. Sands of terrace placers according to this method, after overburden and placement of peat in external dumps and natural defrosting using earthmoving equipment, are moved into the flood plain to the dredge face.

A common drawback of these methods is the large loss of the useful component in the waste sands allowed during the enrichment of clay poorly disintegrated whole sands. They do not allow us to imagine the development of a deposit as a whole, consisting of several floodplain terrace placers, which have recently become involved in production.

The objective of the invention is to develop an effective method for developing a deposit, consisting of several floodplain terrace permafrost placers with clay sands with a general bias towards the river floodplain and falling along strike along the conditions of repeated dredging.

The problem is solved due to the technical result, which consists in developing the field in the cheapest dragee way, allowing it to be worked out stepwise across stretching at the minimum cost of stripping peat, thawing permafrost sands in a natural way and protecting them from seasonal freezing by flooding under conditions of repeated dredging.

The specified technical result is achieved by the fact that in the method of developing shallow perennially frozen floodplain terrace placers in the conditions of repeated dredging, including opening a foundation pit with placing peat overburden in external dumps, defrosting permafrost sand in a natural way, moving sand with earthmoving equipment, developing sand with sand excavation the invention, the development is carried out in stepwise longitudinal strips separated by a strip of excavated whole sands at the passage of the leading longitudinal trench, while the longitudinal stripes are worked out by two single adjacent dredging moves along the ring, of which the placer rebellion move is the first priority, adjacent to the strip of excavated whole sands and allowing its width to be expanded for internal storage of overburden peat by dragging the whole sand without oblique ( ) slaughter with the formation of an adjacent mined-out space not covered by dumps of spent sand.

From peat excavated during the excavation of the leading longitudinal trench and overburden peat of the following longitudinal strip, which is being prepared for dredging, a pioneer longitudinal dam is poured into the leading longitudinal trench after excavation of the whole sands, and in the worked-out space of the first course of dredging, the dredges are poured to raise the water level in the cut section bulkhead dams across its entire width.

From the wholly sands excavated during the driving of the leading longitudinal trench, a longitudinal dam is poured on the thawed sands after overburden of peat in the area of the second dredge reverse run adjacent to the area of its priority run and, consequently, transverse cross-dams on the area of the first dredge run over its entire width at the same time dams on the reverse course dredges are dredged from the whole sands, taken out from the areas adjacent to the base of the dam.

Peat overburden from the rest of the area of the next longitudinal strip, which is being prepared for dredging, is placed with earthmoving equipment on the area of the previously dumped longitudinal dam and the worked out space not covered by dumps of spent sands, followed by the erection of the internal longitudinal transport dam from the dumped peat.

In order to raise the water level in the dredged section and to protect from seasonal freezing of the whole sands thawing naturally after peat excavation by earthmoving equipment, the pits formed by the pioneer and transport longitudinal dams, a longitudinal dam and transverse bulkhead dams are sequentially flooded.

To dredge and protect thawing whole sands from seasonal freezing, water is pumped from the river, and then pumped and gravity from one pit to another.

Before the dredge enters the next foundation pit, a transverse bridging dam is preliminarily planned after the destruction of its body to accelerate the thawing of seasonal permafrost in a natural way, and then its volumes are dredged together with the whole sands lying at the base of the dam, and after the dredge enters the pit during the priority course of the dredge along the rebellion of the placer, the dam-bridge is reconstructed by pouring peat under a dredge stack onto the epoxy dump before filling it with a pebble dump to raise the water level in the preparation nnom dredging ditch.

In the reverse course of the dredge for the fall of the placer, a longitudinal dam is planned after the destruction of its body for accelerated thawing of seasonal permafrost in a natural way, and then its volumes are dredged together with the whole sands lying at the base of the dam.

When the dredge moves to the next practiced longitudinal strip, peat, dumped in the internal longitudinal transport dam, is removed with earthmoving equipment at the transition site, followed by alloying the dredge into the prepared foundation pit and the dam is re-built with earthmoving equipment at the transition site by dumping peat under the dredger glass to raise the water level in a ditch prepared for dredging.

Comparative analysis shows that the proposed method for the development of shallow perennially frozen floodplain terrace placers in conditions of repeated dredging differs from the prototype, i.e. meets the requirements for the invention by the criterion of "novelty."

The proposed method for the development of shallow perennially frozen floodplain terrace placers under repeated dredging conditions meets the criterion of "inventive step", because the combination of its essential features allows you to create conditions for a more complete extraction of useful components from the sands and thereby increase the efficiency of dredging.

The proposed method is illustrated by drawings, in which Fig. 1 shows the development by the dredge of the first course of the uprising of the placer of thawed and flooded whole sands of the first longitudinal strip of the first floodplain terrace placer, Fig.2 - the end of the development by the dredge of the second reverse of the fall of the placer of thawed and flooded whole sand the first longitudinal strip, the first floodplain terrace placer; figure 3 - the beginning of the development of dredged thawed and flooded whole sands of the next longitudinal strip of the first or subsequent floodplain terrace placer after crossing through a longitudinal transport dam.

The drawings show:

A and B, respectively, the longitudinal strip worked out and prepared for mining;

In - a strip of excavated sand in the process of preparing reserves;

G - a strip of sand taken out after the first move of the dredge.

1 and 2, respectively, the longitudinal and transverse external transport dams dumped over the balance sheet contour from overburden peat; 3 - dredge developing sands ready for excavation; 4 - leading longitudinal trench, passed to the raft between the developed and prepared for dredging strips; 5 - dump peat overburden, sprinkled with a trench; 6 - a dump of sand, sprinkled with a trench; 7 - a longitudinal internal transport dam, sprinkled on the area of excavated sands formed during the excavation of trench 4 and the development by dredge 3 of the entire sands with an oblique (asymmetric) face during its adjacent course; 8 - pioneer longitudinal dam, sprinkled in a trench 4 from peat dump 5 and peat overburden adjacent area of the longitudinal strip, prepared for dredging; 9 - a longitudinal dam, dumped from clay sands delivered from dump 6; 10 - transverse dam bridges, dumped from the sands delivered from the dump 6 to thawing whole sands and restored in the worked out space from overburden peat; 11 - the area of overburden of peat used for dumping the pioneer longitudinal dam 8 and the restoration of transverse dam-bridges 10; 12 - area prepared for natural defrosting of permafrost whole sands after overburden of peat; 13 - area of naturally thawing whole sands after overburden of peat; 14 - the area of thawing whole sands protected from seasonal freezing after flooding; 15 - the primary longitudinal course of the dredge in the worked strip; 16 - second reverse longitudinal adjacent stroke of the dredge in the worked strip; 17 is a transverse course of the dredge during the transition of the dredge to the area of the next worked strip. The method is as follows.

The diamondiferous deposit, consisting of four floodplain terrace shallow perennially frozen placers with clay sands adjacent to each other, is developed by the dragee method. The average slope of placers along the strike is 0.003, across the strike toward the floodplain of the river is 0.006, the average thickness of peat is 2.3 m, of sand 2.4 m.

Before the exploitation of the field, in the lower part beyond the outline of the balance reserves, longitudinal 1 and transverse 2 external transport dams are overburden from peat. The latter is growing as the development of floodplain terrace placers increases. Dredge 3 development of the field begins with the first floodplain terrace placer by opening it with a foundation pit at the intersection of these dams.

The deposit is developed in steps of longitudinal stripes separated by a strip of whole sand excavated at two single adjacent passages of dredge 15 and 16, of which the move 15 on the uprising of the placer is the first priority (see Fig. 1). Within the first longitudinal strip after overburdening of peat and placing them in dams 1 and 2, natural thawing of opened permafrost sands occurs. Before dredges come into operation, they carry out work to protect thawed sands from seasonal freezing by flooding them. For this purpose, an advancing longitudinal trench 4 is passed up to the raft outside the first longitudinal strip by earthmoving equipment, into which overburden peat is poured out after sanding and excavated and dumped in dump 5. In trench 4, in addition, overburden peat taken out from the adjacent area 11 of the next longitudinal strip being prepared for dredging when dumping the pioneer longitudinal dam 8.

In order to increase the width of the strip of excavated sands during the excavation of trench 4, the whole sands are dredged with an oblique (asymmetric) face during the first course of 15 dredges 3 with the formation of an adjacent area of the worked out space that is not covered by dumps of used sands. On the obtained wider strip of excavated sands, partially occupied by the pioneer longitudinal dam 8, an internal longitudinal transport dam 7 is constructed using the remaining volumes of overburden peat in the area 12 of the next longitudinal strip, which is being prepared for dredging.

During development by the dredge of 3 stocks of whole sands ready for excavation in the area of one longitudinal strip with two longitudinal single strokes 15 and 16, peat is completely overburdened over the entire area of the next longitudinal strip, after which the thawing of permafrost whole sands is naturally thawed and subsequently protected from seasonal freezing by flooding during the transition of the dredge to the next longitudinal strip.

In order to raise the water level in the dredged section and to flood the thawed sands, in the presence of transport dams 1, 2, and 7, as well as a pioneer longitudinal dam 8, using earthmoving equipment, thaw a longitudinal dam 9 on the area of the return adjacent run 16 at the boundary of the priority run 15 and fill 9 and transverse dam bridges 10 from clay sands of dump 6 in the first course of the dredge. On the reverse course of the dredge, these lintel dams are sprinkled from the wholly sands taken out of the areas adjacent to the base of the dam. In the worked-out space of the first turn 15 of dredge 3, transverse bulkhead dams 10 recover from the peat overburden of area 11. The dams are low, in addition, the bulkhead dams 10 are limited in number due to the small slope of the placers along the strike.

On thawed placers, the indicated dam bridges 10 are necessary only to raise the water level in the working pit, which are constructed during the development of the placer by an uprising behind dredge 3, by falling in front of dredge 3.

Water for flooding thawed sands in order to protect them from seasonal freezing and dredging is pumped from the river, and then pumped and gravity from one pit to another.

Before dredge 3 enters the next foundation pit with the first move 15, a transverse dam bridge, sprinkled from the sands, is planned after the destruction of its body to accelerate thawing of seasonal permafrost in a natural way, and then its volumes are dredged together with the whole sands lying at the base of the dam.

With the passage of dredge to the next pit to raise the water level, the harvested transverse dam-bridge is restored in the worked out space by pouring excavated peat dredges under the stack of dredge onto the epileous dump until the pebble dump dumps it.

During the reverse course 16 sands, poured into the longitudinal dam 9, are taken out by the dredge 3 itself, after its planning, together with the whole sands lying at the base of the dam. Before planning, the dam body is destroyed to accelerate the thawing of seasonal permafrost in a natural way.

Through an ephelle dump containing fine gravel, in which the pores contained in it are filled with clayey clay particles, water filtration is minimal. In the case of a small leak of water from the pit, it can be replaced by pumping.

With the proposed method for the development of the next strip, we have areas of 13 thawed whole sands in time and 14 protected from seasonal freezing by flooding with minimal mining and preparatory work.

If the width of these strips is reduced to the width of one single dredge stroke, while reducing the costs of stripping peat, we are not able to thaw and protect the whole sands in a timely manner on the site adjacent to the dredge transition to the next lane, since the dredged face meets the front of the mining operations. As the width of the strip developed by more than two single dredge moves increases, the unjustified costs of driving a wider leading trench 4 when placing a longitudinal transport dam 7 and peat overburden with an increased distance for their transportation of earthmoving equipment, which are used as bulldozers, increase.

Before the dredge passes to the next run strip, peat, dumped in the internal longitudinal transport dam 7, is removed by earthmoving equipment in the transition area at a lowered water level in the excavated and prepared for mining pit and stored close in a temporary dump. The passage of the dredge is carried out by alloy with an elevated level of water in these pits. With the passage of dredge in the transition section, the said dam is again filled with earthmoving equipment under a stack of dredge from the extracted peat.

Creating a strip of excavated whole sands, including the area of excavation of sands when driving the leading longitudinal trench 4 and the adjacent area of the worked out space that was not covered up with waste sand dumps when dredging with oblique (asymmetric face), allows storing overburden peats in internal dumps with the subsequent construction of longitudinal transport dams 7. The absence of overburden of waste sand dumps with overburden peats in the proposed development method creates a condition for repeated drift agitation, which can be divided into passing and subsequent. The latter is used in practice after the development of the whole sands of the entire field in the reverse order, along the way - if necessary, increase the operating time of the dredged strip by the dredger for preparing the whole sands of the next strip, as well as in obtaining the current economic effect.

If there is a significant presence of settled sludge in the worked-out space, the waste sand dumps are placed together with the common contour of two adjacent single passages by excavating the whole sands with an oblique (asymmetric) face not only during the course of 15, but also 16. In this case, it is possible to avoid the sludge that settles between dumps of waste sand during repeated dredging, if the development of collectively disposed dumps of waste sand is carried out with a single stroke of the dredge with a direct (symmetrical) face.

Dumping of the longitudinal dam 9 is advisable in order to avoid the deposition of sludge formed during the development of clay sands in the reverse area of the dredge 16. These sludges dilute the removed whole sands and reduce the extraction of the useful component during enrichment. With its filling, the need for using water for flooding is also reduced.

Information sources

1. Shorokhov S.M. Technology and comprehensive mechanization of placer mining. M .: Nedra, 1973, p. 409-411.

2. Dorokhov N.M., Ershov V.A. The experience of involving terrace placers in the associated development by dragee method. Mountain Journal. 2006, No. 10, p. 45-47.

Claims (9)

1. A method for developing shallow, permafrosted floodplain terrace placers in conditions of repeated dredging, including opening a foundation pit with placing peat overburden in external dumps, defrosting permafrost sands in a natural way, moving sands with earthmoving equipment, and developing sand with a dredge in longitudinal, adjacent, adjacent steps longitudinal stripes separated by a strip of excavated whole sands when driving an advanced longitudinal trench, while The lane strips are worked out by two dredge moves along the ring, of which the placer rebellion is the first priority, adjacent to the strip of excavated whole sands and allowing to increase its width for internal storage of overburden peat by dragging the whole sands with an oblique (asymmetric) face with the formation of an adjacent mined-out space filled with waste sand dumps. 2. The method according to claim 1, characterized in that a pioneer longitudinal dam is poured from the peat excavated during the driving of the leading longitudinal trench and the peat of the overburden of the next longitudinal strip prepared for dredging in the leading longitudinal trench after excavation of the whole sands, and in the worked out space of the first course of the dredge to raise the water level in the dragee section, transverse cross-dam dams are poured over its entire width. 3. The method according to claim 1, characterized in that from the wholly sands excavated during the driving of the leading longitudinal trench, a longitudinal dam is poured on the thawed sands after overburden of peat in the area of the second dredge reverse course adjacent to its priority course area and, successively, transverse dams - lintels on the area of the dredge’s first course of travel over its entire width, while dams-lintels on the reverse course of the dredge are sprinkled from whole sands taken from sections adjacent to the dam base. 4. The method according to claim 1 or 2, characterized in that the peat overburden from the rest of the area of the next longitudinal strip, prepared for dredging, is placed with earthmoving equipment on the area of the previously dumped longitudinal dam and the developed space not covered by dumps of spent sand, with the subsequent construction from sprinkled peats of the internal longitudinal transport dam. 5. A method according to any one of claims 2, 3, characterized in that pits formed by pioneer and longitudinal transport dams, in order to raise the water level in a cut and to prevent seasonal freezing of whole sands thawed naturally after overburdening peat with earthmoving equipment dam and transverse dam dams, successively flooded. 6. The method according to claim 1, characterized in that for dredging and protecting thawing whole sands from seasonal freezing, water is pumped from the river, and then pumped and gravity from one pit to another. 7. The method according to claim 1 or 3, characterized in that before the dredge enters the next foundation pit, a transverse dam bridge is planned after the destruction of its body for accelerated thawing of seasonal permafrost in a natural way, and then its volumes are dredged together with the whole sands lying in the base dam, and after the dredge enters the pit during the first course of the dredge on the uprising of the placer, the jumper dam is reconstructed by dumping peat under the dredge stack onto the epoxy dump before filling it with a pebble dump for lifting Water level in the pit prepared for dredging. 8. The method according to claim 1 or 3, characterized in that in the reverse course of the dredge on the fall of the placer, a longitudinal dam is planned after the destruction of its body for accelerated thawing of seasonal permafrost in a natural way, and then its volumes are dredged together with the whole sands lying at the base of the dam . 9. The method according to claim 1, characterized in that when the dredge is transferred to the next practiced longitudinal strip, peat, dumped in the internal longitudinal transport dam, is removed with earthmoving equipment at the transition site, followed by alloying the dredge into the prepared foundation pit and re-construction of the dam with earthmoving equipment on section of the transition by dumping peat under a dredge stack to raise the water level in a foundation pit prepared for dredging.

Images