RU2034114C1 - Unit for transportless opencast mining - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: unit for transportless opencast mining consists of face and tail moving nonturning platforms with masts interconnected by track cable and two-sided bucket. Height of mast of face moving platform is less by 1.2-2.1 times than that of must of tail moving platform. Each mast is connected by means of hoisting and pulling cable bending over respective block secured to track cable. Blocks are connected by means of link. Bucket bottom is V-shaped and angle between forming bottom is 130-150 deg. EFFECT: extended process capabilities of unit and its higher efficiency. 2 cl, 4 dwg

Description

 The invention relates to the mining industry and can be used in open pit mining of minerals by transport system in difficult mining and geological conditions.

A known machine for the development of soil, consisting of two running platforms, equipped with arrows, which are interconnected by a traction rope for moving a double-sided bucket [1]
The disadvantages of this machine are limited technological capabilities and low productivity due to the large weight of the running platforms on which booms of equal length are mounted, tilted to the side opposite from the operational trench, as well as the presence of articulated buckets with a traction rope, which cannot be used to draw and unload rock in anywhere along the path of its transportation, to produce a frill of a steep slope of the ledge; scooping the rock with such buckets is associated with increased sticking and freezing of the rock mass, while scooping the rock is accompanied by a low filling factor of the bucket and an increased duration of the scooping cycle.

A known unit for a non-transport development system, including a downhole and dump chassis with masts of various heights, interconnected by a support rope, and a two-sided bucket [2]
The disadvantages of this unit for a non-transport development system are limited technological capabilities and low productivity due to the high weight of the running platforms, rope, bucket and low mobility due to the lack of an optimal ratio of mast height, inclined trusses with articulated supporting skis and a two-sided bucket, consisting of two connected between themselves by a chain of fastened buckets with two traction ropes and suspended from carts moving along the support rope. With a high specific pressure on the ground, the possibility of using the unit in weaker rocks is excluded. There is no possibility of scooping anywhere in the face along the length of the transport, the frills of the steep slope of the ledge. Conditions are created for sticking and freezing of the rock mass. It is not possible to change the angle of introduction during scooping and scooping on steep sections of the face. Due to the increased distance between the masts and the two trolleys moving along the traction rope, the rope consumption increases.

 When using an aggregate for a transportless development system, it is necessary to flatten the slope of the overburden ledge, which will require an increase in the volume of stripping operations and the cost of drilling and blasting.

 The purpose of the invention is the reduction of the weight and dimensions of the running fixed platforms; reduction of the distance between the masts of running fixed platforms at the minimum possible distances from the masts to the upper edge of the overburden ledge and the ledge of dump rocks; creation of a suspension and construction of a bucket, providing: scooping and unloading at any place of the face along the transport length, the possibility of friction of a steep slope of the ledge, reducing sticking and freezing of the rock mass on the bucket, the ability to change the penetration angle when scooping, reducing mineral losses during scooping; the ability to operate the unit at steep slope angles of the overburden ledge; expanding technological capabilities and increasing the productivity of the unit for a transportless development system.

In the proposed unit for a non-transport development system: the mast height of the downhole running platform is 1.2-2.1 times less than the mast height of the dump chassis; each mast is connected to a bucket by a hoisting-and-pulling rope, enveloping the corresponding block, mounted on a supporting rope; blocks are connected by communication; the bucket is equipped with an additional arch; the bottom of the bucket is V-shaped; the angle between the planes forming the bottom is 130-150 ^about ; double-acting bucket, which is an integral design; running fixed platform; counterweight on a running non-rotating platform for perceiving a tipping moment; mast on a running fixed platform.

 Reducing the mast height of the downhole running platform by 1.2-2.1 times in comparison with the mast height of the dumping running platform reduces the weight and dimensions of the running platform, brings the mast closer to the upper edge of the ledge, reduces the weight of the rope due to the reduction of its length.

 As a result, the specific pressure on the soil decreases, which allows the unit to be used in the development of weaker rocks. The connection of the masts with the bucket with lifting and pulling ropes through blocks fixed to the carrier rope, which are interconnected, provides: scooping and unloading the bucket at any place of the bottom along the transport length, the possibility of friction of a steep slope of the ledge and changing the penetration angle when scooping.

 As a result, the rock mass can be most efficiently excavated and placed in the operational trench, as well as loaded vehicles located at the bottom of the operating trench with mineral resources.

 Changing the penetration angle during scooping makes it possible to choose the most rational value of this angle for these rocks, as well as increase the strength of excavated rocks. When the frill of the steep slope of the ledge increases the safety of work. As a result, it is possible to operate the unit at steep slope angles of the overburden ledge.

 The proposed connection between the bucket and the masts helps to reduce the mast height of the downhole running platform, bringing it as close as possible to the upper edge of the overburden ledge. This is explained by the fact that the block fixed to the supporting rope during the fringe of the ledge slope is located above the upper edge of the overburden ledge with the bucket lowered down the slope, and when scooping rock, this block can be placed above the working platform of the overburden ledge.

The V-shaped bucket with an angle between the planes forming the bottom equal to 130-150 ^о С, in combination with the bucket-mast communication system provides: scooping and unloading the bucket anywhere in the face along the transport length, the possibility of friction of a steep slope of the ledge, changing the angle implementations when scooping.

 As a result, the rock mass can be most efficiently excavated and placed in the production trench, vehicles located at the bottom of the production trench can be loaded with minerals, stronger rocks can be excavated, work safety is increased due to the frill of the ledge slope. The escarpment of the ledge is robbed when the bucket moves from bottom to top, which allows you to develop significant magnitude of effort on the teeth of the bucket to separate pieces of rock from the surface of the escarpment, increasing the level of safe condition of the escarpment of the escarpment.

 In addition, the ability to move the bucket when scooping in two opposite directions reduces the loss of minerals in the area of the lower edge of the inner blade. The absence of rotating and rubbing parts in the places where the bucket is filled with rock mass reduces sticking and freezing on the bucket.

 Thus, the proposed unit for a non-transport development system solves the problems with obtaining the technical result of expanding technological capabilities and increasing unit productivity.

 In FIG. 1 shows a unit for a transportless development system; in FIG. 2 bucket in transport position; in FIG. 3 the same, in the process of scooping up the rock mass; in FIG. 4 diagram of the position of the bucket with the frill of the slope of the overburden ledge.

 The unit for a transportless development system (Fig. 1) consists of a bottomhole 1 and dump 2 running platforms with masts 3 and 4 of these platforms, which are located on the side of the operational trench 5. Mast 3 of the downhole running platform 1 is connected to the mast 4 of the dumping running platform 2 bearing the rope 6 of the downhole running platform 1 with the block 7 fixed to it and the supporting rope 8 of the dump running platform 2 with the block 9 fixed to it. Blocks 7 and 9 are interconnected by a connection 10 (Fig. 2).

 The bucket 11 is connected to the mast 3 of the downhole running platform 1 with a lifting and traction rope 12, enveloping the block 7 of the supporting rope 6 of the downhole running platform 1, and with the mast 4 of the dumping running platform 2 with a lifting and traction rope 13, enveloping the block 9 of the supporting rope 9 of the downward moving platform 2.

 The height of the mast 3 downhole running platform 1 is less than the height of the mast 4 dump dump platform 2 in 1.2-2.1 times.

 The limits of the ratio of the height of the masts 4 and 3 of the dump and downhole running platforms 2 and 1 are optimal, since within (1.2-2.1 times) the lowest weight of these platforms is ensured, which gives the lowest specific pressure on the ground, the unit can work in weaker rocks, expanding the technological capabilities of the unit and achieving a technical result.

The indicated limits (1.2-2.1 times) are set for the most common complex mining and geological conditions in which the operation of the unit is provided. The height of the ledge is from 10 to 55 m. The width of the processed entry is from 30 to 50 m. The bucket capacity is from 20 to 100 m ³ .

 When determining the limits under consideration (1.2-2.1 times), the dumping platform 2 was placed from the upper edge of the inner blade 14 at a distance equal to the sum of the width of the prism of the possible collapse and the width of the processed sunset. The downhole running platform was placed from the upper edge of the overburden ledge 15 at a distance equal only to the width of the prism of a possible collapse. The distance from the upper edge of the inner blade 14 to block 9 when unloading the bucket and from the upper edge of the overburden ledge 15 to block 7 when the upper edge is frill is taken based on the parameters of the bucket 11 in conjunction with its suspension.

 The stated nature of the arrangement of the elements of the unit provides a decrease in the height of the mast 3 of the downhole running platform 1 in comparison with the height of the mast 4 of the dumping running platform 2 for all values of the height of the ledge, the width of the worked cast and the capacity of the bucket. In this case, the lowest value of the limit 1.2 corresponds to a step height of 55 m, a width of a worked-in run-in of 30 m for all values of the bucket capacity. The largest value of the limit of 2.1 corresponds to the height of the ledge 10 m, the width of the worked-in run 60 m for all values of the bucket capacity.

 Within the considered limits (1.2-2.1 times), the unit’s operability and technical result are achieved with masts of the minimum necessary height corresponding to mining and geological conditions.

 A decrease in the indicated limit of values of less than 1.2 is possible due to an increase in the height of the mast 3 of the downhole running platform 1. In this case, the weight of the downhole running platform 1 increases, which leads to an increase in the specific pressure on the ground and exclude the possibility of using the aggregate in weaker rocks. As a result, the technical result is not achieved by expanding the technological capabilities of the unit.

 A decrease in the considered limit of values (1.2-2.1) to less than 1.2 is also possible due to a decrease in the height of the mast 4 of the dumping platform 2. In this case, the unloading heights of the bucket 11 of the required value on the dump 14 are reduced to technically impossible. As a result, the unit becomes inoperative, and, as a result, the technical result, the expansion of technological capabilities is not achieved.

 An increase in the considered limit of values (1.2-2.1) more than 2.1 is possible due to a decrease in the height of the mast 3 of the downhole running platform 1. In this case, the distance between the working platform of the overburden ledge 15 and block 7 of the supporting rope 6 of the downhole running platform 1 when the frill of the upper edge of the overburden ledge 15 of the desired value to a distance at which the friction of the upper edge of the slope of the overburden ledge becomes technically impossible. As a result, the unit becomes inoperative, and, as a result, the technical result, the expansion of technological capabilities is not achieved.

 An increase in the considered limit of values (1.2-2.1) more than 2.1 is also possible due to an increase in the height of the mast 4 of the dump platform 2. In this case, the weight of the dump platform 2 increases, which leads to an increase in the specific pressure on the ground and the exclusion the possibility of using the unit in weaker rocks. As a result, the technical result is not achieved by expanding the technological capabilities of the unit.

The bottom of the bucket 11 is made V-shaped with an angle α between two halves of the bottom 17, equal to 130-150 ^about .

The limits of the values of the angle α are optimal, since they provide the greatest filling of the bucket when scooping. In addition, for coherent rocks angle α is ^about 130, is connected to bulk-rocks ^about 140 and ^about 150 for bulk. For each type of rock (cohesive, cohesive-loose and loose), the indicated values of the angles α are optimal. If you deviate from the optimal value of the angle α in one direction or another, the filling of the bucket will decrease.

As a result, when the angle α between the two halves of the bottom 17 in the range ^of 130-150 greatest filling occurs when digging bucket 11, which increases the performance of the unit.

When the angle α is more than 150 ^about for loose rocks and less than 130 ^about for cohesive rocks, the filling of the bucket 11 when scooping is reduced, which reduces the performance of the unit.

 A unit for a transportless development system works as follows.

 The downhole running platform 1 is installed on the overburden ledge 15 at a distance from the upper edge of this ledge, excluding the collapse of the ledge under the influence of the load from the downhole running rotary platform 1. The dump running platform 2 is installed on the internal dump 14 at a distance from the upper edge of this dump, eliminating the collapse of the blade under the influence of the load from the dump chassis 2.

 Downhole running platform 1 moves along the overburden ledge 15. The dumping running platform 2 moves along the upper edge of the internal dump 14. At the same time, the blasted rock 18 is excavated, moved and stored in the dump within the contour 19-20-21.

 By moving the supporting 6 and 8 and the hoisting ropes 12 and 13, the bucket 11 is lowered to the place of scooping the rock. When this bucket 11 is released with its teeth down. Together with the ropes, blocks 7 and 9 are lowered.

 When installing the bucket 11 on the surface of the rock and moving the bucket 11 during scooping towards the downhole running platform 1 (Fig. 3), pull the hoisting rope 12 of the downhole running platform 1. When moving the bucket 11 during scooping towards the dump platform 2, pull traction rope 13 dump platform 2.

 After filling the bucket 11 with rock by the action of the supporting ropes 6 and 8 and the hoisting ropes 12 and 13, the loaded bucket 11 is torn off from the place of scooping and moved towards the internal dump to the place of unloading.

 When developing a mineral stratum after scooping, the bucket 11 is unloaded into a vehicle located on the soil of the mineral stratum.

 When the frill of the slope of the overburden ledge 15 (Fig. 4), the bucket 11 is lowered to the base of the slope of the overburden ledge 15, and the block 7 of the bearing rope 6 of the downhole running fixed platform 1 is installed above the upper edge of the overburden ledge 15. The bucket 11 is moved up the slope of the overburden ledge 15 up by tensioning the hoisting rope 12 of the downhole running platform 1. The angle of introduction is regulated by the hoisting rope 13 of the dumping running fixed platform 2.

 In the process of moving the bucket 11, the pieces of rock prone to fall are separated from the slope surface of the overburden ledge 15, some of which roll down, and some remain in the bucket 11.

 When conducting overburden operations on a transportless development system, the scooping of the rock is carried out mainly by moving the bucket 11 in the direction of the dumping platform 2.

 As a result, part of the rock moves to the internal dump in the process of scooping. This volume is 8-10% of the total overburden, which increases the performance of the unit.

 When excavating a mineral, for example, a shallow coal seam, scooping is done by moving the bucket 11 to both the bottomhole and the dump running fixed platforms 1 and 2. As a result, the loss of mineral in the area of the lower edge of the inner dump 14 is reduced.

Claims (2)

 1. UNIT FOR A TRANSPORTLESS DEVELOPMENT SYSTEM, including a bottom hole and dump platform with masts of various heights connected by a support rope, and a two-sided bucket, characterized in that the mast height of the bottom hole platform is 1.2 2.1 times less than the mast height of the dump platform wherein each mast is connected to the bucket by means of a hoisting rope enveloping the corresponding block fixed on the carrier rope, and the blocks are connected by communication. 2. The unit according to claim 1, characterized in that the bottom of the bucket is V-shaped and the angle between the planes forming the bottom is 130 150 ^o .

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