UA113899U - METHOD OF DISCOVERING THE ORE MINING OF THE IRON ORE - Google Patents

Abstract

The method of open development of upland iron ore deposits involves the development of covering soft rocks, drilling and blasting operations for the formation of ore and ore rocks, mining soft and rock ore and iron ore. The development of the fields is led by a cross-stretch with partial refinement of the covering soft rocks. The porososcate and rudoscate form from the lower border of the soft rocks of the overburden at the top of the mountain to the bottom surface, the latter being performed in two sections with a longitudinal jumper between them. Further, after drilling and blasting operations, rock rock mass is worked out during one of the half of the deposit extending between the rock and rudoskat ledges with the formation of extraction layers and deposits, and transporting the ore to the corresponding section of the rudoskat with unloading through the pre-formation. First, the backing layer of unstable rock of each ledge on the slope of the mountain is reversed with a back blast and transported the rock mass by wheel loaders to the corresponding ore or rock. Then the remnants of soft rock are removed at the top of the mountain and at the same time, with the reduction of the height of the mining works - they quench the corresponding rocks and rudoskat up to the level of the day surface and in the same way develop the opposite longitudinal part of the deposit.

Description

A useful model belongs to the mining business, in particular to the open method of developing iron ore deposits, which lie in mountainous terrain and sink to the level of the day surface.

There is a well-known method of open-pit development of mineral deposits, when ore is extracted on working horizons in a quarry in mountainous terrain and transported to the level of the day surface along vertical ore slopes. They are passed in an underground massif near the non-working side of the quarry, a storage bunker is built in the lower part, from which ore is loaded into railway cars and delivered outside the mountain through a tunnel slightly inclined to the horizon. Empty rocks are taken from the quarry to the edge of the mountain by dump trucks and unloaded under the slope with the help of bulldozers (Problems of development of the Udokan copper mine | hexti / S.N.

Radionov, S.P. Reshetnyak, 9.B. Krasnopolsky and others; under the editorship N.N. Melnikova. - Apatit!: ed.

Kola Scientific Institute Center of the Academy of Sciences of the USSR, - 1990, - 193 p.).

The disadvantage of this method is that the extraction and transport operations in the pit are carried out with the operation of vertical ore shafts, which requires too large capital investments for their construction and operation. Transportation of loose rocks to external dumps significantly increases the cost of excavation work. The storage of loose rocks in external dumps of considerable height adjacent to the mountain disturbs a large area of land. Its reclamation in the forestry direction is not carried out.

The closest in terms of technological essence and achievable result is the method of open development of the upland part of the deposit, starting from the top, in layers from the top of the mountain to the level of the dominant surface of the deposit with the formation of the accumulative composition of ore along the boundary contour of the quarry and temporary storage of empty rocks at the foot of the mountain. Mined ore is loaded into railroad cars and transported outside the quarry, and overburden is moved by rail to the developed space of the spent quarry |Dryzhenko A.Yu. Open pit mining: a textbook / A.Yu. Dryzhenko: Ministry of Education and Science

of Ukraine, National mountain university - D. NSU, - 2014. - 590 si.

The disadvantage of this method is that the use of dump trucks for the transportation of iron ore and overburden rocks with short transportation distances and the compressed development of transport communications on the top and slopes of the mountain cannot provide significant regulatory

From the productivity of extraction and transport works. The operation of direct loaders and dump trucks on mountain slopes is extremely dangerous.

The basis of a useful model is the task of improving the method of open mining of a mountain iron ore deposit, in which, with the introduction of new technological operations, it is possible to exploit a mountain deposit simultaneously along the entire height with the movement of the mining mass to steeply inclined ore slopes and rock slopes, in one technological process, it is possible to simplify the extraction technology and transportation of ore and overburden rocks with a significant increase in the productivity of mining transport equipment and a reduction in the time for their execution.

The task is solved by the fact that in the known method of open-pit development of a mountain iron ore deposit, which includes working out the overlying soft rocks, carrying out blasting for the formation of rock and ore slopes, working out soft and rocky rocks of overburden and iron ore, and differs in that , that the development of the deposits is carried out crosswise with the partial development of the overlying soft rocks, ore rock and rock rock are formed from the lower limit of the soft rocks of the overburden on the top of the mountain to the day surface, and the latter is carried out in two sections with a longitudinal bridge between them, further, after carrying out blasting works, working out the rock mining mass along one half of the extension of the deposit between the rock slide and the ore rock by ledges with the formation of extraction layers and tailings, and transporting the ore to the corresponding section of the rock rock with unloading through a previously formed enclosing shaft, and first of all, the covering side layer of the unstable rock is worked out the rocks of each ledge along the mountain slope with a return pile and transport the mining mass with wheel loaders to the corresponding ore or ore slope, then remove the remains of soft rock on the top of the mountain, and at the same time, with the lowering of the height of the mining operations, extinguish the corresponding rock and ore slope up to the level of the day surfaces and develop the opposite longitudinal part of the deposit in the same way.

The method is explained by drawings, where Figs. 1, 2 and 3 show a diagram of the sequence of development of a mountain deposit, where the following are marked on the plan and longitudinal and transverse sections: 1 - day surface; 2 - the top of the mountain with soft and semi-rocky rocks of the opening above; C - the transverse slope of the mountain; 4 - lift road; 5, 6 - steeply inclined red rock and rock rock, respectively; 7 - a layer of soft and semi-rocky rocks on the slopes of the mountain; 8, 9 - for storage bunkers of ore slag and rock slag; 10, 11 - corresponding outlets of storage bunkers for various types of rich and poor ore with corresponding feeders located below them; 12, 13 - opposite upper edges of the slope 5 in accordance with the location of the lift road 4; 14 - horizontal platforms of ledges; 15 - longitudinal wall of the ore slope; 16, 17 - independent sections of rudoskat; 18, 19, 20 - ledges for the formation of the working area of the quarry; 21 - extraction layers for the development of the massif of the mountain in the escarpments; 22, 23, 24 - the first, second and third extraction ports; 25 - the line of a possible shift of the mountain surface; 26 - safety shaft for unloading the wheel loader; 27 - an auxiliary road for the movement of return vehicles and vehicles.

The method of open development of a mountain deposit of iron ore can be implemented as follows. The development is carried out across the course of the deposit with partial development of the outcrop rocks at the top of the mountain. For this purpose, from the prevailing daytime surface 1T to the top of the mountain 2 along its transverse slope Z, a lift road 4 is passed, which is used to raise the bulldozer and with it, in the locations of the future steeply inclined rock slope 5 and rock slope B, their upper platforms are prepared before the start of construction. Then, a bulldozer is used from top to bottom to carry out ore rock 5 and rock rock 6. Previously, a layer of soft and semi-rocky rocks is removed from their surface on the slopes 7 with wheel loaders. The rock within the longitudinal cross-section of ore slope 5 and ore slope b is excavated with small-diameter wells and carefully blasted without disturbing the walls of the workings. Rocks loosened by the explosion under the influence of their weight roll down to the storage bunkers 8 and 9 and are unloaded by the corresponding feeders through the corresponding outlet openings 10 and 11 to railway vehicles, which are taken outside the construction site.

Along the bottom of the ore slide 5, a longitudinal wall 15 is built in its center, forming two independent sections 16 and 17 along its length, which move rich and poor ore from top to bottom under their own weight. These varieties are accumulated in the corresponding sections of the storage hopper 8, 9 and through the corresponding openings 10 and 11, the feeder is unloaded to vehicles.

During the construction of the ore slope 5, on the opposite side of the lift road 4, crossing its opposite upper edges 12 and 13 across the slope of the mountain Z, horizontal platforms 14 pass through horizontal platforms, which form the ledges of the working area of the quarry 18, 19 and 20 with the corresponding removable layers 21 in each of them.

After blasting operations, the development of each ledge 18, 19, and 20 is carried out by extraction layers 21 with the formation of extraction pits 22, 23, 24 on each of them. the working time is beyond the "line of possible shear on the solid base of the iron ore of each layer, the load of the rock to the wheel loader. The second 23 and subsequent pits 24 beyond the line of possible surface displacement 25 are removed by wheel loaders independently. Different types of ore are transported along the surface of the layer 21 to the edge of the ore dump 5, from where they are unloaded through the safety shaft 26 to its corresponding section 16 or 17. From the upper platform of the ore dump 5 and the mine dump 6 along their length, an auxiliary road 27 passes along which vehicles and the return mechlopata move to the place work The bottom and side walls of rock slope 5 and rock slope 6, if necessary, are reinforced with metal or concrete slabs.

To increase the productivity of mining operations, simultaneously with the development of the slope of the mountain With horizontal platforms 14, or with a certain delay, the opposite longitudinal slope of the mountain is put into operation and developed in the sequence described above. After the entire mining mass at the top of mountain 2 and within layer 21 along ledge 18 as a whole has been worked out, the reinforcement from the corresponding section of bedrock 6 and bedrock 5 is dismantled, and the rock mass below them is removed in the described sequence up to the level of day surface 1. In the same way in this way, the opposite longitudinal part of the deposit is developed, and at the same time as the height of the mining operations is lowered, the corresponding ore slope 6 and ore slope 5 are extinguished up to the level of the day surface 1.

The proposed method of open development of a mountain deposit of iron ore allows to obtain a significant saving of material and monetary resources. Thus, during the development of the Ueleba iron ore deposit located in the territory of the Republic of Guinea (Africa), ore reserves of 155.3 million tons were established, which are located in the mountainous part of the deposit 380 m above the prevailing surface level. According to the technical project, the overburden rock will be stored in an external dump.

Simplification of the development technology of a mountain iron ore deposit and the achievement of significant productivity of mining operations with a reduction in their cost price according to the prototype are achieved due to the development of overburden rocks with storage in the produced space of the quarry. because it is advisable to calculate the economic efficiency of the declared method based on the minimum operational costs for moving empty rocks and ore to the level of the earth's surface due to its weight on the corresponding rock and ore slope. In this case, the efficiency of the new technology is E, million dollars. USA, calculated by the formula:

IS-! 0-bSa (Mziz-M v.pivp); where: Са - costs for transporting 1 m" of mining mass for a distance of 1 km, US dollars; M.", Из - respectively, the volume and distance of transporting mining mass by dump trucks to the level of the earth's surface, million m3 and km; Mvl, Ivp - respectively, the volume and distance of transportation of the mining mass to the level of the earth's surface under the influence of its weight, million m3 and km.

According to the stated method, it is proposed to develop a 2 km long quarry field. At this time, the upland part of the deposit is put into operation and the quarry begins to function. According to the project, overburden rocks in the volume of Mz-Mva-153.3 million m" are sent for storage at a distance of 13-5 km. According to the declared method of performing overburden works, the same volumes of empty rocks will be sent along the mountain slope under the influence of their own weight at the appropriate average distance of transportation by Ivap wheel loaders is 3 km. The cost of 1 tkm of operation of road transport and wheel loaders is assumed to be the same and is Ca-0.925 US dollars. Based on the specified factors, the economic efficiency of the implementation of the declared method E, million US dollars, with minimum distances transportation is:

E-1050,925х153,3(5-3)-283,6.

According to the given data, the annual savings due to the introduction of new technology Er, million dollars. US/year, with a service period of 55 years can be:

Evs-E//-283.6/55-5.16.

The overall effectiveness of the proposed method will be substantiated in the process of implementing project documentation for the development of the deposit and will be significantly increased due to the reduction of capital investments for the construction and operation of steep rock and ore slopes.

Claims (1)

USEFUL MODEL FORMULA The method of open-pit development of a mountain deposit of iron ore, which includes working out the overlying soft rocks, carrying out blasting operations for the formation of rock and From ore slopes, working of soft and rocky rocks of overburden and iron ore, which is distinguished by the fact that the development of deposits is carried out cross-striking with partial working of overlying soft rocks, ore slopes and ore slopes form from the lower limit of soft rocks of the overburden on the top of the mountain to of the bottom surface, and the latter is performed in two sections with a longitudinal bridge between them, then, after blasting, the rock mining mass is worked out along one half of the deposit extension between the rock slope and the ore slope with ledges with the formation of extraction layers and pits, and the ore is transported to the corresponding section of the ore slope with unloading through a pre-formed enclosing shaft, and first of all, the covering side layer of unstable rock of each ledge on the mountain slope is worked out with a reverse machete and the mining mass is transported by wheel loaders to the corresponding ore or rock slope, then the remains of soft rock on the top of the mountain are removed and at the same time but, with a decrease in the height of the mining operations, the corresponding rock and ore slopes are extinguished up to the level of the day surface and the opposite longitudinal part of the deposit is developed in the same way.