RU2198293C2 - Method of ore deposits mining - Google Patents

Abstract

FIELD: mining industry, particularly, mining of thick ore deposits. SUBSTANCE: method includes driving of haulage, ventilation and drill workings, drawing holes in block bottom, drilling of blast holes and breakage of ore by fan holes in clamp under caved rocks. Block is divided into two parts. Breakage of ore overlaying part is carried out by leading along the strike of ore deposit, and then, breakage of ore of block underlying part is effected by sections along the strike of ore deposit. Volume of breakage in sections is selected depending on conditions of seismic safety of haulage workings. In this case, drawing holes in block bottom are driven directly before blasting of next section and they are filled with broken rock mass before section blasting. EFFECT: higher breakage output and working safety. 2 cl, 2 dwg

Description

 The present invention relates to the mining industry and can be used in the development of powerful ore deposits with collapse of overlying rocks without compensation space, in the "clamp".

 A known method of developing a powerful ore deposit (ed. St. 1017796, E 21 C 41/06, published in BI 18, 1983), including dividing the deposits into sections, conducting delivery workings across the extension of the deposit from the lying side, excavation of ore deposits with leading breaking of sections adjacent to the hanging side, placement of delivery workings in sections between leading sections and sections worked from the lying side of the deposit along the strike, connecting them to delivery workings, passed across the strike and leading layers and sections in directions coinciding with the direction of said openings in the sections and on the boundary sections of the delivery workings driven in different directions to form the shielding gap.

 The disadvantage of this method is the relatively low intensity of the mining of ore deposits, which, in the absence of compensation space, is limited by the seismic effect of the exploding sections on the delivery workings and is not well shielded by shielding slots.

 The closest in technical essence and the achieved result to the proposed method is a method of developing ore deposits (Agoshkov M.I., Borisov S.S., Boyarsky V.A. Development of ore and non-ore deposits, 3rd ed., M .: Nedra, 1983 , pp. 222-225, Fig. 115 g), including carrying out transport, ventilation and drilling workings, production workings at the bottom of the block, drilling blast holes and breaking the ore with fan fans in a clamp under collapsed rocks.

 The disadvantage of this method is the destruction of the mine workings at the bottom of the block and transport workings due to the seismic effects of mass explosions, which requires emergency recovery work and reduces the effectiveness of the technology.

 Technical task: to increase the safety of output workings and transport workings in the bottom of the block by reducing seismic effects from sectional explosions in the lower part of the block while ensuring high ore breaking performance due to mass breaking of ore in the overlying part of the block.

 The problem is solved in that in the known method of developing ore deposits, including carrying out transport, ventilation and drilling workings, production workings in the bottom of the block, drilling blast holes and breaking the ore with fans of holes in the clamp under the collapsed rocks, according to the technical solution, the block is divided in height into two parts, the ore of the overlying part is beaten ahead of the strike of the ore deposit, after which the ore of the underlying part of the block is broken down sectionwise across the ore strike beyond lie, and the volume of blasting in the sections is selected from the condition of seismic safety of the transport workings, while the production of output in the bottom of the block is carried out immediately before the blasting of the next section and fill them before it is blown up with the broken rock mass.

 At the same time, an increase in the safety of transport workings and output workings in the bottom of the block is achieved by reducing the seismic effect on the workings of the bottom of the block from sectional explosions in the lower part of the block while ensuring high efficiency of breaking the ore in the blocks due to the use of mass explosions in the upper part of the block with high quality crushing ore in a clamped environment.

где r - расстояние от условного центра взрыва до транспортной выработки, м;
q - расход взрывчатого вещества (ВВ), кг/м³;
С_р - скорость продольной волны, 10^-2 м/с;
σ_p - предел прочности пород днища блока при растяжении, МПа;
n - число ступеней замедления при взрывании;
К_с - коэффициент сейсмического действия, м³ кг^-2/3 с^-1;
Е - модуль упругости пород, МПа.It is advisable to determine the height h of the underlying part of the block from the expression
h ^m + h = B,
where m is an indicator of the degree of attenuation of seismic oscillations in the array;
B - block height, m,
and the volume V of breaking in sections of the underlying part of the block - from the ratio

where r is the distance from the conditional center of the explosion to the transport output, m;
q is the consumption of explosives (BB), kg / m ³ ;
With _p - the velocity of the longitudinal wave, 10 ^-2 m / s;
σ _p - tensile strength of the rocks of the block bottom under tension, MPa;
n is the number of stages of deceleration during blasting;
K _s - seismic coefficient, m ³ kg ^-2/3 s ^-1 ;
E - modulus of elasticity of rocks, MPa.

 At the same time, an additional increase in the safety of the mine workings in the bottom of the block and transport workings is achieved due to the reduction of the seismic effect of section explosions on them in the lower part of the block due to a more accurate calculation of the parameters of ore breaking in sections.

 The essence of the technical solution when implementing the method on the example of developing a powerful steep-dipping ore deposit is illustrated by the description of the implementation example and the drawings, in which Fig. 1 shows a vertical cross-section through the strike of the ore deposit; figure 2 is a section aa in figure 1.

 The proposed method is implemented as follows.

 On the horizon of the general release, across the strike of the ore deposit 1, transport workings 2 pass at the bottom of the block, of which the locations of the workings of output 3 are marked. Above the horizon of the general output (on the sub-floor) are sub-floor drilling workings 4 and ventilation workings 5 in the host rocks 6. Block 7 Deposits 1 are divided into two parts: the overlying part 8 and the underlying part 9 so that the height h of the underlying part 9 is not less than necessary to ensure the stability of the sub-floor drilling 4 when blasting BB in the upstream part 8 of block 7. At the same time, the stability of the transport workings 2 is ensured. Blasting holes 11 are drilled from the drilling workings 10 in the upstream part 8 of block 7. When breaking in the overlying part 8 of block 7 along the strike in the clamp (Fig. .2) good crushing of the broken ore 12. is achieved. In the lower part 9 of block 7, sections 13 are allocated in such a way as to avoid destruction of the transport workings 2 due to the seismic effects of explosives during breaking of sections 13 across the spread of ore deposit 1. In each section 13 and From sub-floor drilling workings 4, drilling fans of blasting holes 14 are drilled, immediately prior to blasting of which from transport workings 2, workings of output 3 are blown through by blasting holes 15 (Fig. 1). Excavations of release 3 before blasting of the next section 13 are filled with broken rock mass 16 to prevent their destruction when blasting fans of blast holes 14 in sections 13. The broken ore 12 is released through excavations of 3 releases under collapsed rocks 17.

где r - расстояние от условного центра взрыва до транспортной выработки, м;
q - расход ВВ, кг/м³;
С_р - скорость продольной волны, 10^-2 м/с;
σ_p- предел прочности пород днища блока при растяжении, МПа;
n - число ступеней замедления при взрывании;
К_с - коэффициент сейсмического действия, м³•кг^-2/3•с^-1;
Е - модуль упругости пород, МПа.It is advisable to determine the height h of the underlying part 9 of block 7 from the expression
h ^m + h = B,
where m is an indicator of the degree of attenuation of seismic oscillations in the array;
B - block height, m,
and the volume V of breaking in sections of the underlying part of the block - from the ratio

where r is the distance from the conditional center of the explosion to the transport output, m;
q is the consumption of explosives, kg / m ³ ;
With _p - the velocity of the longitudinal wave, 10 ^-2 m / s;
σ _p - tensile strength of the rocks of the block bottom under tension, MPa;
n is the number of stages of deceleration during blasting;
K _s - seismic coefficient, m ³ • kg ^-2/3 • s ^-1 ;
E - modulus of elasticity of rocks, MPa.

 At the same time, the safety of mine workings 3 of the outlet and transport mine workings 2 in the bottom of block 7 is achieved by reducing the seismic impact on these mine explosives of explosives in sections 13 of the lower part 9 of block 7 while ensuring high output of broken ore 12 due to the use of mass explosions in the overlying part 8 of block 7 with high quality crushing ore 12 in a "clamped medium".

Claims (2)

 1. A method of developing ore deposits, including carrying out transport, ventilation and drilling workings, production workings in the bottom of the block, drilling blast holes and breaking the ore with fans in the clamp under the collapsed rocks, characterized in that the block is divided into two parts in height, breaking the ore of the overlying part lead ahead of the strike of the ore deposit, after which the ore of the lower part of the block is blasted sectionwise across the strike of the ore deposit, and the breakdown volume in the sections is selected from the condition transport preservation smicheskoy workings, the production output in the bottom block is performed immediately before the next blasting section and fill them up to its detonation of broken rock mass. 2. The method according to claim 1, characterized in that the height h of the underlying part of the block is determined from the expression
h ^m + h = B,
where m is an indicator of the degree of attenuation of seismic oscillations in the array;
B - block height, m,
and the volume V of breaking in sections of the underlying part of the block - from the ratio

where r is the distance from the conditional center of the explosion to the transport output, m;
g is the consumption of explosives, kg / m ³ ;
C _p - longitudinal wave velocity, 10 ^-2 , m / s;
σ _p is the tensile strength of the rocks of the block bottom under tension, MPa;
n is the number of stages of deceleration during blasting;
K _c - seismic coefficient, m ³ kg ^-2/3 s ^-1 ;
E - modulus of elasticity of rocks, MPa.

Images