RU2128773C1 - Method for supporting mining workings with loose roof rock by anchor support - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: according to method, bore-holes are drilled in roof during driving of workings. Load-bearing ceiling is formed, and anchors are secured in it. Bore-holes are drilled in roof rock with advancement of cut face by two runs. Drilled from them at side of working are inclined bore-holes with their extension beyond contour of pressing-out and dangerous deformations of rock mass in sides to value equal to 0.25-0.3 width of working. After that, solution of hardening mixture is injected into bore-holes, and load-bearing ceiling is formed over width of underground working with protrusion of ends of load-bearing ceiling beyond contour of pressing-out and dangerous deformations in sides to values equal to 0.25-0.3 of underground working width. Application of aforesaid method allows for reduction of supporting cost together with increasing stability of underground workings. EFFECT: higher efficiency. 3 dwg

Description

 The invention relates to mining, and in particular to methods of fastening with anchor support for mine workings, the roof of which is composed of weak rocks.

 Anchor support is used in coal and ore mines for fastening capital and preparatory workings, the roof of which is composed of strong and medium-strength rocks, i.e. rocks in which anchors can be fixed with a force sufficient to absorb rock pressure and ensure a safe working condition throughout the entire service life.

 In workings with weak roof rocks, anchor support is not used. The exception is individual cases when the rocks are pre-hardened with cementitious materials - cement-sand mortars or resins, and then the anchor support is used independently or in combination with the usual types of supports.

 The use of anchor supports, characterized by very low material consumption and low cost, in workings for weak breeds, especially with a weak roof, instead of material-intensive and expensive frame, monolithic concrete and solid precast reinforced concrete supports, will dramatically increase the efficiency of the workings fastening.

 Known methods of hardening collapsed rocks with binder materials, the formation of an artificial roof from them and the conduct of hardened rocks under the protection of an artificial roof workings as. USSR N 655459, class E 21 D 9/04, 1979, a.s. USSR N 1033757, class E 21 D 19/00, E 21 D 9/04.

 In these methods, the hardening of the collapsed rocks and the formation of an artificial roof from them are determined to ensure the safe conduct of workings on them and fixing them with frame or solid support. They do not define the conditions and parameters for the formation of a hardened roof with cementitious hardening materials suitable for anchoring in workings.

 A known method for A.S. USSR N 1682580, class E 21 D 11/00, 1991, which determines the area of formation of artificial roofs from collapsed rocks when the workings are blocked by host rocks by hardening them with cementitious materials and installing reinforcing bars in them with locks secured to the rock formation loop. The area of attachment of the workings with anchor support, the roof of which is composed of weak rocks, this method does not determine.

 Known methods for increasing the stability of the ore mass as.with. USSR N 1219814, class E 21 D 20/00, N 1617149, cl. E 21 D 20/00, N 1739044, E 21 D 20/00, the essence of which is to drill from the developed space into the ore mass of wells, install anchors in them, excavate previously anchored ore thickness with tapes and horizontal layers in an ascending order under the protection of established anchors. In these methods, the issues of fixing a weak roof with an anchor support of conducted and supported mine workings are not resolved and the technical solutions known in them do not allow creating a method of fixing workings with weak unstable rocks of the roof with an anchor support. They provide mining of ore deposits in ascending order, rather than fixing and maintaining workings in weak rock massifs with different service lives.

 There is a method of leading anchor fastening when driving workings on and.with. USSR N 1765441 A1, cl. E 21 D 20/00, according to which, when driving openings, inclined leading holes are drilled in the direction of the development, at the end of the inclined part of each hole, a curved section is drilled and then a section perpendicular to the longitudinal axis of the development. The inclined part of each hole is drilled inside the excavation circuit to a depth equal to the length of the drill, while a number of additional perpendicular-directed sections of the hole are drilled from the inclined part with an interval along its length, moreover, the anchors are installed within the direction of the perpendicular sections, and the free part is used after installation Anchors for explosive rock breaking.

 The disadvantage of this method is the lack of a solution for the formation with the help of anchors load-bearing roofs from weak rocks. In addition, the method is very time-consuming due to the need to drill holes for mounting anchors in an arcuate manner, moreover, from the inclined part of the holes, the vertical part of the holes, into which flexible anchors (cable, wire) are installed and, if necessary, are monolified with a hardening mixture. Monolithic anchors in the holes can be made only after the excavation of the rock of the next bookmark.

 The closest technical solution to the claimed invention is a method of securing a mine working as. USSR N 1763674 A1, E 21 D 20/00, which consists in drilling holes in the roof of the mine as it is drilled, installing short submersible and long ductile anchors, holding an unloading gap along the mine and filling it with ductile material, moreover, before installing ductile anchors in the roof of the mine form a reinforced ceiling at a distance from its contour of 0.2-0.25 of the width of the mine, which is reinforced with short immersed anchors, with a length equal to its power, and compliant anchors are set with a length equal to the total lower power and hardened ceiling. The strength of the hardened ceiling is formed taking into account the development gap, physicomechanical properties of the host rocks and the stresses acting in them, based on the perception of the load from the overlying rocks in the pressure vault.

 The disadvantage of this method is that the hardened ceiling is formed after exposure of the roof rocks, which does not exclude the development of dangerous deformations and collapse of weak rocks over time from the moment of exposure to the formation of the ceiling using short immersion anchors or until the installation of ductile anchors with the subsequent formation of the ceiling.

 The width of the ceiling molded by this method is less than the width of the excavation, which is taken based on the width of the natural arch of the collapse of the roof rocks without taking into account possible dangerous deformations of the rocks in the sides of the excavation and their collapse. In the practice of coal and deposits of other minerals, crushing and destruction of rocks in the sides of a mine usually occurs and the width of dangerous deformations and rock outfalls in the roof is significantly larger than the width of the roof collapse roof and the mine width. Consequently, the formation of the ceiling without taking into account dangerous deformations of the rocks in the sides of the excavation and the fastening of the roof of the excavation with anchors does not ensure the stability of the roof and the safe operation of the excavation.

 In addition, this method is very time-consuming, since it involves screwing in the submersible short anchors, with the help of which they form the ceiling, and the device of the discharge gap in the middle of the excavation to a depth to the lower boundary of the hardened ceiling.

 The task of the invention is to reduce the cost of fastening and maintaining the workings and increasing their stability.

 The solution to the problem is achieved by the fact that in the proposed method, including drilling wells in the roof during the workings, forming a load-bearing ceiling, securing anchors in it, characterized in that the wells in the roof rocks are drilled ahead of the bottom by two runs, of which the wells are at the production sides drill obliquely with their exit beyond the extraction circuit and dangerous deformations of the rocks in the sides by an amount equal to 0.25-0.3 of the width of the working hole, inject the solution of the hardening mixture into the wells and form a load-bearing ceiling along the working width from the exit and its ends beyond the contour of the spin and dangerous deformations of the rocks in the sides by an amount of 0.25-0.3 of the working width.

 The proposed method provides, in comparison with the prototype, hardening of the roof rocks in the array to their exposure, which eliminates their dangerous deformation from the moment of exposure to the formation of a load-bearing ceiling and fixing the roof with anchor support. As a result of preliminary hardening of roofing rocks in the massif, an increase in the stability of roofing rocks and safety of work is achieved.

 In the inventive method, in comparison with the prototype, a load-bearing and safe ceiling is formed along the working width based on the width of the possible collapse and dangerous deformations of the roof rocks, which in real mining conditions is made up directly of the working width and the spin value and dangerous rock deformations and the size safe termination (deepening) of its ends (ceiling) behind the dangerous side circuit of the mine. This feature, which is very different from the prototype, provides reliable and safe functioning of the ceiling and, therefore, anchor support and development throughout its entire service life.

 The proposed method in comparison with the prototype is less laborious, since the ceiling is formed not by short immersion anchors with a length equal to the power of the ceiling, which is installed by screwing, but by hardening the roof rocks with a quick-hardening mixture to a load-bearing state. In addition, the method does not include the device of the discharge gap in the roof of the mine, which is a very time-consuming work and in weak rocks leads to a sharp decrease in their stability in exposure.

 Drilling of wells in the roof ahead of the bottom of the output by two runs reduces the time for hardening the mixture (compared to leading the bottom of the hole by one run) and the formation of a load-bearing ceiling, reduces the time spent on the preparatory and final operations of the sinking cycle, and at this length of wells, their effective drilling , uniform and benign injection and distribution of the solution in the hardened rocks. Such an advance is most optimal in terms of ensuring uniform and reliable distribution of the solution in the hardened rocks and the formation of a ceiling and in terms of organizing high-speed excavation of workings.

 An analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the claimed invention, made it possible to establish that the applicant did not find a source characterized by features that are identical (identical) to all essential features of the claimed invention. The definition from the list of identified analogues of the prototype, as the closest in the totality of the features of the analogue, allowed us to establish a set of significant distinctive features in relation to the applicant’s perceived technical result in the claimed method set forth in the claims.

 Therefore, the claimed invention meets the condition of "novelty."

 In FIG. 1 shows a cross-section of a mine with hardened roof rocks and a fixed anchor support, FIG. 2 is a longitudinal section AA, in FIG. 1 with the location of leading boreholes; in FIG. 3 is a section bb in FIG. 1.

 The method is as follows.

 As production 1 is carried out with weak roof rocks, directly from the bottomhole space of the development, the roof of the well 2 is drilled, two holes ahead of the bottom hole 3. Wells 4 are drilled obliquely at the sides of the roof at the sides of the mine, beyond the extraction circuit and dangerous rock deformations in the sides 5 by an amount equal to 0.25-0.3 of the width of the output. In mines developing coal, ore and other mineral deposits, capital and preparatory workings are usually carried out with a width of 3 to 6 m. Therefore, wells 4 at the sides of the mine must be drilled with a length that extends beyond the contour of the zone of possible extraction and dangerous deformations in the sides of the mine by a value from 0.6-0.75 m (with a working width of 3 m) to 1.5-1.8 m (with a working width of 6 m. The amount of spin and dangerous deformation of the rocks in the sides of the working in specific mining and geological and mining technical conditions are usually determined and structural and visual observations and testing the rocks for strength After drilling leading wells 2 and 4 into the roof for the next two openings 3 of the bottom, they inject a solution of a hardening mixture, for example cement-sand, with additives that accelerate setting and hardening, strengthen roofing rocks and form load-bearing ceiling 6, which provides reliable anchoring of the anchor lining in it and the pressure of overlying rocks is perceived.Cexture 6 is formed along the width of the mine with the exit of its ends 7 beyond contour 5 of the spin and dangerous deformations generating laterally by an amount 0.25-0.3 width generation (sinking in). Then, after hardening in the rocks of the solution, boreholes are drilled into the ceiling and anchors 8 are installed in them according to the passport of fixing the excavation in specific conditions. Anchor locks are fixed in the ceiling with the strength required for specific conditions.

 The proposed method improves the reliability and efficiency of fastening mine workings with weak roof rocks, increases their stability, reduces the costs of fastening and maintaining workings by providing a more complete use of the bearing capacity of roof rocks and the formation of a ceiling based on the features of deformation and destruction of rocks under the influence of rock pressure.

Claims (1)

 A method of attaching mine workings with weak roof rocks with an anchor support, including drilling wells into the roof during workings, forming a load-bearing ceiling, securing anchors in it, characterized in that the wells in the roof rocks are drilled ahead of the bottom by two runs, of which the wells are at the sides the workings are drilled obliquely with their exit beyond the extraction circuit and dangerous deformations of the rocks in the sides by an amount equal to 0.25 - 0.3 of the width of the workout, a solution of the hardening mixture is injected into the wells and a load-bearing ceiling is formed in width not developing with the exit of its ends beyond the spin cycle and dangerous deformations of the rocks in the sides by an amount of 0.25 - 0.3 of the width of the working.

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