PL216537B1 - Method of rocks reinforcement in surrounding of existing mine workings - Google Patents

Description

Description of the invention

The subject of the invention is a method of rock strengthening in the vicinity of existing mining excavations, useful in particular in the case of excavations with a rigid masonry or concrete support, both horizontal and inclined or vertical.

Along with descending mining operations to ever greater depths, the problem of maintaining corridor workings and access workings, such as main trenches or shafts, in a usable condition, grows. It should be noted that descending with exploitation causes an increase in dynamic phenomena affecting mining excavations, especially bumps constituting a significant threat to the safety of work in the mine. While in mining excavations this problem is sufficiently solved thanks to modern structures of powered supports, in corridor and vertical workings the degree of pressure control and dynamic relaxation is not sufficient. Hence, cracks in the lining often occur, reducing its load-bearing capacity and strength, and the destruction of rocks directly adjacent to the support, which increases with time, resulting in the lack of proper cooperation of the support with the rock mass, and as a result, rapid destruction of sections of the excavation support. The methods used so far to protect workings against deformation and destruction are, first of all, reinforcement of the support with struts, additional field arches or securing piles, which definitely affects the functionality of the workings and causes additional costs of such protection. If the damage is already too great, it is necessary to rebuild the excavation, which is a costly and dangerous undertaking, or even to construct a completely new excavation as a bypass for the damaged excavation. At the same time, all known methods of protection constitute a factor that greatly disorganizes the mine's operation, which in practice can be very onerous.

For example, from the Polish patent specification No. 189 673, a method of sealing the rock mass is known, consisting in making injection holes in the rock mass around the designed excavation, into which, under pressure, a liquid sealing agent is injected, which becomes solid at a given time. The spatial arrangement of the holes, their mutual distance and length are determined on the basis of the previously carried out studies of rock fracture. It is a method that can be used, in principle, for the construction of a new excavation, but not for the renovation of the existing one.

There is also known, for example, from Polish patent specification No. 167 902, a method of active protection against the effects of rock bursts and tremors in the vicinity of mining excavations, in which, on the basis of geophysical measurements, the width of the buffer zone at the mining excavation is determined mathematically according to the mathematical dependence. in the buffer zone, the cracking zone, and then into the part of the buffer zone at the side walls of the excavation, two-component polyurethane adhesive is injected through the boreholes, preventing, after binding, the movement of coal crush to the mining excavation. This method theoretically allows the excavation to be protected against rock bursts, but in practice it may have various effects, for instance due to the considerable variability of the measured values taken into account in the calculations.

In addition, to protect mining excavations against the influence of water from the rock mass, a two-step injection is used, which was disclosed in the publication "Materials of the School of Underground Operation" '96 from the conference held in Szczyrk on 02 26/03 1996, issued in Krakow in 1996. This method consists in forcing an external injection layer around the casing of the excavation, beyond which, after it has been bonded, another layer is injected to insulate the excavation from the influence of water. However, it is a technology that does not have a significant impact on the formation of mechanical loads in the rock mass surrounding the excavation, as it only serves to close the channels and water-carrying cracks.

The aim of the invention is to develop such a method of rock strengthening in the vicinity of the existing mining excavations, which will be much easier to implement, and at the same time much cheaper and more universal.

The method according to the invention is based on the fact that chemically-hardened binders with different strength parameters for each zone, formed at different depth intervals, are injected into the rock mass surrounding the existing excavation subject to the influence of destructive forces.

PL 216 537 B1

It is advantageous when the zone located in the immediate vicinity of the excavation support is made of chemically hardened binders with the highest mechanical strength after setting.

It is also best when a zone with very low mechanical strength is created between the rock mass zones into which the chemically hardening binder of high mechanical strength has been injected, which creates a zone that absorbs static and dynamic loads acting on the excavation support.

In such a case, it is possible to implement the method in such a way that after making the extreme zones of high mechanical strength, the cushioning zone lying between them disintegrates, for example fractures, which creates a buffer which discharges the impact of sudden dynamic forces.

It is desirable to implement the method in which, first of all, holes are drilled from the excavation to the outermost zone of the excavation, injection bolts with an appropriately positioned assembly for sealing the anchor hole are inserted in them and injected with a self-hardening injection binder through these bolts. this zone of the resulting mechanical strength, and then holes are successively drilled and forced through injection bolts with appropriately set sealing units of the chemically hardening binder selected for the successive zones approaching the excavation support.

In practice, it is good to strengthen the rocks at the excavation progressively with strips of their width matched to the local conditions, which significantly reduces disorganization in the normal use of the excavation, and at the same time increases work safety.

A variation of the method according to the invention is that first the self-curing binders are injected into the innermost zone adjacent to the full pit casing, and then the curing agents are injected between this crowded zone and the full pit casing to form an outer zone.

It is preferred that the chemically hardened binder fed directly under the mantle of the excavation casing is injected at a pressure significantly lower than the injection pressure of the chemically hardened binder into the deep zone of the rock mass.

The main advantage of the method according to the invention is that in the rock mass surrounding the excavation, zones with mechanical strength and thickness adjusted to the depth are created, thanks to which the rock mass functions as a bundle of connected beams, and this results in better maintenance of the excavation. Additionally, by varying the strength, it is possible to create such a system of zones in which the zones of low mechanical strength located between the zones of high mechanical strength will work as absorbing and dissipating dynamic loads acting on the excavation. When making several zones, the anchor holes are arranged according to the drilling meshes offset to each other, which results in the creation of a reinforced mantle and reconsolidated rock mass in the rock mass around the excavation, and thus a significant improvement in the maintenance conditions of the excavation.

The method according to the invention allows for adaptation to various, specific conditions occurring in the surroundings of the excavation on its given section, which makes it universal in relation to both horizontal and vertical excavations occurring in hard coal mines.

The invention is explained in more detail in the embodiment in the drawing, where Fig. 1 shows, in a schematic simplification, the paving excavation reinforced with three zones made with injection bolts and a self-hardening binder, and Fig. 2 - a fragment of the excavation in a wall casing in cross-section, reinforced with injection bolts. and the binding agent crowded by these bolts into the rock mass.

First, along the length of the selected strip of the excavation 1 (Fig. 1), on the circumference of its casing 2, according to the predetermined drilling pattern, anchor holes 3 are drilled. Then, injection bolts 4 with sealing assemblies 5 located at depth l1 are placed in the anchoring holes 3. a polyurethane binder having a very high mechanical strength after setting is forced through these injection bolts 4. The rock mass 6, injected by these injection bolts 4, after binding of the binding agent, forms a reinforcement zone A surrounding the excavation 1 at a distance greater than the injection depth 11 of the binding agent.

After completing the formation of the deep zone A, anchor holes 7 are drilled around the excavation 1, shifted from the original drilling grid, extending to zone A, and injection bolts 4 with sealing units 5 located at depth I2 are embedded in them, and then buried4

After setting, a polyurethane binder with a very low mechanical strength after setting, selected according to the strength of the rocks surrounding the rock mass, is deposited through them 6. After setting, the pressed binder forms zone B surrounding the excavation 1 at a distance between the depth l1 of zone A and I2 zone B. In the last phase C, with a shifted drilling pattern, 1 anchor holes 8 are drilled around the perimeter of the excavation, overlapping with zone B, and injection bolts 4 are embedded in them with sealing units 5 located directly in the area of the excavation support 2. These injection bolts 4 polyurethane binder with very high mechanical strength after setting, around the excavation 1 zone C of the injected rock mass is created 6. The different mechanical strength of zones A, B and C causes that zone B with the lowest mechanical strength takes over and dissipates, and thus absorbs energy of dynamic impacts of the rock mass na excavation 1, which protects this excavation 1 from rapid destruction.

In the case of securing the excavation 1 in a masonry or concrete casing 2, for example serving as a shaft (FIG. 2), the reinforcement is made according to a variant of the invention. First, on the perimeter of the excavation 1, anchor holes 3 are drilled with a predetermined drilling scale, into which injection bolts 4 with sealing units 5 located at a distance I1 from the tip of the injection bolts 4 are inserted, and then a polyurethane binder is injected through these injection bolts 4. As a result, a deep zone D of the rock mass reinforcement 6 around the excavation 1 is obtained. Then, with a shifted drilling pattern around the excavation 1, shorter anchor holes 7 are drilled, and injection bolts 4 are embedded in them with sealing units 5 located next to or in the housing 2 of the excavation. 1 and is injected with a polyurethane binder. As a result of this injection, a reinforced zone E is created, including a part of the rock mass 6 between the casing 2 and the zone D, as well as the casing 2 itself by infecting and filling all possible gaps, cracks and cavities in the casing 2.

Claims (8)

Patent claims 1. The method of rock strengthening in the vicinity of the existing mining excavations using the injection of chemically hardening agents into separate layers surrounding the excavation and injection bolts set in holes drilled around the perimeter of the excavation, with a scale adjusted to the local geological mining conditions, characterized by the fact that the rock mass surrounding the excavation (1) (6) are jammed into zones (A, B, C) formed at different depth ranges, binding agents with different strength parameters. 2. The method according to p. A method as claimed in claim 1, characterized in that the zone (C) in the immediate vicinity of the housing (2) is made of self-hardening binders with the highest mechanical strength after setting. 3. The method according to p. The method according to claim 1 or 2, characterized in that between the zones (A, C) of the rock mass (6), a zone (B) with a very low mechanical strength is created between the zones (A, C) of the rock mass (6) with a high mechanical strength, which is a cushioning zone for the loads acting on the casing. 4. The method according to p. 3. The method according to claim 3, characterized in that, after making the extreme zones (A, C) with high mechanical strength, the zone (B) is fractured therebetween. 5. The method according to p. A method according to claim 1, characterized in that holes (3) are first drilled to the outermost zone (A), injection bolts (4) with an appropriately positioned sealing unit (5) are inserted in them and a self-hardening binder is injected with the intended zones (A) of mechanical strength, and then holes (7, 8) are successively drilled between them and the injection bolts (4) with appropriately set sealing units (5) are injected with a chemically hardened binder selected for the successive zones (B, C) of the approaching to the housing (2) of the excavation (1). 6. The method according to p. The method as claimed in claim 1 or 4, characterized in that the reinforcement of the rocks is performed with progressive strips with the width of the excavation (1) matched to the conditions. 7. Method of rock strengthening in the vicinity of the existing mining excavations, according to which chemically hardening agents are injected into separate layers surrounding the excavation support by injection bolts embedded in boreholes on the circumference of the excavation with a scale adjusted to the local mining and geological conditions and for each of the separate layers, characterized by first injecting the chemically hardening binders into the innermost zone (D) After the complete casing (2) of the excavation (1), the self-curing binders are injected between this crowded zone (D) and the complete casing (2) of the excavation (1) forming the outer zone (E). 8. The method according to p. The method of claim 7, characterized in that the chemosetting agent fed to the outer zone (E) under the mantle of the full casing (2) is injected at a pressure significantly lower than the injection pressure of this agent into the downhole zone (D).