RU2398967C1 - Method for tunnelling of vertical shafts in watered unstable rocks and device for its realisation - Google Patents

Abstract

FIELD: mining. ^ SUBSTANCE: method for tunnelling of vertical shafts in watered unstable rocks includes freezing of rocks, blast-hole drilling, mechanised loading of rocks, fixation of shaft with cast iron tubes and further plugging of clamping space. In process of blast-hole drilling, zones of mine position are determined with permissible limit force of elastic waves action at freezing columns relative to border of two rocks contact with various physical-mechanical properties. Afterwards, rocks are damaged in these zones in mode, which provides for values of stress in freezing columns developed by elastic waves, equal or less than maximum permissible value. ^ EFFECT: invention prevents rupture and deformations of freezing columns, increased reliability of shaft ice wall. ^ 4 cl, 4 dwg

Description

The invention relates to the mining industry and can be used for sinking shaft shafts in flooded unstable rocks.

A known method of sinking vertical shaft shafts with preliminary freezing of rocks and their subsequent mechanical destruction, mechanized loading of rocks and fixing the trunk with a cast-iron concrete support.

A device for implementing this method consists of a system for freezing rocks with columns, a SK-1 shaft-passing combine, a loading complex of the KS-2u / 40 type [1].

The disadvantages of these technical solutions are the presence in the limited space of the bottom of the barrel of two machines, which increases the time for installation work, as well as the insufficient reliability of the lining due to possible deviations of the position of the tubing from the geometric axis of the barrel. In addition, combine destruction of rocks requires significant economic costs.

There is a method of sinking vertical shaft shafts in flooded unstable rocks, including freezing rocks, drilling and blasting, mechanized loading of rocks, fixing the shaft with cast-iron tubing, followed by plugging of the fixed space [2].

A device for sinking vertical shaft shafts in flooded unstable rocks includes a rock freezing system, a drilling rig, a clamshell loader, a mechanism for erecting cast-iron tubing lining, and a grouting complex [2].

These technical solutions are taken by us as prototypes.

The disadvantage of these technical solutions is the destruction of freezing columns in the contact zone of rocks with different velocities of elastic waves that occur when blasting hole charges.

There is a method of constructing mine shafts in flooded unstable rocks, including freezing a rock mass, creating a waterproofing grouting curtain around an ice-rock massif at the boundary of the concentration of temperature stresses by drilling wells, injecting grouting fluid through them to carry out hydraulic fracturing, and pumping a waterproofing material through the cracks, excavating and barrel mount [3].

This invention improves the reliability of waterproofing, but does not prevent the destruction of freezing columns.

The objective of the invention is to ensure the reliability of the ice-rock enclosure of the barrel by preventing tearing and deformation of freezing columns.

This is achieved by the fact that in the method of sinking vertical shaft shafts in flooded unstable rocks, including freezing rocks, drilling and blasting operations, mechanized loading of rocks, securing the shaft with cast-iron tubing, followed by grouting of the fixed space, during drilling and blasting operations determine the position zone of the bottom hole with the maximum possible by the action of elastic waves on freezing columns relative to the contact boundaries of two rocks with different physical and mechanical properties, according to after that, the destruction of rocks in these zones is carried out in a mode that ensures the value of stresses in freezing columns created by elastic waves equal to or less than the maximum allowable value. In addition, for the destruction of rocks in these areas after drilling and blasting operations, they switch to mechanical destruction of rocks or, for the destruction of rocks with a fortress above the fifth category on the Protodyakonov scale, in these zones drilling and blasting operations are carried out with explosive charges with the maximum permissible mass of simultaneously exploded charges, at which the magnitude of the stresses in the freezing columns created by elastic waves during the explosion of charges has an extremely permissible value.

To solve this problem, a device containing a system for freezing rocks, a drilling rig, a grab loader, a mechanism for erecting cast-iron tubing supports, a grouting complex, is equipped with strain gauges installed in freezing wells at a certain distance relative to the contact boundaries of two rocks with a given step, a measuring unit located on the surface, and a complex for mechanical destruction of rocks, including a screw executive body with a drive and a movement mechanism an actuator made in the form of two concentrically mounted cylinders located in a segment of a rotary ring formed by a supporting beam and an overlap rigidly connected to the ring, the inner cylinder being rigidly connected to the actuator through its drive housing and mounted with axial movement and rotation relative to an external cylinder, rigidly fixed in the overlap, and the cylinders are equipped with position locks, and the rotary ring is located in the groove of the mounting ring with possible awn rotation by a drive sprocket and protrusions which interact with the fingers of the rotary ring.

Figure 1 and figure 2 shows a schematic diagram that implements the proposed method at the stage of drilling and blasting and mechanical destruction of rocks, respectively, and figure 3 and 4 is a complex for mechanical destruction of rocks.

The method of driving a vertical shaft shaft is as follows.

This method of sinking vertical shaft shafts in flooded unstable rocks involves freezing rocks, creating an ice-rock fence in the area of the project shaft. After that, drilling and blasting is carried out by drilling holes to the depth of movement of the face, followed by loading and blasting of explosive charges. Next, mechanized loading of the broken rock is carried out and its transportation to the day surface. In the process of drilling and blasting in the rock mass, elastic waves propagate acting on the freezing columns. At the contact boundary of rocks with various physical and mechanical properties, superposition of reflected waves from the contacting surface of the rock layers occurs on the main elastic wave. When the phases of the main elastic wave and the reflected waves coincide, the amplitude of the shock waves increases significantly, which causes deformation and destruction of the freezing columns, and therefore, destruction of the ice-rock fence. To prevent the destruction of freezing columns from the effects of blast waves, the contact boundaries of two rocks with different physical and mechanical properties are first determined by one of the known methods - seismic exploration or GPR using a transmitter and receiver. The choice of a method for determining the position of the boundary depends on the depth of the boundary between two rocks and the given measurement accuracy. After determining the time of arrival of the reflected signal from the contact of the layers to the bottom of the shaft, calculate the distance to this boundary using the well-known formula:

where L is the distance from the bottom of the shaft to the boundary between two rocks with different physical and mechanical properties;

c is the propagation velocity of elastic waves in the overlying rock layer;

t _s - the transit time of the signal from the emitter to the contact boundary of two rocks with different physical and mechanical properties and vice versa.

After determining the contact boundaries of two rocks with different physical and mechanical properties, strain gauges are installed in freeze wells with a given step at a predicted distance relative to the contact boundary of two rocks. The magnitude of the predicted distance is determined based on data from practice. The step between the load cells is determined depending on the specified measurement accuracy. As the face moves toward the contact boundary of two rocks, deformations (stresses) are measured in freezing columns, which increase. According to the measurements, a calibration graph is constructed for the dependence of the strain on the predicted level to the zone with the maximum possible impact of elastic waves on the freezing columns. It is known that pipes for freezing columns are made of carbon steel with heat treatment that can withstand pressure up to 20 MPa. Upon reaching a stress value in the columns close to 14 MPa, which is the maximum allowable value that does not lead to column destruction, the mode of rock destruction at the bottom is changed. At the same time, the amplitude of the elastic wave is reduced by switching to mechanical destruction of the rock or rock destruction is carried out with a fortress higher than the fifth category on the Protodyakonov scale by explosive charges with the maximum permissible mass of simultaneously exploded charges, at which the stress value in the freezing columns has the maximum permissible value. When switching to a mechanical method of rock destruction, the drilling rig is removed from the hoist and transported to the surface. After that, a complex for mechanical destruction of rocks is installed at the bottom of the trunk, with the help of which a shaft section is passed with the maximum allowable force of elastic waves acting on the freezing columns, followed by transportation of the broken rock to the surface and fixing the shaft. Next, the process is repeated.

A device for implementing a method of sinking vertical shaft shafts consists of a system for freezing rocks, including a freezing station 1 with a brine pipe 2 connected to freezing columns 3 installed in freezing wells 4, a set of equipment for drilling and blasting operations, including a drilling rig 5, for example, type BUKS -1M, suspended from a hoist 6 of a loading machine 7, for example, type 2KS-2u / 40, clamshell loader 8, a mechanism for erecting cast-iron tubing lining 9 of known construction and plugging complex 10 also of known construction, the strain gauges 11 installed in the freeze wells 4, the measuring unit 12, for example, UTI1 located on the surface, as well as for complex mechanical rock destruction. This complex includes a screw actuator 13 with a drive located in the housing 14 and a mechanism for moving the actuator, made in the form of two concentrically mounted cylinders 15, 16 located in the segment of the rotary ring 17 formed by the carrier beam 18 and the overlap 19, rigidly connected to the ring . The inner cylinder 16 is rigidly connected to the actuator 13 through the housing 14 of its drive and is mounted with the possibility of axial movement and rotation relative to the outer cylinder 15, rigidly fixed in the ceiling 19. The cylinders are equipped with position locks 20. In this case, the rotary ring 17 is located in the groove of the mounting ring 21 on rollers (not shown) rotatably by means of a drive 22 and an asterisk 23, the protrusions of which interact with the fingers of the rotary ring. The actuator is moved from the barrel wall to its center by turning the inner cylinder 16 relative to the outer cylinder 15, and the actuator is fed to the bottom by axial movement with fixing the positions of the inner cylinder relative to the outer cylinder by means of latches 20. The mounting ring 21 is rigidly connected to the tubing column 24 and mounted on jacks 25. Moving the mounting ring at each step of the tubing installation is carried out on three ropes of winches mounted on the surface ( not shown).

The method of sinking vertical shaft shafts in flooded unstable rocks and a device for its implementation are implemented in relation to the conditions of the Gremyachenskoye field during the construction of a shaft shaft with a diameter of 7.0 m and a depth of 1181.0 m. The reservoir under development is under a thickness of sedimentary unstable rocks with a thickness of about 600 meters, containing several aquifers with hydrostatic pressure up to 5.5 MPa, rock sections are represented by deposits of chalk, sand, clay clay, limestone and granite. The main factor determining the need to use the freezing method under these conditions is the presence in the section of heterogeneous water-saturated unstable sands with a total thickness of more than 150 m, distributed to a depth of 511.5 m, heaving clays, high-pressure groundwater, the pressure of which exceeds 500 m, and high power aquifers of more than 400 m. To create an ice-rock fence 6.2 m thick, 33 freezing wells are drilled along a concentric circle with a diameter of 14.5 m. Freezes Low temperature (brine temperature -35 ° С) for 180 days is provided. The total cooling capacity of the freezing station 1 is 26.5 MJ. The freezing columns 3 consist of a stand of TZK-2 brand sleeveless pipes, the outer diameter of which is 146 mm, and the wall thickness is 11 mm. After creating an ice-rock fence of design thickness, they start digging the barrel with a blasting method. It is planned to drill holes with a BUKS-1m 5 drilling rig with a depth of 1.5 m, a mass of simultaneously exploded charge of 4.2 kg, explosives - ammonite No. 6 ZhV, the distance between the contouring boreholes of the face and freezing columns is 2 m. After blasting, the broken rock with using a grab loader 8 and buckets are transported to the surface. To prevent deformation and destruction of freezing columns from the action of elastic waves arising during the explosion of explosive charges, the contact boundary between sands and clays relative to geological exploration data is refined by georadiolocation. According to the data obtained, the contact boundary of sand and clay is in the depth interval 151.9-152.1 m. Based on practical data, the zones of possible column destruction are in the range from 0.5-2.0 m from the boundary of contact of rocks [4.] For frozen sand and clay the propagation velocities of elastic waves are equal to C ₁ = 5300 m / s and C ₂ = 3200 m / s, and the density ρ ₁ = 2600 kg / m ³ , ρ ₂ = 2000 kg / m ^3, respectively. In this case, the reflection coefficient from the boundary of these media will be:

With this value of the coefficient k, a significant part of the energy will be reflected and added to the energy of the direct wave, which can cause the destruction of the columns. In this regard, it is necessary to determine the position of the face at which deformations (stresses) in the freezing columns reach the maximum permissible value. The stresses in the columns are estimated using strain gauges 11 located in the freezing wells 4 within 2.5 m above and below the contact boundary of the two media. The step of installing the strain gauges is selected from the condition that the measurement accuracy should be 5-10 times higher than one step of advancing the face, equal to 1.5 m. In this case, the step is chosen equal to 25 cm. To assess the degree of influence of the blast wave on the tightness of freezing columns the deformations of the columns are measured using strain gauges 11 and a measuring unit 12, followed by calculation of the stresses in the freezing columns 3. According to the measurement results, it was found that when the bottom reaches a distance of 2.5 m from the layer contact boundary to 1 m, the voltage in freezing columns increases to the maximum permissible value of 14 MPa. Upon reaching the maximum permissible stress values in the columns, the mode of rock destruction at the bottom is changed, in which the magnitude of the effect of elastic waves is reduced by switching to mechanical destruction of the rocks. With rock strength above the fifth category on the Protodyakonov scale in these zones, drilling and blasting operations are carried out with explosive charges with the maximum permissible mass of simultaneously exploded charges. The value of this mass is determined by calculation. The mechanical destruction of the face rock with a trunk diameter of 7 m is carried out by means of a screw actuator 13 with four annular gates with a width of 900 mm by turning the inner cylinder 16 with a screw rotor 13 and two passes of 750 mm each by axial movement. The destroyed rock using a grab 8 is immersed in a tub 26 and raised to the surface. After cleaning the face, the mounting ring 21 is lowered to the face using three winches located on the surface and installed on the face using jacks 25. Then, the next tubing ring is installed on the upper flange of the mounting ring using the mechanism 9 for erecting cast-iron tubing lining and connect it to tubing column 24, combining the bolt holes with mandrels and mounting bolts with their subsequent sbalkivaniya. Through each second tubing ring, subsequent cementing of the anchoring space is carried out by means of the grouting complex 10. To ensure waterproofing of the column, the joints between the tubing are rounded with lead wire. Next, the cycle is repeated. For specific mining and geological conditions, the length of the zone of the bottomhole position with the maximum possible force of elastic waves acting on the freezing columns was 14.2 m, which were accidentally covered in 5 days. The strength of the underlying rocks is f <5 on the Protodyakonov scale, which allowed for further penetration of the trunk by means of the proposed rock destruction complex.

The proposed method of sinking vertical shaft shafts in flooded unstable rocks and a device for its implementation made it possible to ensure failure-free operation of the ice-rock fence during the entire freezing period - 180 days, as well as to achieve a stable shaft sinking speed of at least 45 m / month. As a result, the construction time of the trunk was reduced by more than 40% and the material costs for its construction were reduced by at least 1.5 times.

Information sources

1. The book "Trust" Shakhtspetsstroy "60 years of activity and the development of special ways of sinking shaft shafts." Moscow, 2003, printed in JT Print, p. 121.

2. Book of Rudakov V. M. "The construction of vertical and inclined workings in exploration." Moscow, KDU Publishing House 2009, p.86 (prototype).

3. RF patent No. 2095574, cl. E21D 1/12 of 10/02/1990 "Method for the construction of shaft shafts in flooded unstable rocks"

4. Trupak N.G. “Freezing rocks during the construction of vertical shaft shafts”, Moscow, Nedra, 1983, p.126.

Claims (4)

1. The method of sinking vertical shaft shafts in flooded unstable rocks, including freezing rocks, drilling and blasting, mechanized loading of rocks, securing the shaft with cast-iron tubing with subsequent grouting of the confined space, characterized in that during drilling and blasting operations determine the position zone of the bottom with the maximum possible by the action of elastic waves on freezing columns relative to the contact boundaries of two rocks with different physical and mechanical properties, after what is the destruction of rocks in these zones in the mode, providing the magnitude of the stresses in the freezing columns created by elastic waves equal to or less than the maximum allowable value. 2. The method according to claim 1, characterized in that for the destruction of rocks in these zones after drilling and blasting operations, they switch to mechanical destruction of rocks. 3. The method according to claim 1, characterized in that for the destruction of rocks with a fortress above the fifth category on the Protodyakonov scale in these zones, drilling and blasting operations are carried out with explosive charges with the maximum permissible mass of simultaneously exploded charges, at which the magnitude of the stresses in the freezing columns created elastic waves in the explosion of charges, has the maximum permissible value. 4. A device for sinking vertical shaft shafts in flooded unstable rocks, containing a system for freezing rocks, a drilling rig, a clamshell loader, a mechanism for erecting cast-iron tubing lining, a grouting complex, characterized in that it is equipped with strain gauges installed in the freezing wells at a certain distance relative to the boundaries of the contact of two rocks with a given step, a measuring unit located on the surface, and a complex for mechanical destruction of rocks, incl. a screw auger actuator with a drive and an actuator moving mechanism made in the form of two concentrically mounted cylinders located in a segment of a rotary ring formed by a carrier beam and an overlap rigidly connected to the ring, while the inner cylinder is rigidly connected to the actuator through its drive housing and installed with the possibility of axial movement and rotation relative to the external cylinder, rigidly fixed in the ceiling, and the cylinders are equipped with latches floor zheniya, a rotary ring disposed in the groove of the mounting ring rotatably supported by a drive sprocket and protrusions which interact with the fingers of the rotary ring.

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