RU2777631C1 - Monolithic reinforced concrete lining of an inclined mine working - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to mining, namely the construction of inclined mine workings under conditions of high rock pressure. Monolithic reinforced concrete support of an inclined mine working, consisting of a concrete body and a frame including: reinforcing bars along the inclined working, reinforcing bars across the base of the inclined working, reinforcing bars perpendicular to the base of the inclined working, and steel reinforcement along the arch of the arch, as well as reinforced transverse brackets, with a step corresponding to the calculated reinforcement step, made in an elliptical cross section. The long axis of the reinforcement ellipse is aligned with the maximum loads on the frame of the reinforced concrete lining of the inclined working. For reinforcing bars along an inclined mine working, the maximum moment of resistance along the long axis of the ellipse is aligned with the perpendicular to the side surface, the base, and also with the radius of the circle segment of the roof of the inclined mine working, according to their location. For reinforcing bars across the base and perpendicular to the base of the inclined mine working, the maximum moment of resistance along the long axis of the reinforcement ellipse is aligned with the perpendicular to the base and to the side surface of the inclined mine working, respectively. For steel reinforcement installed along the arch of the arch in the form of a segment of the circle of an inclined mine working, the maximum moment of resistance along the long axis of the reinforcement ellipse is combined with the radius of the segment of the circle of the frame. For reinforcing bars along an inclined working, installed at the corners of the base and the side surface, the maximum moment of resistance along the long axis of the reinforcement ellipse is aligned with the diagonal between the corresponding perpendiculars to these surfaces. For reinforced transverse brackets installed on reinforcing bars in the frame: across the base of the inclined working, perpendicular to the base of the inclined working, and steel reinforcement along the arc of the roof of the inclined working, the maximum moment of resistance along the long axis of the reinforcement ellipse is set parallel to the line of the angle of the mine working. For reinforced transverse brackets mounted on reinforcing bars along an inclined working, the maximum modulus of resistance along the long axis of the reinforcement ellipse is set parallel to the trace of the plane drawn through this bracket, on the side surface, the base of the inclined working, as well as the tangent at the point of exit of the radius to the reinforcement arc, according to their location.

EFFECT: increasing the reliability of monolithic reinforced concrete lining of inclined mine workings.

1 cl, 6 dwg, 1 tbl

Description

Technical field

The invention relates to mining, namely the construction of inclined mine workings under conditions of high rock pressure.

State of the art

A device is known to be a monolithic reinforced concrete lining of a vertical round mine shaft (patent RU 2765447, IPC E21D 5/00, published on January 31, 2022 Bull. No. 4), including a concrete body, a vertical rod working, a horizontal longitudinal rod working steel reinforcement and reinforcing transverse brackets with a step , corresponding to the design step of reinforcement, in the form of a frame, and the vertical rod working, horizontal longitudinal rod working steel reinforcement and reinforcing transverse brackets of the frame of the support of the round mine shaft are made with an ellipsoidal cross-section, the long axis of the reinforcement ellipse is aligned with the maximum loads on the reinforced concrete lining of the round mine shaft , for vertical and horizontal reinforcement, the maximum moment of resistance along the long axis of the ellipse is aligned with the direction of the radius of the round shaft, for reinforcing transverse brackets, the maximum moment of resistance along the long axis of the ellipse is set parallel to the vertical axis of the cr angled trunk.

A disadvantage of the known device is the inability to use it for a monolithic reinforced concrete lining of an inclined mine working.

Closest to the claimed technical solution is the device of a monolithic reinforced concrete lining of an inclined mine working, (Mining engineering graphics. M., Nedra, G.G. Lomonosov, A.I. Arsentiev, et al. 1976, 263 p., p. 91 ), consisting of a concrete body and a frame including: reinforcing bars along the inclined working, reinforcing bars across the base of the inclined working, reinforcing bars perpendicular to the base of the inclined working, and steel reinforcement along the arc of the arch, reinforced transverse brackets, with a step corresponding to the calculated reinforcement step.

The disadvantage of the closest device is the low reliability of the monolithic reinforced concrete lining of the inclined mine workings.

Disclosure of invention

The technical result is to increase the reliability of a monolithic reinforced concrete lining of an inclined mine working.

The specified technical result is achieved in the device monolithic reinforced concrete lining of an inclined mine working, consisting of a concrete body and a frame including: reinforcing bars along the inclined working, reinforcing bars across the base of the inclined working, reinforcing bars perpendicular to the base of the inclined working, and steel reinforcement along the arc of the arch, as well as reinforced transverse brackets, with a step corresponding to the calculated reinforcement step, moreover, reinforcing bars along the inclined working, reinforcing bars across the base of the inclined working, reinforcing bars perpendicular to the base of the inclined working, and steel reinforcement along the arc of the roof of the inclined working, the reinforced transverse brackets are made transverse elliptical cross-section, the long axis of the reinforcement ellipse is aligned with the maximum loads on the frame of the reinforced concrete lining of the inclined working, for reinforcing bars along the inclined working, the maximum moment of resistance along the long axis of the ellipse is aligned with the perpendicular to: the side surface, the base, as well as the radius of the circle segment of the roof of the inclined mine working, according to their location, for reinforcing bars across the base and perpendicular to the base of the inclined working, the maximum moment of resistance along the long axis of the reinforcement ellipse is aligned with the perpendicular to the base and to the side surface of the inclined mine working, respectively, for steel reinforcement installed along the arc of the arch in the form of a segment of the circle of the inclined mine working, the maximum moment of resistance along the long axis of the reinforcement ellipse is aligned with the radius of the frame circle segment, for reinforcing bars along the inclined working, installed at the corners of the base and side surface, the maximum moment of resistance along the long axis of the reinforcement ellipse, is aligned with the diagonal between the corresponding perpendiculars to these surfaces, for reinforced transverse brackets installed on reinforcing bars in the frame: across the base i of an inclined working, perpendicular to the base of the inclined working, and steel reinforcement along the arc of the roof of the inclined working, the maximum moment of resistance along the long axis of the reinforcement ellipse is set parallel to the line of the slope of the working working, for reinforced transverse brackets installed on reinforcing bars along the inclined working, the maximum moment resistance along the long axis of the reinforcement ellipse is installed parallel to the trace of the plane drawn through this bracket, on: the side surface, the base of the inclined working, and also the tangent at the point of exit of the radius to the reinforcement arc, according to their location.

The distinguishing features are:

reinforcing bars along the inclined working, reinforcing bars across the base of the inclined working, reinforcing bars perpendicular to the base of the inclined working and steel reinforcement along the arc of the roof of the inclined working;

the long axis of the reinforcement ellipse is aligned with the maximum loads on the frame of the reinforced concrete lining of the inclined working, this increases the reliability of the monolithic reinforced concrete lining;

for reinforcing bars along the inclined working, the maximum moment of resistance along the long axis of the ellipse is aligned with the perpendicular to: the side surface, the base and the radius of the segment of the circumference of the roof of the inclined mine working, according to their location, which increases the reliability of the support along the inclined working with less consumption of materials;

for reinforcing bars across the base and perpendicular to the base of the inclined excavation, the maximum moment of resistance along the long axis of the reinforcement ellipse is aligned with the perpendicular to the base and to the side surface of the inclined excavation, respectively, which increases the reliability of the support across the inclined excavation with less consumption of materials;

for steel reinforcement installed along the arch of the arch in the form of a segment of the circle of an inclined mine working, the maximum moment of resistance along the long axis of the reinforcement ellipse is aligned with the radius of the segment of the circle of the frame, this increases the reliability of the monolithic reinforced concrete lining on the arch;

for reinforcing bars along an inclined working, installed at the corners of the base and side surface, the maximum moment of resistance along the long axis of the reinforcement ellipse is aligned with the diagonal between the corresponding perpendiculars to these surfaces, which increases the reliability of the monolithic reinforced concrete lining at the corners of the base and side surface;

for reinforced transverse brackets mounted on reinforcing bars in the frame: across the base of the inclined working, perpendicular to the base of the inclined working, and steel reinforcement along the arc of the roof of the inclined working, the maximum moment of resistance along the long axis of the reinforcement ellipse is set parallel to the line of the slope of the mine working, such a direction increases the rigidity of the transverse elements of the frame and lining as a whole;

for reinforced transverse brackets installed on reinforcing bars along an inclined working, the maximum moment of resistance along the long axis of the reinforcement ellipse is set parallel to the trace of the plane drawn through this bracket, on: the side surface, the base of the inclined working, and also the tangent at the point of exit of the radius to the reinforcement arc , according to their location, this direction increases the rigidity of the longitudinal elements of the frame.

The principle of reinforcement reliability is to change the geometric shape of the reinforcement with the same area and with the same material in order to increase the moment of resistance in a certain direction, which means an increase in the reliability of the structure. The moment of resistance along the axis of maximum load, an ellipse with a ratio of the larger axis to the smaller one of 1.28 and with an area equal to the cross-sectional area of a circle of 14 mm, increased by 1.133 times, i.e. by +13.3%, see table. The moment of resistance along the minimum load axis, under similar conditions, decreased to 0.88 times or -12%. The total moments of resistance along both axes increased by 1.008 times, i.e. by +0.8%.

Comparison of the proposed solution with analogue and prototype did not reveal in them the signs of the proposed solution, this allowed us to conclude that the criterion of "novelty" was met.

Brief description of the table and figures

In table. the relationship between the ratio of the values of the axes of the ellipse and the circle with the moments of resistance along the corresponding axes of the ellipse and the circle is presented according to [3].

In FIG. 1 shows a dimetric view of an inclined ascending mine working with a monolithic reinforced concrete lining, including: 1 - a rough section of the mine working; 2 - reinforcing bar of the outer row of the frame along the inclined working; 3 - reinforcing bar of the inner row of the frame along the inclined working; 4 - reinforcing bar, perpendicular to the base of the development of the outer row of the frame; 5 - reinforcing bar, perpendicular to the base of the development of the inner row of the frame; 6 - reinforcing bar across the base of the inclined working of the outer row of the frame; 7 - reinforcing bar across the base of the inclined working of the inner row of the frame; 8 - support base; 9 - side surface of the lining; 10 - set development; 11 - steel reinforcement along the segment of the circumference of the inner row of the frame; 12 - steel reinforcement along the segment of the circumference of the outer row of the frame; 13 - reinforcing bracket connecting the rows of the frame; 14 - outer radius of the arch of the support; 15 - inner radius of the arch of the support; 16 - anchor fixed; 17 - welded joint; 18 - hole; 19 - section of a mine working in the light; 20 - concrete body; 21 - the angle of inclination of the mine working.

In FIG. 2 shows section A-A from FIG. 1 reinforcing bar perpendicular to the base of the excavation of the outer row of the frame, including: 4 - reinforcing bar perpendicular to the base of the excavation of the outer row of the frame; 22 - a line perpendicular to the side surface of the inclined workings.

In FIG. 3 shows a section B-B from figure 1 of a reinforcing bar across the base of the inclined working of the outer row of the frame, including: 6 - reinforcing bar across the base of the inclined working of the outer row of the frame; 23 - a line perpendicular to the base of the inclined mine working.

In FIG. 4 is a section B-B of FIG. 1 reinforcement bracket connecting the frame rows, including: 13 - reinforcement bracket connecting the frame rows; 25 - a line parallel to the line of the angle of inclination of the mine working.

In FIG. 5 shows a G-D section from FIG. 1 steel reinforcement rolled along a segment of the circumference of the outer row of the frame, installed on the arch of the support of an inclined mine working, including: 12 - steel reinforcement along the segment of the circle of the outer row of the frame 24 - a line aligned with the radius of the arch of the support.

In FIG. 6 shows a section D-D from FIG. 1 reinforcing bar along the inclined working of the outer row of the frame, installed in the corner of the base and side surface, including: 2 - reinforcing bar of the outer row of the frame along the inclined working; 26 - diagonal between perpendiculars to the base and side surface.

Implementation of the invention

The process of erecting lining from monolithic reinforced concrete includes laying out lines in the clear 19 of a mine working with an angle of inclination of 21, in the section of a mine working in draft 1, assembly and installation of reinforcement in a frame, formwork and concreting. In the frame, reinforcing bars along the inclined working 2 and 3, reinforcing bars across the base of the inclined working 6 and 7, reinforcing bars perpendicular to the base of the inclined working 4 and 5, as well as steel reinforcement along the arc of the roof of the inclined working 11 and 12, reinforced transverse brackets 13 they are made with an elliptical cross-section, the major axis of the ellipse of this reinforcement is combined with the maximum loads on the reinforced concrete lining of the working.

The preparation of brackets 13 from steel reinforcement is carried out by bending corners by 90 ^° around the major axis of the reinforcement ellipse, with their preliminary heating in a mining blacksmith or a gas burner, with the location of the major axis of the ellipse in the plane of the bracket 13. Preparation of steel reinforcement along the arch of the arch and, in particular, along segment of the circumference of the outer row of the frame 12 and the inner row 11 is performed by rolling on the reinforcement rolls with the outer radius of the arch of the support 14 and the inner radius of the arch of the support 15, with the larger axis of the reinforcement ellipse located along the radii of the arch of the excavation 10. The installation of the reinforcement cage is performed at the location, pre-drilled boreholes 18 along the entire transverse perimeter of the mine working: the side surfaces of the working 9, the arch of the working 10 and install anchors 16 in them, which are the basis for fastening the corresponding reinforcing bars and aligning the major axis of the ellipse of this reinforcement with the maximum loads on the lining and fixing them in this position on anchors 16 on welded with connection 17 for the entire length of the reinforcing bars. The distance between the anchors along the length of the reinforcing bar is taken from the calculation of the linearity of the frame bars. Initially, reinforcing bars of the outer row of the frame 2 are mounted on the anchors 16 along the inclined working at the intersection of the base 8 and the side surface of the working 9, setting the major axis of the reinforcement ellipse diagonally 26 between the corresponding perpendiculars of these surfaces. For the rest of the reinforcing bars of the outer row of the frame 2 along the inclined working, the major axis of the reinforcement ellipse is combined with the corresponding perpendiculars of the surfaces and the radii of the arch of the support, and they are also fixed on the welded joint 17. The reinforcing bars along the inclined working 2 are installed with each other with a step corresponding to the calculated reinforcement step . Then, on the anchors 16, reinforcing bars are also installed perpendicular to the base of the excavation of the outer row of the frame 4, connecting them with steel reinforcement along the arc of the arch and, in particular, along the segment of the circumference of the outer row of the frame 12. Spatial positioning of the larger axis of the ellipse of this reinforcing bar 12 is performed along line 24 combined with the radius of the excavation arch 10. Reinforcing bars perpendicular to the base of the excavation of the outer row of the frame 4 are also installed among themselves with a step corresponding to the calculated reinforcement step and the major axis of the ellipse of this reinforcement is also aligned with the corresponding perpendiculars 22 of the side surface. Similarly, reinforcing bars of the inner row of the frame are mounted along the inclined working 3, reinforcing bars perpendicular to the base of the working of the inner row of the frame 5 and steel reinforcement along the arch of the arch and, in particular, along the segment of the circumference of the inner row of the frame 11. Reinforced transverse brackets 13 connecting the rows of the frame, set with a step corresponding to the calculated reinforcement step. For reinforced transverse brackets 13 installed on reinforcing bars along inclined workings 2 and 3, the maximum moment of resistance along the long axis of the reinforcement ellipse is set parallel to the trace of the plane drawn through this bracket on the side surface of the inclined working, as well as the tangent at the exit point of radius 14 or 15 per reinforcement arc. For reinforced transverse brackets 13 installed in the frame on reinforcing bars 4 and 5 perpendicular to the base of the inclined working and steel reinforcement along the arch of the roof 11 and 12 of the inclined working, the maximum moment of resistance along the long axis of the reinforcement ellipse is set parallel to the line 25 of the angle of the mine working 21. At the next stage, the frame is mounted on the soil of the working at the base of the support 8, the holes 18 are pre-drilled, the anchors 16 are installed. On their basis, the reinforcing bars of the base are mounted across the inclined working of the outer row of the frame 6. These bars 6 are installed between each other with a step corresponding to the calculated reinforcement step and the major axis of the ellipse of such reinforcement is aligned with the perpendicular 23 to the base of the working. For reinforcing bars 2, mounted along the base of the inclined mine working, the maximum moment of resistance along the long axis of the ellipse is combined with the perpendicular 23 to the base of the inclined mine working. Similarly, on the basis of anchors 16, reinforcing bars of the base are mounted across the inclined working of the inner row of the frame 7, which are also installed among themselves with a step corresponding to the calculated reinforcement step and the major axis of the ellipse of this reinforcement is also aligned with the perpendicular 23 to the base of the working and, similarly, the reinforced transverse brackets 13. For reinforced transverse brackets 13 installed in the frame on reinforcing bars across the base of the inclined workings 6 and 7, the maximum moment of resistance along the long axis of the reinforcement ellipse is set parallel to the line 25 of the angle of inclination of the mine working 21.

For a concrete body 20 between the section lines of the excavation in draft 1: and the light 19, a vertical inclined formwork is installed in the form of a horizontal segment in an inclined excavation and a concrete body 20 is simultaneously created, including the base 8, the side surface of the support 16 and the roof of the support 15, using vibration compaction of concrete. For such a design, a sliding segmental horizontal formwork is developed in an inclined working of simultaneous concreting along the entire transverse perimeter of the working by the value of the concreting step in height.

Thus, increasing the reliability of a monolithic reinforced concrete lining of an inclined mine working is achieved by changing the geometric shape of the reinforcement, with the same area and with the same material, redistributing the moment of resistance along the reinforcement axes in a given direction of the load on the lining.

Sources of information

1. Patent RU 2765447, IPC E21D 5/00, published 01/31/2022 Bull. No. 4;

2. Mining and engineering graphics. M., Nedra, G.G. Lomonosov, A.I. Arsentiev, I.A. Gudkova et al. 1976, 263 pp., p. 91;

3. Handbook on the strength of materials / Pisarenko G.S., Yakovlev A.P., Matveev V.V.; resp. ed. Pisarenko G.S. - 2nd ed., revised. and additional - Kyiv: Nauk. Dumka, 1988. - 736 p. (58, 74 pp.).

Tab.

Monolithic reinforced concrete lining of an inclined mine working

Name of indicator A circle,
diameter 14 mm Ellipse 1. Axle length, mm 14×14 15.8599 × 12.3584 2. The ratio of the values of the axes i=1.0 i=1.283 3. Cross-sectional area, cm ² 1.5386 1.5386 4. Moment of resistance along the max axis, cm ³ 0.26926 0.305035 5. Moment of resistance along the min axis, cm ³ 0.26926 0.237686 6. Total moment of resistance, cm ³ 0.53852 0.542716

Claims (1)

Monolithic reinforced concrete support of an inclined mine working, consisting of a concrete body and a frame, including: reinforcing bars along the inclined working, reinforcing bars across the base of the inclined working, reinforcing bars perpendicular to the base of the inclined working, and steel reinforcement along the arc of the arch, as well as reinforced transverse brackets , with a step corresponding to the calculated step of reinforcement, characterized in that the reinforcing bars along the inclined working, the reinforcing bars across the base of the inclined working, the reinforcing bars perpendicular to the base of the inclined working, and the steel reinforcement along the arc of the roof of the inclined working, the reinforced transverse brackets are made in the transverse section of an elliptical shape, the long axis of the reinforcement ellipse is aligned with the maximum loads on the frame of the reinforced concrete lining of the inclined working, for reinforcing bars along the inclined working, the maximum moment of resistance along the long axis of the ellipse is aligned with the perpendicular to: lateral surface, base, as well as with the radius of the circle segment of the roof of the inclined mine working, according to their location, for reinforcing bars across the base and perpendicular to the base of the inclined mine working, the maximum moment of resistance along the long axis of the reinforcement ellipse is aligned with the perpendicular to the base and to the side surface of the inclined mine working, accordingly, for steel reinforcement installed along the arch of the arch in the form of a segment of the circle of an inclined mine working, the maximum moment of resistance along the long axis of the reinforcement ellipse is combined with the radius of the segment of the frame circle, for reinforcing bars along the inclined working, installed at the corners of the base and side surface, the maximum moment resistance along the long axis of the reinforcement ellipse is aligned with the diagonal between the corresponding perpendiculars on these surfaces, for reinforced transverse brackets mounted on reinforcing bars in the frame: across the base of the inclined working, perpendicular to the base of the inclined working, and steel reinforcement along the arc of the roof of the inclined working, the maximum moment of resistance along the long axis of the reinforcement ellipse is set parallel to the line of the angle of the mine working, for reinforced transverse brackets installed on reinforcing bars along the inclined working, the maximum moment of resistance along the long axis of the ellipse reinforcement is installed parallel to the trace of the plane drawn through this bracket, on: the side surface, the base of the inclined working, as well as the tangent at the point of exit of the radius to the reinforcement arc, according to their location.

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