RU2703027C1 - Method for construction of underground working and shield tunneling unit for its implementation - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to mechanized performance of underground openings with round cross-section shape, in particular, to method of construction of underground development with shielding tunnelling unit. Proposed method consists in that shaping of the working, screwing in the head section of the unit and tightening the tail section simultaneously. When forming the working, the helical channel is cut with the cutting tool of the unit, providing a guaranteed gap between the external propulsor and the side walls of the screw channel. When cutting the longitudinal channel, a guaranteed gap is provided between the anti-rotation elements and the side walls of the longitudinal channel. Formation of curvilinear section is started with bending of head section in appropriate direction, then working is formed in specified direction; as tail section is pulled in curvilinear section, it is bent along working section, after outlet of unit from curvilinear section head and tail sections are moved to initial position. Passage assembly comprises head and tail cylindrical sections made of several turns of sheet profile. Adjacent coils of sheet profile are interfaced by means of bead and slot and provide possibility of mutual angular and axial movement. In the head section the groove is made along the normal to the longitudinal axis of the section, it is outward oriented and represents a screw blade acting as an external propulsor. In the tail section, the groove is made normal along the section. Adjacent coils of the sheet profile are connected by jacks for controlling the direction of movement of the unit. Head and tail sections are connected by means of intermediate cylindrical section, on inner surface of which there fixed is fixed gear wheel; in engagement with it there is drive sprocket, axis and drive of which are located in inner space of tail section. Cutting device of the unit is fixed on the frame structure of the head section and is made in the form of large and small chain bars with cutters installed perpendicularly relative to the longitudinal axis of the unit.

EFFECT: technical result consists in improvement of efficiency of construction of underground workings due to bending of head and tail parts of unit and provision of possibility of curvilinear sections performance.

2 cl, 9 dwg

Description

The present invention relates to mining and the construction of underground structures and is associated with the formation of a directed artificial cavity in the bowels of the Earth, providing access to an underground object, which may be a metro station, a section of a mineral deposit, a source of technological disaster, etc. In particular, the invention relates to the mechanized conduct of underground workings with a circular cross-sectional shape.

A known method of conducting underground mining by a shield driving unit, in which the formation of the excavation is carried out by destruction of the rock mass by the cutting unit of the unit, consisting of the head and tail sections, when the head section rotates in one direction. At the same time, helical channels are cut in the surrounding rock mass with the placement of external aggregate propulsors, which ensures the translational movement of the head section of the aggregate in the formed mine. The tail section of the unit is pulled after the head and longitudinal channels are cut in the surrounding rock mass with placement of counter-rotation elements in them, preventing the rotation of the tail section [Eller, A.F. Screw rotary driving units / A.F. Eller, V.F. Gorbunov, V.V. Aksenov. - Novosibirsk: VO Nauka. Siberian Publishing Firm, 1992. - 192 p.] (Analogue of the method).

In this way, it is possible to conduct workings of various purposes and directions (horizontal, vertical, inclined), but only rectilinear, it does not allow curvilinear workings, in particular, to go around insurmountable obstacles or dangerous manifestations of the geomedium, which limits the scope of its use to only straight workings carried out on rocks with known physical properties in advance.

A well-known tunneling unit for conducting underground mining of circular cross-section, containing a screw, end and cutting sections, an executive body, a rotation mechanism, a pump station and a block of distributors [Eller, A.F. Screw rotary driving units / A.F. Eller, V.F. Gorbunov, V.V. Aksenov. - Novosibirsk: VO Nauka. Siberian Publishing Firm, 1992. - 192 p.] (Analogue of the unit). A drawback to the design of the unit is the rigid coaxial orientation of the components of the unit, in particular, the screw and end sections, because of which it does not allow curvilinear in terms of production, limiting the scope of the unit only to straight workings.

As a prototype, a method has been adopted for conducting underground mining by a driving unit, including the destruction of the rock mass by rotating the head section of the aggregate with a cutting actuator, cutting in the rock mass behind the contour of the development of helical channels, the placement of external movers in them, ensuring the translational movement of the aggregate, the formation of the same array of longitudinal channels and the placement in them of the anti-rotation elements of the tail section of the unit, holding it from rotation, pulling the tail projection unit after the parent, loading studded rock the vehicle and mount goaf [Pat. 2552539, IPC E21D 9/06. Geohod (Tunnel shield unit); application 2013153850, filed December 4, 2013, patent holder of the Kemerovo Experimental Mechanical Repair Plant “KORMZ”, publ. 06/10/2015, bull. No. 16].

The disadvantage of this method is the inability to conduct curvilinear workings, in particular, to go around insurmountable obstacles or dangerous manifestations of the geomedium.

For the prototype of the unit, a tunneling shield unit is adopted, containing sequentially installed head and tail cylindrical sections interconnected to rotate the head section around its longitudinal axis. The cutting body in the form of two drums is rigidly fixed to the head section by means of a frame structure; on the outer side of the head cylindrical section, an external mover is mounted, made in the form of short sectors of a spiral surface, and having destructive organs of the mover installed in front of them; inside the head section on sliding bearings, a rotor-type loading organ with loading blades is installed, the drive of which is mounted on the inner surface of the tail section; longitudinal counter-rotation elements are fixed on the outer cylindrical surface of the tail section, before which destructive organs of counter-rotation elements are installed; the head and tail sections are interconnected by means of a shoulder on the edge of the head section and a recess on the bottomhole edge of the tail section [Pat. 2552539, IPC E21D 9/06. Geohod (Tunnel shield unit); application 2013153850, filed December 4, 2013, patent holder of the Kemerovo Experimental Mechanical Repair Plant “KORMZ”, publ. 06/10/2015, bull. No. 16].

The disadvantage of the prototype is the lack of a device that provides a change in the direction of movement of the unit.

These shortcomings reduce the effectiveness of the construction of underground workings, especially special workings with a curved path.

The purpose of the invention is to increase the efficiency of the construction of underground workings for various purposes by ensuring the relative flexibility of the components of the unit and, as a result, the possibility of curved sections of the work when enveloping insurmountable obstacles and / or adverse manifestations of the geological environment.

This goal is achieved by the fact that in the method of constructing an underground mine, including the formation of an oriented cavity in the bowels of the Earth with a shield driving unit, consisting of a head and tail sections arranged sequentially and coaxially, in a direct course when the head section rotates in one direction, cutting screw and longitudinal channels in the near-edge zone of development in the array of surrounding rocks, with the placement of external propulsors and elements of counter-rotation of the unit, respectively, screwing in the head with of the section and tightening the tail and maintaining the worked out space by erecting the lining, in accordance with the technical solution, the formation of the working out, screwing in the head section of the unit and pulling up the tail section are carried out simultaneously, the screw channel is cut by the cutting unit of the unit, while cutting the screw and longitudinal channels, they provide a guaranteed gap between the external mover and the side walls of the helical channel and between the counter-rotation elements and the side walls of the longitudinal channel, when forming volineynogo portion generating head section is compressed and bent in the corresponding direction, is then formed in the specified direction generation; as the tail section is pulled in the curved section of the mine, it is bent along the profile of the mine, and the deviation of the longitudinal axis of the formed part of the mine from the axis of the formed part of the mine is provided depending on the geometrical dimensions and the relative position of the head and tail sections, movers and anti-rotation elements of the unit and the clearances in the mates the listed parts of the unit in the excavation, helical and longitudinal channels, respectively, and after the unit leaves the curved section the starting position of the head and the tail section.

This goal is also achieved by the fact that in the shield tunneling unit containing sequentially and coaxially located head and tail cylindrical sections connected to each other with the possibility of rotation of the head section around its longitudinal axis; a cutting body fixed to the head section by means of a frame structure; external mover made in the form of protruding blades; loading organ installed inside the head section, longitudinal counter-rotation elements with destructive counter-rotation elements located in front of them mounted on the outer surface of the tail section, in accordance with the technical solution, the cutting body is made in the form of large and small (one, two or more) radially directed chain bars with cutters installed in the plane perpendicular to the longitudinal axis of the unit with the possibility of movement along the frame structure in the radial direction, and the departure the boom of the small bar corresponds to the contour of the cylindrical surface of the head section, the boom of the big bar goes beyond the specified contour by an amount corresponding to the height of the blades of the external mover; the head and tail sections are made of several turns of the sheet profile in the form of a single start spiral, adjacent turns of which are interconnected by a groove and a shoulder, the groove width being greater than the thickness of the shoulder, and the groove itself is made in the inner space of the propeller blade of the head section and in the inner space of the tail section, moreover, the turns of the sheet profile are associated with the possibility of mutual movement both in the angle and along the longitudinal axis of the section; the external mover is made in the form of a helical blade along the entire length of the interface line of the coils; on the inner surface of the head section, normal to the spiral lift line, jacks are installed to control the direction of movement of the unit, evenly distributed along the entire length of the interface line of the coils and connecting adjacent coils; the edge of the head section from the side of the tail section is made with an end face normally oriented to the longitudinal axis, is rigidly connected to the intermediate section, a gear wheel is rigidly fixed on its inner surface, a drive sprocket is in internal engagement with it, the axis and drive of which are rigidly fixed on the inner surface of the tail sections.

The invention is illustrated by diagrams. In FIG. 1 shows a General view of the tunneling shield unit (side view); in FIG. 2 - the same (plan view); in FIG. 3 - the same (front view); in FIG. 4 driving unit (longitudinal section); in FIG. 5 is a view A in FIG. four; in Fig.6 - sinking aggregate in the rock mass during the straightforward development; in FIG. 7 is a section BB in FIG. 6. explaining the presence of a gap: FIG. 8 - change of direction of movement of the head section of the unit; in FIG. 9 - sinking aggregate in the rock mass during the curvilinear development section.

The shield driving unit contains a cutting body 1, a head 2, an intermediate 3 and a tail 4 sections and a loading organ (not shown), as well as a control system (not shown).

The head section 2 is made in the form of a cylindrical shell 5 and contains engagement elements 6 and 7, the frame 8, brackets 9 and hydraulic jacks 10. The shell 5 is made of several spiral turns of a sheet profile with an end face normally oriented towards the longitudinal axis of the section from the side of the intermediate section. The engagement element 6 (aka external mover) is made in the form of a U-shaped protrusion normally directed outward along the edge of the profile from the side of the cutting body. The engagement element 7 is made in the form of a flange normally directed outward along the opposite edge of the profile. The width of the inner space of the U-shaped protrusion is greater than the thickness of the shoulder. The middle turns of the shell 5 are engaged, both with the previous turn and with the next, by introducing the shoulder 7 into the inner space of the U-shaped protrusion 6, and allow mutual movement of the turns, both angular and along the axis of the section. On the inner wall of the first side of the cutting organ of the shell of the shell, a frame 8 is fixed rigidly for mounting the cutting organ 1. On the inner side of the head section, the brackets 9 of the hydraulic jacks 10 for controlling the direction of movement of the unit are evenly distributed along the entire length of the coupling line of the coils, the longitudinal axis of the jack is oriented normal to the line of elevation of the spiral of conjugation of turns.

The cutting body 1 consists of a large 11 and small (one, two or more) 12 chain bars in the form of an ellipse with cutters, their engines and gearboxes. In the initial position, the chain bars 11 and 12 are mounted on the frame 8 perpendicular to the longitudinal axis of the unit and are radially directed. The boom of the small bar 12 corresponds to the outer contour of the cylindrical surface of the head section, the boom of the large bar 11 extends beyond the specified contour by an amount corresponding to the height of the blades of the external mover 6. In this case, the plane of the ellipse of the large bar 11 is oriented in alignment with the external mover 6. Bars 11 and 12 mounted on the frame 8 with the possibility of radial movement.

The intermediate section 3 is made in the form of two cylinders 13 (internal) and 14 (external), with the help of collars 15 (external) and 16 (internal) engaged with each other with the possibility of free rotation of one cylinder relative to the other. A gear wheel 17 is rigidly fixed on the inner surface of the cylinder 13. In this case, one edge of the cylinder 13 is rigidly connected to the end of the head section 2, for example, by welding, and the opposite edge of the cylinder 14 is similarly connected to the tail section 4.

The tail section 4 is made in the form of a cylindrical shell 18 of several spiral turns of the sheet profile with ends normally oriented to the longitudinal axis of the section and contains: engagement elements 19, 20, counter-rotation elements 21, cutting bodies 22 counter-rotation elements, a drive sprocket 23 with a rotation drive of the head section . The spiral turn of the sheet profile from the side of the head section has an engagement element 19, made in the form of a U-shaped protrusion, directed inside the shell 18 and normally oriented to it. On the opposite side, the profile has an engagement element 20, made in the form of a shoulder, also directed normal to the inside of the shell 18. The width of the inner space of the U-shaped protrusion is greater than the thickness of the collar, and the height of the collar is less than the height of the shelves of the U-shaped protrusion. The middle turns of the shell are connected with each other and the extreme turns by introducing the shoulder 20 into the inner space of the U-shaped protrusion 19. This connection allows both longitudinal movement of the turns of the shell within the width of the inner space of the U-shaped protrusion, and angular, violating the coaxiality of adjacent turns in any direction. The counter-rotation elements 21 are installed along the longitudinal axis of the tail section on the outer surface of each turn of the shell 18 and are radially oriented to it. Before the counter-rotation element of the coil in contact with the intermediate section 3, also on the outer surface of the shell there is a cutting member 22 of the counter-rotation element made in the form of a trapezoidal mill and having the ability to move along the axis of rotation of the mill.

A gear wheel 17 mounted on the inner surface of the cylinder 13 of the intermediate section 3 is engaged internally with a drive sprocket 23 mounted on the inner surface of the shell 18 of the tail section 4.

Before the start of the development, the unit is installed in the initial position, in which the counter-rotation elements 21 are reliably fixed from rotation around the longitudinal axis of the unit, the cutting body 1 is closely moved to the rock mass, the external mover 6 is inserted into the pre-prepared helical channel 24.

Underground excavation of circular cross section is as follows. The cutting organ 1 is included in the operation - the chains with incisors on large 11 and small 12 bars begin to move.

The drives of the cutting bodies 22 of the anti-rotation elements 21 and the drive of the drive sprocket 23 are turned on, which, remaining in place, rotates the gear wheel 17 — the inner cylinder 13 of the intermediate section 3 and with it the head section 2 begin to rotate.

With the beginning of the rotational movement of the head section 2, the cutting body 1, consisting of a large Pi of small 12 chain bars, begins to destroy the rock mass, forming a conductive mine 25. At the same time, a small bar 12 (one or several) provides a given diameter of the mine and a guaranteed clearance between the head shell sections and an array of enclosing rocks. This gap is determined by the outbreak of the boom of the small bar beyond the contour of the shell of the head section and is controlled by the radial movement of the small bar 12 along the frame 8. The large bar 11, destroying the rock in the bottom of the excavation, also cuts the helical channel 24 in the near-edge array, which includes the blade of an external mover 6. In this case, the large bar 11 cuts the helical channel 24 wider than the thickness of the blades of the external mover 6. Based on the board of the helical channel 24 (farthest from the bottom of the mine), the external mover provides translational movement th section 2 to the face. In this case, between the blade of the external mover 6 and the opposite side of the screw channel 24 there is a guaranteed clearance.

When the head section 2 is rotated one revolution around its axis:

- the specified section, screwing into the rock mass through the helical channel 24, will move to the step of winding the turns of the sheet profile;

- due to the engagement of the shoulder 7 with the U-shaped protrusion 6, the intermediate section 3 will move by the same amount, which will pull the tail section 4 along with it;

- when the tail section 4 moves after the head one, each cutting organ 22 of the counter-rotation element will cut a longitudinal channel 26 in the near-side array equal in length to the step of winding the turns of the shell of the head section, and the counter-rotation elements themselves will move along these channels by the same amount.

That is, the formation of the development, screwing into it the head section of the unit and pulling the tail is carried out simultaneously.

The development after the unit is fixed with an annular frame support.

If it is necessary to change the direction of the development (insurmountable obstacle, utilities, etc.), the cutting unit 1 is first turned off with the sprocket 23 working for some time. As a result, all the turns of the sheet profile of the head section 2 are closed within the gaps between the propeller blade and the screw channel - the head section is compressed. Then the head section is bent, including hydraulic jacks 10. In this case, a part of them located further from the axis of curvature of the mine (external radius jacks) is used to extend the rod, and another part located closer to the axis (internal radius jacks) is retracted stock. Hydrojacks located between them (jacks of average radius), remain in a neutral position. This bending of the head section is possible only within the movement of the shoulder 7 in the inner space of the blade 6, and also due to the elimination of the gap between the blade of the external mover 6 and the bottom face of the screw channel 24.

As a result of pressure from the jacks of the outer radius, the first turn of the shell of the head section with its part farthest from the center of curvature of the mine will shift to the bottom of the screw channel 24, and the part located closer to the center of curvature will remain in place, held by hydraulic jacks of near radius.

In the next turn of the head section, these operations are repeated and thereby ensure a smooth curvature of the production in the given direction. In this case, the head section, due to the engagement of the turns of the sheet profile, bends more and more in a given direction, thereby ensuring the curvature of the workings.

When approaching the beginning of the curvature of the development of the tail section, they first provide the necessary clearance between the counter-rotation elements and the side stacks of the longitudinal channels by increasing their width. For this, the cutting bodies 22 of the counter-rotation elements, made in the form of a truncated cone, extend further from the shell of the unit. Then, the tail section is bent by the production profile by pulling up after the head section. In this case, the counter-rotation elements are located in a wider longitudinal channel not aligned with it for any change in the direction of development.

Upon exit of the unit from the curved part of the output, the jacks 10 are turned off, and the destruction organs 22 of the counter-rotation elements are returned to their original position. Due to this, the head and tail sections will again be aligned.

The method of constructing an underground mine and a shield tunneling unit are connected by a single inventive concept. Due to the implementation of the head and tail sections in the form of several turns of the sheet profile, engaged by means of a protrusion and a shoulder, the unit received relative flexibility, which allows not only to bend and compress these sections, but also to carry out workings for various purposes, curved in any plane. This indicates an increase in the efficiency of underground construction, i.e. to achieve the objective of the invention.

Claims (2)

1. A method of constructing an underground mine, including the formation of an oriented cavity in the bowels of the Earth with a shield driving unit, consisting of a head and tail sections arranged sequentially and coaxially, with a direct stroke when the head section rotates in one direction, cutting of screw and longitudinal channels in the near-edge working zone in the mass of surrounding rocks, with the placement of external movers and anti-rotation elements of the unit, respectively, screwing in the head section and pulling the tail section and supporting the development of the worked-out space by erection of the support, characterized in that the formation of the working, screwing in of the head section of the unit and pulling up of the tail section is carried out simultaneously, the screw channel is cut by the cutting unit of the unit, when cutting the screw and longitudinal channels, they provide a guaranteed gap between the external mover and the side walls of the screw channel and between counter-rotation elements and side walls of the longitudinal channel, when forming a curved section of the development, the head section is compressed and bend in the corresponding direction, then form a development in the specified direction; as the tail section is pulled up in a curved section, it is bent along the profile of the working, and the deviation of the longitudinal axis of the generated working part from the axis of the formed working part is provided depending on the geometric dimensions and the relative position of the head and tail sections, propulsion units and counter-rotation elements of the assembly and the gaps in the mates of the above parts of the unit in the excavation, helical and longitudinal channels, respectively, and after the unit leaves the curved section, they are transferred to the original position of the head and tail sections. 2. Shield tunneling unit, containing sequentially and coaxially located head and tail cylindrical sections, interconnected with the possibility of rotation of the head section around its longitudinal axis; a cutting body fixed to the head section by means of a frame structure; external mover made in the form of protruding blades; loading organ installed inside the head section, longitudinal counter-rotation elements with destructive counter-rotation elements located in front of them mounted on the outer surface of the tail section, characterized in that the cutting body is made in the form of large and small chain bars with cutters installed in a plane perpendicular to the longitudinal the axis of the unit, with the possibility of movement along the frame structure in the radial direction and oriented diametrically opposite to the axis of the unit, t boom of a small bar corresponds to the contour of the cylindrical surface of the head section, the outreach of the boom of a large bar goes beyond the specified circuit by an amount corresponding to the height of the blades of the external mover; the head and tail sections are made of several turns of the sheet profile in the form of a single-start spiral with ends normally oriented to the longitudinal axis, the adjacent turns of which are interconnected by a groove and a shoulder, and the width of the groove is greater than the thickness of the shoulder, and the groove itself is made in the inner space of the blade of the head section mover and in the inner space of the tail section, and the turns of the sheet profile are associated with the possibility of mutual movement both in the angle and along the longitudinal axis of the section; the external mover is made in the form of a helical blade along the entire length of the interface line of the turns; on the inner surface of the head section, normal to the spiral lift line, jacks are installed to control the direction of movement of the unit, evenly distributed along the entire length of the coupling line of the coils and connecting adjacent coils; the edge of the head section from the side of the tail section is rigidly connected with the intermediate section, a gear wheel is rigidly fixed on its inner surface, a drive sprocket is in internal engagement with it, the axis and drive of which are rigidly fixed on the inner surface of the tail section.

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