RU2795402C2 - Assembly for expansion of a drilling system shaft - Google Patents

Abstract

FIELD: drilling system.

SUBSTANCE: group of inventions relates to a shaft expansion assembly for a drilling system, and a drilling system comprising said shaft expansion assembly with a hollow column located near the lower end of the drilling system. The assembly for expanding the shaft contains a hollow column located near the lower end of the drilling system, and the hollow column contains an upper section, a middle section, a lower section and a telescopic part, which is axially movable relative to the rest of the hollow column; an expander section comprising the first cutting head assembly tapering downwardly that is mounted on a hollow column with a possibility of rotation, with the first drive means configured to rotate the first cutting head assembly relative to the hollow column so as to drill down a hole having a diameter corresponding to that of the first cutting head assembly; a drill head assembly coupled to a working lower end of the telescopic portion of the hollow string, the drill head assembly ending in a downwardly tapering second cutting head assembly to drill a guide or pilot hole; an axial movement section configured to advance the drill head assembly relative to the expansion section; spreader assembly. A drilling system is also claimed, which contains the specified assembly for expanding the shaft and contains a plurality of auxiliary platforms located above the assembly for expanding the shaft inside the hole drilled by the first assembly of the cutting head, and the assembly for expanding the shaft is made with the possibility of separation from the plurality of auxiliary platforms.

EFFECT: assembly for expanding the drilling shaft.

20 cl, 32 dwg

Description

Technical field

The invention relates to a drilling system (or drilling rig or machine), and more particularly, in one embodiment, to a system for drilling a blind mine shaft. In general terms, a drilling system comprises an above-ground derrick support structure, and an underground mine shaft extension assembly. The drilling system can be used to drill substantially vertical holes or shafts by first drilling through rock at ground level and drilling vertically down a predetermined distance without the need for pre-drilling, as is often required with blind hole systems.

State of the art

Conventional raise drilling starts with drilling a pilot hole vertically downwards, typically using a directional drilling system. It is drilled using a drilling rig at the surface of the earth, from which extends down a hollow drill string containing a plurality of drill pipes connected together. To drill a pilot hole, a roller bit is attached to the lowest part of the drill pipe of a drill string containing standard threaded pipes for high torque applications. After the pilot hole has been drilled to the bottom level, the cone bit is removed and replaced with a reaming head containing a plurality of cutters. The expansion head is rotated and raised back to the surface-mounted drilling rig so as to drill a larger diameter pit, or rise, through the earth's surface and rock. Drill cuttings fall by gravity into a chamber located at the bottom of the pit, usually in an uncontrolled manner, from where it is removed using a loading device.

On the other hand, drilling a blind hole involves drilling a very large pilot hole. A very large pilot hole can be drilled either in one step or, more typically, by first drilling the original 400 mm diameter pilot hole, for example, which is then progressively expanded to create a very large 3 m diameter pilot hole. This process is fairly well known in the art. A cutting head is then placed over the large size pilot hole drilled so that downward drilling can be performed. The drill cuttings are then washed out of the large pilot hole. This particular technique is not used as often as the potential for clogging of the pilot hole and formation of quicksand breaks at the bottom of the hole is relatively high.

None of the known drilling systems allows relatively large holes (preferably having a diameter of 6 to 9.5 meters) to be drilled with drilling cuttings above the drilling system, without the need to flush the cuttings using, for example, backwashing.

It is an object of the present invention to provide a drilling system or rig to achieve the above objectives in an efficient and versatile manner and without the need to drill an initial pilot hole, as is commonly done.

Disclosure of the essence of the invention

According to the invention, a shaft expansion arrangement for a drilling system is provided, wherein the shaft expansion arrangement comprises:

a hollow string located near the lower end of the drilling system;

an expander section comprising a downwardly tapering first cutting head assembly that is rotatably mounted on a hollow string, with a first drive means configured to rotate the first cutting head assembly relative to the hollow string so as to drill down a hole having a diameter substantially corresponding to the diameter of the first cutting head arrangement;

a drill head assembly coupled to a working lower end, the drill head assembly ending in a downwardly tapering second cutting head assembly to drill a pilot or pilot hole having a diameter that is less than that of the first cutting head assembly as the drilling system continues downward drilling ;

an axial movement section configured to advance the drill head assembly relative to the expansion section; And

a spacer arrangement configured to lock the assembly to expand the shaft inside the drilled pit and control the advancement of the drilling head assembly relative to the expansion section.

In one embodiment, the first cutting head arrangement comprises a support element supporting the first blade arrangement, the support element being rotatably mounted about a column, the first blade arrangement comprising a plurality of blades attached to the support element, each blade comprising an oblique or laterally extending , typically at 45 degrees, a support beam on which is mounted or which contains a plurality of first cutting elements. The angled support beams are arranged to define a substantially V-shaped cutting profile.

In one embodiment, a gear housing is mounted above the first cutting head assembly and around the column, wherein the first drive means is mounted on top of the gear housing and configured to drive the gear assembly within the gear housing, which in turn is configured to rotate the support element and the first layout of the cutting head around the column. Typically, the first drive means comprises a plurality of electric motors disposed around a side surface of the gear housing.

In one embodiment, each blade is detachably attached to, or attachable to, a support member such that blades of different sizes can be interchanged to allow drilling holes of different diameters.

In one embodiment, at least one collection channel is provided in the hollow string below the first cutting head assembly, into which drill cuttings generated as the first cutting head assembly is rotated can be collected. The collection channel defines an inlet for receiving drill cuttings, an outlet through which the drill cuttings can exit the channel into the string, and a passage is provided between the inlet and the outlet at a downward angle to facilitate the passage of drill cuttings into the string by gravity. , for subsequent collection in a tunneling bucket moved up and down the column.

Typically, a shaft reaming arrangement comprises a pair of diametrically opposed collection channels, with the lowermost portions of the paddle assembly containing scrapers for scraping drill cuttings into the collection channels as the first cutting head assembly rotates relative to the string.

In one embodiment, the spacer arrangement is coupled to a hollow column, the spacer arrangement comprising a first row of circumferentially distributed base plates located between the first cutting head arrangement and the axial movement section, with a second row of circumferentially distributed base plates located between the axial movement section and second cutting head arrangement. The spacer assembly is configured to be securely supported on a guide hole drilled by the second cutting head assembly so as to fix the drilling system in position within the drilled hole, control the advancement of the drill head assembly relative to the reamer section, and facilitate rotation of the first cutting head assembly and/or control them.

In one embodiment, the first and second rows of base plates extend away from the hollow column through an outer guard and are movable by the first and second actuator arrangement, respectively, between a retracted disengagement position and an extended engagement position, wherein the plates engage with the guide hole formed by the second cutting head arrangement.

In one embodiment, a third actuator arrangement is provided within the axial movement section, configured to advance the drill head assembly relative to the expander section.

In one embodiment, the second cutting head arrangement comprises a support element supporting the second blade arrangement, the support element being rotatable relative to the support body from which it emerges.

The second blade arrangement includes a plurality of blades attached to the support element, each blade having an oblique or transversely extending, typically 45 degree, support beam on which a plurality of first cutting elements are mounted or which contains. The angled blade arms are positioned to form a substantially V-shaped cutting profile.

In one embodiment, the second drive means is mounted on top of the support body and configured to drive the gear assembly within the support body, which in turn is rotatable to the support member and the second cutting head assembly. Typically, the second drive means comprises a plurality of electric motors disposed around a side surface of the support housing.

In one embodiment, a guard is provided around the support body and the second drive means, with the support body and/or the second drive means connected to the end of the hollow column.

In one embodiment, the fourth actuators are configured to move the blades relative to the support member between an extended, working V-configuration to facilitate drilling, and a folded, substantially aligned (typically parallel) configuration to allow separation of the second cutting head assembly from the rest of the assembly. for expanding the shaft of the mine and raising by means of a hollow column to the surface. Thus, the diameter of the folded second cutting head assembly, which substantially corresponds to the diameter of the support body, is smaller than the diameter of the hollow column to facilitate its extraction.

In an alternative, preferred embodiment, the drill head assembly comprises a frustoconical mud-feed drill head comprising a mud pump, the mud-feed drill head having a tapered sidewall ending in an end surface, wherein the tapered sidewall and/or the end face is provided with a second cutting head arrangement for drilling a pilot hole as the drilling system moves down. In some embodiments, the implementation of the second layout of the cutting head may be equipped with, or contains, a plurality of second cutting elements.

In one embodiment, the drill head assembly comprises a support housing with a mud-fed drill head rotatable relative to the support housing, wherein a second drive means is mounted on top of the support housing and configured to drive the gear assembly, which in turn is configured to with the possibility of rotation of the drilling head with the supply of drilling fluid relative to the support body.

In one embodiment, the mud-fed section of the drill head can be detached and removed from the mud-fed drill head, the detachable section comprising at least an end face and a mud pump.

In one embodiment, each of the second cutting elements comprises a working surface from which a plurality of rows of carbide inserts emerge. The rows of carbide inserts are spaced about 25 mm apart, which provides a cut size of about 25 mm due to the interaction between the carbide inserts and the cutting surface. In addition, the working surface of the cutting element is located at a distance of about 50 mm from the cutting surface.

In one embodiment, the drilling system comprises a plurality of auxiliary platforms positioned above the shaft expansion assembly within the hole drilled by the first cutting head assembly, the shaft expansion assembly being separable from the plurality of auxiliary platforms.

The drilling system further comprises an above-ground drilling rig support structure, comprising an upper support assembly and a headframe structure for lifting and lowering the shaft expansion assembly and a plurality of auxiliary platforms.

In one embodiment, a movable maintenance platform is provided above a plurality of auxiliary platforms, to which a traverse is attached or configured to be attached, wherein the movable maintenance platform can be raised, detached, and temporarily placed within the headframe structure to allow the traverse to be used to grip a component. or element inside a mine shaft and its rise to the surface.

In one embodiment, to create a horizontal opening extending away from the shaft being formed, the shaft expansion assembly may be completely detached (or disengaged) from the rest of the drilling system and covered with a cover configured to cover a portion of the shaft directly above the detached assembly for mine shaft expansion. A plurality of auxiliary platforms may then be raised from the disconnected assembly to widen the shaft to provide sufficient space to form a sidetrack. With explosives or appropriate equipment, a branch can be formed and once formed, the cover can be removed and the reamer assembly can be reattached to the rest of the drilling system to allow the reamer assembly to continue operating.

In one embodiment, one of the auxiliary platforms includes a lifting device.

In one embodiment, the lifting device comprises a pump and an arc screen, the arc screen receiving cuttings water forced through the pipeline by a mud pump located adjacent to the cutting fluid feed cutting head. The slurry water is separated and the harder components/cut rock are discharged into the tunneling bucket via the sliding chute. The separated sludge water is then pumped with a three-cylinder pump through a pipeline in which fine particles will be removed from the water. The clean water can then be pumped back into the system.

In another embodiment, the lifting device includes a vacuum system for sucking dry broken rock and drill cuttings into a vacuum tank, the vacuum tank then unloading dry material through a sliding chute into a tunneling bucket, which can then be raised to the surface. This device is especially useful in geological conditions where water cannot be used, such as salt mines.

In yet another embodiment, the lifting device includes a high pressure water pipe for forcing water from the surface into the system, a low pressure water pipe configured to drain waste water back to the sump, a high pressure water pipe that contains particles to be lifted to the surface, an inlet low pressure water pipe with particles, and a multi-chamber device with valves for regulating and controlling the flow of water flowing through the water pipes.

In one embodiment, the drilling system comprises a pipe running device, wherein the pipe running device comprises a suspended derrick for lifting and lowering at least one pipe, and a guide means comprising a plurality of rotatable roller bearings that comprise a rounded recess to accommodate the outer rounded part of the pipe, so that when lifting and lowering the pipes, a pair of adjacent roller bearings places the pipe to guide the movement of the pipe between them.

Brief description of graphic materials

These and other features of the present invention will be apparent when viewed in light of the following description and drawings, in which:

in FIG. 1 is a side view of a first embodiment of a drilling system using one embodiment of a mine shaft expansion arrangement in accordance with the present invention;

in FIG. 2 is a side view of a shaft expansion assembly for a drilling system in accordance with an embodiment of the present invention;

in FIG. 3 is a cross-sectional side view of the shaft expansion assembly shown in FIG. 2;

in FIG. 4 is a bottom perspective view of the shaft expansion arrangement shown in FIG. 2 and 3;

in FIG. 5 shows a detailed cross-sectional side view of the first cutting head arrangement used in the arrangement shown in FIG. 2–4;

in FIG. 6 is a detailed cross-sectional side view of the spacer arrangement used in the arrangement shown in FIG. 2–4;

in FIG. 7 is a perspective view of a second slurry reamer cutting head arrangement used in the arrangement shown in FIG. 2–4;

in FIG. 8 is a side view of the second cutting head arrangement shown in FIG. 7, in an extended, working configuration;

in FIG. 9 is a side view of the second cutting head arrangement shown in FIG. 7, in a retracted configuration;

in FIG. 10 and 11 show a cross-sectional and side view of a shaft expansion assembly for a drilling system in accordance with another embodiment of the present invention;

in FIG. 12 and 13 show a side view and a cross-sectional view of the mud-fed drill head assembly used in the reaming assembly shown in FIG. 10 and 11;

in FIG. 14 shows the sequence of steps that must be followed to remove the mud-fed drill head component from the remainder of the mud-fed drill head assembly shown in FIG. 12 and 13;

in FIG. 15 is a detailed view of the cutter configuration and spacing used in the mud-fed drill head assembly shown in FIG. 12 and 13;

in FIG. 16 shows the possibility of building a drilling system that uses the shaft expansion arrangement shown in FIG. 10 and 11 to provide for the formation of a horizontal mine branch, wherein the shaft expansion assembly can be detached from the rest of the drilling system;

in FIG. 17 and 18A-18I show the relative position of the moving service platform and the traverse relative to the upper support assembly in order to ensure the unhindered extraction of elements from the mine shaft;

in FIG. 19-21 show various lifting devices that can be equipped with one of the auxiliary platforms; And

in FIG. 22 and 23 show a pipe running device that can be used in a drilling system.

Detailed description of graphic materials

Referring first to Fig. 1, a drilling system 100 is shown in which a shaft reaming assembly 10 of the present invention may be used. In general terms, the drilling system 100 includes an elevated derrick support structure 102 comprising an upper support assembly 102. A winch is provided to move the assembly 10 to expand the shaft up and down as needed within the drilled shaft or hole 104 by means of ropes or wires. 106 (as best shown in FIG. 2) extending between the winch and the shaft expansion assembly 10. A bucket elevator 108 is also provided to move the bucket elevator 32 up and down, as needed, through the hollow column 12 of the assembly 10, also by ropes or cables 110 (as best shown in FIG. 3) passing between the bucket elevator 108 and the bucket bucket. 32. Other surface components include: maintenance hoists, traverse locking device, tunneling bucket 32 tilting device at the surface to remove drill cuttings from tunneling bucket 32.

Within the drilled shaft or pit 104, but above the shaft expansion assembly 10, a plurality of auxiliary platforms 112 are provided that serve various purposes such as an operator platform, platform for supporting drilling tools and working with drilling mud, hydraulic and electrical auxiliary working platform and lower working/formwork platform to secure the pit 104.

Turning now to FIG. 2-4, which shows an arrangement 10 for reaming a shaft for a drilling system such as that shown in FIG. 1, the shaft enlargement assembly 10 includes a hollow column 12 located near the lower end of the drilling system. Column 12 includes a top section 12A, a middle section 12B, and a bottom section 12C. The column 12 further comprises a telescoping portion 12D which is axially movable relative to the remaining hollow column portions 12A, 12B and 12C, which will be described in more detail below.

The first cutting head arrangement 14 corresponding to the expansion section is rotatably connected to the hollow column 12, namely, to the middle section 12B of the column 12. Driving means in the form of electric motors 16 are configured to rotate the first cutting head arrangement 14 relative to (i.e., around) the hollow column 12. This results in the hole 104 to be drilled down having a diameter substantially corresponding to the diameter of the first cutting head arrangement 14. Column 12 is typically double walled to form ventilation and/or cooling passages.

The first cutting head assembly 14 includes a support member 18 supporting a bladed arrangement 20, wherein the abutment member 18 is rotatably mounted on a column 12. The bladed arrangement 20 comprises a plurality of substantially triangular blades 22 attached to the abutment member 18. Each blade 22 comprises an inclined or projecting laterally, typically at 45 degrees, a support beam 24 on which is mounted or which contains a plurality of first cutting elements 26 extending along the length of the beam 24. The angled support beam 24 is positioned so as to form a substantially V-shaped cutting profile.

In one embodiment, the gear housing 28 is mounted above the first cutting head assembly 14, with the first drive means mounted on top of the gear housing 28 and configured to drive the gear assembly within the gear housing 28. This in turn is configured to rotate the support member 18 and thus the first cutting head assembly 14 around the column 12. Typically, the electric motors 16 of the first drive means are located around the side surface of the gear housing 28.

In one embodiment, each blade 22 is detachably attached to, or attachable to, a support member such that blades 22 of different sizes can be interchanged to allow drilling holes of different diameters.

As best shown in FIG. 3, at least one collection passage 30 is formed in the hollow string 12, near the junction between the middle section 12B and the lower section 12C, below the first cutting head assembly 14, in which cuttings generated by the rotation of the first cutting head assembly 14 can collect, as indicated by arrow 31. The manifold conduit 30 defines an inlet for receiving drill cuttings, an outlet through which the drill cuttings can exit from the conduit to the string, and a downward angled passageway is provided between the inlet and the outlet to facilitate passage of the drill cuttings. in the column 12, namely, in the lower section 12C, under the influence of gravity. It can be collected in a tunnel 32 that is moved up and down the column 12.

Typically, a shaft expansion arrangement 10 comprises a pair of diametrically opposed collection channels 30, as best shown in FIG. 3, with the lowermost portions of the blade assembly 20 including scrapers (not shown) for scraping cuttings into the collection channels 30 as the first cutting head assembly 14 rotates around the string 12.

In one embodiment, the shaft expansion assembly 10 comprises a spacer assembly 34 mounted on (ie, around) the hollow column 12, which will be described with reference to FIG. 6. In particular, the spacer arrangement 34 comprises a first row of circumferentially distributed base plates 36 that are located, in use, below the manifold channels 30, and a second row of circumferentially distributed base plates 37 that are located, in use, below the first a row of base plates 36 and above of a drill head arrangement 38 (which will be described in more detail below). The spacer assembly 34 is capable of being securely supported on the pilot hole 114 drilled by the second cutting head assembly 39 of the drill head guide assembly 38 so as to fix the drilling system 100 in position within the drilled hole 104.

The first and second rows of base plates 36, 37 extend away from the hollow column 12; namely, the first row of base plates 36 extends from the middle section 12B of the column 12 and through the outer guard 43. Similarly, the second row of base plates 37 extends from the bottom, telescoping section 12D of the column 12 and through the outer guard 45. The base plates 36, 37 are movable by means of the first and second actuator assemblies 40, 42, respectively, between a retracted disengagement position and an extended engagement position in which the plates 36, 37 engage with the guide pit 114 formed by the second cutting head assembly 39, to assist or control the rotation of the first cutting head assembly 14.

The lower, telescoping section 12D of string 12 is axially movable relative to the remainder of string 12 by a third actuator assembly 44 in the form of a plurality of hydraulic axial movement cylinders to form an axial movement section to advance the drill head assembly relative to the expansion section. Relative axial movement provides the functions of axial movement and direction control and typically involves the use of four hydraulic axial movement cylinders that are interconnected with the lower and middle sections 12C and 12B of the column 12. Axial movement and direction control is typically used in combination with a locking element pads 36, 37 such that when the pads 36, 37 are in their extended fixed configuration, the third actuator assembly 44 can activate the downward drilling movement of the drill head assembly 38.

The drill head assembly 38 is attached to the working lower end of the string 12, namely the lower end of the telescoping portion 12D. In one embodiment, the drilling head assembly 38 is detachably attached to the working lower end of the string 12 so that it can be separated from the rest of the assembly 10 to expand the shaft if/when needed, as will be described in more detail later in the description.

The drill head assembly 38 ends at the second cutting head assembly 39 to drill the pilot hole 114 as the drilling system 100 continues to drill down, as will be described with reference to FIG. 7–9. The second cutting head assembly 39 is typically equipped with, or includes, a plurality of second cutting elements 46. In one embodiment, the second cutting head assembly 39 includes a support member 48 supporting the second blade assembly 50, the support member 48 being rotatable relative to the support member. building 52, from which he leaves.

The second blade arrangement 50 includes a plurality of blades 54 attached to a support member 48. Each blade 54 includes an oblique or laterally projecting, typically 45 degree, blade arm 56 on which a plurality of second cutting elements 46 are mounted or comprised. the arms 56 of the blades are arranged to form a substantially V-shaped cutting profile.

In one embodiment, second drive means 58 is mounted on top of support housing 52 and configured to drive a gear assembly within support housing 52, which in turn is rotatable to support member 48 and second cutting head assembly 39. Typically, the second drive means 58 comprises a plurality of electric motors disposed around a side surface of the support housing 52.

As best shown in FIG. 2-4, a guard 60 is disposed around the support body 52 and the second driving means 58, with the support body 52 and/or the second driving means 58 attached to the end of the hollow column 12.

Returning to Fig. 7-9, the fourth actuators 62 are articulated with the blade arms 56 relative to the support member 48 between an extended, working V-shaped configuration to facilitate drilling as shown in FIG. 7 and 8, and folded in a substantially aligned (generally parallel) configuration to allow the second cutting head assembly 39 to be separated from the rest of the shaft expansion assembly 10 and raised by the hollow column 12 to the surface as shown in FIG. 9. Thus, the diameter of the folded second cutting head assembly 39, which substantially corresponds to the diameter of the support body 52, is smaller than the diameter of the hollow column 12 to facilitate its extraction.

The fourth actuating means 62 is typically in the form of a hydraulic piston to act on a lever member extending between the piston and the end of the vane arm 56 so as to rotate the vane arm 56 between two configurations.

In an alternative embodiment, the drill head assembly 38 comprises a mud-fed drill head terminating on a working flat surface to form a mud guard, the flat surface being equipped with a second cutting head assembly for drilling a pilot hole as the drilling system moves downward. . In this embodiment, the second cutting head assembly may be equipped with, or comprise, a plurality of second cutting elements, wherein the drive means is configured to drive the second cutting elements of the drill head with drilling fluid.

Shaft expansion arrangement 10 typically includes a pair of platforms 70, 72, as best seen in FIG. 2 mounted on a hollow column 12 above the first cutting head assembly 14 to support personnel performing shaft fixing and/or maintenance work.

Turning now to FIG. 10 and 11, which shows an arrangement 150 for reaming a shaft for a drilling system 152 (as best shown in FIG. 16) in accordance with the second embodiment. Shaft reaming assembly 150 includes a hollow string 154 located near the lower end of drilling system 152. Reaming section 156 includes a downwardly tapering first cutting head assembly 158 that is rotatably coupled to hollow string 154. Although not shown in these graphics, the first driving means is configured to rotate the first cutting head assembly 158 relative to the hollow string 154 so as to drill down a hole having a diameter substantially corresponding to the diameter of the first cutting head assembly 158.

The shaft expansion assembly 150 further comprises a drill head assembly 160 coupled to the working lower end of the expansion assembly 150. The drill head assembly 160 terminates at the downwardly tapering second cutting head assembly 162 to drill a guide or pilot hole having a diameter that is smaller than that of the first cutting head assembly 158 as the drilling system 152 continues downward drilling.

Between the first and second cutting head assemblies 158, 162, an axial movement section 164 is provided to allow the drilling head assembly 160 to advance relative to the expansion section 156, the spacer assembly 158.1, 158.2 being used to lock the assembly 150 to widen the shaft within the drilled shaft and control by advancing the drill head assembly 160 relative to the expander section 156. The description of the operation of the axial movement section 164 and the spacer arrangement 158.1, 158.2 has basically been given above and for this reason will not be repeated.

As best shown in FIG. 12 and 13, the drilling head assembly 160 comprises a frustoconical mud head 170 comprising a mud pump 172, the mud head 170 having a tapered side wall 174 terminating in an end surface 176, wherein the tapered side wall wall 174 and/or end face 176 is provided with a second cutting head assembly 162 for drilling a pilot hole as the drilling system 152 moves downward. In some embodiments, the second cutting head assembly 162 may be equipped with, or comprise, a plurality of second cutting elements 178.

The drilling head assembly 160 comprises a support body with a mud-feeding drill head 170 rotatable relative to the support body, typically using a swivel known in the art. As described above, although not shown, a second drive means is mounted on top of the support housing and is configured to drive the gear assembly within the support housing, which in turn is configured to rotate the mud-feeding drilling head 170 relative to the support housing. Typically, the second drive means comprises a plurality of electric motors disposed around a side surface of the support housing. The swivel can handle various types of media and related pressures such as hydraulic fluid and slurry water.

As best shown in FIG. 11, a guard 180 is positioned around the drilling fluid portion of the drill head 170, with the guard 180 extending upwardly toward the spacer assembly 158.2.

Turning now to FIG. 14, a section 170.1 of the mud-fed drill head 170 can be detached and removed from the mud-fed drill head 170, the detachable section 170.1 comprising at least an end face 176 and a mud pump 172. The detachable section 170.1 of the mud-fed drill head 170 has a number of advantages. For example, when the removable section 170.1 is detached, access to the cutting surface 174, 176 is provided without the need to resurface the entire assembly 150 to widen the shaft. This allows maintenance of the cutting surface 174, 176 to be carried out in a highly versatile and efficient manner. The weight of the removable section 170.1 is determined by the capacity of the bucket hoist (as described above and further below), which can now also be used to lift the removable section 170.1. When the removable section 170.1 is raised to the surface, maintenance and repair can be performed, including the replacement of the cutters 178 and the repair of the mud pump 172, etc. the mud-feed portion of the drill head 170 includes reverse-cut cutters. This design allows the cutters of the removable part 170.1 to be changed at the surface without the need to remove, for example, the mud pump 172.

Turning now to FIG. 15, each of the second cutting elements 178 includes a working surface 182 from which a plurality of rows 184 of carbide inserts extend, the second cutting elements 178 being rotatably placed within the cavity 186. The rows of carbide inserts 184 are spaced about 25 mm apart, which provides the size of the cuttings formed due to the interaction between the carbide inserts and the cutting surface 188, approximately 25 mm. In addition, the working surface 182 of the cutting element 178 is located at a distance of approximately 50 mm from the cutting surface 188. This is important to meet the requirements for water flow required to maintain cuttings in suspension and remove fines from the cutting surface 188 through the drilling pump 172. solution up to the separating unit, since the farther the working surface 182 is located from the cutting surface 188, the higher the required water flow. When the spacing is 50 mm, particles larger than 50 mm are prevented from being sucked into the mud pump 172, which may block the suction port of the mud pump 172 (which is usually limited to a 50 mm particle size). Thus, this configuration helps to control the particle size entering the mud pump 172 . Also, in the case of drilling in geological conditions where the use of water can be problematic, such as salt mines and potash mines, this particular interval configuration will allow the use of a vacuum system instead of a mud pump system if required or desired, as described below with with reference to Fig. 20.

In addition, the suction port 190 of the mud head 172, as shown in FIG. 13 is located at a certain radius on the cutting head with drilling fluid to ensure that all drilling cuttings are removed from the bottom of the cutting surface. Suction port 190 has a diameter of approximately 150 mm to ensure that the water flow rate is high enough to ensure removal of drill cuttings.

Turning now to FIG. 16, the drilling system 152 includes a plurality of auxiliary platforms 200 positioned above the assembly 150 for expanding the shaft within the hole 202 drilled by the first cutting head assembly 158. In one embodiment, the shaft expansion assembly 150 may be separate or detachable from a plurality of auxiliary platforms 200.

The drilling system further comprises an elevated derrick support structure 204 comprising an upper support assembly 206 and a headframe structure 208 for raising and lowering the shaft expansion assembly 150 and a plurality of auxiliary platforms 200. The headframe structure 208 typically comprises at least:

a winch for moving the shaft expansion assembly up and down as needed within the shaft shaft 202 by means of ropes or cables passing between the winch and the shaft expansion assembly 150;

a bucket elevator for moving the tunnel elevator 210 up and down, as needed, through the hollow column 154 and through the hollow column 212 on which the tiers 200 are mounted, by means of ropes or cables passing between the bucket elevator and the tunnel bucket 210; And

a platform lift for moving the plurality of auxiliary platforms 200 up and down as needed.

In one embodiment, a movable maintenance platform 214 is provided above a plurality of auxiliary platforms 200 to which a yoke 216 (comprising end hooks 218) is attached or configured to be attached. The movable maintenance platform 214 can be raised, detached, and temporarily positioned within the headframe structure 208 to allow use of the yoke 216 to grab a component or element within the shaft 202 and lift it to the surface 220.

In particular, the upper support assembly 206 includes a lower support frame 222 that defines an area 224 for accommodating the moving platform 214 for servicing after it has been raised. In operation, when it is necessary to remove equipment from the shaft 202, such as the tiers 226 of the auxiliary platforms 200 and/or the assembly 150 for expanding the shaft, the moving platform 214 for maintenance can be raised within/between the headframe structure 208, as indicated by the dashed line. 228. In this position, the moving service platform 214 is out of the way and thus does not need to be removed from the headframe structure 208. The lifting beam 216 can now be used to grab a suitable component or piece of equipment located down the shaft 202 and lift it to the surface 220 where it can be disconnected.

During operation, with reference to FIG. 18, a support platform 230 may be provided, with the top of the shaft typically covered by a cover 232 (as shown in FIG. 18A). As indicated above, the moving service platform 214 is raised and set aside. Then, after the cover 232 is removed, the tiers 226 of the sub platforms 200 can be raised using the headframe structure 208 in conjunction with the traverse 216, as shown in FIG. 18b. The cover 232 can then be replaced to allow the platform 230 to move over the mine, as shown in FIG. 18C. Then the upper tiers 226 can be detached from the yoke 216, unloaded onto the platform 230 and then moved to the side (Fig. 18D and Fig. 18E). The yoke 216 can then be lowered and attached to the next tier(s) 226 (FIG. 18F). The process is then only repeated to allow lifting and moving towards the remaining tiers 226.

Again with reference to FIG. 16, in order to create a horizontal working 240 extending away from the shaft 202, the assembly 150 for expanding the shaft shaft can be completely detached (or disengaged) from the rest of the drilling system 152. The cover 242 is configured to cover a portion of the shaft 202 immediately above disconnected layout 150 for expanding the shaft of the mine. A plurality of auxiliary platforms 200 may then be raised from the disconnected assembly 150 to widen the shaft to provide sufficient space to form a branch 240. With explosives or suitable equipment 244, a branch 240 may be formed, and immediately after its formation, the cover 242 can be removed and the reamer assembly 150 can be reattached to the rest of the drilling system 152 to allow the reamer assembly 150 to continue operating.

Turning now to FIG. 19-21, one of the tiers 226 of the auxiliary platforms 200 contains lifting devices 250, 270 and 290, respectively.

In one embodiment, as shown in FIG. 19, the lifting device 250 includes a "wet" lifting device 250. The lifting device 250 includes a three-cylinder pump 252 and an arc screen 254, the arc screen 254 receiving slurry water pumped through conduit 256 by means of a mud pump 172 located adjacent to the cutting head with drilling fluid supply. The slurry water is separated and the harder components/broken rock are discharged into the tunneling bucket 210 via the retractable chute 258, which can then be lifted to the surface using a bucket hoist. The separated sludge water is then pumped by a three-cylinder pump 252 through a conduit 260 in which fine particles will be removed from the water. The clean water can then be pumped back into the system.

In another embodiment, as shown in FIG. 20, the lifter 270 is a "dry" lifter. Elevator 270 includes a vacuum system for sucking dry broken rock and drill cuttings into vacuum tank 272, where vacuum tank 272 then discharges the dry material through chute 274 into sinking bucket 210, which can then be lifted to the surface. This device is especially useful in geological conditions where water cannot be used, such as salt mines.

In another embodiment, as shown in FIG. 21, the lifting device 290 is a "hydraulic" lifting device. The lifting device 290 includes a high pressure water pipe 292 for pumping water from the surface into the system 290, a low pressure water pipe 294 configured to drain waste water back to a sump, a high pressure water pipe 296 that contains particles to be lifted to the surface, an inlet pipe 298 for low pressure water with particles, and a multi-chamber device 300 with valves 302 for regulating and controlling the flow of water flowing through the water pipes. During operation, the first chamber 304 waits to rise, the second chamber 306 performs the rise; wherein the second chamber 306 carries out the lifting by means of a high pressure injection system, and the third chamber 308 carries out the loading of the particles. Waste water will flow back to the sump through the water pipe 294. All 302 valves are actuated in a precisely controlled timing sequence to ensure smooth flow through the system. The high pressure water that contains the particles will be lifted to the surface through pipe 296. This system does not require a sinking bucket as all drilling particles will be lifted by the hydraulic lift system 290. This system 290 will be fully attached to one of the tiers 226 as shown, and so that as the shaft enlargement assembly 150 advances, the hydraulic lift system 290 also advances, thereby ensuring continuous movement.

Turning now to FIG. 22 and 23, the drilling system 152 includes a pipe running device 310, the pipes 312 typically including supply pipes such as water pipes and ventilation pipes. The pipe running device 310 includes a hanging mast 314 that can be mounted on top of the upper support assembly 206 to raise and lower at least one pipe 312 (but typically a plurality of pipes 312, as shown in FIG. 23). Guide means 316 is provided, comprising a plurality of rotatable roller bearings 318 that form a rounded recess 320 for receiving the outer rounded portion of the pipe 312. Thus, when the pipes 312 are raised and lowered, a pair of adjacent roller bearings 318 positions the pipe 312 to guide the movement of the pipe. between them.

Claims (46)

1. A shaft expansion assembly for a drilling system, wherein the shaft expansion assembly comprises: a hollow string proximate the lower end of the drilling system, the hollow string comprising an upper section, a middle section, a lower section, and a telescoping portion that is axially movable relative to the remaining portions of the hollow string; an expander section comprising a downwardly tapering first cutting head assembly that is rotatably mounted on a hollow column, with a first drive means configured to rotate the first cutting head assembly relative to the hollow column so as to drill down a hole having a diameter corresponding to that of the first cutting head layout; a drill head assembly coupled to a working lower end of the telescoping portion of the hollow string, the drill head assembly ending in a downwardly tapering second cutting head assembly to drill a guide or pilot hole having a diameter that is less than that of the first cutting head assembly as the drill the system continues to drill down, with the drilling head assembly releasably attached to the working lower end of the hollow string so that it can be separated from the rest of the assembly to expand the shaft if necessary; an axial movement section configured to advance the drill head assembly relative to the expansion section; And a spacer assembly configured to fix the assembly to expand the shaft inside the drilled pit and control the movement of the drilling head assembly relative to the expansion section, wherein the drilling system comprises a plurality of auxiliary platforms disposed above the shaft expansion assembly within the hole drilled by the first cutting head assembly, the shaft expansion assembly being separable from the plurality of auxiliary platforms. 2. The arrangement for expanding the shaft according to claim 1, characterized in that the first arrangement of the cutting head contains a support element supporting the first bladed arrangement, and the abutment element is mounted for rotation around the hollow column, and the first bladed arrangement contains a plurality of blades attached to support element, and each blade contains an inclined or extending in the transverse direction of the support beam, which is installed or which contains a plurality of first cutting elements. 3. The arrangement for expanding the shaft according to claim. 1 or 2, characterized in that at least one collector channel is made in the hollow column below the first assembly of the cutting head, in which drill cuttings can be collected, which is formed during the rotation of the first assembly of the cutting head, and the collector channel defines an inlet for receiving drill cuttings, an outlet through which the drill cuttings can exit the channel into the hollow string, and a downward angled passage is provided between the inlet and the outlet to facilitate the passage of drill cuttings into the hollow string under the action of gravity, for subsequent collection in a tunneling bucket moved up and down the hollow column. 4. A shaft expansion arrangement according to any one of the preceding claims, characterized in that a plurality of auxiliary platforms are connected to a hollow column above the shaft expansion arrangement in a hole drilled by the first cutting head assembly, the drilling system further comprising an above ground drilling derrick support structure and the design of the headframe, containing: a winch for moving the assembly to expand the shaft up and down, as needed, inside the drilled hole by means of cables; a bucket elevator for moving the tunneling bucket up and down through the hollow column, also by means of cables passing between the bucket elevator and the tunneling bucket; And platform lift to move multiple auxiliary platforms up and down as needed, wherein the shaft expansion assembly is detachable from the plurality of auxiliary platforms, so that the shaft expansion assembly and the auxiliary platforms can be raised and lowered separately. 5. A shaft expansion arrangement according to any one of the preceding claims, characterized in that the spacer arrangement is coupled to a hollow column, the spacer arrangement comprising a first row of circumferentially distributed base plates located between the first cutting head assembly and the axial movement section, wherein a second row of circumferentially distributed base plates is located between the axial movement section and the second cutting head assembly. 6. Shaft expansion arrangement according to any one of the preceding claims, characterized in that the lower telescoping section of the hollow column is axially movable relative to the rest of the hollow column by means of a third actuator arrangement in the form of a plurality of axial movement hydraulic cylinders to form an axial movement section to allow the drilling head assembly to advance relative to the expansion section. 7. The arrangement for expanding the shaft according to claim 5, characterized in that the first row of base plates extends from the middle section of the hollow column and through the outer safety casing, the second row of base plates extends from the lower telescopic section of the hollow column and through the outer safety casing, the support the plates are movable by the first and second actuator arrangements, respectively, between a retracted disengagement position and an extended engagement position, in which the plates engage with a guide pit formed by the second cutting head arrangement to promote rotation of the first cutting head arrangement and/or manage it. 8. Shaft expansion arrangement according to any one of the preceding claims, characterized in that the second cutting head arrangement comprises a support element supporting the second blade arrangement, the support element being rotatable relative to the support housing from which it emerges. 9. The arrangement for expanding the mine shaft according to claim 8, characterized in that the second blade arrangement contains a plurality of blades attached to the support element, and each blade contains an inclined or transversely extending arm of the blade, on which are mounted or which contains a plurality of second cutting elements, and the second drive means is configured to drive the support element and the second layout of the cutting head. 10. The shaft expansion arrangement of claim 9, wherein the fourth actuators are configured to move the blade arms relative to the support member between an extended working V-configuration to facilitate drilling and a folded, aligned configuration to allow separation of the second cutting head assembly. from the rest of the layout to expand the shaft and raise it through a hollow column to the surface. 11. The layout for expanding the shaft according to any one of paragraphs. 1-5, characterized in that the layout of the drilling head contains a drilling head with a drilling fluid supply in the form of a truncated cone, containing a drilling fluid supply pump, and the drilling head with the drilling mud supply has a tapering side wall ending in an end surface, and the tapering side wall and /or the end face is connected to the second cutting head assembly to drill a pilot hole as the drilling system moves down. 12. The arrangement for expanding the shaft according to claim. 11, characterized in that the section of the drill head with the supply of drilling mud can be separated and removed from the drill head with the supply of drilling mud, and the section removed from the drill head with the supply of drilling mud contains at least an end face and a mud pump. 13. The arrangement for expanding the shaft according to claim 12, characterized in that the second arrangement of the cutting head is equipped with or contains a plurality of second cutting elements containing a working surface from which a plurality of rows of carbide inserts extend, moreover, the plurality of rows of carbide inserts are made with the possibility of limiting the size of drill cuttings below a predetermined size, the second cutting elements are placed with the possibility of rotation inside the cavity, the rows of carbide inserts are located at a distance of 25 mm from each other, which ensures that the size of the cuttings formed due to the interaction between the carbide inserts and the cutting surface is 25 mm. 14. The arrangement for expanding the shaft according to claim 13, characterized in that the working surface of each second cutting element is located at a distance of 50 mm from the cutting surface. 15. A drilling system comprising a shaft expansion assembly, wherein the shaft expansion assembly comprises: a hollow string proximate the lower end of the drilling system, the hollow string being configured to receive a tunneling bucket moved up and down the hollow string; an expander section comprising a downwardly tapering first cutting head assembly that is rotatably mounted on a hollow column, with a first drive means configured to rotate the first cutting head assembly relative to the hollow column so as to drill down a hole having a diameter corresponding to that of the first cutting head layout; a drill head assembly coupled to the working lower end of the hollow string, the drill head assembly ending in a downwardly tapering second cutting head assembly to drill a guide or pilot hole having a diameter that is less than that of the first cutting head assembly as the assembly is to expand the mine shaft continues drilling down; an axial movement section configured to advance the drill head assembly relative to the expansion section; And a spacer assembly configured to fix the assembly to expand the shaft inside the drilled pit and control the movement of the drilling head assembly relative to the expansion section, wherein the drilling system further comprises: a plurality of auxiliary platforms located above the assembly for expanding the shaft inside the hole drilled by the first assembly of the cutting head, and an elevated support structure of a drilling rig and a structure of an overhead headframe, comprising: a winch for moving the shaft expansion assembly up and down as needed within the drilled hole by means of cables passing between the winch and the shaft expansion assembly; a bucket elevator for moving the tunneling bucket up and down through the hollow column, also by means of cables passing between the bucket elevator and the tunneling bucket; And a platform lift for moving the plurality of auxiliary platforms up and down to separate the auxiliary platforms from the assembly to expand the shaft as needed. 16. The drilling system according to claim 15, characterized in that a movable service platform is provided above the plurality of auxiliary platforms, to which a traverse is attached or which is configured to attach a traverse, and the movable service platform can be raised, separated and temporarily placed inside the structure of the overhead copra to allow the use of a traverse to grab a component or element inside a mine shaft and lift it to the surface. 17. The drilling system according to claim. 15 or 16, characterized in that one of the auxiliary platforms contains a lifting device, and the lifting device includes a pump and an arc screen, and the arc screen receives cuttings water injected through the pipeline by means of a drilling fluid supply pump located nearby with a drilling head arrangement, whereby the cuttings water is then separated and the harder components/cut rock are discharged into a tunneling bucket via a sliding chute. 18. Drilling system according to any one of the preceding paragraphs. 15–17, characterized in that one of the auxiliary platforms contains a vacuum system for sucking dry broken rock and drill cuttings into a vacuum tank, and dry material is then unloaded from the vacuum tank through a retractable chute into a sinking tub, which can then be raised to the surface. 19. Drilling system according to any one of the preceding paragraphs. 15-18, characterized in that one of the auxiliary platforms contains a lifting device containing: a high pressure water pipe for receiving water from the surface; a low pressure water pipe configured to drain waste water back to the sump; a high pressure water pipe that contains particles to be brought to the surface; inlet pipe for low pressure water with particles; And multi-chamber device with valves for regulating and controlling the flow of water flowing through water pipes. 20. Drilling system according to any one of the preceding paragraphs. 15-19, characterized in that it contains a device for lowering and lowering pipes, and the device for lowering or lowering pipes contains a suspended tower for lifting and lowering at least one pipe, and a guide means containing a plurality of rotatable roller bearings, which contain a rounded recess for receiving the outer rounded part of the pipe, so that when the pipes are raised and lowered, a pair of adjacent roller bearings will place the pipe to guide the movement of the pipe between them.

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