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AU2015258233B2 - An apparatus for forming an underground tunnel - Google Patents

An apparatus for forming an underground tunnel Download PDF

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Publication number
AU2015258233B2
AU2015258233B2 AU2015258233A AU2015258233A AU2015258233B2 AU 2015258233 B2 AU2015258233 B2 AU 2015258233B2 AU 2015258233 A AU2015258233 A AU 2015258233A AU 2015258233 A AU2015258233 A AU 2015258233A AU 2015258233 B2 AU2015258233 B2 AU 2015258233B2
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Australia
Prior art keywords
tunnel
cutting head
support structure
conveyor
during
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AU2015258233A
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AU2015258233A1 (en
Inventor
Matthew Lumb
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Individual
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Priority claimed from AU2007906904A external-priority patent/AU2007906904A0/en
Priority claimed from AU2008338242A external-priority patent/AU2008338242A1/en
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Priority to AU2015258233A priority Critical patent/AU2015258233B2/en
Publication of AU2015258233A1 publication Critical patent/AU2015258233A1/en
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Abstract

- 30 The present disclosure provides an apparatus for forming an underground tunnel. The apparatus comprises a cutting 5 head for removing material from a wall portion of the tunnel and thereby forming a portion of the tunnel. Further, the apparatus comprises a support structure for supporting a previously formed portion of the tunnel. The support structure is arranged to provide a supporting 10 force against a surface of the tunnel when stationary and when being moved along the tunnel. Further, the apparatus comprises a conveyor for conveying removed material from the cutting head to a location remote from the cutting head during formation of the portion of the tunnel. 7137359_1 (GHMatters) P64494.AU.2 JMEAD \op,

Description

1 2015258233 18 Nov 2015
AN APPARATUS FOR FORMING AN UNDERGROUND TUNNEL FIELD OF THE INVENTION 5 The present invention relates to an apparatus for forming an underground tunnel.
BACKGROUND OF THE INVENTION 10 Structures for supporting the inner surface of a mining tunnel, particularly the roof, have been used for some time. These structures prevent tunnels from caving-in due to forces exerted on the tunnel by the surrounding environment. 15 A section of the tunnel is cut by a cutting head, which is then stopped and the support structure is erected. Consequently, typical machinery for cutting mining tunnels operates in a "start-stop" fashion. 20
The start-stop procedure of driving a tunnel continues as the tunnel is being progressed. Positioning and adjusting of existing support structures is also required and can be very time consuming. 25
Further, the accumulation of cut material in the tunnel also slows down the cutting of the tunnel. Once a section of the tunnel is cut, the cutting machinery is stopped and the accumulated cut material is moved away. 30
There is a need for technological advancement.
7137359.1 (GHMallers) P64494.AU.2 JMEAD 2 2015258233 18 Nov 2015
SUMMARY OF THE INVENTION
The present invention provides in a first aspect an apparatus for forming an underground tunnel, the apparatus 5 comprising: a cutting head for removing material from an end-face of the tunnel and thereby forming a further portion of the tunnel; machinery for operating the cutting head being at 10 least partially positioned at a location remote from the cutting head; a member coupled to the cutting head and arranged to push the cutting head against the end-face of the tunnel during removal of the material; 15 a support structure for supporting a previously formed portion of the tunnel by providing a supporting force against a surface of the tunnel, the support structure comprising a plurality of supporting parts, wherein each supporting part is arranged to exert a 20 supporting force and is drivable to move along a surface of the tunnel in a manner such that the supporting force is maintained during movement relative to the surface of the tunnel, the support structure further comprising a bolting machine for installing bolts into the surface of 25 the tunnel wherein the support structure is arranged such that bolts can be placed at or near a location of a supporting part during formation of the further portion of the tunnel; and a conveyor for conveying removed material to a 30 location remote from the cutting head during formation of the further portion of the tunnel; wherein the apparatus is arranged so that a space is provided at or immediately behind the cutting head so
7137359.1 (GHMatters) P64494.AU.2 JMEAD 3 2015258233 18 Nov 2015 that the support structure, or a portion thereof, during removal of the material by the cutting head, is movable to a position immediately behind the cutting head, without restricting movement of the cutting head in a direction 5 that is transversal to a direction of movement of the support structure or the portion thereof, and wherein the cutting head is movable independently from the support structure and in a direction into the tunnel. 10 Throughout this specification the term "cutting head" is used to refer broadly to a head that is arranged for removing the material by drilling, grinding, cutting, or any other suitable technique. 15 Throughout this specification the term "tunnel" is used for any type of tunnel also including a branch tunnel, such a tunnel that branches off another tunnel.
The underground tunnel typically is not in an open pit environment however the tunnel may commence in an open pit 20 environment and may be located many tens, a hundred or even more metres below a ground plane. The tunnel may for example be a roadway. The tunnel may be formed in hard earth, rock, coal or an ore. 25 The apparatus typically is arranged to form a tunnel having a cross-sectional area of the order of 10 to 25m2.
The member may comprise a hydraulic arrangement and typically is provided in the form of a "push beam". The 30 member typically comprises an anchoring structure that in use provides a basis for pushing the cutting head against the end-face of the tunnel. Alternatively, the support structure may comprise a mount for mounting the member.
7137359.1 (GHMatters) P64494.AU.2 JMEAD 4 2015258233 18 Nov 2015
The member typically is arranged so that the cutting head is movable independently from the support structure in a direction along the underground tunnel. 5 Further, the cutting head typically is arranged, and at least a portion of the machinery is positioned, so that a space is provided at or immediately behind the cutting head in a manner such that the probability that accumulated cut material requires interruption of tunnel 10 formation is reduced.
The apparatus typically is arranged so that in use the support structure, or a portion thereof, during removal of the material by the cutting head, is movable to a position 15 immediately behind a coupling of the cutting head within 0.5 - 5 m of the cutting head, without restricting movement of the cutting head in a direction that is transversal to a direction of movement of the support structure or the portion thereof. 20
In one specific embodiment the conveyor is arranged to enable conveying of the removed material along the tunnel to a suitable location in a manner such that inhibiting of formation of the portion of the tunnel, or the entire 25 tunnel, due to accumulated removed material is avoided.
The support structure typically comprises a void area through which in use the removed material is transported. In one example, a portion of the member and/or a portion 30 of the conveyor are positioned within the void area.
The apparatus typically is arranged so that in use removed material is continuously conveyed away from the cutting
7137359.1 (GHMalters) P64494.AU.2 JMEAD 5 2015258233 18 Nov 2015 head.
The support structure may comprise a plurality of supporting parts, such as a series of the supporting 5 parts. Each supporting part typically is arranged to exert a supporting force and move along the surface in a manner such that the supporting force is maintained during movement relative to the surface of the tunnel. 10 Each supporting part typically comprises a drive and typically is drivable, either automatically controlled by a distance measurement device or manually controlled by a driver . 15 The supporting parts typically are spaced apart from each other at a distance which permits support bolts to pass there between.
Throughout this specification, the term "bolt" (and 20 variations thereof) is used to refer to a member, such as a steel member, that is put in place to provide a permanent support for the surface of the tunnel.
The apparatus according to embodiments of the present 25 invention provides a supporting force, conveys material away from the cutting head and is arranged for placing support bolts during formation of the tunnel and during movement of the apparatus along the tunnel. Consequently, time delay associated with the "start-stop" progression 30 technique of known apparatus can be avoided or reduced and the apparatus according to embodiments of the present invention enables formation of the tunnel at relatively high average speed.
7137359.1 (GHMatters) P64494.AU.2 JMEAD 6 2015258233 18 Nov 2015
The apparatus may comprise a coupling that couples the cutting head to a portion of the apparatus, typically the member, and that comprises an arrangement, such as a 5 hydraulic arrangement, that enables pivoting the cutting head relative to the portion of the apparatus.
The apparatus may be arranged for pivoting the cutting head in a horizontal plane. In addition, the apparatus may 10 be arranged for pivoting the cutting head in a vertical plane or in any other plane. Consequently, the apparatus according to an embodiment of the present invention provides the advantage that non-straight sections of the tunnel can be formed. 15
The conveyor typically comprises conveyor elements that are movable relative to each other and typically are pivotable relative to each other. For example, a first conveyor element may comprise a portion that overlaps a 20 portion of an adjacent second conveyor element and that is in use positioned behind the first conveyor element during forming of the tunnel. In one specific embodiment the conveyor comprises a series of conveyor elements and each conveyor element has a portion that is overlapped with a 25 portion of an adjacent conveyor element.
In one specific embodiment of the present invention at least a portion of the machinery for operating the cutting head is in use positioned at a location remote to the 30 cutting head, for example at a distance of up to 5m, 10m, 50m, 100m or more along the tunnel behind the cutting head.
7137359_1 (GHMallers) PS4494.AU.2 JMEAD 7 2015258233 18 Nov 2015
In one example, the cutting head is driven by a hydraulic motor or an electric motor that may be positioned in or adjacent the cutting head. A device for generating the hydraulic pressure for operating the hydraulic motor 5 and/or the hydraulic arrangement for pushing the cutting head typically is in use positioned at the position remote from the cutting head, such as 5m, 10m, 50m, 100m or more along the tunnel behind the cutting head. Consequently, the apparatus according to embodiments of the present 10 invention provides the advantage of increased space at the cutting head or immediately behind the cutting head, which further reduces the probability that accumulated cut material requires a "stop" during formation of the tunnel thus increasing space to facilitate use of higher 15 efficiency driving equipment including automatic bolters.
Each of the supporting parts may comprise spaced apart wheels, a belt mounted on the wheels and guides arranged to retain the belt on the wheels. The support structure 20 may be arranged to exert the supporting force against a roof and/or a side of the tunnel.
The member may comprise an interior that is enclosed at side and top portions and may also comprise a closed 25 bottom portion. The member may be arranged for conveying cut material away from the cutting head through the interior of the member.
The apparatus may comprise a ventilation system that uses 30 the member as a duct for sucking or blowing gases and dust from a workplace or cutting face and wherein the apparatus may be arranged for ventilating a workplace using the ventilation system.
7137359.1 (GHMatters) PS4494.AU.2 JMEAD 8 2015258233 18 Nov 2015
The apparatus may be arranged for introducing explosion prevention materials into the interior of the member during conveying of the cut material through the interior of the member. 5
The apparatus may comprise a steering unit for steering at least one of the cutting head, the member and a pushing unit for pushing the member. 10 The present invention provides in a second aspect a method of forming an underground tunnel, the method comprising: pushing a cutting head against an end-face of the underground tunnel; removing material from the end-face of the 15 underground tunnel using the cutting head and thereby forming a further portion of the underground tunnel; moving the cutting head into the tunnel as formation of the tunnel progresses; supporting a previously formed portion of the 20 underground tunnel using a support structure, the support structure comprising a plurality of supporting parts wherein each supporting part is arranged to exert a supporting force and is drivable to move along a surface of the underground tunnel in a manner such that the 25 supporting force is maintained during movement relative to the surface of the tunnel; moving the support structure, or a portion thereof, to a position at or immediately behind the cutting head, without restricting movement of the cutting 30 head in a direction that is transversal to direction of movement of the support structure or the portion thereof wherein the cutting head is moveable independently from the support structure; and
7137359.1 (GHMallers) PS4494.AU.2 JMEAD 9 2015258233 18 Nov 2015 conveying removed material to a location remote from the cutting head during formation of the underground tunnel. 5 The movement of the cutting head typically is independent from the movement of the support structure.
The step of supporting the previously formed portion of the underground tunnel using a support structure, 10 typically comprises providing the supporting force during movement of the support structure along the tunnel including a position within 0.5 - 5 m behind the cutting head. 15 The method typically comprises pushing the cutting head against the end-face of the underground tunnel using a member, such a as a push beam, that may be anchored at the tunnel. The method typically comprises moving the cutting head relative to an anchoring of the member using a 20 hydraulic arrangement.
The step of moving the support structure, or a portion thereof, typically comprises checking a location of the cutting head relative to the support structure, or a part 25 thereof, and driving at least a portion of the support structure during removal of the material by the cutting head so that the support structure is positioned immediately behind the cutting head without restricting movement of the cutting head in a direction that is 30 transversal to direction of movement of the support structure .
Checking the location of the cutting head may be performed
7137359.1 (GHMatters) P64494.AU.2 JMEAD 10 2015258233 18 Nov 2015 visually or with the aid of a distance measurement device.
The method typically comprises placing support bolts during movement of at least a portion of the support 5 structure and during removal of the material by the cutting head in a manner such that formation of the tunnel does not have to be interrupted for the placement of the bolts . 10 The method may also comprise the step of extending the conveyor during advancement of the portion of the tunnel.
The method typically comprises the additional step of extending an effective length of a conveyor during 15 conveying of removed material by that conveyor. This additional step typically is conducted so that formation of the tunnel is possible without interruption and during extension of the length of the conveyor. 20 Extending the effective length of the conveyor typically comprises extending the path-length of a conveyor belt along a portion of a conveyor belt loop at which the conveyor belt in use does not convey removed material.
For example, the step of extending the effective length of 25 the conveyor may comprise tilting guiding idlers at a top conveyor strand at an end-portion of the conveyor so that the conveyor belt has a trough-like cross-sectional shape at the end-portion and a reduced width, which facilitates access and positioning of additional guiding elements 30 required for the extension of the effective length of the conveyor.
In one embodiment the method comprises ventilating a
7137359.1 (GHMatters) P64494.AU.2 JMEAD 11 2015258233 18 Nov 2015 workplace, such as a workplace positioned on the member, using a ventilation system that uses the member as a duct for sucking or blowing gases and dust from the workplace. 5 The method may also comprise introducing an explosion preventing medium into the interior of the member.
The member may have an interior that is enclosed at side and top portions and the method may comprise conveying 10 material from the cutting head through the interior of the member .
The method may comprise using the member as a working platform. 15
The method may also comprise steering at least one of the cutting head, the member and a pushing unit.
The invention will be more fully understood from the 20 following description of specific embodiments of the invention. The description is provided with reference to the accompanying drawings.
Brief Description of the Drawings 25
Figures 1 illustrates an apparatus for forming an underground tunnel according to a specific embodiment of the present invention;
Figure 2 illustrates an apparatus for forming an 30 underground tunnel according to a further embodiment of the present invention; and
Figures 3 to 5 illustrate components of the apparatus for forming an underground tunnel according to a 7137359_1 (GHMatters) P64494.AU.2 JMEAD 12 2015258233 18 Nov 2015 specific embodiment of the present invention.
Detailed Description of Specific Embodiments 5 Referring initially to Figure 1, an apparatus and a method for forming an underground tunnel according a specific embodiment of the present invention are now described. In this embodiment the tunnel is formed in an underground environment and may form a part of a mine. 10
Figure 1 shows the apparatus 100 comprising a cutting head 102 for removing material from an end-face of the tunnel and thereby advancing the tunnel. The end-face may comprise hard earth, rock or an ore. In this embodiment 15 the cutting head 102 is arranged for removing the material by grinding. Alternatively, the cutting head 102 may be arranged for removing the material by cutting, drilling or any other suitable technique. 20 The apparatus 100 also comprises a push-beam 104 with coupling 105 and a support structure 106. The cutting head 102 is coupled to the push beam 104 by the coupling 105 so that the cutting head 102 can be moved in horizontal and vertical directions. Consequently, the apparatus 100 is 25 arranged for forming tunnels having bent portions. When the apparatus is positioned in a tunnel portion for advancement of the tunnel, mechanisms and controls for the steering of the apparatus can be added along the length of the push beams, at a pushing station or at the cutting 30 head at the face.
An end-portion of the push beam 104 is anchored into a wall portion of the tunnel to provide a basis for pushing 7137359_1 (GHMatters) PS4494.AU.2 JMEAD 13 2015258233 18 Nov 2015 the cutting head 102 against the end-face of the tunnel during removal of the material. The push beam 104 comprises a hydraulic arrangement that allows movement of cutting head into the tunnel while the tunnel advances. 5 When the tunnel is advanced to a predetermined depth, the push beam is removed from the anchoring and re-anchored at a position deeper in the tunnel. The hydraulic arrangement is initially retracted so that a further tunnel portion may be formed without interruption using the hydraulic 10 arrangement and moving the support structure 106 accordingly.
In a variation of the described embodiment the push beam 104 may also be anchored at one of the support structure 15 106. However, in any case the push beam typically is arranged so that the cutting head 102 and the support structures 106 are movable independently.
In this embodiment the cutting head 102 comprises an 20 electric motor. Alternatively, the cutting head may comprise a hydraulic motor. A device for generating the hydraulic pressure for operating the hydraulic motor and/or the hydraulic arrangement of the push beam 104 is located at a position remote from the cutting head 102, 25 such as at a suitable location behind the support structure 106.
The push beam 104 is positioned within the support structure 106 and comprises an outer housing within which 30 two augers or other conveying devices such as a belt or chain conveyor are positioned. The apparatus 100 also comprises a conveyer (not shown in Figure 1) that is arranged to convey material that was removed by the
7137359_1 (GHMatters) P64494.AU.2 JMEAD 14 2015258233 18 Nov 2015 cutting head 102. The removed material is collected from an end-portion of the push beam 104.
The push beam 104 provides a rigid structure that 5 transfers a force required to push the cutting head against an uncut face of the tunnel and thereby, with the rotation of the cutting head, excavate at the uncut face area. The push beam 104 also acts as a dead weight to pull a pushing mechanism and the overlap structure at the end 10 of the belt conveyor forward to allow it to be reset.
Further, the push beam 104 is arranged to provide a safe enclosure for enclosing a mineral conveying system positioned in the push beam 104 to prevent harm to persons working in the area. The push beam 104 also provides a 15 sturdy base for the addition of a potential dedicated robust ventilation duct within the push beam 104 with means to allow the periodical or continuous addition of explosion suppressant material such as stone dust.
Further, the push beam 104 is arranged for mounting of 20 ventilation fans (where necessary), adapters and scrubbing equipment to create a safe work environment.
The support structure 106 comprises support parts 108.
Each support part 108 is arranged to support a roof and 25 side portions of the formed tunnel and for moving behind the cutting head 102 in a manner such that a supported force is maintained during the movement. The support parts 108 will be described in further detail below with reference to Figure 4. 30
Further, the apparatus 100 comprises a device for placing bolts (not shown in Figure 1). The bolts are placed in wall portions of the formed tunnel and are arranged to 7137359_1 (GHMatters) P64494.AU.2 JMEAD 15 2015258233 18 Nov 2015 provide sufficient support if the support parts 108 have moved past a formed portion of the tunnel and consequently no longer provide the supporting force. Each support part 104 is arranged so that support bolts may be placed during 5 movement of the support part 104.
The apparatus 100 has the advantage that the support structure 106 provides a supporting force during movement of the support structure 106. Bolts can be positioned 10 during advancement of the tunnel and the material that is removed by the cutting head 102 is continuously conveyed away from the cutting head 102. Further, the apparatus 100 is arranged so that at least a portion of the machinery for operation of the cutting head 102, such as the drive 15 that provides the hydraulic pressure for the hydraulic arrangement of the push beam 104, is located remote from the cutting head 102 so that the available space at the cutting head 102 is increased. Consequently, the apparatus 100 according to an embodiment of the present invention 20 has the significant commercial advantage that at least for the formation of a straight section "start-stop" operation of the apparatus 100 can be avoided or reduced and the tunnel can be formed at a relatively high average speed. 25 For formation of bent tunnel portions the advancement of the tunnel may be interrupted for a short period of time until the support part are moved along a bent portion of the tunnel. Alternatively, the support parts 108 may also be arranged to move around the bent during operation of 30 the cutting head 102 and while maintaining the supporting force to support the roof. For example, the elements 108 may be arranged so that, if they also support for side-portions of the tunnel, momentarily the side supporting
7137359_1 (GHMatters) P64494.AU.2 JMEAD 16 2015258233 18 Nov 2015 elements are retracted to reduce the width of the support parts 108 and enable movement of the support parts 108 around the bend. 5 Figure 2 shows a schematic illustration of the components of the apparatus for forming an underground tunnel. The shown apparatus 200 comprises a cutting head 202 for removing the material and a push beam 204 for supporting the cutting head 202 and moving material away from the 10 cutting head 202. Further, the apparatus 200 comprises a means for steering the push beam (not shown) and pushing the push beam 204 in a forward direction. A conveyer element 208 is arranged to collect the removed material form the push beam 204 and to covey the collected removed 15 material to another conveyer element 210. In this embodiment, a portion of the push beam 204 penetrates through a support structure (not shown), such as the support structure 106 illustrated in Figure 1. 20 The support 206 is arranged for anchoring in the tunnel to provide a basis for pushing the cutting head 202 against the end-face of the tunnel. The support 206 comprises anchoring means, for example provided in the form of suitable hydraulic jacks, which secure the support 206 25 relative to wall portion of the tunnel. Once the cutting head 202 and push beam 204 have advanced as far as possible, then an arrangement for releasing the anchoring means and moving the support structure 206 with the anchoring means along the tunnel is used. The arrangement 30 for releasing the anchoring means and moving support structure 206 may comprise alternately operable pairs of hydraulic rams clamping to the wall, floor or roof portions of the tunnel.
7137359_1 (GHMallers) PS4494.AU.2 JMEAD 17 2015258233 18 Nov 2015
The arrangement for releasing the anchoring means and moving the support structure 206 may also comprise a means for the prevention of push beam lifting during times of 5 excessive force being supplied from the pushing unit.
The conveyer elements 208 and 210 are movable relative to the push beam 204 and comprise overlapping portions. For example, the conveyor element 208 may be a chain conveyor 10 and the conveyor element 210 may be a belt conveyor that may have a length much longer than the chain conveyor 208. The conveyor elements 208 and 210 are movable relative to each other about a vertical axis that this located at the overlapping region. In this case the conveyor elements 208 15 and 210 are arranged so that the removed material may be conveyed along a bent portion of the tunnel.
It is to be appreciated that in variations of the described embodiments the apparatus 200 may alternatively 20 comprise only one conveyor element. Further, the apparatus 200 may comprise any number of conveyor elements that may or may not be movable relative to the push-beam 204.
The conveyor is arranged so that the conveyor can be 25 extended during advancement of the tunnel by extending the length of the conveyor element 210.
The conveyor element 210 typically is arranged to provide sufficient space to enable operators to extend the 30 conveyor element 210 during operation. For example, the conveyor element 210 may comprise idlers that guide a conveyor belt and that are adjustable. Such adjustable idlers may be positioned at the "outbye" tail ends of the
7137359.1 (GHMatters) PS4494.AU.2 JMEAD 18 2015258233 18 Nov 2015 conveyor element 210. The idlers may be adjusted so that at the outbye end the conveyor belt is directed over angled idlers so that the conveyor belt has a trough-like cross-sectional shape and a narrower footprint in the area 5 where conveyor belt frames are to be installed. The narrower footprint provides space for placing additional support brackets and guiding members required for guiding an extended length of the conveyor belt. 10 As the and cutting head 202 and the push beam 204 advance forward, the effective length of the conveyor belt is extended. For example, the effective length of the conveyor belt may be extended by releasing additional conveyor belt from a loop of conveyor belt of a device 15 that is arranged to keep the tension of the conveyor belt largely constant. The deeper "troughing" idlers move forward with the conveyor belt tail end and the conveyor belt ramps down to run on the now installed conveyor belt frames. This set-up enables the extension of the effective 20 conveyor belt length without interrupting the cutting process and during conveying of removed material. A formed tunnel may have a length of a few hundred meters or even a few kilometers. The apparatus 200 may comprise a 25 support structure, such as the support structure 106, which may comprise any number of support parts. The apparatus 200 may comprise any number of conveyer elements, such as conveyor elements 208 and 210, which are arranged so that each conveyer element overlaps the 30 portion of an adjacent conveyer element whereby transport of removed material from one conveyer element to an adjacent conveyer element is facilitated.
713735SM (GHMatters) P64494.AU.2 JMEAD 19 2015258233 18 Nov 2015
The cutting of through-cuts between parallel tunnels (roadways) can be conducted using the apparatus 100 or 200 in the described manner. Alternatively, the apparatus 100 or 200 may also comprise an additional, usually shorter, 5 push-beam and normally wider cutting head for cutting such through-cuts. For example, the additional push-beam and cutting head assembly may be mounted on the push beam 104. Hydraulic bolters or other types of bolters may be mounted on this unit to permanently support the roof and side-10 portions of the tunnel.
All ventilation and electrical and mechanical service devices can also be mounted on the push beam 104 or 204. Supply of consumables and any material that is used during 15 operation of the apparatus 100 or 200 can be provided by monorail.
Guidance of the cutting head 102 head may for example be provided using a gamma-ray monitor to detect the roof and 20 floor of the tunnel or using any other from of guidance system, for example a guidance system that is arranged for inertial guidance.
It is to be appreciated by a person skilled in the art 25 that alternatively the conveyor may take any other suitable form.
Figure 3 shows schematically a coupling 300 for coupling the cutting head, such as the cutting head 102 shown in 30 Figure 1, to the push-beam, such as the push-beam 104 also shown in Figure 1. The coupling 300 comprises a plurality of sections 304 that are coupled by hydraulic elements 302 having a length that is controllable by a hydraulic
7137359_1 (GHMallers) PS4494.AU.2 JMEAD 20 2015258233 18 Nov 2015 pressure applied to the elements 302. By controlling the hydraulic pressure it is possible to bend the coupling 300 in a horizontal plane so that tunnels with left hand or right hand bends may be formed. The sections 304 have 5 overlapping portions along which the removed material moves towards the push-beam. The coupling 300 also comprises a similar hydraulic arrangement that allows bending of the coupling 300 in a vertical direction (not shown in Figure 3). 10
Referring now to Figure 4, a support structure 400 is now described in further detail. For example, the support structure 400 may replace the support structure 106 shown in Figure 1. The support structure 400 comprises support 15 parts 402, which have frames that are made from a material that is capable of carrying the load that is exerted by the surface of the tunnel. The various parts of each support part 402 are welded and/or bolted together. The frames have two main spaced apart outer sections 403 and 20 405, which define a void 406 located therebetween. The void 406 is such that it is capable of housing the push beam a portion of the conveyor and other mining equipment.
The support structure 400 includes a bolting machine 408 25 for installing bolts into the tunnel surface as the support structure 400 moves along the tunnel. The machine 408 is arranged to install side and roof bolts independently. The machine 408 is mounted on rotary actuators (not shown) so that the position of the bolts 30 can be varied as required.
The apparatus 400 has spaced apart portions 412 for placement on the floor of the tunnel, and which carry the 713735SM (GHMatters) P64494.AU.2 JMEAD 21 2015258233 18 Nov 2015 support structure 400. As can be seen in Figure 4, the spaced apart portions 412 are attached to the support parts 402 at the corners thereof. The apparatus 400 also has parts 414 that are located on top of the support 5 structure 400 and which bear against the roof of the tunnel so as to exert a supporting force.
The space between parallel parts 414 is such that it can accommodate the end of bolts that have been installed into 10 the roof so as to avoid contact between the parts 414 and the end of the bolts as the support structure 400 moves along the tunnel.
The portions 412 and 414 each include a belt that is 15 mounted on spaced apart wheels. The belts and the wheels effectively form what is generally referred to as a 'caterpillar track', which is commonly found on many excavators and tanks. By using the belts mounted on the wheels, the portions 412 and 414 are able to readily move 20 along the surface of the tunnel, thus permitting the apparatus 400 to be moved whilst supporting the surface of the tunnel.
The portions 412 and 414 comprise drives that are 25 controllable by a driver. The support parts 412 and 414 are driven so that one of the portions 412 and 414 is positioned immediately behind a coupling of the cutting head 102, typically within 0.5 - 5 m of the cutting head, without restricting movement of the cutting head in a 30 direction that is transversal to direction of movement of the support structure or the portion thereof. During operation the driver frequently checks how far the cutting head progresses and moves the portion 412 and 414
7137359_1 (GHMatters) P64494.AU.2 JMEAD 22 2015258233 18 Nov 2015 accordingly. One or more portions 412and 414 typically follow. The support bolts are positioned during movement of the parts 412 and 414 so that the tunnel can be formed largely without interruptions. 5
The portions 414 also include accommodating means for allowing unevennesses which may be present in the surfaces of the tunnel to be accommodated. The accommodating means is provided by virtue of the belts being flexible. 10
Further details of the support structure are disclosed in PCT international application number PCT/AU2003/001251, which is hereby incorporated by cross-reference. 15 The reference that is being made to PCT international application number PCT/AU2003/001251 does not constitute an admission that the PCT international application number PCT/AU2003/001251 is part of the common general knowledge in Australia or any other country. 20
It is to be appreciated that the present invention may be provided in many different forms.
7137359_1 (GHMatters) P64494.AU.2 JMEAD

Claims (18)

  1. The Claims:
    1. An apparatus for forming an underground tunnel, the apparatus comprising: a cutting head for removing material from an end-face of the tunnel and thereby forming a further portion of the tunnel, the cutting head comprising an electric or hydraulic motor; machinery for operating the cutting head being at least partially positioned at a location remote from the cutting head; a push beam providing a rigid structure arranged to push the cutting head against the end-face of the tunnel during removal of the material; a coupling comprising a plurality of sections that are coupled by hydraulic elements, the sections being positioned between the hydraulic elements and the hydraulic elements being positioned to enable bending of the coupling between the cutting head and the push beam in a horizontal plane, the sections of the coupling comprising overlapping portions along which in use the removed material moves towards the push beam; a support structure for supporting a previously formed portion of the tunnel by providing a supporting force against a surface of the tunnel, the support structure being arranged to move along the tunnel while maintaining the supporting force formation of the further portion of the tunnel; and a conveyor for conveying removed material to a location remote from the cutting head during formation of the further portion of the tunnel; wherein the apparatus is arranged, and at least a portion of the machinery is positioned, so that a space is provided at or immediately behind the cutting head so that the support structure, or a portion thereof, during removal of the material by the cutting head, is movable to a position immediately behind the cutting head, without restricting movement of the cutting head in a direction that is transversal to a direction of movement of the support structure or the portion thereof, and wherein the cutting head is movable independently from the support structure and during removal of the material away from the end-face of the tunnel and the support structure is arranged to move into the tunnel in response to and during progression of the tunnel.
  2. 2. The apparatus of claim 1 wherein at least a portion of the machinery is positioned at a location at least 10m behind the cutting head along the tunnel.
  3. 3. The apparatus of claim 1 wherein the push beam comprises an anchoring structure that in use provides a basis for pushing the cutting head against the end-face of the tunnel.
  4. 4. The apparatus of any one of the preceding claim wherein the apparatus is arranged so that in use the support structure, or a portion thereof, during removal of the material by the cutting head, is movable to a position within 0.5 - 5 m behind the cutting head without restricting movement of the cutting head in a direction that is transversal to a direction of movement of the support structure or a portion thereof .
  5. 5. The apparatus of any one of the preceding claims wherein the conveyor is arranged to enable conveying of the removed material along the tunnel to a suitable location in a manner such that inhibiting of formation of the portion of the tunnel, or the entire tunnel, due to accumulated removed material is avoided.
  6. 6. The apparatus of any one of the preceding claims wherein the apparatus is arranged so that in use removed material is continuously conveyed away from the cutting head.
  7. 7. The apparatus of any one of the preceding claims wherein the support structure comprises a void area through which in use the removed material is transported and wherein a portion of the conveyor is positioned within the void area.
  8. 8. The apparatus of claim 7 wherein the support structure comprises a plurality of support parts and is arranged so that support bolts may be placed at or near the location of the plurality of supporting parts and during movement of the support structure.
  9. 9. The apparatus of any one of the preceding claims wherein the coupling comprises an arrangement that enables pivoting of the cutting head relative to a portion of the apparatus .
  10. 10. The apparatus of any one of the preceding claims wherein the apparatus is arranged for formation of nonstraight sections of the tunnel.
  11. 11. A method of forming an underground tunnel, the method comprising: pushing a cutting head against an end-face of the underground tunnel, the cutting head being coupled to push a beam by a coupling comprising a plurality of sections that are coupled by hydraulic elements, the sections being positioned between the hydraulic elements and the hydraulic elements being positioned to enable bending of the coupling between the cutting head and the push beam in a horizontal plane, the sections of the coupling comprising overlapping portions along which in use removed material moves towards the push beam; moving the cutting head into the tunnel as formation of the tunnel progresses; supporting a previously formed portion of the underground tunnel using a support structure, the support structure being arranged to provide a supporting force during movement of the support structure along the tunnel including a position immediately behind the cutting head without restricting movement of the cutting head in a direction that is transversal to a direction of movement of the support structure or the portion thereof: moving the support structure along the tunnel during removal of material by the cutting head: and conveying the removed material to a location remote from the cutting head during formation of the underground tunnel.
  12. 12. The method of claim 11 wherein the push beam is anchored at the tunnel at the support structure and wherein the method comprises moving the cutting head relative to an anchoring of the push beam.
  13. 13. The method of claim 11 or 12 comprising moving a portion of the support structure during removal of the material by the cutting head so that a portion of the support structure is positioned within 0.5 - 5 m behind the cutting head.
  14. 14. The method of any one of claims 11 to 13 comprising placing support bolts during movement of at least a portion of the support structure and during removal of the material by the cutting head in a manner such that formation of the tunnel does not have to be interrupted for the placement of the bolts .
  15. 15. The method of any one of claims 11 to 14 wherein the step of moving the support structure, comprises checking a location of the cutting head relative to the support structure, or a part thereof, and driving at least a portion of the support structure during removal of the material by the cutting head so that the support structure is positioned immediately behind the cutting head without restricting movement of the cutting head in a direction that is transversal to a direction of movement of the support structure .
  16. 16. The method of claim 11 comprising extending a conveyor during advancement of the underground tunnel.
  17. 17. The method of claim 16 wherein the step of extending the conveyor extends an effective length of the conveyor and is conducted so that formation of the tunnel is possible without interruption and during extension of the effective length of the conveyor.
  18. 18. The apparatus of claim 1 comprising a device for placing support bolts and wherein the apparatus is arranged so that the formation of the tunnel does not have to be interrupted for the placement of the bolts.
AU2015258233A 2007-12-17 2015-11-18 An apparatus for forming an underground tunnel Ceased AU2015258233B2 (en)

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AU2015258233A AU2015258233B2 (en) 2007-12-17 2015-11-18 An apparatus for forming an underground tunnel

Applications Claiming Priority (7)

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AU2007906904A AU2007906904A0 (en) 2007-12-17 An apparatus for forming a tunnel
AU2007906904 2007-12-17
AU2008900022 2008-01-03
AU2008900022A AU2008900022A0 (en) 2008-01-03 An Apparatus for Forming a Tunnel
AU2008338242A AU2008338242A1 (en) 2007-12-17 2008-12-17 An apparatus for forming an underground tunnel
PCT/AU2008/001850 WO2009076710A1 (en) 2007-12-17 2008-12-17 An apparatus for forming an underground tunnel
AU2015258233A AU2015258233B2 (en) 2007-12-17 2015-11-18 An apparatus for forming an underground tunnel

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Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4199193A (en) * 1978-07-28 1980-04-22 Acme Machinery Company Underground mining machine having temporary roof support means and roof bolting means associated therewith
US4348138A (en) * 1979-07-06 1982-09-07 Charbonnages De France Sliding supporting gallery
WO2004027215A1 (en) * 2002-09-23 2004-04-01 Lumb, Hilary, Leith An apparatus for supporting a tunnel

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4199193A (en) * 1978-07-28 1980-04-22 Acme Machinery Company Underground mining machine having temporary roof support means and roof bolting means associated therewith
US4348138A (en) * 1979-07-06 1982-09-07 Charbonnages De France Sliding supporting gallery
WO2004027215A1 (en) * 2002-09-23 2004-04-01 Lumb, Hilary, Leith An apparatus for supporting a tunnel

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