This invention relates to a rock bolt.
A friction-type rock bolt relies on friction which is generated between at least part of the bolt and a surrounding surface of a hole in which the rock bolt is located, to be effective. The effectiveness of the anchor, provided by the rock bolt, depends on the frictional force which is generated by the interaction of the bolt with the surrounding rock mass and on the length of the rock bolt which extends into solid rock, beyond the rock which is being supported by the rock bolt.
A mechanically-anchored bolt makes use of an expansion unit, at one end of a shank, which is expanded into close contact with a surrounding wall of a hole in which the rock bolt is inserted. A washer is connected to an opposing end of the shank, with the washer bearing on an outer surface of a rock face in which the hole is formed. The effectiveness of this type of anchor is dependent, at least, on the washer being in load-bearing contact with the rock face.
Although friction-type bolts are relatively easy to install they are susceptible to corrosion and, as noted, the effectiveness of this type of bolt depends on the frictional force which is generated.
The invention provides a rock bolt which includes an expansible tubular section and an expansion unit which is connected to the tubular section.
The tubular section may comprise an elongate tubular section which is radially expansible.
A valve may be connected to the tubular section and a pressurised fluid, eg. water, may be caused to pass through the valve into an interior of the tubular section to expand the tubular section.
The tubular section may be provided in a collapsed or non-expanded form wherein, in cross section, the tubular section includes a generally U-shaped outer portion and a smaller, generally U-shaped inner portion which is positioned at least partly inside the outer portion.
The valve may be connected to a first end of the tubular section.
A bearing plate or similar load-distributing appliance may be engaged with the tubular section preferably at a position at which the bearing plate abuts valve collar structure which serves to retain the bearing plate engaged with the tubular section.
The tubular section may have a second end which is tapered.
The rock bolt may include a stud or shank which extends between the tubular section and the expansion unit.
The tapered second end may be attached or secured to the stud in any appropriate way. For example the tubular section may be swaged onto the stud or it may be welded to the stud or both techniques of attachment may be used.
The expansion unit may be of any suitable kind and preferably comprises a spring-loaded bail-type expansion unit which has a conical or wedge-shaped member at one end of the shank, a plurality of shells which abut an outer surface of the wedge member, a bail which is connected to the shells and a biasing member, such as a coil spring, which acts between the bail and the wedge member.
The wedge-shaped member may be formed integrally with the shank, or it may be formed separately from the shank and then connected to the shank.
The invention is further described by way of example with reference to the accompanying drawings in which:
An elongate tubular collar 18 is attached to the end 14. A bearing plate or load-distributing washer 20 abuts a valve collar 21 to which is secured a valve 22. The valve collar 21 is fixed to a free end of the tubular collar by welding.
An expansion unit 26 is attached to the second end 16 of the stud.
The shank 12 is of substantially conventional construction and has a diameter and length which are determined by the application. The first end 14 is formed with formations 30 which may be thread formations or similar peaks and troughs which provide a surface to which an end 32 of the collar can be directly swaged. This is done by deforming the end 32 so that it at least partly encloses the formations 30. Thereafter the end is welded to the shank.
The collar is tubular, as is evident from an inset drawing in
The second end 16 of the stud 12 is threaded and is engaged in a threaded hole, not visible in
Lower ends 56 of the shells can be held together by means of a breakable tie, eg. of plastic or rubber, to ensure that the shells are retained in position during transport and storage.
The tubular collar 18 has a lower or second end 60 to which is attached the valve collar 21.
The valve collar 21 is tubular in cross-section and has an inner diameter 62 which is just large enough to pass over the tubular collar 18, and a flared end 64 to prevent the bearing plate 20 from travelling past the valve collar. There is a hole 66 in the U-shaped outer portion 34 of the collar 18 to accept the valve 22.
The bearing plate 20 is made from a planar metal sheet 68 with a dome 70 which has a centrally positioned hole 72 into which the tubular collar 18 is inserted.
The valve 22 includes a valve body 76 with a hexagonal head 80. A passage, not visible in
The lower end 60 of the tubular collar is shown in
The expansion unit 26 is actuated simply by twisting and pulling slightly on the end of the rock bolt which protrudes from the hole 90. This causes the unit to expand into load-bearing contact with the wall of the hole 90. Thereafter a pressurised source of water is connected to the valve 22. The valve body 76 is of a conventional design so that it can be used with existing water pumps and connectors.
When the interior of the tubular collar 18 is pressurised it expands radially into contact with an opposing surface 100 of the hole 90. At the time of installation therefore the rock bolt is anchored mechanically by means of the expansion unit 26 and frictionally by means of the inflated tubular collar. The mechanical anchor 26 is clearly not dependent on frictional effects, as is the case with conventional friction-anchored bolts, to exhibit its load-bearing characteristics. On the other hand the inflated tubular collar 18 bonds frictionally to the rock surface 100 adjacent the mouth of the hole and thereby reduces reliance on the load-bearing washer 20. The rock bolt is totally mechanical in operation and does not require grout or resin.
The rock bolt 10A includes a coupling device 104 which includes a short bar 106 and an internally threaded tube 108 which is attached to the bar 106 by being threadedly engaged therewith, or by means of a welding, swaging or any other technique which leaves the tube with an open mouth 110.
An end 32A of the collar 18A is attached to one end of the bar 106 in a manner which is similar to the way in which the shank 12 is attached to the collar 18 of the rock bolt 10.
An end 30A of the shank 12A is threaded and can be threadedly engaged with the tube 108 passing through the mouth 110.
The rock bolt 10A thus comprises two parts 12A and 18A respectively which are detachably engageable with each other in an indirect sense in that use is made of the coupling device 104 for this purpose. This approach allows the collar 18A to be standardised so that it is only necessary to select a shank 12A of an appropriate length, for use with the collar, according to the overall length of the rock bolt 10A which may be required for a particular installation. Also, as the shank and collar can be threadedly engaged with each other when the threaded end 30A and the tube 108 are positioned inside a hole, it becomes possible to install a rock bolt of an extended length in an underground location such as a stope which has limited clearance which normally would restrict the maximum length of a rock bolt which could be installed.
In a further modification, not shown in the drawings, the threaded end 30 is directly threadedly engaged with an internally threaded formation at the end 32 of the collar which, therefore, is not swaged to the shank 12 nor to the bar 106.
Most of the components used in the rock bolt of the invention are standard components and can be manufactured using existing technology. It is possible to incorporate a pop-out pressure indicator in the valve or on the tubular collar which allows for post-installation quality checks.
Depending primarily on the cross-sectional design of the tubular collar 18 the valve 22 can comprise a one-way filler valve so that the interior of the collar 18, once the collar has been expanded, remains pressurised. Alternatively water can be allowed to drain from the tubular collar which then remains frictionally engaged with the wall of the hole due to its previous expansion.
Number | Date | Country | Kind |
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2003/8405 | Oct 2003 | ZA | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/ZA04/00131 | 10/28/2004 | WO | 2/27/2007 |