The present invention concerns a tubular rock bolt that can be expanded with a pressurised medium for insertion into a drilled hole according to the introduction to claim 1. The invention concerns also a method for the manufacture of a rock bolt according to claim 8.
Prior art expandable rock bolts comprise a tube, the interior of which is set under pressure by a pressurised medium, for example a high-pressure fluid, and thus expand. The rock bolt is introduced into a drilled hole. The medium is supplied from a high-pressure pump through a tube to a connection in the end of the rock bolt that protrudes from the drilled hole. The medium is supplied to the interior of the tube, whereby the tube expands to come into contact with the wall of the drilled hole.
Rock bolts in drilled holes in rock are exposed to an aggressive environment, and also to tensile forces, shear forces and corrosion. This environment influences the lifetime and strength of the rock bolt. The bolt is weakened with time through corrosion, and it may finally fail if it is subject to shear forces and tensile forces. It should be realised that certain bolts are so located in the rock that the forces to which they are subject are relatively small, and that these bolts for this reason do not fail, even if the environment is aggressive.
In order to resist corrosion, the rock bolt may be provided with a coating of an agent that protects from corrosion. This coating may, however, be damaged when the bolt is introduced into the drilled hole. Furthermore, the coating may be damaged when the bolt is expanded, since the shape of the surface of the bolt is changed. This damage leads to openings in which corrosion may become established.
The purpose of the present invention is to provide a rock bolt that demonstrates better strength against the forces to which it is exposed, and greater resistance to corrosion.
This purpose is achieved through a rock bolt that demonstrates an internal reinforcement means that is present in a protected environment as long as the rock bolt is undamaged and that increases the strength of the rock bolt against tensile forces and shear forces.
The invention will be described below with reference to the attached drawings, in which:
The external tubular part 2 demonstrates, according to
One end 15 of the external tubular part 2, the end that is intended to be placed farthest into a drilled hole 16 when the rock bolt 1 has been placed into the drilled hole 16, comprises an end section 17 in the form of a sheath, which can be seen in
The end piece 19 is arranged with a connection part 22 for an expansion means 23. The connection part 22 comprises a hole or an opening for communication with the interior compartment 24 that is formed by the external tubular part 2. The expansion means 23 comprises a connector, for example a sheath provided with a gasket that is threaded on outside of the end piece or a nipple, and it is connected to a source 25 of high-pressure fluid, such as water. It should be realised that another type of fluid can be used, for example pressurised air.
A rock bed 26 is shown in
Cross-sections of a rock bolt 1 arranged in a drilled hole 16 are shown in
The rock bolt 1 can fail if it is exposed to tensile forces and shear forces from the motion of the rock, if these forces become too great. It can also become weaker with time through corrosion due to the cracks that form in the surface of the external tubular part 2 when the rock bolt 1 is expanded, which leads to the possible failure of the rock bolt 1. When it fails, the reinforcement means 3 absorbs the forces that the external tubular part 2 of the rock bolt is intended to absorb. Due to the reinforcement means 3 having been kept in a protected environment, and due to it not having been expanded, the reinforcement means 3 is in its original condition, and is thus able to withstand corrosion attack better than the external tubular part 2 of the rock bolt, and the lifetime of the rock bolt 1 is in this way extended.
When the rock bolt 1 is subject to tensile forces, when the rock is influenced by seismic motion and cracks, the rock bolt bends and may finally fail. Due to both the external tubular part 2 and the reinforcement means 3 being attached at the end section 17 and the end piece 19, the tensile force is displaced from the external tubular part 2 to the reinforcement means 3 when the external tubular part 2 fails.
When the rock bolt 1 has been arranged in the drilled hole 16 and has been expanded to come into contact with the walls 27 of the drilled hole, the external tubular part 2 can only be bent through a limited amount at the parts that can slide against the walls of the drilled hole and at the end that protrudes from the drilled hole. When the external tubular part 2 has been exposed to forces that exceed its strength, the internal reinforcement means 3 continues to absorb forces, since it is freely attached between the end section 17 and the end piece 19, and can be bent along its complete length between the end section and the end piece. Thus, it should be realised that the proposed rock bolt absorbs energy and can absorb the dynamic loads to which the rock bolt is exposed during motion of the rock. The shear strength and tensile strength of the rock bolt increase also due to the amount of steel per cross-sectional area being increased above that of rock bolts according to the prior art technology.
A rock bolt 1 according to the invention is manufactured through:
When the reinforcement means 3 of the rock bolt 1 comprises a tube that is placed inside the external tubular part 2, also the reinforcement means 3 is provided with a fold 14 when the fold 13 is rolled or pressed into the external tubular part 2 of the rock bolt 1. The pressurised medium is led only into the external tubular part 2, for which reason the reinforcement means 3, in the cases in which this comprises a tube, continues to demonstrate the longitudinal fold 14 after the expansion. The advantage of this is that the form of the surface of the reinforcement means 3 is not changed during the expansion, and for this reason is not influenced by the corrosion protection of the reinforcement means 3, which—furthermore—is not deformation hardened.
The present invention is not limited to what has been described above and shown in the drawings: it can be changed and modified in several different ways within the scope of the innovative concept defined by the attached patent claims.
Number | Date | Country | Kind |
---|---|---|---|
1150608-6 | Jun 2011 | SE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/SE2012/050695 | 6/21/2012 | WO | 00 | 12/20/2013 |