SE527107C2 - Procedure for rocking and rocking - Google Patents

Abstract

A method for providing a rock bolt ( 2 ) for rock bolting, wherein a rock bolt ( 2 ) having a tubular bolt portion ( 4 ) with a closed cross section is inserted and expanded for bearing contact in a bore hole ( 3 ) in a rock structure ( 1 ). The length of the tubular bolt portion ( 4 ) is determined such that maximum frictional force at pulling inside a bore hole ( 3 ) of a rock bolt with a tubular bolt portion with this length is below a predetermined maximum value. The invention also concerns a rock bolt.

Description

tott O I I I 00 0000 I. OIIO 2 N u1 O I CU Q CIII I. I I 'I' '.w .II- O: O ICC. Ö 5 2 7 1 0 7. frr:. 1 n n o n on os; 0000 0 Hereby it is achieved that a rock bolt with a tubular bolt portion can be produced and dimensioned so that large tensile forces, which typically a rock bolt can be exposed to during strong but in space limited movements in the rock structure it is intended to stabilize, do not cause fracture of the rock bolt. a controlled sliding of the tubular bolt portion a limited distance in the borehole, after which the rock bolt is again able to take up substantially the same load as before the sliding, so that such movements in the rock structure become tolerable.

The advantages of the invention are in addition to rock bolt failure also being avoided that the number of rock bolts per unit area can be reduced and that the dimensions of used rock bolts can be reduced, since the intended and emerging resilience allows rock movements in a controlled manner. The rock structure thus does not need to be stabilized in an excessive and more costly manner.

It is preferred that the length of the tubular bolt portion is determined based on at least one measurement performed when drawing at least one rock bolt with a tubular bolt portion of a certain length in at least one borehole in the same or in a corresponding rock structure.

Based on the values obtained from this tensile measurement or these tensile measurements, the rock bolts to be used in the stabilization can then be provided and adequately dimensioned with respect to the length of the tubular bolt portion so that the desired sliding at the intended loads is achieved.

It is preferred that said predetermined value is the yield load for the tubular bolt portion, which means that the material is advantageously optimized to prevailing conditions.

The floating load for the tubular bolt portion to a rock bolt it 72767.doc: 2004-05-24 10 15 20 in question can be determined by a person skilled in the art by load tests known per se.

It is preferred that a number of tensile tests, such as 5 to 10 tensile tests, be performed, in order to obtain more reliable values for the dimensioning. Based on such a plurality of tensile test results, the spread in the result is taken into account to determine the margin of the buoyancy load when the length of the tubular bolt portion, which is to be used for each rock bolt, is to be determined.

With a larger spread, a larger margin is typically needed for the floating load. Then it may be appropriate to dimension the rock bolt so that, based on the average value of the tensile samples, the maximum calculated frictional force is, for example, 60 - 70% of the buoyancy load.

In the case of smaller scattering, which is also to be regarded as normal scattering, based on the average value of the tensile samples, the maximum calculated frictional force can be 80 - 90% of the buoyancy load.

It should be noted that this is an example and that it is within the scope of the invention that other values may come into question.

It is also preferred that the length of the tubular bolt portion is so determined and dimensioned that said frictional force exceeds a predetermined minimum value in order to avoid unnecessary sliding movements during less powerful rock movements.

Corresponding advantages are achieved by the invention with a rock bolt with corresponding features. By means of a rock bolt according to the invention, large and sudden rock movements can be controlled.

After a sliding movement, the ability of the rock bolt to absorb force is essentially the same as it was before the sliding movement.

A device for carrying out said method, comprises means for engaging a rock bolt with a tubular bolt portion inserted and expanded in a borehole, means for applying 72767 .d0c; 2004-05-24 10 15 527 107 aë a traction force on said rock bolt, means for detecting sliding of said rock bolt as a result of application of said traction force, and means for detecting and measuring the traction force corresponding to the detected slip.

This device allows efficient determination of the effective length of a rock bolt, which has the ability to be resilient by sliding during major movements in the rock structure.

The invention will now be described in more detail with reference to exemplary embodiments and with reference to the accompanying drawings.

Brief description of the drawing In the attached drawing: Fig. 1 shows a section through a rock structure with a rock bolt according to the invention, Fig. 2 a device for carrying out a method according to the invention in connection with a rock bolt, and Pig. 3 is a sequence for illustrating a method of rock bolting according to the invention.

Description of exemplary embodiments In Fig. 1, reference numeral 1 refers to a rock structure in which a rock bolt 2 is inserted into a borehole, the inner wall of which is designated 3. The rock bolt 2 comprises a tubular expandable bolt portion 4 and a tie rod 5, which connects to the tubular bolt portion 4 via an adapter sleeve 6. Figure 1 shows a tie rod in the form of a number of pipe sections 5 'spliced in pairs by means of a splice sleeve 5 ". This arrangement allows the use of rock bolts of large total length even in narrow places, which limit the length of a tie rod in one piece. 0000 000 00 0000000 0 00 0 0000 00 0 0 0 0 0 0 0 527 107 the borehole 3 terminates the tubular bolt portion 4 with a termination sleeve 7.

As usual, a rock washer 8 is arranged on the outside of the borehole 3, which, by prestressing the drawbar 5, exerts an influential stabilizing compressive force against the outer part of the rock structure.

In Fig. 1, 9 denotes a crack in the rock structure, in order to illustrate to some extent the inherent instability of the rock structure 1. According to the invention, movements in the rock structure cause which tend to displace the rock washer 8 axially outwards, i.e. to the right in Fig. 1, and which subject the rock bolt to a sufficiently high force, a sliding of the tubular bolt portion 4 against the inner wall of the borehole 3. This occurs in particular if the force exerted on the rock bolt, by the moving part of the rock structure, exceeds a minimum value.

In this way, a controlled yield of the rock bolt takes place through the sliding movement, which is why the rock bolt is thereby able to withstand large forces and movements of the structure without failing.

Fig. 2 shows a device 14 for measuring frictional forces which are relevant for a certain type of expandable rock bolts in connection with a certain rock structure. This device is intended for dimensioning rock bolts according to the invention and in particular the length of the tubular bolt portion.

According to the invention, a process is undertaken for determining the effective length of a tubular bolt portion of a rock bolt before inserting a number of rock bolts into a rock structure to stabilize a rock side such as, for example, in tunnel construction or local drift in mining operations. 72767.d0C; 2004-05-24 10 15 20 0000 0 0 0 0 00 0 0000 0 0 0 0 0000 J. ZN LH 00 0 0000 0 0 00 0 0 0 0 I 0 0 0 0 0 0 0 00 000 00 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 000 0 0 0 0 0 000 0 0 0 0 0 0 0 0 0 0 0 0 00 000 0000 0 527 107 šß The measurement is made so that a sample in the form of a rock bolt 10 with a tubular bolt portion of a predetermined length is inserted into a borehole 12 in the rock structure 13 in question.

The length of the tubular bolt portion is suitably selected so that sliding of the rock bolt is safely obtained at a force which is less than the yield strength of the tubular bolt portion. Should the yield strength be reached before sliding is achieved, a new rock bolt with a shorter tubular bolt portion 11 is selected.

The measuring device 14 includes a drawbar 15 for connection to the expanded tubular bolt portion, a support portion 16 for abutment against the side of the rock structure, an engaging member 17 for engaging the drawbar 15 and a draw mechanism 18 which, for example by hydraulic means, applies a draw force to the rock bolt 9. A control unit 19 senses applied traction and detects when sliding takes place, and at what traction this takes place.

Based on the results of the measurement, which can be transmitted to frictional force per unit length of tubular bolt portion, rock bolts can be dimensioned with adequate lengths of tubular bolt portion so that a tensile force, involving sliding, for the selected rock bolt with tubular bolt portion of selected length corresponds to about 60 - approx. 90% of said buoyancy load. Selection of adequate length can, for example, be made practical through lists, diagrams or the like.

Figure 3 illustrates a sequence for carrying out the method according to the invention.

Position 20 indicates the start of the sequence.

Heading 21 relates to the insertion and expansion of a tubular rock bolt of a predetermined length in a pre-drilled borehole in a rock structure.

Heading 22 refers to the axial pull of the rock bolt in the direction 72767.d0C; 2004-05-24 10 15 20 s 2 7 1 o 7 - If? - Ilší 7 utåt.

Heading 23 relates to the detection of slippage of the rock bolt and the traction force at which slippage occurs.

The dashed line 26 indicates that a plurality of tensile tests can be performed. Position 24 refers to the calculation of the length of tubular bolt portions at a rock bolt, either by manual control in tables, diagrams, etc. or automatically by a circuit connected to the control unit. This is performed on the basis of the tensile test or tensile tests and associated detections performed in positions 22 - 24.

Position 25 refers to the end of the sequence.

The invention can be varied within the scope of the claims. Thus, the device for performing the method may be designed differently as long as it includes means for exerting a traction force, detecting sliding and recording traction force during sliding.

It is preferred that the buoyancy load is used as a reference in the dimensioning of rock bolts according to the invention. However, it is not excluded that other values significant for a rock bolt can also be used in the dimensioning. For example, the breaking load of the rock bolt could be utilized, whereby the tubular portion of the rock bolt could be dimensioned to have a length corresponding to a frictional force, constituting a certain determined proportion of the breaking load. It is also not excluded that the dimensioning is based on the frictional force constituting a certain determined proportion of a significant value for the rock's strength.

The rock bolt according to the invention can be of different designs.

It is not excluded, for example, that a rock bolt according to the invention comprises more than one tubular bolt portion arranged one after the other. 72767 .d0C, '2004-05-24

Claims (10)

A method for providing a rock bolt (2) for rock bolting, wherein a rock bolt (2) having a tubular bolt portion (4) with a closed cross section is inserted and expanded to abut in a borehole (3) in a rock structure (1), characterized in that - the length of the tubular bolt portion (4) is determined so that maximum frictional force when pulling in a borehole (3) for a rock bolt with a tubular bolt portion of this length, below - a predetermined maximum value rises. Method according to claim 1, characterized in that - the length of the tubular bolt portion (4) is determined on the basis of a measurement or measurements made (-a) when drawing at least one rock bolt (10) with a tubular bolt portion (11 ) of a fixed length in boreholes (12) in the same or in a corresponding rock structure. Method according to claim 1 or 2, characterized in that - said predetermined value is the floating load of the tubular bolt portion. Method according to claim 3, characterized in that - the length is set so that said maximum calculated frictional force is set to about 60 - cza 90% of said buoyancy load. Method according to any one of the preceding claims, characterized in that - said length is determined so that the minimum frictional force in a borehole for a rock bolt (2) with a tubular bolt portion (4) of this length exceeds a predetermined minimum value. 72767 .dOCI 2004-05-24 10 15 20 527 107 šßš * 9 Rock bolt (2), including a tubular bolt portion (4) with closed cross section for insertion and expansion into abutment in a borehole (3), characterized in that - the length of the tubular bolt portion (4) is dimensioned so that maximum frictional force when pulling in a borehole for a rock bolt with a tubular bolt portion of this length, is less than a predetermined maximum value. Rock bolt according to claim 6, characterized in - that the length of the tubular bolt portion (4) is determined on the basis of at least one measurement performed when drawing at least one rock bolt with a tubular bolt portion of a certain length in boreholes in the same or in a corresponding rock structure. Rock bolt according to claim 6 or 7, characterized in that - said predetermined value is the floating load of the tubular bolt portion. Rock bolt according to claim 8, characterized in that - the length is dimensioned so that said maximum frictional force constitutes approximately 60 - approximately 90% of said buoyancy load. Rock bolt according to any one of claims 6 - 9, characterized in that - said length is dimensioned so that the minimum frictional force in a borehole for a rock bolt (2) with a tubular bolt portion (4) of this length exceeds a predetermined minimum value. 72767 .doC; 2004-05-24