SE529595C2 - Rock bolt casting method, involves sealing borehole with elastic plug provided on bolt after casting material has been injected - Google Patents

Abstract

The method comprises the following steps: (A) injecting a casting material, preferably cement, into the borehole; (B) pressing a bolt which is provided with an elastic sealing plug into the borehole so that the plug forms a seal against the borehole walls, preventing the casting material and cement from escaping; and (C) allowing the casting material to solidify. An independent claim is also included for the sealing plug.

Description

This casting method usually works very well and with a suitable water content of the cement mill, it remains in place in the borehole until it solidifies even when the borehole is directed upwards. However, it has been found that this method of grouting is not suitable for grouting anchor bolts in water-bearing boreholes, i.e. boreholes in which water penetrates from surrounding mountains. In such a water-bearing borehole, there is a risk that the water penetrating into the borehole creates such a pressure against the cement mortar introduced into the borehole that the cement mortar is forced out of the borehole before it has solidified. This risk also exists when the borehole is only water-bearing to a lesser extent. To avoid this problem, it is common for sealant to be injected into the rock around the water-carrying borehole to stop the water penetration into the borehole before the anchoring bolt is cast in the manner indicated above.

This sealing procedure requires the use of chemical or cement mortar-based sealants and is time consuming and costly.

An alternative solution to the problem of casting an anchor bolt in a water-bearing borehole is to attach a sealing sleeve to the anchor bolt to seal the space between the anchor bolt and the borehole wall, the casting mass being introduced into the borehole via a hose bolt extending through the sealing sleeve. and the sealing sleeve was put in place in the borehole.

Sealing sleeves of this type are described, for example, in the patent documents US 3,204,416 A and US 5,003 749 A. The latter solution requires the use of relatively expensive and complex accessories and is relatively time consuming. In addition, with this solution it is difficult to ensure that the space between the anchoring bolt and the borehole is completely filled with casting compound.

OBJECT OF THE INVENTION The object of the present invention is to provide a method by means of which a stable casting of a bolt can be achieved relatively easily and quickly in a borehole which at the time of casting is moist or slightly water-carrying. SUMMARY OF THE INVENTION According to the present invention, said object is achieved by means of a method having the features stated in claim 1.

The method according to the invention comprises the steps of: - introducing casting mass, preferably in the form of cement mortar, into the borehole, - pushing a bolt provided with a sealing plug of elastic material into the casting mass in the borehole so that the sealing plug is pressed into the borehole and comes into contact with the borehole wall and the casting mass while forming a seal between the bolt and the borehole wall which counteracts the expulsion of casting mass and water from the borehole, and - allowing the casting mass to solidify in the borehole after pressing the bolt provided in the sealing plug into the bolt hole.

With the solution according to the invention, casting mass is injected into a still water-carrying borehole before a bolt provided with a sealing plug is pressed into the borehole and the casting mass applied therein. The sealing plug then holds back the casting mass in the borehole while the casting mass solidifies so that the not yet solidified casting mass is prevented from penetrating out of the borehole under the action of the water pressure from the water leaking into the borehole. By applying the casting compound in the borehole before the bolt and the sealing plug, the procedure becomes extremely simple and fast with a relatively small risk of casting errors at the same time as a simple and inexpensive sealing plug can be used. The sealing plug also helps to center the bolt in the borehole.

The method according to the invention is intended to be used for casting a bolt in a borehole which at the time of casting is water-carrying to a lesser or relatively moderate extent. Practical tests have shown that this method can be applied with good results for the injection of a conventionally dimensioned anchoring bolt with a diameter of about 25 mm into a conventional dimensioned borehole with a diameter of approx. 45 mm which has a water leakage of up to at least 0.4 liters / minute, using conventional casting compound in the form of cement mortar. However, it is quite conceivable that the method according to the invention can also be applied when pouring a bolt into a water-carrying borehole which has a water leakage exceeding 0.4 liters / minute.

The upper limit of the acceptable water leakage at which the method according to the invention gives a satisfactory casting of a bolt of a certain type and dimension in a water-carrying borehole of a certain dimension can be easily determined by empirical tests.

Preferred embodiments of the method according to the invention appear from the dependent claims and the following description.

The invention also relates to a sealing plug with the features defined in claim 5 for use in the method according to the invention.

Preferred embodiments of the sealing plug according to the invention appear from the dependent claims and the following description.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in more detail below with the aid of exemplary embodiments, with reference to the accompanying drawings.

It is shown in: Figs. 1-3 longitudinal section through a borehole illustrating different stages during the injection of a bolt into the borehole by a method according to a first embodiment of the present invention, Fig. 4 a schematic longitudinal section through a sealing plug according to an embodiment of the present invention, and Fig. 5 a longitudinal section through a part of a borehole illustrating a stage during the injection of a bolt into the borehole by a method according to a second embodiment of the present invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS Figures 1-3 illustrate various stages during the casting of a bolt 1 into a water-carrying borehole 2 in rock 3 by a method according to the present invention. The fact that the borehole 2 is water-carrying means that water penetrates the borehole 2 from the surrounding rock 3. In the illustrated example, the bolt 1 is an anchoring bolt which is intended to be molded into the borehole 2 to bind loose rock parts to each other and possibly to underlying firmer rocks. An anchoring bolt of this type usually has a length of 3-5 meters and can, for example, have a diameter of about 25 mm. However, the method according to the invention can also be used for pouring a shorter so-called installation bolt into a water-carrying borehole. An installation bolt is used to anchor different types of equipment in rock and usually has a length of about 1 meter cast into the rock.

According to the invention, first casting compound 4, preferably in the form of cement mortar, is introduced into the borehole 2 so that the borehole is filled with a suitable amount of casting mass. The casting compound can, for example, be injected into the borehole 2 by means of a hose 5, as illustrated in Fig. 1. In the case where cement mortar is used as casting compound, this cement mortar may advantageously have a lower water content than in the corresponding casting of a bolt , ie dry, borehole because the cement mill is supplied with water that leaks into the water-bearing borehole.

After the desired amount of casting mass 4 has been applied to the borehole 2, a bolt 1 provided with a sealing plug 10 is pressed into the casting mass 10 in the borehole so that the sealing plug 10 is pressed into the borehole and comes into abutment against the borehole wall. 6 and the casting mass 4 to form a seal between the bolt 1 and the borehole wall 6 which counteracts the expulsion of casting mass and water from the borehole. Thereafter, the casting mass 4 is allowed to solidify in the borehole 2 so that the bolt 1 is cast into the borehole.

In order to ensure that the bolt 1 is held in the borehole before the casting mass has solidified, one or more fixing elements 7uav of conventional type are suitably arranged on the bolt. These fixing elements 7 enable a bolt to be fixed in a borehole in a centered manner, i.e. so that the bolt does not come into contact with the borehole wall, at the same time as the fixing elements do not appreciably impede the flow of the casting mass along the bolt. Respective fixing elements may, for example, be of the type described in the Swedish patent specification SE 505 666 C and comprise a base portion in the form of a ring spring, which is intended to be applied around the bolt, and two legs projecting on opposite sides of the ring spring, which are intended to support the borehole wall via their ends and thereby hold the bolt in the borehole at a distance from the borehole wall.

The sealing plug 10 should have an outer diameter at its widest portion which is slightly larger than the inner diameter of the borehole 2 so that the sealing plug is slightly deformed when pressed into the borehole and clamped against the borehole wall 6. The frictional force between the sealing plug 10 and the borehole wall counteract the pressure force on the casting mass 4 from the water leaking into the borehole so that the casting mass is prevented from penetrating out of the borehole.

The sealing plug 10 is suitably fastened at a distance from the front insertion end 1a of the bolt which corresponds to the distance of the bolt which is intended to be molded, the bolt 1 provided with sealing plug 10 being pressed into the casting mass 4 in the borehole 2 in such a way that substantially all casting mass 4 in the borehole after pushing in the bolt is enclosed between the bottom 2a of the borehole and the sealing plug 10, as illustrated in Fig. 3. The sealing plug 10 is suitably in the form of a truncated cone, as illustrated in Fig. 4. The sealing plug is intended to be inserted into a borehole with the narrower end 11 of the sealing plug first, i.e. with the narrower end facing the bottom of the borehole. The narrower end 11 should have an outer diameter that is slightly smaller than the inner diameter of the borehole 2, while the wider end 12 should have an outer diameter that is slightly larger than the inner diameter of the borehole. Extending between the ends 11, 12 of the sealing plug is a central hole 13 which is adapted to receive a bolt 1. The hole 13 should have an inner diameter which is slightly smaller than the outer diameter of the bolt 1 so that the sealing plug 10 can be threaded onto the bolt 1 with press fit and thereby held to the bolt by frictional action. The sealing plug 10 is suitably made of rubber material with good elasticity, but could alternatively be made of elastic plastic material.

Sealing plugs 10 can advantageously be provided in different sizes adapted to bolts with different outer diameters and / or boreholes with different inner diameters. Sealing plugs of different sizes can advantageously be distinguished by color marking.

In the event that a sealing plug 10 mounted on a bolt 1 has a size which is slightly too small to give a satisfactory abutment pressure against the borehole wall 6 of a borehole, the sealing plug 10 can be caused to expand in radial direction to increase the sealing plug outer diameter. This expansion is advantageously effected by means of a nut 14 which is mounted on a threaded rear part 1b of the bolt 1 between the sealing plug 10 and the rear end of the bolt, the nut 14 being screwed in the direction of the sealing plug 10 to press the sealing plug against a bolt 15 provided on the bolt so that the sealing plug is compressed in the axial direction and thereby caused to expand in the radial direction, as illustrated in Fig. 5. The sealing plug can be caused to expand in this way either before or after the insertion of the bolt and the sealing plug in the borehole. Said abutment 15 may consist of a washer which abuts a shoulder formed on the bolt 1 in the transition between the threaded rear rear of the bolt 10 15 20 529 595 part 1b and the front grouting part 1c of the bolt. Advantageously, a washer 16 is also arranged between the nut 14 and the sealing plug 10. The nut 14 and the abutment 15 also ensure that the sealing plug 10 is held in place in the longitudinal direction of a bolt 1 and does not slide along the bolt when inserting the bolt into a borehole.

In the case where a sealing plug 10 is attached to a bolt 1 without nut and countertop, a sliding of the sealing plug along the bolt caused by the friction between the sealing plug and the borehole wall when inserting the bolt into a borehole can be counteracted by means of a tool, for example a pipe of suitable dimension, which is pressed against the rear end surface 17 of the sealing plug and is advanced as the bolt is pressed into the borehole.

The invention is of course in no way limited to the embodiments described above, but a number of possibilities for modifications thereof should be obvious to a person skilled in the art, without this for that reason deviating from the basic idea of the invention as defined in the appended claims. .

Claims (1)

10 15 20 '25 30 35 529 595 9 PATENT REQUIREMENTS A method for casting a bolt (1) in a borehole (2) in rock, which method comprises the steps of: - introducing casting compound (4), preferably in the form of cement mortar, into the borehole, - pressing one with a sealing plug (10 ) bolt (1) provided with elastic material into the casting mass (4) in the borehole (2) so that the sealing plug (10) is pressed into the borehole and comes into contact with the borehole wall (6) and the casting mass to form a seal between the bolt and the borehole wall which counteracts the ejection of casting mass and water from the borehole, and - allowing the casting mass (4) to solidify in the borehole (2) after the bolt (1) provided with sealing plug (10) is pressed into the casting mass so cast into the borehole. . Method according to claim 1, characterized in that the sealing plug (10) is fastened at a distance from the front 'insertion end (1a) of the bolt which corresponds to the distance of the bolt which is intended to be molded, and that it with sealing plug (10) for - seen bolt (1) is pressed into the casting mass (4) in the borehole (2) in such a way that substantially all the casting mass in the borehole after the pressing of the bolt is enclosed between the bottom of the borehole (2a) and the sealing plug. Method according to Claim 1 or 2, characterized in that the sealing plug (10) is caused to expand in the radial direction after its attachment to the bolt (1) in order to increase the outer diameter of the sealing plug. . Method according to claim 3, characterized in that said expansion of the sealing plug (10) is effected by means of a. nut (14) mounted on the bolt (1) between the sealing plug (10) and the rear end of the bolt, the nut being screwed in the direction of the sealing plug to press the sealing plug against a bolt (15) arranged on the bolt so that the sealing plug 10 529 595 10 is compressed in the axial direction and thereby caused to expand in the radial direction. . Sealing plug for use in a method according to any one of claims 1-4, characterized in that it has the shape of a truncated cone with a central hole (13) which is adapted to receive a bolt. . Sealing plug according to Claim 5, characterized in that it is made of rubber or plastic material.