SE509139C2 - Ways to simultaneously seal cracks around boreholes and anchor a rock bolt, as well as rock bolt - Google Patents

Abstract

Cracks round a bore hole (19) are sealed while at the same time a rock bolt (20) is anchored in the bore hole by injecting a sealing material (23) through an injection nozzle. This comprises a sealing sleeve (10-14) with a through hole and a nonreturn valve device and is left in the bore hole after injection. The rock bolt (20) is inserted through the through hole of the valve nozzle and through the nonreturn valve device (16, 20). According to the invention, one sealing element of the non return valve device is formed of the rock bolt (20) and its other sealing element is formed of a sealing socket (16). This is pressed in a yielding and sealing manner against the rock bolt. The injection of the sealing material (23) is carried out through a gap (21) between the rock bolt and the sealing sleeve (10-14) and through the non return valve device (16, 20) during elastic deformation of the sealing socket (16).

Description

509 139 2 10 15 20 25 30 35 and the rock has many large or small cracks. In such cases, the injection procedure must be repeated until a sufficient density has been obtained for the borehole where the rock bolt is to be inserted to be dry. When dryness is reached, the rock bolt can be anchored either by forming it (eg according to US-A-4290515) by first injecting cement mortar into the borehole and as an expander bolt or then pushing in the rock bolt. The latter procedure is cumbersome, since in many cases the rock bolt can have a considerable length, usually 3-4 m if the rock is of poor quality with many cracks. The difficulties arise mainly due to the need to carefully adjust the amount of cement used to the dimensions of the borehole and rock bolt, so that a complete filling of the borehole is obtained around the depressed rock bolt without too much pressure being forced out of the hole during the pressing of the rock bolt.

According to US-A-4289427, an attempt has been made to counteract this problem by replacing the rock bolt with a rope, which is pushed into the borehole. For this purpose, a special type of rope is used, which is formed of glass fibers and has one or more longitudinally extending ventilation ducts. The line is rotated during insertion into the borehole, and at the same time the area around the mouth of the borehole is sealed by pressing an annular sealing disc against the rock road. An grouting equipment is used to ensure during the insertion of the sealing compound partly through the rotation. high pressure inject a sealant into the borehole. one of the line, partly by allowing excess air in the borehole to be released through the mentioned ventilation ducts. After the sealing compound has solidified, the rope can be used for anchoring purposes, for example in connection with the pouring of a continuous concrete layer on the inside of the rock.

Although this known technique can be used for anchoring ropes, it is not suitable for anchoring rock bolts. In addition, it is difficult to achieve sufficient tightness between the sealing ring and the adjacent rock surface, since the rock surface is naturally rough.

An object of the present invention is therefore to provide a method of anchoring rock bolts in a borehole in a rock wall while simultaneously injecting a sealing compound.

Another object of the invention is to provide a method of sealing rock while simultaneously anchoring rock bolts and sealing the rock formation by injecting a sealing compound.

A further object of the invention is to minimize the need for grouting a rock by simultaneously sealing the rock formation and anchoring the rock bolts.

These and other objects of the invention are achieved with a method and a device according to the independent claims 1 and 2, respectively. The dependent claims set out particularly preferred embodiments of the invention.

In summary, the invention lies in the idea of simultaneously sealing cracks around boreholes anchoring a rock bolt in the borehole by injecting a sealing material through an injection nozzle. This comprises a sealing sleeve with a through hole and a non-return valve device and is left in the borehole after the injection.

The rock bolt is passed through the through hole of the valve nozzle and through the non-return valve device. According to the invention, one sealing element of the non-return valve device is formed by the rock bolt and its other sealing element is formed by a sealing sleeve. This is pressed resiliently and sealingly against the rock bolt. through a gap between the rock bolt and the sealing sleeve The injection of the sealing material is carried out and through the non-return valve device under elastic deformation of the sealing sleeve.

An example of a method and a device according to the present invention will be described in more detail below with reference to the accompanying drawings. 509 139 4 10 15 20 25 30 35 Fig. 1 shows an example of an injector nozzle in longitudinal section.

Fig. 2 shows this injector nozzle, when used in a borehole for simultaneous anchoring of a rock bolt and injection of a grouting compound.

The example of a grouting device according to the present invention shown in the drawing comprises an elongate sleeve 10, which is externally threaded at one end and which at its other end is rigidly connected to or formed in one piece with an outwardly directed flange 11.

A sealing element 12 in the form of a hose piece of elastic material is threaded over the sleeve 10. This sealing element has at each end a washer 13, which is preferably fixedly connected to the end surface of the sealing element.

A pressure transfer sleeve 15 is placed between the sleeve 10 and a nut 14 attached to it. On the outwardly facing side of the flange 11 (on the left in Fig. 1) a sealing sleeve 16 is vulcanized. The sleeve is formed of an elastic material and has a through hole 17 with at least one portion smaller in diameter than the inner diameter of the sleeve 10. In the example shown, the through hole 17 of the sleeve is also conically tapered in the direction of the outlet end, two inwardly directed sealing ridges 18 being formed in the through hole. These sealing ridges do not need to have semi-circular warping sealing lips.

When this grouting device is to be used, a hole 19 is first drilled in the rock wall. The borehole may have the desired diameter, eg about 64 mm, and the desired depth, eg 3-4 m, the nozzle of the grouting device into the borehole, which is common in this context. The nut 14 is then screwed in so that the sleeve 12 is compressed longitudinally to bend outwards and is pressed tightly against the borehole wall. The tightening of the nut can take place in a known manner, the borehole has a diameter of 64 mm, for example as shown in the above-mentioned US-A-4260295. If a suitable outer diameter for the hose piece 12 can be 57 mm. 10 15 20 25 30 35 5 509 139 After the nozzle has been anchored in the borehole 19 in this way, a rock bolt 20 is pushed in through the nozzle. The diameter of the rock bolt 20 must be smaller than the inner diameter of the sleeve 10 in order to leave an annular gap 21 between the bolt and the sleeve. In addition, the through holes 17 of the collar 16 have a minimum diameter which is smaller than the outer diameter of the rock bolt, so that the collar 16 will expand during the insertion of the rock bolt and will therefore be pressed sealingly against it. If the collar 16 consists of rubber material, the rock bolt can have a diameter of 22 mm, the narrowest section of the collar 16 suitably being 20 mm.

If the rock bolt 20 has a diameter of 22 mm, a suitable inner diameter of the sleeve 10 may be 32 mm, so that the annular gap 21 has a width of 5 mm.

After the rock bolt is pushed into the borehole through the grouting nozzle, a grouting device 22 is connected to the sleeve 10. In the example shown, the projecting portion of the rock bolt is completely enclosed in the grouting device 22, but it is possible to design this equipment so that the rock bolt extends through the equipment and protrude from it. In that case, a seal must also be arranged around the protruding end of the rock bolt.

By means of the grouting equipment, a grouting nozzle is pushed into a suitable sealing material 23, for example a cement grout, the sealing material flowing through the gap 21 and out through the sleeve 16, which thereby gives elastic expansion under the influence of the pressure in the sealing material. The sealing material 23 fills the borehole 19 around the rock bolt 20 and penetrates in the usual way into large and small cracks in the borehole wall to seal the rock and lift any flow of water out through the boreholes and surrounding rock wall.

When the grouting is completed, the grouting equipment 22 is disconnected from the sleeve 10. The grouting nozzle is therefore also left in the borehole, as is the case with the grouting equipment described in US-A-4260295. By providing the invention with a different non-return valve than that used in the said American patent specification, it has become possible to carry out grouting and anchoring of the rock bolt in one and the same operation. In the invention, the rock bolt is used as one component of a non-return valve, the other component of which consists of the sealing sleeve 16. Because the sealing sleeve 16 is affected by the pressure in the injected borehole, this pressure will be kept sealingly pressed against the rock bolt, 10 so that the sealing mass is prevented from penetrating and instead remains in the hole during the hardening or solidification of the sealing mass. This applies regardless of whether the sealing compound is based on an inorganic or an organic sealing material. The preferred sealing compound is a cement slurry but also liquid or semi-liquid plastic material can be used for this purpose.

Claims (4)

10 15 20 25 30 35 7 509 139 PATENT CLAIMS A method of simultaneously sealing cracks around boreholes (19) (20), which injection of a sealing material into the borehole, at (23) having a sealant and anchoring a rock bolt is carried out through an injection nozzle, schett til device and which is left in the borehole after injection. - (10-14) with a through hole and a non-return vent, characterized in that the rock bolt (20), while leaving a gap, is passed through the through hole (21) through the valve nozzle and through the non-return valve device between the hole and (16, 20 ), (20) and resiliently presses the rock bolt, one of which sealing elements is formed by the rock bolt (16) and that the injection of is carried out through said gap (21) (16, 20) into the borehole whose other sealing element seals against the rock bolt, (23) and through the non-return valve device (19). Injection device for injecting a seal (23) into a borehole (19), injector nozzle with expandable towards surrounding boreholes (10-14) (16, 20), wherein the injector nozzle has a continuous (16, 20) injector nozzle inwards towards the borehole the sealing material comprising a sealing sleeve and a non-return valve device hole and the non-return valve device is arranged at the characteristic thereof, (16, 20) which is arranged at the inlet material (19) of the injection nozzle and has a through hole for sealing non-return valve device (s). 16), towards the borehole is formed by a sealing sleeve facing end and which is formed by a (17), connected to the through hole of the injection nozzle, which is where the through hole of the injection nozzle has a larger diameter than a rock bolt intended for use with the injection device (20) (16) (17) several portions with a smaller diameter than this rock bolt for and wherein the through hole of the sealing sleeve has one or 509 139 8 10 elastically pressed against the rock bolt and together with (16, 20). Injection device according to claim 2, this forming the non-return valve device characterized in that the through hole of the sealing sleeve (16) (17) of the injection nozzle. through holes are tapered in the direction from Grouting device according to Claim 2 or 3, characterized in that the sealing sleeve (16) has inwardly projecting sealing ridges (18) (20) on its inside. or lips for pressing against the rock bolt