SE458133B - Drilling process for quarrying and mining - Google Patents

Abstract

In the drilling process, a continuous line is used to move a feed pipe to a position where a hole is to be bore in rock. A line (16) is fed through the feed pipe into the bore hole, and then the pipe is pressed to seal against the bore hole wall. The process then involves feeding a cement medium through the pipe, and the pipe is then removed and the line severed. To seal the space between the line and the pipe, a seal (20) is compressed between them axially. This seal is an elastic, compressible ring forming a passage hole which is diminished radially, when the ring is axially compressed.

Description

458 133 2 so that the air in the borehole can be led out of the hole. Another function of the rotor disk is to act as a seal around the line, and the disk itself is sealed against the frame of the rotating device and against its end plate. Insufficient sealing can occur, however, between the hole in the rotor disc and the line, especially if the disc is worn and does not fit snugly to the shape of the line, the disc consists of a solid piece. The object of the present invention is to provide a method and equipment for avoiding the disadvantages described above and to allow sealing and position retention of the rope in a simple manner, when a cheap rope of ordinary construction is used.

This is achieved by means of a method according to the invention, which is characterized in that the seal is compressed axially for radial contraction of the seal around the line to contact with the circumferential surface of the line and by means of an equipment characterized in that the feed pipe has two guide pipes are mounted axially slidably inside each other, that the sealing ring is mounted axially between the guide tubes, so that one end of the sealing ring is axially stationary relative to one of the guide tubes, and that the other end is axially displaceable by means of the other guide tube.

The invention is based on the idea that the sealing and position holding of the line is effected by means of an axial movement, by which a radial contraction of the seal of elastic material around the line is effected, so that when pressed against the line both seals the line and holds it in a reliably in position during feeding and curing of the cementing agent. The sealing method is based on an elastically compressible seal and is not sensitive to abrasion and can adapt itself to diameter variations that may occur in the ropes.

It is characteristic of all embodiments that the sealing ring is compressed axially and thanks to elasticity at the same time radially against the rope. that the invention will be described in detail below with reference to the accompanying drawings.

Fig. 1 shows from the side a preferred embodiment of a bolting equipment according to the invention.

Figures 2 and 3 show enlarged axial sections of the front end of the feed pipe of the bolting equipment at two different operating positions.

Figures 4-7 show axial sections of alternative embodiments of the front end of the feed pipe.

The rock bolting equipment in Fig. 1 has a transfer beam 2, which is supported by means of a cradle 1 and is movable in the longitudinal direction relative to the cradle on sliding shoes 3 by means of a cylinder 4, which acts between the transfer beam and the cradle. The beam carries a feed mechanism S for the line, which mechanism may possibly have the construction described in us 4 155 409 and which is movable in the longitudinal direction on the transfer beam by means of a setting cylinder 6, which acts between the transfer beam and the feed mechanism. A feed tube 7 projects from the feed mechanism parallel to the transfer beam, the front portion of the tube being supported on a carriage 9 by means of a support 8. The carriage 9 is movable longitudinally on the transfer beam by means of a transfer cylinder 10 acting between the carriage and the feed mechanism.

The feed tube 1 Figs. 1-6 is telescopic and comprises an outer guide tube 11 and an inner guide tube 12, which can move axially relative to each other. Attached to the front end of the outer guide tube a pair of nosepieces 13, which is provided with a rubber tip 14. The nosepiece is provided with an axial hole 15, through which the line 16 is intended to be fed and from which are branched a channel lf for a cementing agent and a channel 18 for an air hose 19.

In the embodiment in Figs. 1-3, the inner guide tube of the feed tube is attached to the support 8 of the carriage 9. Inside the outer guide tube, a sleeve-shaped sealing rubber 20 is attached between the nozzle piece and an annular press member 21, which is attached to the end of the inner guide tube.

The equipment is also provided with a cutting member 22, which is hingedly mounted on the transmission beam for cutting the line.

The rock bolting is accomplished as follows: By adjusting the transfer beam 1, the feed pipe 7 is aligned with the hole 24 drilled in the rock 23. By moving the feed mechanism 5 by means of the cylinder 6 and the carriage 9 by means of the cylinder 10, the nose piece 13 is guided axially to a position opposite the drill heel and the nosepiece, a certain distance is pushed into the hole (in this case into the hole), for the purpose of a protective tube 25, which is mounted to exclude displacement in the transverse direction- Then the line 16 is fed from a roller feed mechanism via the guide tubes , the sealing rubber and the nose piece into the borehole. The end of the air outlet hose 19 is attached to the end of the rope, so that the rope pulls the hose into the hole. (Fig. 2). 26 by means of After feeding the line, the feeding of the cementing agent begins. First, the feed tube is pushed forward by the transfer cylinder 10, so that the conical rubber tip 14 is pressed tightly against the end edge of the protective tube. This sliding is maintained by means of the displacement cylinder, whereby movement of the outer guide tube 11 becomes more difficult when the rubber tip is compressed. Thereby, the inner guide tube 12, on which the pushing force acts, is displaced axially forward relative to the outer guide tube and compresses the well-shaped sealing rubber 20 placed around the rope axially. As a result of this axial compression, the sealing rubber is pressed radially against the line and with sufficient compression seals the space between the line and the nose piece. When the seal is made in this way, the cementing means is fed by means of the pump 27 through the channel 17 in the nozzle into the borehole, the air present in the hole being discharged through the air outlet hose, when the cementing means penetrates into the hole without obstructing 458 133 the supply of this agent.

When a sufficient amount of cementing agent has been fed, the feeding of cementing agent is interrupted and the inner tube is pulled back by means of the transfer cylinder 10, whereby the sealing rubber is released from compression and expanded away from contact with the line. When the inner guide tube is moved further back, it is pulled along the outer guide tube with the nose piece in the direction of the feed mechanism. Finally, the line is cut off by means of the cutting member 22.

In the pressing member 21 fixed to the guide tube between the sleeve-shaped sealing rubber and the inner guide tube, there is a conical hole 28 which faces the guide tube and which guides the line into the tube via the sealing rubber without destroying it. In the described embodiment, the same power source, i.e. a hydraulic displacement cylinder, is used in order to displace the outer guide tube into sealing contact with the borehole and to compress the sealing rubber into sealing contact with the line. As an alternative, it is possible to fasten the outer guide tube to the support 8 of the carriage 9 and to install a hydraulic displacement cylinder 10 'between the outer guide tube and the inner guide tube, as shown in Fig. 4.

In the embodiment in rig S, the inner guide tube engages the outer guide tube by means of a threaded adapter 29. The outer guide tube is attached to the support of the carriage 8. In order to rotate the inner guide tube about its symmetrical axis relative to the outer protective tube, a rotating device 31 arranged, which is only schematically damaged. When the inner guide tube is rotated, it moves axially in the direction of the sealing rubber and compresses it axially. In the embodiment shown in Fig. 6, the hole passing through the nozzle 21 * of the inner guide tube is formed with a wedge surface 21a having the shape of a double cone, and the end of the sealing rubber 20 'facing the nozzle is provided with a corresponding, conical wedge- M 458 133 6 surface 20a. When the nozzle is pushed against the sealing rubber, the nozzle compresses this both axially and radially.

In the embodiment shown in Fig. 7, the feed tube has only one outer guide tube 11, to which the support 8 of the carriage is attached. Inside the guide tube is mounted a hydraulic cylinder-piston structure, the piston 31 of which is axially slidable towards end pieces 32. Inlet and outlet ports for pressure fluid are indicated by reference numerals 33 and 34. When the piston is pressed in the direction of the sealing rubber, it compresses it axially , so that the rubber is pressed radially against the rope. Instead of a double-acting cylinder, a single-acting hydraulic cylinder can be used, in which the piston is returned by means of the compression force of the sealing rubber.

The drawings and description above are intended only to illustrate the inventive idea. In its details, the equipment according to the invention may vary within the scope of the appended claims. Instead of a sleeve-shaped seal, it is possible to use a seal with the shape of, for example, a truncated cone, whereby the tip of the cone can be oriented in any direction. However, it is preferably oriented away from the rock, so that the pressure generated by the cementing agent presses the seal even more tightly around the line and thereby improves the seal. Correspondingly, it is possible to use a seal in the shape of a double cone, whereby the seal becomes conically narrower in both directions from the center of the seal. Round or annular seals formed in different ways as well as groups of seals, which possibly consist of several seals with the same or different shapes, can also be used according to the invention.

Claims (5)

10 15 20 25 30 458 133 PATENT REQUIREMENTS A method of rock bolting by means of a continuous line, wherein a feed pipe (7) is moved to a position opposite a hole (24) drilled in a rock, a line '(16) is fed through the feed pipe into the drill the hole, the feed pipe is pressed against the borehole for sealing the feed pipe relative to the rock, the line is sealed by means of a seal (20) relative to the feed pipe, the seal (20) is compressed axially to contract the seal radially around the line (16) circumferential surface, a cementing agent is fed through the feed pipe into the borehole, the feed pipe is moved from the borehole and the line is cut off, characterized in that the feed pipe (7), which is pressed against the borehole (24), is further pressed in the direction of the borehole for axial compression. 20). Equipment for * rock bolting by means of a rope, which equipment comprises a transfer beam (1), a feed pipe (7) supported by the beam, the end of which is provided with a nose piece (13), a displacement device (10) for movement of the feed pipe axially along the transfer slide, a means (5, 27) for feeding the line and a cementing means through the nose piece, an elastically compressible sealing ring (20) supported by the feed pipe, which forms a fitting for the line (16), which hole is radially reduced , when the sealing ring is compressed axially, and a drive mechanism (10: the ring, characterized in that the feed 10 '; 30; 31) for axial compression of the sealing tube (7) has two guide tubes (11, 12), which are mounted axially slidably inside each other, that one end of the sealing ring (20) is axially stationary relative to one is mounted axially between the guide tubes, so that the guide tubes (11) are sealed, and that the other end is axially displaceable by means of the other guide tube (12). 458 135 10 15 Equipment according to claim 2, characterized in that the inner guide tube (12) of the feed tube (7) is attached to a support (8), by means of which the feed tube is supported axially displaceable on the transfer beam (1), and that the drive mechanism (10 ) comprises the transfer device for the feed pipe, which acts between the support and the transfer beam. Equipment according to claim 2, characterized in that the drive mechanism (10 ') comprises a pressure medium cylinder which acts between the outer guide tube (11) and the inner guide tube (12). Equipment according to claim 2, characterized in that the sealing ring (20 ') is provided with a conical wedge surface (20a), by means of which the sealing ring is pressed against a surrounding wedge surface (21a) in the inner guide tube ( 12).