NO131948B - - Google Patents

Description

Anchor bolt.

The invention relates to the Æorankringbol-

ter of the kind that is provided with a de-

long extension part for insertion into the drill hole (e.g.

e.g. a hole in clay, rock, stone or masonry), in that an expander-like fastening member is attached to one end of this part which engages with the walls of the hole in a position which is located at a distance from the open end of the hole (f eg at or near the bottom of the borehole, and to the other end is attached a compression screw which rests against the rock or another surface around the mouth of the borehole and which exerts pressure on this surface and preferably also on the surrounding surface.

Such anchor bolts have many prac-

tical applications. They are used e.g. often in mines (both in ore and coal mines) as roof supports, and will be referred to below as roof bolts, without the invention being thereby limited to applying to a roof support. Roof supports are e.g. necessary when mining operations are conducted in rock

layers that have been heavily cracked and broken up, and the bolts are used to hold or

fix the broken layers to the overlying solid rock, while working up and removing

ner cracked rock or ore. To achieve

this, boreholes are drilled (usually at a depth of a few meters) with a specific design

ning through the broken layers all the way to the solid rock, then the roof bolts are inserted into the hole and fasteners arranged at the bolt-

the end is usually caused to expand by turning the roof bolt to keep the bolt engaged with the fixed rock. The compression screw is then pulled towards

surface of the broken rock, preferably with the aid of a pneumatic wrench to a specific torsional load (the size of which depends on the type of rock to be processed), whereby the bolt un-

where tension attaches the broken layers to the solid rock.

In the current roof bolts, the anchoring part has a rigid construction, which in certain cases means that inserting and removing the bolts becomes a time-consuming and difficult operation, especially in limited spaces (e.g.

in low shafts) and/or in the often-occurring cases where the drills have shifted and the hole is not sealed.

The purpose of the present invention

see is to reduce or avoid these disadvantages. The invention provides a roof bolt comprising an elongated tension member consisting of a length of flexible steel wire, cable or rope to the ends of which a screw-threaded end piece is attached, an expansion screen el-

ler other expander-type fastening means is attached to one of the end pieces for Engaging with the hole and while on the other end-

part is equipped with a nut and a carrier

plate which, by pressure from the nut, is brought into engagement with the surface to be supported.

The cable or rope should preferably

be able to transfer a significant torsional load in each direction without re-alignment. Thus, the rope may comprise rope strands wound in one direction on core strands or core threads wound in the other direction. It is further preferred that

the rope is constructed as indicated in the British patents 794 411 and 794 412.

Various embodiments of expandable fastening means can be used in the invention and some of them will be described later.

The end parts can be attached to the rope or cable in different ways and more examples of this will be given later.

In the following, for example, some embodiments of roof bolts according to the invention are described with reference to attached drawings where: Fig. 1 shows a complete roof bolt. Fig. 2 shows one of the end parts in position on the rope ready for swaging. Fig. 3 shows in section the end part and the rope according to fig. 2 after hammering (swaging). Fig. 4 is a section showing an alternative embodiment of the end part of the rope end. Fig. 5 is a section through a rope used in the bolt. Fig. 6 is a side view showing a construction of the expansion screen. Fig. 7 is a diagram similar to fig. 6, but shows the insertion of the screen into a hole. Fig. 8 is a side view of one of the expandable cups used in the one of Fig. 6 and 7 displayed screen. Fig. 9 is a ground plan of the one in fig. 8 shown cup. Fig. 10 is a side view of another embodiment of the expandable cup

fig. 11 is a diagram corresponding to fig. 6, showing another construction of the echo expansion screen.

In the one in fig. 1, the tension part consists of a length of steel wire rope 20 to the ends of which screw-threaded end parts 21, 22 are attached coaxially with the end of the rope. The end part 21 has threaded over it a gripping device, usually known as an expansion screen, which comprises an external, short tube-like part 23 provided with a fluted circumference with, in this case, four equally spaced longitudinal slits 24 which extend from a end almost to the other end and thereby form four elastic blades 25. This pipe consists of malleable iron in the form of a casting. Next to rifling, each blade has an axial or longitudinal nib 26 near the free end of the blade to form an anti-rotation key. In the first-mentioned end of the tube fits a cast, internally threaded, conical nut 28 which is screwed onto the output end of threads in the end part 21 and which, when the end part is turned in the nut, penetrates between the 'blades 25 and expands them. A breasting 29 on the end part limits the movement of the pipe 23 along the end part.

The end part 22 passes through a hole in a steel bearing plate 30, which in this case is square or rectangular. One

nut 31 is also screwed onto the end part.

When during use the roof bolt is to be inserted, the conical nut 28 is screwed back to allow the blades 25 to close and to contract to their smallest diameter.

This end of the bolt is then inserted into a hole in the rock or other material that it is to support, until almost the entire length of the bolt is inside the hole.

The end part 22, the threaded portion of which protrudes from the hole, is rotated until a sufficient torsion has been transmitted to draw the conical nut into the tubular part 23 and thereby force the blades 25 apart and into engagement with the walls of the hole.

The carrier plate 30 is then allowed to slide over the threaded part of the end part 22 followed by the nut 31 and a pneumatic wrench is given the desired load and applied to the nut. The plate 30 is thereby brought into pressure engagement with the ceiling or with another surface to be supported, and the cable acts as a tension part that supports the lower or outer structure.

In those cases where it is possible and desired to be able to recover the bolts after the mining work has ended, said roof bolt is removed by loosening the nut 30 on the bearing plate and by striking the free end of the bolt in an upward direction. This drives the tapered nut up or into the hole and releases the expansion screen. When necessary or desired, the tension member can be rotated a few revolutions counter-clockwise before the upward stroke is applied, thereby ensuring that the parapet 29 is retracted from the end of the screen.

As already mentioned, different methods can be used to design and attach the threaded end pieces to the rope or cable. In a method shown in fig. 2 and 3, the end part to be attached is provided at one end with an externally threaded part 34 and at the other end with an internal sleeve-shaped part 35 which is coaxial with the threaded part. On the outside, the sleeve-shaped part has two diameters 36, 37. The end of the rope 20 is inserted into the part 35, and the part 36 is hammered or pressed down to the size of the part 37. This plastically deforms the metal in the sleeve wall to engage with the rope and also causes the free ends of wire units in the rope to extend outwards into the inner, non-hammered end 38 of the sleeve-shaped part (see Fig. 3) and provides an additional key or anchorage.

Another method, shown in fig. 4, consists in shaping the end part of a length of pipe 40 into which the end of the cable or rope 20 is inserted. The pipe is then hammered over its entire length on the cable or rope and finally a thread 41 is cut or rolled along the end part of the pipe.

A third method consists in inserting the end of the cable or rope into the pipe for about two-thirds of the length of the pipe and in hammering the pipe from the end at which the rope or cable is inserted, almost to the end of the rope, whereby the rope is gripped while the wire ends can :spread freely, as already described. A piece of a threaded rod is then inserted into the other end of the tube, with part of the rod protruding from the tube. Finally, the pipe is hammered onto the rod and the hammering is continued until the pipe is firmly deformed on the threads and the threads themselves are deformed into locking engagement with the pipe.

The rope used in the examples mentioned above and in the examples to be described later consists of six strands 42 of 9 x 9 x 1 wound to the left on a core of 9 x 9 x 1 wound to the right. Each strand 42 and also the core has that in fig. 5 shown form and is produced using the method shown in British patent no. 794 411 and 794 412. The rope can transmit a significant torsion in each direction of rotation and has a significant tensile strength. Furthermore, it has a greater shear resistance than a fixed rod, as roof bolts are occasionally exposed to shear forces due to the fact that the rock layers tend to slide over each other.

Fig. 6-9 show another construction of an expandable fastening device. In this construction, the device comprises a series of four cup-shaped parts 50 threaded over the screw-threaded part of the end part 21 towards the parapet 29. Each of the cup-shaped parts 50 has a base surface 51 with a hole 52 threaded over the end part and with sides that by means of recesses 53 is divided into tongues 54. The tongues 54 are flexible, or highly connected to the base surface, and they spread outwards from the base surface so that, as shown in fig. 7, the tension part can press into the drill hole with the base surfaces 51 first and with the tongues 54 compressed against the walls of the hole, while release from the hole is prevented by the tongues 54 engaging with the hole's

walls with knee joint action and tend to open outwards and to cut into the walls. With this construction, the expansion takes place by pulling on the cable without turning. The cups are held on the end part by means of the nut 57 and are separated by means of collars or spacers 58. The cups consist of impact-resistant elastomer which is described later.

The eggs on the different cups in the row are staggered, and they can have different lengths. The depth of the recesses 53 can also be varied.

In a modification of this construction, the plastic cups, as shown in fig. 10, shallow and without eggs or tongues. The surface of the cups or their outer edges can in both constructions be corrugated. The peripheral edges or the edge of the tongues can also here be provided with notches or serrations.

In the one in fig. 11 construction shown are the four cup-shaped parts of that in fig. 6 shown example set upside down on the end piece so that their mouths face the adjacent end of the piece. The tongues 54a or the walls of the cups are flexibly inclined inwards. Within each cup there is a tapering (with truncated cone shape) part 60 which, when moved into the cup, opens the mouth of the cup (ie spreads out the tongues). The two-sided end of each intermediate taper supports the base of the adjacent cup. The last of these parts (i.e. the part 60a which is located closest to the end of the bolt) is screwed onto the end part 21 and a nut is placed on the bolt which rests against this part. The cups can be with or without tongues, as described above. In this example, the tapered portions are retracted to allow the walls of the cups to be contracted inwards. The bolt is pushed into the hole, with the mouths of the cups coming first. Rotation of the tension member then causes it to screw into the nut or into the last tapered portion which causes the cups to expand to engage the walls of the hole.

A suitable elastomer for making the cups is sold by the British Geon Co. Ltd. under the name R. A. 170 High Impact polyvinyl chloride, but other elastomeric substances with similar physical and chemical properties can be used.

It is possible within the scope of the invention to replace the row of cups in each of the described constructions with just a single cup.

The bolts according to the invention can be used

to support roofs in mines from overhead

layer and they can also be used to start

solid mine walls and floors.

Claims (12)

1. Anchor bolt or ceiling bolt, characterized by a tension part (20) consisting of a length of flexible steel wire, cable or rope, to the ends of which are attached screw-threaded end pieces, (21, 22, 40), an expansion screen rim or other expandable fastening device (23, 28, 50, 57, 58, 60) attached to one of the end parts (21) for engagement with the drill hole or the like, as a nut (31) and a bearing plate (30) are placed on the other end part (22) which, when pulled from the nut, engages the surface on which the drill is supported. 2. Ceiling bolt as stated in claim 1, characterized in that the cable or rope (20) comprises rope strands wound in one direction on core strands or core wires that are wound in another direction in order that the hollow can absorb torque in both directions of rotation, as that the roof bolt can be loosened after use. 3. Roof bolt as specified in any of claims 1-2, characterized in that the fastening device comprises a cup-shaped part (50), threaded over an end part (21) of the tension part and whose sides (54), which are flexible or connected to the base surface (51), lies along the length of the stretch part (20) and diverges or tends to diverge outwards from the base surface, so that the stretch part can be pushed into the hole by first introducing the base surface (51) of the cup-shaped part (50), whereby the sides are compressed against the walls of the hole, and detachment of the part from the hole is prevented by the sides (54) or the edges of the cup-shaped part engaging with the walls of the hole by knee joint action and by having a tendency to open and press into the walls. 4. Roof bolt as stated in claim 3, characterized in that a number of cup-shaped parts (50) are kept at a distance from each other along the end part (21) of the tensile part. 5. Roof bolt as indicated in claim 1 3 or 4, characterized in that the cup-shaped part or each of these parts consists of a highly impact-resistant elastomer. 6. Roof bolt as specified in any one of claims 2-5, character characterized by the fact that recesses are provided in the sides of the cup-shaped part, or at least one of these parts when there are several parts, in the entire depth of the cups or in part of this depth counted from the mouth, at intervals around the cup to produce eggs or blade (54). 7. Roof bolt as stated in claim 6, characterized in that there is a row of cups (50) provided with eggs (54) and that the eggs of the successive cups along the row are offset in a circumferential direction. 8. Roof bolt as stated in any of claims 1-3, where the fixing device comprises a cup-shaped part consisting of impact-resistant elastomer, one end of which is threaded over an end part of the tension part, and whose sides face this end of the part, characterized by funds being arranged, e.g. a breasting on the end part (21), which supports the outer surface of the cup, that a tapered part (60) is led over said end part, its narrow end penetrating into the cup and facing the stretch part, as well as threaded devices (60a) (or a nut) which engages with the screw-threaded end part and when the tension part rotates, pulls the tapered part into the cup and thereby expands its sides in pressure engagement with the walls of the hole in which the cup is inserted. 9. Roof bolt as stated in claim 8, where a number of cup-shaped parts are arranged, characterized in that each of them is provided with such a tapering part (60). 10. Roof bolt as stated in any of the previous claims, characterized in that at least one end part (21, 22) has an external screw-threaded part (34) at one end and an internal sleeve-shaped part (35) at the other end which is coaxial with the threaded part (34) and which occupies the end of the rope or cable (20), the walls of the sleeve-shaped portion near the mouth being hammered or pressed inward to engage the rope or cable, and the ends of strands of the rope or cable extending into the sleeve-shaped portion (at 38) beyond the portion which is hammered or pressed. 11. Roof bolt as specified in any of claims 1-9, characterized in that at least one end part of the end parts (21, 22) consists of a length of pipe which surrounds the end of the rope or cable (20) and is hammered into engagement with the rope, a screw thread is formed on at least part of the tube's outer side. 12. Ceiling bolt as specified in any of claims 1-9, where at least one end part consists of a length of pipe which from one end over part of its length surrounds and tightly encloses the end of the rope or cable, characterized in that the other end surrounds and tightly grips a rod, as the rod has a threaded part, which protrudes from the tube.