DE2405883C3 - Mountain anchor - Google Patents

Description

The invention relates to a rock anchor corresponding to 6ο corresponding to the preamble of claim 1.

From FR-PS 15 25 224 a rock anchor has become known, which consists of a pipe from a elastic material. This tube is open at both ends and is parallel to its longitudinal axis 6s over its entire length with a slot-shaped recess extending through its entire wall thickness Mistake. This pipe, which serves as a rock anchor, is inserted into a borehole in the rock To brace the rock anchor, a threaded spindle is screwed into the pipe, through which the pipe wall is pressed against the mountains. A disadvantage of the known rock anchor is that in his Installation two different work steps are necessary. Furthermore, this rock anchor is expensive to manufacture, because a threaded spindle is used

A mountain anchor is from the DT-AS 1178815 became known, which consists of a pipe in the end portion lying in the mountains a wooden bolt The rock anchor is first inserted into the hole provided in the rock, whereupon a wedge is driven into the wooden floor, so that the corresponding end portion of the pipe expands and thereby comes into frictional engagement with the mountains surrounding it. A disadvantage of this known Mountain anchor consists in the fact that it is not over its entire length, but only over a small one Section can be brought into engagement with the mountains. Also with this anchor there are two when installing Work steps are necessary, namely first the anchor must be inserted into the hole and then the wedge be hammered in, which presses the wooden bolt apart.

From de- US-PS 28 13 449 a rock anchor has become known, which has a complicated design The end section of this tubular rock anchor lying deepest in the mountains is with provided several disks, which are spaced one above the other and have central bores. These bores are essentially frustoconical Cross-section. After the rock anchor has been inserted into the borehole, from its free end is shot in by a bolt that expands the individual disks, creating the cylindrical Outer wall of the rock anchor is widened at the points where the discs are. A disadvantage of this rock anchor is that it is expensive to manufacture because of the special disks must be made, which is fixed at one end of the rock anchor, for example by welding to be ordered. Another disadvantage is that here, too, two different operations Installation are necessary and that only the end section of the rock anchor with the mountains surrounding it in Intervention can be brought about.

Another rock anchor is from DT-PS 9 36 204 became known, which, however, is designed completely differently than the rock anchor according to the invention. This well-known mountain anchor consists of two different building materials, one of which is a high one Elasticity and the other has high tensile strength. This mountain anchor has a tubular shape Shaft inside one or more ropes made of steel wire or textile materials or a round steel rod is arranged to absorb the tensile forces. The rock anchor is braced with the help of a Wedge that is driven into the mountain anchor. This mountain anchor has the disadvantage that its Manufacture is relatively complicated and that it only covers part of its entire length with the him surrounding mountains can be engaged.

An object of the invention is to provide a rock anchor that is simple and inexpensive can be produced and installed quickly and, if necessary, automatically, whereby it is in the built-in state not just over a section

its length is in engagement with the mountains surrounding it

A solution to this problem is given by the characterizing part of claim 1.

A major advantage of the S rock anchor according to the invention is that it can be installed in a single operation. When being introduced into the borehole, the anchor is compressed at the end with which it is introduced into the borehole comes into frictional engagement with the surrounding mountains. The rock anchor can then easily be driven into the borehole. As a result, the rock anchor is installed in a single operation, as it does not require any additional means for bracing. The dimensioning of the slot-shaped recess extending over its entire length and penetrating its entire wall thickness ensures that, on the one hand, the cross section of the anchor can be changed so that it fits into the borehole and, on the other hand, this change is caused by the change in cross section of the built-in anchor counteracting forces are sufficient to press the anchor firmly against the mountains surrounding it almost over its entire length. Thus it is not mn over a portion of the surrounding mountains engaged. Furthermore, there is an advantage that when installing such anchors in hanging rock this normally lowering rock lifts during installation, whereby the various rock layers are strengthened.

In an advantageous development of the invention, the ratio between the radial thickness of the tubular anchor bolt and its outer diameter at most about 1: 5 and at least about 1:50 be. Such a dimensioning can ensure that a plastic deformation of the tubular anchor body is possible while moving into the bore.

In a further development of the invention, the ratio z-.vischen the length of the tubular Anchor bolt and its outer diameter should be at least about 16: 1. This ensures that there is sufficient engagement between the tubular bolt and the mountains surrounding it.

In a training in which the outer circumferential dimension of the tubular anchor bolt is at least is about 50 mm, you get a mountain anchor that is securely anchored in the mountains Results are obtained even if one takes various measures that further develop the invention serve, combined with each other, so z. B when the ratio between the length of the tubular Anchor bolt and its outer diameter at least 16: 1 and the outer circumferential dimension of the Anchor bolt is at least 50.8 mm

Embodiments of the invention are described below with reference to the drawings. It indicates

F i g. 1 shows a side view of an embodiment of a tubular anchor bolt,

F i g. 2 shows the top view of the anchor bolt according to FIG. 1,

F i g. 3 is a side view in which the anchor bolt according to FIG. 1 its position of use in a borehole in the ceiling of a mine tunnel or another occupies underground opening,

F i g. 4 shows a section along the line 4-4 in FIG. 3 and F i g. 5 shows a reduced rxial partial section a second embodiment of a tubular anchor bolt, which is its position of use in a Occupies a hole in the ceiling of a mine tunnel or other underground opening

In Fig. 1 and 2, a tubular anchor bolt 10 for rock is shown, which is of relatively simple construction and can be manufactured at low cost, but it enables a formation in a very effective manner, e.g. B. to stabilize the ceiling or a side wall of a mine tunnel or other underground opening. According to the drawing, the anchor bolt 10 is designed as an elongated, generally ring-shaped, tubular anchor body 12 which is open at both ends and which has a single, longitudinally extending, straight slot-shaped recess 14 which extends over the entire length of the body 12 and over the entire radial one Thickness T of the body extends The body 12 has no other openings, it is generally cylindrical in shape, the outer diameter of the body is constant over its entire length, and the ratio between the length of the body and its outer diameter is at least about 16: 1 and preferably about 32: 1 or 48: 1, but one could also build such anchor bolts of greater length from interconnected sections, in which the said ratio is 16: 1 or more in each case extending edge portions 16 of the body rs 12 formed The width W of the slot-shaped recess 14 measured in the circumferential direction is so large in the uncompressed state of the anchor body 12 that there is a distance between the edge sections 16 in the circumferential direction which enables the body 12 in the circumferential direction in one compress a substantial amount so that it can be inserted into a bore the diameter of which is considerably smaller than the original outer diameter of the body. The outer circumferential dimension of the body 12, excluding the width W of the slot 14, is greater than about 50.8 mm, and the width W of the slot 14 corresponds at most to about 25% of the total outer circumferential dimension of the anchor bolt 10, that is, it is no greater than about 25% of the complete ring that is formed by the body 12 and the slot-shaped recess 14.

The body 12 is made of steel so that it is compressed to a considerable extent in the circumferential direction can be inserted into a bore with a significantly smaller diameter to be able to, and so the body after insertion into such a hole strives to Spread open so that the outer peripheral surface of the body is in frictional contact with the Anchor bolts surrounding the bore wall occurs to the formation in question, z. B. the ceiling of a mine tunnel, to solidify. It can be seen that the anchor bolt 10 does not have any form elements that prevent such a significant compression of the body 12 in the circumferential direction, and that the Interior 18 of the body 12 is completely open or empty. The outer diameter of the anchor body 12 is for every hole with a certain diameter like this

chosen that it is considerably larger than the diameter of the bore, but that the edge portions 16 of the body form a butt joint or only separated by a relatively narrow gap after the anchor bolt has been installed in the associated hole. The relation between the radial thickness Γ of the body 12 to the outer diameter of the body is at most about 1: 5 and at least about 1:50, so that a plastic deformation of the body during retraction into the Drilling is possible; although the body 12 according to the drawing has a constant between its ends Outside diameter, but the outside diameter of the front end could be smaller than the outside diameter the remainder of the body to facilitate insertion into the bore.

F i g. 3 and 4 show the tubular anchor bolt 10 according to FIG. 1 and 2 in one when installed pre-drilled hole 20 in a ceiling 22 to be consolidated. While driving into the bore the body 12 of the anchor bolt 10 is deformed in the plastic range so that the following equation applies:

1.19

Is in here

ο the difference between the outer diameter of the body 12 before insertion into the bore and the outer diameter of the body after insertion,

D is the outside diameter of the body 12 before the Introduce,

t is the radial thickness of the body 12,

E is the modulus of elasticity and

y is the yield stress of the material.

As shown in the drawing, the outer peripheral surface of the body 12 of the built-in anchor bolt 10 stands over the entire length of the body in frictional contact with the surrounding wall of the Hole 20. This anchors the anchor bolt to the wall of the hole. The outer peripheral surface of the Body can of course be epoxy coated, roughened, or otherwise designed be that an increased frictional engagement between the anchor bolt and the bore wall is achieved. According to Figure 3, the body 12 of the anchor bolt such a length that it extends essentially over the the entire length of the bore 20 extends. The force that

s would have to be applied in order to pull the built-in anchor bolt out again after installation, is slightly greater than the compressive force required to insert the anchor bolt into the bore 20; if the installation compressive force is known, it can be

ι ο also determine the force required to pull it out.

In Fig. 5. in which the parts correspond to those shown in FIGS shown correspond, each with the same reference numbers, but with the addition of the letter a, denoted, is part of a tubular

ι s anchor bolt 10a shown for rock, which differs from the anchor bolt 10 described only in that it additionally has a device for tensioning the body 12a after it has been inserted into the bore 20a . According to FIG. 5, the body 12a of the anchor bolt 10 is inserted into the bore 20a so that a small portion 24 with a length of several centimeters protrudes from the bore 20a. An anchor plate 26 with a central opening 28 for receiving the body 12a belongs to the anchor bolt 10a. The plate 26 rests on the underside of the ceiling 22a . Furthermore, the anchor bolt 10i includes a wedge-shaped pin 30 which, after the body 12a has been installed in the bore 20a directly below the plate 26, is driven into two coaxial openings 32 and 34 of the body 12a in order to tension the body.

In order to stabilize the mountain with the aid of the inventive mountain anchor, the mountain is with provided a hole in which the circumferential compressible rock anchor is introduced. The outer diameter of the rock anchor is dabe chosen so that it is larger than that of the hole. When driving the anchor, this will consequently be in the hole Compressed in the circumferential direction. The slit-shaped recess that extends over the entire Length of the tubular anchor bolt extends partially closed. So it is tubular! Anchor bolt essentially over its entire length with a friction fit on the wall of the bore, so dal the mountain formation is stabilized and consolidated.

1 sheet of drawings

Claims (7)

Patent claims: 1. Mountain anchor for anchoring the roofs and joints of underground pits, which consists of a tubular, below and above open anchor bolt made of elastically and / or plastically deformable material, which over its entire length with a slot-shaped recess extending through its entire wall thickness ο see and can be braced within a borehole, characterized in that the outer diameter of the tubular anchor bolt (10, 12) is greater than the inner diameter of the bore (20) receiving it and the circumferential width (W) of the slot-shaped recess (14) is at most 25% of the circumferential dimension of the anchor bolt (10, 12), but is at least selected so large that the tubular anchor bolt (10, 12) can be introduced into the borehole (20) while reducing its outer diameter and can be braced in it 2. rock anchor according to claim 1, characterized in that the ratio between the Length of the tubular anchor bolt (12) and its outer diameter at least about 60: 1 amounts to. 3. Rock anchor according to claim 1, characterized in that the ratio between the radial thickness (T) of the tubular anchor bolt (12) and its outer diameter is at most about 1: 5 and at least about 1:50. 4. rock anchor according to claim 1, characterized in that the outer circumferential dimension of the tubular anchor bolt (12) is at least about 50.8 mm. 5. rock anchor according to claim 1, characterized in that the outer peripheral surface of the tubular anchor bolt (12) is at least substantially free of openings. 6. Rock anchor according to claim 1 or one of the preceding claims, characterized in that that the ratio between the length of the tubular anchor bolt (12) and its outer diameter is at least about 16: 1 and that the outer circumferential dimension of the anchor bolt (12) is at least 50.8 mm 7. rock anchor, characterized in that on the protruding from the borehole (20) end of the tubular anchor bolt (10, 12) in a known manner on the mountain supporting anchor plate (26) can be pushed on, which by means of an anchor bolt (10,12) perpendicular to its longitudinal axis penetrating wedge-shaped pin (30) can be braced against the mountains.