EP0861986A1 - Anchor for rock or concrete - Google Patents

Abstract

The nut has a central and axial threaded hole (7) for a threaded bar. A number of discs (1) rest on the outside of the conical nut (2) whose first end has a smaller periphery than the second end (6). The conical nut is movable axially in the discs. The end of the discs facing the second end of the conical nut carry a thrust-piece (4) gripping over the conical nut from outside for axially supporting the threaded bar.

Description

The present invention relates to a rock or Concrete anchor with the features of the preamble of the claim 1.

Such anchors are known from practice. you find Use in anchor removal in mining or as anchoring for tie rods in concrete testing.

In detail (in addition to the usual dowels) are the Slot wedge anchor, the expansion sleeve anchor and the Double wedge anchor known.

The slot wedge anchor carries one at the end of its rod Slot, which when the anchor is driven in by an Bore-supported wedge is expanded. The Widening ensures the necessary anchoring in the rock. The disadvantage here is that the anchoring is only relative soft rock is good and the drilling depth is very good must be strictly observed so that the anchor is sufficient is expanded.

The expansion sleeve anchor has one of several at the upper end Slats existing expansion sleeve, into which by turning the Anchor rod a conical nut is pulled in while doing so the expansion slats are pressed against the borehole wall. For the axial support of the expansion sleeve there is a setting tube required that the expansion sleeve towards the Cone nut presses. The setting tube must be used to set the anchor in the borehole will be inserted and after setting the anchor be removed again. This is considered in practice considered unfavorable.

The double wedge anchor has a two-part expansion body, formed by two diagonally cut cylinder halves that are in contact with each other with their cut surface. The the smaller wedge is screwed to the anchor rod. Becomes rotated this, the wedge body moves down and pulls against the second wedge, which is the result of a Only move the stop on the anchor head transversely and thereby in Mountains can get stuck. With double wedge anchors only wear two opposite surfaces of the double wedge. Here is just one of the two wedges to increase friction ribbed while the other wedge must be smooth because it is on the bore wall slides. The holding force achieved and the Spreading of the double wedge anchor is in some Use cases not sufficient.

It is therefore an object of the present invention, a concrete or To create rock anchors that are easy with good holding power is to be set. This task is done by a concrete or Rock anchor solved with the features of claim 1.

Because the fins on the second end of the cone nut assigned end an overlapping the cone from the outside Wear abutment for axial support of the threaded rod, is the anchor only by the relative displacement of the Taper nut in the fins without additional support on Bottom of the hole or spread on a riser. Are there opposite surfaces relative to the bore wall in Quiet, so that all outer surfaces with one the friction supportive structure can be provided.

If the abutment for axial support of the threaded rod can extend into the area of the threaded hole Slats with their end adjacent to the bottom of the hole support directly against the threaded rod. It is there particularly easy if the slats each have at least one Have approach that radially overlaps the cone and after is directed inside. It also simplifies Production of the fins when the abutment with the assigned slat is in one piece. It can also be provided be that the slats are a common abutment, for example in the form of a disc inserted from the inside, carry. If, in addition, the abutment is above a certain torque can be overcome by the threaded rod, can, after securely anchoring the anchor, what the Support must be sufficient, the threaded rod through the Anchor are screwed further into the hole and thus directly for fastening plates or the like to be used.

Advantageous geometric relationships arise when a total of three slats are provided. It is preferably the surface of the cone nut facing each Slat roof-like with an angle of 120 ° to 130 °, preferably angled about 125 °.

It is also advantageous if that of the cone nut facing away surface of each lamella is at least one in The circumferential groove carries that with all slats together results in a circumferential ring groove. Here you can Holding the anchor together when not in use and a circumferential when inserted into the borehole Belay device, in the simplest case an elastic band, can be used, which holds the fins around the cone nut.

Finally, an in Circumferential direction groove can be provided, in the one Spring means is inserted. This spring means pushes the Slats in the area of the thinner end of the cone nut outside and ensures a reliable system on the Hole wall at the first moment of spreading.

Figur 1:

Einen Felsanker in ungespreiztem Zustand in einer perspektivischen Darstellung;

Figur 2:

den Felsanker gemäß Figur 1 in seiner gespreizten Stellung;

Figur 3:

die Konusmutter und zwei Lamellen des Felsankers gemäß Figur 1 und Figur 2;

Figur 4:

den Felsanker in einem Bohrloch in nicht gespreizter Stellung, in einer Stirnansicht vom Bohrungsgrund her; sowie

Figur 5:

einen Querschnitt durch den Felsanker in nicht gespreizter Stellung beim Einführen in ein Bohrloch.

An embodiment of the present invention is described below with reference to the drawing. Show it:

Figure 1:

A rock anchor in an unexpanded state in a perspective view;

Figure 2:

the rock anchor according to Figure 1 in its spread position;

Figure 3:

the cone nut and two slats of the rock anchor according to Figure 1 and Figure 2;

Figure 4:

the rock anchor in a borehole in a non-spread position, in an end view from the bottom of the hole; such as

Figure 5:

a cross section through the rock anchor in a non-spread position when inserted into a borehole.

1 shows an embodiment of a rock anchor according to the invention shown in perspective. Of the Rock anchor comprises three slats 1, the outside of one approximately hexagonal cone nut 2. The slats 1 point outside a partially cylindrical surface, which in this Embodiment with an approximately center outside on the Surface provided, circumferential groove 3 is provided. On at one end, the slats 1 each carry a Cone nut 2, radial abutment 4. The abutment 4 of each lamella 1 lies in the Unspread position according to Figure 1 on the front of the Cone nut 2.

In FIG. 2, the rock anchor according to FIG. 1 is in one spread or expanded position shown. Same Components have the same reference numbers as in the figure 1. In the representation according to Figure 2 it can be seen that the Cone nut 2 has approximately hexagonal shape and in has substantially flat outer surfaces 5 which are at an angle of about 120 ° to each other. The cone nut 2 is at its end 6 adjacent to the abutments 4 of the slats 1 slightly larger in diameter than on the abutments 4 opposite end. The cone nut 2 has an axial inside Threaded hole 7 for screwing in the usual anchor rods. The lamellae 1 face the cone nut Inside two roof-like angled surfaces 8 each are adapted at an angle to the outer surfaces 5 of the conical nut 2 and concern them. The adjacent surfaces 5 and 8 of the cone nut 2 and the lamella 1 are smooth and can therefore slide on each other. The circumferential groove 3 of three slats 1 complement each other to form a rotating one Ring in which an elastic ring 10, for example a Rubber ring, is inserted. This rubber ring 10 holds the Slats around the cone nut 2.

3 shows the conical nut 2 and two lamellae 1 shown in a kind of exploded view. Same Reference numbers in turn designate the same features. Because of the The third louvre 1 was made more clear omitted. In Figure 3 it can be seen that the Cone nut 2 between two adjacent surfaces 2 carries a rib 11 which is integral with the conical nut 2 is connected and with a rectangular cross-section over the full axial length of the conical nut 2 runs. The rib 11 prevents unintentional twisting of the cone nut 2 inside the slats 1 and thus ensures the flawless Orientation of the abutting surfaces 5 and 8 is advantageous for secure anchoring.

The rock anchor according to FIGS. 1 to 3 is in FIG unexpanded position shown in a borehole. The illustration is an axial view of the Abutment 4 seen from the bottom of the hole. The slats 1 are on the outside of the cone nut 2 and are there by the Rubber ring 10 held. The rib 11 is between two Slats 1 and prevents the accidental rotation of the Cone nut 2. The bore wall 15 surrounds the rock anchor from Outside. Inside the threaded hole 7 is for Anchoring required anchor rod 16 arranged.

FIG. 5 shows the one inserted into the bore 15 Rock anchors in a cross section from the side. The rock anchor is in an unexpanded state, so that the Cone nut 2 with its end face 6 on the abutments 4 Slat 1 is in contact (only one slat is shown). The Threaded rod 16 is so far into the threaded bore 6 screwed in that they are approximately flush with the end face 6 of the Cone nut 2 closes. In this embodiment compared to the rock anchor of Figures 1 described so far to 4 other circumferential grooves 17 and 18 are provided. The one Abutment 4 adjacent groove 17 carries a rubber ring 19, the serves the slats 1 around the cone nut 2 hold together. A rubber ring 20 is located in the groove 18, which is conical on the outside and which Abutment 4 facing a smaller extent than on the side facing away from the abutment 4. The abutment 4 opposite side of the rubber ring 20 protrudes in the outer diameter beyond the slat 1 and is dimensioned so that it even if the rock anchor on the wall 15 is not spread Bore is present.

In practice, the one described so far works Rock anchor as follows: The rock anchor is with his Cone nut 2 and three fins 1 from one in the grooves 3 or 17 and 18 inserted rubber ring 10 or 19 and 20 in unexpanded position held together. In this Position with its threaded bore 7 on a Anchor rod 16 screwed on, at most, however, until the end face of the anchor rod 16 on the abutments 4 straight is present. Now the rock anchor can be drilled in hole 15 be inserted. If the desired depth for the Rock anchor is reached, the threaded rod 16 continues in the threaded hole 7 screwed in, against the Abutment 4 presses and the slats 1 against the Cone nut 2 moves axially. Due to the abutment 4 towards increasing cross-section of the conical nut 2 and correspondingly obliquely arranged inner surface 8 of the lamella 1 the lamella 1 with high force against the bore wall 15 pressed. In difficult conditions, the Rubber ring 20 via its abutting the bore wall 15 outer lip also prevents the rock anchor from twisting to back up. In general, however, this does not appear required.

The rock anchor can therefore by means of the threaded rod 16 without additional risers or the like in the bore 15 in of any depth. It is not one exact positioning with respect to the bottom of the hole additional aid for inserting or spreading the Rock anchor required. The outer surfaces of the slats 1 are ribbed in the usual way, which in favor of Clarity of the figures is not shown. There with all external surfaces can be ribbed with this rock anchor, there is particularly good friction in the borehole.

In another embodiment, not shown can be provided that on the abutment 4th opposite end of the slats 1 on the inside, ie in the inner surface 8, a circumferential groove is provided in the again an elastic ring can be inserted. This Ring can then be provided, the slats 1 already in unexpanded state to some extent Lift off cone nut 2 and thus the friction in the bore when expanding for the first time.

The thickness or the material of the abutment 4 can be almost can be varied as required. It is particularly conceivable that the abutment 4 is designed so that it at one certain torque overcome by the threaded rod 16 can be. In such a case, when fixed Rock anchor the threaded rod 16 further into the bore 15 be screwed in so that with a possibly on the Anchor rod 16 existing screw head plates and the like to be attached to the outside of the rock can.

The rock anchor described so far, but also others Embodiments of this anchor according to the invention cannot serve only as a rock anchor, but also as a concrete anchor. This Application of the anchor according to the invention is for Strength tests of concrete used. Here is essential that the pull-out force that the concrete anchor for Provides is higher than the corresponding strength of the concrete. The anchor according to the invention ensures easy handling and simple construction very high Anchoring and pull-out forces.

Claims (11)

Rock or concrete anchors with a polygonal or round cone nut, which carries an approximately central and axially running threaded hole for a threaded rod, and with a number of lamellae lying on the outside of the cone nut, the cone nut having a first end of smaller circumference and a second end has a larger circumference and the conical nut is displaceable in the lamellae in the axial direction, characterized in that the lamellae carry at their end assigned to the second end of the conical nut an abutment which overlaps the conical nut from the outside for axially supporting the threaded rod. Concrete or rock anchor according to claim 1, characterized in that the abutment extends into the area of the threaded bore. Concrete or rock anchors according to one of the preceding claims, characterized in that the lamellae each have at least one extension which radially engages over the conical nut and is directed inwards. Concrete or rock anchor according to one of the preceding claims, characterized in that the lamellas carry a common abutment. Concrete or rock anchor according to one of the preceding claims, characterized in that the abutment can be overcome by the threaded rod above a certain torque. Concrete or rock anchor according to one of the preceding claims, characterized in that the slats are integral with the abutment. Concrete or rock anchor according to one of the preceding claims, characterized in that a total of three slats are provided. Concrete or rock anchor according to one of the preceding claims, characterized in that the surface of each lamella facing the cone nut is angled like a roof at an angle of 120 ° to 130 °, preferably 125 °. Concrete or rock anchor according to one of the preceding claims, characterized in that the surface of each lamella facing away from the cone nut carries at least one groove running in the circumferential direction. Concrete or rock anchor according to one of the preceding claims, characterized in that the grooves are associated with a circumferential securing means that holds the lamellae around the conical nut. Concrete or rock anchor according to one of the preceding claims, characterized in that the surface of each lamella facing the cone nut carries at least one groove running in the circumferential direction, in which lies a spring means which urges the lamellas away from the cone nut in the region of the first end.

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