DE3741345C2 - Anchoring procedure for fasteners - Google Patents

Description

The invention relates to a method for anchoring Fastening element by means of a curing Ein or Multi-component adhesive in a borehole, especially in the crack-prone tensile zone of a building, the detention mass serves the adhesive connection with the building and that Fastening one of the positive anchoring has the load shoulder serving the adhesive.

Anchoring fasteners using hardening Single or multi-component adhesive, for example according to DE-PS 12 05 038, because of their advantages such as lack of spreading pressure, largely independence from dimensional deviation borehole diameter and good durability against chemical influences in many cases today turned. For certain fixings, especially in the tensile zone of a structure susceptible to cracking, could However, these so-called composite anchors have not yet been used clog. The cracks that develop in this zone run very often through the boreholes as these weakening points form with a reduced cross-section. One through the borehole running crack can detach the adhesive from the borehole wall and thus to failure or little lead to a reduction in anchorage.

Fortifications in the crack-prone tensile zone of a building for the reasons mentioned, are often carried out by means of expenditure special tools that create an undercut and corresponding special dowels.

The invention has for its object a method for Anchoring a fastener particularly in the crack-prone Traction zone of a building by means of hardening one or more to create component adhesive compositions.

According to the invention, this is achieved in that before the introduction of the adhesive and the insertion of the fastener supply element in the wall of the borehole above it  Circumference evenly distributed essentially in the axial direction directional grooves.

By making the grooves according to the invention cracks through the borehole in the area of detention mass in a certain way. Such in Existing crack area of the borehole can be circumferential Direction at most to the next groove along the outside of the borehole because the crack through the next groove would be deflected too much. The crack then leads to a tear of the adhesive and runs through the Adhesive radially inward against the fastener. The crack then runs over part of the circumference along the surface of the fastener. Around The surface of the fastener can facilitate cracking supply element by means of a release agent, for example Grease, wax or the like can be coated. Through the positive anchoring of the fastener in the Adhesive mass over the load shoulder causes this detachment of the curing adhesive from the fastener not too egg failure of the anchorage. About diametrically opposite to initiate the crack the crack is then Adhesive radially outwards against the borehole wall closing along the borehole wall to the next groove and then continue through the recording material. By the tearing of the hardening adhesive becomes segments formed by opening and closing the crack be moved relative to each other. So these segments form with a kind of jaws that form with the fastener conclusive intervention.

For the operation of the grooves, it is appropriate that these have an approximately rectangular cross section. About right Square cross-section grooves result in the transition area strong cross-sectional differences in the adhesive and force the crack, in the area of the smallest cross section to run through the adhesive. Rectangular cross Cut grooves are also relatively easy to manufacture bar.  

Advantageously, four to four are distributed over the circumference twelve, preferably eight grooves arranged. By a ge sufficient number of grooves, a crack at most over one small portion of the circumference on the outside of the hardening adhesive.

The grooves are preferably made subsequently the production of the borehole. It is therefore advisable the tool for making the grooves as essentially the diameter of the borehole with the mandrel radially protruding cutting edges. The tool is thus by the essentially the diameter of the Centered in the borehole and the corresponding mandrel Grooves are used when advancing the tool, for example using a hammer or chisel hammer through which the mandrel radially protruding blades out of the borehole wall worked. The number of cutting edges can be the finished number correspond to the grooves or a part of the grooves. In the latter In this case, the grooves are created in several steps, in which the tool after making a group of grooves is rotated by a certain angle before the next Grooves are made.

The fastener is in the adhesive by shape anchored in the end. To have a good positive connection reach, it is advantageous to attach the load shoulder of the fastener training element as a circumferential annular bead. A circumferential ring bead results in a force transmission uniform distribution of forces over the entire circumference the fastener.

The one introduced by the fastener onto the adhesive Force can be relatively large. To overload the To prevent adhesive, several are expedient provided axially spaced annular beads. Several Ring beads arranged at an axial distance also result in a Favorable application of force via the adhesive to the borehole wall.

The invention is intended to be used below for example reproducing drawings are explained in more detail. Show it:

Fig. 1 shows an inventive tool for making grooves,

Fig. 2 is a view of the tool shown in Fig. 1, in the direction of arrow A,

Fig. 3 is an anchor according to the invention a fastening element in a receiving material,

Fig. 4 shows a cross section through the anchorage according to FIG. 3, along the line IV-IV.

The tool 1 shown in FIGS. 1 and 2 has a shaft 1 a, the rear end 1 b of which can be acted upon directly by a hammer or which is provided for receiving in a hammer drill or chisel hammer. The shaft 1 a is seen with a locking longitudinal groove 1 c ver. The front region of the tool 1 is designed as a mandrel 1 d, which corresponds approximately in diameter to that of the borehole to be machined. A number of cutting edges 1 e, in this case eight in number, are arranged along the circumference of the mandrel 1 d. Depending on the type of recording material to be processed, the cutting edges 1 e can be hardened or provided with hard metal inserts. The tool 1 is inserted with the part of the mandrel 1 d axially projecting beyond the cutting edges 1 e into a borehole and then driven against the bottom of the borehole. The cutting edges 1 e produce grooves in the borehole wall.

The anchoring shown in FIGS. 3 and 4 consists essentially of a fastening element 2 , which is inserted into a borehole 3 a of a receiving material 3 . In the wall of the bore hole 3 a previously mounted b by means of the duri Fende in Fig. 1 and 2 apparent tool 1 in the axial direction grooves 3. The space between the wall of the bore hole 3 a and the fastening element 2 is filled by means of a thermosetting adhesive composition. 4 Be the fastening element 2 has a front end 2 a in the setting direction and a rear end 2 b. The area of the fastening element 2 adjoining the rear end 2 b is provided with a thread 2 c. In the anchoring area, the fastening element 2 has a number of circumferential annular beads 2 d. The annular beads 2 d form load shoulders 2 e, which enable the anchoring force to be introduced onto the adhesive compound 4 . The fastening element 2 and the adhesive 4 are in positive connection via the annular beads 2 d. The connection of the adhesive 4 with the wall of the borehole 3 a, however, is predominantly adhesive in the pull-out direction.

As shown in FIG. 4, a crack 3 c in the receiving material 3 runs through the borehole 3 a. The crack 3 c is initiated in the region of a groove 3 b in the connection between the adhesive 4 and the receiving material 3 . The crack then runs inward through the adhesive 4 against the fastening element 2 . Over a part of the circumference, the adhesive mass 4 is removed from the fastening element 2 . Then the crack 3 c again runs through the adhesive 4 radially outwards and in the loading area of a further groove 3 b further in the receiving material 3 . As shown in FIG. 4, the adhesive material is 4 c through the crack 3 in two segments 4 a, b subdivided 4. These segments 4 a, 4 b can move relative to each other when opening and closing the crack 3 c. However, since the segments 4 a, 4 b are positively supported in the axial direction on the annular beads 2 d of the fastening element 2 , the fastening is not impaired by the opening and closing of the crack 3 c. From the release of the adhesive 4 from the fastener 2 can be facilitated in that the surface of the Befestigungsele element 2 is coated by a release agent. Such a release agent can be, for example, fat, wax or the like.

Claims (6)

1. A method for anchoring a fastener by means of a hardening one- or multi-component adhesive in a borehole, in particular in the crack-prone tensile zone of a building, the adhesive serving for the adhesive connection to the building and the fastening element serving as a positive anchoring in the adhesive Serving load shoulder, characterized in that before the introduction of the adhesive ( 4 ) and the insertion of the fastener ( 2 ) in the wall of the borehole ( 3 a) evenly distributed over the circumference of the borehole in the axial direction grooves ( 3 b) be attached. 2. The method according to claim 1, characterized in that the grooves ( 3 b) have an approximately rectangular cross section. 3. The method according to claim 1 or 2, characterized in that four to twelve, preferably eight se grooves ( 3 b) are arranged distributed over the circumference. 4. Device for performing the method according to one of claims 1 to 3, characterized in that the tool ( 1 ) for producing the grooves ( 3 b) as the diameter of the borehole ( 3 a) corresponding mandrel ( 1 d) with these radially outstanding cutting edges ( 1 e) is formed. 5. Fastening element for anchoring according to a method according to one of claims 1 to 3, characterized gekennzei chnet that the load shoulder ( 2 e) of the fastening element ( 2 ) is designed as a circumferential annular bead ( 2 d). 6. Fastening element according to claim 5, characterized in that a plurality of axially spaced annular beads ( 2 d) are provided.