KR100200990B1 - Fixing element having an expander element - Google Patents

Abstract

The fastening element 1 has a trapezoidal drawing and has a longitudinal slot 5 produced by stamping and an extension region formed by a displaceable expansion element 6 inserted into the longitudinal slot 5 and displaceable. On the two sliding surfaces 22, 23 of the longitudinal slots 5 arranged at an angle with respect to each other, two bearing surfaces 24, 25 arranged at similar angles to each other are laid, The outer surface of the extension element 6, on which the teeth 8 of the structure are provided, projects beyond the shank 2 of the fixing element 1 to at least a portion of the height of the teeth. Since the extension element 6 lies in the longitudinal slot 5, it is easily displaceable and allows for continuous expansion of the fixed fastening element 1 even if the drilled hole widens as a result of the formation of the crack.

Description

Fixed element with extension element

1 shows a fastening element with an extension element lying in a longitudinal slot of an extension area inserted into a drilled hole in a building part (wall);

2 is a partial longitudinal cross-sectional view of the securing element of FIG. 1 in a locked position.

3 is a cross-sectional view of the fixing element taken along the line A-A of FIG.

4 is a longitudinal cross-sectional view of a securing element having an internal helix shown during the securing process using a driving-in tool.

FIG. 5 shows a fastening element according to FIG. 4 in which threaded rods are screwed and an elastic element arranged between the extension element and the threaded rod. FIG.

* Explanation of symbols for main parts of the drawings

5: longitudinal slot 6: extension element

8: tooth 12: stop sludder

14: tip 22,23: sliding surface

24,25: bearing surface 26,27: base area

30: internal thread 34: naked photo rod

The invention relates to a securing element with retaining means arranged at the rear end for clamping an article according to claim 1.

DE-OS 29 14 739 discloses a fixing element having an extension region formed by an extension slot inserted in the longitudinal slot and a longitudinal slot having a base inclined upwardly in the region of the tip surface. The fastening of such fastening elements is accomplished by driving the shank into a predrilled hole in the building part (wall) and then moving axially with respect to the extension element where the shank is drilled into the wall of the drilled hole when the article to be clamped is clamped in the building part. Is achieved. By the fact that the base of the longitudinal slot which receives the extension element is inclined upwardly, the extension element is pressed radially outward and the fixing element is finally wedged in the drilled hole. The known fastening element, however, has the disadvantage that the extension element has teeth on the outer surface which form a straight edge which projects transversely beyond the shank in the longitudinal direction. These edges, which hold the entire width of the extension elements, are high resistance when the fastening elements are embedded into the building part, and are particularly resistant to additional parts, especially in the case of the building part of the concrete, which facilitates assembly. This resistance damages the fastening elements that impose the fastening function. Moreover, the extension element scraps material from the inner wall of the drilled hole during the drilling operation. This material is guided by an extension element to be collected in the longitudinal slot and filled in the longitudinal slot as much as possible. This allows the variability of the extension element in the longitudinal slot to be imposed such that continuous expansion is impossible in the case where the drilled hole widens with the formation of a crack after the fixing operation. Because of this deficiency, conventional fastening elements are unsuitable for use in the tension zone causing cracks. It is believed that the reason for not being suitable in the tensioning zone and even having a relatively low holding value even in concrete without cracks is in the bounding of the longitudinal slots towards the leading end of the fixing element by the stopping surface in the conventional fixing element. Thus, on the one hand only a slight elevation angle to the base of the longitudinal slot can be obtained, on the other hand the length of the extension element must also be considerably short relative to the length of the longitudinal slot in order to obtain a satisfactory displacement movement during fixation. do. In the case where the drilled hole must be further widened due to the formation of the cracks, there is a risk that the extension element will be supported against the leading stop face of the longitudinal groove and do not provide any further potential expansion.

This situation can also occur, for example, when the predrilled hole for the fastening element is bent out and becomes somewhat larger than expected when the hole is ready.

In conclusion, the planar base of the longitudinal slot and the planar bearing surface of the extension element provide high contact pressures during the expansion process which can lead to cold steel welding. Eventually, it impedes continuous expansion and thus also impairs the rudderness of use in the tension zone.

DE 33 34 745C shows an expandable plug, which is a sleeved structure with internal threads for screws or screw rods. The wedge-shaped extension element of the expandable plug is part of the plug body and is joined to the plug body by a web that remains between the incisions and acts as a desired break. The cutout is arranged on the one hand to form an inclined surface which is inclined upward toward the tip of the plug body and on the other hand to form a wedge shape of the extension element. A stop member protruding into the sleeve bore of the plug body is integrally formed on the extension element to apply the expansion mold to the surface.

To secure the expandable plug, the extension element is first torn at the desired break point using the extension mold and then moved towards the tip of the plug body. The tearing at the desired break point requires the pushing force necessary to support the brace at the bottom of the hole drilled into the conventional expandable plug. Moreover, in order to bridge the incision separating the two sliding surfaces of the plug body and the extension element, and to obtain an expansion effect, a fairly large axial displacement of the extension element is required. Moreover, since both the extension element and the plug body are made of the same material, continuous expansion does not occur since there is a risk that the two sliding surfaces will be damaged by cold welding and binding during expansion. The formation of cracks makes them inadequate to be used in the widening tension zone and needs to be corrected through continuous expansion.

Therefore, the present invention allows the fastening element to be embedded with less resistance, to be fixed in a simple way in the building part and to have a high holding value as a result of good continuous expansion behavior even when the drilled hole is widened by crack formation. It is based on the problem of improving the fixed elements of the kind mentioned at the outset.

This problem is solved by the features specified in claim 1. The longitudinal slots produced by stamping with a trapezoidal cross section provide sliding surfaces which are arranged at an angle with respect to each other, and compression is made on these surfaces. The compressive force promotes sliding behavior and therefore reduces the tendency to cold weld and unbond when the extension element is displaced in the longitudinal slot during the expansion process. Further reduction of the binding tendency is achieved by reducing the contact pressure due to the fact that the two sliding surfaces are arranged at an angle to each other and at the same time also acting as lateral guidance of the extension element during displacement.

By means of the teeth of the roof-like structure arranged on the outer surface of the extension element and part of their height protrude past the shank, only the grooves cut into the drill holes prepared when the fastening elements are embedded ( score out). Since the vertices of the toothed extension element only dig into the wall of the drilled hole, the resistance to overcome when the fixing element is embedded is low.

After drilling, the teeth placed on the extension element remain immovable in the drilled hole, while the shank is moved axially relative to the extension element during the fixing operation. The upwardly inclined longitudinal slot forces the extension element radially outward into the wall of the drilled hole and the roof shape of the tooth reduces the resistance of the outer surface of the extension element penetrating into the wall of the drilled hole. Therefore, only low screw torque is needed for fixing.

Moreover, since the base which slopes upwards of the longitudinal slot projects at a distance from the tip at the outer periphery of the shank, firstly a longer extension element with a larger pressure application area can be used, and secondly Larger radial expansion can be achieved with smaller axial displacements due to the steeper elevation of the base.

For both the sliding behavior and the manufacture of the longitudinal slots, the two sliding surfaces are arranged at an angle of 100 ° -120 ° to each other and the width of the base area of the two sliding surfaces of the base area of the two bearing surfaces of the extension element Less than width has been proven to be good. Making the width of the base area of the two sliding surfaces less than the width of the base area of the two bearing surfaces of the extension element ensures that the bearing surface of the extension element lies exclusively with the sliding surface.

It has been proven that structures with longitudinal slots at the ends facing towards the rear end of the fixing element have a depth corresponding to at least half the diameter of the shank and the elevation angle of the base lies between 11 ° and 13 °.

Since the extension element is supported when the securing element is embedded, a stop member of the semicircular structure is provided in the restriction of the longitudinal slot facing towards the rear end of the securing element, and the extension element is supported in the deepest position with respect to the restriction.

Moreover, the retaining element, for example a rubber ring, a stamped bead or similar structure, can be held movable in the longitudinal slot before the securing element is embedded in the drilled hole, so that the extension element Do not accidentally fall out of the slot. The good characteristic action of the teeth combined with low resistance when embedded is achieved by the fact that the teeth have tooth flanks that are completely different and the shorter tooth flanks are arranged towards the tip.

To facilitate the nailing operation, ramped ramps extending to the tip of the first tooth in other structures of the present invention may be disposed at the tip of the extension element.

In another structure of the present invention, the fastening element may have internal threads at the rear end, so that the article can be fastened to the fastening element fixed in the masonry by screws, threaded rods or similar means. The weight acting on the plug body creates a slight displacement between the plug body and the fixed extension element, and this displacement makes the expansion stronger by the base inclining upwards in the longitudinal slot. Because of the good sliding properties of the sliding surface, even if the drilled hole widens in the formation of cracks, axial displacement occurs between the extension element and the plug body.

In some cases, the displacement of the plug body relative to the extension element is also undesirable as it creates a displacement of the screw or screw rod. To overcome this displacement, better structural equipment extends beyond the stop slad into the longitudinal slots, with the bore adjacent to the internal threaded portion of which cross section is intersected by this and the extension element screwed towards the tip to secure the fastening element, Threaded rods or punches are made to displace the tool.

In particular, an elastic element, suitably a compression spring, can be arranged between the extension element and the screw and screw rod being screwed. This elastic biasing of the extension element pushes the extension element continuously when the drilled hole is widened as a result of the crack formation, so that axial movement of the plug body is not necessary for continuous expansion. Rubber bolts can also be used as elastic elements.

The invention is illustrated by the embodiment shown in the drawings.

The fastening element 1 shown in FIG. 1 has an extension region formed in the longitudinal slot 5 and an extension region formed by an external thread 3 and a trapezoidal longitudinal slot 5 at the rear end 4. It has a shank 2 with an element 6. The extension element 6 which is easily movable in the longitudinal slot 5 is retained by a retaining element 7, in particular in a particular embodiment by a rubber ring.

The outer face of the extension element 6 has teeth 8 which are cross-sectional roof shaped (see FIG. 3). When the fastening element 1 enters the drilled hole 9 in the building part 10, the extension element 6 is placed in its deepest position, where the rearward semicircular end face 11 of the extension element 6 is located. Is similarly abutted with a limit (limit) of the longitudinal slot 5 which is semicircular and acts as the stop member 12. In this position the teeth 8 protrude in the height direction past the shank 2 of the fixing element.

The fastening element 1 is driven into a hole drilled at right angles to the article 16 to be fastened. By screwing the nut 17 into the protruding portion 3, the shank 2 is moved axially relative to the extension element 6 towards the mouse of the drilled hole, so that the extension element 6 is It is extended radially outward by the base 18, which is inclined upwardly of the directional slot 5 (see also FIG. 2).

3 is a cross-sectional view taken along the line A-A of FIG. The roof structure of the tooth 8 is good for the deep penetration of the extension element 6 into the wall of the drilled hole in the building part 10. The trapezoidal cross section of the longitudinal slot 5 can also be recognized in FIG. 3. The trapezoidal shape creates two sliding surfaces 22, 23 arranged at an angle to each other, and the extension element 6 lies on two bearing surfaces 24, 25. The angle B formed by the two sliding surfaces or the bearing surface is suitably 100 ° -120 °. In order to ensure that the bearing surfaces 24, 25 slide on the sliding surfaces 22, 23, the width of the base region 26 between the two sliding surfaces is equal to the two bearing surfaces 24 of the extension element 6. It is somewhat smaller than the width of the base region 27 between 25.

The fastening element 1a shown in FIG. 4 has an internal thread 30 for receiving a skew or threaded rod at its rear end. Adjacent to the inner threaded portion 30 is a bore 31 of reduced diameter compared to the core diameter of the inner threaded portion, which extends past the staying slender 12 into the longitudinal slot 5 and a portion of the cross section. Intersect the longitudinal sliding 5. The rear end of the extension element 6 therefore protrudes into the bore 31 so that the ram 32 of the drive mechanism 33 abuts against the rear end of the extension element 6. By using the driving mechanism 33, the extension element 6 can be moved on the inclined base 18 upward of the longitudinal slot 5 towards the bottom of the now drilled hole 9. Therefore, the extension element 6 is wedged into the drilled hole 9 in the building part 10 to achieve fixing of the fastening element. The axial movement of the extension element 6 can also be achieved directly, in which a screw or threaded rod is screwed into the inner screw part 30. In this case, the inner thread 30 may extend beyond the stop stud 12, or a reduced portion corresponding to the bore 31 may be arranged at the end face of the screw or photo rod.

In the illustration of FIG. 5, for example, the threaded rod 34 for suspending a pipe, ceiling or similar structure is screwed into the internal thread 30 of the fastening element 1b. The extrusion spring 35 is arranged as an elastic element between the extension element 6 and the threaded rod 34. The compression spring 35 can be pushed into the stationary element 1b by the pusher and clamped to the threaded rod 34 or the axial movement of the extension element 6 by the threaded rod 34 directly. Can be used for The compression spring exerts a steady pressure on the extension element 6 after the screw or threaded rod has been screwed in. On the one hand, the hole drilled through the extension element 6 may be widened due to the formation of cracks. When it continues to push and at the same time on the other hand it provides a safeguard against vibration of the naked rod 34.

The extension element 6 can be produced from malleable cast iron by pressure die casting or by cold forging in stamping and bending dies. The extension element of malleable cast iron has very good sliding properties because of graphite (graphite) in malleable cast iron.

Claims (12)

A base having retaining means arranged at the rear end for clamping the article to the building part, starting from the leading end, extending longitudinally with respect to a portion of the length of the shank of the fastening element, and which is inclined upwardly towards the leading end In a fixed element having a longitudinal slot having a longitudinal extension and an expansion area formed by a displaceable extension element inserted in the longitudinal slot, the longitudinal slots 5 are formed by stamping, It has a trapezoidal cross section with two sliding surfaces 22, 23 arranged at an angle and rising radially towards the tip 14, wherein the extension element 6 has two supporting surfaces on the sliding surfaces 22, 23. With two bearing surfaces 24, 25, the teeth of the roof-like structure of which part of the height protrudes beyond the shank 2 are provided on the outer surface. Characterized by a fixed element. 2. The fastening element according to claim 1, wherein the two sliding surfaces (22, 23) of the longitudinal slots (5) are arranged at an angle of 100 ° -120 ° to each other. 2. The width of the base area 27 between the two bearing surfaces 24, 25 of the extension element 6 of the width of the base area 26 between the two sliding surfaces 22, 23. A fixed element characterized by less. 2. The angle according to claim 1, wherein the longitudinal slots 5 correspond to at least half of the diameter of the shank 2 at an end facing towards the rear end 4 of the fixing element 1. Fixed element, characterized in that it has an elevation angle α of the base 18 that lies between them. The fastening element according to claim 1, characterized in that the extension element 6 is supported against the semi-circular stop member in the restriction of the longitudinal slot 5 facing towards the rear end 4 of the fastening element. Element. 2. The retaining element according to claim 1, characterized in that the retaining element of the rubberized form acts on the extension element 6, which retains the extension element 6 displaceably in the longitudinal slot 5. Stationary elements. 2. A fastening element according to claim 1, characterized in that the teeth (8) have completely different tooth flanks and shorter tooth flanks (19) are arranged facing towards the leading end (14). The fastening element according to claim 1, characterized in that a ramped ramp (28) extending at the tip of the first tooth (8) is arranged at the tip of the extension element (6). 2. Fastening element according to claim 1, characterized in that an internal thread (30) for a screw threaded rod (34) or similar means is arranged at the rear end of the fastening element (1a, 1b). 10. The bore 31 according to claim 9, which extends beyond the stop slad 12 into the longitudinal slot 5 and whose part of the cross section intersects the slot, is adjacent to the internal thread 31 and the extension element 6 is A fastening element, characterized in that it is displaceable with a screw, threaded rod (34) or a driving tool (33) towards the tip for fastening the fastening elements (1a, 1b). The fastening element according to claim 1, characterized in that the extension element (6) is made of malleable cast iron. 2. The fastening element according to claim 1, wherein the extension element is made from a sheet metal blank and the edge of the sheet metal blank is bent inwardly in the shape of a roof.