DE19801105A1 - Self-tapping anchorage bolt for concrete structure - Google Patents

Abstract

A self-tapping anchorage bolt cuts a thread in a concrete hole. The anchorage bolt has a conical tip with a cutting thread which increases until reaching the parallel shank. The initial section of the thread has a series of cutting tips (14) which increase in diameter from a minimum (21) to a maximum, followed by a section of cutting thread (25) which has a finely serrated edge (26).

Description

The invention relates to a thread-cutting screw, in particular Concrete screw according to the preamble of claim 1.

Such a screw is from DE 297 04 226.2 U1 (corresponding PCT / EP97 / 03867) known. Basically it is with such screws desirable the cutting section only in the area of the insertion end the screw so that the subsequent turns of the in the Always wear a catchy thread in full in concrete or the like, at the same time it should also be achieved that not by too long formed cutting sections ge by means of the cutting section cut thread is worked out too far with the result that the tight fit of such a screw would no longer be guaranteed. Other on the other hand, it has been shown that when screwing in such screws in high fe concrete, screw in the pebbles present in the concrete can be heavy.

The invention is therefore based on the object, a screw of the gat appropriate form so that on the one hand also a slight one screws in high-strength concrete and on the other hand ensure a tight fit is steady.

This object is achieved by the features in the characterizing part solved part of claim 1.  

Because on the one hand the cutting section with relatively large ß cutting teeth only in the area of the insertion end is si made that free through the cutting section in the concrete or the like cut area is no further than the thread itself. On the other hand there is a fine reworking by the micro cutting teeth.

Advantageous refinements result from the subclaims.

Further features, advantages and details of the invention emerge from the following description of an embodiment with reference to the drawing. It shows:

Fig. 1 is a plan view of a concrete screw,

Fig. 2 is a plan view of an enlarged partial view of the insertion of the concrete screw,

Fig. 3 is an end view of the insertion end of the concrete screw in Enlarge ter representation,

Fig. 4 shows a cross section through the concrete screw according to the section line IV-IV in Fig. 1 in an enlarged scale;

Fig. 5 is a partial longitudinal section through the concrete screw according to the line VV in Fig. 1 in a greatly enlarged representation,

Fig. 6 shows a further partial longitudinal section through the concrete screw according to section line VI-VI in Fig. 1 in a greatly enlarged representation and

Fig. 7 is a partial plan view of a modified embodiment of a cutting notch.

The screw shown in Fig. 1 has a core 1 , which has a slightly tapered, truncated cone section 3 at a first end, the introducer 2 . An arbitrarily designed screw head 5 is formed on a second end 4 of the core 1 . A web-shaped single thread 6 is formed on part of the core 1, including the tapered section 3 .

As can be seen to 4 in Figs. 2, on the tapered portion 3 of the core 1, a rising threaded portion 7 of the thread 6 formed that starts of the core 1 at the insertion end 2 of the surface 8 of the ver the Last section 3 out and a half to a whole turn, ie a pitch t, the thread 6 out to the full thread height, ie the outer diameter D of the thread 6 increases. The flan ken 9 of the threaded portion 7 rise directly from the surface 8 of the tapered portion 3 of the core 1 and at an opening angle of about 60 °, that is, the two flanks 9 of the threaded portion 7 are each about 30 ° to a radius the central longitudinal axis 10 of the core 1 is inclined. The opening angle should be in the range of 50 ° to 70 °. The diameter d of the core 1 at its end 2 is a little smaller than the nominal diameter of a bore into which the screw is to be inserted. The nominal diameter of a hole is internationally standardized, i.e. 4, 5, 6, 8, 10, 12, 14, 16 ,. . . mm.

Behind the tapered section 3 with the ascending threaded section 7 , the thread 6 is configured as is known from DE 297 04 226.2 U1 (corresponding to PCT / EP97 / 03867). It has mutually parallel flanks 11 , which run parallel to a radius on the central longitudinal axis 10 . The flanks 11 each pass by means of an inclined foot section 12 a or 12 b into the core 1 , the respective foot section 12 a or 12 b being inclined with respect to the radius mentioned, so that the foot sections 12 a, 12 b limited foot 13 of the thread 6 widens towards the core 1 . The rising thread section 7 goes continuously into the subsequent thread 6 .

The rising thread section 7 and at most the two closing turns of the thread 6 are provided with cutting teeth 14 and 15 , respectively. Where the thread 6 is provided with cutting teeth 15 , it forms a cutting section 16 . The cutting teeth 14 in the rising thread section 7 are essentially formed by cutting notches 17 , each of which - as can be seen in FIG. 3 - have the shape of an isosceles triangle. The longitudinal edges 18 , 19 , 20 of the cutting notches 17 , that is, the two longitudinal edges 18 , 20 at the transition to the outer surface 21 and the longitudinal edge 19 at the bottom of the cutting notch 17 run parallel to the axis 10 . The longitudinal edge 20 lagging behind in relation to the screwing-in direction of rotation 22 is a cutting edge. The surface formed between this cutting edge 20 and the longitudinal edge 19 running at the bottom of the cutting notch 17 is a removal surface 24 for drilling dust. As can in particular Fig. 3 seen, the cutting teeth 17 can be arranged so that the trailing cutting edge 20 of a cutting notch 17, the leading longitudinal edge 18 of the next cutting notch. In this case, the outer surface 21 shrinks to such a longitudinal edge, which is in each case a cutting edge. The above description applies to the design of the cutting teeth 15 of the cutting section 16 , so that the same reference numbers are used with a raised line without a renewed description. The radial height h 'of the cutting notches 17 ' is 0.2 to 0.5 mm for nominal bore diameters of 5 mm and 0.5 to 0.8 mm for example for nominal bore diameters of 16 mm.

The threaded section adjoining the cutting section 16 can be designed as a simple threaded section with the same basic shape as the cutting section 16 , but without cutting teeth, and possibly with a slightly reduced outer diameter D, as in DE 297 04 226.2 U1 (corresponding PCT / EP97 / 03867). When screwing the screws into high-strength concrete, however, the pebbles in the concrete can make screwing in more difficult. For such cases, the section of the thread 6 adjoining the cutting section 16 is designed as a micro-cutting section 25 , as can be seen in particular from FIG. 4. Here are micro cutting teeth 26 seen before, which are basically designed as it has already been described for the cutting teeth 14 , 15 ; therefore the same reference numerals are used as before, but with a double prime. The micro cutting teeth 26 have a considerably lower radial height h '' of 0.1 to 0.2 mm compared to the cutting teeth 15 . The micro cutting teeth 26 still carry out a slight post-cutting work. The following applies to height h 'in relation to height h'':2h''≦h' and preferably 3h '' ≦ h 'and 7h''≦h'.

As shown in particular in Figs. 5 and 6 is removed, the core 1 of the screw is not cylindrical. Rather, it has two core outer surface sections 27 , 28 between two adjacent turns. The core outer surface section 27 , which leads in the longitudinal direction 23 , tapers against the longitudinal direction. The section 28 , which adjoins the screw-in longitudinal direction 23, is cylindrical. The section 27 extends in the direction of the axis 10 over a length a, while the section 28 extends over a length b. We have a ≧ b. By this configuration, a chamber 29 is formed between the adjacent threads, which - based on the borehole wall 30 indicated in FIGS . 5 and 6 - extends. The core outer surface section 27 serves as a drainage surface for the drilling dust, which is mainly stored in the area of the core outer surface section 28 in the chamber 29 . Since the volume of the chamber 29 in the region of section 28 is greater than the volume of the hole cut into the borehole wall 30 , the drilling dust does not impede the screwing-in process, ie there is no increase in the torque when screwing in the screw, caused by friction between the drilling dust stored in the chamber 29 and the borehole wall 30 could be formed. As FIGS. 5 and 6 is also apparent, the turns of the thread 6 bear over its full height in the area bounded by the hole wall 30 concrete.

As indicated in Fig. 7, in particular the cutting teeth 15 a in the cutting section 16 a have a course through which they get a Ge thread function. The cutting notches 17 a are formed in this case so that the longitudinal edges 20 lagging in the screw-in direction of rotation 22 and thus the removal surfaces 24 a of the cutting notches 17 a lag in relation to the screw-in direction of rotation 22 and the screw-in longitudinal direction 23 , so that a largely friction-free trans port of the drilling dust through the cutting notches 17 a in the subsequent chambers 29 takes place. The cutting notches 17 a thus form a threaded channel with a large slope of 60 ° to 80 ° based on the one longitudinal direction 23 . This embodiment can of course also hen with the cutting teeth 14 and the micro cutting teeth 26 , although this is not so important because of the relatively low amount of drilling dust.

Claims (6)

1. tapping screw, in particular concrete screw, with a core ( 1 ) with a central longitudinal axis ( 10 ) and a screw-in longitudinal direction ( 23 ),
with a thread ( 6 ) formed in one piece with the core ( 1 ), with an introducer ( 2 ) and
with a cutting section ( 16 ) formed in the region of the insertion end ( 2 ), in which cutting notches ( 17 ') are formed open to the outer periphery of the thread ( 6 ) and have a depth h' radial to the central longitudinal axis ( 10 ) have, characterized in
that adjoins the cutting section ( 16 ) a micro cutting section ( 25 ) in which the thread ( 6 ) is provided with open outer cutting edges h in micro cutting teeth ( 26 ), the depth h '' of which is radial to the center -Longitudinal axis ( 10 ) is considerably smaller than the depth h 'of the cutting notches ( 17 ') in the cutting section ( 16 ). 2. Screw according to claim 1, characterized in that for depth h '' in relation to depth h 'the following applies: 2 h' 'gilt h'. 3. Screw according to claim 2, characterized in that for depth h '' in relation to depth h 'the following applies: 3 h' 'gilt h'. 4. Screw according to one of claims 1 to 3, characterized in that the depth h '' in relation to the depth h 'is: 7 h' '≦ h'.   5. Screw according to one of claims 1 to 4, characterized in that for the depth h '' the following applies: 0.1 mm ≦ h '' ≦ 0.2 mm. 6. Screw according to one of claims 1 to 5, characterized in that the cutting section ( 16 ) has at most two turns of the thread of ( 6 ).