DE3502607A1 - Anchor, in particular load-dependent dowel - Google Patents

Abstract

An anchor, in particular a load-dependent dowel, is proposed having a slotted sleeve into which an expanding body provided with wedge surfaces can be drawn, with the wedge tip to the front, said expanding body containing an internal thread, penetrating axially to its ends, for a threaded bolt. On its outer circumferential surface, the slotted sleeve is cylindrical in design. In an end portion receiving the expanding body, it has an approximately frustoconical inner circumferential surface, the cone angle of which corresponds to that of the expanding body. The expanding body and the sleeve are secured against relative rotation by axis-parallel slots and projections engaging therein, and are axially connected in a permanent manner by a securing ring. At the other end, locking tongues are cut out of the wall of the sleeve and bent outwards. Said locking tongues catch in the wall when the anchor is driven into the bore, and provide fixed attachment while securing against withdrawal and rotation.

Description

Anchors, especially load-dependent dowels

The invention relates to an anchor in particular load-dependent Dowel, with a slotted sleeve into which an expansion body provided with wedge surfaces, with the chisel point first, retractable, which is axially continuous to both ends Contains internal thread for a threaded bolt.

A known anchor of this type (DE-GM 75 07 019) has a slotted Sleeve on a continuously cylindrical sleeve made of sheet metal, which before the retraction of the The expansion body is also cylindrical in the area that can accommodate the expansion body has a cylindrical inner and outer circumferential surface. On the opposite of the expansion body The end area of the sleeve is provided with bent locking tongues that when inserted of the anchor in the borehole are intended to provide additional security. To when moving in The expansion body is used to prevent the expansion body from rotating at the same time in the sleeve on its circumferential surface and at the end that has the smaller conical base circle, knurled on the outside. A connection between the expansion body and If the fastening screw is not screwed in, the sleeve should enter the expansion body as a result be created that the sleeve at the end area facing the expansion body inside has a circumferential ring shoulder, which is formed by embossing the sheet metal is formed and in a corresponding annular groove on the facing, engages cylindrical end region of the expansion body as an axial lock.

An anchor of this type has a number of disadvantages. By the fact that the sleeve also on the end area into which the expansion body can be retracted, before retraction is designed to be continuously cylindrical, making the retraction of the expansion body extreme great forces are necessary to convert the cylinder shape into a truncated cone shape. The anchor can be used once in a borehole in the concrete that if the expansion body has not yet been drawn into the sleeve and which goes over the ring shoulder and the annular groove is axially secured on the sleeve, directly or at the free end of the sleeve hit it with an aid and hit it into the borehole will. The locking tongues then deflect radially and produce a radially outward movement directed expansion force and claw in the borehole wall with safety the sleeve both against twisting and against pulling out again. The outside diameter of the expansion body at the point of greatest diameter corresponds in this initial position the outer diameter of the sleeve. As a result, there is a risk that the expansion body already when hammering the anchor into the borehole on the borehole wall with his foremost end finds resistance and the axial lock through into the ring groove of the The ring shoulder engaging the expanding body is lost because of this resistance, i.e. when the expansion body is stuck in the borehole, the sleeve is slammed onto the latter is overcome by overcoming the positive axial coupling between the expansion body and Sleeve. As a result, however, the expansion body is knocked into the front end of the sleeve and the latter widened approximately in the shape of a truncated cone with associated blocking in the Borehole wall. The result would then be that the anchor is in the borehole wall anchored before the sleeve is even hammered into the borehole as far as desired can be. The dowel is incorrectly seated and must be pulled out again. This inadequacy is due to the fact that the outer diameter of the expansion body at the largest point, i.e. at the foremost end, the same, if not even Is dimensioned a little larger than the outer diameter of the continuously cylindrical Sleeve.

If one wants to prevent these difficulties, one is forced to Drill the borehole significantly larger. But then you run the risk that the mode of action the locking tabs are no longer guaranteed; because the greater the excess between The borehole and outer diameter of the sleeve, the lower the function of the Locking tabs. So if you drill the borehole in diameter for safety reasons larger, there is a risk that the locking tongues are no longer effective.

Even if you insert the anchor in a different way into a borehole tries, problems arise. The other mounting option would be as follows. Of the Anchor is first inserted into the hole with a screw, a threaded bolt od. The like. Completed, which is screwed into the internal thread of the expansion body and protrudes from the end of the sleeve at the other end. The spreader has it as before, the same position before penetration into the sleeve with axial relative locking by engaging the inner annular shoulder of the sleeve in the annular groove of the expansion body. The fastening bolt is then used to drive the anchor onto the fastening screw Od. Like. Beaten and tries to drive the expansion body into the borehole and pull the sleeve over this. There is a high risk here> all the more so that the axial connection between the expansion body and the sleeve is released automatically slotted more than the sleeve at the end region into which the expansion body can be retracted and is divided into individual expansion flaps, which can be stretched out relatively easily, especially in the area of its free end, where the axial lock over into the annular groove engaging ring shoulder is present. This danger is even more so than that Locking tongues against pulling the sleeve into the borehole. set. If the drill hole is roughly matched to the outer diameter of the sleeve, in order to ensure its effectiveness to secure the locking tongues, these prevent the retraction of the sleeve on the expansion body acting tensile force. Instead, the axial coupling between the expansion body and Sleeve loosened.

The result is then that the expansion body sits in the borehole, which The sleeve, however, is still separated from it outside the borehole. Even with this mounting option so there are considerable difficulties that ultimately make the anchor unusable do.

Even if it is assumed that the anchor will initially be in a borehole could be placed and now the expansion effect unfolds over the expansion body this causes considerable difficulties. On the one hand there is the anti-twist device Inadequate between expansion body and sleeve. The knurling at the end of the expansion body is only slightly in physical contact with the free end of the sleeve in this Area. Since the sleeve walls also spring out relatively easily because of the slot is relatively easy when screwing a screw into the expansion body rotated relative to the fixed sleeve. The knurling can prevent rotation cannot guarantee reliably. If the expansion body rotates when screwing in a Screw, the dowel is unusable because the expansion body is drawn into the Sleeve is not possible. Even if one assumes that when screwing in a screw of the expansion body does not turn, it causes considerable problems To pull the expansion body into the sleeve in order to expand the latter in this end area; because the necessary axial tensile forces that have to be applied via the screw, are enormous because the cylindrical sleeve in this area now becomes a truncated cone must be widened. These forces can only be applied if a special fastening screw with head is used as an abutment, which is on a support plate, which in turn attaches itself to the concrete, prop up can. Only then can the large tensile forces be applied to the expansion body actually to be able to pull into the latter by spreading the sleeve end. However, this type of handling complicates the anchor. So you have to have a special one Have tools at hand for handling, in the form of a suitable one long screw with head and washer and in the form of a corresponding wrench. In addition, the achievable expansion effect depends on the expansion body to be drawn in on the commitment and skill of the craftsman. So they are not reproducible fixed anchoring achievable. Since you cannot look into the borehole from the outside can, one has to reckon in one or the other case that the craftsman will use the expansion body has only drawn insufficiently far into the sleeve by actuating it accordingly the screw, so that the anchor is not yet reliably anchored firmly in the borehole is. This shows up when you want to attach parts to it. Then the anchor can Slip in the axial direction and move accordingly.

Another major disadvantage is that the known anchor an unfavorable ratio of the outer diameter to the diameter of the expansion body has screw to be screwed in; because the outer diameter of the sleeve is a lot larger than the diameter of the internal thread in the expansion body and thus the external diameter of the threaded bolt that can be used to attach a part to the anchor. So you have to create a very large borehole and can only use the anchor load relatively low forces.

The invention has for its object to provide an anchor of the initially to create the type mentioned, through which the disadvantages explained at the beginning - all of them are eliminated.

The task is in an anchor of the type mentioned according to the Invention by the features in the characterizing drawing part of claim 1 solved.

Advantageous further features of the anchor according to the invention result from the other claims 2-20.

The anchor according to the invention has the following advantages achieved, which also result from the handling explained below.

To the anchor according to the invention in a concrete wall or concrete ceiling to introduce, for example, a borehole is drilled with a diameter that corresponds to that of corresponds to the outer circumferential surface of the sleeve and can be, for example, about 14 mm. Then the anchor, with the end containing the expansion body first, is inserted into the Borehole used. The locking tongues, which e.g. have a radial protrusion of about 2 mm stand in the way of the anchor being pressed in without the use of force. Therefore is used to insert the anchor in one fastening method on the free lower one Hit the end of the sleeve directly or by means of a pipe extension, sleeve or the like. The locking tongues deflect radially inwards and exert a strong spreading force and thus adhesive force against the borehole wall.

This already makes it possible for the anchor to be axially fixed in the borehole is placed without the risk that the anchor is approximately opposite to the direction of impact is pulled out again at all. Those who oppose this then face this Locking tongues against. In addition, there is a safeguard against twisting of the sleeve in the borehole also given by the locking tongues. With this type of insertion of the Anchor the expansion body is not at all stressed with forces in the borehole. He but cannot get stuck in the borehole and resist the hammering of the sleeve, since the outside diameter is no larger than in the area of the expansion body the rest of the sleeve.

Instead, the anchor according to the invention can also be used in the following manner be placed in the borehole. A threaded bolt, for example, can be used as an assembly aid Insert a screw or the like from the lower end into the sleeve and into the expansion body screw in. The anchor can then be hammered into the borehole, that this threaded bolt is hit. The thus exerted on the expansion body The tensile force is effectively transferred from it to the sleeve via the locking ring, without this fuse being able to loosen. The locking ring itself is reliable held in the sleeve.

The coupling with the expansion body is also form-fitting and reliable, in this way the sleeve can be pulled into the borehole and result in the same anchoring as explained above. The danger that while the expansion body detaches from the sleeve, and so that the anchor becomes ineffective, there is so not.

If the anchor is used in the manner described, then it is already firmly anchored in the borehole. The expansion effect achieved by the expansion body is not even unfolded. If this is to be done, then the threaded bolts screwed into the expansion body exert a downward tensile force exercised. This already causes the to be pulled in without a necessary abutment Spreader in the wedge-shaped end portion of the sleeve and thus spreading the lobe of the sleeve.

So it is already a low axial tensile force in this area Pulling in the expansion body with its expansion wedge into the frustoconical inner one Circumferential surface and spreading possible, and this without the need special Special tools, particularly high expenditure of force or the like .. Should then be a part attached to the concrete deck or concrete wall in which the anchor is placed in this ice this can be screwed in more or less in height by means of a and thus adjustable threaded bolts happen. With simple means is herewith a height adjustability achieved.

No additional special tools are required during assembly, just as little as additional other materials to compensate. Of special The advantage is reliable anchoring without the anchor being subjected to stress for example, it could still slide in the borehole and thus move axially a little. Since the assembly of the anchor no particularly vigorous turning or strong hammering with different Requires tools, the assembly is no longer reliable and skill of the craftsman dependent. It is always reproducible Anchoring of the same quality achievable. Another major advantage is that that a threaded bolt as large as possible in diameter can be used and however, only one hole in the concrete required to receive the anchor the smallest possible diameter is required. The ratio of borehole diameter to usable cross-section of the threaded bolt is very favorable. This means that they are above average great strengths and thus resilience possible. The expansion body with axial continuous internal thread also has great strength due to this design, without this leading to an enlargement of the diameter and thus possibly necessary Increasing the drill hole diameter in the concrete would result. This also contributes to higher resilience at. In addition, the anchor is both a load-dependent dowel as well as with the same advantages as an Insat socket for all materials. It is relatively inexpensive because the sleeve is designed as a complete sheet metal part and the expansion body as a forged part into which the thread is introduced.

Further details and advantages result from the following Description.

The full wording of the claims is foregoing only Avoidance of unnecessary repetitions are not reproduced, but only instead by naming the claim number referring to it, whereby however all these Claim features as expressly disclosed at this point and essential to the invention have to apply.

The invention is shown below with reference to in the drawings Embodiments explained in more detail.

They show: FIG. 1 a schematic perspective exploded view of an anchor according to a first embodiment, FIG. 2 is a view of the anchor corresponding to Fig. 1, but in the assembled state, Fig. 3 each a schematic, axial longitudinal and 4 section of the armature in Fig. 2 along the line III-III and IV-IV, in an exploded view or in the assembled state, FIG. 5 is a schematic Side view only of the lower sleeve part of an anchor according to a second embodiment.

The anchor shown in Fig. 1-4 according to the first embodiment is to be used in particular as a load-dependent dowel and is inserted into a not shown Drill hole in a wall, ceiling or the like, e.g. made of concrete.

The anchor is in three parts. It has an expansion body 10 in the form of a one-piece forged part, one formed from a one-piece sheet metal part Sleeve 11 and a locking ring 12 in the form of a transversely slotted spring ring on, over which the expansion body 10 and the sleeve 11 in the assembled state (Fig. 2.4) are and will remain together.

The expansion body 10 has a frustoconical expansion wedge 13 on, the outer surface 14 of which extends in the direction of the sleeve 11, i.e. in Figs. 1 - 4 downwards, tapered.

The end of the expanding wedge 13, which is thicker in diameter, connects an integral cylinder section 15 with it towards the top. The outside diameter of the cylinder section 15 is equal to that of the largest conical base circle of the Expanding wedge 13.

The frustoconical expanding wedge 13 and cylinder section 15 are both penetrated by an axially continuous to both ends of the expansion body 10 Internal thread 16, which has e.g. M10. For placing the anchor in the borehole and / or for fastening any elements by means of the inserted into a borehole Anchor is in the internal thread 16 of the expansion body 10 only in Fig. 4 with a dashed line indicated threaded bolt 17 can be screwed in continuously and thus axially adjustable, which has a matching external thread 18, here e.g. M10. The threaded bolt 17 penetrates the sleeve 12, which is open and continuous on the inside.

The sleeve 11 has an upper, slotted one facing the expansion body 10 End section 20 and a cylindrical one adjoining this in one piece Sleeve part 21, both of which have a continuous cylindrical outer circumferential surface 22 have. While the cylindrical sleeve part 21 also has a cylindrical inside Has circumferential surface 23 and is therefore also continuously cylindrical on the inside the end section 20 at least on such an axial area where it the expansion body 10 can accommodate inside, an approximately frustoconical inner peripheral surface 24, the cone angle at least substantially that of the frustoconical Outer surface 14 of the expanding wedge 13 corresponds. This frustoconical inner peripheral surface 24 can be seen particularly well in FIGS. 1 and 3. The wall of the sleeve 11 runs so over the axial area of the cylindrical sleeve part 21 constant with the wall thickness s, which is then the wall in the area of the upper End portion 20 starting from the smaller diameter conical base circle of the frustoconical Circumferential surface 24 up to the conical base circle which is larger in diameter tapered approximately wedge-shaped at the top. The wall of the end section 20 thus increases in Fig. 3 upwards, whereby with a continuously cylindrical outer circumferential surface 22, the inner frustoconical peripheral surface 24 is formed. This wedge-shaped Wall cross-section is formed by sheet metal deformation of the sheet metal part from which the Sleeve 11 is created, formed.

The end portion 20 of the sleeve 11 is slotted so that it is when Retraction of the expansion body 10 into the interior of this end section 20, with the wedge tip ahead, can expand radially. The wall of the end section is for this purpose 20 of the sleeve 11 via axially parallel slots 25 which are the same in the circumferential direction, for example Successive distances, divided into individual flaps 26, which by means of the retractable Spreader 10 are spreadable. The slots 25 are set in the axial direction into the wall of uniform cross-section of the cylindrical sleeve part 21, e.g. up to about half the length of the entire sleeve.

In these slots 25, approximately wing-like outer projections 27 engage a, which are arranged with the same angular division on the expansion body 10, namely there extend over the axial region of the expanding wedge 13 and radially outward stick out. The outer projections 27 together with the slots 25 form a form-fitting Anti-twist protection between the expansion body 10 on the one hand and the sleeve 11 on the other hand, so that when screwing the threaded bolt 17 into the expansion body 10 or in opposite directions Unscrewing this is fixed relative to the sleeve 11 and cannot rotate with it.

The end section 20 of the sleeve 11 points, for example, approximately halfway axially Length over which the slots 25 extend on its outer peripheral surface 22 an annular groove 28.

in the assembled state of the locking ring 12 in a form-fitting manner is held so that it is connected to the sleeve 11 in this way.

The approximately wing-like outer projections 27 of the expansion body 10 can have at least slightly recessed recesses 29 on their outside, so that at the lower end of these wing-like outer projections in FIGS 27 form protruding foot pieces 30, which in the assembled state of the anchor and before being inserted and fastened in the borehole in FIGS. 2 and 4 from below Hit the locking ring 12 and thus create an axial connection and axial securing form between the expansion body 10 and the sleeve 11 such that the expansion body 10 does not automatically move out of the slotted end section 20, upward in FIGS. 1-4 can slip out. The outer diameter of the recesses 29 in the wing-like Outer projections 27 is about as large as the groove base of the annular groove 28 in the sleeve 11. On the other hand, an opposing drawing-in movement of the expansion body into the sleeve 11 is possible undisturbed.

On the area facing away from the expansion body 10, the cylindrical Sleeve part 21 bent out of the cylinder wall, approximately fin-shaped locking tongues 31 on.

Appropriately, the locking tongues 31, viewed in the circumferential direction, each arranged on a gap between the slots 25 of the sleeve 11, which in particular from Fig. 3 and the section there can be seen. The outer peripheral surface of the Locking tongues 31 are at least substantially wedge-shaped, with the tip of the wedge in the direction of impact of the anchor and in the opposite direction to the tip of the cone of the expansion body 10 is directed. The lower end of the cylindrical sleeve part 21 in FIGS. 1-4 is unslotted so as not to cause any weakening of the cross-section.

Rather, the locking tongues 31 are unslotted at an axial distance therefrom Cylinder wall made from the material of the sleeve 11 punched out and with their free ends bent out radially, the free ends of the locking tongues 31 a substantial axial distance from the lower end of the sleeve in FIGS. 1-4 11 have. This distance between the free end of the locking tongues 31 and the end face at the lower end of the sleeve 11 is, for example, at least 1 cm to 1.5 cm, so that at Insertion of the anchor into a drill hole in an iron-reinforced concrete ceiling or wall the locking tongues 31 already store with their free ends in the area of the reinforcement.

The anchor is ready for assembly in the assembled state according to Fig. 2 and 4 provided. To install the anchor in a concrete wall or concrete ceiling, in the embodiment shown, for example, a borehole with the diameter bored, which corresponds to that of the outer peripheral surface 22 of the sleeve 11. This can e.g. be about 14 mm. Then the anchor is in the orientation according to Fig. 1-4, that is to say with the cylinder section 15 in front, inserted into the borehole. the Locking tongues 31 can have a radial protrusion of about 2mm. They stand in the way of pressing in the anchor without applying force.

To insert the anchor into the borehole, reference is therefore made to the method shown in Fig. 1 - 4 lower end of the sleeve 11 directly or by means of a pipe extension, Sleeve or the like beaten. The locking tongues 31 deflect radially inward and exert a strong expansion force and thus adhesive force against the borehole wall. As a result, the anchor is placed axially firmly in the borehole, so that there is no danger consists that the anchor is pulled out again approximately in the opposite direction to the direction of impact will. The opposing locking tongues 31 oppose this. Also one The locking tongues 31 are used to prevent the sleeve from rotating in the borehole. In this way of inserting the anchor into the borehole, the expansion body 10 is not strained at all.

Instead, the anchor can also be placed in the borehole in the following manner will. It is used as an assembly aid z.t3. the threaded bolt 17 in FIGS. 1-4 inserted into the sleeve 11 from the lower end and screwed into the expansion body 10. Then the anchor can be hammered into the borehole that on the lower end of the threaded bolt 17 is struck. The so on the expansion body The tensile force exerted by the latter is transferred to the sleeve 11 via the locking ring 12 transferred without the fuse can loosen, so that this also the Sleeve 11 is pulled into the borehole and the same anchoring means the locking tongues 31 results, as previously explained.

The anchor is already firmly anchored in the borehole.

The expansion effect that can be achieved by the expansion body 10 is, however not yet unfolded. If this is desired, it is inserted into the expansion body 10 screwed-in threaded bolts a tensile force directed downwards in FIGS. 1 - 4 exercised that already without any necessary abutment pulling in the expansion body 10 in the end section 20 of the sleeve 11 and thus causes the tabs 26 to spread open. In this area, there is already a pulling in due to the slight axial tensile force of the expansion body with its expansion wedge 13 in the frustoconical inner circumferential surface 24 and spreading possible, and this without the need for special special tools, Particularly great effort or the like .. Should then be a part of the concrete ceiling or concrete wall, in which the anchor is placed in this width, are attached, this can be done by means of a screw that can be screwed in more or less in height and thus adjustable threaded bolt 17 happen. With simple means, this is a Height adjustability achieved. There is no additional special tool required for assembly necessary, as well as additional other materials to compensate. from A particular advantage is a reliable anchoring without the stress of the Anchor this about in the borehole slip and thus something axially could wander. Since the assembly of the anchor does not require particularly strong turning or requires heavy hammering with various tools is the assembly no longer dependent on the reliability and skill of the assembly staff.

A reproducible anchorage of the same quality can always be achieved. Another important advantage is that a diameter as possible large threaded bolt 17 can be used and still used for the recording of the anchor required hole in the concrete only as small a diameter as possible needed. This results in above-average strengths and thus resilience possible. The expansion body 10 with an axially continuous internal thread 16 has due to this design also has a high degree of strength without resulting in an increase in size the diameter and thus any necessary enlargement of the necessary borehole diameter would result in concrete. This also contributes to the higher resilience.

The anchor is in this way both as a load-dependent anchor Can also be used with the same advantage as an Insat socket for all materials. He is relatively inexpensive due to the design of the sleeve 11 as a complete sheet metal part and the expansion body 10 as a forged part into which the internal thread 16 is introduced is.

In the second embodiment shown in Fig. 5 are for Parts that correspond to the first exemplary embodiment have reference numerals greater by 100 used, so that this leads to the description of the first embodiment Is referred to.

In the second embodiment, the locking tongues 131 are in the circumferential direction considered, in the same direction as the thread direction of the internal thread in the expansion body, not shown inclined. In this way, the anti-rotation device becomes one in a borehole Hammered anchor on these locking tongues 131 is still increased, as this Inclination when screwing in a threaded bolt with a right-hand thread in the screwing direction According to arrow 132 in the expansion body, the locking tongues 131 also oppose this.

Regardless of this inclination of the locking tongues 131 can In addition, the arrangement, as also shown in FIG. 5, can be made that between each two in the circumferential direction successive identical Locking tongues 131 is arranged at least one further locking tongue 133, which is opposite the locking tongue 131 is axially offset, so in Fig. 5 is higher than the locking tongue 131. In this way there is even greater security and liability when striking such an anchor given into a borehole, because then all the more secured is that the locking tongues 131, 133 are in the borehole wall at corresponding Claw in place. Blank page

Claims (20)

Claims 1. Anchors, in particular load-dependent dowels 1 with a slotted sleeve (11) into which an expansion body provided with wedge surfaces (14) (10), with the chisel point first, is retractable, one axially to both ends contains continuous internal thread (16) for a threaded bolt (t17), which means that c h e k e k e n n n e i c h n e t that the slotted sleeve (11) on its outer Peripheral surface (22) is cylindrical and at least in the area of one of the Spreader body (10) receiving end portion (20) an approximately frustoconical inner circumferential surface (24), the cone angle of which is essentially that corresponds to the wedge surfaces (14) of the expansion body (10). 2. Anchor according to claim 1, d a d u r c h g e k e n n z e i c hn e t, that the wall of the sleeve (11) is divided into individual tabs (26) by means of slots (25) is, which can be expanded by means of the retractable expansion body (10), and that in the slots (25) of the sleeve t11) corresponding to the expansion body (10), radial and approximately wing-like outer projections (27) engage axially, which together with the slots (25) a form-fitting anti-twist device between the sleeve (11) and form the expansion body (10). 3. Anchor according to claim 1 or 2, d a d u r c h g e -k e n n z e i c h n e t that on the end section (20) receiving the expansion body (10) the sleeve (11) is connected step-free by an inside and outside cylindrical sleeve part (21). 4. Anchor according to claims 2 and 3, d a d u r c h g e k e n n z e i c h n e t that the slots (25) are in the wall of the cylindrical sleeve part (21) continue inside. 5. Anchor according to one of claims 1-4, d a d u r c h g e k e n n z e i c h n e t that the slotted end section (20) of the sleeve (11) has a locking ring (12) which in recesses (29) on the outside of the slots (25) the sleeve (11) penetrating, approximately wing-like outer projections (27) of the expansion body (10) engages and the expansion body (10) at least in the opposite direction to the retraction direction of the expansion body (10) captively couples with the sleeve (11). 6. Anchor according to claim 5, d a d u r c h g e k e n n -z e i c h n e t that the locking ring (12) is designed as a transversely slotted spring ring, 7. Anchor according to claim 5 or 6; d a d u r c h g e -k e n n n z e i c h n e t that the locking ring (12) within an outer annular groove (28) of the slotted end portion (20) of the sleeve (11) is held in a form-fitting manner. 8. Anchor according to one of claims 3 - 7, d a d u r c h g e k e n n z e i c h n e t that the cylindrical sleeve part (21) on the other, the slotted one End portion (20) facing away from the end region from the wall of the sleeve part (21) has protruding locking tongues (31; 131, 133). 9. Anchor according to claim 8, d a d u r c h g e k e n n -z e i c h n e t that the locking tongues (31; 131; 133) in the circumferential direction on the gap between the Slots (25) and are arranged with an offset to these. 10. Anchor according to claim 8 or 9, d a d u r c h g e -k e n n z e i c h n e t> that the locking tongues (31; 131; 133) on their outside essentially run in the shape of a wedge, the tip of the wedge pointing in the direction of the anchor and in opposite directions runs to the tip of the cone of the expansion body (10). 11. Anchor according to one of claims 1 - 10, d a d u r c h g e k e n It is noted that the cylindrical sleeve part (21) at the slotted end section (20) the end region facing away from the sleeve (11) has an unslotted cylinder wall and that the locking tongues (31; 131; 133) at a distance from this unslotted cylinder wall from the material these are punched and bent out and with their free Ends at a substantial axial distance from the front end of the cylindrical sleeve part (21), which is, for example, at least 1 cm to 1.5 cm. 12. Anchor according to one of claims 8-11, d a d u r c h g e k e n n z e i c h n e t that the locking tongues (131, 133), viewed in the circumferential direction, equal little to the thread direction of the internal thread (16) of the expansion body (10) are inclined. 13. Anchor according to one of claims 8-12, d a d u r c h g e k e n n z e i c h n e t that between each two in the circumferential direction successive similar locking tongues (31; 131) at least one further, axially offset opposite Locking tongue (133) is arranged in the axial direction of the slotted end portion (20) is closer than the other locking tongues (31; 131). 14. Anchor according to one of claims 1-13, d a d u r c h g e k e n n z e i c h n e t that the expansion body (10) has a frustoconical expansion wedge (13), the approximately wing-like outer projections (27) of which have an outer diameter which corresponds at most to that of the largest cone base circle, 15th Anchor according to one of claims 1 - 14, d u r c h g e k e n n n z e i c h n e t, that at the end of the expanding wedge (13) with a thicker diameter there is a cylinder section (15) connects in one piece, through which the internal thread (16) extends. 16. Anchor according to claim 15 »d a d u r c h g e k e n n -z e i c h n e t that the outer diameter of the cylinder section (15) is equal to that of the is the largest conical base circle of the expanding wedge (13). 17. Anchor according to one of claims 1 - 16, d a d u r c h g e k e n n z e i c h n e t that the expansion body (10), possibly together with the approximately wing-like Outer projections (27), is formed from a one-piece forged part, which with the axially continuous internal thread (16) is provided. 16. Anchor according to one of claims 1 to 17, d a d u r c h g e k e n N z e i c h n e t that the slotted end section (20) of the sleeve (11) possibly together the cylindrical sleeve part (21) formed from a one-piece shaped sheet metal part is. 19. Anchor according to one of claims 1 to 18, d a d u r c h g e k e n n z e i c h n e t that the wall of the slotted end section (20) with constant Diameter of its outer peripheral surface (22) starting from the smaller in diameter Conical base circle up to the larger diameter conical base circle of the frustoconical inner circumferential surface (24) continuously tapers approximately in the shape of a wedge. 20. Anchor according to claim 19, d a d u r c h g e k e n n -z e i c h n e t that the wedge-shaped wall cross-section by sheet metal deformation of the sheet metal part is formed.