DE102018116974A1 - expansion anchor - Google Patents

Abstract

The invention relates to an expansion anchor (1) for anchoring in concrete, which has an anchor shaft (2) made of metal, which extends along a longitudinal axis (L). A metal expansion sleeve (12) is arranged on an expansion section (13) and has an embossing (18) projecting radially outwards. According to the invention, the embossing (18) is designed in such a way that a connecting straight line (28) which is perpendicular to the longitudinal axis (L) from a tip (27) of the embossing (18) to the longitudinal axis (L) through a corner point (29) of a base area (23 ) of the embossing (18).

Description

The invention relates to an expansion anchor with the features of the preamble of claim 1.

From the European patent application EP 1 314 897 A2 a generic expansion anchor is known. The expansion anchor, a so-called bolt anchor, comprises a pin-shaped anchor shaft with an external thread, which is arranged on the anchor shaft at the rear as a load introduction device. The expansion anchor has an expansion area at the front, with an expansion section of the anchor shaft on which an expansion sleeve is arranged. At the front of the expansion section there is an expansion cone which can be drawn into the expansion sleeve, as a result of which the expansion sleeve is expanded and pressed against a wall of a borehole into which the expansion area is inserted for anchoring the expansion anchor. For anchoring, the expansion sleeve must be expanded by moving the anchor shaft back. In order to enable the expansion, the expansion sleeve must be held so firmly in the borehole that it does not move, or at least not to the same extent, when the anchor shaft moves back out of the borehole, through which the expansion cone is drawn into the expansion sleeve for expansion the expansion cone, as this would prevent spreading. In order to ensure that the expansion sleeve is held in the borehole even before the actual expansion, the known expansion anchor has pyramid-shaped embossments which protrude radially outwards from a cylindrical base body of the expansion sleeve that is slotted at the front end. The embossments each have a tip at their rear end, with which the embossments engage in the wall of the borehole and thus hold the expansion sleeve in place in the borehole. However, when the expansion anchor is driven into the borehole, the tips wear out due to friction on the wall of the borehole, which means that after driving in, there is no longer a point and the pyramid rounded off due to the friction does not prevent the expansion sleeve from moving back when the anchor shaft moves back can hold more in the borehole, so that it is not possible to spread the expansion sleeve as planned.

The object of the invention is therefore to improve the known expansion anchor so that a planned spreading of the expansion sleeve is guaranteed.

This object is achieved according to the invention by an expansion anchor with the features of claim 1. The expansion anchor according to the invention for anchoring in concrete has an anchor shaft made of metal, which extends along a longitudinal axis. The anchor shaft has a pin-like basic shape, ie it is several times longer than its diameter or, in the case of a non-circular cross section of the anchor shaft, than the diameter of a circle that describes the cross section of the anchor shaft. A load introduction device, in particular an external thread or an internal thread, is provided on the anchor shaft at the rear, with which a load can be transferred from an add-on part, which is fastened to the anchoring base with the expansion anchor, to the expansion anchor. At the front, the anchor shaft has an expansion section on which a metal expansion sleeve is arranged. "Front" and "rear" refer to the direction in which the expansion anchor is inserted into a borehole in the base of the anchor. The anchoring base, for example a ceiling or a wall of a building, is in particular made of concrete. The expansion section and expansion sleeve form the expansion area of the expansion anchor, with which the expansion anchor can be anchored in the anchoring base in such a way that the load can be transferred from the attachment to the anchoring base via the expansion anchor. For anchoring, the expansion anchor is inserted or driven into the borehole in the direction of insertion with the expansion area ahead, the expansion sleeve, which surrounds the anchor shaft in the expansion section in the circumferential direction, braced against the borehole wall. “Reaching around” does not necessarily mean a complete reaching around here, but only that the expansion sleeve is held captively on the anchor shaft, but can be moved forward in the longitudinal direction. The expansion sleeve must also be expanded to ensure it is securely anchored in the borehole. For this purpose, the expansion sleeve can be moved forward relative to the anchor shaft along the longitudinal axis, so that an expansion element of the expansion section, which is particularly wedge-shaped and widens in diameter in the direction of insertion, reaches the expansion sleeve and presses it apart radially and thereby expands it. For this purpose, the expansion sleeve has slots at its front end in particular, which divides an especially hollow cylindrical base body of the expansion sleeve into a front section into individual expansion arms. The base body does not have to form a closed cylinder. It can be produced in particular by stamping, shaping and / or bending from a flat sheet metal and have a slot which is continuous in the longitudinal direction.

After the expansion area of the expansion anchor according to the invention has been inserted into a borehole and the expansion sleeve has braced against the wall of the borehole, the anchor shaft is pulled backwards in the opposite direction of the insertion direction. As a result, the expansion element, for example an expansion cone, is drawn into the expansion sleeve and the expansion sleeve is expanded, expanded and further braced against the wall of the borehole. The return movement of the anchor shaft relative to the expansion sleeve corresponds to a relative movement of the expansion sleeve to the anchor shaft forwards. So that the expansion sleeve clamped in the borehole at the Back movement of the anchor shaft spreads out and is not moved backwards out of the borehole by the return movement of the expansion element, a radially outwardly projecting embossment is arranged in one piece on the base body. The embossing serves to increase the friction with and / or to engage in the borehole wall, which increases the hold of the expansion sleeve in the borehole. The embossing itself has a real or imaginary base surface that faces the base body, a side surface and a tip. The base area lies flat against an outer surface of the base body that circumscribes the base body. The base area geometrically forms the transition from the embossing to the base body. The tip of the embossing protrudes radially outward from the base body and forms the radially outermost point of the embossing. In addition, the tip is arranged on the embossing in such a way that it forms the rear end of the embossing alone or with another point, an edge or a surface. The base area and the tip are connected to one another by the at least one side area which intersects the base area in a base edge. The embossing can also have a plurality of side surfaces, each side surface intersecting the base surface with a base edge.

The embossing need not be massive. It is produced in particular by embossing the base body, that is to say by locally pressing it into the material of the base body, without producing a slot or an opening. In particular, the base body consists of a bleaching strip bent in the circumferential direction, from which the embossing is pressed outwards in the radial direction, which is in particular curved outwards. This means that the embossing is in particular a type of curvature in which the material of the base body is pressed radially outwards, but is not removed from the base body. The material pressed outwards forms the embossing, which protrudes geometrically radially over the base body. Such an embossing has a high resistance to radial compression when the expansion sleeve is inserted into a borehole.

It is characteristic of the expansion anchor according to the invention that the embossing is designed in such a way that a straight line perpendicular to the longitudinal axis runs through the tip and the longitudinal axis runs through a corner point of the base area. The connecting straight line thus forms the perpendicular to the longitudinal axis through the tip, it being possible for the straight connecting line to deviate from the theoretically exact perpendicular within a few degrees within the manufacturing tolerances. The "corner point" is any point on the base edge. If the embossing has several side surfaces, the corner point is in particular the intersection of two side surfaces with the base surface. The corner point forms the rear end of the embossing with the tip. Such an embossing has the advantage that even if the original tip of the embossing was worn when driving the expansion area of the expansion anchor into a borehole, a kind of tip is still formed by an edge directed backwards and running radially to the longitudinal axis between the corner point and the tip, which lies on the connecting straight line. The radially outer point of this edge then acts as a tip, which prevents the expansion sleeve from moving backwards out of the borehole when it is spread.

According to the invention, exactly one embossing can be provided on the expansion sleeve. In particular, the expansion sleeve has at least two, in particular at least three, embossments which are arranged on the expansion sleeve in an evenly distributed manner in the circumferential direction. If spreading arms which are separated by slots are provided on the expanding sleeve, an embossing can in particular be arranged on each of the spreading arms. In particular, the embossing is not arranged on the front of the expansion sleeve, in particular it does not form the front end of the expansion sleeve. In contrast, it can be arranged at the rear end of the expansion sleeve, the embossing preferably being arranged such that its base is enclosed on all sides by the outer surface of the base body. The embossing thus forms neither the front nor the rear end of the expansion sleeve. The embossing can in particular be pyramid-shaped, for example as a tetrahedron with flat triangular surfaces, it being possible for the side surfaces to also be spatially curved.

The embossing rises in particular against the direction of insertion along the longitudinal axis in the radial direction from the base to the tip, in particular from a base edge forming a transition to the embossing. The increase can also be discontinuous, for example in several sections. The embossing thus forms a type of wedge shape, which facilitates the insertion of the expansion sleeve into a borehole in the direction of insertion. However, pulling out of the borehole is made more difficult by the edge formed at the rear end of the embossing and running between the corner point and the tip.

In a preferred embodiment of the expansion anchor according to the invention, the at least one side surface of the embossing extends in the circumferential direction, so that it forms a rear side of the embossing. This back side includes the top of the embossing. This side surface forming the rear side lies in particular in a radial plane to the longitudinal axis, ie it runs purely in the circumferential direction. In this embodiment, the rear side surface preferably rises in the radial direction as seen from behind and in a clockwise direction with respect to the longitudinal axis, from the base surface to the tip, the increase can also be discontinuous. The embossing thus also forms a kind of wedge in the circumferential direction, which prevents the expansion sleeve from turning when, as is usual with bolt anchors, the return movement of the anchor shaft out of the borehole takes place by unscrewing a nut onto an external thread acting as a load introduction device.

It is further preferred that the embossing of the expansion anchor according to the invention has at least two side surfaces which intersect and whose cutting edge encompasses the tip. These two side surfaces include in particular an angle between 60 degrees and 120 degrees, in particular an angle between 80 degrees and 100 degrees. In particular, the side surfaces form an angle of essentially 90 degrees. The side surfaces thus also form a type of wedge that inhibits movement of the expansion sleeve out of a borehole.

The two side surfaces are preferably arranged normal to the lateral surface of the base body. "Normal to the lateral surface of the base body" means that at each intersection of the base body and the side surface there is a surface normal of the base body in a tangent plane to the side surface. In particular, the tangential plane is a radial and / or an axial plane, in particular one of the tangential planes is a radial plane and the other is an axial plane. Such a configuration of the side surfaces leads to a great resistance of the expansion sleeve against being pulled out of the borehole.

In a further preferred embodiment of the expansion anchor according to the invention, the two side surfaces face towards the rear. This means that the two side surfaces protrude in a plan view from behind in the direction of insertion and protrude beyond the base body of the expansion sleeve. In other words, the vectors of the surface normals of these side surfaces have a component which is directed parallel to the longitudinal axis against the direction of insertion. In this embodiment, the two side surfaces are preferably inclined to the longitudinal axis. This means that when the surface normals of a side surface are projected into an axial plane of the longitudinal axis in which the longitudinal axis lies, the projection of the surface normals is inclined with respect to the longitudinal axis. The angles of inclination of the two side surfaces to the longitudinal axis are preferably the same. Each of the angles of inclination is in particular between 30 degrees and 60 degrees, as a result of which a kind of wedge shape of the side surfaces arises from a drill hole against the direction of extension.

It is further preferred that the two side surfaces are symmetrical about an axial plane of the longitudinal axis, which facilitates the production of the embossing.

It is further preferred that a base edge of the base surface does not run in a straight line, but in particular in an arc shape. In particular, the embossing has three base edges, two of the base edges running in a straight line and the third base edge in an arc shape. In this case, the two rectilinear base edges belong to flat side surfaces which in particular run normal to the lateral surface of the base body and whose intersection forms the corner point which lies with the tip on the connecting straight line which runs perpendicular to the longitudinal axis. On the other hand, the arched base edge is particularly oriented towards the front in the direction of insertion and the associated side surface, which can also be referred to as the "wedge surface" or "inclined surface", rises radially from the base edge to the tip against the direction of insertion. An angle between the lateral surface and the wedge or inclined surface is a maximum of 30 degrees. This embodiment has proven to be particularly advantageous since it does not increase the insertion resistance of the expansion sleeve into a borehole or only slightly increases it compared to the embossments known from the prior art, but significantly improves the resistance of the expansion sleeve to being pulled out of a borehole.

The features and combinations of features, designs and configurations of the invention mentioned above in the description, as well as the features and combinations of features mentioned below in the description of the figures and / or drawn in a figure, are not only in the respectively specified or drawn combination, but also in any other desired manner Combinations or can be used individually. Embodiments of the invention are possible which do not have all the features of a dependent claim. Individual features of a claim can also be replaced by other disclosed features or combinations of features. Embodiments of the invention are possible which do not have all the features of an exemplary embodiment, but rather any part of the marked features of an exemplary embodiment, optionally in combination with one, more or all of the features of the further exemplary embodiment.

• 1 einen ersten erfindungsgemäßen Spreizanker in einer Seitenansicht;
• 2 eine vergrößerte Darstellung des Spreizbereichs des ersten erfindungsgemäßen Spreizankers in einer gegenüber der 1 um 90° um die Längsachse gedrehten Seitenansicht;
• 3 eine Draufsicht auf die Abwicklung der Spreizhülse des ersten erfindungsgemäßen Spreizankers;
• 4 eine Draufsicht auf die Abwicklung einer alternativen Spreizhülse für den erfindungsgemäßen Spreizanker; und
• 5 eine Schnittdarstellung eines Spreizarms der alternativen Spreizhülse aus 4 entlang der Schnittlinie V-V.

The invention is explained below with reference to the drawing. Show it:

• 1 a first expansion anchor according to the invention in a side view;
• 2 an enlarged view of the expansion area of the first expansion anchor according to the invention in a compared to the 1 Side view rotated by 90 ° around the longitudinal axis;
• 3 a plan view of the development of the expansion sleeve of the first expansion anchor according to the invention;
• 4 a plan view of the development of an alternative expansion sleeve for the expansion anchor according to the invention; and
• 5 a sectional view of an expansion arm of the alternative expansion sleeve 4 along the cutting line VV ,

In 1 is a first expansion anchor according to the invention 1 shown for anchoring in an anchoring base made of concrete. The expansion anchor 1 includes an anchorage 2 Made of metal that extends along a longitudinal axis L from a rear end 3 in the direction of insertion e of the expansion anchor 1 into a borehole in the anchoring base (not shown) to a front end 4 extends. The back end 3 of the expansion anchor 1 forms the face of a knock-in pin 5 with an external thread 6 as a load introduction device 7 followed. On the external thread 6 is a mother 8th screwed on with a washer 9 can be braced against an attachment (not shown) against the anchoring base. To the external thread 6 closes in the direction of insertion e a non-threaded spacer 10 with a covenant 11 that has a stop for an expansion sleeve 12 forms. In the direction of insertion e in front of the federal government 11 points out the anchorage 2 a spreading section 13 in which the expansion sleeve 12 a reduced diameter neck section of the anchor shaft 2 encompasses in the circumferential direction. The expansion sleeve 12 is captive due to the change of grip, but relative to the anchorage 2 along the longitudinal axis L forward against one as a spreading element 14 acting expansion cone 15 displaceable. The expansion sleeve 12 has two slots 16 on in the longitudinal direction from the front end of the expansion sleeve 12 run backwards, in the back in a hole 19 ends, and the the front two thirds of the expansion sleeve 12 in three spreader arms 17 divided that when pushing on the expansion sleeve 12 on the expansion cone 15 are pushed radially outward to spread. The slots 16 and the division of the spreading arms 17 is particularly good in 3 to recognize the flat development of the expansion sleeve 12 or the expansion sleeve 12 shows before this around the neck portion of the anchor shaft 2 was bent around.

So that the expansion sleeve 12 after insertion of the expansion section 13 of the expansion anchor 1 finds a firm hold in the borehole in a borehole before spreading, so that the expansion sleeve 12 by shifting the anchor shaft 2 against the direction of insertion e by tightening the mother 8th can be spread out is on each of the spreading arms 17 an imprint 18 arranged. The imprints 18 stand by a basic body 20 the expansion sleeve 12 radially outwards. The basic body 20 is formed from the flat undeformed sheet metal strip from which the expansion sleeve 12 will be produced. When the expansion anchor is not expanded 1 as he in the 1 and 2 is shown, the base body 20 a cylindrical surface 21 on that in the handling of the 3 a flat rectangular surface 22 forms. The one on the main body 20 arranged embossments 18 each have an imaginary base area 23 , three sides 24 . 25 . 26 and a tip 27 on. The footprint 23 is the basic body 20 facing and is due to this. The footprint 23 forms the dividing surface between an embossing purely geometrically 18 and the outer surface 21 of the basic body 20 , The three side surfaces 24 . 25 . 26 connect the base 23 with the top 27 , Each of the tips 27 of the three imprints 18 the expansion sleeve 12 stands radially outwards from the base body 20 and forms the radially outermost point and the respective rear end of the embossing 18 , Here are the imprints 18 designed such that one each on the longitudinal axis L vertical connecting straight line 28 from the respective tip 27 to the longitudinal axis L through a corner point 29 the base area 23 runs ( 2 ). Between the corner point 29 and the top 27 forms the connecting line 28 a cut edge 30 the first side surface 24 and the second side surface 25 , This cut edge 30 forms together with the top 27 the rear end of the embossing 18 , The two side faces 24 . 25 run normal, i.e. perpendicular, to the lateral surface 21 of the basic body 20 , Both rise from the floor 23 back to the top 27 radially towards and are turned towards the back and of the same size. The first face 24 , and the second side surface 25 are to the longitudinal axis L each at an angle of inclination α ₁ . α ₂ inclined by 45 ° like this in 1 you can see. So the two side faces 24 . 25 to an axial plane of the longitudinal axis L symmetrical. The third side surface 26 points to the development of the top view 3 the shape of a circular sector, the center of which is the corner point 29 forms. The cut of the third side surface 26 with the footprint 23 thus forms a base edge 31 , which is not straight, but curved, in the development in the form of an arc.

Will the expansion sleeve 12 inserted into a borehole, so the tip grips 27 into the borehole wall and holds the expansion sleeve 12 in the borehole. Because the imprints 18 from the main body 20 embossed and not punched, they are stable and can be compressed less radially than punched and bent, cantilever-shaped wings. Because the top 27 with the cut edge 30 the rear end of each imprint 18 is the top 27 protected against deformation due to friction on the borehole wall during insertion. But even if the top 27 should be rubbed off during insertion, it remains on the outside and tapered cutting edge at the back 30 for engaging in the borehole wall.

The 4 and 5 show an alternative embodiment of the expansion sleeve 12a that up to the embossing 18a with the expansion sleeve 12 the 1 to 3 is identical. In order to avoid repetitions, only the embossing will follow 18a received. The embossing 18a is also in the top view of the development also a circular sector, the outer geometry with the embossing described above 18 identical, but compared to the embossing described above 18 by 45 ° to the longitudinal axis L is rotated.

Due to the rotation is the second side surface 25a parallel to the longitudinal axis L , and the first face 24a runs in the circumferential direction. The first face 24a forms the rear side of the embossing 18a which here as the only side surface 24a is facing backwards. It rises from behind in the direction of insertion e seen and related to the longitudinal axis L clockwise from the base 23 radial to the tip 27 towards.

In both designs of the expansion sleeve 12 . 12a form the side surfaces 26 . 26a of the mintings 18 . 18a wedge-shaped surfaces that rise radially to the rear. This facilitates insertion into a borehole. The peaks 27 . 27a or the radially outer ends of the cut edges 30 . 30a hold the expansion sleeves 12 . 12a for spreading safely in the borehole and prevent the expansion sleeve 12 . 12a when spreading from and with the expansion cone 15 is moved out of the borehole.

LIST OF REFERENCE NUMBERS

1

expansion anchor

2

anchor shank

3

rear end of the expansion anchor 1

4

front end of the expansion anchor 1

5

in pin

6

external thread

7

Load transfer device

8th

mother

9

washer

10

spacer section

11

Federation

12, 12a

expansion sleeve

13

spreading

14

spreader

15

expansion cone

16

slot

17

spreading arm

18, 18a

embossing

19

drilling

20

body

21

lateral surface

22

rectangular area

23, 23a

Floor space

24, 24a

first side surface

25, 25a

second side surface

26, 26a

third side surface

27, 27a

top

28

connecting line

29, 29a

vertex

30, 30a

cutting edge

31,31a

base edge

e

of introduction

L

longitudinal axis

α ₁

Tilt angle of the first side surface 24

α ₂

Inclination angle of the second side surface 25

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• EP 1314897 A2 [0002]

Claims (10)

Expansion anchor (1) for anchoring in concrete, which has an anchor shaft (2) made of metal, which extends along a longitudinal axis (L) and has a load introduction device (7) at the rear and an expansion section (13) at the front, the expansion section (13 ) an expansion sleeve (12, 12a) made of metal is arranged, the expansion sleeve (12, 12a) encompassing the anchor shaft (2) in the circumferential direction and being displaceable relative to the anchor shaft (2) along the longitudinal axis (L), the expansion sleeve (2) has a base body (20) on which an embossment (18, 18a) protruding radially outward from the base body (20) is arranged in one piece, the base surface (23, 23a), at least one side surface (24, 24a, 25 , 25a, 26, 26a) and a tip (27, 27a), the base surface (23, 23a) facing the base body (20), the side surface (24, 24a, 25, 25a, 26, 26a) the base surface (23, 23a) connects with the tip (27, 27a) and the tip (27, 27a) to the outside radially protrudes from the base body (20) and forms the radially outermost point and the rear end of the embossing (18, 18a), characterized in that the embossing (18, 18a) is designed such that one is perpendicular to the longitudinal axis (L) standing connecting line (28) through the tip (27, 27a) and the longitudinal axis (L) through a corner point (29, 29a) of the base surface (23, 23a). Expansion anchor after Claim 1 , characterized in that the side surface (24a) of the embossing (18a) extends in the circumferential direction and forms a rear side of the embossing (18a) which includes the tip (27a). Expansion anchor after Claim 2 , characterized in that the side surface (24a) seen from the rear and increases radially with respect to the longitudinal axis (L) clockwise from the base surface (23a) to the tip (27a). Expansion anchor according to one of the preceding claims, characterized in that the embossing (18, 18a) has at least two intersecting side surfaces (24, 24a, 25, 25a), the cutting edge (30, 30a) of which comprises the tip (27, 27a). Expansion anchor after Claim 4 , characterized in that the two side surfaces (24, 24a, 25, 25a) are arranged normal to the lateral surface (21) of the base body (20). Expansion anchor after Claim 4 or Claim 5 , characterized in that the two side surfaces (24, 25) face backwards. Expansion anchor according to one of the Claims 4 to 6 , characterized in that the two side surfaces (24, 25) are inclined to the longitudinal axis (L). Expansion anchor after Claim 7 , characterized in that the angle of inclination (α ₁ , α ₂ ) of the two side surfaces (24, 25) is the same. Expansion anchor according to one of the Claims 4 to 8th , characterized in that the two side surfaces (24, 25) are symmetrical to an axial plane of the longitudinal axis (L). Expansion anchor according to one of the preceding claims, characterized in that a base edge (31, 31a) of the base surface (23, 23a) does not run in a straight line, but in particular in an arc shape.

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