RU2575430C2 - Fastener - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates the fastener for locking in the drilled hole. The fastener contains a rod section and counterforce, wherein on the rod section the brace body with counterforces is located. The counterforce has several arc-like lobes, wherein each lobe is created by two ribs connected by a clamp. The ribs of the brace lobes together set side surface (M) of counterforces, this side surface is a body of rotation symmetrical relatively to the longitudinal axis of the fastener. At that the clamp has arc-like convexity, that in radial direction project beyond the side surface (M).

EFFECT: invention ensures the fastener use both in wide and narrow drilled hole.

8 cl, 2 dwg

Description

The invention relates to a fastener with signs of a restrictive part of paragraph 1 of the claims.

A fastener of this type for fastening with anchor bolts in a drilled hole is known from the laid-out description of the invention DE 4011229 A1. The fastening element described in this description is suitable, in particular, for fastening structural elements such as slabs, for example slabs of natural stone, to load-bearing structures. This fastener is designed as an anchor dowel for holes with undercuts and has a core section and an expansion element. On the rod portion, a spacer body expanding in diameter adjoins its inserted front end, by means of which the spacer element can be moved apart. The rod portion also has, on the rear side, means for applying a load. The spacer element consists of a wire ring with arches bent forward in the direction of the spacer body, spacer petals with two ribs connected by a U-shaped clamp at the front end. U-shaped collar in an unopened state lies on a spacer body. In addition, a spacer sleeve is placed on the core portion of the fastener. When the spacer sleeve moves in the direction of the conical spacer body along the axis of the core portion, the spacer sleeve presses on the spacer element through the spacer body expanding in the input direction, as a result of which the spacer petals are expanded so that they at least partially fill the undercut of the drilled hole. Due to the opening of the spacer tabs, the fastener is fixed in the drilled hole with a geometric closure.

A drilling tool is used to drill a hole, which, depending on the degree of wear, makes a relatively wide or narrow hole. With a relatively wide drilled hole with a known fastener, it may happen that the spacer does not completely block the space between the spacer body and the wall of the drilled hole, so that the fastener will not be fixed in the drilled hole.

The objective of the invention is to create a fastener for which the permissible deviations of the drilling tool will not be critical.

This task according to the invention is solved by a fastener with the features of paragraph 1 of the claims. According to the invention, the fastener for fixing in the drilled hole comprises a core portion and a spacer element. A spacer body for expanding the spacer element is located on the core portion. The rod section, in particular, is made in the form of a cone bolt with a conical, in particular in the form of a truncated cone, spacer body, which expands in the direction of entry and is located on the front end of the rod section from the input side. In addition, usually the rod portion has a means of applying a load, for example, a thread. The spacer element is usually made in the form of a sleeve, with the "shape of the sleeve" means that the spacer element essentially covers the circumference of the core portion. In particular, the spacer element is a sleeve closed around the circumference. By "insertion direction" or "insertion side" is meant the direction or side in which / with which the fastener is inserted into the drilled hole. The spacer element consists of several arcuate spacer petals, each spacer petal formed by two ribs connected by a clamp. In particular, the ribs and the collar of one petal are made thin-walled and / or in the form of a wire. The ribs of the spacer lobes together define the lateral surface of the spacer, which is a body of revolution that is symmetrical about the longitudinal axis of the fastener. In other words, the ribs lie on the lateral surface of the body rotationally symmetrical to the longitudinal axis, in particular, the cylinder or cone.

A distinctive feature of the fastener according to the invention is a special structural embodiment of the clamp of one or more spacer tabs. According to the invention, the collar of the at least one spacer lobe has a bulge that extends radially above the side surface. Due to this, the radial length of the clamp is greater than the thickness of the clamp material in the radial direction, as a result of which it is achieved that a part of the spacer in the region of the clamp in the expanded state penetrates further into the drilled hole into which the fastener is inserted. The spacer lobe can, therefore, also in the relatively wide drilled hole, the space between the wall of the drilled hole and the spacer body overlap so that the fastener in the drilled hole sits firmly.

In a preferred embodiment of the fastener according to the invention, the clamp forms the front end of the spacer tab. Thus, the clamp, when expanding the spacer lobe, is removed as far as possible in the radial direction of the longitudinal axis of the anchor and moves farthest in the direction of the wall of the drilled hole. Preferably, the apex of the arcuate bulge is directed radially outward from the spacer body. The top of the bulge is adjacent, while the first part of the clamp - to the wall of the drilled hole. Compared to the inward convexity, there is the advantage of reducing spacer forces. It is also an advantage that the arcuate bulge extends substantially circumferentially. In particular, the bulge passes along one axis and in the form of a bridge in a circle. If the arcuate bulge extends essentially in a circle and the vertex is directed radially outward, then this bulge acts as an element of roughness, a kind of tooth or rib, which increases the friction force between the spacer and the wall of the drilled hole, catching on the roughness of this wall.

In a further preferred embodiment of the fastener according to the invention, the bulge, due to its geometrical shape, acts in the radial direction as a leaf spring. If, for example, the bulge extends essentially like a bridge in one direction, for example, in a circle, then this bulge acts as a leaf spring. The fact that the bulge acts in the radial direction as a leaf spring has the advantage that the collar, when expanded, can adapt to the size and shape of the drilled hole. If the clamp adapted to the dimensions of the wide drilled hole only due to thickening of the material or massive relief, then in the narrow hole this would lead to the appearance of additional undesirable spacer forces when the fastener would open completely. Due to the geometric shape of the bulge in the form of a leaf spring, a device with relatively less force is possible. The leaf spring is pressed radially into the cramped hole without the occurrence of spacer forces of appreciable magnitude. In particular, if the clamp has a small cross section, for example, is made in the form of a wire, then the bulge is relatively elastic and easily deformed, so that even with small forces in the radial direction it acts like a spring.

In a further preferred embodiment of the fastener according to the invention, the spacer tabs are configured so that they taper in the direction of their free ends. In particular, a U- or V-shaped clamp connecting the transverse ribs forms the front end of the spacer in the direction of entry. This gives the advantage that the spacer tab in contact with the wall of the drilled hole can be more easily deformed, as a result of which the stresses that can occur when the fastener contacts the walls of the drilled hole when the spacer abuts against the bottom of the hole are reduced.

Another advantage is that the spacer of the fastener according to the invention has a closed annular main body at its rear end in the input direction, on which spacer tabs are located on the input side. The closed main body ensures that the spacer element does not extend beyond the spacer body even at high loads, and the fastener is securely fixed.

An advantage is that the spacer element of the fastening element according to the invention is a stamped part, in particular a metal part bent in a stamp. This simplifies and makes cheaper the manufacture of the spacer element and the fastener according to the invention.

The invention is further explained in more detail using one of the exemplary embodiments shown in the drawings.

SHOWN IN THE DRAWINGS:

FIG. 1 is a fastener according to the invention in an unopened state, a perspective view,

FIG. 2 is a partial sectional view of a fastener.

The drawings show the fastener 1 according to the invention in an unopened state, since it can be inserted in the direction of entry E into a hole not shown. The direction of entry E is oriented parallel to the longitudinal axis A of the fastener 1. The fastener 1 is designed as an anchor dowel for anchoring in an unimaged drilled hole with undercut. The fastener 1 consists of a core portion 2, a spacer 3 and a spacer sleeve 4.

The core section 2 is a conical bolt with a cylindrical section 5 and a conical section 6 adjacent to it from the input side, the diameter of which increases in the direction of the input E. The conical section 6 forms a spacer body 8, which has the shape of a truncated cone and forms the front end of the rod section 2 By means of the spacer body 8, the spacer 3 is expanded when it is pushed in the direction of the input E onto the conical section 6. The cylindrical section 5 has means 7 for applying a load in the form of an external thread. The load application means 7 serves, for example, to secure the fastener 1 to an unimaged load-bearing structure.

The spacer element 3 forms at its rear end an annular main body 10, which annularly covers the cylindrical section 5 of the core section 2 as a closed sleeve. On the main body 10, from the input side, there are four spacer tabs 11, which are circumferentially separated from each other by recesses 12. Each spacer tab 11 has an opening 13 in the form of an opening surrounded on all sides, which is located approximately in the middle of the corresponding tab 11. Spacer tabs 11 , thus, have an arcuate shape, with one spacer lobe 11 is formed using two ribs 14 and a U-shaped clamp 15, and the clamp 15 connects both ribs 14 together. The clamp 15 forms the front end of the spacer 11, which, due to the U-shape of the clamp 15, tapers in the direction of its front end.

The ribs 14 of the spacer tabs 11 together define a side surface M of the spacer 3, which is a rotational body symmetrical about the longitudinal axis A of the fastener 1 and has a conical shape. In other words, the ribs 14 lie on the lateral surface M of the body symmetrical about the longitudinal axis. The clamp 15 forms an arcuate bulge 17, which in the radial direction R protrudes beyond the side surface M and extends essentially along one axis around the circumference. The apex 18 of the bulge 17 points in a radial direction R outward from the spacer body 8. The protruding bulge 17 acts in the radial direction as a leaf spring, which can compensate for deviations in the diameter of the drilled hole. In the region of convexity 17, the radial extent of the collar 15 is greater than the thickness of the material of the collar 15, therefore, the apex 18 of the convex 17 is adjacent to the walls of the drilled hole even with a relatively wide drilled hole. If the drilled hole, on the contrary, is relatively narrow, then the springy bulge 17 is compressed in the radial direction, therefore, the spacer element 3 and in the narrow drilled hole can systematically slide on the spacer body 8, without the occurrence of undesirable large reaction forces of the material of the wall of the drilled hole. In particular, with the wire clamp 15, the convexity can be relatively radially compressed. By “wire type” is meant here that the clamp 15 has a cross section whose dimensions are relatively small relative to the length of the clamp 15 around the circumference. In the fastener 1 according to the invention shown in the drawings, the ratio of the circumferential length Aj of the clamp 15 to the thickness of the material dj of the clamp 15 in the radial direction is approximately 2.5 / 1.

Spacer sleeve 4 is made in the form of a hollow cylindrical body. Moreover, the cavity formed as a cylindrical hole 16 has an inner diameter that substantially corresponds to the outer diameter of the cylindrical portion 5 of the core portion of the core portion 2. When the spacer sleeve 4 is shifted in the direction of insertion E by a force acting along the axis, for example, under the influence of an unimaged driven tool, the spacer sleeve 4 presses on the spacer element 3 through the spacer body 8 so that the spacer tabs 11 open in the radial direction R.

So that when the fastener 1 is inserted into the hole and pushed into the external thread, the load application means 7 can be screwed on with a nut (not shown) so that the fastener 1 is not involved in the rotation, the latter is provided with protection against rotation. The first part of this anti-rotation protection is the nasal protrusion 9 on the conical portion 6 of the spacer body 8. The other parts of the anti-rotation protrusion form a recess 12 and an expansion lobe 11, to which the nasal protrusion 9 is adjacent in an unshown open state. The anti-rotation protection means transmit the torque that occurs when the nut is screwed on to the open spacer element 3 through a frictional closure on the unimaged wall of the drilled hole. Since the spacer element 3 of the fastening element 1 according to the invention due to the bulge 17 fits snugly against the walls of the drilled hole, this reliably prevents the fastening element 1 from turning in the drilled hole.

The spacer element 3 of the fastening element 1 is made as a metal part bent in a stamp. The rod portion 2 is also made of metal, which does not require large expenditures by the method of cold processing of sheet material by pressure. The spacer sleeve 4, in contrast, is made of a fiber-reinforced synthetic material by injection molding. The fastener according to the invention does not require high costs in production, effective due to its structural design and easy to assemble.

LIST OF REFERENCE POSITIONS

1. Fastener

2. The core section

3. Spacer element

4. Spacer sleeve

5. Cylindrical section

6. Conical section

7. Load application facility

8. Spacer body

9. Nose-shaped protrusion

10. The main body

11. Spacer lobe

12. Mining

13. The hole

14. Rib

15. Clamp

16. drilled hole

17. Bulge

18. The top of the bulge 17

E Direction of entry

A longitudinal axis

R Radial direction

Aj Clamp 15 circumference

dj The thickness of the clamp 15 in the radial direction R

M Side surface

Claims (8)

1. The fastener (1) for fixing in the drilled hole,
- with a rod section (2) and a spacer element (3),
- moreover, on the core section (2) is a spacer body (8) for opening the spacer element (3),
- moreover, the spacer element (3) has several arcuate spacer petals (11),
- wherein each expansion lobe (11) is formed by two ribs (14), which are connected by a clamp (15),
- moreover, the ribs (14) of the spacer tabs (11) together define the lateral surface of the spacer element (3), which forms a body of revolution symmetrical about the longitudinal axis (A) of the fastening element (1),
characterized in that the collar (15) of at least one expansion lobe (11) has an arcuate bulge (17), which in the radial direction (R) protrudes beyond the side surface (M). 2. A fastener according to claim 1, characterized in that the clamp (15) forms the front end of the spacer tab (11). 3. A fastener according to claim 1 or 2, characterized in that the apex (18) of the arcuate bulge (17) is directed radially outward from the spacer body (8). 4. A fastener according to claim 1, characterized in that the arcuate bulge (17) essentially extends in a circumferential direction. 5. A fastener according to claim 1, characterized in that the arcuate bulge (17) in the radial direction (R) acts as a leaf spring. 6. A fastener according to claim 1, characterized in that the spacer lobe (11) narrows to its front end. 7. A fastener according to claim 1, characterized in that the spacer element (3) at its rear end in the direction of entry (E) has a closed main body (10), on which spacers (11) are located. 8. The fastener according to claim 1, characterized in that the spacer element (3) is a stamped part, in particular, curved in a bending stamp.

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