DE102010060611A1 - Anchor for driving into substrate, particularly into non-cohesive base, has holding element which is elastically bendable, such that holding element curves opposite to driving direction during driving of anchor into substrate - Google Patents

Abstract

The anchor (1) has an armature shaft (2), where an anchor point (3) is arranged at the front in a drive side. A holding element (4) is provided for produce a holding force in an underground, and has a diameter larger than the diameter of the armature shaft. The holding element is elastically bendable, such that the holding element curves opposite to the driving direction during the driving of the anchor into a substrate. The holding element is made of plastic.

Description

The invention relates to a ground anchor with the features of the preamble of claim 1.

Ground anchors are known from the prior art. In addition to so-called herring and earth screws, as for example in the German utility model DE 295 03 115 U1 are described, ground anchors are also common, which have a special holding element for generating a holding force in the ground. Thus, the published patent application DE 29 19 173 A1 in the 16 and 17 a ground anchor with an anchor shaft and a eintreibseitig front arranged anchor point on which a holding element for generating a holding force in the ground is arranged. The holding element consists of three blades, which are fastened to the ground anchor in such a way that they are pivotable about axes which run in the direction of the longitudinal axis of the ground anchor. The blades can be swung into the ground after driving in the ground anchor. The swung-out blades cause the ground anchor can initiate high holding forces into the ground, so that objects can be attached to the ground with the ground anchor. The from the published patent DE 29 19 173 A1 known ground anchor is particularly suitable for non-binding substrates of gravel and sand. Similar ground anchors are from the published patent application GB 2 315 285 A and the utility model DE 200 13 087 U1 known.

A disadvantage of the known ground anchors is either that their holding power in non-cohesive soils is very low or that the additional holding element, which is intended to improve the holding force of the ground anchor in non-cohesive substrates, requires a relatively large additional installation effort and makes the production of the ground anchor expensive.

The object of the invention is therefore to provide a ground anchor, which is easy to assemble and in particular has a large holding force in non-cohesive soils.

This object is achieved by a ground anchor with the features of claim 1. The ground anchor according to the invention is suitable for driving into a subfloor, in particular in non-cohesive soils. "Driving in" in this context means that the ground anchor can be, for example, hammered into the ground, shaken or screwed. "Non-binding" are in particular surfaces of sand and / or gravel. The ground anchor according to the invention has an armature shaft and an armature tip arranged in front of the ground anchor in the driving direction. The anchor tip does not have to be pointed. It can also be dull or rounded. Rather, "anchor tip" means that this component is arranged on the drive side front of the ground anchor and suitable in shape and choice of material for driving into a ground. On the armature shaft a load application means is arranged, with which the ground anchor can be connected to an object to be fastened. The load application means may for example be formed as a thread, plate-shaped for attaching a geotextile, hook-shaped or tubular for receiving a parasol. To generate a large holding force in the ground, a holding element is arranged on the ground anchor.

Characteristic of the ground anchor according to the invention is that the holding element has a larger diameter than the armature shaft, even in a pre-assembly position, before the ground anchor is driven into the ground. By "diameter" is meant in a non-circular cross-section of the diameter of the armature shaft or the retaining element circumscribing circumference, wherein the diameter is measured radially to the longitudinal axis of the ground anchor. In order to generate large holding forces, the holding element is thus in the radial direction over the armature shaft. In order for the ground anchor to be easily driven into the ground despite the enlarged diameter of the retaining element in relation to the shank, the retaining element is elastically bendable, such that the retaining element bulges against the driving direction when the ground anchor is driven into the ground. The elastic retaining element is bent backwards counter to the driving direction by the resistance of the substrate, which counteracts the driving in, so that the driving resistance of the retaining element is reduced. The retaining element bulges in particular so that it is stabilized in itself due to the deformation. The stabilization prevents the retaining element from being compressed or folded together and completely resting against the armature shaft, which would mean that the retaining element could produce only a small retaining force in the ground. The holding element is designed such that it generates high holding forces without further assembly steps in the ground, as it has a larger diameter than the anchor shaft due to the curvature even after driving and thus a considerable resistance to movement out of the ground and thus a large Holding force generated. In addition, the curvature causes material of the subsurface, for example sand, which is located within the curvature, can not move out of the support element with a movement of the ground anchor out of the ground, which would facilitate extraction of the ground anchor from the ground. The curved against the driving direction holding element acts like a parachute or a trawl net, which encloses the material within the curvature.

The ground anchor according to the invention can be produced inexpensively, since no additional mechanical parts and devices for activating the retaining element in the ground are necessary. The ground anchor according to the invention can be in a simple manner, for example, striking drive in the ground and is easy to install due to its design.

In a preferred embodiment, the holding element is disc-shaped, wherein "disk-shaped" not necessarily means circular, but the disc can also be oval, with one or more, for example, finger-like shaped segments or even square. "Disc-shaped" means that the extension of the retaining element in two directions, the disc plane, is significantly greater than in the third direction, wherein the third direction is the direction of the longitudinal axis of the ground anchor. Preferably, the disc-shaped retaining element is arranged on the ground anchor such that the longitudinal axis of the ground anchor is substantially orthogonal to the disc plane. The longitudinal axis of the ground anchor then forms the surface normal to the disk plane. The disc-shaped design of the retaining element has the advantage that the retaining element is arched when driving into the ground, creating a stable in itself arching mold. The disk-shaped holding element can be bent so far that an optimum between the penetration resistance into the ground and the holding force in the ground is achieved. By arranging the disc plane orthogonal to the longitudinal axis, the holding force is maximized.

Preferably, the holding element is made of plastic, such as polyamide PA 6. A holding element made of plastic can be easily bent and can still be so strong that a formation of a stable vault is possible without the holding element breaks at high holding forces. If the holding element is disk-shaped, the disk can also be bent due to the elasticity of the plastic if it is made relatively thick. Due to the use of plastic, the holding element is also inexpensive to produce, for example as an injection molded part.

Furthermore, it is preferred that the ground anchor has a first abutment for the holding element. The first abutment supports the holding element when driving into the ground. A further preferred embodiment of the ground anchor according to the invention has a second abutment for the holding element. The second abutment supports the holding element in a movement out of the ground. The abutments prevent the retaining element from being released from the ground anchor or its position on the ground anchor being substantially changed with respect to the longitudinal axis of the ground anchor when the ground anchor is moved in the underground. Preferably, the first abutment is arranged on the armature shaft, for example as a stop shoulder in the form of a circumferential collar at the front end of the armature shaft. Furthermore, it is preferred that the second abutment is arranged on the armature tip, on which it is formed, for example, as a flat bearing. Preferably, the holding element is arranged between the armature shaft and armature tip, which favors a simple construction of the ground anchor.

In a further preferred embodiment of the ground anchor according to the invention, the anchor tip on a wedge-like cutting edge, which allows easy penetration of the ground anchor into the ground. The cutting edge may be formed, for example, pyramidal, conical, star-shaped or as a flat chisel with a line-shaped cutting edge, depending on in which background the ground anchor is to be driven.

Preferably, the wedge-like blade, with respect to the longitudinal axis of the ground anchor, uniaxially stretched in a radial direction. The cutting edge has, for example, the shape of a saddle roof with the base of an elongated rectangle. The uniaxially stretched shape of the cutting edge has the advantage that the cutting edge for the holding element act as a line support and thus can take over the function of the second abutment, but still the driving resistance of the ground anchor in the ground is relatively low. It is preferable that the cutting edge has a width of 35 mm to 80 mm in the one radial direction, with a width of substantially 50 mm being preferred. The cutting edge is in the orthogonal radial direction only 10 mm to 30 mm, preferably substantially 20 mm wide.

A further preferred embodiment of the ground anchor according to the invention has a second wedge-like cutting edge, which is uniaxially stretched in a second radial direction. In particular, the second wedge-like cutting edge is also arranged on the armature tip. Furthermore, it is preferred that the second cutting edge is substantially orthogonal to the first cutting edge. The two cutting edges can be integrally connected to each other and made as one part.

Alternatively to the formation of one or more wedge-like cutting edges on the armature tip, the armature tip can be helical. The ground anchor is then not hammered, but driven in rotation, in the manner of a screw, driven into the ground.

Preferably, at least one of the armature shank of the ground anchor according to the invention wing-like support element arranged. The support element is arranged on the armature shaft spaced from the armature tip. If the ground anchor loaded transversely to its longitudinal axis, the support member takes on a portion of the transverse loads and prevents the ground anchor tilts around a tilt axis orthogonal to the longitudinal axis and is shaken loose by repeated transverse load.

The invention will be explained in more detail with reference to two embodiments illustrated in the drawings.

Show it:

1 a first ground anchor according to the invention in a perspective view;

2 the first ground anchor according to the invention in a first side view;

3 the first ground anchor according to the invention in a second side view, in which the ground anchor against the 2 rotated 90 ° about its longitudinal axis;

4 the first ground anchor according to the invention in a sectional side view in the direction of 3 illustrated arrows A;

5 a second ground anchor according to the invention in the installed state in a first side view;

6 the second ground anchor according to the invention in the installed state in a second side view, in which the ground anchor against the 5 rotated 90 ° about its longitudinal axis;

7 a third ground anchor according to the invention in a perspective view; and

8th a fourth ground anchor according to the invention in a perspective view.

The 1 to 4 show a first ground anchor according to the invention 1 , The ground anchor 1 is elongated along its longitudinal axis A _E and has an armature shaft 2 , an anchor tip 3 that the drive side front end of the ground anchor 1 forms, and a holding element 4 on, between the anchor point 3 and the armature shaft 2 is arranged.

The anchor shaft 2 is designed as an elongated cylinder, with a load application 5 in the form of a thread, which is at its in the driving direction rear end of the armature shaft 2 is arranged. On the load attack 5 For example, a nut or a threaded eye (not shown) can be screwed, with the ground anchor 1 with an object to be fastened (not shown) is connectable. The anchor shaft 2 is made of a glass fiber reinforced polyamide. As in 4 can be seen, the anchor shaft 2 at its front end in the driving direction a central bore 6 with an internal thread 7 on, leaving the anchor tip 3 by means of an external thread formed on a cylindrical pin 8th at the back end of the anchor point 3 is placed in the hole 6 screwed in and with the anchor shaft 2 tensile strength can be connected. In addition, the anchor tip 3 with the anchor shaft 2 by an additional gluing of the thread 7 . 8th rotatably connected. Alternatively, the anchor tip 3 with the anchor shaft 2 only be connected via a bond.

The anchor tip 3 has a cuboid base body 9 on, being the rectangular base 14 elongated in a first radial direction R ₁ . That is, the rectangular base 14 of the basic body 9 has in the first radial direction R _{1 has} a width B ₁ , which is greater than the width B ₂ in the direction of a second radial direction R ₂ , which is orthogonal to the first direction R ₁ . In the illustrated embodiment, the width B _{1 is} 50 mm and the width B ₂ 20 mm. To the main body 9 closes in Eintreibrichtung a saddle roof-shaped, wedge-like edge 10 at. This cutting edge 10 can be driven into a subsoil relatively simply beating. Due to its side surface, the cutting edge acts 10 as anti-rotation device for the ground anchor 1 , so that even in a loose ground, a nut or an item with an internal thread on the thread of the load application means 5 can be screwed on without the ground anchor 1 rotates. The anchor tip 3 is inexpensively made of fiber-reinforced plastic, for example made of glass fiber reinforced polyamide.

Between the anchor shaft 2 and the anchor tip 3 is the retaining element 4 arranged. The holding element 4 is disc-shaped as an annular disc made of polyamide, the disc plane E _S is substantially orthogonal to the longitudinal axis L _{S of} the ground anchor 1 is like this 2 shows. The diameter D _{H of} the holding element 4 is greater than the diameter D _{S of} the armature shaft 2 , whereby the retaining element 4 can generate a significant holding force in the subsurface. The diameter of the inner opening of the annular retaining element 4 but is smaller than the diameter D _{S of} the armature shaft 2 and corresponds to the diameter of the external thread 8th the anchor point 3 so that the front end of the anchor shaft 2 a first abutment 11 in the form of a circular stop shoulder for the holding element 4 forms. The side of the main body 9 the anchor point 3 , which is opposite to the driving direction, forms a second abutment 12 for the holding element 4 , While the holding element 4 on the first abutment 11 only annular in an anchor shaft 2 facing inner region of the retaining element 4 can support, so it is when driving the ground anchor 1 into the ground not from the ground anchor 1 but triggers to bend and buckle against the driving direction, is the holding element 4 on the second abutment 12 flat on. The second abutment 12 acts as a flat line bearing or as a support for the retaining elements 4 ,

The in the 5 and 6 illustrated second embodiment of the ground anchor according to the invention 1' is different from the one in the 1 to 4 illustrated ground anchor 1 exclusively by the shape of the wedge-shaped cutting edge 10 the anchor point 3 ' , which in this case has the shape of a pyramid whose base is the main body 9 forms. As the retaining element 4 at both ground anchors 1 . 1' is the same and also works the same, the following statements apply to the function of the holding element 4 also for the in the 1 to 4 illustrated ground anchor 1 ,

In the 5 and 6 is the ground anchor according to the invention 1' when installed in a sandy ground 13 shown. When driving into the underground 13 became the holding element 4 substantially uniaxial, arched around an axis extending in the direction of the first radial direction R ₁ axis. The uniaxially stretched anchor point 3 ' prevents the retaining element 4 is also arched around an axis extending in the direction of the second radial direction R ₂ axis. Due to the resistance of the underground 13 when driving the parts of the retaining element 4 in the second radial direction R ₂ over the main body 9 the anchor point 3 ' survive, elastically to the rear, so bent against the Eintreibrichtung. The disk-shaped holding element 4 arched, so that a self-consistent vault shape is formed, which together with the elongated anchor point 3 ' prevents the entire retaining element 4 flat against the anchor shaft 2 is pressed, making it no significant holding force in the ground 13 could produce. The first abutment 11 prevents when driving, that the holding element 4 from the ground anchor 1' solves, or that the retaining element 4 along the anchor shaft 2 shifts. Will now be at the ground anchor 1' pulled against the driving direction and from the ground 13 moved out so activates the umbrella-like curved holding element 4 the holding element 4 surrounding ground 13 and generates a holding force that pulls out the ground anchor 1' from the underground 13 prevented. Due to the curvature of the retaining element 4 the holding element acts 4 like a parachute or a trawl, that is, the curved retaining element 4 includes the material of the substrate lying in it 13 that does not leave the ground anchor 1' can move, which would reduce the holding force. In this case, the retaining element is supported 4 at the base 9 the anchor point 3 ' starting as the second abutment 12 acts. The curved holding element 4 generated due to its radial extent, which is greater than that of the body 9 , a significantly greater holding force than would do a ground anchor, which has no retaining element.

In the 7 and 8th Two further embodiments of the ground anchor according to the invention are shown. In order to avoid repetition, only the features that are included in the 7 and 8th illustrated ground anchor 1'' . 1''' from the in the 1 to 6 illustrated ground anchors 1 . 1' differ.

The Indian 7 illustrated ground anchor invention 1'' indicates at the front end in the direction of insertion of its anchor point 3 '' a cone-shaped center point 15 on, whose diameter decreases in the direction of insertion. The center point 15 At the beginning of the drive-in operation, a targeted attachment of the ground anchor is facilitated 1'' on the ground. In addition, the centering tip increases 15 the directional stability of the ground anchor 1'' during the drive-in process, causing the ground anchor 1'' easier to drive into a substrate with coarser components such as stones. The wedge-shaped cutting edge 10 '' the anchor point 3 '' is formed relatively short in the direction of the longitudinal axis A _E , the main body 9 '' On the other hand, it is greatly enlarged, causing the anchor tip 3 '' is much more stable. This also improves the driving into a coarse-grained ground. The anchor tip 3 '' has a second wedge-like edge 16 whose shape is that of the first cutting edge 10 '' equivalent. The second cutting edge 16 extends in the direction of the second radial direction R ₂ , which is orthogonal to the first radial direction R ₁ , so that the armature tip 3 '' the holding element 4 in two directions R ₁ , R ₂ by means of second abutment 12 supports. Between the load application 5 and the anchor tip 3 '' are at the anchor shaft 2 '' of the ground anchor 1'' four wing-like support elements 17 arranged, which in their form and alignment the cutting 10 '' . 17 the anchor point 3 '' correspond. After penetration of the support elements 17 in the underground support the support elements 17 the ground anchor 1'' against tilting about an axis perpendicular to the longitudinal axis A _E axis. Through the support elements 17 can the ground anchor 1'' record significantly larger loads, transverse to the longitudinal axis A _{E of} the ground anchor 1'' Act.

The Indian 8th illustrated ground anchor 1''' has an anchor point 3 ''' in the form of a helical coil 18 on, by means of the ground anchor 1''' can be easily screwed into the ground and unscrewed. Depending on the surface, this is when driving in the ground anchor 1''' advantageous.

The ground anchor according to the invention 1 . 1' . 1'' . 1''' is due to its training with few components inexpensive to produce, easy to install and has a large holding power especially in non-binding ground.

LIST OF REFERENCE NUMBERS

1, 1 ', 1' ', 1' ''

ground anchor

2, 2 '' '

anchor shank

3, 3 ', 3' ', 3' ''

anchor tip

4

retaining element

5

Load application means

6

drilling

7

inner thread

8th

external thread

9, 9 ''

body

10, 10 ', 10' '

wedge-shaped cutting edge

11

first abutment

12

second abutment

13

underground

14

rectangular base of the body 9

15

conical center point

16

second wedge-shaped cutting edge

17

support element

18

helical coil

D _H

Diameter of the retaining element 4

D _S

Diameter of the anchor shaft 2

A _E

Longitudinal axis of the ground anchor 1 . 1' . 1'' . 1'''

B ₁

Width of the anchor point 3 . 3 ' in the direction of R ₁

B ₂

Width of the anchor point 3 . 3 ' in the direction of R ₂

R ₁

first radial direction

R ₂

second radial direction

E _S

disk plane

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely 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.

Cited patent literature

• DE 29503115 U1 [0002]
• DE 2919173 A1 [0002, 0002]
• GB 2315285 A [0002]
• DE 20013087 U1 [0002]

Claims (15)

Ground anchor ( 1 . 1' . 1'' . 1''' ) for driving into a subsoil ( 13 ), in particular in non-cohesive soils, - with an anchor shaft ( 2 ) and - with an armature tip ( 3 . 3 ' . 3 '' . 3 ''' ), - the anchor shaft ( 2 ) a load application means ( 5 ), with which the ground anchor ( 1 . 1' . 1'' . 1''' ) is connectable to an object to be fastened, and - wherein the ground anchor ( 1 . 1' . 1'' . 1''' ) a holding element ( 4 ) for generating a holding force in the underground ( 13 ), characterized in that - the retaining element ( 4 ) has a larger diameter (D _H ) than the armature shaft ( 2 ), - that the retaining element ( 4 ) is elastically bendable, such, - that the holding element ( 4 ) when driving in the ground anchor ( 1 . 1' . 1'' . 1''' ) into the underground ( 13 ) buckles against the driving direction. Ground anchor according to claim 1, characterized in that the retaining element ( 4 ) is disc-shaped. Ground anchor according to claim 2, characterized in that the longitudinal axis (A _E) of the ground anchor ( 1 . 1 . 1'' . 1''' ) is substantially orthogonal to the disk plane (E _S ). Ground anchor according to one of claims 1 to 3, characterized in that the retaining element ( 4 ) is made of plastic. Ground anchor according to one of claims 1 to 4, characterized in that - the ground anchor ( 1 . 1' . 1'' . 1''' ) a first abutment ( 11 ) for the retaining element ( 4 ), such that - the first abutment ( 11 ) the retaining element ( 4 ) when driving into the ground ( 13 ). Ground anchor according to one of claims 1 to 5, characterized in that - the ground anchor ( 1 . 1' . 1'' . 1''' ) a second abutment ( 12 ) for the retaining element ( 4 ), in such a way that - the second abutment ( 12 ) the retaining element ( 4 ) when moving from underground ( 13 ). Ground anchor according to claim 5 or 6, characterized in that the first abutment ( 11 ) on the armature shaft ( 2 ) is arranged. Ground anchor according to one of claims 5 to 7, characterized in that the second abutment ( 12 ) at the anchor tip ( 3 . 3 ' . 3 '' . 3 ''' ) is arranged. Ground anchor according to one of claims 1 to 8, characterized in that the retaining element ( 4 ) between the armature shaft ( 2 ) and the anchor tip ( 3 . 3 ' . 3 '' . 3 ''' ) is arranged. Ground anchor according to one of claims 1 to 9, characterized in that the anchor tip ( 3 . 3 ' . 3 '' ) a wedge-like blade ( 10 . 10 ' . 10 '' ) having. Ground anchor according to one of claims 1 to 10, characterized in that the wedge-like cutting edge ( 10 . 10 ' . 10 '' ) is uniaxially stretched in a radial direction (R ₁ ). Ground anchor according to claim 11, characterized in that the wedge-like cutting edge ( 10 . 10 ' . 10 '' ) has a width (B ₁ ) of 35 mm to 80 mm, in particular of substantially 50 mm. Ground anchor according to one of claims 11 or 12, characterized in that the ground anchor ( 1'' ) a second wedge-like blade ( 16 ) which is uniaxially stretched in a second radial direction (R ₂ ). Ground anchor according to one of claims 1 to 9, characterized in that the anchor tip ( 3 ''' ) is helically formed. Ground anchor according to one of claims 1 to 14, characterized in that on the armature shaft ( 2 ''' ) a wing-like support element ( 17 ) is arranged.

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