DE29719443U1 - Anchoring element for a fence post - Google Patents

Description

The invention relates to an anchoring element for a fence post to be driven into the ground, with a foot that can be driven into the ground and a head-side receptacle for the fence post.

Such an anchoring element for a wooden fence post is already known. This anchoring element, which cannot be documented in any documents, comprises a cup-shaped holder located above the ground surface and a foot that can be driven into the ground and consists of two conical, cross-welded flat irons. When the foot is driven into the ground, the front surfaces of the conical flanks of the flat irons can, depending on the nature of the ground, hit stones or harder roots, so that the foot has to avoid the obstacle as it continues to move. This requires a change in the direction of movement. The relatively large leg surfaces of the flat irons, which are desirable so that the

Postbank Credit and Volksbank eG Commerzbank AG VAT ID No. Eat Wuppertal-Barmen Wuppertal-Barmen VAT No. (Bank code 360 100 43) 445 04-431 (Bank code 330 600 98) 301 891 024 (Bank code 330 400 01) 4 034 823 DE 121068676

Carl Froh GmbH

anchored fence post can absorb large transverse forces, but prevent such an evasive movement. Driving in such an anchoring element can therefore prove to be very laborious.

Alternatively, other known methods of fastening fence posts to the ground involve directly hammering the fence post into the ground. This is the norm, especially with metal fence posts. It is also possible to dig a hole in the ground and fill it with concrete, for example, in order to achieve a particularly strong hold.

However, this method of anchoring the fence post proves to be cumbersome and time-consuming, since the fence post cannot yet bear any load during the drying period for the cement mixture to harden.

It is therefore the object of the invention to create an anchoring element according to the preamble of claim 1, which can be driven into the ground in a simple manner.

The invention essentially solves this problem in that the anchoring element is designed as an axially elongated, essentially cylindrical body.

The principle of the invention therefore essentially consists in determining the effective cross-sectional area of the anchoring element to be driven into the ground.

Carl Froh GmbH

and at the same time minimise the resistance surface that counteracts an evasive movement or change of direction when driving in. By designing the anchoring element as an essentially cylindrical body, it is easier to evade when hitting an obstacle. This makes driving the anchoring element into the ground less laborious.

According to an advantageous embodiment, the anchoring element is designed as a substantially tubular body. This has the advantage that it is possible to use the anchoring element itself or its interior as a holder for the fence post. It is no longer necessary to provide a separately designed holder flanged to the head, as is the case with the prior art. In addition, it is now possible to use an axial area of the anchoring element corresponding to its axial length to adjust the height of the fence post. In addition, a metal fence post, for example with a small cross-section, can now also be held securely in the holder, since a comparatively long axial section of the anchoring element is available for support.

According to a further advantageous embodiment, the anchoring element comprises at least one rib arranged essentially in the axial direction and arranged like a blade, which is arranged in its base area. This is advantageous in that the rib facilitates penetration into the ground. The soil is thereby

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Reaching the full cross-section ..of the tubular body radially pushed apart.

According to a particularly advantageous embodiment, several axially extending guide ribs are arranged in the head area of the anchoring element. These have the advantage that the anchoring element can be anchored very securely in the ground. Additional holding surface is provided, which prevents the anchoring element from tipping over in the ground even when leaning against a fence post. The exclusive arrangement of guide ribs in the head area of the anchoring element has the advantage that the anchoring element can still avoid obstacles while the anchoring element is being driven in. It was recognized that an evasive movement in front of an obstacle during driving in takes place around an axis of rotation that lies approximately in the head area of the anchoring element. However, transverse surfaces arranged there, such as those assigned to the guide ribs, offer only a small resistance to an evasive movement.

If a person leans against the fence post, there is a risk that the anchoring element will tilt, which will then occur around a rotation axis that is located in the base area of the anchoring element. Holding surfaces in the head area of the anchoring element, i.e. close to the ground surface, have a much greater influence in preventing such a tipping movement than holding surfaces located in the base area.

Carl Froh GmbH

Additional advantages of the invention emerge from the further subclaims and from an embodiment shown in the drawings. In the figures:
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Fig. 1 shows a view of an anchoring element driven into the ground with a fence post accommodated in it,

Fig. 2 the anchoring element according to Fig. 1,
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Fig. 3 is a plan view of the anchoring element according to arrow III in Fig. 2,

Fig. 4 a bottom view of the anchoring element according to arrow IV in Fig. 2,

Fig. 5 a spatial representation (obliquely from above) of the anchoring element according to Fig. 2 with a clamping element inserted into the head side,
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Fig. 6 an isolated spatial representation (obliquely from above) of the clamping element according to Fig. 5,

Fig. 7 is a plan view of the clamping element according to Fig. 6,

Fig. 8 is a side view of the clamping element according to arrow VIII in Fig. 7,

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Fig. 9 a side view of an impact iron for head-side insertion into the anchoring element,

Fig. 10 a spatial representation of an anchoring element partially driven into the ground and a hammer for driving in/

Fig. 11 a spatial representation of the anchoring element driven further into the ground with respect to Fig. 10 with clamping element and fence post loosely held in it,

Fig. 12 the anchoring element according to Fig. 10 and 11, completely driven in, with the clamping element not yet fully inserted and the fence post loosely held in it, as well as with indicated auxiliary elements for completely driving in the clamping element and

Fig. 13 shows the fully driven anchoring element according to Fig. 12 with a cross brace attached to it.

The anchoring element, designated in its entirety as 10 in the drawings, serves for the permanent, secure fastening of a fence post 11 in a ground 12. It comprises a tubular body 13 with a foot 14 that can be driven into the ground 12. In order to facilitate the introduction and driving into the ground 12, several, in the embodiment four, blade-like ribs 15 are arranged in the area of the foot 14. They each comprise a blade-like edge 16 (Fig. 4) as well as on both sides of each

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Surfaces 17 arranged on the edge 16 and widening conically away from the foot area 14.

The formation of the four ribs 15 is carried out in a particularly simple manner by flattening the lower free end of the tubular body 13. This is pinched or clamped so that a stable, easily driven-in tip is formed in one operation without additional components or work steps being required.

When the anchoring element 10 is driven into the ground 12, the initial immersion of the foot 14 into the ground 12 is facilitated by the cutting edges 16 of the blade-like ribs 15. Then, as the anchoring element 10 is driven in further, the inclined surfaces 17 can continuously displace the soil radially outwards and, if necessary, compact it until the full cross-section Q of the tubular body 13 is reached. At the same time, a certain degree of anti-twisting protection is already achieved, so that the anchoring element 10, which has only been driven insignificantly into the ground 12, will generally not change its rotational position as it is driven further into the ground 12. This does not affect the ability of the anchoring element 10 to evade if the foot 14 encounters an obstacle as it is driven in.

A receptacle 19 for the fence post 11 is arranged on the head 18 of the anchoring element 10, which is opposite the foot 14. The interaction between the fence post II and the receptacle 19 will be described in detail later.

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Four guide ribs 20 are arranged on the head 18 of the anchoring element 10. Their respective circumferential position can correspond to that of the cutting-like ribs 15.
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In the embodiment, each guide rib 20 has three differently designed axial sections. A first axial section 22, close to the base 14, is conical with a conical flank 21 and can be easily driven into the ground 12 in a similar way to the cutting-edge ribs 15. In contrast to the conical surfaces 17, however, they do not cause any compaction or displacement of the ground, but merely plunge or cut into the ground 12 like a knife.

A second axial section 23 of each guide rib 20 comprises an outer edge parallel to the longitudinal axis L of the anchoring element 10 and, as the anchoring element 10 is driven further into the ground 12, it follows the axial section 22 and plunges into the cavities created by it, so that no further displacement takes place when the axial section 23 is driven in. A third axial section 24, which extends only over a short length, is again at least partially conical, with the guide rib 20 in this axial section 24 tapering partially conically towards the longitudinal axis L of the anchoring element.

In the embodiment, the guide ribs 20 are formed by separately manufactured guide plates, which are attached to the

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Head 18 of the anchoring element IO is welded on. Preferably a fillet weld is used as the weld, which may optionally consist of several spaced-apart sections.
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The anchoring element 10 comprises a pointed foot 14 and a head 18 with guide ribs 20 for directional stabilization when driving the anchoring element 10 into the ground 12. The anchoring element 10, which is completely driven into the ground 12, has a very high degree of resistance to twisting. In addition, the anchoring element 10 now also has relatively large holding surfaces assigned to the guide ribs 20, which prevent, for example, the anchoring element 10 in the ground 12 from tilting relative to the ground surface 0 when a person leans against the anchored fence post 11 or when other large forces are applied across the fence post 11. Such tilting in any direction is prevented by at least two surfaces of the guide ribs 20 when four guide ribs 20 are used, as in the exemplary embodiment. Due to the overall large area, a relatively large amount of soil volume would have to be displaced or compacted during tipping, so that tipping is largely prevented.

Fig. 5 shows an oblique view of the anchoring element 10 with a clamping element 25 inserted into the receptacle 19. The receptacle 19 is formed in a particularly simple manner in the embodiment in that the anchoring element 10 is designed as an essentially tubular

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Body 13 is formed. Thus, in the area of the head 18 of the anchoring element 10, an opening is available, namely the pipe interior, into which the fence post 11 can be inserted. Since in principle the entire pipe interior can be used _, it is now possible to securely anchor metal fence posts, even those with a small diameter.

In order to achieve a rotationally fixed and non-sliding connection between the fence post 11 and the anchoring element 10, the clamping element 25 is provided. Fig. 6 shows this in detail. It comprises a shaft 26 which can be inserted into the receiving opening 19 and a flange-like collar 27 with a larger outer diameter than the shaft 26. The underside 27a of the collar 27 rests on the annular face 28 (Fig. 3) of the tubular body 13 when the clamping element 27 is fully inserted into the receiving opening 19.

The shaft 26 of the clamping element 25 comprises a first circular-cylindrical axial section 29, a second slightly conical axial section 30 and a third circular-cylindrical axial section 31, the outer diameter of which is slightly larger than the outer diameter of the first circular-cylindrical axial section 29. The conicity of the outer circumference of the middle axial section 30 is approximately 7°, i.e. it is in the self-locking range. At least the lower circular-cylindrical axial section 29 of the shaft 26 has indentations 32 which protrude radially inwards and extend over a certain axial length.

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-listrecken. In this way, the wall of this section 29 is formed in a wave-like manner.

A slot 34 extends over the entire axial length of the clamping element 25, which leads to a certain variability of the diameter of the clamping element 25.

In order to securely fasten the fence post 11 to the anchoring element 10, the clamping body 25 is first inserted with its first circular-cylindrical axial section 29, which is remote from the collar 27, into the receptacle 19 of the tubular body 13. The indentations 32, in conjunction with the slot 34, allow a small amount of flexibility so that the axial section 29 can avoid or be guided past any obstacles that may be present inside the pipe, such as an internal weld seam of the pipe. The indentations 32 thus prevent any obstructions caused by such obstacles when inserting the clamping element 25. To do this, an indentation 32 protruding towards the inside of the clamping body 25 simply has to be brought into the same circumferential position as the obstacle. The additionally arranged slot 34 facilitates the deflection of the clamping element 25 in the area of the obstacle by radially forcing it towards the inside of the pipe.

The fence post 11 can then be inserted into the clamping element 25. For this purpose, a circumferential insertion bevel 33 is provided on the inner circumference of the collar 27. The fence post 11 can now be easily moved axially relative to the anchoring element 10 until it reaches a

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maximum position in which the lower end of the fence post reaches the area of the foot 14 and hits the constrictions formed by the ribs 15. The clamping body 25 can then be pressed completely into the receptacle 19, i.e. until the underside 27a of the collar 27 hits the annular face 28 of the tubular body 13. In order to apply the necessary forces, an auxiliary element 41, which is indicated in Fig. 12, can be used, for example. If the conical section 30 of the shaft 26 passes the inner edge of the annular face 28, the clamping element 25 is compressed radially. The resulting clamping forces act on the fence post 11 radially and thus ensure a firm connection between the fence post 11 and the anchoring element 10 in the manner of a press fit. When the last axial section 31 of the shaft 26 is driven in further, the clamping forces are further increased so that an overall large axial area clamps on the fence post 11. The use of such a clamping element 25 thus initially allows a selectable height positioning of the fence post 11 relative to the ground surface O and then a secure locking of the fence post 11 in the anchoring element 10.

In addition, tolerances can be compensated by using such a clamping element. Polyamide, for example, can be used as a material for the clamping element.

Fig. 10 shows a mushroom-shaped driving iron 35 for placing on the anchoring element 10 during the installation

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hammering it into the ground 12. It comprises an extension 36 for insertion into the receptacle 19 and a head 37 that is wider relative to the extension 36 and provides a relatively large striking surface for a hammer or similar instrument. The underside 38 of the protruding head 37 of the driving iron 35 rests on the annular face 28 of the anchoring element 10. In this way, a simple force transmission element is created that sits centrally on the anchoring element 10, absorbs the large forces to be transmitted and can be detached from the anchoring element 10 and reused after it has been hammered in. A special material can therefore be selected for the driving iron 35, which may differ from that of the anchoring element 10.

Fig. 11 shows an anchoring element 10 that has not yet been completely driven into the ground 12, with a clamping element 25 partially inserted into the receptacle 19 and a fence post 11 received therein. An indicated spirit level 40 is intended to make it clear that the inclination of the fence post 11 can be checked before the anchoring element 10 is completely driven into the ground 12. Thus, corrections are still possible in this state.

Fig. 12 shows an anchoring element 10 completely driven into the ground 12, with a clamping element 25, onto which an auxiliary element 41 is placed so that the shaft 26 of the clamping element can be driven with a hammer 39.

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tes 25 can be completely pressed into the holder 19.

An analogous use of an anchoring element 10 for a cross brace 43 of a fence is shown in Fig. 13. Here, the stump 44 of an articulated foot 45 of a cross brace 43 is clamped into the clamping element 25. Since cross braces 43 are generally intended to absorb large transverse forces, the use of the anchoring element according to the invention proves to be particularly suitable here.

Claims (29)

Carl Froh GmbH Claims 1. Anchoring element (10) for a fence post (11) for driving into the ground (12), with a foot (14) that can be driven into the ground (12) and a head-side receptacle (19) for the fence post (11), characterized in that the anchoring element (10) forms an axially elongated, substantially cylindrical body (13). 2. Anchoring element according to claim 1, characterized in that the cylindrical body is essentially a tubular body (13). 3. Anchoring element according to claim 2, characterized in that the cylindrical body (13) has a round cross-section. 4. Anchoring element according to claim 2, characterized in that the cylindrical body (13) has a polygonal cross-section. 5. Anchoring element according to one of the preceding claims, characterized in that the cylindrical body (13) carries in its foot region (14) at least one cutting-edge rib (15) running essentially in the axial direction. 6. Anchoring element according to claim 5, characterized in that the cylindrical body (13) in its Carl Froh GmbH Foot area (14) carries several ribs (15),
the longitudinal axis (L) of the cylindrical
are arranged rotationally symmetrically. concerning body (13) 7. Anchoring element according to claim 6, characterized in that four ribs (15) are provided, each offset by 90° around the circumference. 8. Anchoring element according to claim 7, characterized in that the ribs (15) extend from the longitudinal axis (L) of the cylindrical body (13) extend radially outward. 9. Anchoring element according to claim 8, characterized in that the ribs (15) are formed by flattening the foot region (14) of the cylindrical body (13). 10. Anchoring element according to claim 9, characterized in that the ribs (15) each taper radially conically at least over a region of their axial length towards the foot region (14) of the cylindrical body (13). 11. Anchoring element according to one of the preceding claims, characterized in that substantially axially extending guide ribs (20) are arranged in the head region (18) of the cylindrical body (13). 12. Anchoring element according to claim 11, characterized in that the guide ribs (20) each Carl Froh GmbH · - 17 - taper conically over at least a portion (22) of their axial length towards the base portion (14) of the cylindrical body (13). 13. Anchoring element according to claim 12, characterized in that the guide ribs (20) are arranged rotationally symmetrically with respect to the longitudinal axis (L) of the anchoring element (10). 14. Anchoring element according to claim 13, characterized in that four guide ribs (20) are provided, each offset by 90° around the circumference. 15. Anchoring element according to claim 14, characterized in that the guide ribs (20) extend radially outward from the longitudinal axis (L) of the cylindrical body (13). 16. Anchoring element according to claim 15, characterized in that the guide ribs (20) taper radially conically towards the head region (18) of the cylindrical body (13). 17. Anchoring element according to claim 16, characterized in that the guide ribs (20) are made of flat steel and are welded to the outer peripheral surface of the cylindrical body (13). 18. Anchoring element according to one of the preceding claims, characterized in that in the fully inserted Carl Froh GmbH *..**·· - 18 - In the struck state of the anchoring element (10), the head-side receptacle (19) is almost flush with the floor surface (0). 19. Anchoring element according to claim 18, characterized in that in the fully driven-in state of the anchoring element (10), the guide ribs (20) extend to just below the ground surface (0). 20. Anchoring element according to claim 19, characterized in that the cutting-like ribs (15) and the guide ribs (20) are axially spaced from one another by a rib-free region of the cylindrical body (13). 21. Anchoring element according to one of the preceding claims, characterized in that the cutting-like ribs (15) and the guide ribs (20) are each connected to one another to form continuous ribs. 22. Anchoring element according to one of the preceding claims, characterized in that it is galvanized. 23. Anchoring element according to one of the preceding claims, characterized in that the receptacle (19) for the fence post (11) is at the same time a receptacle for a driving iron (35) which is designed as a mushroom-shaped body with a projection which can be inserted into the receptacle (19). · Carl Froh GmbH * - 19 - · set (36) and a striking surface (37) for an impact hammer. 24. Anchoring element according to one of the preceding claims, characterized in that the receptacle (19) for the fence post (11) is at the same time a receptacle for a clamping element (25) for connecting a fence post (11) to the anchoring element (10), the clamping element (25) being designed as a sleeve-shaped body, with a shaft (26) that can be inserted into the receptacle (19) and a flange-like collar (27) that rests on the top side (28) of the edge of the receptacle opening (19) when the clamping element (25) is fully inserted. 25. Anchoring element according to claim 24, characterized in that the outer circumference of an axial section (30) of the shaft (26) of the clamping element (25) tapers conically away from the collar (27) of the clamping element (25). 26. Anchoring element according to claim 25, characterized in that the shaft (26) of the clamping element (25) starting from the collar (27) comprises successively a circular-cylindrical axial section (31) with a large outer diameter, a conical axial section (30) and a second circular-cylindrical axial section (29) with a smaller outer diameter. 27. Anchoring element according to claim 26, characterized in that the wall of the circular cylindrical axial Carl Froh GmbH ·..··..'.'.. .!. .. . - 20 - Section (29) of the clamping element (25) with a smaller diameter comprising radially inwardly projecting, axially extending indentations (32). 28. Anchoring element according to claim 27, characterized in that the clamping element (25) has a slot (34) extending over its entire axial length. 29. Anchoring element according to claim 28, characterized in that the collar (27) of the clamping element (25) has a circumferential insertion bevel (33) for the fence post (11) on its inner circumference.