EP0842342A1 - Anchoring device for a pole- or post-like object - Google Patents

Abstract

Described is an device designed to anchor a pole- or post-like object (4) in the ground, the device having a threaded section, which can be drilled into the ground and removed again in the same way, and a tubular section designed to hold the object (4), a device (8) designed to maintain the object (4) in the upright position in the tubular section being located in the tubular section (6). The device (8) which maintains the object in the upright position has a support element (14; 66) which is located in the tubular section (6) and which has an aperture enabling it to fit round the object (4). The support element can be moved with respect to the tubular section (6) to enable the direction of the longitudinal axis (LG) of the object (4) to be adjusted with respect to the direction of the longitudinal axis (LB) of the tubular section (6) and to remain locked in place in any position selected.

Description

 description

Fastening device for a rod or post-shaped object

The invention relates to a fastening device for a rod-shaped or post-shaped object, according to the preamble of claim 1.

When setting up bars, piles or posts, for example when erecting a fence, when setting up a sign or the like, there is always the problem of aligning the post or post exactly vertically, if possible. The vertical alignment can take place, for example, in that the vertical alignment is checked and given by means of a spirit level or a plumb line in the course of the fastening or anchoring of the rod-shaped, pile-shaped or post-shaped object in the ground, for example by ramming in or hammering in or also concreting in ¬ is corrected if necessary. This is cumbersome and time-consuming, since, for example, when a pile or post is rammed into the ground, the ramming process has to be interrupted again and again in order to check the alignments and, if necessary, to correct them Creation of the same in the case of concrete that has not yet set has no problem, but means must then be used to maintain this exactly vertical arrangement until the concrete has set so far that this vertical alignment no longer takes care of itself can adjust; the post or post must therefore be supported or braced laterally, for example.

In addition to ramming in or digging in or also concreting in a post or post, it is known to use fastening devices which can be anchored in the ground and which then carry the post-shaped or post-shaped object at their upper free end. The fastening device which can be anchored in the ground comprises, for example, a screw or screw which is screwed into the ground like a corkscrew, after which the post or post is then screwed to this fastening device or inserted into it. An example of this is described in DE-GM 93 13 258. Furthermore, it is known to form the pole-shaped or post-shaped object and the fastening device which can be corkscrew-anchored in the ground in one piece, so that the object has the fastening device at one of its free ends, which is then screwed into the ground and anchored therein .

With these two methods or these possibilities for erecting a pile or post there are essentially the same problems with regard to the vertical arrangement of the pile or post as when driving in or concreting them in. Instead of the driving-in process, the screwing of the fastening device into the ground must be interrupted again and again in order to ensure the later vertical alignment of the pile or post by means of appropriate measurement and, if necessary, correction processes. In the past, therefore, adjustment or adjustment mechanisms have already been arranged on the fastening devices in order to make the position of the object adjustable relative to the fastening device. For example, DE-GM 88 09 142 shows the possibility of vertical adjustment of a post relative to a base plate by means of a ball joint. The US-PS 4,199,908 enables the alignment of a post or pile in the vertical direction due to slot-shaped recesses in a support part.

DE-GM 88 09 142, however, has the essential structural disadvantage that when tightening the spherical shell surrounding the spherical head, hardened projections formed there should dig into the material of the spherical head in order to additionally secure the position of the post by means of a positive fit . In practice, this means that with a changing installation position of the holder, which requires a different position of the ball head relative to the holder, the ball head may no longer be able to be held securely in the new position due to the ball head possibly deformed by the projections and needs to be replaced.

The adjustment device according to US Pat. No. 4,199,908 only allows adjustment in one plane. In addition, it is structurally disadvantageous in that, in order to function correctly, the floor bracket there must be anchored in the concrete foundation at such a depth that the hole there is aligned with the elongated hole of the support part, since otherwise the screw these two holes, in which the Adjustment takes place in one direction, can no longer enforce. From the generic DE-GM 93 13 260 of the same applicant, various embodiments of fastening devices for rod-shaped or post-shaped objects in the ground have become known, which have a threaded section which can be screwed into and out of the ground and a tubular holding section for receiving the Have an object, a device for aligning the object with respect to the holding section being arranged on the holding section, so that the article can be vertically aligned even when the threaded section is not screwed in exactly vertically or vertically.

Although essentially all of the fastening devices described in DE-GM 93 13 260 have proven their worth in practice, the lack of detail is still due to them that the once selected position of the rod-shaped or post-shaped object relative to the fastening device is only greater in terms of time and manipulation Effort can be changed again. So z. B. several clamping screws are loosened and / or other, thicker or thinner underlay profiles must be used to change the relative position of the object to the fastening device. If there is now a need to move the individual fence posts back into the vertical position, for example in the case of a fence that has been pushed into an oblique position by external forces, dozens of individuals may have to be used for the fastening devices according to DE-GM 93 13 260 Fastening devices are time-consuming readjusted, which is unsatisfactory in practice. In contrast, the present invention has set itself the task of designing a fastening device according to the preamble of claim 1 so that with it a rod or post-shaped object can be quickly and exactly brought into the vertical position, this vertical position or orientation if necessary can be adjusted just as quickly.

This object is achieved according to the invention by the features specified in claim 1.

Accordingly, according to the invention, a fastening device for a rod-shaped or post-shaped object is created in the ground, with a threaded section which can be screwed into and out of the ground and with a tubular holding section for receiving the object, with a holding section on the holding section Device for aligning the object is arranged opposite the holding section, the fastening device being characterized in that the device for aligning has a receiving part on the holding section with a receiving opening for the peripheral storage of the article, which is opposite the holding section is movable in such a way that the longitudinal central axis of the object is adjustable relative to the longitudinal central axis of the holding section and is self-holding in any selected position.

The fastening device according to the invention allows on the one hand a quick and exact alignment of the rod-shaped or post-shaped object with respect to the holding section in such a way that the object is exactly vertical or vertical, but on the other hand the possibility is additionally created by the mobility of the receiving part relative to the holding section. If necessary, the object can be readjusted relative to the holding section, so that when the fastening device is displaced in the ground, for example by forces acting from outside, this displacement causing the rod-shaped or post-shaped object to tilt, this object is opposite the fastening device can be adjusted to return to its original vertical position.

The fact that the object is self-holding relative to the holding section in every set position means that additional fastening or fixing means are not necessary, so that the loosening of such fastening or fixing means is unnecessary in the case of readjustment or readjustment processes.

Advantageous developments of the invention are the subject of the dependent claims.

The receiving opening in the receiving part is preferably eccentrically adjustable in one direction with respect to the longitudinal central axis of the holding section. If, according to a further preferred embodiment, the receiving part can still be rotated relative to the holding section, there is the possibility with a simple construction to adjust the longitudinal central axis of the rod-shaped or post-shaped object relative to the longitudinal central axis of the holding section on all sides. the longitudinal central axis of the rod-shaped or post-shaped object lying on the outer lateral surface of a circular cone, the central axis of which is the longitudinal central axis of the holding section. According to a preferred embodiment, the receiving part is formed in two parts, namely with an annular outer part which can be arranged on the holding section and which defines a bearing opening and an annular inner part which is rotatably arranged in the bearing opening of the outer part and which defines the receiving opening for the object. In order to make it possible to adjust the rod-shaped or post-shaped object, the center of the receiving opening is offset eccentrically to the center of the inner part and the center of the bearing opening is centered on the center of the outer part. This embodiment of the present invention has a simple and at the same time robust and reliable structure and allows all-round adjustment of the longitudinal central axis of the rod-shaped or post-shaped object relative to the longitudinal central axis of the holding section.

The outer part and the inner part preferably have points of attack for a tool with which the outer part can be rotated relative to the receiving section and the inner part relative to the outer part.

Both the outer part and the inner part preferably each have an axially and radially continuous slot in the region of their thinnest wall thicknesses. This makes it possible to manufacture the outer part with respect to the holding section and the inner part with respect to the bearing opening of the outer part with a slight oversize, so that the outer part in the holding section and also the inner part in the bearing opening of the outer part are light clamped, and thus the self-holding of the outer part and the inner part with respect to one another or with respect to the holding section takes place solely by frictional engagement without any additional means. Any tolerance Fluctuations in production are thereby almost completely absorbed. Furthermore, the receiving opening for clamping the object in relation to the diameter of the object is particularly preferably made with undersize. As a result and through the slot in the inner part, the inner part is slightly widened or spread when pushed onto the object, so that it sits clamped on the object and cannot slip or get lost. Furthermore, when the somewhat expanded inner part is pressed into the bearing opening of the outer part, the inner part is compressed or tensioned so that it fits tightly against the object or clamps it securely, and the inner part is also securely held in the bearing opening of the outer part .

The inner part, as well as the bearing opening and the receiving opening preferably each have a wall profile that is inclined to the respective longitudinal central axis. The seat of the outer part in the holding section and the seat of the inner part in the bearing opening of the outer part are hereby ensured solely by the influence of gravity. Furthermore, the object is simply and reliably compressed or clamped in the receiving opening and the inner part in the bearing opening of the outer part when the inner part and outer part move relative to one another along the conical surfaces.

If the inner part has a circumferential strip-shaped projection on the inner circumferential wall of the receiving opening, the rod-shaped or post-shaped object is better supported since it can rest against a defined line or edge. In a further preferred embodiment, the longitudinal axis of the inner part can be that of the

Outer part by rotating the inner part relative to

Outer part can be tilted. This allows larger adjustment angles to be achieved.

According to a further embodiment of the present invention, the receiving opening can be formed centrally in a plate-shaped receiving part which can be displaced and fixed in an essentially horizontal plane at the upper free edge of the holding section. This also makes it possible to adjust the longitudinal central axis of the object with respect to the longitudinal central axis of the holding section and thus to carry out an adjustment of the object with respect to the fastening device. In this case, the plate-shaped receiving part can be fixed to a radial flange of the holding section by means of through-bolts which can be screwed into threaded sections on the flange and pass through the plate-shaped receiving part in oversized bores. Due to the oversized holes, the plate-shaped receiving part can be displaced horizontally relative to the holding section, and the plate-shaped receiving part can be fixed to the holding section with high holding forces by the through screws, so that rod-shaped or post-shaped objects can be held in this embodiment of the invention which are exposed to particularly high loading forces due to their own weight or due to certain external influences.

The receiving opening is preferably essentially circular with a plurality of radially extending from its peripheral wall to the material of the plate-shaped receiving means. partially extending slots. The circumference of the receiving opening is hereby formed by a plurality of resiliently deformable tongues, so that the rod-shaped or post-shaped object can be held particularly securely.

The tubular holding section tapers preferably conically downwards on a longitudinal section facing away from the receiving part, at least in the inner cross section. This conically tapering length section represents the lower support point for the rod-shaped or post-shaped object and since this length section tapers conically, it automatically adapts to different diameters of the object without special fastening means being necessary for this.

Further details, aspects and advantages of the present invention result from the following description of embodiments with reference to the drawing.

It shows:

1A shows a plan view of an annular inner part according to an embodiment of the present invention;

IB shows a section through the inner part of FIG. 1A along the line B-B there;

2A shows a plan view of an annular outer part according to an embodiment of the present invention, FIG. 2B shows a section through the outer part from FIG. 2A along the line BB there;

3 shows a plan view of the outer part and inner part in the assembled state, the receiving opening formed in the inner part being shown in a maximum eccentricity position;

FIG. 4 shows a representation corresponding to FIG. 3, but the receiving opening of the inner part is arranged essentially in the center;

5A and 5B show an embodiment of the present invention, in which the longitudinal axis of the inner part can be tilted from the vertical by rotating the inner part relative to the outer part;

6A, 6B and 6C are views of how the degree of eccentricity and the direction for exactly vertical alignment can be determined using an auxiliary instrument, which is also the subject of the present invention, and can be adjusted on the inner and outer part;

7 shows a longitudinal sectional view through an embodiment of a fastening device according to the invention, which uses the outer part and the inner part according to FIGS. 1A to 4;

8 shows a view corresponding to FIG. 7 of a further embodiment of the present invention;

9 shows a plan view of a plate-shaped receiving part in the embodiment of FIG. 8; and FIG. 10 shows a representation corresponding to FIG. 7 of a modification of the present invention.

A first embodiment of the present invention will be explained in more detail below with reference to FIGS. 1A to 4 and 7.

A fastening device for a rod-shaped or post-shaped object 4, designated overall by 2 in FIG. 7, essentially has a tubular holding section 6 for receiving the object 4, and a device 8 for aligning the object 4 with respect to the holding section 6. At the lower end of the holding section 6 in FIG. 7, a non-visible threaded section is formed, with which the fastening device 2 can be screwed into and out of the ground. With regard to further details of the threaded section, reference is made to DE-GM 93 13 258 by the same applicant, to which reference is hereby made in full.

The holding section 6 has an upper area 10 with an essentially constant cylindrical cross section, and an area 12 adjoining it in FIG. 7 below, which tapers conically in the direction of the threaded section, not shown. The device 8 for aligning the object 4 is arranged at the upper open end of the holding section or its region 10.

According to FIGS. 1A to 4, this device 8 is formed by a receiving part 14, which is designed in two parts or in two parts with an annular outer part 16 (FIGS. 2A and 2B) that can be arranged on the holding section 6 and an annular inner part 18 (FIGS. 1A and 1B), the outer part 16 according to FIG. 7 being insertable into the open end of the holding section 6 from above and being supported here with an annular flange or a shoulder 20 on the upper edge of the holding section 6. The outer part 16 defines a bearing opening 22 in which the inner part 18 can be rotatably inserted, as can be seen from FIGS. 3 to 5. The inner part 18 in turn defines a receiving opening 24 which, according to FIG. 7, serves to receive the object 4.

As FIGS. 1A, 2A, 3 and 4 show, the outer part 16 and the inner part 18 are not designed to be closed in a circular manner, but rather each have an axially and radially continuous slot 26 and 28, respectively. Furthermore, according to FIGS. 1A and 2A, the center points of bearing opening 22 and receiving opening 24 are not aligned with the center points of the outer circumferences of outer part 16 and inner part 18, but are shifted by a certain eccentricity amount E for this purpose. The outer part 16 and the inner part 18 are thus sickle-shaped or moon-shaped in a plan view according to FIGS. 2A and 1A, the slots 26 and 28 being in the region of the thinnest wall thicknesses.

The outer diameter of the inner part 18 is the same, but may also be somewhat larger than the inner diameter of the bearing opening 22 and the outer diameter of the outer part 16 is also the same, possibly somewhat larger than the inner diameter of the upper region 10 of the holding section 6 through the formation of the slots 26 and 28, the outer part 16 in the region 10 and the inner part 18 of the bearing opening 22 are held under pressure and slightly frictionally, so that a rotation of the outer partly 16 relative to the holding section 6 and a rotation of the inner part 18 relative to the outer part 16 is accordingly difficult. In addition, the inner part 18 according to FIG. 1B is on its outer surface 30 and the outer part 16 is slightly conical on an inner surface 32 of the bearing opening 22, so that the inner part 18 is securely held in the bearing opening 22 and in the 7 can not fall down into the interior of the holding section 6.

As already mentioned, the diameter ratios of the bearing opening 22 to the inner part 18 are not absolutely critical. This is reinforced by the conical design of the inner part 18 on its outer surface 30 and of the outer part 16 on its inner surface 32 of the bearing opening 22. Tolerance fluctuations can be compensated for by a more or less deep insertion of the inner part 18 into the bearing opening 22, without the secure seating of the inner part 18 in the bearing opening 22 suffering. The slots 26 and 28 or in particular the slot 26 in the inner part 18 also result in the solution which is particularly preferred in the context of the invention that the receiving opening 24 for clamping the object 4 is made with an undersize in relation to the diameter of the object 4 . As a result, and through the slot 26 in the inner part 18, the inner part 18 is slightly expanded or spread when pushed onto the object 4, so that it sits clamped on the object 4 and cannot slip or get lost. Furthermore, when the somewhat widened inner part 18 is pressed sufficiently deeply into the bearing opening 22 of the outer part 16, the inner part 18 is compressed or tensioned so that it fits tightly on the circumference of the object 4 or securely inserts it. spans and also a secure mounting of the inner part 18 in the bearing opening 22 of the outer part 16 takes place.

A circumferential strip-shaped projection 36 is formed on an inner surface 34 of the receiving opening 24.

The outer part 16 and the inner part 18 have points of attack 38 in the form of through holes or blind bores on their upper side, which serve as points of attack for a tool with which the outer part 16 faces the receiving part 14 and the inner part 18 faces the outer part 16 are rotatable. One possibility of designing the points of attack 38 and one possibility of a suitable tool is to use a known tool which is used for clamping and unclamping the discs of a cut-off machine.

As already mentioned, the dimensioning of the inner part and outer part makes the rotation of the outer part 16 relative to the holding section 6 and the rotation of the inner part 18 relative to the outer part 16 difficult when the inner part 18 with simultaneous circumferential clamping of the object 4 is sufficiently deep Bearing opening 22 of the outer part 16 is pushed or pressed, since the receptacle opening 24, which is preferably made with an undersize in relation to the diameter of the object 4, develops force components acting radially outward when the object is clamped, which force the outer part 16 with respect to the holding section 6 and the inner part 18 with respect to it brace the outer part 16 and the object 4 with respect to the inner part 18. Under certain circumstances, it may be desirable to make this twisting possibility even more difficult or to block it completely. This can if necessary, a clamping device can be provided, which for example consists of a bore, the bore penetrating the wall of the holding section and ending on the outer circumference of the outer part. The bore is provided with an internal thread so that an Allen or grub screw can be screwed into the bore. By tightening the screw, the outer part can thus be non-rotatably braced relative to the holding section or the smooth movement of the rotary movement between the outer part and the holding section can be set as desired. Such clamping devices working with clamping screws are generally known; therefore, it is not shown in the drawing. It should also be noted that such an additional clamping device is generally not necessary or is only necessary in extreme cases, since the outer part 16 with respect to the holding section 6, the inner part 18 with respect to the outer part 16 and the object 4 with respect to the inner part 18 due to the Cone surfaces 30 and 32 and the receiving opening 24, which is preferably made with an undersize in relation to the object 4, are braced on the circumference with sufficient radially acting forces.

As can best be seen from FIGS. 3 and 4, depending on the relative position of the inner part 18 to the outer part 16, there is a different position of the receiving opening 24, because due to the eccentricity E of the bearing opening 22 and receiving opening 24 when the inner part 18 is rotated to the outer part 16, the receiving opening 24 undergoes a more or less strong displacement in the direction of the outer circumference of the receiving part 14, so that the longitudinal central axis LG of the object 4 is displaced by a certain amount from the longitudinal central axis LB of the fastening device 2 or of the holding section 6. can be pushed, as best shown in FIG. 7. The object 4, which is supported by its lower free end in the conical region 12, can thereby be rotated in any desired direction by turning the inner part 18 relative to the outer part 16 and, if appropriate, the outer part 16 relative to the holding section 6 an amount determined by the eccentricity E of the inner part 18 and outer part 16 can be tilted so that any skewing of the holding section 6 can be compensated for again, and so the object 4 is exactly vertical or vertical. The object 4 is supported on the circumferential projection 36 in the receiving opening 24, as can be seen in FIG. 7, so that the object is held securely in the receiving opening 24 on the one hand and at its lower end in the conical region 12 on the other hand is kept tilt and wobble-free.

When setting the direction and amount of eccentricity, the outer part 16 specifies the direction of eccentricity, i. H. the direction in which the object to be clamped has to be tilted in order to compensate for an inclined or inclined position of the fastening device screwed into the ground and the inner part 18 gives the amount of eccentricity, i. H. the degree of tilt.

Since the rotation from the inner part 18 to the outer part 16 and possibly from the outer part 16 to the holding section 6 is stiff, since the outer part 16, which is preferably made of plastic, is pressed into the holding section 6 while again compressing the gap 28 which is initially somewhat widened or spread by the object 4 and preferably also from art fabric-made inner part 18 - optionally with compression of the gap 26 - pressed into the bearing opening 22, usually remains between the inner part 18 and outer part 16 and between the outer part 16 and the holding section 6 by means of the points of attack 38 and thus also the relative position the position of the object 4. In the event of greater expected loads acting on the object 4, for example permanent vibrations from passing vehicles, strong wind forces or the like, the aforementioned clamping device can also be provided, with which the relative positions of at least the outer part 16 and the holding section 6 can be partially or completely blocked to each other. The holding forces of the inner part 18 with respect to the outer part 16 and the clamping of the object 4 in the receiving opening 24 can be increased as required by pressing the inner part 18 further into the bearing opening. Due to the conicity of the surfaces 30 and 32 and due to the gap 26 in the inner part 18, the inner part is pressed ever more radially together, so that its mounting relative to the outer part 16, its mounting or clamping relative to the holding section 6 and the mounting voltage of the object 4 can be improved or reinforced. The inner part 18 can be pressed further down by a tool, for example a hammer or the like, or an additional clamping sleeve 48 is used according to FIG. 10.

In FIG. 10, the same reference numerals as in FIG. 7 denote the same or corresponding parts, and the description will not be repeated.

10, the clamping sleeve 48 is placed over the upper free edge of the holding section 6. The school- ter 20 of the outer part 16 is formed in this modification or embodiment according to the taper of the bearing opening 22 in the outer part 16, ie the center of the circular circumferential shoulder 20 coincides with the center of the bearing opening 22 in the outer part 16, so that the shoulder 20 in the 10 on the left side protrudes beyond the free edge of the holding section 6 as on the right side. An inwardly projecting section 50 is formed on the sleeve 48, which engages behind the shoulder 20 of the outer part 16 from below in the manner shown in FIG. 10 and bears against the outer peripheral wall of the holding section 6. The section 50, like the shoulder 20, is not uniformly thick over its circumferential extent, but also has a constantly increasing or decreasing thickness that matches the eccentricity of the bearing opening 22, so that the section 50 in FIG. 10 is correspondingly thicker on the left side and correspondingly thinner on the right side, but is nevertheless always supported on the underside of the shoulder 20. The clamping sleeve 48 has a central opening 52 through which the object 4 passes. Below the opening 52 there is a further sleeve 54 which consists of a short vertical section 56 and a circumferential collar 58 which is perpendicular thereto. The object 4 also passes through the opening in the sleeve 54 defined by the section 56 in the manner shown in FIG. 10. The lower free vertical sections 56 rest on the top of the inner part 18.

To the object 4 after alignment by means of the inner part 18 and the outer part 16 on the To be able to determine holding section 6, the procedure is as follows:

Before the object 4 is inserted into the holding section 6, the clamping sleeve 48 and then the sleeve 54 are first pushed onto the object 4 from the lower free end thereof. Subsequently, the object 4 is aligned with the aid of the inner part 18 and outer part 16 with respect to the holding section 6, which can optionally be done with the aid of an appropriate tool and the bores 38. Then the sleeve 54 is allowed to slide downward along the object 4 and lie on the top of the inner part 18 and then the clamping sleeve 48 is snapped behind or under the shoulder 20. By stepping vigorously on the top of the clamping sleeve 48, the latter is moved downward and thereby presses the sleeve 54 via the collar 58 and thus via the section 56 the inner part 18 further down into the outer part 16, this being caused by the conical Surfaces 30 and 32, and is radially compressed by the slot 26 and clamps the object 4 on the one hand and itself in the bearing opening 22 of the outer part 16. By providing the clamping sleeve 48, the inner part 18 can thus be pressed quickly and cleanly into the outer part 16 without any tools in order to fix the previously set inclined position of the object 4 with respect to the longitudinal axis LB of the fastening device 2.

In a further embodiment, which is not shown in the drawing but is also preferred, the clamping sleeve 48 can also be a union nut which is connected to an external thread at the upper edge of the holding section 6 is engaged and, when screwed onto this external thread - with or without intermediate connection of an additional device corresponding to the sleeve 54 - presses the inner part 18 correspondingly deep into the outer part 16. The outer part 16, the shoulder and the projection 50 are then formed in one piece and the union nut is in engagement with the external thread, which is formed on the projection 50 radially on the outside. This embodiment has the essential advantage that, due to the tightened union nut, a permanent pressure is exerted on the inner part 18, so that the hold of the object 4 in the receiving opening 24 is particularly resistant to vibration and vibration.

If, for whatever reason, the precisely vertical orientation of the object 4 once set has changed over time, it is sufficient to place a tool at the corresponding points of attack 38 and the relative positions of the inner part 18, outer part 16 and holding section 6 to each other until the changing eccentricity of the receiving opening 24 relative to the holding section 6 brings the object 4 held therein back into the vertical. This can be done quickly and easily without the need for major manipulations.

FIGS. 5A and 5B show a modification of the present invention in which, compared to the embodiment according to FIGS. 1A to 4, larger angles of tilt of the object 4 with respect to the holding section 6 are possible. FIGS. 5A and 5B also show the possibility of not providing the holding section 6 on a floor plug or the like to be screwed into the ground, but on one cup-shaped or cup-shaped base support 60 with a circumferential peripheral wall 64 tapering conically towards a base plate 62. The base plate 62 can, for example, be firmly screwed to a base or concreted into it or otherwise fastened, or else it allows the holding section 6 to be set up freely anywhere. In the embodiment shown in FIGS. 5A and 5B, the bearing opening 22 is introduced in the outer part 16 at an angle to the vertical and the outer surface 30 of the inner part 18 has an oblique course corresponding to it in such a way that in the position according to FIG. where the two slots 26 and 28 of the inner part 18 and outer part 16 lie opposite one another (analogously to the illustration in FIG. 4), the longitudinal axis of the inner part 18 is aligned with the longitudinal axis of the holding section, that is to say it is exactly vertical in the ideal case. When the inner part 18 is rotated with respect to the outer part 16, due to the oblique course of the inner surface 32 of the outer part 16 defining the bearing opening 22, the inner part 18 is tilted with respect to the outer part 16 and thus with respect to the holding section 6 as shown in FIG. 5B. 5B shows the maximum tilting state, where the two slots 26 and 28 are aligned with one another (analogously to the illustration according to FIG. 3), where the greatest eccentricity or tilting of the inner part 18 relative to the outer part 16 is present.

Compared to the embodiment according to FIGS. 1A to 4 and 7 or 10, in this embodiment according to FIGS. 5A and 5B a much greater tilt or inclination of the object 4 held in the receiving opening 24 can be achieved. It goes without saying that combinations of the previously described embodiments with one another are also possible. In particular, the eccentric arrangement of the bearing and receiving opening according to FIGS. 1 to 4 can be combined with an inclined position of these openings according to FIGS. 5A and 5B. The arrangement of the conical surfaces 30 and 32 can also be chosen differently; for example, the outer peripheral surface of the outer part 16 and the inner peripheral surface of the holding section 6 can be tapered

FIGS. 8 and 9 show a second embodiment of the present invention. The same or corresponding components and elements as in the previously described embodiments are again provided with the same reference numerals.

The embodiment according to FIGS. 8 and 9 again essentially comprises the holding section 6 with the cylindrical area 10 and the conically tapering area 12, at the lower end of which a threaded section not visible in FIG. 8 is connected. The object 4 is held in the holding section 6 by the receiving part 14, this receiving part 14 in the second embodiment being a plate 66 which, for example, is circular according to FIG. 9 and has the receiving opening 24 in the center. The plate 66 is fastened to the holding section 6 by means of a radial flange 68 which runs around the upper free edge of the holding section 6 and on which the plate 66 rests. 9, the plate 66 has a plurality of bores 70 which are equidistant from the center of the receiving opening 24 and which serve to receive screws 72 which, according to FIG. 8, are interposed from the top of the plate 66 of washers 74 penetrate the bores 70 and are screwed into the material of the flange 68. In this case, a threaded bushing can optionally be placed on the underside of the flange 68 in order to provide a sufficient thread length for the screws 72.

As can best be seen from FIG. 8, the bores 70 have a certain excess in relation to the outside diameter of the screws 72, so that when the screws 72 are not tightened, the plate 66 can be displaced by a certain amount in an essentially horizontal plane. so that the center of the receiving opening 24 can be adjusted eccentrically about the longitudinal central axis LB of the fastening device 2, and so the object 4 held in the receiving opening 24 can also be adjusted eccentrically about the longitudinal central axis LB of the fastening device 2 with its longitudinal central axis LG. The lower free end of the object 4 is supported, as in the embodiment approximately in accordance with FIG. 7, lying freely in the lower conical region 12 of the holding section 6. With correspondingly tightened screws, the movement of the plate 66 relative to the holding section is correspondingly stiff or completely blocked, so that the positions of the plate 66 are self-holding. If necessary, a ring with a material which increases the friction can be inserted between the plate 66 and the flange 68.

According to FIG. 9, a plurality of radially outwardly extending slots 76 can extend from the essentially circular receiving opening 24 and are rounded at their ends facing away from the receiving opening 24 in order to avoid cracking. The material of the plate 66 is in the area through these slots 76 the receiving opening 24 resilient / resilient, so that with appropriate deformation of the tongues formed between the individual slots 60 the object 4 can be held more or less clampingly in the receiving opening 24. This clamping bracket is reinforced by the fact that the plate 66 according to FIG. 8 is slightly convex; when the object 4 is inserted into the receiving opening 24, when the screws 72 are tightened, the plate 66 is deformed in the horizontal direction, which is accompanied by a reduction in the diameter of the receiving opening 24 and simultaneous springing open of the tongues between the slots 76, so that the object 4 is securely clamped on the circumference and is also pulled downward in the direction of the conically tapering region 12.

As in the first embodiment, the eccentricity of the longitudinal central axis LG of the object 4, once selected, can be increased or decreased as compared to that of the fastening device 2 after loosening the screws 72 and correspondingly displacing the plate 66 within the adjustment path of the plate 66 and / or be moved in other directions in order to be able to realign object 4 vertically if necessary. The only steps that are necessary for this are loosening and later tightening the screws 72.

FIGS. 6A to 6C show a further embodiment of the present invention, or an auxiliary instrument 78, with which the degree and direction of eccentricity for precisely vertical alignment of the object can be determined and adjusted on the inner part 18 and the outer part 16. According to FIG. 6A, the auxiliary instrument 78 has for this purpose a short vertical socket 80 and a shoulder 82 adjoining it above. The outer diameter of the socket 80 corresponds to the inner diameter of the upper free edge of the holding section 6, so that the auxiliary instrument 78 can be supported on the upper free edge of the holding section 6 in a manner similar to the outer part 16. The shoulder 82 is part of a closed surface on which a dragonfly 84, which is designed in a known manner, is arranged. An air bubble 86 floats in the dragonfly 84 in a known manner. As can best be seen from the top view of the auxiliary instrument 78 according to FIG. 6B, a quarter circle sector is provided on the shoulder 82 with a first scale 88, which in the illustrated embodiment of FIG 0 to 7 may be divided. Furthermore, the top of the sight glass of the level 84 is provided with a plurality of concentric rings which form a second scale 90, which may also be divided from 0 to 7 radially outwards from the center of the level 84 to the peripheral edge of the shoulder 82 .

6B, the air bubble 86 is located exactly in the center of the concentric in the plan view according to FIG. 6B

Circles that form the second scale 90, the entire arrangement is in an exactly vertical

Alignment (spirit level principle).

FIGS. 6B and 6C now illustrate how an oblique position determined by the level 84 or second scale 90, for example of the holding section 6, can be compensated for by the alignment device 8. For such compensation, it is necessary to determine both the direction of eccentricity and the eccentricity. knowing degree of tricity. The direction of the skew is compensated by a corresponding rotation of the outer part 16 and the degree of compensation is carried out by a corresponding rotation of the inner part 18.

It is assumed according to FIG. 6B that the holding section 6 screwed into the ground "hangs" to the bottom left in the top view according to FIG. 6B, so that the air bubble 86 of the dragonfly 84 in the exemplary embodiment shown in FIG May be shifted out of the center and come to rest on the ring of the second scale 90, which is assigned to the number 5.

The level 84 is now rotated until the air bubble 86 - as shown in FIG. 6B - comes to lie on a marking line 87 which runs radially outwards from the zero or center point to the number 7 on the first scale 88. The number 5 read from the second scale 90 is now searched for on the first scale 88 and the position of this number 5 on the first scale 88 is marked by an object next to the holding section 6, for example by a stone 92. Then the auxiliary instrument 78 is removed from the upper free edge of the holding section 6 and instead of this the outer part 16 is inserted such that the slot 28 of the outer part 16 points in the direction of the stone 92. On the semicircular sector of the outer part 16 diametrically opposite the slot 28 there is a third scale 94, which - analogously to the first and second scale - also extends from 0 to 7. The inner part 18 is now inserted into the bearing opening 22 of the outer part 16 such that a marking 96 on the top of the inner part 18 with the Number 5 of the third scale 94 on the outer part 16 comes to cover. As a result, the slot 26 of the inner part 18 is rotated relative to the slot 28 of the outer part 16 by a certain angular amount, so that the receiving opening 24 of the inner part 18 also assumes a certain eccentricity in the direction and amount towards the center. This eccentricity is now exactly the direction and amount that compensates for the original skew of the holding section 6, so that the object 4 is exactly vertical.

It is thus possible according to FIGS. 6A to 6C to set the exact vertical alignment of the object 4 with little effort during the clamping of the object 4 solely with the aid of the auxiliary instrument 78, or else to adjust it subsequently using the previously determined values Set uses of the tool which is inserted into the bores 38 of the outer part 16 and inner part 18.

Claims

Expectations

1. Fastening device for a rod-shaped or post-shaped object (4) in the ground, with a threaded section which can be screwed into and out of the ground and with a tubular holding section (6) for receiving the object (4), wherein a device (8) for aligning the object (4) with respect to the holding section (6) is arranged on the holding section (6),

characterized in that

the device (8) for aligning has a receiving part (14; 66) on the holding section (6) with a receiving opening (24) for peripheral storage of the object (4), which is opposite the holding section (6) in this way It is movable that the longitudinal center axis (LG) of the object (4) is adjustable relative to the longitudinal center axis (LB) of the holding section (6) and is self-retaining in any selected position.

2. Fastening device according to claim 1, characterized in that the receiving opening (24) in the receiving part (14) with respect to the longitudinal central axis (LB) of the holding section (6) is eccentrically adjustable in one direction.

3. Fastening device according to claim 1 or 2, characterized in that the receiving part (14) can be rotated relative to the holding section (6).

4. Fastening device according to claim 3, characterized in that the receiving part (14) can be fixed in a rotationally fixed manner in relation to the holding section (6) in each rotational position.

5. Fastening device according to one of claims 1 to 4, characterized in that the receiving part (14) is constructed in two pieces with an annular outer part (16) which can be arranged on the holding section (6) and which defines a bearing opening (22) and an annular inner part (18) which is rotatably arranged in the bearing opening (22) of the outer part (16) and which defines the receiving opening (24) for the object (4), the center of the receiving opening (24) being the center of the inner part (18) and the center of the bearing opening (22) is offset eccentrically from the center of the outer part (16).

6. Fastening device according to claim 5, characterized in that the outer part (16) and the inner part (18) have points of attack (38) for a tool with which the outer part (16) relative to the holding section (6) and the inner part (18) is rotatable relative to the outer part (16).

7. Fastening device according to claim 5 or 6, characterized in that the outer part (16) and the

The inner part (18) has an axially and radially continuous slot (26, 28) in the area of its thinnest wall thicknesses.

8. Fastening device according to one of Ansprü¬ che 5 to 7, characterized in that the inner part (18) and the bearing opening (22) and receiving opening (24) each have an inclined wall profile to the respective longitudinal central axis.

9. Fastening device according to one of claims 5 to 8, characterized in that the inner part (18) on the inner peripheral wall (34) of the receiving opening (24) has a circumferential strip-shaped projection (36).

10. Fastening device according to one of Ansprü¬ che 5 to 9, characterized in that the outer part (16) and the inner part (18) are made of plastic.

11. Fastening device according to one of claims 5 to 10, characterized in that the longitudinal axis of the inner part (18) can be tilted relative to the outer part by rotating the inner part (16) by rotating the inner part.

12. Fastening device according to claim 1 or 2, characterized in that the receiving opening (24) is formed in the center in a piatten-shaped receiving part (66) which on the upper free edge of the holding section (6) shifts in a substantially horizontal plane - and is definable.

13. Fastening device according to claim 12, characterized in that the plate-shaped receiving part (66) on a radial flange (68) of the holding section (6) can be fixed by means of through-bolts (72) which are in threaded sections on the flange ( 68) can be screwed in and the plate-shaped receiving part (66) pass through excessively in bores (70).

14. Fastening device according to claim 12 or 13, characterized in that the receiving opening (24) is essentially circular with a plurality of slots (76) extending radially from its peripheral wall into the material of the plate-shaped receiving part (66).

15. A fixing device according to any one of Ansprü¬ che 1 to 14, characterized in that the rohrfor¬-shaped holding portion (6) located at a _¬ of the receiving part of the length portion facing away cross-section tapers conically downward at least in the inside.