EP4357533A1 - Clamping plate with anchoring rods - Google Patents

Abstract

Tension plate (1) for introducing tensile forces into the subsoil (2) by means of threaded rods (39), with a base plate (3) anchored to the ground, which has a number of threads (20) distributed over the surface with different inclinations (30-35) through which the threaded rods (39) can be screwed, wherein the base plate (3) consists of a bending profile which is bent several times parallel to its longitudinal extension and which is bent upwards at an angle from the surface of the base plate (3).

Description

The subject matter of the invention is a guy plate for introducing primarily tensile forces, but also compressive forces, into the subsoil according to the preamble of the patent claim.

For example, the end of tension struts, which can be used to anchor masts, antennas, guy ropes and the like, but also inclined supports or masts, are attached to such a guy plate.

The anchor plate essentially consists of a base plate that is placed on the subsurface (e.g. soil, rock, ice, etc.) and of threaded rods that are driven through the base plate and screwed through the corresponding threaded holes in the base plate in different directions and angles in order to be anchored in the soil or rock in different angles and directions. They serve to improve the load-bearing capacity of the anchoring in the subsurface.

The EP 2 689 071 B2 shows a guy plate which can be used to introduce tensile forces into the subsoil by means of a base plate anchored to the ground which has a number of threads distributed over the surface with different inclinations through which the threaded rods can be screwed.

The disadvantage of this well-known anchor plate is that only a certain number of threaded rods can be accommodated per base plate, which limits the possibility of introducing forces into the subsoil. For larger construction projects, more than one of the well-known anchor plates is therefore required to ensure the necessary anchoring.

The invention is therefore based on the object of further developing a guy plate in such a way that, taking into account a flexible surface design, a product is available that is both easy to set up and easy to install, with which the tensile forces that occur can primarily be introduced into the subsoil.

The object is achieved according to the invention by the features of the independent patent claim, while advantageous embodiments and further developments of the invention can be taken from the subclaims.

An advantageous feature is that the base plate of the guy plate consists of a bent profile that is bent parallel to its longitudinal extension and is bent upwards at an angle from the surface of the base plate.

A curved bending profile means, for example, a simply curved profile or an L-profile, but the invention is not limited to this.

Preferably, it is a bending profile that is bent several times parallel to its longitudinal extension.

This increases the tear-out strength by allowing the tips of the threaded rods to penetrate the ground far away from the anchor plate. The effective area of the anchor plate is significantly improved compared to flat designs. This means that more linear meters of threaded rods can be inserted in the direction of impact than with the known flat designs.

Compared to known systems, a higher load-bearing capacity can be achieved with the same amount of material (e.g. installed linear meters). The higher load-bearing capacity, the reduced assembly time and the lower logistics effort therefore represent an increase in performance.

Depending on the application, the base plate is made of steel, iron, cast iron, aluminum or fiberglass. The base plate can, for example, have a length of approx. 83cm and a width of approx. 42cm and a height (without guy legs) of approx. 8cm, although the present invention is not limited to this.

The base plate is the main component of the guy plate, which also includes at least the threaded rods, the guy leg and other small parts. In the following, the terms base plate and guy plate are used synonymously unless otherwise specified.

The base plate preferably has an approximately rectangular outline and has at least two planes that are angled relative to the vertical and are connected to one another via at least one bending edge. The threads for screwing in the threaded rods are located in the planes. In an alternative embodiment, the base plate has an arrow shape.

The bends of the plate and the planes available with them, which in the preferred embodiment accommodate two rows but also one, three or more rows of threaded sleeves, enable the individual threaded sleeves to be aligned at different angles to the normal of the plate. This alignment of the threaded sleeves can thus be selected to optimize the forces acting on it.

In a further embodiment of the invention, the threaded sleeves can also be distributed and not arranged in series in the planes.

For higher load-bearing capacities, several guy plates can be connected to a traverse, allowing higher forces to be introduced into the subsoil.

The term plate normal refers to a straight line that is orthogonal (ie at right angles, perpendicular) to the surface of the plate at a certain point. Since the plate is partially curved, this surface refers to the parts that are not curved and are flat, ie parallel to the substrate.

To better explain the invention, the planes in which the threaded sleeves are located each have a normal that is perpendicular to the plane. The normals are referred to below as surface normals.

In the preferred embodiment, the back surface normal of the plane has an angle of 30° and the front surface normal of the plane has an angle of 45° with respect to the plate normal. However, in further embodiments, these angles may have a different value, such as 35° and 47°.

Within such an alignment to the vertical or a plane formed by this alignment, the individual threaded sleeves are again fanned out in their angular alignment in the horizontal. This fanning out means that although the center lines of the threaded sleeve have an angle of e.g. 30° or 45° to the plate normal, within this 30° or 45° plane formed in this way, the threaded sleeves have additional angles to the surface normal, which is perpendicular to the plane.

The center lines of the threaded sleeves, for example, form an angle between -5° and 20°. The term center line, which is used uniformly below, refers to the axis of symmetry shown in a technical drawing of components that are symmetrical in a plane or in space. Since the threaded sleeve is a rotationally symmetrical component, the center line is also the axis of rotation.

The threads run within threaded sleeves that are positioned in recesses in the planes of the base plate at defined angles in relation to their center line. The threaded sleeves are welded, shrunk or glued to the base plate.

Due to the different angular orientations of the threaded sockets, the individual threaded rods are driven into the subsoil at defined angles.

As explained above, the threaded sleeves are aligned at an angle to the surface normal of a plane. For example, the center line alignment is an angle between 0° and 45° to the plate normal and an additional angle between -5° and 20° to the surface normal of a plane.

For the sake of simplicity, the magnitudes of the angles are given below.

By driving the threaded rods at specific angles horizontally and vertically using the guy plate, a three-dimensional anchoring is technically achieved, so that the tensile force, compressive force and transverse force of the guy plate are significantly increased.

A guying leg is arranged centrally on the base plate, which is designed as a suspension lug/socket for the installation of a guying element or as a support for the installation of a support.

The guy leg has a mounting opening, which is designed either as a lug/socket for mounting a guy element (cable/rod) or as a support with a bolt/ball for mounting a support. Ideally, the resulting force is in line with the resulting resistance, e.g. for a guy element in the overhead line with a guy angle of 30°.

There are square positioning holes in the base plate into which a mounting fixture can be inserted at the beginning of the assembly of the device on the substrate and can be removed again later as soon as the first threaded rods have been inserted into the substrate.

The threaded rod is driven in with a screwing machine, which is described as follows:
A specific type of assembly machine is used to assemble the threaded rods in the base plate. One such known assembly machine consists of a drive motor that rotates a drill chuck designed as a clamping chuck. To anchor it with such an assembly machine, the threaded rod is inserted with its rear end into the drill chuck or clamping chuck. clamped and then the threaded rod is placed with its front end on the thread of the threaded sleeve and then the drilling machine is switched on. The rotating drive of the threaded rod drives it progressively into the soil or rock beneath the anchor plate because the thread pitches arranged around its circumference pull the threaded rod into the soil. The threaded rods are screwed in automatically, so to speak, because the threaded rods are advanced by the thread of the threaded rods engaging in the threaded holes on the base plate side.

The threaded rod can be inserted via an insertion opening arranged on the mounting head into a drive sleeve which is driven in rotation in the mounting head and which in turn drives the threaded rod in rotation in the longitudinal direction.

For this purpose, it is known to provide the threaded rods with flats on opposite sides so that the thread pitches are only arranged outside of these flats on the outer circumference of the threaded rod. The standard size of the threaded rods used is a length of 2-4 m, but the present invention is not limited to this.

In this way, it is possible to insert the threaded rod into the rotating drive sleeve, which is profiled to match the profile of the threaded rod described above, and to create a frictional connection with the flat sides of the threaded rod there. The drive sleeve is then driven in rotation and the threaded rod is screwed from top to bottom through the insertion opening in the assembly head through the threaded hole in the base plate and is driven into the soil or rock with its front tip. The threaded rod is advanced by the threaded rod engaging in the threaded hole on the base plate side. It is not necessary to apply manual force to the assembly machine to generate a feed of the threaded rod.

• geringe Montagezeit
• hohe Zug-, Druck- und Querkräfte
• vielseitiger Einsatz im Gelände
• zur Montage können entweder mechanische Werkzeuge oder ein Elektroschrauber, Luftschrauber oder ein Hydraulikschrauber verwendet werden.
• leichte bzw. nicht aufwendige Demontage aus dem Erdreich
• wiederholter Einsatz möglich
• kostengünstiges Preis- und Leistungsverhältnis des Verankerungssystems, da nur eine geringe Anzahl an Abspannplatten verwendet werden muss
• Verhältnis zwischen Materialeinsatz (ca. 100 kg Stahl) und erhaltener Traglast (ca. 20 to) ist sensationell. Somit auch ökologisch besonders wertvoll.

The advantages of the guy plate according to the invention are:

• short assembly time
• high tensile, compressive and transverse forces
• versatile use in the field
• For assembly, either mechanical tools or an electric screwdriver, pneumatic screwdriver or hydraulic screwdriver can be used.
• easy or inexpensive dismantling from the ground
• repeated use possible
• cost-effective price-performance ratio of the anchoring system, as only a small number of anchor plates have to be used
• The ratio between the material used (approx. 100 kg of steel) and the load-bearing capacity (approx. 20 tonnes) is sensational. This also makes it particularly valuable ecologically.

It is therefore a guy plate with fixed threaded sleeves, which are preferably welded in, but can also be shrunk, glued, etc. The guy plate is particularly characterized by its bends, which on the one hand serve to increase rigidity and on the other hand provide the possibility of adaptation to the forces acting on it. This makes it possible to drive the individual threaded rods into the subsoil at defined angles due to the different angular orientations of the threaded sleeves.

The subject matter of the present invention results not only from the subject matter of the individual patent claims, but also from the combination of the individual patent claims with one another.

All information and features disclosed in the documents, including the abstract, in particular the spatial configuration shown in the drawings, could be claimed as essential to the invention, insofar as they are new individually or in combination compared to the prior art. The use of the terms "essential" or "according to the invention" or "essential to the invention" is subjective and does not imply that the features so named Features must necessarily be part of one or more patent claims.

The invention is explained in more detail below with reference to drawings showing several embodiments. Further essential features and advantages of the invention emerge from the drawings and their description.

Figur 1:

eine perspektivische Ansicht der Grundplatte der Abspannplatte

Figur 2:

eine perspektivische Ansicht der Grundplatte mit eingefügten Gewindemuffen

Figur 3a:

dreidimensionales Koordinatensystem ergänzend zu Figur 3

Figur 3:

eine Draufsicht auf die Abspannplatte

Figur 4a:

dreidimensionales Koordinatensystem ergänzend zu Figur 4

Figur 4:

eine Seitenansicht von rechts auf die Abspannplatte

Figur 5:

ein Ausführungsbeispiel einer Gewindemuffe

Figur 6:

ein Ausführungsbeispiel einer montierten Abspannplatte

Show it:

Figure 1:

a perspective view of the base plate of the guy plate

Figure 2:

a perspective view of the base plate with inserted threaded sleeves

Figure 3a:

three-dimensional coordinate system in addition to Figure 3

Figure 3:

a top view of the guy plate

Figure 4a:

three-dimensional coordinate system in addition to Figure 4

Figure 4:

a side view from the right of the guy plate

Figure 5:

an example of a threaded sleeve

Figure 6:

an example of a mounted guy plate

Figure 1 shows the base plate 3 with a rectangular outline, whereby the base plate 3 is bent several times parallel to its longitudinal extension. Starting from the bottom, the base plate has several levels, surfaces and bending edges, beginning with an upwardly bent end surface 4, which merges into a bending edge 5. The bending edge 5 also serves as a support edge 6 with which the base plate 3 stands on the substrate 2.

Starting from the bending edge 5, the base plate 3 is bent upwards again and thus forms the plane 7, in which a plurality of recesses 18 are made. The threaded sleeves 19 are fitted into these recesses 18 in a later assembly step. For this purpose, the recesses 18 in the example shown have a hexagonal shape, into which the corresponding and also hexagonal outer profile 21 of the threaded sleeves 19 can be fitted.

The plane 7 merges into the bending edge 8, which in turn merges into the intermediate surface 9, which runs approximately parallel to the base 2. In the example shown, the intermediate surface 9 has two positioning openings 23, into which a holding device (not shown) can engage when the guy plate 1 is mounted on the base 2. In this way, the guy plate 1 can be fixed in the desired position in the transition period until the first threaded rods 39 have been driven into the base 2.

The intermediate surface 9 passes over the bending edge 10 into the intermediate surface 11, which is aligned approximately in the direction of the substrate 2. The intermediate level 11 passes over the bending edge 12 into the support surface 13, which rests flat on the substrate 2 when the guy plate 1 is mounted, or a flat support is aimed for. The guy plate 1 thus rests on the substrate 2 with the support edge 6 and the support surface 13.

In the example shown here, the support plane 13, which runs approximately parallel to the base 2, also has two positioning openings 23, into which a holding device can engage when the first threaded rods 39 begin to be screwed in in order to temporarily fix the anchor plate. Once a sufficient number of threaded rods 39 have been screwed in, the holding device can be removed again.

The support surface 13 passes over the bending edge 14 into the plane 15, which is bent upwards. A plurality of recesses 18 are arranged in the plane 15, which in the example shown here are also hexagonal.

The plane 15 passes over the bending edge 16 into the end surface 17, which has a handle 22 approximately in the middle. The base plate 3 can be moved manually using this handle 22.

The base plate 3 thus consists of a bending profile that is bent several times parallel to its longitudinal extension and is bent upwards at an angle from the plane of the base plate. This is due to the plurality of bending edges 5, 8, 10, 14 and 16 which are arranged between the planes 7, 15 and intermediate surfaces 9, 11 as well as end surfaces 4, 17.

A guy leg 24 is positioned vertically in the middle of the base plate. The guy leg 24 has a mounting opening 25 into which a guy element 41 can be hooked. In the example shown, the mounting opening is located in the area of level 7, bending edge 8 and intermediate surface 9. Above the bending edge 9, the guy leg 24 has a drill hole 26 into which guy elements or other items can also be hooked.

Starting from the intermediate level 9, the guy leg 24 runs in the direction of the support surface 13 and level 15 with a bending surface 27. The bending surface 27 is not higher than the distance of the bending edge 16 from the ground and ends shortly before the start of the bending edge 16 in level 15. The bending surface 22, which develops from a bend located approximately in the area of the bending edge 10 in the surface of the guy element 24, serves to introduce and distribute the tensile forces on the base plate 3.

Figure 2 shows the bracing plate 1, whereby the threaded sleeves 19 have now been inserted into the recesses 18 of the base plate 3. The threaded sleeves 19 protrude from the levels 7, 15 to different extents. For example, the outermost threaded sleeves 19 of a row have a greater length in relation to the surface of the plate than the two inner threaded sleeves 19 of such a row. The threaded sleeves 19 also have a different orientation compared to the surface normal 28, 29 of the levels 7, 15. This Alignment at a defined angle enables a targeted introduction of the threaded rod 39 into the substrate 2 and thus a most defined spreading of the tips of the threaded rods 39 to one another.

Figures 3a and 4a serve to better understand the graphical representation of the invention using xyz coordinate axes. For the sake of simplicity, negative angles have been omitted in the representation of the invention and the angle dimensions are only given in amounts. In Figure 3a, the z-axis points into the plane of the drawing and clarifies in relation to Figure 3 the orientation into the substrate 2. The x- and y-axes in Figures 3a, 3 thus form a plane on or parallel to the substrate 2. Figure 3 is the top view of the guy plate 1.

Figure 4a shows the z-axis again, which points into the background. The y-axis points in the direction of the viewer, ie out of the drawing plane. Figure 4 shows the side view from the right of the guy plate 1.

In the Figures 3 , 3a assumes a surface normal 28, 29 of a plane 7, 15. The surface normal 28 is perpendicular to the plane 7 and the surface normal 29 is perpendicular to the plane 15.

For better understanding, the surface normal has been drawn in the middle of each recess 18 in which a threaded sleeve 19 is located. Depending on the orientation of the threaded sleeve 19 on or in the planes 7, 15 of the base plate 3, the center line 42, 43 of the threaded sleeve 19 is congruent with the surface normal 28, 29 or forms an angle α between itself and the surface normal.

In Figure 3 At the top right, next to the anchor leg 24, the threaded sleeves 19 are arranged in a row of five. The center line 42 of the leftmost threaded sleeve 19 has an angle 31 to the surface normal 29. In the example shown here, this angle 31 is 10° and is located to the left of the normal 29.

The center line of the threaded sleeve 19 to the right has an angle 30 to the surface normal 29. In the example shown here, this angle 30 is 5° and is located to the left of the normal 29.

The center line 42 of the middle threaded sleeve 19 of the row of five is aligned in the same way as the surface normal 29.

The center line 42 of the threaded sleeve 19 to the right has an angle 31 to the surface normal 29. This angle 31 is 10° in the example shown here and is located to the right of the normal 29.

The center line 42 of the right outer threaded sleeve 19 has an angle 33 to the surface normal 29. In the example shown here, this angle is 20° and is located to the right of the normal 29.

For this purpose, the alignment of the threaded sleeves 19 to the left of the guy leg 24 is mirror-inverted.

In the row of four under the right row of five in Figure 3 the center lines 43 are also partially arranged at an angle to the surface normal 28.

The center line 43 of the leftmost threaded sleeve 19 has an angle 31 to the surface normal 28. This angle 31 is 10° in the example shown here and exists to the left of the normal 28.

The center line 43 of the threaded sleeve 19 to the right is aligned in the same way as the surface normal 28 and is therefore 0°.

The center line 43 of the threaded sleeve 19 to the right has an angle 31 to the surface normal 28. This angle 31 is 10° in the example shown here and is located to the right of the normal 28.

The center line 43 of the right outer threaded sleeve 19 has an angle 32 to the surface normal 28. In the example shown here, this angle is 15° and is located to the right of the normal 28.

In the Figure 4 and the explanatory Figure 4a it is shown how the entire base plate 3 has a plate normal 44, which is perpendicular to the substrate 2 and the parallel flat sections of the base plate, such as the support surface 13. This can also be understood as the normal of an unbent base plate

Compared to this plate normal 44, the surface normals have an angle β, which is indicated with the reference symbol 34 in relation to the surface normal 28 and with the reference symbol 35 in relation to the surface normal 29. In the example shown here, the angle 34 is 30° and the angle 35 is 45°.

Each center line 42, 43 of a threaded sleeve 19 thus describes a straight line in a three-dimensional coordinate system, the origin of which is in the respective center of a recess 18 and runs through an x, y, z point in the coordinate system. This straight line has the angle α with respect to the x-axis and the angle β with respect to the z-axis, whereby it is assumed that the z-axis points into the substrate, the x-axis runs along the width of the base plate 3 and the y-axis along the longitudinal extension of the base plate. For the sake of simplicity, negative angles have been omitted and only the amounts of the angles have been given.

The surface normal 28 is orthogonal to plane 7 and the surface normal 29 is orthogonal to plane 15.

In addition, Figure 4 the guy leg 24 is shown with the oval mounting opening 25 and the borehole 26 as well as the bend surface 27 with which the guy leg runs out or extends in the direction of the plane 15. Tensile forces acting on the guy leg 25 can thus be introduced into the base plate 3.

Figure 5 shows an embodiment of a threaded sleeve 19 with the center line 42, 43. In the upper area, the sleeve 19 has an outer profile 21 in hexagonal shape. Tools, for example, can be used here. Starting from the outer profile 21, the threaded sleeve 19 has a round-profiled intermediate section, which merges into an end section with a reduced diameter that is also round-profiled.

Alternatively and not shown, the outer profile 21 can also extend over the entire length of the threaded sleeve 19. The outer profile corresponds to the inner profile of the recess 18 into which the threaded sleeve is inserted and fixed in the base plate 3.

Figure 6 shows a further embodiment of a guy plate 1, which is screwed to the base 2 via the threaded rods 39. The threaded sleeves 19 are arranged in the levels 37, 38.

The planes 37, 38 are arranged at an angle to the substrate so that their surface normals form an angle to the substrate. The center lines of the threaded sleeves or the screwed-in threaded rods are also aligned at a defined angle to these surface normals. This allows the tips of the threaded rods to fan out as much as possible, thereby achieving optimal anchoring of the guy plate.

Drawing legend

• 1. Guy plate
• 2. Subsurface
• 3. Base plate
• 4. End face
• 5. Bending edge
• 6. Support edge
• 7th level
• 8. Bending edge
• 9. Intermediate surface
• 10. Bending edge
• 11. Intermediate surface
• 12. Bending edge
• 13. Support surface
• 14. Bending edge
• 15th level
• 16. Bending edge
• 17. End face
• 18. Recess
• 19. Threaded socket
• 20. Thread
• 21. External profile
• 22. Handle
• 23. Positioning opening
• 24. Guy legs
• 25. Mounting opening
• 26. Borehole
• 27. Bend surface
• 28. Surface normal first level
• 29. Surface normal second plane
• 30.5° angle
• 31.10° angle
• 32.15° angle
• 33.20° angle
• 34.30° angle
• 35. 45° angle
• 36..
• 37th level
• 38th level
• 39. Threaded rod
• 40. Arrow direction
• 41. Guying element
• 42. Center line
• 43. Center line
• 44. Plate standards
• α Angle of an xy vector to
  Normal x
• β Angle of an xz vector to
  Normal z

Claims (15)

Tension plate (1) for introducing tensile and compressive forces into the subsoil (2) by means of threaded rods (39), with a base plate (3) anchored on the ground, which has a number of threads (20) distributed over the surface with different inclinations (30-35) through which the threaded rods (39) can be screwed, characterized in that the base plate (3) consists of a bending profile bent parallel to its longitudinal extent, which is bent upwards at an angle from the surface of the base plate (3). Guying plate (1) according to claim 1, characterized in that the base plate (3) has at least two angled planes (7, 15) which are connected to one another via at least one bending edge (8, 10, 12) and that the threads (20) for screwing in the threaded rods are located in the at least two planes (7, 15). Guying plate (1) according to claim 2, characterized in that a first plane (7) is preferably bent at a 30° angle and a second plane (15) is preferably bent at a 45° angle with respect to a support surface (13) of the base plate (3) resting flat on the substrate. Tension plate (1) according to one of claims 1 to 3, characterized in that the threads (20) run within threaded sleeves (19) which are positioned in recesses (18) in the planes (7, 15) of the base plate (3) at defined angles (30-35). Tension plate (1) according to claim 4, characterized in that the threaded sleeves (19) are aligned at an angle (30-35) with respect to the surface normal of a plane (7, 15). Tension plate (1) according to claim 4 or 5, characterized in that the angle (30-35) of the threaded sleeves (19) is between 0° and 45° with respect to the surface normal (28, 29) of a plane (7, 15). Tension plate (1) according to one of claims 4 to 6, characterized in that the threaded sleeves (19) align the individual threaded rods (39) at defined angles (30-35) into the substrate (2) during the screwing-in process due to the different angular orientations of the threaded sleeves (19). Tension plate (1) according to one of claims 4 to 7, characterized in that the threaded sleeves (19) are welded or shrunk or glued to the base plate (3). Guy plate (1) according to one of claims 1 to 8, characterized in that the base plate (3) consists of steel, iron, cast iron, aluminum or fiberglass. Guy plate (1) according to one of claims 1 to 9, characterized in that the guy plate (19) has a rectangular outline. Guying plate (1) according to one of claims 1 to 10, characterized in that a guying leg (24) is arranged centrally on the base plate (3), which is designed as a suspension lug/sleeve for the installation of a guying element (41) or as a support for the installation of a support. Guying plate (1) according to claim 11, characterized in that the guying element (41) is a rope or a rod. Tension plate (1) according to one of claims 1 to 11, characterized in that square positioning openings (23) are present in the base plate (3), into which a mounting fastening engages at the beginning of the assembly of the device on the substrate (2). Use of the guy plate (1) according to one of the preceding claims for guying an overhead line with a guy angle of 30°. Use of the guy plate (1) according to claim 14, for mounting and dismounting on a substrate made of soil or rock.

Images