DE102021204966B4 - Device for anchoring platforms in trees, surmounting element, method for anchoring a platform in a tree and method for manufacturing a device for anchoring platforms in a tree - Google Patents

Abstract

A device (1) for anchoring platforms in trees has an anchoring section (7) with a thread (11), the thread (11) having asymmetrical thread flanks (30, 31) at least in a first section (7a).

Description

The invention relates to a device for anchoring platforms in trees. The invention also relates to an overflow element for such a device. Furthermore, the invention relates to a method for anchoring a platform in a tree. Finally, the invention relates to a method for producing such a device.

Tree house screws, for example, are used to anchor platforms, in particular for tree houses, in trees. Inserting such screws into trees can result in damage to the trees. Reducing the diameter of the bolts can cause them to fail to withstand the load they are subjected to.

From the DE 10 2017 117 246 A1 and the DE 20 2018 103 776 U1 devices and methods are known for creating a permanent point of attachment to a tree. From the EP 3 141 768 A1 a wood screw is known. From the FR 2 974 599 A1 a tree screw is known.

There is a need to improve a device for anchoring platforms in trees.

This object is solved by the features of claim 1.

According to one aspect of the invention, the device has an anchoring section with a thread whose thread flanks are asymmetrical. The thread of the anchoring section has asymmetrical thread flanks at least in a first section. Here, the first section can be a real section of the thread. For example, it can extend over at most 90%, in particular at most 70%, in particular at most 50% of the entire threaded section. As an alternative to this, the thread of the anchoring section can have asymmetrical thread flanks over its entire length.

Asymmetrical thread flanks mean in particular that the flank facing the first end of the bolt, which is also referred to as the front flank, has a different shape than the flank facing away from the first end of the bolt, which is also referred to as the rear flank.

In particular, the front flank can be less steep than the rear flank.

The front flank can in particular be less sharp-edged than the rear flank.

The thread can in particular be a buttress thread. As an alternative to this, the thread can also be designed as a trapezoidal thread, apart from the asymmetry. In principle, the bolt can also have a symmetrically designed trapezoidal thread.

The aspect and the details of the formation of the thread can also be advantageous independently of further details of the invention.

According to one aspect of the invention, the device includes an overflow element. The overgrowth element serves to be surrounded or overgrown by the tree. This supports a particularly reliable, permanent anchoring of the device in the tree.

In particular, the bridging element has a bridging body with a larger outer diameter than the anchoring section. As a result, after the device has been introduced into a tree, it can lie against the outside of the tree or against a contact surface provided for this purpose on the outside of the tree.

The outer diameter of the bridging body is in particular at least twice, in particular at least three times, in particular at least five times as large as that of the anchoring section.

The overflowing element can have a lateral surface with a constant diameter in the direction of the pin axis or a lateral surface in the shape of a truncated cone.

The surging body can in particular have a cylinder-like, in particular a circular-cylindrical lateral surface. Here, a cylinder designates a general cylinder, which can have an essentially arbitrary cross-section defined by a guide curve. The cross section of the overflow body perpendicular to the bolt axis is preferably round, in particular circular, or polygonal, in particular as a regular square or regular hexagon. The overflow body can in particular be designed in the shape of a circular cylinder, a truncated cone or a prism.

The bridging body can also have different sections extending in the direction of the bolt axis. In particular, it can have a prism-shaped section and/or a have a circular-cylindrical section and/or a frustoconical section.

A prismatic section may facilitate unscrewing the surge body and/or screwing the device into a tree. A circular-cylindrical section can facilitate manufacture. A frusto-conical section can lead to a particularly good bridging and in particular to a particularly reliable anchoring of the device in a tree.

According to a further aspect of the invention, the thread has thread flanks, at least in the first section, which are rounded on their side facing the first ends. In particular, provision can be made for the front flank of the thread to be rounded.

A rounded configuration is understood here in particular to mean that a minimum radius of curvature of the thread flank, particularly in the area of the outer circumference of the thread, is at least 0.2 mm, particularly at least 0.3 mm, particularly at least 0.5 mm.

A rounded design of the front thread flanks can prevent the wood fibers from being cut when the bolt is screwed in. In addition, this can reduce the screwing torque.

The rear thread flank can preferably be formed with sharp edges. A sharp-edged design is understood to mean, in particular, a design with a minimum radius of curvature of at most 0.1 mm, in particular at most 0.05 mm, in particular at most 0.03 mm, in particular at most 0.02 mm, in particular at most 0.01 mm.

The rear flank can in particular be aligned perpendicularly to the bolt axis or even arranged at an acute angle to it. An acute-angled arrangement is understood here to mean that the surface of the bolt in the region between two thread flanks and the rear thread flank in each case encloses an acute angle. The angle between the rear thread flank and the outer surface of the core of the anchoring section is in particular at most 90°, in particular at most 80°, in particular at most 70°.

A sharp-edged design of the rear thread flank leads to a particularly high pull-out torque.

According to a further aspect of the invention, the front thread flank has a minimum radius of curvature rv and the rear thread flank has a minimum radius of curvature rh, where the following applies: rv: rh ≥ 2, in particular rv: rh ≥ 3, in particular rv: rh ≥ 5.

According to a further aspect of the invention, the device can be designed in two or more parts.

According to one aspect of the invention, the device includes a bolt and a bridging element releasably connectable to the bolt.

It has been shown that this leads to an improvement in the resilience of the device. At the same time, the effort involved in manufacturing the device could be reduced. The device is particularly reliable on the one hand and inexpensive on the other.

Initial tests in reference books have shown that the bolt withstands pull-out forces of over 45 kN with an anchoring section with a diameter of 16 mm. The device withstands vertical loads of over 18 kN.

According to one aspect of the invention, the bolt has an anchoring portion extending in a longitudinal direction from a first end and a coupling portion extending in a longitudinal direction toward a second end. The direction from the second end to the first end is also referred to as the screw-in direction. If the orientation is not important, the direction parallel to the longitudinal direction or parallel to the screwing-in direction is also referred to as the axial direction.

In particular, the bridging element can be releasably connected to the coupling section of the bolt. In particular, it can be screwed onto the coupling section of the bolt. For this purpose, the coupling section can have a thread, in particular an external thread. The coupling section can in particular have a metric ISO thread. The thread of the coupling section is in particular suitable for a corresponding internal thread in the bridging element. The overflow element can in particular be screwed onto the coupling section.

The thread of the coupling section and the thread of the bridging element can in particular be an M10, M12, M14, M16, M18, M20 thread. This list is not to be understood as exhaustive.

According to an alternative, the bridging element can also be designed in one piece with the anchoring section. The device can in particular be designed in one piece overall.

According to a further aspect of the invention, the bolt has a transition section arranged in the longitudinal direction between the anchoring section and the coupling section. In particular, the transition section can have an outer diameter which is larger than a core diameter of the anchoring section and/or a core diameter of the coupling section. The outer diameter of the transition section is in particular at least 10% larger than the core diameter of the anchoring section and/or the coupling section.

The transition section can be designed as a ring protruding in the radial direction from the bolt. In particular, it can have a cylindrical shape, in particular a circular-cylindrical shape. It can also be designed in the shape of a truncated cone or double-conical (biconic).

The transition section can have a circular-cylindrical lateral surface. The transition section can also taper slightly towards the first end, ie counter to the longitudinal direction. The convergence angle is in particular at most 10°, in particular at most 5°, in particular at most 3°. It can be at least 1°, in particular at least 2°, in particular at least 3°.

The transition section forms in particular a sealing element for sealing a borehole into which the anchoring section can be inserted, in particular screwed.

The transition section can also form a support collar. A component of the overflow element can also serve as a support collar. The support collar can be sunk into the sapwood when screwing the bolt into a tree.

The transition section can in particular have an outside diameter which corresponds to the thread diameter of the anchoring section. The outer diameter of the transition section deviates in particular by at most 10%, in particular at most 5%, from the thread diameter of the anchoring section. As a result, a particularly reliable sealing of the bore into which the anchoring section is screwed can be achieved.

In particular, the outer diameter of the transition section is smaller than the outer diameter of the eruption element. The ratio of the outside diameter of the transition section to the outside diameter of the overflow section is in particular at most 4:5, in particular at most 3:4, in particular at most 2:3, in particular at most 1:2. relationship improved.

According to a further aspect of the invention, the device comprises a force transmission element tapering in the longitudinal direction.

The cone tapers conically, in particular in the longitudinal direction, that is to say counter to the direction in which the bolt is inserted into the bore provided for this purpose. Due to the conical design of the force transmission element, the bending moment acting on the device is transmitted particularly effectively to the bolt. It has been shown that the resilience of the device could be significantly improved in this way.

The convergence angle, which corresponds to exactly half the opening angle of a cone adapted to the conically tapering outer surface of the force transmission element, is in particular in the range from 1° to 30°. In particular, it is at most 20°, in particular at most 15°, in particular at most 10°, in particular at most 5°. In particular, it can be at least 2°, in particular at least 3°.

According to a further aspect of the invention, the force transmission element is designed in one piece with the bolt, in particular in one piece with the transition section.

As an alternative to this, the force transmission element can also be screwed onto the bolt.

The transition section can also be designed as an element that can be screwed onto the bolt.

The power transmission element can also serve as a sealing element.

The force transmission element can also form the transition section.

According to a further aspect of the invention, the conically tapering force transmission element bears against the transition section or is formed in one piece with it.

According to a further aspect of the invention, the bolt is made of steel, in particular stainless steel, in particular stainless steel. The bolt can in particular be made of machine steel. He can in particular be provided with an anti-corrosion layer, in particular in the form of a cathodic dip coating (KTL).

According to an advantageous variant, the material of the bolt can be chosen depending on the tree species. For screwing into coniferous trees, the bolts can preferably be galvanized. For all other types of trees with the exception of oaks, the bolt can preferably be made of V2A steel, in particular CrNi steel 1.4301, 1.4541 or 1.4307. Due to the formation of tannic acid, V4A steel, in particular CrNiMo steel 1.4401, 1.4571 or 1.4404, is advantageous for use in oak trees. The remaining components of the device are preferably made of the same material as the bolt.

According to a further aspect of the invention, the bridging element has a recess whose shape is adapted to the conical shape of the force transmission element in such a way that a form-fitting connection can be produced between the bridging element and the force transmission element.

The shape of the recess of the overflow element is in particular complementary to the conical shape, in particular to the conical area of the force transmission element.

The overflow element comes into contact with the force transmission element, in particular when it is connected to the bolt, in particular when it is screwed onto the coupling section of the bolt. In particular, it can lie flat against the force transmission element. It is preferably in contact with the force transmission element over the entire surface area of the recess. This ensures a particularly good transmission of force and moment between the overflow element and the force transmission element and thus the bolt.

The depth of the recess, ie its extension in the longitudinal direction, can in particular be just as great as the extension of the conical section of the force transmission element in the longitudinal direction. It can also be somewhat smaller than the extension of the conical section of the force transmission element. In particular, it can be at least 1 mm less than the extension of the conical section of the force transmission element in the longitudinal direction. In this way it can be avoided that bending moments acting on the bridging element lead to tension loads on the anchoring section in the tree. In particular, the device enables a substantially stress-free arrangement of the bolt in a tree. It is therefore particularly gentle on the tree.

According to a further aspect of the invention, the anchoring section has a thread. The thread is preferably an asymmetrical thread, in particular a buttress thread, or a trapezoidal thread. The thread is particularly adapted to the growth of the tree. The thread is designed in particular based on the model of branch connection according to Axel Shigo. In particular, it is designed in such a way that it does not cut the wood fibers of the trunk, but only displaces them. When the anchoring section is screwed in, the wood fibers are pressed to the side, in particular pressed against one another. This leads to self-consolidation. In other words, the anchoring section simulates the natural branch connection. A gentle attachment of the bolt in the tree can also be improved in this way. The thread depth takes over the function of the branch spurs.

According to an advantageous variant, the thread height of the anchoring section can be adapted to the thickness, in particular the average thickness, of the annual rings of the tree into which the bolt is to be screwed. Provision can in particular be made to provide different bolts with anchoring sections with different thread heights.

According to a further aspect of the invention, the ejection element may have a longitudinally extending internal thread. The internal thread makes it possible in particular to receive a fastening element, for example a threaded rod or a screw.

The thread is preferably a metric thread, in particular an ISO thread. For example, it can be an M8, M10, M12, M14, M16, M18, M20, M22 thread. This list is not to be understood as limiting.

In the longitudinal direction, the eruption element can extend at least 1 cm, in particular at least 2 cm, in particular at least 3 cm, in particular at least 5 cm and in particular at least 6 cm. Provision can be made to provide different overflow elements. In this way, account can be taken of the different rates of growth of the wood into which the bolt is to be screwed. Preferably, the length of the eaves element in the longitudinal direction is at least half the growth of the tree in the radial direction plus 1 cm, if the bolt is to be used for platforms. For use in tree houses, bridging elements with at least twice the length in the longitudinal direction are preferably used.

Another object of the invention is to improve a bridging element for a device for anchoring platforms in trees.

This object is achieved by an overflow element with an overflow body and a conical recess arranged at the end of the overflow body.

The advantages result from those previously described.

The overflow body has in particular a rotationally symmetrical outer circumference. In particular, it can have a cylindrical, in particular a circular-cylindrical lateral surface.

However, it can also be advantageous to provide symmetry-breaking means on the outer circumference of the overflow body, for example contact surfaces for screw-in means, in particular contact surfaces for a wrench.

It can also be advantageous for the overflow body to taper conically, in particular in the form of a truncated cone. On the one hand, this leads to a more attractive appearance, and on the other hand, this increases the pull-out resistance of the device if the overflowing element overflows over time. According to a particularly preferred variant, the overflow body has a section with a circular-cylindrical lateral surface and an adjoining section with a chronically tapering lateral surface, in particular designed in the shape of a truncated cone.

With regard to further details of the overflow element, reference is made to the previous description.

In particular, the eruption element may have an internal thread extending axially from a second end opposite the first end.

The overflow body can be designed with sharp edges on the peripheral side, in particular at its second end. In this way, a form-fitting connection to the platform wood can be effected.

The second end is understood to mean in particular the end of the overflow body opposite the first end of the bolt.

The effervescence body may have a hexagonal cross-section. For example, it can be in the form of an M30 or more, in particular M35 or more, in particular M40 or more hexagon.

A hexagonal overflow body is particularly advantageous for platform attachment.

The overflow body can in particular have a diameter which is larger than the diameter of the transition section.

The surging body can also have a circular outer diameter. The outer diameter of the overflow body can be at least 30 mm, in particular at least 35 mm, in particular at least 40 mm.

A surge body with a circular outer diameter is used in particular in a device for attaching a lifeline in a tree.

Another object of the invention is to improve a method of anchoring a platform or lifeline in a tree.

• - Bereitstellen einer Vorrichtung gemäß der vorherigen Beschreibung,
• - Einbringen einer Stufenbohrung in einen Baum,
• - Verbinden des Überwallungselements mit den Bolzen,
• - Einschrauben des Verankerungsabschnitts des Bolzens in die Stufenbohrung,
• - wobei das Überwallungselement an einer Anlagestufe der Stufenbohrung zum Anliegen kommt.

This task is solved by a procedure with the following steps:

• - providing a device according to the previous description,
• - Drilling a stepped hole in a tree,
• - connecting the flashing element with the bolts,
• - screwing the anchoring portion of the bolt into the stepped hole,
• - The overflow element comes to rest on a contact stage of the stepped bore.

Here, in the case of a two-part or multi-part design of the device, the bridging element can be connected to the bolt before or after the anchoring section of the bolt is screwed into the stepped bore.

The stepped bore has an inner bore and a contact step. The attachment stage is preferably within the cambium of the tree arranged. This can be achieved by a suitable selection of the drilling depth. Because the attachment stage is within the cambium, the overflow element does not exert any pressure on the cambium. It has been shown that this leads to an improved overflow of the overflow element.

The stepped bore can be introduced, for example, with a stake drill. Here, the drill head is preferably adapted to the geometric dimensions of the anchoring device. The front part of the drill is particularly adapted to the geometry of the anchoring portion of the bolt. The rear part of the drill head is particularly adapted to the geometry of the overflow element. In particular, it has the same outside diameter as the overflow element.

The stepped bore serves in particular to accommodate the anchoring section and to partially accommodate the overflow element.

The bolt is preferably screwed into the stepped bore, ie into the tree, in such a way that the anchoring section is stress-free in the wood. This is particularly gentle on the tree. Stress-free installation of the bolt can be ensured using a suitable screwing tool. The bolt is screwed into the tree until the tool is in contact with the stepped bore. The tool is then removed and the overflow element is screwed onto the coupling section. In particular, it is screwed onto the coupling section of the bolt until it rests against the stepped bore.

Provision can preferably be made for the bore to first be cleaned and/or disinfected before the anchoring section is screwed in. The core bore can be cleaned in particular with the help of a brush. A dibromol tincture or a nosocomia spray, for example, can be used to disinfect the drill and/or the bore.

Disinfecting can reduce the risk of rot or disease in the tree.

In order to screw the anchoring section of the bolt into the inner part of the stepped bore, a removable bolt guide can be applied to the bolt, in particular to the anchoring section. The bolt guide preferably has an outer circumference which corresponds to that of the flashing element. It therefore just fits positively into the stepped bore. The bolt guide can be designed in two parts. In particular, it can be divided along a central longitudinal plane. This makes it easier to attach the bolt guide to the bolt or remove it from it. Using a bolt guide facilitates precise insertion of the anchoring device into the stepped bore.

According to a further aspect of the invention, a region of the stepped bore surrounding the anchoring section is sealed when the bolt is screwed in.

The inner area of the stepped bore, which is also referred to as the core bore, is sealed in particular by the transition section of the bolt and/or by the force transmission element.

In particular, the bolt can be screwed into the stepped bore so far that the transition section is drawn into the core bore, in particular so far that the outer edge of the transition section comes to rest conclusively with the contact surface of the contact step of the stepped bore.

According to a further aspect of the invention, to improve the seal, a sealant, in particular a liquid sealant, is introduced into the stepped bore before the bolt is screwed in. It can be a hardening sealant. In particular, it can be tree wax or a mixture of tree resin and wax. This is particularly gentle on the tree. In addition, this leads to a particularly reliable sealing of the bore. This can effectively prevent liquid from penetrating into the bore and thus the formation of rot.

Another object of the invention is to improve a method of manufacturing a device for anchoring platforms in trees.

• - Bereitstellen eines Rohlings mit einer Länge, welche der Gesamtlänge des herzustellenden Bolzens entspricht, und einem Durchmesser,
• - Einbringen eines Gewindes in den Rohling zur Ausbildung des Verankerungsabschnitts,
• - wobei der Durchmesser des Rohlings beim Eindringen des Gewindes höchstens um 10 % reduziert wird.

This task is solved by a procedure with the following steps:

• - Providing a blank with a length that corresponds to the total length of the bolt to be produced and a diameter,
• - introducing a thread into the blank to form the anchoring section,
• - where the diameter of the blank is reduced by a maximum of 10% when entering the thread.

The method enables the device to be manufactured very inexpensively. It will esp special reduced the amount of material removal. In this way, in particular, the material costs for the production of the bolt are reduced.

The thread is introduced in particular into the area serving as the anchoring section. With regard to the details of the thread, reference is made to the previous description.

The thread can be produced in particular by means of a milling or turning process. In particular, it can be turned or milled into the area serving as the anchoring section. In particular, it can be CNC milled or turned.

Different aspects of the invention, in particular the one-piece or multi-part design of the device, the details of the thread on the anchoring section and the details of the bridging element can each form the basis for advantageous designs of the device, also referred to overall as a tree bolt. They can also essentially be freely combined with one another and thus lead to particularly advantageous embodiments.

The fact that not all advantageous embodiments have been covered by separate, in particular independent, claims is exclusively due to cost reasons and/or the need for unity. In particular, the right should remain reserved to protect further advantageous combinations of features by means of independent claims, if necessary by means of divisional applications.

• 1 schematisch eine Schnittdarstellung einer Vorrichtung zum Verankern von Plattformen in Bäumen mit einem Bolzen und einem Überwallungselement,
• 2 eine schematische Darstellung gemäß 1 einer Variante der Verankerungsvorrichtung,
• 3 eine schematische Darstellung gemäß 1 einer weiteren Variante der Verankerungsvorrichtung,
• 4 schematisch eine Darstellung der Verankerungsvorrichtung gemäß 1 in einem in einen Baum eingebrachten Zustand,
• 5 exemplarisch eine Darstellung zur Erläuterung eines Verfahrens zum Einbringen der Verankerungsvorrichtung in einen Baum,
• 6 exemplarisch eine schematische Darstellung gemäß 1 einer weiteren Variante der Verankerungsvorrichtung und
• 7 schematisch eine vergrößerte Darstellung der Gewindeflanken des Gewindes auf dem Verankerungsabschnitt zur Erläuterung einer bevorzugten Ausführungsform.

Further features and advantages of the invention result from the description of different variants of the same with reference to the figures. Show it:

• 1 schematically a sectional view of a device for anchoring platforms in trees with a bolt and a bridging element,
• 2 a schematic representation according to 1 a variant of the anchoring device,
• 3 a schematic representation according to 1 another variant of the anchoring device,
• 4 a schematic representation of the anchoring device according to FIG 1 in a state brought into a tree,
• 5 an example of a representation explaining a method for introducing the anchoring device into a tree,
• 6 exemplarily a schematic representation according to 1 a further variant of the anchoring device and
• 7 schematically shows an enlarged view of the thread flanks of the thread on the anchoring section to explain a preferred embodiment.

The following is with reference to the 1 describes a device 1 for anchoring platforms in trees.

The device 1 comprises a bolt 2 and a bridging element 3.

The bolt 2 extends in a longitudinal direction 4 from a first end 5 to a second end 6. The first end 5 is also referred to as the inner end or screw-in end. The second end 6 is also referred to as the outer end. In the figures, the longitudinal direction 4 is oriented opposite to a screwing-in direction 4a. The bolt 2 has a bolt axis BA extending in the longitudinal direction 4 .

The bolt 2 comprises an anchoring section 7 extending from the first end 5 in the longitudinal direction 4.

The bolt 2 comprises a coupling section 8 extending in the longitudinal direction 4 towards the second end 6.

A transition section 9 is arranged between the anchoring section 7 and the coupling section 8 .

The transition section 9 has an outer surface 17 in the shape of a circular cylinder jacket.

The device 1 comprises a force transmission element 10.

The force transmission element 10 is formed in one piece with the transition section 9 or is in direct contact with the transition section 9 . The force transmission element 10 can in particular form a part of the transition section 9 .

The bolt 2 can in particular be designed in one piece. In particular, it can be turned from a one-piece blank.

In the area of the anchoring section 7, the bolt 2 has a thread 11 at least in a first section 7a. The thread 11 is designed in particular as a trapezoidal thread.

The bolt 2 has a thread 12 in the area of the coupling section 8 . The thread is 12 designed in particular as a metric ISO thread.

The power transmission element 10 is designed to taper conically in the longitudinal direction 4 . The convergence angle b is 3°. It is generally in the range from 1° to 30°, preferably at most 25°, preferably at most 20°, preferably at most 15°, preferably at most 10°, preferably at most 5°. It is in particular at least 1°, in particular at least 2°.

The overflow element 3 has an overflow body with an outer surface 13 in the shape of a circular cylinder jacket.

The overflow element 3 has a through hole 14 . An internal thread 15 is provided in the through hole 14 . The internal thread 15 is designed to match the thread 12 on the coupling section 8 of the bolt 2 .

The overflow element 3 has a recess 16 at the end.

The recess 16 is formed like a blind hole.

The recess 16 is in particular arranged in a complementary manner to the force transmission element 10 . This enables a positive connection between the overflow element 3 and the force transmission element 10.

The overflow element 3 can be connected to the bolt 2 . In particular, it can be screwed onto the coupling section 8 . This results in direct contact between the coupling section 8 and the recess 16. The coupling section 8 comes into contact with the recess 16 in particular over its entire surface.

In the connected state of the overflow element 3 with the bolt 2, the recess 16 is preferably completely filled. In particular, it is completely filled by the force transmission element 10 . To improve the connection, a filler, in particular a liquid filler, in particular a hardening filler, for example an adhesive, can first be introduced into the recess 16 when connecting the overflow element 3 to the bolt 2 . In this way it can be achieved that no cavities remain in the recess 16 .

The dimensions of the bolt 2 and the bridging element 3 can be selected as required, in particular as a function of the loads to be expected. Smaller dimensions lead to a gentler attachment of the device to the tree. Larger dimensions allow higher loads. Specific dimensions for components of the anchoring device 1 are specified below by way of example. This information is not to be understood as limiting. Other dimensions are also possible if required.

The length l ₂ of the bolt 2, in particular the length l ₇ of the anchoring section 7, and the diameter d ₇ of the anchoring section 7 can be selected in particular depending on the tree species (hardwood or softwood) and/or depending on the standard of the tree.

The length l ₃ of the overflow element 3 can be determined from a core drilling analysis of a reference tree at the respective location. The length l ₃ of the overflow element 3 can in particular correspond to the mean growth of the reference tree in the last 10 years plus 1 cm.

The anchoring section 7 can have a length l ₇ in the range from 1 cm to 20 cm. The length l ₇ of the anchoring section 7 is preferably at least 3 cm, in particular at least 5 cm.

The anchoring section 7 has in particular an outer diameter d ₇ , in particular a thread diameter of at least 8 mm, in particular at least 10 mm, in particular at least 12 mm, in particular at least 14 mm, in particular at least 16 mm, in particular at least 18 mm, in particular at least 20 mm, in particular at least 22mm up.

The transition section 9 has a length l ₉ in the range from 0.5 cm to 2 cm.

The transition section 9 has a diameter d ₉ which deviates from the diameter d ₇ of the anchoring section 7 by a maximum of 10%. The diameter d ₉ preferably corresponds to the diameter d ₇ , d ₉ ≈d ₇ . The diameter d ₉ of the transition section 9 is greater than a core diameter d _7K of the core of the anchoring section 7. The following applies in particular: d ₉ : d _7K ≧1.05, in particular ≧1.1.

The power transmission element 10 has a maximum outer diameter d _10m , which is just as large as the diameter d ₉ of the transition section 9.

The power transmission element 10 has a length l ₁₀ in the longitudinal direction 4 in the range of 0.5 cm to 5 cm, in particular in the range of up to 4 cm, in particular in the range of up to 3 cm, in particular in the range of up to 2 cm.

The coupling section 8 can have an outside diameter d ₈ , in particular a thread diameter, which corresponds to the outside diameter d ₇ of the anchoring section 7 . The diameter d ₈ of the coupling section 8 can also be smaller than the diameter d ₇ of the anchoring section 7.

The coupling section 8 has a length l ₈ in the longitudinal direction 4, which can be in the range from 1 cm to 10 cm. The length l ₈ is in particular at most 8 cm, in particular at most 5 cm. The length l ₈ is preferably at least 2 cm, in particular at least 3 cm.

The length l ₈ is smaller than a length l ₁₄ of the through-bore 14 of the overflow element 3. The following applies in particular: l ₈ : l ₁₄ ≦2:3, in particular l ₈ : l ₁₄ ≦1:2.

The length l ₁₄ of the through-bore 14 of the overflow element 3 can be in the range of 2 cm to 20 cm. The length l ₁₄ is in particular at most 15 cm, in particular at most 10 cm, in particular at most 6 cm. The length l ₁₄ of the through hole 14 is in particular at least 2 cm, in particular at least 3 cm, in particular at least 5 cm.

The overflow element 3 has a maximum outer diameter d _3m in the range from 2 cm to 25 cm. The maximum diameter d _3m of the overflow element 3 is in particular at most 20 cm, in particular at most 15 cm, in particular at most 10 cm. The maximum diameter d _3m of the overflow element 3 is in particular at least 3 cm, in particular at least 5 cm.

In the 2 a variant of the anchoring device 1 is shown. Identical components are given the same reference numbers as in the variant according to FIG 1 .

In the variant according to 2 the power transmission element 10 is designed as a separate element. The coupling section 8 extends to the transition section 9. The force transmission element 10 can be applied to the transition section 9, in particular screwed on. For this purpose, it has an internal thread 18 that matches the thread 12 .

This variant allows existing anchoring devices or tree screws to be retrofitted, which have a coupling section with an external thread but no force transmission element 10 , in particular no force transmission element 10 that tapers conically.

According to a variant not shown in the figures, the transition section 9 can also be correspondingly screwed onto the coupling section 8 . In this case, the coupling section 8 can be connected directly to the anchoring section 7 .

In this variant, the transition section 9 and the force transmission element 10 can advantageously be designed in one piece.

According to a variant that is also not shown in the figures, a contact shoulder can be formed in the area between the transition section and the force transmission element 10 . The contact shoulder can be designed as a ring protruding radially to the longitudinal direction 4 outwards. The contact shoulder can define the maximum screw-in depth of the bolt 2.

According to another in which 3 variant shown as an example, the transition section 9 is designed to diverge conically in the longitudinal direction 4 . In other words, it tapers in the screwing-in direction 4a, that is to say its diameter decreases. In this way it can be achieved that when the bolt 2 is screwed into a hole provided for this purpose, the hole is gradually sealed off when the transition section 9 is drawn into the hole.

Like in the 3 is also shown as an example, the force transmission element 10 can also have a circular-cylindrical lateral surface. In this case, the recess 16 is designed as a circular-cylindrical blind hole.

The following is with reference to the 6 and 7 a further embodiment of the anchoring device 1 is described as an example.

The essential components of the anchoring device 1 correspond to those of the previously described embodiments, to which reference is hereby made.

In the embodiment according to 6 and 7 the thread on the anchoring section 7 has asymmetrical thread flanks 30, 31 in a first section 7a (see in particular 7 ).

The first end 5 of the bolt 2 facing thread flank 30, which as a front Thread flank 30 is called, is rounded.

The first end 5 facing away from the thread flank 31, which is also referred to as the rear thread flank 31 is sharp-edged.

The front thread flank 31 has a minimum radius of curvature rv of at least 0.2 mm.

The rear thread flank 31 has a minimum radius of curvature rh of at most 0.1 mm.

The rear thread flank 31 encloses an angle g in the range from 60° to 90° with the outer circumference of the core of the bolt 2 .

The rear thread flank 31 can in particular be oriented perpendicularly to the core of the bolt 2 .

The first section 7a of the anchoring section 7 is arranged in particular in the area of the first end 5 . It can only extend over a partial area of the anchoring section 7 . In this case, the anchoring section 7 has a second section 7b. The thread in the second section 7b can be designed differently from the thread in the first section 7a. The thread in the second section 7b can in particular be designed as a thread with symmetrical thread flanks. In particular, it can be designed as a trapezoidal thread.

The first section 7a can also extend over the entire length of the anchoring section 7 .

Like in the 6 is shown as an example, the anchoring device 1 can be formed in one piece. In particular, it is possible to form the transition section 9 in one piece with the anchoring section 7 .

It is also possible to form the bridging element 3 in one piece with the transition section 9 and the anchoring section 7 . In principle, this is also possible in the case of the previously described embodiments.

The eruption element 3 can have a hexagonal outer circumference. It can also have a circular outer circumference. This is also possible in the previously described embodiments.

The surging element 3 is designed with sharp edges on the peripheral side, in particular at its second end 6 opposite the first end 5 . The radius of curvature rü of the overflow element 3 in the area of the peripheral delimitation of the second end 6 is in particular at most 0.1 mm.

The effervescence element 3 can in particular have an outer peripheral surface in the shape of a cylindrical shell, in particular an outer peripheral surface in the shape of a circular cylindrical shell.

The different details of the variants, which are based on the 1 until 3 , 6 and 7 or have been described without reference to a figure can be freely combined with one another. In particular, the one-, two- or multi-part design of the bolt 2 is independent of the geometric details of the transition section 9 and/or the force transmission element 10 and/or the bridging element 3 and independent of the details of the thread on the anchoring section 7.

The following is a method of anchoring a platform or lifeline in a tree. Of course, the method can be used accordingly for anchoring other constructions in trees or wooden beams.

First, the anchoring device 1 with the bolt 2 and the bridging element 3 is provided.

A hole is then drilled into the wood, particularly into the trunk of the tree. Here, a core hole 20 can first be introduced into the wood. This can then be made into a stepped bore 19 . The stepped bore 19 can be produced in particular with the aid of a stake drill.

The step bore 19 can be introduced in a single bore step or in two successive bore steps.

The stepped bore 19 has a contact step 21 .

The core bore 20 is preferably cleaned, in particular disinfected.

The outer part of the stepped bore 19 has a depth t which is greater than a distance d _k of the innermost region of the cambium 22 from the outer circumference 23 of the tree 24, ie from the outer surface of the tree bark. In the 4 Annual ring boundaries 25 are shown as an example.

Before the anchoring section 7 is screwed into the core bore 20 , a sealing agent 26 , in particular a mixture of tree resin and wax, is preferably introduced into the core bore 20 . As a result, a seal, in particular an airtight seal, of the core bore 20 can be achieved.

A bolt guide 27 can preferably be applied to the anchoring section 7 for precise introduction of the bolt 2 into the stepped bore 19 . The bolt guide 27 is divided into two. It can also be made in several parts. It can be slipped onto the anchoring section 7 . In the attached state, the bolt guide 27 has, in particular, an outer circumference which corresponds to that of the flashing element 3 .

The bolt 2 is screwed into the stepped bore 19. In particular, the bolt 2 is screwed into the stepped bore 19 far enough for the transition section 9 to seal off the core bore 20 from the outside. In particular, the bolt 2 is screwed into the core bore 20 far enough for the outer end of the transition section 9 to come to lie level with the contact step 21 . The transition section 9 is then located at the very end of the core bore 20.

A sealant, in particular a mixture of tree resin and wax, can also be introduced into the stepped bore 19 in the area of the contact step 21 . In this way, a tight connection, in particular a liquid-tight and/or air-tight connection, can be produced between the overflow element 3 and the stepped bore 19 . In particular, this reduces the risk of liquid and/or vermin being able to penetrate into the stepped bore 19 .

In particular, a torque wrench can be used to screw the bolt 2 into the core bore 20 . The bolt 2 can thus be screwed into the core bore 20 with a predetermined torque. In order to screw the bolt 2 into the core bore 20 , a screw-in adapter can be screwed onto the coupling section 8 in particular.

In order to attach further fastening elements, for example a threaded rod 28 , the bridging element 3 is screwed onto the coupling section 8 . The flashing element 3 can be connected to the bolt 2 before or after the bolt 2 is screwed into the core bore 20 .

After the anchoring device 1 has been installed, the tree 24 can overgrow the bridging element 3 . The tree 24 can overgrow the overgrowth element 3 in particular due to growth of reaction wood. It has been shown here that it is advantageous that the anchoring device 1 does not exert any pressure on the cambium 22 of the tree 24 . The growth of the tree 24 is only minimally affected.

A method for producing the anchoring device 1 is described below.

To produce the anchoring device 1, a blank is provided with a length that corresponds to the total length l ₂ of the bolt 2 and a diameter. A thread is then introduced into the blank to form the anchoring section 7 . Here, the diameter of the blank is reduced by a maximum of 10%.

In other words, only a very small amount of material must be removed.

A turning method, in particular a CNC turning method, can be used to produce the thread 11 of the anchoring section 7 .

The bolt 2 can thus be produced very precisely, quickly and inexpensively.

A two-part or multi-part design of the anchoring device 1 also allows existing tree screws to be retrofitted.

Claims (11)

Having device (1) for anchoring platforms in trees 1.1. a bolt (2). 1.1.1. a bolt axis (BA) and 1.1.2. an anchoring section (7) extending from a first end (5) counter to a screwing-in direction (4a) and 1.2. with an overflow element (3). 1.2.1. an at least partially prismatic, circular-cylindrical or truncated cone-shaped overflow body and 1.3. a force transmission element (10) tapering counter to the screwing direction (4a), 1.4. wherein the anchoring section (7) has a thread (11) which has asymmetrical thread flanks (30, 31) at least in a first section (7a), and 1.4. wherein the bridging element (3) has a recess (16), the shape of which is adapted to the conical shape of the force transmission element (10) in such a way that a positive connection can be established between the bridging element (3) and the force transmission element (10). Device (1) according to claim 1 , characterized in that the angle of convergence of the recess (16) is in the range of 1° to 30°. Device (1) according to one of the preceding claims, characterized in that the force transmission element (10) is constructed in one piece with the bolt (2). Device (1) according to one of the preceding claims, characterized in that a depth of the recess (16) is just as large or slightly less than the extension of the conical section of the force transmission element (10) in the longitudinal direction (4). Device (1) according to one of the preceding claims, characterized in that the thread (11) has thread flanks (30), at least in the first section (7a), which are rounded on their side facing the first end (5) and on their side facing the first end (5) are sharp-edged, at least in the first section (7a) a front thread flank (30) has a minimum radius of curvature (rv) and a rear thread flank (31) has a minimum radius of curvature (rh), where the following applies: rv : rh ≥ 2 Device (1) according to one of the preceding claims, characterized in that the bolt (1) has a coupling section (8) extending parallel to the longitudinal direction (4), the bridging element (3) being detachably connectable to the coupling section (8) and /or characterized in that the bolt (2) has a transition section (9) which is arranged in the longitudinal direction (4) between the anchoring section (7) and the coupling section (8) and has an outer diameter (d ₇ ) which is greater than a Core diameter (d _7K ) of the anchoring section (7) and/or the coupling section (8). Comprising an overflow element (3) for a device (1) according to any one of the preceding claims 7.1. an overflow body 7.1.1. with a conical recess (16) arranged at a first end in the overflow body and 7.1.2. internal threads (15) extending axially from a second end opposite the first end. Overflow element (3) according to claim 7 , characterized in that the overflow body is formed at its second end with sharp edges on the peripheral side. Method for anchoring a platform in a tree, comprising the following steps: 9.1. Providing a device (1) according to one of Claims 1 until 6 , 9.2. Introducing a stepped bore (19) in a tree, 9.3. Screwing the anchoring section (7) of the bolt (2) into the stepped bore (19), 9.4. wherein the overflow element (3) comes to rest on a contact step of the stepped bore (19). procedure according to claim 9 , characterized in that a region of the stepped bore (19) surrounding the anchoring section (7) is sealed when the bolt (2) is screwed in. Method for producing a device (1) according to one of Claims 1 until 6 comprising the following steps: 11.1. Providing a blank with 11.1.1. a length which corresponds to the total length of the bolt (2) and 11.1.2. a diameter, 11.2. introducing a thread (11) into the blank to form the anchoring section (7), 11.3. the diameter of the blank being reduced by a maximum of 10% when the thread (11) is introduced, 11.4. Providing an overflow element (3) according to one of Claims 7 until 8th .

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