AT16212U1 - Height-adjustable pedestal - Google Patents

Abstract

The invention relates to a height-adjustable pedestal bearing (1) comprising a lower part (2), a middle part (3) and a top part (4), which are arranged along a common vertical main axis (5) and which each have a lower side (6), an upper side (7) and at least one outer radial surface (8), and which at least on the lower or upper side (6, 7) at least one helically wound, a slope (9) having, form and functionally complementary support surface area (10) in that the support surface region (10) of the lower part (2) is cooperatively formed on its upper side (7) with the at least one corresponding support surface region (10) of the adjacently arranged central part (3), and the support surface region (10) of the upper part (4) its underside (6) is cooperatively formed with the at least one corresponding support surface region (10) of the adjacently arranged central part (3), and wherein at least one middle part (3) is formed which has at least one support surface region (10) on its underside (6) and upper side (7), wherein the support surface region (10) of the underside (6) coincides with the at least one corresponding support surface region (10) of the Bottom part (2) cooperatively and with respect to the lower part (2) is rotatable, and the support surface area (10) of the upper side (7) with the at least one corresponding support surface area (10) of the upper part (4) or another central part (3) cooperating and is formed rotatable relative to the upper part (4) or the further middle part (3).

Description

Description: The invention relates to a height-adjustable pedestal bearing, comprising a lower part, at least one middle part and an upper part for use as level compensation between a substrate and a support floor.

Such support bottoms can also be used in addition to double or assembly floors, e.g. Plates or frame structures for plate or floor elements.

Above all, support bearings are known which use support plates for receiving the support base and whose height adjustment is effected via a nut / spindle arrangement, as disclosed, for example, in EP 1840296 A2.

Also known are pedestal bearings which consist of height-adjustable support halves whose mutually facing sides have complementary, helically wound oblique planes. As disclosed in DE 3926978 C1, an additional inclined plane, inserted between two inclined planes of a support half, form a tongue and groove arrangement which is to form a reliable transverse guide. Similarly, it is disclosed in EP 2101011 B1 that by the arrangement of the outer walls and inner pitches a guide of the identically shaped support halves can be made.

Alternatively, DE 4420807 A1 discloses a support member having two rotatable support halves, which by 180 ° staggered helical, tortuous, concentric and have the same slope form and functionally complementary surface areas. In DE 4420807 A1, a projecting guide element is provided on at least one surface region of the first support half, and a form-fitting and function-complementary recess is provided on the associated surface region of the second support half.

However, the known support bearing, which consist of two support halves and in which a height adjustment via the rotation of the first support half relative to the second support half done, however, have the disadvantage that their permissible height adjustment depends heavily on the design and arrangement of the support surface areas.

If the slope of the surface areas selected small, the height adjustment is indeed finely adjustable, but overall very limited. Alternatively, a relatively large height adjustment could be achieved by choosing a relatively large slope of the surface areas, but both the stability of the pedestal in the axial and especially radial direction can be affected and a good adjustability of the pedestal is adversely affected.

The object of the present invention was to overcome the disadvantages of the prior art and to provide a pedestal bearing, by means of which a user is able to a simple and precise, preferably stepless, height adjustment at the same time relatively large Höhenverstellbereich make.

This object is achieved by a height-adjustable pedestal bearing, comprising a lower part, a central part and a top, which are arranged along a common vertical main axis, and which each have a bottom, an upper surface and at least one outer radial surface, and which at least the support surface region of the lower part is cooperatively formed on its upper side with the at least one corresponding support surface region of the adjacently arranged central part, and the support surface region of the upper part on its Underside is cooperatively formed with the at least one corresponding support surface region of the adjacently arranged central part, and that at least one central part is formed, which on its underside and top The support surface region of the underside with the at least one corresponding support surface region of the lower part zusammenwir kend and rotatable relative to the lower part is formed rotatably, and the support surface area of the upper side with the at least one corresponding support surface area of the upper part or another middle part cooperating and opposite to the at least Upper part or the further middle part is formed rotatable.

The advantage of the invention Stelzlagers is thus in the embodiment of rotatable relative to the lower part designed at least one Mitteilteils, as well as the equally rotatable relative to the lower part or the adjacently arranged at least one middle part designed upper part. By using at least one such middle part, as well as a corresponding upper part for the pedestal a telescopic height adjustment is achieved, which can be adjusted very precisely.

In the context of the present invention, the term "supporting elements" as a synonym for the lower part, the at least one middle part, as well as the upper part used at a suitable location to avoid unnecessary repetition of the list of said supporting parts of the pedestal. In an analogous manner, the term "supporting elements" is used in the description of the functions and possible arrangement of the lower part, the at least one middle part and the upper part relative to each other.

The corresponding support surface areas adjacently arranged support elements of the pedestal bearing are formed in the manner described and functionally complementary and thus cooperatively formed, whereby a precise adjustment of the height of the at least one middle part relative to the lower part, or analogous to the upper part relative to the at least one middle part, each other is very easy to adjust. In the case of several middle parts these are also designed to cooperate with each other in the same way. Due to the interaction of the height adjustment of the at least one central part and the upper part, a relatively large overall height adjustability of the pedestal bearing is made possible.

The support elements have an outer concentric boundary surface, which is referred to by its same radius from the common vertical main axis as a radial surface. It is within the scope of the invention that the corresponding support surface areas of the support elements can be formed completely. Likewise, the support surface areas may be divided into a plurality of subregions, that is to say segmented, in each case over a defined angular range in the circumferential direction, which in total occupy the entire circumference of the support elements.

The pedestal bearing according to the invention can even in the extended state, ie by rotation of at least one central part and the upper part so that the largest height adjustment is utilized by a segmented design of the support surface areas within the radial surfaces have a good assurance against displacement of the individual support elements in the radial direction ,

The support surface areas have a pitch, which must be the same for the corresponding support surface areas arranged adjacent cooperating support elements. It has been found that the use of relatively shallow slopes of less than 30 °, preferably less than 20 °, may be sufficient to achieve a sufficiently high friction with a suitable material pairing of the cooperating support elements, which avoid accidental pushing together under axial load of the pedestal ,

Furthermore, it may be expedient if the lower part, the at least one central part and / or the upper part at least on a lower and / or upper side helically wound, having a slope, form and functionally complementary guide grooves or at least one Führungsfortsatz, wherein the lower part has on its upper side at least one guide groove for receiving at least one corresponding guide extension of the adjacently arranged central part, and wherein the upper part has on its underside at least one guide extension for engagement in the at least one corresponding guide groove of the adjacently arranged central part, and wherein the at least a middle part has on its underside at the bottom at least one guide extension for engagement in the at least one corresponding guide groove of the adjacently arranged lower part, and wherein the at least one middle part at the top at least one F guide groove for receiving the guide has at least one corresponding extension of the adjacently arranged upper part and the other central portion.

In the context of the application, the term "guide element" may refer to both a guide groove or a guide extension cooperating therewith. The term "guide element" is used where appropriate to avoid unnecessary repetition of the listing of guide groove and guide extension. By the formation of guide elements, ie guide grooves on the underside of the at least one central part and / or the upper part, as well as complementarily designed guide extensions on the upper side of the adjacent lower part and / or the at least one middle part, an additional safeguard against radial displacement is achieved. The guide groove can be closed in the circumferential direction to form a safeguard against unintentional "overwinding". The corresponding guide extensions can for example be designed as a pin, pin, or narrow web.

Further, it can be provided that the at least one shape and function complementary guide or the at least one guide extension of the lower part, the at least one middle part and / or the upper part are arranged radially further inboard than the support surface areas.

The arrangement of the guide elements within the support surface areas, a compact design of the pedestal can be achieved. As a result, furthermore, the support surface areas can be chosen sufficiently large so that the largest possible axial load of the pedestal bearing is achieved.

In addition, it can be provided that the at least one shape and functionally complementary support surface region of the lower part, the at least one middle part and the upper part and / or the at least one guide segmented in the circumferential direction, and thus each an angular range of 87.5 ° up to 350 °, are formed.

Due to the segmented design of the support surface areas on the top or bottom of the support elements, the introduction of force in the vertical direction can be divided into several support surface areas. Especially in the "extended" state of the pedestal bearing decreases in contact surface of the corresponding support surface areas of adjacent support elements, whereby the local surface pressure increases to the loaded support surface areas. Therefore, it is particularly advantageous for large expected axial loads to apply the load distributed over the circumference of the cooperating support surface areas better, which is made possible by the described measure of the segmentation in a simple manner.

It is also conceivable that a plurality of helically wound, having a slope, form and functionally complementary support surface areas, offset from one another at an angle in the circumferential direction and adjacent to each other in the radial direction are provided on the respective support elements. This measure allows a further maximum load capacity of the pedestal bearing in the axial direction.

Analogous to the above-described segmentation of the support surface areas, it may be advantageous to form the guide segments segmented.

Also advantageous is an expression, according to which it can be provided that the at least one guide groove is arranged offset by 45 ° to 90 ° to the at least one support surface region of the lower part, the at least one middle part and / or the at least one upper part in the circumferential direction ,

By displacing the guide groove relative to the support surface area in the circumferential direction by a predetermined angle, an additional securing of the support elements against displacement in the radial direction can be achieved.

According to a development, it is possible that the slope of the helically wound, form and functionally complementary support surface areas of the corresponding support surface areas of the lower part and middle part different, especially larger, is opposite to the slope of the corresponding support surface areas of central part and upper part.

This embodiment allows in a simple manner a very precise adjustment of the height of the pedestal bearing with different "coarse" or "fine" adjustability of at least one central part relative to the lower part, or of the upper part relative to the at least one central part. This allows two different gradations to be used to adjust the height. In the exemplary case of a larger pitch of the support surface areas of the lower part and the cooperating middle part, relative to a relatively lower slope of the support surface areas of the upper part and the cooperating central part, the slope of the lower part thus corresponds to a "coarse adjustment", while the upper part allows a "fine adjustment" , The reverse case is of course also conceivable.

Furthermore, it may be expedient if the support surface areas of the lower part, the at least one middle part and / or the upper part a plurality of locking elements, in particular stages have.

The latching elements may be formed, for example, as a form complementary steps on the surface of the support surface areas. Such steps have a smaller pitch than the mean value of the respective support surface area and can be implemented over the width of a support surface area. Likewise, all kinds of latching projections or latching recesses are conceivable as latching elements. As a latching extension outstanding elevations are meant compared to the level of the support surface area. Similarly, with recessed depressions relative to the level of the support surface area of the cooperating support element recessed recesses meant, which are formed cooperatively with the latching projections. Such locking elements have the advantage that discrete height adjustments of the pedestal are adjustable. Moreover, such locking elements by the "locking" an additional rotation against unwanted "collapse" of the pedestal is. Thus, a greater slope of the support surface areas compared to "smooth" support surface areas without locking elements allows. In addition, the rotation of the support elements relative to each other by "clicks" of the cooperating locking elements can also be perceived acoustically. This can e.g. allow the view hidden, but correct adjustment of the height of such a pedestal bearing, since the user can determine the height by counting the "clicks" of the at least one central part or the upper part.

In addition, it can be provided that the number of locking elements of the corresponding support surface areas of the lower part and the adjacently arranged central part different, in particular lower, compared to the number of locking elements of the corresponding support surface areas of the upper part and the adjacently arranged central part.

By a different number of locking elements as described above, an additional adjustment possibility can be created, since the number of locking elements discrete steps for adjusting the height, respectively, the associated rotation corresponds. In the exemplary case of a smaller number of locking elements of the support surface areas of the lower part and the cooperating central part, relative to a relatively larger number of locking elements of the support surface areas of the upper part and the cooperating central part, the locking elements of lower part / middle part thus correspond to a "coarse adjustment", while the Locking elements of upper part / middle part allow a "fine adjustment". The reverse case is of course also conceivable.

Furthermore, it can be provided that the radius to the outer radial surface of the lower part, at least one central part and / or the upper part relative to the radius to the outer radial surface of the adjacently arranged lower part, at least one central part and / or the upper part differently, in particular in the direction of common vertical main axis decreasing, are formed.

Although the radii to the radial surface, so the outer diameter of all supporting elements of the pedestal can be the same, it may be advantageous if the radii of adjacent support elements are different. In this case, for example, the radius of the central part may be smaller than the radius of the lower part and the upper part, whereby a kind of "sandwich construction" tion is achieved. As a result, a very compact design can be made possible. Alternatively, the decrease of the radius to the radial surface, along the vertical main axis viewed from the lower part, is possible. This can be a measure to define the largest possible contact surface of the pedestal bearing on the underside of the base, whereby the tendency to tilt of the pedestal can be reduced.

According to a particular embodiment, it is possible that the at least one central part and / or the upper part at the top have radial extensions and / or radial recesses.

The radial extensions can u.a. are referred to as tabs, flat gripping elements, wings and the like and thus have a larger diameter than the respective central part or upper part. As a result, a tool-free rotation by attacking the radial extensions can be achieved even in the contracted state of the pedestal bearing. Similarly, it is possible to provide recesses in the radial direction in the region of the upper side of the support element on the radial surface, which recesses can be gripped by the user relatively easily with the fingers. Due to the radial extensions and / or recesses, the pedestal can thus be adjusted without tools.

According to an advantageous development can be provided that the upper part has a concave support surface for receiving an adapter plate or a coupling element at the top.

The concave support surface may be formed symmetrically about the vertical main axis and, for example, correspond to the shape of a spherical segment. In this way, the top of the upper part forms a kind of bearing shell for an adapter plate or a coupling element. Due to the concave shape, the adapter plate or the coupling element can thus be mounted so as to be pivotable at least in one direction relative to the vertical main axis. This allows the compensation of unevenness of the ground relative to a support floor, which can be arranged resting on the top of the adapter plate. Similarly, the Kop pelement take over this spatial compensation function and an adapter plate can be arranged on the coupling element. In addition, at the top of the upper part, a shoulder may be provided, which limits the highest permissible tilting of the coupling element and / or the adapter plate. The tilt angle can be up to 10 °, preferably up to 5 °, particularly preferably up to 3.5 °.

In particular, it may be advantageous if the adapter plate for concave support surface of the upper part form and function complementary, as well as pivoting and / or rotatable to the main axis is formed.

By the possibility of pivotally supporting the adapter plate can easily be an angle compensation of the adapter plate against a e.g. inclined level of the underground can be achieved. Due to the convex-shaped underside of the adapter plate, a non-shiftable mounting of the adapter plate in the upper part can also be achieved. In addition, the adapter plate on the top spacer elements and / or Einrichthilfen have the support floor. As spacer elements and / or Einrichthilfen can e.g. T-shaped or cross-shaped elevations are used, which facilitate the position of the individual elements of a support floor at a defined distance from each other. Likewise, a simple alignment of the coupling element, and thus any spacers and / or Einrichthilfen to the vertical main axis is possible without the height of the pedestal must be adjusted.

Alternatively, it can be provided that the coupling element to concave-shaped

Support surface of the upper part form and function complementary, as well as pivoting and / or rotatable to the main axis is formed.

Such a coupling element may be advantageous since it can be used to receive an adapter plate with a flat bottom. In such a case, the pivoting or. rotatable storage taken over by the coupling element. The corresponding adjacent to the support floor adjacent adapter plate with a flat bottom, can thus also be formed with spacers and / or Einrichthilfen. The advantages of this arrangement can be seen analogously to the description of the above adapter plate.

Furthermore, it can be provided that the lower part, the at least one central part and the upper part each have a central recess in the region of the main axis.

By a central recess, such as a hole, a fastening means for fixing the pedestal bearing on the ground in a simple manner can be mounted from above. Slipping or shifting of the pedestal bearing with lateral or obliquely introduced from above load is thereby efficiently avoided. It is also conceivable that the central recess is designed in the form of an elongated opening, whereby a slight displacement along the longitudinal axis of the opening is made possible. This can be helpful in particular when setting up the position, ie before fixation.

In addition, it can be provided that the upper part at the top has at least one recess suitable for receiving a tool.

In some cases, it may be advantageous if the upper part can be adjusted from above for adjusting the height of the pedestal bearing. This can be advantageous, for example, in the assembly of pedestals in corner areas, or in local repairs to support floors, where limited lateral access to the pedestal is possible. Such a depression may e.g. be designed as a over the center of the upper part extending groove for receiving a flat object. Likewise, however, also cross-shaped, or even paired openings, conceivable in which form-fitting a Phillips screwdriver, a wrench, or the like, can be applied to the rotation of the upper part.

Also advantageous is an expression, according to which it can be provided that the adapter plate and / or the coupling element has a plurality of openings which are formed extending continuously from the top to the bottom of the adapter plate or the coupling element.

The plurality of openings allow the fixation of the adapter plate and / or the coupling element in a certain position. A set tilt angle of the adapter plate and / or the coupling element is thus easily fixed by a fastener. This can be done in the simplest case via a nail or a screw which connects the adapter plate and / or the coupling element with the upper part and / or the at least one middle part and / or the lower part and / or with the substrate. The plurality of openings may be arranged concentrically around the center position of the adapter plate and / or the coupling element and provided with predetermined indices. As a result, indices of the openings, e.g. designate the tilt angle or an angle indication, which facilitates precise and rapid assembly without the use of additional measuring instruments.

According to a development, it is possible that the lower part has a flange on the underside, the radius of which is at least 10% larger than the radius to the radial surface on the upper side of the lower part.

By continuing the footprint of the lower part and thus the entire pedestal is increased, whereby an increase in security against tilting and / or slipping of the pedestal can be achieved.

Furthermore, it may be expedient if the flange of the lower part has a plurality of lower part openings.

The lower part openings may be performed in the form of holes or even elongated slots. In this way, the lower part can be fixed separately on the ground in a simple manner by means of one or more fastening means. As a result, the security against tilting and / or slipping of the pedestal can be additionally increased.

In addition, it can be provided that the lower part and / or the at least one middle part and / or the upper part and / or the coupling element and / or the adapter plate of a vibration-damping material having an E-modulus of less than 45 GPa, preferably less than 20 GPa, in particular plastic, are made.

By using a material which has a lower modulus of elasticity than the ground, an attenuation of shocks in the axial direction can be achieved by the pedestal bearing. The support elements, ie the lower part, the at least one central part, the upper part, the coupling element and / or the adapter plate can be made of the same or different materials. The described arrangement of the support elements and the possible coupling element or the adapter plate creates a plurality of interfaces between the individual components. At each of these interfaces, the dissipation of impact energy is enabled. Further, for vibration damping, additional means such as rubber inserts or the like may be disposed at the interfaces to further increase this effect.

For a better understanding of the invention, this will be explained in more detail with reference to the following figures.

In each case, in a highly simplified, schematic representation: FIG. 1 shows an exploded view of an exemplary embodiment of a pedestal bearing; Fig. 2 oblique view of an embodiment of a middle part and a top part; Fig. 3 embodiments of the upper side of an upper part (a), an upper part in combination with an adapter plate (b), and an upper part in combination with a coupling element and an adapter plate (c); Fig. 4 embodiments of a central part or upper part with radial extensions (a), as well as radial recesses (b); Fig. 5 exploded view of an embodiment of a pedestal bearing; 6 is a sectional view of an embodiment of a pedestal bearing.

By way of introduction, it should be noted that in the differently described embodiments, the same parts are provided with the same reference numerals and the same component names, the disclosures contained throughout the description can be mutatis mutandis to the same parts with the same reference numerals or the same component names. Also, the location information chosen in the description, such as top, bottom, side, etc. related to the immediately described and illustrated figure and these position information in a change in position mutatis mutandis to transfer to the new location.

FIG. 1 shows an exemplary embodiment of an inventive pedestal bearing 1 in an exploded view. A lower part 2, a middle part 3, and an upper part 4 are each shown in an oblique view in order to explain the functioning of the corresponding lower sides 6a, 6b, 6c and upper sides 7a, 7b, 7c and better. The lower part 2, a middle part 3, as well as an upper part 4, also generically referred to as support elements 2, 3, 4, are arranged along a common vertical main axis 5. The lower part 2 has on its upper side 7a at least one helically wound, a slope 9 having, form and functionally complementary support surface area 10. This support surface area 10 can be divided into two or more partial areas, or as in FIG. into four sections, divided, so be segmented. The support surface regions 10 can also be arranged offset in the radial direction and / or circumferential direction. This applies analogously to the middle part 3, as well as the upper part 4 in the same way.

On its own reference numerals for the different support surface areas 10, and the

Slope 9 in the representation of the respective support elements 2, 3, 4 is omitted for clarity.

The support surface areas 10 of the lower part 2 and the middle part 3 are opposite each other, that is, corresponding, formed. Similarly, the support surface areas 10 of the middle part 3 and the upper part 4 complement each other in a form and function complementary manner. In the assembled state thus a small total height of the pedestal bearing 1 can be achieved when the support elements 2, 3, 4 shown are screwed or plugged into each other. If the middle part 3 and / or the upper part 4 are rotated in the circumferential direction relative to the lower part 2, the cooperating support surface regions 10 slide adjacent support elements 2, 3, 4 on each other and increase the total height of the pedestal 1 according to the slope 9 of the support surface areas 10th

Due to the special design of the central part 3, which has formed on its top and bottom bb 6b such support surface areas, a cooperation with the lower part 2 and the upper part 4, and thus the support surface areas 10 allows. In an analogous manner further middle parts 3 can be used with corresponding support surfaces 10, whereby the entire height adjustment of the pedestal bearing 1 can be further expanded.

As shown in Fig. 1, the lower part 2, the middle part 3 and the upper part 4 each have a radius 16a, b, c to their outer radial surfaces 8a, b, c, which for the sake of clarity only shown for the lower part 2 becomes. With the radial surfaces 8a, b, c, the lateral surfaces of the lower part 2, the at least one middle part 3, respectively, of the upper part 4 are designated. These radial surfaces 8a, b, c can each have a height that is the same in the circumferential direction in the direction parallel to the main axis 5 and thus form an outer boundary for the support surface regions 10 in the radial direction.

In Fig. 2, a further possible embodiment is shown, which in addition to the support surface areas 10 on the lower sides 6 and / or top 7 mutually form and functionally complementary guide elements in the form of guide grooves 11 and Führungsfortsätzen 12 represents. The illustrated example in FIG. 2 shows guide grooves 11 on the upper side 7b of a central part 3 and guide projections 12 cooperating therewith on the underside 6c of the upper part 4. The person skilled in the art is made clear that the guide elements 11, 12 shown are analogous to the upper part 7a , b, c or undersides 6a, b, c of all support elements 2, 3, 4 can be provided. Likewise, the skilled artisan recognizes that the guide elements 11,12 also in the reverse direction of action, ie guide grooves 11 and on an underside 6 of a support member 2, 3, 4 and guide extensions 12 cooperating therewith on the top 7 of the adjacent support member 2, 3, 4th can be provided. In the selected representation in Fig. 2, the at least one helically wound, a slope 9 having, form and function complementary guide 11 are formed as a segmented, two-part guide grooves 11 which are arranged in the circumferential direction such that they each have an angle of about 180 ° describe.

Furthermore, it can be seen in FIG. 2 that in the embodiment shown, the guide groove 11 or the at least one guide extension 12 of the corresponding support elements 2, 3, 4 are arranged radially further inwards than the support surface areas 10. It can likewise be seen from FIGS. 1, 2 and 5 that the support surface regions 10 and / or the guide elements 11, 12 are segmented, that is to say each can be formed over a predefined angular region 13. An angular region 13 of 180 ° can be seen in particular for the support surface regions 10, or for the guide elements 11, 12 from the illustration in FIG. 2.

In addition, it can be seen in FIG. 2 that the at least one guide groove 11 is offset from the at least one support surface region 10 of the lower part 2, the at least one middle part 3 and / or the at least one upper part 4 by approximately 90 ° in the circumferential direction is.

Likewise, it can be shown by way of example in FIG. 2 that the support surface regions 10 of the support elements 2, 3, 4 have a multiplicity of latching elements 15. The design of these locking elements 15 is selected in the illustrated embodiment as stages, which form substantially horizontal step surfaces on which the corresponding support surface areas 10 can support each other under load in the axial direction.

The expert recognizes from the illustrations of Fig. 1, Fig. 2, and Fig. 5 clearly that the slope 9 and / or the number of any locking elements 15 of the support surface areas 10 cooperating support elements 2, 3, 4 are coordinated. However, the pitch 9 and / or the number of locking elements 15 may be formed differently on the lower 6b and upper sides 7b of a middle part 3. Likewise, in such a case, forming different pitch pairings, such as e.g. Lower part 2 with the nearest middle part 3 and the middle part 3 with the upper part 4, the slope 9 and / or the number of locking elements 15 of the corresponding support member 2, 3, 4 adapted thereto.

It can further be seen from the comparison of the exemplary illustrations in FIGS. 1, 2, 5 and 6 that the radius 16 a, b, c to the outer radial surface 8 a, b, c of the support elements 2, 3 4 may be the same, but the radii 16a, b, c may also be different.

FIGS. 3a-c show different embodiments of a top part 4.

In the simplest case, as shown in Fig. 3a, the upper surface 7c of the upper part 4 normal to the main axis 5, ie substantially horizontally, be formed and as shown, possibly spacer elements and / or Einrichthilfen and / or surface structures relative to the thereof have to be laid support floor.

However, it is also possible that the upper side 7c of the upper part 4 has an at least partially concave support surface 20. This bearing surface 20 does not have to be formed over the entire area of the upper side 7 c, but may be suitable for mounting an adapter plate 19, as shown in the example shown in FIG. 3 b, whose bottom 6 d is convex. As a result, the adapter plate 19 is pivotally and / or rotatably received in the support surface 20 of the upper part 4. As in the example shown, the adapter plate 19 may comprise an e.g. have substantially square or rectangular shape.

Furthermore, an exemplary embodiment can be seen from the illustration in FIG. 3b, wherein the upper part 4 additionally has at least one recess 23 around a central recess 22 on the upper side 7, which serves to receive a tool.

A further embodiment of an upper part 4 is shown in Fig. 3c, wherein this upper part 4 is suitable for receiving a coupling element 21. The coupling element 21 is so convexly formed on its underside 6e that it is formed with the concave support surface 20 of the upper part 4 form and function complementary. As can be seen in the same illustration, the coupling element 21 for receiving an adapter plate 19 have lateral boundaries. Furthermore, in Fig. 3c, a plurality of openings 24 can be seen, which penetrate the coupling element 21 in the axial direction. In addition to the openings 24, indexes 27 for indicating e.g. a tilt angle or an angle indication, whereby a precise and quick installation without the use of additional measuring instruments is facilitated. The indices 27 can be imprinted or also formed as recesses in the upper side 7e of the coupling element 21.

As can be seen in Fig. 4 a, b, the middle part 3 for tool-free adjustment also easy to grasp extensions 17 and / or recesses 18 have. As shown in Fig. 4a, the projections 17 may be formed on the upper side 7b of the central part 3 so that they extend in the radial direction beyond the radius 16 addition. In this way, a gripping of the central part 3 is made possible even in "retracted" state of the pedestal bearing 1 in a simple manner. As another embodiment, a plurality of recesses 18 are shown on the radial surface 8b in Fig. 4b. The recesses 18 may be formed penetrating the radial surface 8b, ie in the form of holes, or as superficial recesses 18. The examples of extensions 17 and / or recesses 18 shown can be transferred analogously for a plurality of middle parts 3 or for the upper part 4 by a person skilled in the art.

In Fig. 5, an embodiment is shown, which shows a combination of lower part 2, a middle part 3, an upper part 4, and a coupling element 21 and an adapter plate 19. The exploded view shows a common main axis 5 along which said components of the pedestal bearing 1 are shown axially spaced. All support elements 2, 3, 4, as well as the coupling element 21 and the adapter plate 19 have in the selected form of representation a central recess 22, which may have different radial dimensions for the individual parts. Such a central recess 22 can also be seen in FIGS. 1, 2, 3a-c, and 4a, b.

Analogous to the representation of the upper part 4 in Fig. 4b, a recess 23 in the region of the central recess 22 is also visible in Fig. 5, which can be used for rotating the upper part 4 by means of a tool from above.

Furthermore, an example of a lower part 2 is shown in FIG. 5, on the underside 6a of which a flange (28) is formed, which has an at least 10% larger radius 16 than the radius to the radial surface 8a on the upper side 7a of the lower part 2 having. In addition, in Fig. 5, a plurality of lower part openings (25) are shown, which penetrate the flange 28 and the lower part 2. These lower part openings 25 can be used for fastening the pedestal bearing 1 on the ground by means of various fastening means 26.

6 shows a sectional view through an embodiment of the invention Stelzlagers 1. In the illustration in Fig. 6, the pedestal 1 is seen in "retracted" state, the support elements 2, 3, 4 are thus pushed into each other or turned that a very low overall height of the pedestal 1 is set. As can also be seen in the illustration, the coupling element 21 is deflected by a tilt angle with respect to a normal to the main axis 5 of the pedestal bearing 1. The convexly shaped bottom 6e of the coupling element 21 is received in the support surface 20 of the upper part 4. The tilting of the coupling element 21 can be taken over by the adapter plate 19, which is received by the coupling element 21, whereby a leveling of the support base relative to the substrate can be achieved. As can further be seen in the sectional view in Fig. 6, a fastening means 26 is indicated, which can fix the pedestal bearing 1 on the ground. Furthermore, it can be seen in the figure that one of the openings 24 is penetrated by the fastening means 26, as a result of which the tilt angle of the coupling element 21 or the adapter plate 19 can be fixed.

The embodiments show possible embodiments, it being noted at this point that the invention is not limited to the specifically illustrated embodiments thereof, but rather also various combinations of the individual embodiments are mutually possible and this possibility of variation due to the doctrine of technical action representational invention in the skill of those skilled in this technical field.

All information on ranges of values in the present description should be understood to include any and all sub-ranges thereof, e.g. is the statement 1 to 10 to be understood that all sub-areas, starting from the lower limit 1 and the upper limit 10 are included, ie. all sub-areas begin with a lower limit of 1 or greater and end at an upper limit of 10 or less, e.g. 1 to 1.7, or 3.2 to 8.1, or 5.5 to 10.

For the sake of order, it should finally be pointed out that, for a better understanding of the structure, elements have been shown partially unevenly and / or enlarged and / or reduced in size.

REFERENCE LIST 1 Pedestal 2 Bottom 3 Middle 4 Upper 5 Main axis 6 Bottom 7 Top 8 Radial surface 9 Slope 10 Support surface area 11 Guide groove 12 Guide extension 13 Angle range

Circumferential direction 15 locking element 16 radius 17 extensions 18 recess 19 adapter plate 20 bearing surface 21 coupling element 22 central recess 23 recess 24 opening 25 base openings 26 fastening means 27 indices 28 flange

Claims (20)

claims A height-adjustable pedestal bearing (1), comprising a lower part (2), a middle part (3) and a top part (4), which are arranged along a common vertical main axis (5) and which each have a lower side (6), an upper side (7) and at least one outer radial surface (8), and which at least on the lower or upper side (6, 7) at least one helically wound, a slope (9) having, form and functionally complementary support surface area (10), characterized in that - the support surface region (10) of the lower part (2) is designed to cooperate with the at least one corresponding support surface region (10) of the adjacently arranged central part (3) on its upper side (7a), - and the support surface region (10) of the upper part (7) 4) on its underside (6c) with the at least one corresponding support surface region (10) of the adjacently arranged central part (3) is designed to cooperate, and d at least one middle part (3) is formed which has at least one support surface region (10) on its lower side (6b) and upper side (7b), wherein the support surface region (10) of the underside (6b) is connected to the at least one corresponding support surface region (10 ) and the support surface region (10) of the upper side (7b) with the at least one corresponding support surface region (10) of the upper part (4) or of a further middle part (3 ) cooperatively and with respect to the upper part (4) or the further middle part (3) is rotatable. 2. pedestal bearing (1) according to claim 1, characterized in that the lower part (2), the at least one central part (3) and / or the upper part (4) at least at a lower (6b, c) and / or top ( 7a, b) helically wound a (9) having, form and function complementary guide grooves (11) or at least one guide extension (12), - wherein the lower part (2) on its upper side (7a) at least one guide groove (11) , for receiving at least one corresponding guide extension (12) of the adjacently arranged central part (3), and wherein the upper part (4) has on its underside (6c) at least one guide extension (12) for engagement in the at least one corresponding guide groove (11) the at least one middle part (3) has on its underside (6b) at least one guide extension (12) for engagement in the at least one corresponding guide groove (11) of the adjoining central part (3) and wherein the at least one middle part on the upper side (7b) has at least one guide groove (11) for receiving the at least one corresponding guide extension (12) of the adjacently arranged upper part (4) or of the further middle part (3 ) having. 3. pedestal bearing (1) according to claim 2, characterized in that the at least one shape and functionally complementary guide groove (11) or the at least one guide extension (12) of the lower part (2), the at least one central part (3) and / or the upper part (4) are arranged radially further inward than the support surface regions (10). 4. pedestal bearing (1) according to one of the preceding claims, characterized in that the at least one shape and functionally complementary support surface area (10) of the lower part (2), the at least one central part (3) and the upper part (4) and / or the at least one guide groove (11) segmented in the circumferential direction, and thus each an angular range (13) of 87.5 ° to 350 ° engaging, are formed. 5. pedestal bearing (1) according to one of claims 3 or 4, characterized in that the at least one guide groove (11) to the at least one support surface area (10) of the lower part (2), the at least one central part (3) and / or at least one upper part (4) is arranged offset in the circumferential direction by 45 ° to 90 °. 6. pedestal bearing (1) according to any one of the preceding claims, characterized in that the slope (9) of the helically wound, form and functionally complementary support surface areas (10) of the corresponding support surface areas (10) of the lower part (2) and central part (3) , in particular larger, is opposite the slope (9) of the corresponding support surface areas (10) of middle part (3) and upper part (4). 7. pedestal bearing (1) according to any one of the preceding claims, characterized in that the support surface areas (10) of the lower part (2), the at least one central part (3) and / or the upper part (4) has a plurality of latching elements (15), in particular stages. 8. pedestal bearing (1) according to claim 7, characterized in that the number of latching elements (15) of the corresponding support surface areas (10) of the lower part (2) and the adjacently arranged central part (3) different, in particular lower, is compared to the number of Latching elements (15) of the corresponding support surface areas (10) of the upper part (4) and the adjacently arranged central part (3). 9. pedestal bearing (1) according to any one of the preceding claims, characterized in that the radius (16a) to the outer radial surface (8) of the lower part (2), at least one central part (3) and / or the upper part (4) relative to the radius (16b) to the outer radial surface (8) of the adjacently arranged lower part (2), at least one central part (3) and / or the upper part (4) differently, in particular in the direction of the common vertical main axis (5) decreasing, are formed. 10. pedestal bearing (1) according to one of the preceding claims, characterized in that the at least one central part (3) and / or the upper part (4) on the upper side (7) radial projections (17) and / or radial recesses (18) exhibit. 11. pedestal bearing (1) according to any one of the preceding claims, characterized in that the upper part (4) on the upper side (7) has a concave support surface (20) for receiving an adapter plate (19) or a coupling element (21). 12. pedestal bearing (1) according to claim 11, characterized in that the adapter plate (19) for concave support surface (20) of the upper part (4) form and function complementary, as well as the main axis (5) is pivotable and / or rotatable , 13. pedestal bearing (1) according to claim 11, characterized in that the coupling element (21) to the concave support surface (20) of the upper part (4) form and function complementary, as well as the main axis (5) is pivotable and / or rotatable , 14. pedestal bearing (1) according to any one of the preceding claims, characterized in that the lower part (2), the at least one central part (3) and the upper part (4) each have a central recess (22) in the region of the main axis (5) , 15. Pedestal bearing (1) according to one of the preceding claims, characterized in that the upper part (4) on the upper side (7) has at least one recess (23) suitable for receiving a tool. 16 pedestal bearing (1) according to one of claims 12 to 14, characterized in that the adapter plate (19) and / or the coupling element (21) has a plurality of openings (24) extending from the top to the bottom (6 ) of the adapter plate (19) and the Kop-pelements are formed continuously extending. 17. pedestal bearing (1) according to one of the preceding claims, characterized in that the lower part (2) on its underside (6) has a flange (28) whose radius (16) is at least 10% larger than the radius (16 ) to the radial surface (8a) on the upper side (7a) of the lower part (2). 18 pedestal bearing (1) according to claim 17, characterized in that the flange (28) of the lower part (2) has a plurality of lower part openings (25). 19 pedestal bearing (1) according to one of the preceding claims, characterized in that the lower part (2) and / or the at least one central part (3) and / or the upper part (4) and / or the coupling element (21) and / or the adapter plate (19) made of a vibration-damping material having an E-modulus of less than 45 GPa, preferably less than 20 GPa, in particular plastic, are made. For this 7 sheets drawings