EP2989253A1

EP2989253A1 - Structural bearing

Info

Publication number: EP2989253A1
Application number: EP14713830.9A
Authority: EP
Inventors: Christian Braun
Original assignee: Maurer Soehne Engineering GmbH and Co KG
Current assignee: Maurer Soehne Engineering GmbH and Co KG
Priority date: 2013-04-22
Filing date: 2014-03-28
Publication date: 2016-03-02
Anticipated expiration: 2034-03-28
Also published as: WO2014173621A1; DE102013104064A1; RU2665772C2; RU2015147440A; EP2989253B1

Abstract

A structural bearing (10; 31) which has a sliding body (12) with a base surface (16) and a convexly curved sliding surface in the form of a spherical portion and which has a receptacle (14) for movably holding the sliding body (12), wherein the receptacle (14) has a concavely curved receiving surface (20) in the form of a spherical portion and at least partially encloses the sliding surface (17) of the sliding body (12). The underlying object here is to provide a novel structural bearing which is designed in a particularly space-saving manner and can be used particularly flexibly. This object is achieved in that the receptacle (14) has at least one receptacle lateral surface (21; 22) which is arranged such that the receptacle surface (20) is delimited in such a way that it has a surface edge (13) which, based on the lowest point (Ta) of the concavely curved receiving surface (20), has a height which is variable in its profile in the region of the receiving lateral surface (21; 22). As a result, the bearing device (10, 31) is designed in a particularly space-saving manner in comparison.

Description

Structural bearings

The invention relates to a structural bearing, which has a sliding body with a base surface and a convex, spherical segment curved sliding surface and a receptacle for movable mounting of the slider, wherein the receptacle has a concave, spherical portion curved receiving surface and the sliding surface of the slider at least partially surrounds.

Structural warehouses generally serve the defined and at least partially restraint-free storage of structures or parts of structures. There are a variety of structural bearings known. Depending on the design and mode of operation, the bearings have a different number of degrees of freedom. For example, bearings are known which allow movement by rolling, rolling, etc., by deformation or by sliding of sliding surfaces. For building warehouses, it is desired that a translational movement in a horizontal or vertical direction is at least partially restricted in order to allow guidance or stationary storage of buildings or structural parts. The twistability, however, is often not limited. This is especially true for the use of bearings in bridges.

In the past, roller bearings _» cylindrical bearings or linear tilt bearings were frequently used. A disadvantage of these bearings is that ^"would take due to the linear contact axis of the rollers used, rollers, cylinders or the like at the respective on of the bearing a limitation of the rotatability in the transverse direction determined is .. By limiting the rotatability overloads can these bearings occur. For this reason, these bearings have not been proven and are preferably in accordance with the additional technical yield conditions and guidelines for civil engineering works of the Federal Ministry of Transport (ZTV-ING) to replace point-tilt bearings.

As Punktkippiager calotte bearings have prevailed and are now used predominantly in construction. These have a dome-shaped sliding body and a mounting would be with a correspondingly concave receiving surface for the slider on. A disadvantage of this bearing is that due to the design of the slider, the geometric shape of the bearing is already largely determined. Shoots for dome-shaped slider are formed in their base, for example, square or circular. Depending on the spatial conditions, the use of spherical bearings with great effort or for geometric reasons is not possible. This is the case, for example, in confined spaces or when exchanging longitudinal, narrow roller, cylinder or linear tilt bearings.

The invention is therefore based on the object to provide a novel structural warehouse, which is designed to save space and is particularly flexible.

This object is achieved in that the recording has at least one receiving side surface which is arranged so that it limits the receiving surface such that it has a surface edge, based on the lowest point of the concave receiving surface in its course in Area of the receiving side surface has variable height. The invention is based on the finding that for a secure mounting of the slider or the dome not necessarily a same height edge of the concave receiving surface is necessary. Thus, according to the invention, it is possible to provide only one segment of a conventional receptacle, so that the structural bearing according to the invention is designed to save space compared to bearings with "complete" receptacle.Pictureally speaking, the space-saving design of the receptacle according to the invention is achieved in that at least one partial area a known, complete recording is quasi cut away, leaving a segment of the recording remains.The receiving side surface is to a certain extent the cutting surface. This extends at least through the receiving surface.

Furthermore, the receptacle may have a side surface which has a circumferential surface edge which at least partially delimits the receiving base surface and the receiving surface. Figuratively speaking, a part of a conventional recording is separated with a cut from the recording surface to the recording base. Advantageously, this makes it possible to realize a particularly narrow base surface or base surface in the case of the recording according to the invention. Structural bearings with such a receptacle are particularly suitable for use in bridge piers.

Depending on the design and number of at least one side surface, the bearing may have various geometric shapes and is thus flexibly adaptable to different spatial conditions. For example, the receptacle may have only one side surface described above. As a result, a space-saving structural bearing, in particular for use in structures in which little or no twists are to be expected in one direction, can be provided.

Further, the receptacle has at least two receiving side surfaces, which are arranged so that they limit the receiving surface such that it has a surface edge, with respect to the lowest point of the concave receiving surface a variable in their course in the receiving side surfaces Height. An elongate shape of the receptacle can be realized in this way, which is particularly advantageous when replacing line dump bearings.

Preferably, the receptacle may have four of the side surfaces described above. As a result, the opening angle can be limited depending on the distance of the side surfaces to each other.

According to a development, at least two opposing receiving side surfaces are arranged symmetrically to the lowest point of the concave receiving surface. As a result, in the installation position of the structural bearing according to the invention, a uniform force distribution and secure mounting, at least partially by force fit, can be realized. The receiving surface effectively forms a valley into which the corresponding convex sliding surface of the slider is pressed. Furthermore, overstrain in outer peripheral areas of these curved surfaces can be prevented by a symmetrical design.

If the forces and twists to be expected are not uniform, the structural bearing has, in addition or as alternatives to the above-mentioned symmetrical side surfaces, at least two opposite receiving side surfaces, which are arranged asymmetrically to the lowest point of the concavely curved receiving surface.

As described above, line tilt bearings, roller bearings, cylinder bearings and the like are preferably replaced by point tilt bearings. These usually have a rectangular base. In order for such bearings to be replaced in a particularly simple way by the structural bearing according to the invention, the receptacle has a rectangular base surface in plan view in accordance with a further development. The sliding body may have a shape corresponding to the receptacle in order to enable a good sliding behavior, a uniform distribution of forces and a space-saving design.

In a further development, the sliding body has the shape of a segment of a spherical cap which has at least one sliding body side surface which has a variable height. As a result, the structural bearing according to the invention can be realized even more space-saving and flexible use.

For a particularly uniform force distribution and safe storage further education at least two opposing sliding body side surfaces are arranged symmetrically to the highest point of the convexly curved sliding surface of the slider.

According to a further development, at least two opposing sliding body side surfaces are arranged asymmetrically to the highest point of the convexly curved sliding surface of the sliding body in addition or as an alternative to the above symmetrical sliding body side surfaces. As a result, uneven loading of the construction worker can be taken into account.

Further, the slider has a rectangular in plan view base, so that the building warehouse according to the invention is particularly space-saving feasible and can easily replace line tilt bearings

For realization of a particularly expedient corresponding embodiment of

Slider and recording, the slider is arranged according to a development in the rest position in the building warehouse that at least one slider side surface is aligned approximately in alignment with at least one receiving side surface.

Hereby, the slider side surface and the receiving side surface may have an offset with each other. In particular, the slider side surface may protrude beyond the receiving side surface. This can be avoided that an edge of the sliding surface abuts immediately upon rotation on the receiving surface.

For a particularly good suitability for the replacement of line tilt bearings, the sliding body and / or the receptacle according to a development has or have a substantially cuboid shape. In addition, the substantially cuboid shape allows a particularly simple production of the slider and / or the receptacle, for example, from semi-finished by means of machining. For an overall particularly narrow design of the structural bearing according to the invention further education at least one side surface of the slider and / or the receptacle is arranged perpendicular to the base of the slider and / or the base of the receptacle. This also allows a particularly simple production. According to one embodiment, the slider and / or the receptacle are designed so that it meets or meets the requirements of EN 1337-7 with respect to the permissible opening angle for calottes, in particular to provide a particularly safe Punktkippiager or Punktkippgleitlager.

Slider and / or receptacle may be formed of metal, for example, steel and / or aluminum. Further, they may each have an at least partially finished (e.g., chrome, rolled, and / or painted) surface.

So that material pairings can be realized with particularly favorable sliding properties, a curved sliding plate is arranged in the receptacle in a further development. Then, the pairing of the surface of the sliding surface of the slider and the surface of the sliding plate facing it forms a sliding surface in the sense of EN 1337-2 for bearings in construction. It is also conceivable that facing surfaces of the receptacle and the slider directly a sliding surface in the sense of o.g. Form norm.

According to a development, the structural bearing has at least one planar sliding plate. As a result, not only the geometric dimensions but also the functional properties of the bearings to be replaced, for example roller bearings, can be reproduced by means of the structural bearing according to the invention. In addition to a rotation then a shift of stored structures or building parts to each other can be realized. For example, the support system of a roller bearing is retained and at the same time freedom from constraints is achieved.

The flat sliding plate is further forming the base of the recording and / or the

Base surface of the slider facing the bearing is arranged so that at least partially a floating bearing slidable mounting of the receptacle or the slider is feasible.

Preferably, the structural bearing according to the invention may comprise two sliding plates, so that a floating or displaceable mounting of sliding body and recording is feasible.

The curved and the flat sliding plate can by means of a mechanically detachable or non-detachable and / or an at least partially positive and / or non-positive Attachment to components of the structural warehouse according to the invention be fastened.

For example, the structural bearing according to the invention may have a recess as a receptacle for the planar and / or curved sliding plate. In installation position, the plane or the curved slide plate is pressed into the recess. The attachment of the curved and / or flat sliding plate should preferably be shear-resistant.

The planar sliding plate and the curved sliding plate are expediently formed from a suitable sliding material, such as PTFE, UHMWPE, polyamide and / or from a composite sliding material.

The structure bearing according to the invention further comprises at least one flat counter-plate for the flat Gleitpiatte to conveniently allow a particularly low-friction sliding.

According to a development, at least one flat Gegenpiatte is held in a Trägerpiatte. By means of the carrier plate, the dimensional stability of the sliding plates is ensured. Conveniently, the counter-plate can then be made particularly thin, for example as a polished sheet steel. As a result, a cost-effective production is also possible since only the counter-plate is made of relatively expensive sliding material.

The carrier plate has a substantially rectangular shape. As a result, as described, in particular Linienkipp- and roller bearings are particularly simple replaceable by the structural bearing according to the invention.

The support plate may be formed of metal, in particular of steel. Furthermore, the Trägerpiatte may also be formed of a pressure-resistant plastic, such as polycarbonate.

In installation position, the support plate is preferably arranged on the building side.

The counter-plate can be fastened to the carrier plate, for example, mechanically detachable or mechanically non-detachable. For example, the counter-plate can be fastened to the carrier plate by means of screws, by spots or welding and / or by adhesive.

Preferably, the counter-plate may have a rectangular shape corresponding to the carrier plate. As a result, sliding properties to a similar extent as in Linienkipp- and roller bearings with similar geometric dimensions can be realized. The Bauwerksiager invention further educating a stop on the other, so that a rotational or translational movement of the receptacle, the slider and / or at least one support plate is at least partially limited. By means of the stop, an unwanted slipping out of the receptacle and the slider over the edge of the counter-plate and an over-turning of the slider with respect to the

Prevent recording.

For example, it can be provided _» that the stop is integrally formed with the one with the support plate and / or the receptacle. The Trigerplatte may have a paragraph or leadership, which acts as a stop. The counter-plate can then have a corresponding shape by edgings.

The stop can also be designed separately and be fastened by means of detachable and non-detachable fastening means. For example, the attachment by means of welding, gluing, threads, etc. take place.

According to a development, at least one stop is arranged on the carrier plate and / or on the receptacle. Such an arrangement is particularly useful because the support plate and recording are designed to be robust and dimensionally stable.

The stop is further formed so that the structural bearing according to the invention has a game, so that a degree of limitation of a shift and / or rotation of the building bearing according to the invention by means of the arrangement can be fixed. For example, depending on the spacing of the stop from the carrier plate and / or from the receiving side surface, a correspondingly large horizontal clearance and / or an azimuthal clearance can be realized.

Further, the stop has an L-shaped profile. As a result, the degree of restriction can be set particularly easily in accordance with the geometric dimensions of the L-shaped profile. Because the L-shaped profile comprises a web to the spacing of the stop from the support plate and / or from the recording. In order to avoid premature material fatigue due to friction, the stop has a sliding contact surface according to a further development.

This Gleitanlagefläche may be similar to the sliding plates already described and fastened. The invention will be explained in more detail with reference to two embodiments.

Show it:

Fig. 1 is a front view of a first embodiment of the

structural warehouse according to the invention,

Fig. 2 is a side view of the first embodiment

3 is a plan view of a cutting position according to the sectional plane C shown in Fig. 1,

4 is a perspective view of the first embodiment,

Fig. 5 is an exploded view of the first embodiment

6 is a front view of a second embodiment of the

structural warehouse according to the invention,

Fig. 7 is a side view of the second embodiment

8 is a plan view of a cut position of the second embodiment according to the sectional plane C shown in Fig. 8,

9 is a perspective view of the second embodiment

and

10 is an exploded view of the second embodiment.

According to the first embodiment, the structural bearing 10 according to the invention has a sliding body 12 with a base surface 16 and a convex, spherical segment-shaped curved sliding surface 17 and a receptacle 14 for the movable mounting of the slider 12.

The receptacle 14 has a concave, spherical segment-shaped curved receiving surface

20, which at least partially surrounds the sliding surface 17 of the slider 12.

Further, the receptacle 14 has four receiving side surface 21, 22, which is arranged so that they limit the receiving surface 20 so that each has a surface edge 13, with respect to the lowest point Ta of the concave receiving surface 20 one in her Course in the region of the receiving side surface 21; 22 variable height.

In the present case, the receptacle 14 has two pairs of opposing receiving side surfaces 21, 22, which are arranged symmetrically to the lowest point Ta of the concave receiving surface 20.

The receptacle 14 also has a substantially cuboid shape with a rectangular planar base 19 of an opposite concave Aufufnahmeflä- che 20 and four to the base 19 vertical side surfaces 21, 22. These are aligned with the slider side surfaces 18 of the slider 12. The curvature of this

Receiving surface 20 corresponds to the sliding surface 1? of the sliding body. The recordings are presently made of steel and has a rectangular in plan view base 19. The opening angles of the receiving surfaces meet the European standard 1337-7.

The slider 12 has the shape of a segment of a spherical cap with at least one slider side surface 18 having a variable height. Furthermore, the slider 12 has a substantially cuboid shape with a rectangular, flat base surface 16 and four planar Gleitkörper- side surfaces 18 perpendicular to the base 16, wherein each two opposing side surfaces 18 symmetrical to the highest point Tg of the convexly curved sliding surface of the slider 12th are arranged.

The slider 12 is presently made of metal and has a hard chrome-plated surface.

Furthermore, the structural bearing 10 according to the first embodiment comprises a counter surface formed here in the form of a counter-plate 23. This counter-plate 23 faces the base 16 of the slider 12, whereby a floating mounting of the slider 12 on the counter-plate 23 can be realized. The counterplate 23 is configured as an austenitic chromium-nickel-plated steel sheet and has a substantially rectangular shape. Alternatively, however, the mating surface can also be formed from a suitable surface finishing layer, in particular a hard chrome plating layer.

The counter-plate 23 is in turn attached to a support plate 24. The support plate 24 is presently formed of metal and has a corresponding to the counter-plate 23 shape. The support plate 24 has a significantly higher material thickness than the counter-plate 23. Support plate 24 and counter-plate 23 are permanently connected to each other.

To improve the sliding properties, the structural bearing 10 according to the invention according to the first embodiment, each having a curved and flat sliding plates 25, 26. These slide plates 25, 26 serve as sliding partners for the counter-plate 23 and the sliding body 12 and are formed from one of the above-mentioned sliding materials. In addition, these non-illustrated lubrication pockets for a lubricating material. These slide plates 25, 26 are shear-resistant respectively attached to the concave Aufnahmefiäche 20 of the receptacle 14 and on the flat base surface 16 of the slider 12.

The sliding plates 25, 26 have a shape which corresponds to the receiving surface 20 or the base 16, but are less wide and long than these. The curved slide plate 26 accordingly has opening angles 2 ft x and 2, which are somewhat smaller than those of the receiving surface 20.

The receiving surface 20 and the base 16 of the slider 12 have recesses

27, 28, in which the sliding plates are chambered in such a way that they protrude in accordance with the requirements of EN 1337-2 partially on each of the receiving surface 20 or the base 16. In the installed position, the sliding plates 25, 26 arranged shear-resistant in the recesses 27, 28.

The building warehouse 10 has four stops 29. In the present case two stops 29 are arranged on the longitudinal receiving side surfaces 21 of the receptacle 14.

As a result, a rotational movement of the slider 12 in the direction of the stops 29 is at least partially limited.

In the present case, the stops 29 have an L-shaped profile, so that respective stop regions 30 are spaced from the receiving side surfaces 21 of the receptacle 14. In this way, the structural bearing according to the first embodiment has an azimuthal play.

The second embodiment of the structural bearing 31 according to the invention initially differs from the first in that it has a second counter-plate 36 and support plate 32, which are formed analogously to the first counter-plate 23 and support plate 24. This second counter-plate 36 faces the base 19 of the receptacle 14.

The second carrier plate 32 is also formed of metal. At the base 19 of the receptacle 14 facing side of the support 32, two elongated guides 34 are arranged made of metal. These run in each case at the edge and parallel to the end faces 35 of the carrier 32.

These guides 34 restrict the movement of the receptacle 14 to the second counter-plate 36, which is formed as a thin austenitic chromium-nickel-alloyed steel sheet. This steel sheet is bent in a U-shape, so that this fits perfectly between the Guides 34 on the support plate 32 can be arranged, counter-plate 36 and stops 34 are welded to the support plate 32.

To improve the sliding properties, the structural bearing 31 according to the second embodiment has a further sliding plate 37. This also consists of one of the above sliding materials, such as PTFE, UHM PE, polyamide or the like. This is similar to the sliding plates 25, 26 fixedly mounted on the receptacle 14. For this purpose, the receptacle on the base 19 on a recess, not shown, in which the sliding plate 37 is chambered in such a way that it protrudes at least partially over the base 19 of the slider.

According to the second embodiment, the receptacle 14 also has lateral casting surfaces 40 on its end faces 38 facing in the installation position 34. These are presently designed as thin strips of one of the already mentioned, suitable sliding materials. These are fastened by means of screwing in corresponding recesses on the end faces 38 such that the Gleitanlageflächen 40 at least partially project laterally beyond the end faces 22 of the system 14.

The guides 34 are arranged such that movement in the longitudinal direction of the carrier 32 is prevented, while a transverse movement parallel to the guides 34 is possible.

The carrier plates 24, 32 also each have two stops 42, which are each arranged centrally on the longitudinal sides 43, 46 of the carrier plates 32, 24. By means of the stops 42 and an unwanted sliding out of the receptacle 14 and the slider 12 over the edge of the counter-plate 36, 23 is prevented, since the movement of the receptacle 14 and the slider 12 in the transverse direction of the carrier 32, 24 limited by the stops 42 becomes.

These stops 42 have similar to the stops 29 on the receptacle 14 on an L-shaped profile. Furthermore, these stops 42 also sliding bearing surfaces 44 which are formed here as a thin strip of a sliding material. These are fastened in a manner not shown in recesses of the stops 42, which face in the installation position of the receptacle 14 and the slider 12. By means of the Gleitanlageflächen 44 excessive rubbing of the receptacle 14 is prevented at the stops 42. The stops 42 are formed here from metal. The Gleitanlageflächen 44 are spaced by means of the profile-shaped shape of the stops 42 of the longitudinal sides 43, 46 of the support plates 24, 32. In installation position receptacle 14 and slider 12 floating between the counter plates 23, 36 and support plates 24, 32 are stored. The structural bearing 31 according to the second embodiment has azimuthal play and horizontal play.

reference numeral

10 structural warehouse

12 sliding bodies

13 area border

14 recording

16 base area

17 convex sliding surface

18 sliding side surface

19 base area

20 concave receiving surface

21 longitudinal receiving side surface

22 end-side receiving side surface

23 counter plate

24 carrier plate

25 curved sliding plate

26 level sliding plate

27 recess

28 recess

29 stop

30 stop area

31 structural warehouse

32 carrier plate

34 leadership

35 front side

36 counter plate

37 level sliding plate

38 front side

40 sliding contact surface

42 stop

43 long side

44 sliding contact surface

46 long side

Ta lowest point of the concave receiving surface Tg highest point of the convex sliding surface 9x opening angle

iJ opening angle

Claims

claims

1 . Structural bearing (10; 31), which has a sliding body (12) with egg ner base (16) and a convex, spherical segment curved sliding surface and a receptacle (14) for movably mounting the slider (12), wherein the receptacle (14) a concave, spherical segment-shaped curved receiving surface (20) and the sliding surface (17) of the sliding body (12) at least partially surrounds,

characterized in that

the receptacle (14) has at least one receiving side surface (21; 22) which is arranged such that it delimits the receiving surface (20) in such a way that it has a surface edge (13) which is related to the lowest point (Ta). the concavely curved receiving surface (20) has a variable in its course in the region of the receiving side surface (21; 22) height.

2. structural bearing (10; 31) according to claim 1,

characterized in that

the receptacle (14) has at least two, preferably four, receiving side surfaces (21; 22) which are arranged so as to delimit the receiving surface (20) such that it has a surface edge (13) which is related to the lowest

Point (Ta) of the concavely curved receiving surface (20) has a variable in their course in the region of the receiving side surfaces (21; 22) height.

3. structural bearing (10; 31) according to claim 2,

characterized in that

at least two opposing receiving side surfaces (21, 22) symmetrically to the lowest point (Ta) of the concave receiving surface (20) are arranged.

4. structural bearing (10; 31) according to one of claims 2 or 3,

characterized in that

for example, two opposing receiving side surfaces (21; 22) are arranged asymmetrically to the lowest point (Ta) of the concavely curved receiving surface (20).

5. structural bearing (10; 31) according to one of the preceding claims,

characterized in that

the receptacle (14) has a rectangular in plan view base (1 9).

6. structural bearing (10; 31) according to one of the preceding claims,

characterized in that

the slider (1 2) has the shape of a segment of a spherical cap with at least one slider side surface (18) having a variable height.

7. structural bearing (10; 31) according to claim 6,

characterized in that

at least two opposing sliding body side surfaces (18) symmetrically to the highest point (Tg) of the convexly curved sliding surface (1 7) of the slider

(12) are arranged.

8. structural bearing (10; 31) according to one of claims 6 or 7,

characterized in that

at least two opposing sliding body side surfaces (18) are arranged asymmetrically to the highest point (Tg) of the convexly curved sliding surface (1 7) of the sliding body (12).

9. structural bearing (10; 31) according to one of the preceding claims,

characterized in that

the sliding body (12) has a rectangular in plan view base (16).

10. structural bearing (10; 31) according to one of the preceding claims,

characterized in that

in the rest position, the sliding body (12) is arranged in the structural bearing (10; 31) such that at least one sliding body side surface (18) is aligned approximately in alignment with at least one receiving side surface (21;

1 1. Structural bearing (10; 31) according to one of the preceding claims, characterized in that

the sliding body (12) and / or the receptacle (14) have or have a substantially cuboid shape.

12. Structural bearing (10; 31) according to one of the preceding claims,

characterized in that

at least one side surface of the slider (1 2) and / or the receptacle (14) perpendicular to the base surface of the slider (12) and / or the base of the receptacle (14) is arranged.

13. Structural bearing (10; 31) according to one of the preceding claims, characterized in that

the sliding body (12) and / or the receptacle (14) are designed so that they

Requirements of EN 1337-7 with regard to the permissible opening angles for domes fulfilled / fulfilled.

14. Structural bearing (10; 31) according to one of the preceding claims, characterized in that

in the receptacle a curved slide plate (25) is arranged.

15. Structural bearing (10; 31) according to one of the preceding claims, characterized in that

the structural bearing (10; 31) has at least one planar sliding plate (26; 37).

16. structural bearing (10; 31) according to claim 15,

characterized in that

the planar sliding plate (26; 37) of the base (19) of the receptacle (14) and / or the base (16) of the slider (12) facing the bearing is arranged so that at least partially a floating mounting of the receptacle (14) and / or of the slider (12) is feasible.

17. Structural bearing (10; 31) according to one of claims 15 or 16,

characterized in that

Structural bearing (10; 31) has at least one flat counter-plate (23; 26) for the flat sliding plate (26; 37).

18. Structural bearing (10; 31) according to claim 17,

characterized in that

at least one flat counter-plate (23; 36) is held in a carrier plate (24; 32).

19. Structural bearing (10; 31) according to claim 18,

characterized in that

the carrier plate (24, 32) has a substantially rectangular shape.

20. Structural bearing (10; 31) according to one of the preceding claims,

characterized in that

Bauwerkslager (10; 31) at least one stop (29; 34; 42), so that a rotational or translational movement of the receptacle (14), the Gleitkör- Pers (12) and / or at least one support plate (24, 32) is at least partially limited.

21. Structural bearing (1 0, 31) according to claim 20,

characterized in that

a stop (29; 42) on the carrier plate {24; 32) and / or on the receptacle (14) is arranged,

22. Structural bearing (10; 31) according to one of claims 1 1 to 13, characterized in that

the stop (29; 42) is arranged so that the

Structural warehouse (10, 31) a horizontal and / or

has azimuthal play.

23. Structural bearing (10; 31) according to one of claims 20 to 22, characterized in that

the stop (29, 42) has an L-shaped profile.

24. Structural bearing (10; 31) according to one of claims 20 to 23,

characterized in that

the stop (42) has a Gleitanlagefläche (44).