BE1023536B1 - PLATE STORAGE AND THE PLATE STOCKER USING PLATE BOTTOM - Google Patents

Abstract

A tile support (101; 401) for positioning and supporting a tile floor on a building surface, the tile support having a lower tile support surface (103; 403) adapted to face a building surface. An upper disk bearing surface (105; 405) of the disk bearing (101, 401) is spaced from the lower surface (103; 403) by a body of material (107) from which the disk bearing is formed. The upper disk bearing surface (105; 405) faces a plurality of radially arranged projections (109; 409) extending from the upper disk support surface in a direction perpendicular thereto Each projection (109; 409) is adapted to be provided with a recess (205; 505) on a floor (203; 503) of a plate edge (209; 509). A radially extending slot (111; 4111) is provided between each adjacent pair of projections (109; 409). Each radially extending slot (111; 4111) is formed to optionally allow an alignment tab (17) of a pedestal to extend therethrough The panel support (101; 401) may be part of a panel floor supported on a primary building surface, e.g. is for example a roof, in connection with several individual panels (201; 501), each of which has at least one recess (205) on the bottom edge. The plate support (101; 401) can optionally also be part of a raised floor which rests on a plurality of height-adjustable bases (5) and can be arranged between the base and the plate (201; 501).

Description

PLATE BEARINGS AND THE PLATE BEARING USER

PANEL FLOOR

The invention relates to a plate bearing for positioning and supporting a plate floor on a building surface and on

Disk tray assemblies containing such disk bearings. In particular, the invention relates to board floors on top of roofs, such as patio floors and parking decks.

Plate bottoms forming a secondary surface over a primary surface are well known. Such floors can come in a variety of forms, such as raised office floors, makeshift exhibition shelves, tents or stage floors for events, and patio floors on generally flat roofs. With the exception of well-known features such as primary surface customization and ease of installation, the requirements for these particular applications are very different. A particular problem arises when such a slab floor is used outside of buildings for terraces or parking decks in which concrete tiles or concrete slabs are used. Due to the required load carrying capacity of such slab bottoms, it is important to limit lateral movement of the individual slabs. In known arrangements in which height-adjustable pedestals are used at the node junctions between two or more adjacent rectangular tiles, such pedestals have a substantially flat head portion from which radial alignment tabs project in an upward direction to position the tiles and separate from each other. To prevent the tiles of such a floor from moving apart, additional measures are required at the outer edge of the floor. Such additional measures for holding the tiles or tiles on the outer edge of the floor are cumbersome and increase the cost and installation of such floors. There is therefore a need for improvement.

As a disadvantage, it is also felt that the radial alignment tabs projecting upwardly from the substantially flat head portion of the prior art pedestals are quite susceptible to damage. These alignment tabs also ensure that there is a limited gap between adjacent tiles or plates that allows drainage of rainwater. As a result, the material thickness of these alignment tabs is dictated by the maximum allowable rainwater drainage gap and is usually no more than 2 to 3 mm. With the current popularity of using plastic material for these sockets, and therefore the alignment tabs, there is a serious risk that, when positioning fairly heavy concrete slabs or concrete tiles, they inadvertently come to rest on top of these tabs and cause them to collapse. There is therefore a need to reduce or eliminate this risk.

In addition to the above-mentioned improvement capability, there is also a need for a much simpler arrangement for placing panels on a generally flat roof in situations where adjustability of level and / or incline is not required. Such situations may exist when maintenance access is required for an air conditioning or ventilation system on top of a roof.

In some applications, contact noise from the plate floor via the pedestals into the building structure is undesirable. Therefore, the provision of sound-absorbing properties in existing roof-mounted floors is another need.

Further, there is a general desire that not only is it possible to adjust the height of the secondary tray with respect to the primary tray, but also to compensate for the inclination of the pedestal heads, which are usually parallel to the primary tray or roof surface.

Accordingly, it is an object of the present invention to provide an improved plate bearing, a plate and a plate bottom. In a more general sense, it is therefore an object of the invention to overcome or reduce at least one of the disadvantages of the prior art. In addition, it is an object of the present invention to provide alternative solutions which are less cumbersome to install and operate and which, moreover, can be made relatively less expensive. Alternatively, it is an object of the invention to provide at least one useful alternative.

To this end, the invention provides a plate bearing, a plate and a plate bottom, as defined in one or more of the appended claims.

In particular, the invention provides a disc storage for positioning and supporting a disc tray on a building surface, the disc storage having a lower surface adapted to face a building surface and an upper surface extending from the lower surface through a body Material is spaced from which the plate bearing is formed, wherein the upper surface has a plurality of radially arranged projections which extend from the upper surface in a direction perpendicular thereto, wherein each extension is adapted to a recess at a bottom of a plate edge engaging and wherein a radially extending slot is provided between each adjacent pair of extensions to allow an alignment tab of a socket to extend therethrough. Such a plate bearing positions the individual plates to each other in opposite lateral directions, which eliminates the need to hold the plates to an outer edge of the plate bottom. Optionally, the plurality of radially disposed extensions of the plate bearing may include four extensions each adapted to engage a recess of a corner of a single plate. Alternatively or additionally, the bottom surface may be a flat surface and / or the bottom surface may be parallel to the top surface when not angled, or a spherical bottom surface may not be used.

As a further possibility, each radially arranged extension may be tapered to taper to a free upper end, and / or each radially disposed extension may have a height above the upper surface adapted to have a vertical depth of a recess in a floor of a panel frame not to exceed. These features can help to position the plates and ensure firm support on the individual plate bearings.

The invention also provides a slab bottom which is disposed for support on a building surface having such slab bearings as discussed above in combination with a plurality of individual slabs each having at least one recess in the lower edge thereof. Optionally, these plates may each have a rectangular edge with four corners. Then, the at least one recess may be part of a recess at each corner of each individual plate. Alternatively or additionally, each recess in the bottom edge of each plate may then be tapered to become wider toward a bottom surface of that plate, and / or each recess in the bottom edge of each plate may have a vertical depth which is a height does not exceed radially disposed projections above the upper surface of the bottom bearing. As explained above, these features can help to position the plates and ensure firm support on the individual plate bearings.

Optionally, the slab floor of the present invention may also include a plurality of sockets for raising the floor to a raised position and for leveling the floor with respect to a building surface on which it is supported. Each pedestal then has a base for positioning on a primary building surface and a height-adjustable head on which the bottom surface of the disc storage rests, and at least one alignment tab on the head of the pedestal can then project upwardly to pass through one of the radially extending ones Slots in the plate storage to extend. Optionally, either the base or the head of each pedestal can be joined together with a grub screw for height adjustment. In addition, either the base or the head can optionally be joined together by means of a rotatable nut with the threaded pin, which then allows a height adjustment with at least a portion of the tiles or tiles in place.

Further advantageous aspects of the invention will become apparent from the following description with reference to the accompanying drawings. It shows:

Fig. 1 shows a conventional plate bottom which is supported above a primary building surface in a raised position;

Fig. 2 is an isometric view of a disk storage according to the present invention;

Fig. 3 is a plan view of the plate bearing according to the invention;

4 shows a cross section through the plate bearing according to the invention along the line IV-IV in Figure 3 in the direction of the indicated arrows ..;

5 shows a view of a plate according to the invention from below;

Figure 6 is a cross-section of the plate according to the invention along the line VI-VI in Figure 5 in the direction of the indicated arrows ..;

Fig. 7 is a side view of an alternative embodiment of a plate bearing according to the invention;

8 shows a side view of a further alternative embodiment of a plate bearing according to the invention;

Fig. 9 is a plan view of a resilient pad;

Fig. 10 is a plan view of another embodiment of a disk storage according to the present invention;

Fig. 11 is a cross-sectional view of the plate bearing of Fig. 10 along the line XI-XI;

Fig. 12 is a cross-sectional view of the plate bearing of Fig. 10 along the line XII-XII;

Fig. 13 is a partial perspective view of a panel according to the invention employing an alternative embodiment of a panel; and

FIG. 14 is a partial perspective view of the alternative plate embodiment of FIG. 13. FIG.

In the partial perspective view of Fig. 1, a conventional raised floor structure 1 is shown. In this case, a node in such a floor structure is shown in which one of a plurality of individual plates or tiles 3 has been removed to expose a socket 5. The base 5 has a base 7 with a lower flange 9 for its support on a primary building surface, such as in particular a roof. On the base 7 a head 11 is supported with a flat upper surface 13. The flat top surface 13 is generally parallel to the flange 9 of the base 7. In a conventional arrangement, the head 11 is adjustable in height relative to the base 7 to compensate for the normal sloping roof that is present to allow drainage of rainwater enable. To achieve this height adjustment either the base 7 or the head 11 can be joined together with a threaded rod (not shown here, but conventional), which is assigned to the other from the base 7 or the head 11. In the prior art arrangement shown in Figure 1, the base 7 is associated with a rotatable nut 15 to allow adjustments while the plates 3 are in place. The upper surface 13 is further provided with alignment tabs 17, thereby also ensuring that a gap 19 between adjacent panels 3 is maintained. Such a raised plate floor assembly is generally publicly known and has been generally described in patent document US 4,558,544.

Fig. 2 is an isometric view of a plate bearing 101. The plate bearing 101 has a lower surface 103 and an upper surface 105. The upper surface 105 is spaced from the lower surface 103 by a body of material 107 from which the plate bearing 101 is formed , Conveniently, this body of material 107 may be a plastic material, such as an elastomer or a recycled plastic material. In addition, the body 107 of the plate bearing 101 may be formed of rubber granules with polyurethane binder, such as recycled automotive tire material, which is pressed with a polyurethane binder. However, it is also conceivable that the body 107 consists of a shaped metal sheet. To prevent contact noise, a certain degree of resilience would be preferred, but this can also be achieved by adding a resilient layer to the plate bearing. The plate bearing 101 further has four extensions 109 each radially disposed with respect to a center of the upper surface 105 and extending upward therefrom. Between each adjacent pair of extensions 109, a radially extending slot 111 is disposed. The slots 111 are arranged to allow the alignment tabs 17 of prior art sockets 5 to extend therethrough. However, the use of the plate bearings 101 is not limited to the raised floor structure 1 of FIG. 1, but may be used directly on a building structure such as a roof. In this application, the lower surface 103 of the plate bearing 101 then rests directly on the primary building surface. As shown in Figures 3 and 4, it can be seen that the radially extending slots 111 extend through the entire thickness of the body of material 107, thereby allowing the alignment tabs 17, if any, to protrude above the top surface 105 and to maintain their function of maintaining a gap (such as in Fig. 1) between adjacent plates (such as 3 in Fig. 1).

Another feature of the present invention will now be explained with reference to FIGS. 5 and 6. 5 is a view of the lower surface 203 of a plate 201. The plate 201 is of concrete or similar material and is generally similar to the plate 3 of FIG. 1, except that it has a recess 205 at each corner 207 of its rectangular rim 209 having. As shown in the side cross-sectional view of FIG. 6, the recesses 205 may have a vertical depth D. The recesses 205 may engage with one of the extensions 109 of a corresponding plate bearing 101. A tapered shape of the recess 205, which becomes wider towards the lower side 203, may be adapted to a tapered shape of the extension 109, which then tapers from the upper surface 105 of the plate bearing 101. If a height H of the extension 109 (see FIG. 4) is chosen to be greater than a depth D of the recess 205 in the plate 201 (see FIG. 6), then it is possible for the plates 201 to be opposite the bottom surface 103 of the plate bearings 101 are slightly angled. As a result, the plate bearings 101 can conform to a non-planar or oblique part of the primary building surface, while an upper surface 211 of the plates 201 can remain unaffected by such changes in the supporting surface. Further, it will be appreciated that by the interaction of the extensions 109 and the recesses 205, the plates 201 are not only prevented from moving towards each other, but also prevented from moving away from each other. Other shapes of extensions 109 and recesses 205 are also conceivable, such as extensions having a rounded upper end, or the like. In the prior art arrangement shown in Fig. 1, additional measures are needed around the outer edges of the floor structure 1 to prevent movement of the panels 3 outwardly.

In addition, referring to Figures 7 and 8, it may be necessary to compensate for a slope angle of the roof surface in conjunction with the drainage of rainwater. As explained with reference to FIG. 1, the upper surface 13 of the base 5 is generally parallel to the lower surface of the lower flange 9. This may cause the tiles 3 or 201, when used with the plate bearing 101, to engage their corners 207 are not in continuous contact with the upper surface 105 of the plate bearings 101. This can affect the stability of the slab as a whole. To compensate for such an inclination and allow proper surface contact between the plate corners 207 and the upper plate bearing surface 105, the surface 103A of a slightly modified plate bearing 101A may have a corresponding angle, as shown in FIG. The alternative plate bearing 101A may thus have an upper surface 105 which is not parallel with its lower surface 103. The angled lower surface 103A may then be disposed using the radially extending slots (111 in the embodiment of Figs. 2-3) in a direction to level the roof pitch. A slightly different alternative plate bearing 101B is shown in FIG. The alternative plate bearing 101B has a bottom surface 103B which is spherical, and therefore can be adapted to a whole range of different inclination angles.

In Fig. 9 is a plan view of a resilient pad 301 is shown. This resilient pad 301 may be made of a sheet of resilient material, such as an elastomer in a thickness range of 1 to 2 mm. The web 307 of resilient material 307 is provided with round openings 309 and radial slots 311. The round apertures 309 and the radial slots 311 allow the resilient pad 301 to be placed anywhere on the head 11 of a pedestal on any of the above-described disc bearings 101, 101A, 101B or on top of the other form of disc storage described below with reference to Figs 12 is described is arranged. Conveniently, the circular openings 309 are slightly larger than the extensions of the plate bearings so that the extensions can extend therethrough. Likewise, the slots 311 are arranged to be slightly larger than the radially extending slots of the disk bearings so that they do not interfere with them and allow the alignment tabs 17 to also extend through the radial slots 311. As also shown in FIG. 9, the radial slots 311 may terminate at their opposite longitudinal ends in pre-scored tear lines 313. These pre-scored tear lines 313 may be useful when less than four tiles or plates are to be supported at the node provided by a panel bearing of the invention.

A plan view of another form of plate bearing 401 according to the present invention is shown in FIGS. 10, 11 and 12. This plate bearing 401 generally has a somewhat thinner body 407 and therefore may preferably be used as an adapter on top of a pedestal head 11 (as shown in FIG. 1). This plate bearing 401 is also preferably combined with the resilient pad 301 described above with reference to FIG. 9, which may also be glued or permanently attached thereto for this purpose. This plate bearing 401 has an upper surface 405 analogous to the above-described plate bearings 101, 101A, 101B, and a lower surface 403 (seen only in FIGS. 10 and 11). From the upper surface 405, there are a total of four radially disposed projections 409. Each extension 409 has a substantially smaller diameter at the top than at its base so that an upwardly extending surface 409A has a tapered shape that tapers in a direction away from the top surface 405 of the plate bearing 401. Preferably, each extension 409 has a diameter B at its base that is at least slightly greater than a distance S at which each extension 409 is spaced from an adjacent radially extending slot 411. It has also proved to be favorable when an angle α of the conical lateral surface 409A is in a range of 60 degrees. This is best shown in the cross-section of FIG. 11 along the line XI-XI in FIG. With such proportions, it can be ensured that the load of a concrete tile or slab, as shown in Figures 5 and 6, is always carried by one of the extensions 409 when placed adjacent an alignment tab (17 in Figure 1). which extends through the slot 411 therethrough. This then prevents damage to the sensitive alignment tab and allows easy correction of the disc position, to which the conical projection 409 and the conical recess 205 at the bottom corner of the plate 201 contribute. In this regard, it is only necessary that either the recess 205 or the extension 109, 409 have a conical surface, while the other from the extension 109, 409 and the recess 205 may have a cylindrical lateral surface with straight sides. It will be understood that the plate 201 does not differ in the use of any of the above-described plate bearings, and that the proportions of the extensions may also be selected to be identical in their spacing from the radially extending slots.

As further shown in cross-section in FIGS. 11 and 12, the plate bearing 401 is further different from the previously described plate bearings 101, 101A, 101B in that a peripheral edge 415 extends downwardly from the lower surface 403 of the plate bearing 401. Aside from reinforcing the plate bearing, this peripheral edge 415 may also be sized to fit just about the head (11 in Fig. 1) of a socket. This has proven to be favorable for the stabilization of the plate bearing 401, while tiles or plates (201 in FIGS. 5 and 6) are deposited thereon. Another aspect of the plate stocker 401 may be the provision of a predetermined tear line 417 around the base of the extensions 409. This allows a single tab 409 to be easily removed from the panel bearing 401 when only two panel corners are supported on the panel bearing and an associated socket on one edge of a panel floor. Then it is convenient to remove the innermost projections and the alignment tabs that are parallel to the outer edge of the floor. This will then allow each of the adjacent edge plates to rest on the entire top surface 405 of the disc storage 401.

Referring to Figures 13 and 14, there is shown an alternative embodiment of a disc tray according to the invention employing an alternative embodiment of disc 501. The raised floor structure shown in Figure 13 is shown (for greater clarity) by a single adjustable pedestal 5 and a single alternative form of tile or plate 501. A plate bearing, such as the plate bearing 401, is supported on an upper surface of the adjustable base 5 and is engaged with radially extending slots 411 via alignment tabs 17 protruding from the upper surface of the base 5. As explained with reference to FIGS. 10 to 12, the projections 409 are arranged radially on the upper surface 405 of the plate bearing 401 in order to engage corners of a tile or plate. In the

Embodiment of Figures 13 and 14, the plate 501 differs from the plate 201 described with reference to Figures 5 and 6 in that at each corner of the edge 509, a corner member 521 is attached to a lower surface 503 of the plate 501. The corner element 521 has a recess 505 formed therein in the form of a cylindrical through-hole, but the recess may optionally also have a conical shape. The corner member 521 may be attached to the lower surface 503 by means of a suitable cement or adhesive. Such self-applied corner elements 521 would be particularly suitable for plates, such as ceramic plates, in which it may be difficult in the one-piece production of recesses. The corner member 521 may be formed of a rigid or semi-rigid material. When formed of a semi-rigid material, the corner members 521 may obviate the provision of a resilient pad, such as the pad 301 of FIG. 9. As already explained, it is only necessary that the extension 409 has a tapered surface to ensure that the load of the plate always rests on one of the extensions 409 when in a position of abutment with one of the rather sensitive alignment tabs 17 , The recess 505 may, as shown in Fig. 14, have a cylindrical lateral surface with straight sides.

Accordingly, a disk storage 101; 101A; 101B; 401, which is useful for positioning and supporting a panel floor on a building surface. Each plate storage 101; 101A; 101B; 401 has a lower surface 103; 103A; 103B; 403, which in use is adapted to point to a building surface. An upper surface 105; 405 of the disk storage 101; 101A; 101B; 401 is from the lower surface 103; 103A; 103B through a body of material 107; 407 spaced, from which the plate bearing is formed. The upper surface 105; 405 has a plurality of radially arranged extensions 109; 409 extending from the upper surface 105; 405 extend in a direction perpendicular thereto. Each extension 109; 409 is adapted to a recess 205; 505 on a lower surface 203; 503 at a plate edge 209; 509 to be engaged. A radially extending slot 111; 411 is between each adjacent pair of extensions 109; 409 provided.

Each radially extending slot 111; 411 is adapted to selectively allow an alignment tab 17 of a socket 5 to extend therethrough. The plate bearing 101; 101A; 101B; 401 may be part of a slab resting on a primary building surface, such as a roof, in combination with a plurality of individual slabs 201; 501, each with at least one recess 205 in its lower edge. The plate bearing 101; 101A; 101B; Optionally, 401 may also be part of a raised floor 1 which rests on a plurality of height-adjustable base 5 and between base 5 and plate 201; 501, wherein the alignment tabs 17 through the radial slots 111; 411 extend therethrough.

It is therefore understood that the operation and structure of the present invention will be apparent from the foregoing description and the accompanying drawings. For purposes of clarity and succinct description, features are described herein as part of the same or separate embodiments, however, it will be understood that the scope of the invention may include embodiments having combinations of all or some of the described features. It will be understood by those skilled in the art that the invention is not limited to any embodiment described herein, but that modifications are possible within the scope of the appended claims. Kinematic reversals are also to be considered inherently disclosed and may be included within the scope of the invention. In the claims, reference signs are not intended to be interpreted as limiting the claim. The terms "comprising" and "containing", when used in the present specification or appended claims, should not be interpreted in an exclusive or exhaustive sense, but rather in an inclusive sense. Therefore, the term "including" or "comprising" as used herein does not exclude the presence of other elements, additional structures, or additional acts or steps in addition to those listed. Further, the words "a" and "one" are not to be interpreted as a limitation to "one only" but rather are meant to mean "at least one" and are not intended to exclude a plurality.

Features that are not specifically or explicitly described or claimed may be included in the construction of the invention without departing from its scope. Expressions, such as: "means for ..." shall mean: "component configured to ..."; or "element designed for." and should be interpreted to include equivalents to the structures disclosed. The use of terms such as "critical", "preferred", "particularly preferred", etc. are not intended to limit the invention. As far as structure, material or actions are considered essential, they are expressly stated as such. Additions, deletions, and modifications within the scope of those skilled in the art may be made generally without departing from the scope of the invention as determined by the claims

Claims (22)

PROTECTION CLAIMS A plate bearing for positioning and supporting a plate bottom on a primary building surface, the plate bearing having a lower plate bearing surface adapted to face a building surface and an upper plate bearing surface spaced from the lower surface by a body of material is, from which the plate bearing is formed, wherein the upper plate bearing surface has a plurality of radially arranged projections which extend from the upper plate bearing surface in a direction perpendicular thereto, wherein each extension is adapted, with a recess at a bottom of a plate edge in engagement and wherein a radially extending slot is provided between each adjacent pair of extensions to allow an alignment tab of a socket to extend therethrough. 2. A plate bearing according to claim 1, wherein the plurality of radially arranged projections comprise four projections, which are each adapted to engage with a recess of a corner of a single plate. 3. A plate bearing according to claim 1 or 2, wherein the lower surface is a flat surface. 4. A plate bearing according to claim 1, 2 or 3, wherein the lower surface is parallel to the upper surface. 5. A plate bearing according to any one of claims 1 to 4, wherein each radially arranged extension is tapered to taper towards its upper end. 6. plate bearing according to claim 5, wherein each extension has a conically shaped upstanding lateral surface. 7. The plate bearing according to claim 6, wherein the conically shaped upstanding circumferential surface is at an angle of substantially 60 degrees to the upper plate bearing surface. 8. A plate bearing according to any one of claims 5 to 7, wherein the extension has a diameter at its base surface, which is associated with the upper plate bearing surface having a dimension which is greater than a distance between a projection and a radially adjacent slot. The plate bearing according to any one of claims 1 to 8, wherein each radially arranged projection has a height above the upper plate bearing surface adapted to not exceed a vertical depth of a recess in a bottom of a plate edge. 10. A plate bearing according to any one of claims 1 to 9, wherein the upper plate bearing surface is resilient. 11. The plate bearing according to claim 10, wherein the upper plate bearing surface comprises a separately made pad of a resilient sheet material. 12. A plate bearing according to claim 10, wherein the entire plate bearing is made of a resilient material. A disc tray intended to be supported on a building surface, comprising a disc storage according to any one of claims 1 to 12, and a plurality of individual discs each having at least one recess at the bottom edge thereof. 14. A slab according to claim 13, wherein each slab has a rectangular edge with four corners. 15. The plate bottom according to claim 14, wherein the at least one recess is part of a recess at each corner of each individual plate. 16. A slab according to any one of claims 13 to 15, wherein each recess in the bottom edge of each slab is tapered to expand to a bottom surface of this slab. 17. The plate bottom according to claim 13, wherein each recess in the bottom edge of each plate has a vertical depth which is not greater than a height of the radially arranged extension of the upper surface of the plate bearing. 18. plate bottom according to one of claims 13 to 17, wherein the at least one or each recess in the bottom edge of the individual plates is integrally formed. 19. A slatted floor according to any one of claims 13 to 17, wherein the individual plates have at each corner a specially attached corner element which is fixed to a bottom surface of the bottom edge, and wherein in the corner element, the at least one recess is formed. The disc tray of any of claims 13 to 19, further comprising a plurality of pedestals for raising the tray to a raised position and leveling the tray with respect to the primary building surface on which it is supported, each pedestal having a base for positioning on a primary building surface and a height-adjustable head on which the lower surface of the disc storage rests, and wherein at least one alignment tab projecting upwardly from the head of the pedestal extends through one of the radially extending slots of the disc storage. 21. The plate bottom according to claim 20, wherein either the base or the head of each base is assembled with a threaded pin to make a height adjustment. 22. The plate bottom according to claim 21, wherein either the base or the head is assembled by means of a rotatable nut with a threaded pin