The present invention relates to a formwork core for a formwork system for casting a bell-shaped body, in particular larger prefabricated units of residential buildings.
Such a formwork system essentially consists of an outer formwork and the formwork core, which is generally cuboid in shape and is inserted into the outer formwork. The outer formwork has a fixed formwork floor as well as vertical longitudinal walls and end walls that stand on a formwork floor. The formwork core sits between the formwork walls of the outer formwork. Liquid concrete is pressed into the remaining space between outer formwork and formwork core. After the concrete has hardened, the outer formwork elements are removed. In order to detach the formwork core from the inner walls of the fully cast bell-shaped body, the side formwork elements of the formwork core have to be drawn inwards to be detached from the finished concrete part.
Formwork cores with inwardly retractable side formwork elements, so-called shrink cores, are known from the prior art.
European patent EP 2 083 977 B1 of the applicant describes a formwork system for casting room modules, comprising outer formwork and formwork core. The formwork core comprises a cover element, end elements and side elements as well as a coupling mechanism. The end elements and side elements are each coupled to the base and the cover element and are movably connected. The coupling mechanism is designed in such a manner that vertical movement of a horizontal element causes the vertical elements to move inwards in such a manner that the distance between the opposite vertical elements is reduced. The coupling mechanism comprises a plurality of pivoted levers.
DE 20 469 03 A1 describes a method for producing a bell-shaped body for larger prefabricated units as well as a device for carrying out the method. One embodiment of the device comprises a stationary formwork core with columns and retractable side formworks. The side formworks are rotatably suspended from the columns via several control arms. The mechanics of pivoting cause the side formworks to fold back so that wedge-shaped gaps are created between the walls of the finished concrete body and the formwork elements.
Another older patent of the applicant, EP 1 923 185 B1, describes a displacer which is designed as a shrinking body and can be pulled upwards out of a side formwork after casting.
DE 25 04 218 A1 describes a formwork core for room cell formworks, which can be used as an inner form for producing a garage or a similar body. The formwork core has a variable cross-section. There is play between several of the pressure beams so that the cross-section can be reduced to remove the formwork.
DE 40 04 654 C1 discloses a formwork core for producing prefabricated gar-ages or similar room cells made of concrete. The formwork core can be adjusted in its width. The width can be adjusted by arranging formwork parts on slides that can be moved on rails. DE 28 12 974 A1 discloses a formwork core for a formwork system for casting a bell-shaped body according to the preamble of claim 1.
While the outer formwork consists of comparatively simple, in principle flat formwork walls, a formwork core with side formwork elements that can be retracted inwards is constructed in a quite complicated and technically complex way. The total costs for a formwork system for casting a bell-shaped body are therefore primarily determined by the costs for the complicated inner formwork core.
The outer formwork elements required for casting a prismatic bell-shaped body are in principle designed as flat formwork panels. Therefore, the outer formwork parts can be used again and again, even if a bell-shaped body with different dimensions, in particular a larger or smaller width and/or length is to be produced. It is sufficient to simply re-assemble the flat formwork walls.
A shrink core, on the other hand, can only ever be used for a specific room cell with predetermined fixed dimensions in three dimensions. Due to the complex construction and the complicated adjustment mechanism, such a shrink core is difficult to dismantle into its individual parts in order to reuse them to produce a new formwork core with different dimensions. As a result, conventional shrink cores are usually only used when a larger number of identical bell-shaped bodies are to be cast, since the relatively high cost of the formwork core can then be apportioned to the number of concrete parts produced.
Against this background, it is an object of the present invention to provide a formwork core with inwardly retractable side formwork elements which can be changed quickly and easily in such a manner that it can be used to produce bell-shaped bodies of different dimensions, in particular different widths and lengths.
In solving this problem, the starting point is a formwork core according to the preamble of the first claim, comprising a base, vertical corner supports and side formwork elements which are suspended on the corner supports via pivoted levers in such a manner that the side formwork elements can be retracted inwards.
The object is achieved by the features of the characterizing part of the first claim.
In the formwork core according to the invention, two corner supports each are releasably attached in variable distance to a common base frame. The corner supports each carry two corner connection panels, which are arranged perpendicular to each other and are synchronously retractable and extendable without touching. The corner connection panels have a flat outer wall that is designed as a formwork wall. In the fully extended state, there remains a narrow vertical gap between the two corner connection panels in the area of the corner. The corner supports also each carry a corner bracket, which can be retracted and extended synchronously with the corner connection panels. In the fully extended state, this corner bracket closes the gap between the two corresponding corner connection panels, thereby forming a vertical outer edge of the formwork core.
According to the invention, the vertical edges of the corner connection panels remote from the corner are designed such that they can be releasably attached to one another. This makes it possible that the corner connection panels lying in one plane, for instance those that form a side surface of the formwork core, can be connected directly to one another. The resulting formwork core then has a minimal length and/or width. If required, one or possibly also several intermediate elements can be releasably inserted between the corner connection panels of one side. In this way, the width and/or length of the formwork core can be increased in a very simple manner if a larger bell-shaped body is to be cast. If necessary, the formwork core according to the invention can also be restored to its original dimensions by directly connecting again the vertical edges of the corner connection panels that face each other.
The formwork core designed according to the invention thus has the great advantage that it can be easily adapted to different dimensions of a bell-shaped body to be cast, without changing those elements which are structurally complex and thus particularly expensive to manufacture. In particular, the corner supports, the corner connection panels movably mounted on the corner supports, and the corner brackets can thus be used again and again, even if the hollow bodies to be cast have very different dimensions. The same applies to the complex coupling mechanism for driving the shrink core.
According to the invention, the corners of the formwork core are formed by two, in principle flat, corner connection panels which are arranged perpendicular to one another around the corner, and a corner bracket which closes the gap between the adjacent corner connection panels and forms the vertical outer edge of the formwork core. This construction has the advantage that the length of the corner connection panels can be easily varied. It is thus possible to implement wider and shorter and/or narrower and longer formwork cores very simply just by using shorter or longer corner connection panels. The corner supports with their elaborate lever mechanisms and the coupled corner brackets can be used without modification in any case.
In order to quickly and easily, but at the same time firmly, connect and later release the vertical edges of the corner connection panels facing away from the corner, the corner connection panels comprise inward-facing bolt flanges at their free edges. By means of these bolt flanges, the corner connection panels of one side can either directly be releasably connected to one another or, alternatively, one or more extension parts can be attached.
The corner brackets are preferably coupled to the corner connection panels in such a manner that when the formwork core is drawn in, that is to say when the formwork core shrinks, the corner brackets move inwards before the corner connection panels do. The corner brackets are thus moved out of the way before the corresponding corner connection panels are drawn inwards.
The formwork core according to the invention is advantageously supplemented by a central ceiling formwork panel which is mounted horizontally on the corner supports, wherein the corner connection panels and the corresponding corner angles are coupled to the corner supports in such a manner that when the formwork core is drawn in, the corner connection panels and corresponding corner brackets move inwards and at the same time upwards above the stationary ceiling formwork panel. The length and width of such a ceiling formwork panel can no longer be changed subsequently; however, since this formwork element is in principle a simple flat plate, the replacement of the ceiling formwork panel, if necessary, is of little cost in the context of the reuse of the other, much more complex parts of the formwork core for casting a bell-shaped body with different dimensions.
Advantageously, the corner connection panels and the corner brackets have ceiling webs at their upper edges, which ceiling webs are attached at right angles to the inside. In the fully extended state of the formwork core, these ceiling webs form the top side of the formwork core together with the central ceiling formwork panel. When shrinkage begins, the horizontal ceiling webs separate from the ceiling formwork panel and move upwards and then away inwards.
According to the invention, the distance between two corner supports can be varied in that these corner supports are releasably attached to a common base frame. This makes it possible to easily adjust either the width or the length of the formwork core. An embodiment is preferred in which the base frames comprise a plurality of parallel fastening grooves in which fastening means engage, which are arranged at the foot of the corner supports. This allows the two corner supports, which are attached to this base frame, to be steplessly moved in order to vary the distance between the corner supports. Particularly preferable is an embodiment in which the base frames comprise a number of T-beams arranged in parallel and at a distance from one another.
Two adjacent T-beams each form a fastening groove for fastening the corner supports.
Optionally, at least one side formwork panel each can be releasably inserted between two corner connection panels that form a side surface of the formwork core. As a result, the length and/or width of the formwork core can be increased in a simple manner if the corner connection panels themselves are not long enough and shall not be replaced by corner connection panels of a greater length. In principle, the corner connection panels can be made very narrow, that is, they can be very short in the horizontal direction; the length and/or the width of the formwork core is then essentially determined by the dimensions of the intermediate elements.
Advantageously, not only the corner connection panels, but also the optionally insertable side formwork panels have inward-facing bolt flanges at their vertical edges, which bolt flanges correspond with the bolt flanges of the corner connection parts. This allows for a quick and releasable screw connection between corner connection panels and side formwork panels.
Hereinafter, exemplary embodiments of the invention are described in more detail with reference to the enclosed Figures, in which:
The formwork system according to
The outer formwork 20 comprises two opposite end walls 21, two side walls 22 arranged perpendicular thereto, as well as a number of vertical outer supports 23 at which the end walls 21 and the side walls 22 are suspended. The outer supports 23 are releasably attached to guide rails 24 so that all side formwork elements can be moved off outwards after casting.
The formwork core 30 sits between the outer formwork 20. The bell-shaped concrete part (not shown) can be pulled or pushed out vertically upwards after hardening, whereupon it detaches from the formwork core 30. The formwork core 30 has the shape of a rectangular cuboid, the rear side of which is open.
Its outer walls are formed by a total of eight corner connection panels 31, four side formwork panels 32 inserted between two corner connection panels 31, and a central horizontal ceiling formwork panel 33 (cf.
Two vertical side supports 36 each are arranged between the corner supports 34 along the two long sides of the formwork core 30. These side supports 36 carry the side formwork panels 32.
The corner supports 34 and the side supports 36 are releasably attached in pairs on a common base frame 40. The distance between the corner supports 34 and/or side supports 36 mounted on a base frame 40 is variable so that the width of the formwork core 30 can be adjusted. The base frames 40 comprise a plurality of fastening grooves 41 which are arranged parallel to one another and are open at the top. The base frames 40 comprise a plurality of T-beams 42 arranged in parallel and at a distance from one another, between which the fastening grooves 41 are arranged. The ends of the T-beams 42 are screwed onto narrow crossbeams 43 which rest on the base plate 10 (cf.
The guide rails 24 for the outer supports 23 (
The formwork core 50 shown in
The smaller formwork core 50 is also designed as a shrink core. The side formwork elements of the formwork core 50 comprise a total of eight corner connection panels 51, four side formwork panels 52 arranged between them, as well as a central, approximately square ceiling formwork panel 53. In
The load-bearing structure of the formwork core 50 is formed in particular by four vertical corner supports 54, as can be clearly seen from
As can be seen in particular in
The enlarged illustration of
From
The corner connection panels 51 have ceiling webs 51b attached inwards at right angles at their upper edges (
The corner brackets 55 are resiliently mounted on pressure plates 70 at their lower ends (cf.
Horizontal and vertical tension and compression rods stiffen the construction (
Number | Date | Country | Kind |
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18173984 | May 2018 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/059453 | 4/12/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2019/223936 | 11/28/2019 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4570896 | Strickland | Feb 1986 | A |
4650150 | Pacheco-Pifano | Mar 1987 | A |
5524861 | Solomon | Jun 1996 | A |
5755982 | Strickland | May 1998 | A |
20060260238 | Barcons | Nov 2006 | A1 |
20150083889 | Floreani | Mar 2015 | A1 |
Number | Date | Country |
---|---|---|
2 046 903 | Mar 1972 | DE |
25 04 218 | Aug 1976 | DE |
2812974 | Oct 1979 | DE |
40 04 654 | May 1991 | DE |
10 2009 055 690 | May 2011 | DE |
1 923 185 | Aug 2014 | EP |
1584749 | Feb 1981 | GB |
Entry |
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Jul. 3, 2019 Search Report issued in International Patent Application No. PCT/EP2019/059453. |
Number | Date | Country | |
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20210238870 A1 | Aug 2021 | US |