DE102006015054A1 - Ceiling formwork structure comprises standard grid elements having longitudinal supports and transversal supports which are rigidly interconnected - Google Patents

Abstract

Ceiling formwork structure comprises standard grid elements (2) having longitudinal supports (4, 8) and transversal supports (5, 10) which are rigidly interconnected. The grid elements have two transversal supports in the opposite end regions of the longitudinal supports while transversal compensating grid elements (6) are fitted with two transversal beams which are offset towards the inside in relation to the grid elements. Preferred Features: In the assembled state one longitudinal support of the transversal compensating element lies between two neighboring longitudinal supports of a grid element.

Description

The The invention relates to a slab formwork system with a plurality of grate elements, each of a plurality of mutually parallel Side members and at least one on vertical supports mountable or attachable, running transversely to the longitudinal members crossbeam consist.

Such a slab formwork system is known from German Offenlegungsschrift DE 102 34 445 A1 the applicant known. In this system, a plurality of mutually parallel side members are connected to each other via grills provided on its underside to each other to grate elements, that the relative positions of the side members are fixed to each other. The said spars are provided at a relatively large distance from the front ends of the side members spaced apart.

at the mounting of the known slab formwork system first cross beams are mounted on vertical supports, then then the from the side rails and Holmen existing, each with the same rust elements with perpendicular to the cross members extending longitudinal members the crossbeams can be hung from above. Due to the fact that the side members do not work with the cross members firmly connected and the spars spaced from the front ends provided the side member are, it is possible in the longitudinal direction together interlock adjacent grate elements with each other, so that respectively a section of a longitudinal member of a Grate element between two longitudinal members of a this toothed grate element comes to rest. In this way can by the interlocking of the grate elements a longitudinal compensation be made, which means that with the said slab formwork system longitudinal the side member individual dimensions can be set independently of the Pitch of the Grate elements selected can be.

A The object of the invention is a slab formwork system of the aforementioned type such that a slab formwork not only in the direction of the side members, but Also perpendicular to this can be adapted to individual size ratios, where especially a possible quick, easy and safe assembly and disassembly of the Ceiling formwork system should be ensured.

These The object is achieved by the Features of claim 1 and in particular solved in that Along- and crossbeams the grate elements are rigidly interconnected, with standard grate elements two have cross members provided in the end regions of the side members facing away from each other, while Cross compensation grid elements one or two offset inwardly compared to the standard grate elements crossbeam have.

According to the invention So the side members of a Rust element not in a known manner via separate spars with each other connected, but the connection of the longitudinal members of a grate element is directly above realized one or more fixedly connected to the longitudinal members cross member, which then in turn are suitable, placed on vertical supports or to be mounted. In this respect, the invention thus already achieved that the number of parts to be handled compared to known Ceiling formwork systems is reduced because cross member and Side members each form firmly connected units or grate elements, so that cross member and side members no longer must be handled separately from each other.

Furthermore, in the context of a system according to the invention, the grate elements are provided in at least two mutually different embodiments, with the standard grate elements defined above being realized in concrete terms, as well as the already mentioned cross-compensating grate elements. When mounting a slab formwork system whose size in each direction corresponds to an integer multiple of the respective grid dimension of the standard grate elements, it is possible to use only standard grate elements, which are not interlocked in any way. However, if it is necessary, for example, to provide individual dimensions outside the grid dimension in a direction perpendicular to the longitudinal members, transverse compensating grid elements are also used according to the invention in addition to the standard grid elements. This Querausgleichs- and grate elements differ from the standard grate elements in that its or their cross member are further offset inwardly. This surprisingly simple measure makes it possible to interlock a standard grate element and a transverse compensation grate element in such a way that an outer side member or also a plurality of outer side members of a transverse compensation grate element respectively come to rest between two adjacent side members of the standard grate element. In this case, then all the longitudinal members of the standard and the cross-compensation grate element extend parallel to each other, wherein they are all spaced from one another transversely to their longitudinal direction or arranged with their longitudinal sides adjacent to each other. Thus, in a direction perpendicular to the longitudinal beams transverse direction individual dimensions can be realized by the respective desired An number of side rails of a cross-compensating grate element between each two adjacent side members of a standard grate element is positioned. By the different attachment of the cross member to the standard grate elements and the cross compensation grate elements is thereby ensured that the cross member interlocked standard and cross compensation grate elements do not collide with each other. Rather, the cross member of all intermeshed grate elements extend either perpendicular to each other or the cross member interlocked grate elements abut each other.

Prefers it is when the side members of the standard grate elements the same length own like those of the cross-balancing grate elements. As part of a slab formwork system can do this however, for example, two or more classes or types of grate elements each with different dimensions are used, then to each class standard grate elements and at least corresponding cross-compensation grate elements exist, whose side members the have the same dimensions as those of the standard grate elements of respective class. Such a system, which e.g. two different ones Classes of standard grate elements and appropriately trained Querausgleichs rust elements used is in the context of the description of the figures even closer explained.

If the side members of the Standard grate elements of a type the same length as those the cross balancing grate elements of the same type, it is not possible, cross-balancing grate elements linear from below to an already mounted standard grate element introduce and to interlock with this in the context of a pure linear motion, since in this case, the opposite ends of the side members of the Transverse equal grate element with the cross members of the standard grate element would collide. In this case, rather than the cross-compensating grate element according to the invention "threaded" into the standard grate element from below, which means that the first one front ends of a respective desired number of longitudinal members of the Cross compensation grid element from below between the respective side members of the standard grate element introduced and over the one cross member of the standard grate element moves from inside to outside become. This movement is then continued in the direction of the longitudinal members, until the other ends of the side members of the Cross compensation grate element over the other cross member be raised and supported on the standard rust element can. The mentioned process of threading is described in more detail in the description of the figures.

From It is also advantageous if the distance between adjacent side members of the Grate elements at most 20 cm. At such distances can with the greatest possible Safety can be avoided by having a fitter pass between two adjacent side rails can fall, so that a mounted inventive grate element a reliable one Fall protection represents. The distance between adjacent side members has to be but be at least as big like the width of the side members, so that a side member of a Cross compensation grate element between two adjacent side members of a standard grate element can be moved. It is particularly preferred if the distance adjacent side member of the Grate elements is at least two or three times the width of the side members. In this Case can then be additional with longitudinal compensation grate elements and / or Kombiausgleichs grate elements are worked on which below yet. closer will be received. in principle it is also possible the distance between adjacent side members at least fivefold the Width of the side members increase. On this way will be extra possible combinations all available standing rust elements allows.

Especially it is preferred if in the context of a slab formwork system according to the invention in addition to the standard grate elements and the cross compensation grate elements even the ones already mentioned Longitudinal compensation grate elements for disposal are placed, which only in one of the two facing away from each other End portions of the side members a or more cross members exhibit. With such longitudinal compensation grate elements can then Also slab formwork systems are built, which in the direction the side member individual, different from the grid Dimensions have. Specifically, it is by the arrangement of or the crossbeam in only one end region of the longitudinal beams possible, the Longitudinal compensation grid elements with her or the cross members opposite crossbeam free Side between two adjacent side members of a standard or a cross-compensation grate element over the insert the required distance. The insertion must at least so far that the cross-beam free Ends of the longitudinal compensation grate element on crossbeams a standard or a cross-compensation grate element to lie come. Maximum can the longitudinal compensation grate elements so be pushed far until their cross member or their cross member to the crossbeams a standard grate element or a cross-compensation grate element nudge. Between these two extreme positions are infinitely arbitrary Insertion positions selectable, in order to produce individual dimensions in the direction of the longitudinal members here to be able to.

The Longitudinal compensation grid elements can be inserted when the standard grate elements adjoining them and / or Cross balancing grate elements are already mounted. That's it possible, that with mounted slab formwork or the cross member of a Longitudinal compensation grid element are arranged externally relative to the overall formwork, wherein the side members of the Longitudinal compensation grid element point inwards. Alternatively, however, it is also possible to have one Longitudinal compensation grate element of the Bottom of another rust element forth with its cross-beam free end progressing from the inside out a crossbeam to push the other grate element, so that the side members of the Longitudinal compensation grid element ultimately in the mounted position over the cross member of the other grate element to the outside addition collar.

Further it is preferred if in the context of the slab formwork system according to the invention also Kombiausgleichs grate elements are still provided, which only in one of the two opposite end portions of the side members a or more compared to the longitudinal balance grate elements have arranged offset inwardly cross member. With such combi-compensation grate elements can thus simultaneously a transverse compensation and a longitudinal compensation created become. This will be illustrated in the description of the figures.

If according to the invention next Standard grate elements Cross compensation grate elements, longitudinal compensation grate elements and combi-balance grate elements can be used in certain Installation situations a constellation exist, in which a side member of a Cross compensation grid element, a side member of a Longitudinal compensation grid element and also a side member of a Kombiausgleichs grate element between two adjacent side rails of a Standard rusting elements come to rest. In this case then the Distance between adjacent side members of a Standard grate element amount to at least three times the width of the side members.

Basically it is preferred if adjacent side members of all Grate elements are each spaced in the same way from each other and / or if the side members of all Grate elements have mutually equal lengths.

Advantageous it is also, if Stirnabschalungsträger between the end regions two adjacent side members to this are fastened. In this way, then Stirnabschalungen on these Stirnabschalungsträgern be mounted, which is perpendicular to the actual formwork skin extend and thus a receiving area for the applied to the formwork Limiting concrete and frame. Such can be particularly easy Stirnabschalungsträger mount when the particular peripheral edge region of a mounted Slab formwork formed almost exclusively by longitudinal members is, which run perpendicular to the respective edge region. In this Case can then mounted at any point between adjacent side rails Stirnabschalungsträger become.

It is particularly preferred if a side rail of at least one cross-compensation grate element is longer than the distance between two cross members of a standard grate element, wherein at the same time the remaining side members of the respective cross-compensation grate element are dimensioned shorter than the distance between two cross members of a standard grate element , This design of a cross-compensation grate element ensures that during assembly, the cross-compensation grate element does not have to be threaded completely over the head into a standard grate element. Rather, it is possible to position the cross-compensating grate element in a substantially vertically aligned position with the longer side member above a cross member of a standard grate element, then hochzuschwenken in a further substantial union vertical position and then with the other end of the longer side member to position above another cross member of the standard grate element, so that the cross compensation grate element is vertically suspended coupled to the standard grate element. Subsequently, the transverse compensation grate element can then be pivoted into a substantially horizontal position. In the latter pivoting process, at the conclusion of the fitter must ultimately turn over work, then a large part of the weight of the cross compensation grate element is already taken up by the cross members of the standard grate element, so that there is a much easier handling for the fitter. The said principle will be described below on the basis of 9 to 12 explained in more detail.

at the latter preferred embodiment of the invention It continues to be beneficial if only one of the very outside Side member of a Cross compensation grate element longer is formed as the remaining side members of the respective cross-compensation grate element. By this measure is achieved that the cross compensation grate element when threading the longer side member in a standard grate element only over one preferably low altitude must be raised.

The longer side member of a transverse compensation grate element can with its two end over the ends of the shorter longitudinal member of the respective cross-compensation grate element adjacent to it. Thus, it can be ensured that the remaining, shorter side members of the cross-compensation grate element do not collide with cross members of a standard grate element when the cross-compensating grate element is pivoted into its horizontal position.

The longitudinal extension the longer one Longitudinal member one Cross compensation grid element can essentially the distance of the opposite outer sides two cross beams a standard grate element correspond. In this way it is achieved that the longer one Side member of the transverse compensation grate element in its assembled position does not protrude beyond the longitudinal members of that standard grate element, in which he was threaded.

Of the longer Longitudinal beams owns preferably a smaller cross section and in particular a smaller one Height as the remaining side members of a cross compensation grate element, this cross section is in particular rectangular. Especially It is advantageous if the diagonal dimension of the longer longitudinal member is less than the height of the remaining longitudinal members. hereby it is achieved that the cross-compensating grate element also and can be switched off when on the standard grate element, with which the cross-compensation grate element is or is coupled, a formwork skin rests. The longer one Side member then hits namely due to its dimensions when pivoting the Cross compensation grate element not on the underside of this formwork skin at.

Further preferred embodiments The invention are described in the subclaims.

The Invention will now be described with reference to exemplary embodiments with reference explained on the drawings; in these show:

1 a three-dimensional view of a standard grate element,

2 a three-dimensional view of a cross-compensating grate element,

3 a three-dimensional view of a longitudinal compensation grate element,

4a C shows schematically illustrated method steps during the assembly of a cross compensation grate element on a standard grate element,

5 a plan view of a completely assembled inventive slab formwork system,

6a a three-dimensional view of a standard grate element, which is coupled with a longitudinal compensation grate element before completion of the assembly,

6b a view according to 6a after completion of the assembly,

7 a three-dimensional view of a combi-compensation grate element,

8th a top view of four mutually different, coupled together grate elements,

9 3 shows a three-dimensional view of a cross-compensation grate element to be coupled with a standard grate element according to a preferred embodiment in a first assembly step,

10 a view according to 9 at a second assembly step,

11 a view according to 9 at a third assembly step, and

12 a plan view of an arrangement of six standard grate elements and three cross-compensation grate elements, which according to the 9 to 11 coupled with each other.

1 shows a standard grate element 2 , Which consists of a total of six parallel and spaced from one another longitudinal members 4 and two crossbeams 5 consists. The two crossbeams 5 extend perpendicular to the side rails 4 , each with a cross member 5 in each of the two opposite end portions of the side members 4 is attached.

2 shows a cross balancing grate element 6 , which also consists of six parallel and spaced from each other longitudinal members 8th and two perpendicularly extending cross members 10 consists. The side members 10 however, the cross balancing grate element is compared to the standard grate element 2 according to 1 arranged offset inwards so that they ultimately not in the front end portions of the side members 8th to come to rest. The said offset of the cross member 10 is significantly larger than the width of the cross member 5 the standard grate element 2 Preferably, the offset is about three times the said width (eg, about 13 cm).

Alternatively to an arrangement according to 2 it would also be possible, just a single cross provide carrier, which would then be arranged in the manner mentioned also offset inwards. In particular, such a single cross member could also be centered on the longitudinal members 8th be provided.

3 shows a longitudinal compensation grate element 12 , which in turn consists of six parallel and spaced apart longitudinal beams 14 and two perpendicularly extending cross members 16 consists. The crossbeams 16 However, in this case, both are in the same front end region of the side members 14 arranged, resulting in that the opposite end-side end region of the side members 14 is designed transversely free. Instead of the two in 3 illustrated cross member 16 can only one such cross member 16 come to use, the embodiment with two cross beams 16 However, with regard to the stability of the longitudinal compensation grate element 12 advantageous.

The mutual distance between adjacent side members 4 . 8th . 14 is with all rust elements 2 . 6 . 12 same size. Likewise, all have longitudinal members 4 . 8th . 14 all rust elements 2 . 6 . 12 each same length. This leads to that of the entirety of the side members 4 . 8th . 14 a grate element 2 . 6 . 12 each with the same size areas can be covered. Ultimately, therefore, all have rust elements 2 . 6 . 12 mutually equal sizes.

The top of the side members 4 . 8th . 14 forms in the assembled state of the grate elements 2 . 6 . 12 a support surface for an ultimately applied formwork, which may for example consist of wood flooring, which in a suitable manner with the top of the side members 4 . 8th . 14 get connected.

Both for the side members 4 . 8th . 14 as well as for the crossbeams 5 . 10 . 16 each open profiles or hollow sections can be used, with all longitudinal beams 4 . 8th . 14 the same profile shape can be used. Similarly, a particular profile shape for all cross member 5 . 10 . 16 be used. The profile shape of the longitudinal members, 4 . 8th . 14 However, this may be due to the profile shape of the cross member 5 . 10 . 16 differ.

For all rust elements 2 . 6 . 12 are the crossbeams 5 . 10 . 16 in the assembled state of a slab formwork completely below the respective side members 4 . 8th . 14 , which means that the side members 4 . 8th . 14 extending in a different plane than the cross member 5 . 10 . 16 However, the two said levels are adjacent to each other.

Longitudinal and cross member 4 . 8th . 14 ; 6 . 10 . 16 For example, they can be welded, bolted or riveted together.

If a cross compensation grate element 6 with an already installed standard grate element 2 is to be coupled, according to 4a a respective desired number of longitudinal members 8th of the transverse compensation grate element 6 between each adjacent side member 4 a standard grate element 2 threaded until the ends of the threaded side rails 8th of the transverse compensation grate element 6 above a crossbeam 5 the standard grate element 2 are located. This position is in 4a shown. Starting from this position then the cross compensation grate element 6 in the direction of the arrow around one in the area of the cross member 5 extending axis to be pivoted upward until the side members 8th of the transverse compensation grate element 6 in the same plane as the side members 4 the standard grate element 2 , This position is in 4b shown. According to 4b it becomes clear that the side members 4 . 8th the two grate elements 2 . 6 not flush in this assembly stage mitein other, rather collar the ends of the side members 8th of the transverse compensation grate element 6 over the ends of the side members 4 the standard grate element 2 out.

Starting from this, in 4b The position shown is then the cross compensation grate element 6 in the direction of arrow according to 4b moved linearly until the end faces of the side members 4 . 8th both grate elements 2 . 6 aligned with each other, as well as in 4c is shown. Due to the inwardly offset arrangement of the cross member 10 at the cross compensation grate element 6 will that be in connection with 4 described threading a cross compensation grate element 6 in a standard grate element 2 possible without the cross member 5 . 10 both grate elements 2 . 6 collide with each other.

5 shows a plan view of a fully assembled inventive slab formwork system, which uses grate elements of two different types in two different sizes. The different sizes of the grate elements 2 . 6 . 12 on the one hand and 2 ' . 6 ' On the other hand, it is realized that the side members of said grate elements have different lengths. Concretely, the length of the longitudinal members of the grate elements 2 ' . 6 ' about half the length of the longitudinal members of the grate elements 2 . 6 . 12 , The distance between adjacent side rails is at all grate elements 2 . 6 . 12 . 2 ' . 6 ' equal. All rust elements 2 . 6 . 12 . 2 ' . 6 ' each have six side members, which results in all the grate elements 2 . 6 . 12 . 2 ' . 6 ' have the same widths.

The slab formwork according to 5 closes to a wall 18 on, out of a total of seven, each because it is arranged at right angles to each other sections. Furthermore, the slab formwork system shown also includes two free-standing columns 20 . 20 ' which is spaced from the wall 18 are arranged.

For easier explanation of the structure of the slab formwork system according to 5 the adjoining edge portions of the slab formwork system are indicated by consecutive letters which will be referred to below.

The basis of the slab formwork system according to 5 is made up of a total of sixteen adjoining standard grate elements 2 formed, which are arranged in a 4 × 4 matrix and thus the largest part of the surface of the slab formwork system according to 5 cover. Five of these standard grate elements 2 form the edge sections A and B.

In the region of the edge section C, two transverse compensating grate elements adjoining one another in the direction of the longitudinal members are provided 6 provided, each with a standard grate element 2 are toothed by the cross balancing grate elements 6 according to 4 in the standard grate elements 2 were threaded. Regarding both cross balance grate elements 6 in each case two longitudinal members between adjacent longitudinal members of the respective standard grate elements 2 to lie.

The edge sections D and F are from a longitudinal compensation grate element 12 formed, which so far in a cross-compensating grate element 6 is inserted, that the free ends of the longitudinal members of the longitudinal compensation grate element 12 on a cross member of the transverse compensation grate element 6 support. Three longitudinal members of the longitudinal compensation grate element 12 come between each two adjacent longitudinal members of the cross-compensation grate element 6 whereas the three other longitudinal members of the longitudinal compensation grate element 12 in each case between a longitudinal member of the transverse compensation grate element 6 and a side member of that standard grate element 2 to come to rest, which with that Querausgleichs grate element 6 is toothed, on the cross member, the side members of the longitudinal compensation grate element 12 support.

The edge portion G is from a further longitudinal compensation grate element 12 formed, which so far with two longitudinal beams in the respect to the edge portion D called longitudinal compensation grate element 12 inserted is that the cross member of the two longitudinal compensation grate elements 12 to come into contact with each other in sections. The free ends of the edge portion G forming longitudinal compensation grate element 12 are on a cross member of that standard grate element 2 supported, which with the part of the edge portion C forming Querausgleichs grate element 6 interlocked.

The edge portion H is of two further longitudinal compensation grate elements 12 formed, which in two in the transverse direction adjoining standard grate elements 2 pushed so far that the significantly larger portion of the side members of the said longitudinal compensation grate elements 12 between the two cross members of the standard grate elements 2 in which said longitudinal compensation grate elements 12 were inserted.

Another longitudinal compensation grate element 12 forms the comparatively short edge portion I and in turn a further longitudinal compensation grate element 12 the edge section K. When installing the longitudinal compensation grate elements 12 , which form the edge portions H, I, K, must be proceeded such that first the longitudinal compensation grid element forming the edge portion K 12 , then the longitudinal compensation grid element forming the edge section I 12 and finally, the two longitudinal compensation grid elements forming the edge section H. 12 in the already mounted standard grate elements 2 be inserted.

All previously explained edge sections A to K are of grate elements 2 . 6 . 12 formed, which belong to a first type of grate elements. By contrast, the edge sections L to Q mentioned below are made of grate elements 2 ' . 6 ' formed belonging to a second type of grate elements. The grate elements of the second type correspond to the length of the respective side members of the grate elements of the first type. The longitudinal members of the grate elements 2 . 6 . 12 of the first type are about twice as long as the longitudinal members of the grate elements 2 ' . 6 ' of the second type.

In the edge portions L to P forming grate elements 2 ' . 6 ' the side members are perpendicular to the longitudinal members of those grate elements 2 . 6 . 12 which form the edge sections A to K. This close the grate elements 2 ' . 6 ' but directly to rust elements 2 . 12 on, so that between the grate elements 2 . 12 of the first type and the grate elements 2 ' . 6 ' the second type no gap exists.

The edge section M is made of two standard grate elements 2 ' formed, wherein in each of these two standard grate elements 2 ' in the manner already explained in each case a cross-compensating grate element 6 ' was threaded. This the edge section L forming transverse compensation grate element 6 ' was doing so in the corresponding standard grate element 2 ' threaded, the total of three side members of the cross-compensation grate element 6 ' between the respective longitudinal members of the standard grate element 2 ' to come to rest. The comparatively short, to a schematically illustrated column 20 ' adjoining edge portion N forming transverse compensation grate element 6 ' on the other hand, it is arranged such that a total of five of its longitudinal members are connected between the respective side members of a standard grate element 2 ' are located.

As in the illustrated slab according to 5 the distance between two adjacent longitudinal members of a grate element corresponds to three times the width of the side members, transverse grating elements threaded in standard grate elements can still be displaced in a direction perpendicular to their longitudinal members by a maximum of twice the width of the longitudinal members, thus ultimately fine-tuning to achieve the cross compensation to be achieved. For example, it is off 5 it can be seen that the side members of that cross-compensating grate element 6 ' , which forms the edge portion N, approximately in the middle between two adjacent side rails of the respective standard grate element 2 ' whereas the side members of the cross-compensation grate element 6 ' , which forms the edge portion L, directly to the respective longitudinal members of the associated standard grate element 2 ' issue.

The edge portion P is of a total of five directly adjacent standard grate elements 2 ' formed, the cross member abut the front side directly to each other. In the closest to the pillar 20 ' arranged standard grate element 2 ' is in turn a cross-compensating grate element 6 ' threaded, which forms the edge portion O.

The on another pillar 20 adjacent edge portion Q eventually becomes another cross-balancing grate element 6 ' of the second type formed into a standard grate element 2 the first type is threaded. This shows that cross balancing grate elements of the second type can also be incorporated into standard grate elements of the first type.

The 6a , b show an already installed standard grate element 2 with side rails 4 and crossbeams 5 in which according to 6a a longitudinal compensation grate element 12 is threaded from below such that first the free ends of the side members 14 of the longitudinal compensation grate element 12 between the side members 4 the standard grate element 2 plugged in and then over a crossbeam 5 the standard grate element 2 be pushed and finally pivoted, so that ultimately the side members 14 of the longitudinal compensation grate element 12 according to 6b over the side members 4 the standard grate element 2 Collar out. In the assembled position according to 6b lies the top of the cross member 16 of the longitudinal compensation grate element 12 at the bottom of the side members 4 the standard grate element 2 at. In this way it is ensured that when pressure is applied to the over the side members 4 also cantilevered ends of the side members 14 of the longitudinal compensation grate element 12 no tilting of the same can take place.

7 shows a combi-compensation grate element 22 whose shape is substantially that of a longitudinal compensation grate element 12 according to 3 equivalent. The only difference is that the cross members 26 the combi-compensation grate element with respect to a longitudinal compensation grate element 12 are arranged offset inwards, said offset can correspond to that measure, to which also the cross member 10 a cross compensation grate element 6 are offset inwards. A combi-compensation grate element 22 can alternatively also with only one cross member 26 be equipped.

8th shows how a combi-balance grate element 22 according to 7 can be used to simultaneously realize a longitudinal compensation and a transverse compensation.

According to 8th are in a standard grate element 2 the longitudinal members of a longitudinal compensation grate element 12 inserted so far that the longer region of the longitudinal members of the longitudinal compensation grate element 12 between the longitudinal members of the standard grate element 2 located. It also became the standard grate element 2 a cross compensation grate element 6 threaded so that there are two side members of the cross-compensation grate element 6 approximately midway between longitudinal members of the standard grate element 2 are located. Thus, by the longitudinal compensation grate element 12 individual dimensions in the direction of the longitudinal members of the standard grate element 2 realized, whereas with the cross-compensating grate element 6 individual dimensions can be realized perpendicular thereto.

In order to ultimately create a total rectangular grate surface with individual length and individual width, it is necessary in the already explained arrangement according to 8th also a combi-compensation grate element 22 use. The free ends of the longitudinal members of such a combination compensation grate element 22 be first from below between the longitudinal members of the longitudinal compensation grate element 12 moved and then over the respective cross member of the standard grate element 2 and the cross compensation grate element 6 pushed until the Combination compensation grid element 22 can be pivoted in that plane in which the already mounted grate elements 2 . 6 . 12 are arranged. After this pivoting is a cross member of the Kombiausgleichs grate element 22 in sections on a cross member of the longitudinal compensation grate element 12 at. The fact that the cross member of the combi-compensation grate element 22 opposite the cross members of the longitudinal compensation grate element 12 offset inwards, it is possible, longitudinal compensation grate element 12 and combi-balance grate element 22 Position each other so that their respective side rails are aligned flush with each other.

9 shows in three-dimensional view a standard grate element 2 , which in its four corner areas each have a vertical support 28 supported on the bottom side. The standard grate element 2 according to 9 is thus in a horizontal orientation.

Further shows 9 a preferred cross-compensating grate element 30 , which consists of six shorter side rails 32 , a longer side member 34 and two the side members 32 . 34 supported from below cross members 10 consists. The crossbeams 10 extend perpendicular to the side rails 32 . 34 and are opposite the end faces of the shorter side members 32 arranged slightly inwards. The shorter side members 32 are shorter than the distance between the facing inner sides of the cross member 5 the standard grate element 2 , The longer side member 34 has approximately the same length as the side members 4 the standard grate element 2 ,

Due to the said arrangements and dimensions, it is possible, at substantially vertical, in 9 shown alignment of the transverse compensation grate element 30 one end of the longer side member 34 above a crossbeam 5 the standard grate element 2 to position. Then then the cross compensation grate element 30 pivoted upward in further substantially vertical orientation and then in the longitudinal direction of the longer side member 34 be moved so far until the other end of this side member 34 above the other cross member 5 the standard grate element 2 comes to rest, as in 10 is shown. In this position depends on the cross equal-rust element 30 with its side member 34 on the standard grate element 2 substantially vertically downwards.

Starting from the position according to 10 can the cross compensation grate element 30 then around the longitudinal axis of the longitudinal member 34 be pivoted upward, as indicated by the in 11 illustrated arrow is illustrated. With a continued pivoting of the cross-compensation grate element 30 in the direction of the arrow 11 ultimately hit the tops of the cross member 10 of the transverse compensation grate element 2 on the undersides of the side members 4 the standard grate element 2 so that then both the standard grate element 2 as well as the cross compensation grate element 30 in a common plane in a substantially horizontally oriented position.

The latter position is in 12 illustrated, according to the three cross-compensation grate elements 30 with three standard grate elements 2 coupled, this coupling according to the in connection with the 9 to 11 accomplished process steps was accomplished.

It is readily apparent that the last-described coupling method is easier to handle for a fitter than overhead threading of all the side members 8th a cross compensation grate element 6 according to 2 ,

2

Standard grate element

4

Side member of a Standard grid element

5

Cross member of one Standard grid element

6

Cross compensation grid element

6 '

Cross compensation grid element

8th

Side member of a Cross compensation grid element

10

Cross member of one Cross compensation grid element

12

Longitudinal compensation grid element

14

Side member of a Longitudinal compensation grid element

16

Cross member of one Longitudinal compensation grid element

18

Wall

20

pillar

20 '

pillar

22

Combination compensation grid element

24

Side member of a Combination compensation grid element

26

Cross member of one Combination compensation grid element

28

vertical supports

30

Cross compensation grid element

32

shorter side members

34

longer side member

Claims (17)

Slab formwork system with several grate elements ( 2 . 2 ' . 6 . 6 ' . 12 . 22 . 30 ), each of a plurality of mutually parallel longitudinal members ( 4 . 8th . 14 . 24 . 32 . 34 ) and at least one on vertical supports ( 28 ) mounted or suspended transverse to the longitudinal beams ( 4 . 8th . 14 . 24 . 32 . 34 ) extending cross member ( 5 . 10 . 16 . 26 ), characterized in that the longitudinal and transverse beams ( 4 . 8th . 14 . 24 . 32 . 34 ; 5 . 10 . 16 . 26 ) of the grate elements ( 2 . 2 ' . 6 . 6 ' . 12 . 22 ) are rigidly connected to each other, whereby standard grate elements ( 2 . 2 ' ) two in the mutually remote end portions of the side members ( 4 ) provided cross member ( 5 ), while cross-compensating grate elements ( 6 . 6 ' . 30 ) one or two compared to the standard grate elements ( 2 . 2 ' ) offset inwardly arranged cross member ( 10 ). Ceiling formwork system according to claim 1, characterized in that when mounted slab form a longitudinal beam ( 8th . 32 . 34 ) of a transverse compensation grate element ( 6 . 6 ' . 30 ) between two adjacent side members ( 4 ) of a standard grate element ( 2 . 2 ' ) comes to rest. Slab formwork system according to one of the preceding claims, characterized in that the longitudinal members ( 4 ) of the standard grate elements ( 2 . 2 ' ) have the same length as those of the cross-balancing grate elements ( 6 . 6 ' . 34 ). Ceiling formwork system according to one of the preceding claims, characterized in that the distance between adjacent longitudinal members ( 4 . 8th . 14 . 24 . 32 . 34 ) of the grate elements ( 2 . 2 ' . 6 . 6 ' . 12 . 22 . 30 ) at most 20 cm and at least the simple, preferably at least three times the width of the longitudinal members ( 4 . 8th . 14 . 24 . 32 . 34 ) is. Slab formwork system according to one of the preceding claims, characterized in that longitudinal compensation grate elements ( 12 ) only in one of the two opposite end regions of the longitudinal members ( 14 ) one or more cross members ( 16 ) exhibit. Ceiling formwork system according to one of the preceding claims, characterized in that when mounted slab formwork both a side member ( 8th . 32 . 34 ) of a transverse compensation grate element ( 6 . 6 ' . 30 ) as well as a side member ( 14 ) of a longitudinal compensation grate element ( 12 ) between two adjacent side members ( 4 ) of a standard grate element ( 2 . 2 ' ) come to rest. Ceiling formwork system according to one of the preceding claims, characterized in that when mounted ceiling formwork or the cross member ( 16 ) of a longitudinal compensation grate element ( 12 ) are arranged inside or outside. Slab formwork system according to one of the preceding claims, characterized in that combi-compensation grate elements ( 22 ) only in one of the two opposite end regions of the longitudinal members ( 24 ) one or more compared to the longitudinal compensation grate elements ( 12 ) offset inwardly arranged cross member ( 26 ) exhibit. Slab formwork system according to one of the preceding claims, characterized in that when mounted slab form a longitudinal member ( 8th . 32 . 34 ) of a transverse compensation grate element ( 6 . 6 ' . 30 ), a side member ( 14 ) of a longitudinal compensation grate element ( 12 ) and also a longitudinal member ( 24 ) of a combination compensating grate element ( 22 ) between two adjacent side members ( 4 ) of a standard grate element ( 2 . 2 ' ) come to rest. Ceiling formwork system according to one of the preceding claims, characterized in that Stirnabschalungsträger between the end regions of two adjacent side members ( 4 . 8th . 14 . 24 . 32 . 34 ) are attachable to these. Ceiling formwork system according to one of the preceding claims, characterized in that the in particular peripheral edge region of a mounted slab formwork by longitudinal members ( 4 . 8th . 14 . 24 . 32 . 34 ) is formed, which are perpendicular to the respective edge region. Ceiling formwork system according to one of the preceding claims, characterized in that a longitudinal member ( 34 ) at least one cross-compensating grate element ( 30 ) is longer than the distance between two cross members ( 5 ) of a standard grate element ( 2 ), and that the remaining side members ( 32 ) of the respective transverse compensation grate element ( 30 ) are shorter than the distance between two cross members ( 5 ) of a standard grate element ( 2 ). Ceiling formwork system according to claim 12, characterized in that only one of the very outer longitudinal members ( 34 ) of a transverse compensation grate element ( 30 ) is longer than the remaining side members ( 32 ) of the respective transverse compensation grate element ( 30 ). Slab formwork system according to one of claims 12 or 13, characterized in that the longer side member ( 34 ) of the respective transverse compensation grate element ( 30 ) with its two end regions over the ends of the longitudinal member ( 32 ) of the respective transverse compensation grate element ( 30 ) survives. Ceiling formwork system according to one of claims 12 to 14, characterized in that the longitudinal extent of the longer longitudinal member ( 34 ) of the respective transverse compensation grate element ( 30 ) substantially the distance of the mutually remote outer sides of two cross members ( 5 ) of a Stan dard grate element ( 2 ) corresponds. Ceiling formwork system according to one of claims 12 to 15, characterized in that the longer side member ( 34 ) has a smaller cross-section and in particular a smaller height than the remaining longitudinal members ( 32 ). Slab formwork system according to one of claims 12 to 16, characterized in that the longer side member ( 34 ) has a rectangular cross-section, wherein in particular its Diagonalmaß is less than the height of the remaining longitudinal members ( 32 ).