DE2905165A1 - Three dimensional concrete building unit - has spaced interfacing sections swinging together, with mutual end support - Google Patents

Abstract

Two sections in a spatial arrangement relative to each other form an inherently stable three-dimensional load bearing entity. They are used in a building unit, esp. constructed of concrete. Interfacing and surfaces of two individual components forming these sections are at a predetermined interval apart in a finishing plane, and connected by a lost turning hinge joint, to swivel together. The pivotal point (D) is selected so that when the sections are swung in, part of the end face of one is supported on a surface section on the top or bottom of the other. This is widely adaptable, and compact for transport, but requires only simple formwork.

Description

Spatial structure The invention relates to spatial structures, in particular made of concrete from at least two structural sections arranged spatially to one another, which form a stable space structure.

To produce such spatial structures were previously constructive and in terms of cost, particularly complex formwork brackets are necessary, which also often were limited to the production of a certain type of structure. The high demands to the stability and the dimensional accuracy with the simultaneous possibility of the mechanical Tapering for better stripping required particularly precise formwork constructions, which were only profitable in large series.

Apart from the very complex production of the known spatial Structures are these between the place of manufacture and the place of use only on a special basis awkward and costly manner transportable, with the required transport space can only be used insufficiently particularly uneconomical because of the large amount of space it takes up.

The object of the invention is therefore to provide a spatial structure of the indicate the type mentioned at the beginning, which only requires a simple formwork body, which is suitable for a wide variety of building types and where the transport the structure with optimal utilization of the transport space no particular difficulties more prepares. At the same time, the space needed to store the building structure should be be significantly reduced in size.

The object is achieved in that the one another facing end faces of two individual components forming the building section have a predetermined distance from each other in a production level and over a lost swivel joint swiveling clear connected to each other are, wherein the three-point position is chosen such that in the spatial Shape of the structure pivoted individual components at least a part of the end face of the one component is at least on a surface section on the upper or Supports the underside of the other component.

Provide advantageous embodiments and developments of the invention from the features of the subclaims and from the following description for exemplary embodiments which are only used to better explain the underlying of the invention Serve the idea without restricting the invention to these exemplary embodiments and which are shown schematically in a drawing. Fig. 1 shows a serine lying in its production level, not yet pivoted into its spatial shape Building structure according to the invention in plan view, Fig. 2 shows a detail from plan view in an enlarged view, FIG. 3 shows a section along the lines III-III in FIG. FIG. 4 shows a section along lines IV-IV in FIG. 2, FIG. 5 shows a section along the lines the lines V-V in Fig.2, Fig. 6 unfolded into its final spatial shape Structure according to FIG. 1 in the detail and in the sectional plane according to FIG. 3, FIG. 7 of the The structure according to FIG. 1, unfolded into its final spatial shape, is shown in detail and in the sectional plane according to FIG. 4, Fig. 8 of the in its final spatial shape unfolded building structure according to Fig. 1 in the cutout and in the Scllittebene according to FIG. 5, FIG. 9, the sectional view of the structural section according to FIG. 8 is attached on the upper end of a vertical wall section; to another building according to Fig. 1 can belong.

FIG. 10 shows the sectional view of the lower part of the structure according to FIG. 9, FIG. 11 shows a section of a further structure according to the invention in a sectional view accordingly Fig. 3 and 6 in its production position and in its unfolded spatial shape, FIGS. 12-16 sections of further structures according to the invention in sectional views corresponding to FIG. 11 in their production positions and in their unfolded positions spatial shapes, FIG. 17 two opposite sections of the invention Structure in sectional views corresponding to FIG. 8, the two structures on stand on a foundation, Fig. 18, two stacked one on top of the other in their production levels Structures ready for transport according to FIG. 1 in a perspective view, FIG. 19 a cross section along the lines IX - IX in Fig.18, Fig. O the simultaneous lifting three building structures stacked one on top of the other in their production levels Fig. 1 in a perspective view 21 the unfolding of the top of the three structures according to FIG. 20 in its spatial shape and FIG. 22 the stacking of the same structures that have been given their spatial shape 21 in side view.

Fig. 1 shows a plan view of a manufactured in one plane three-part structure, which is still in its production level and out of this can be opened into its spatial shape. There is more in detail Structure from a flat rectangular ceiling or floor part 2 and two on the side adjacent rectangular wall parts 3 and 4, which are used when assembling the structure can be unfolded from the drawing plane into vertical positions. To do this, close the wall parts 3 and Lt via articulated connections 5 and 6 to the base part 2. in the Example cases are the wall parts via two articulated connections 5 and 6 to the Bottom part 2 connected. The axes of rotation 7 and 8 of the articulated connections run parallel to the narrow sides of the bottom part 2 within recesses 9 and 10 in the narrow sides of the bottom part 2. The recesses 9 and 10 become the bounded on both long sides by projecting bottom sections 11, 11 and 12, 12, on which the unfolded wall sections come to support, so that the joints are only loaded when the wall parts are swung open. In the recesses 9 and 10 the ends 13, 14, 13 'and 14' of BewGrungseisen protrude, which are mutually offset lie uni are connected to each other by cross bars, which will be discussed below will be discussed in more detail. In the unfolded state, the recesses 9 and 10 potted with concrete, whereby the wall parts over the reinforcements firmly to the bottom part are connected with the wall parts after the concrete has hardened in the Recesses 9 and 10 forms a stable stool-like space structure in which the Articulated connections 5 and 6 are lost and attached to the reinforcement in the nodal points take part.

It is clear that the reinforcing bars 13, lit, 13 'and 14' are in the Junction points are unnecessary if the joints 5 and 6 aureiciieiid strong are formed and rlae the nuiltiappcrl of the side walls by welding or Screw together to form rigid angles. This can especially be the case if pro Connection more than two joints 5 and 6 are present or if the joint connections 5 and 6 are combined to form a wide hinge joint.

Fig. 2 shows a detail from Fig. 1 with the articulated connection 5 in an enlarged view. The joint connection consists of flat joint iron 16 and 17, which are firmly anchored in the bottom part 2 and in the wall part 3 and their free The ends grip into the recess 9 of the bottom part 2. These free ends are in Area of the recess 9 articulated to one another, which is indicated by the dash-dotted line Line 18 should be indicated. The joint can be a rod, with one end articulated through holes 19 and 19 'in the free ends of the a pair of hinges 16 and 17 grip. The other end of the rod then engages articulated through corresponding holes in the free ends of the other pair of hinge pins, which forms the second articulation 6 (Fig. 1). It is clear that instead of two Articulated connections also several articulated connections can be present, which through a common pivot pin or pivot rod are connected to one another. Instead of a common pivot pin or pivot rod, it can also be be individual bolts lying in one axis.

As already mentioned, the articulated connections 5 and 6 can also be wide Form hinge bars. A multitude of possible solutions are available to the person skilled in the art which cannot all be listed here in detail. The invention is in any case not limited to the versions shown.

The ends 13 and 14 of the rebar are different here than in Fig. 1 relatively close to one another, in the unfolded position of the wall part 3 are connected to each other before the recess 9 is poured with concrete. It it is clear that the relatively wide recesses 9 and 10 are each narrowed by two Recesses can be replaced in which the ends the articulating iron 16 and 17 find space for an articulated connection.

This assumes that the continuous swivel rod through individual Hinge pin is replaced per GeIeilv'rbiiiduiig. A continuous swivel rod but is still possible if the joint rod is through a through hole engages in the bottom part, which according to the invention consists of a lost metal or plastic sleeve is formed that when manufacturing the structure in the formwork body in their predetermined Position for the later swivel joint is held. The ends can accordingly the pivot point in round holes in the projecting bottom sections 11 and 12 intervene. According to the invention, these holes can consist of sleeves or pipe sections Metal or plastic can be formed when the structure is manufactured from the formwork body be held in a predetermined position.

With an outer wall cladding is referred to.

FIG. 3 shows a section along the line III-III in FIG. 2.

While the front end face 21 on the bottom section 12 of the bottom part 2 forms a right angle with its outer surface 22, is the opposite End face 23 of wall part 3 beveled at angle 24. To a corresponding Angle 24 is the support surface 25 beveled on the inner surface 26 of the bottom part. On the support surface 25, the beveled end face 23 comes in the pivoted open Position of the wall part 3 to lie, as can be seen below with reference to FIG is.

The position of the axis of rotation of the swivel joint between the base part 2 and the wall part 3 is denoted by D. As explained in more detail with reference to FIG. 11 the two end faces 21 and 23 have the distance "2d-s" if "s" the thickness or height of the bottom part 2 and ?? d1? the shortest distance of the inner surface 26 of the bottom part 2 is from a horizontal plane through the axis of rotation. The exterior wall cladding 20 is in the area of the projecting sections 11 and 12 for connecting a wall part omitted, as shown in the following alalld of FIG.

FIG. 4 shows a section along the lines IV-IV in FIG. 2.

The joint iron 16 and 17 can be seen here as flat iron.

The sufficient anchoring of the hinges in the bottom part 2 and the wall part 3 are not shown in detail and require neither further explanation. The holes 19 and 19 'in the free ends of the hinges, of which only the hole 19 in the golf course 17 is not visible in FIG. 4 are shown as Elongated holes designed to allow manufacturing tolerances on the bottom and wall parts 2 and 3 to be able to compensate. In Fig. Lt is a hinge pin or a hinge rod, which engages through the holes 19 and 19 ', denoted by 18'. The dash-dotted one Line 18 in Fig. 2 then represents the axis of the pivot pin or the pivot rod 18 '. As already mentioned, it is clear that the ends of such hinge pins or Articulated rods can engage in sleeves made of metal or plastic, which are in the protruding sections 11, li and 12, 12 of the bottom part are embedded.

Such a joint sleeve is shown in dashed lines in FIG 28 designated. In this way, the ends of the hinge pins can be in the protruding Support sections 11, 11 and 12, 12 of the bottom part 2.

Fig. 5 shows a section along the lines V-V in Fig.2. The in Fig.1 with 13 and 14 designated ends of reinforcing iron are formed in Fig. 5 as stirrups, which overlap somewhat with their front ends, so that-between the temple ends the swivel rod 18 'can be passed through, as can be seen in FIG.

Fig. 6 shows the unfolded into its final spatial shape Structure according to FIG. 1 in the detail and in the sectional plane according to FIG. 3. This shows that the inclined face 23 of the wall part 3 on the beveled bearing surface 25 of the protruding portion 12 of the bottom part 2 comes to rest.

Fig. 7 shows the unfolded structure of FIG. 1 in detail and in the sectional plane according to FIG. 4. The hinges 16 and 17 are now substantially perpendicular to each other.

As also from FIGS. 4 and 5 and FIG. 8 to be described 9 and 9, a part of the end face of the bottom part 2 runs in the area its recess 9 beveled downwards. In this way it results in the unfolded structure an inclined feed hopper, which from the inclined surfaces 29 and 23 of the brought into their right-angled position to each other Components 2 and 3 is limited and filled into the free joint space via the concrete can be.

Fig. 8 shows the unfolded structure according to FIG. 1 in detail and in the sectional plane corresponding to FIG. 5. It can then be seen that the bow-shaped Ends 13, W14 of the reinforcing iron form a node, which is essentially a has a rectangular cross-section.

Fig. 9 shows the unfolded structure in section according to Fig. 8, with its two protruding sections on the face of a vertical Wall part 3§ rests, which belong to an unfolded structure according to FIG can. From the wall part 3 'also bow-shaped ends 31 of reinforcing iron protrude out that in gaps between the bow-shaped ends 13, 14 of the rebar of components 2 and 3 intervene.

To connect the reinforcing bars to each other, the inner four corners of the junction point distribution iron 32 used and with the rebar tied together. To insert the distributor iron 32 in in inn nodes are in at least one of the protruding sections 11, Ii and 12, 12 of the bottom part kept holes free, one of which is a hole in the protruding portion 12 in Figs. 4, 6, 7 and 8, respectively is denoted by 33.

Are the structures in the position shown in Fig. 9 and are the distributor bars 32 at the inner corners of the bow-shaped ends of the reinforcing bars attached, then the free joint space can be filled with concrete, whereby after the solidification of the concrete through the reinforcement bars in connection with the distribution bars a stable node is created.

It is clear that the outer wall cladding 20 is in the vertical section between the two wall parts 3 and 3 against the pressure in the free joint space added concrete mass is sufficiently stiffened. It can also be sufficient fix the protruding outer wall cladding sections on the reinforcing iron, as shown in Fig.iO. Here is the Attachment of a protruding Outer wall cladding is designated by 3 on a reinforcement cisctl.

The beveled surfaces 23 and 29 on the wall and the bottom part guarantee that when the concrete mass is poured into the free joint space, ' do not form dead nests5 into which no concrete penetrates.

The rebar to form a junction point across the two or - as FIG. 9 shows - three components are permanently connected to one another and are unnecessary when the hinges 16 and 17 are sufficiently stable and sufficiently firm in the Components are anchored and if the articulated iron after swinging the wall construction firmly welded or screwed together.

A joint lock in the form of wedges can also be sufficient which are driven into slots in the articulation iron, which are in the upright position of the wall part are brought to cover. There are a number of options available to those skilled in the art from solutions that do not all need to be described here the pivoting of the structure with each other firmly attached to the joint can absorb the forces at the associated junction point and reinforcing iron are not necessary in connection with distributor iron 32 according to FIG. 9, then it is sufficient if instead of the continuous relatively wide recesses 9 and 10 (Fig. 1) in the two connection surfaces of the bottom part only two or more relatively narrow recesses are provided, inside the joint iron find place in pairs. That is, between two pairs of hinges for connecting a wall part to a bottom part 2, as it is As shown in Fig. 1, a central portion may extend, which in cross section is formed corresponding to the outer sections lis 11 and 12, 12 and on the a corresponding middle section on the wall part 3 after it has been pivoted open supports.

In such a case, the continuous swivel rod for two pairs of joint irons should be replaced by two short joint bolts, one joint bolt each articulately connects two hinges. As mentioned above, can a continuous toggle rod can also be used here if in the middle Section of the bottom part 2 between two recesses for two joints a continuous There is an opening through which the toggle rod engages. This can be done during manufacture of the bottom part a sleeve or a tube made of plastic are used by which the toggle rod is passed through.

Fig. 11 shows the necessary distance of a wall part 3 from one Bottom part 2 in the horizontal position from which the wall part 3 about the axis of rotation D1 can be pivoted to take a vertical position in which his End face 23 comes to rest on the inner surface 25 of the bottom part 2.

In the embodiment in FIG. 11, the end face 23 forms the wall part 3 is at right angles to its outer surface 34.

With a strength "s" of the bottom part 2 and the wall part 3 has the upper edge 27 on the end face 23 of the wall part 3 in its horizontal Position of this edge 27 after pivoting the wall part 3 in the vertical Position a distance ?? 2dz and the two vertical end faces 21 and 23 of Floor and wall parts 2 and 3 lying in the horizontal position have the distance tt2d-s ". The axis of rotation Dz of the articulated connection between the base part 2 and the wall part 3 lies in a plane which is defined as the surface diagonal 35 from the lower D. Front edge 36 starts on the outer surface 22 of the bottom part 2 and extends up to a trailing upper line parallel to the lower front edge 36 of the vertical Front face 21 extends, the vertical distance of this line from the horizontal Outer surface 22 - and its horizontal - distance from the vertical end surface 21 each has the length tstt. So that the wall part 3 from its horizontal position is pivotable into its vertical position, the inside 25 of the bottom part 2, near its upper edge 37, its end face 21 is somewhat beveled.

How the positional relationships of the bottom part 2 and the wall part 3 with the size ratios according to Fig. 11 and an unchanged distance "2d-sn change according to FIG. 11 when the axis of rotation on the surface diagonal 35 a assumes a different position than in FIG. 11, FIGS. 12 and 13 show. According to FIG. 12 the vertical distance of the axis of rotation D2 on the surface diagonal 35 from the outer surface 22 of the bottom part 2 larger than in Fig. II, then the wall part 3 comes in the pivoted open perpendicular position above the inner surface 25 of the bottom part 2 to lie. This means, depending on the position of the axis of rotation D2 on the surface diagonal 35 above the axis of rotation D1, the wall part 3 is supported in its vertical position on an intermediate part 38 with a height hl which rests on the inner surface of the bottom part. With this one Intermediate part 38 can be, for example, an insulating part. Is the axis of rotation D3 according to FIG. 13 on the surface diagonal 35 below the axis of rotation D1 from FIG. 11, then the wall part 3 is supported in its vertical position on a horizontal surface 39 of the bottom part 2, which is lower than the inner surface by the vertical dimension h2 25 of the bottom part.

The assumption is made from the relationships in FIG. 11 and from the axis of rotation D1 laid a plane 40 which is perpendicular to the surface diagonal 35 and migrates the axis of rotation D1 on the plane 40 obliquely upwards to the position D4, then takes the wall part 3 in its vertical position the position shown in Fig. 14, in which the outer surface 34 of the wall part 3 is no longer as in the preceding ones Embodiments are aligned with the end face 21 of the bottom part 2 but compared to this by the dimension h-3 - Vor-s-6ingt. However, the turning point D1 takes up the Level 40, the lower layer D5> then has the wall part 3 in its vertical position Position the position shown in FIG. 15, in which the outer surface 34 of the wall part 3 is set back with respect to the end face 21 of the bottom part by the dimension h4.

These few exemplary embodiments according to FIGS. 11 to 15 become clearly that depending on the position of the axis of rotation of the swivel joint between the bottom (> n- and the wall part the position of the wall part in its pivoted Position elected n katiii.

Fig. 16 shows a further embodiment in which the axis of rotation at the level of the outer surface 22 of the bottom part 2 but outside the bottom part 2 is, so no longer set back with respect to the end face 21 of the bottom part 2 is, as is the case in the above exemplary embodiments according to FIGS. 11 to 15 is. If the wall part 3, which lies on a shoulder 41 in its horizontal position pivoted about the axis of rotation D5 into the vertical position, it takes the position shown in FIG. 16 position shown, in which its outer surface 34 with the end face 21 of the bottom part is aligned and where it is supported on a horizontal surface 42, the opposite the inner surface 25 of the bottom part 2 is offset by the vertical depth h5.

This additional example makes it clear that an innumerable There are a number of possible variations depending on the position of the axis of rotation advantageously runs inside the bottom part 2, but also outside of the bottom part 2 can be. It is clear that the floor and wall parts are not the need to have the same height. It is also clear that the wall part 3 not only can be pivoted into a right angle to the bottom part 2. It can be a corresponding formation of the support surface 25 of the bottom part, e.g. also via a pivot angle of 450 out into a gable-like inclined position compared to the Swivel base part 2.

Fig. 17 shows sections of two structures according to the invention accordingly Fig. 1 with vertically pivoted wall parts 3 and a horizontal bottom part 2, isolated from each other on a gemeils amcI Iundailenl; 4j 43 rest. To the complete sound insulation can also separate the foundation into two sections be, as the dashed lines 44 are intended to indicate.

Fig. 18 shows two stacked structures according to the invention, each consisting of a bottom part 2 and two wall parts 3, 3 exist, the wall parts are only swiveled open at the place of use5 around a stool-like structure To form a structure, the free joint spaces of which are filled with concrete. To the Undersides of the base parts 2 and on the later outer sides of the wall parts 3 are located wall coverings 20. By stacking two on top of each other still in their production level Spread out building structure, these are separated from one another by an outer wall cladding separated. To transport one or more structures stacked on top of each other to enable, which are still in their production level, offer a A number of possibilities, with an untimely opening or closing of the wall sections 3 is prevented. So in recesses 9 and 10 for the articulated connections Wedge-shaped bodies are used, which are only removed to pivot the wall parts calves. Furthermore, between two floor and wall parts lying on top of one another one or more dowel-like bodies can be inserted into corresponding recesses the bottom and wall parts engage, thereby causing a relative movement of two superimposed To prevent floor or wall parts.

Such a dowel-like body is denoted by 45 in FIG. 19, the here has a fir-shaped shape, which makes the upper structure slightly from the lower structure can be lifted off, but together they have a load-bearing stiffness Form unity.

Finally, the joints can also be bridged by rigid iron bars be that engage in the bottom and the wall part and to open the wall part 2 are severed.

Fig. 20 shows the simultaneous lifting of three stacked one on top of the other Structures in their production levels.

Fig. 21 shows the simultaneous unfolding of the two wall parts of the top structure of the stack in FIG. 20 and FIG. 22 shows the placement of a unfolded building structure on an unfolded one that has already been brought into an end position Structure of the same shape. After placing the upper structure on the lower one Structural members, if necessary, the distributor bars 32 (FIG. 9) are used and the free joint space filled with concrete. Until the concrete has finally hardened in the joint spaces are the wall parts 3.3 by struts 46 held on the associated base parts 2, so that a swiveling of the wall parts 3.3 is avoided in its horizontal position.

The structures according to the invention leave themselves without difficulties Manufacture in a flat formwork, with only additional devices must be available, which determines the position of the articulated connections. In a formwork In addition, several structures can be built one on top of the other, each supported by a Outer wall cladding are separated from each other.

So the two structures in Fig. 18 can be successively in a formwork be made. Here there is a simple possibility, the dowels 19 between insert the building structure.

A formwork for the production of structures according to the invention in one Level that is only given a spatial shape at the place where the building is used but is not only used to produce one or more structures of one type on top of each other. Different building types can also be and produce the same formwork inexpensively, with only the device need to be moved accordingly to fix the position of the hinge points.

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Claims (1)

Claims (1.) Spatial structure, in particular made of concrete with at least two spatially mutually arranged structural sections that have a Form a stable space structure, characterized in that the facing Front surfaces of two individual components forming the structural sections in a production level a predetermined distance (2d-s) from each other and about a lost Rotary joint connection are pivotally connected to one another, the pivot point position (D) is chosen such that the pivoted into the spatial shape of the structure Individual components at least a part of the end face of the one component is at least is supported on a surface section on the top or bottom of the other component. 2. Structure according to claim 1, characterized in that the two Individual components consist of plate-shaped buildings that are in a common formwork are made and that the joint connection consists of rigid iron parts, one ends of which are firmly anchored to the components and the other free ends are articulated together. 5. Structure according to claim 2, characterized in that the free Ends of two joint irons, each connected to a component, with a bolt are hingedly connected through openings in the free ends of the hinges engages. 4. Structure according to claim 2 or 3, characterized in that the articulation between two individual components made of at least two pairs of flat bars consists, which are arranged at a distance from each other, each one flat iron of the flat bar pairs with one component and the other flat bars of the flat bar pairs are firmly anchored to the other component and wherein the free ends of the flat iron each of a flat iron pair overlap in a hinge-like manner and through the aligned holes in the free ends of the flat irons of both Flat iron pairs engage a common bolt to form the swivel joint. 5. Structure according to claim 3 or 4, characterized in that the bolt to compensate for manufacturing tolerances by Lang-Dl.öcllol 110 (lelot o: isell, reiCt. 6. Structure according to one of claims 1 to 5, characterized in that that emerge at the end faces of the individual components reinforcement parts that are in the engage free joint space between the two individual components and in the spatial position of the two components with one another by means of inserted hinge brackets are connected. 7. Building structure according to one of claims 1 to 6, characterized in that it identifies that the axis of rotation of the swivel joint between two components within one or several end-face recesses of the one individual component is located. 8. Structure according to claim 7, characterized in that at least the upper edge of the opposite end face of the other individual component in the horizontal production level from the one component kept at the distance (2d-s) where "s" is the height of at least the one having the pivot recess Component measured from its horizontal outer surface and d "the shortest distance the upper edge of the vertical face of the component from a horizontal plane is through the pivot point. 9. Structure according to claim 7 or 8, characterized in that the joint axis within a recess of the one built-in part in a plane which is the surface diagonal from the lower front edge to the horizontal outer surface of the component goes out and is parallel to a back top line extends to the lower front edge, their distances from the vertical end face through the lower front edge and from the horizontal outer surface of the component in the are essentially the same length. 10. Structure according to claim 9, characterized in that the distances. have the length "s". 11. Structure according to one of the preceding claims 1 to 10, characterized gekenn7, calibrates that the end face on a component and the associated support surface bevelled at the same angles on the other component. 12. Structure according to claim 11, characterized in that the hinge recess in the end face of a built-in part on an inclined surface to facilitate Feeding of construction filler into the free joint space follows. 13. Structure according to one of claims 1 to 12, characterized in that that to block the articulated connection after the manufacture of the individual components in a At least one joint bridging rod is provided with the plane both components of the joint is firmly connected and to unlock the joint is severable. 14. Structure according to one of claims 1 to 12, characterized in that däß to block the articulated connection after the production of the individual components in one Level at least one loose locking body inserted into the gap between two components is removable to unlock the joint. 15. Structure according to one of claims 1 to 12, characterized in that that to block the articulated connection after the manufacture of the individual components in a Level at least two similar structures are layered on top of each other, with dowels are inserted between the components of two structures lying on top of one another, which loosely engage in the recesses lying one above the other in the components and prevent a relative displacement of the components in the support plane. 16. Structure according to one of claims 1 to 15, characterized in that that it consists of three individual components in a common formwork in one Level are made, with the middle component being a ceiling or floor body and both express Components on both sides of the middle component Form side wall parts that are connected to the middle ball part via articulated joints (lell nind and that the two outer components form a U-shaped structure are pivotable. 17. Structure according to claim 16, characterized in that the upper end faces of two vertical wall components protrude reinforcement parts that each engage in the free joint spaces of a pivoted U-shaped structure and with the reinforcement parts of the structure protruding into the joint spaces are connected and that to connect the structure with the vertical wall components the free joint spaces of the structure are filled with a building filler. 18. Structure according to one of claims 1 to 16, characterized in that that the articulated connections in the unfolded state of the structure by screw connections or welding are locked. 19. Building structure according to one of claims 1 to 18, characterized in that that the swivel joint between two components in recesses in one Component engages. 20. Device for the production of various hinged structures in one plane according to claims 1 to 19, characterized by a flat basic formwork body with a device for adjustable position fixing of at least one or more Joint jams. description