NL1009493C2 - Modular construction system. - Google Patents

Description

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MODULAR CONSTRUCTION SYSTEM

The invention relates to a modular building system for a spatial structure, comprising a number of knotting elements, structural elements to be maintained by and between those knotting elements, and coupling elements which can be coupled to a knotting element 5 and a structural element for coupling a knotting element to a knotting element structural element to be maintained, wherein at least three structural elements can be maintained from one knot element and the coupling elements extend radially from a central knot element axis.

Such a building system is known, for example, from US patent No. 4,567,707 as a skeleton for a department store. The known building system comprises a number of flat triangular knot elements with an elongated slot in each side surface, in which slot a corresponding end of a coupling element can be accommodated to form a mortise and tenon joint. Elongated structural elements can also be coupled to the coupling element, also with a mortise and tenon joint. The coupling elements in the known building system are pushed into the known knot element from an open top in the longitudinal direction of the mutually parallel slots, until they butt on a closed underside, after which the coupling elements are simultaneously secured by applying a lid to the top side. of the coupling element, which closes the slots open at the top.

With the known building system it is not possible to lock a coupling element coupled to a knot element therein before all other coupling elements to be coupled to that knot element are also arranged. Nor is it possible with the known building system to uncouple a coupling element coupled to a knot element and secured therein, without releasing the securing of other coupling elements coupled in that knot element, which in certain applications of the building system can lead to undesired or even dangerous situations. lead. For these reasons, among others, the known building system is less suitable for use in a building in which it must be possible to make changes to it in a simple manner within the life cycle of that building.

It is an object of the invention to provide a modular construction system with a rigid structure, which system is applicable for self-supporting floors and walls, and is easy and quick to assemble, for instance as an easy-to-assemble floor structure for several stands at an exhibition or scholarships.

It is also an object to provide a modular building system with which, when applied in a building, it is possible in a simple manner to make changes therein during the life cycle of that building.

It is further an object to provide a building system, the components of which, after use thereof in a building, can be used again after the demolition of that building as components of that building system in a subsequent building, whereby a strong reduction of the amount of waste resulting from the demolition of construction works.

These objectives are achieved, and the said and other advantages are achieved with a modular construction system of the type mentioned in the preamble, in which, according to the invention, each coupling element is separately secured against translation in a direction parallel to the knot element axis in the position coupled to a knot element. .

In one embodiment, the coupling elements are each provided with a hook-shaped part on an edge zone and the knot elements each comprise a sleeve which is provided with at least three slots distributed radially and circumferentially extending substantially radially and in a direction parallel to the button element axis 35 for receiving a coupling element on said edge zone, which slots are each bridged in transverse direction by a fastening element for attaching a coupling element received in its slot in a slot to its edge zone in a transverse direction.

A hook-shaped part of a coupling element attached to a fastening element in a knot element 5 deprives that coupling element of its degree of translation freedom in the longitudinal direction of the slot of that knot element.

In an advantageous embodiment of a construction system with a bush according to the invention, the bush comprises an upper disc-shaped part and a lower disc-shaped part, which parts are provided with grooves extending substantially radially inwards from the edges, with a groove in the upper part in combination with a corresponding groove in the lower part, a said slot forms substantially radially and in a direction parallel to the button element axis, and the fastening elements are received between the disc-shaped parts.

The fastening elements are provided, for example, by a ring closed in the circumferential direction of the sleeve.

In order to limit the number of parts of a sleeve and reduce the mounting costs accordingly, the disc-shaped parts and the fasteners are preferably provided by an integrated cast of, for example, cast iron or aluminum.

In a further embodiment, a sleeve designed as an integrated casting comprises an axial feed-through channel, for the passage of cables or other pipes when this bush is used in a construction system.

In the latter sleeve, if the axial feed-through channel is cylindrical and is threaded at at least one end, the sleeve can easily be coupled in axial direction with a corresponding sleeve by means of a rod or tubular element which is of a said screw thread cooperating screw thread is provided.

For example, the sleeve in these embodiments has a regular polygon in cross section, for example a 10 034 9 3 ^ 4 triangular or hexagon, or a quadrilateral or octagon, but can in principle take the form of an arbitrary polygon in cross section, or for example cylindrical.

In a bus, the number of slots regularly distributed around the circumference is 8 in one embodiment, so that the bus is applicable both in construction systems in which adjacent structural elements enclose an angle of 45 ° in that bus, and in construction systems in which adjacent structural elements in that bus have a straight enclose corner.

In a bus, the number of slots distributed regularly around the circumference in another embodiment is 12, so that the bus is applicable both in construction systems in which adjacent structural elements enclose an angle of 60 ° in that bus, as well as in construction systems in which adjacent structural elements in that bus enclose a right angle. With such a sleeve, a structure with a triangular connection, and thus a particularly rigid construction, becomes available.

A sleeve in which the number of slots 10 regularly distributed around the periphery 20 is particularly suitable for use in geodesic domes.

The buses are, for example, made of metal, such as stainless steel, galvanized steel or aluminum, or of plastic. The fastening elements are for instance made of metal, such as stainless steel or galvanized steel.

In yet another embodiment of a building system according to the invention, the structural elements comprise substantially plate-shaped parts, each of which can be coupled to at least two edge zones with respective coupling elements.

When plate-shaped structural elements are used, the connection to the coupling elements can be established in a very simple and thus cost-saving manner.

In an advantageous embodiment, the plate-shaped parts are formed by substantially quadrangular plates, each of which can be coupled to respective edge zones extending from their four corners with respective coupling elements.

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The plate-shaped parts are manufactured, for example, from metal, such as stainless steel, galvanized steel or aluminum, from (fiber-reinforced) plastic, from laminates of metal and plastic or from solid or laminated wood.

In an advantageous embodiment of a building system according to the invention, recesses are formed in the quadrangular plates on opposite sides thereof to be directed towards the knot elements, on both sides of which an edge zone which can be coupled to a coupling element extends. 10 Recesses in the quadrangular plates offer the inherent advantage of material savings and thus of weight and cost savings, but in addition, in a modular construction system composed in a regularly repeating pattern, the openings in cable ducts and pipes formed by the 15 recesses, for example to implement utilities. The recesses also have the advantage that the edge zones which can be accommodated in a knot element are easily accessible, which facilitates mounting, that is to say clamping the plates in the knot elements.

In a very advantageous embodiment, the structural elements substantially comprise two parallel mutually coupled strips, each of which can be coupled to at least two edge zones with respective coupling elements.

Because the distance of the parallel strips is determined by the way in which they are mutually coupled, this embodiment can be adapted in a simple and thus cost-saving manner to the requirements of a particular application.

In order to reinforce the plates, they can each be provided with a reinforcing profile or with a bent edge profile, which in turn can form a guide trough for receiving a fastening element, for instance a square nut, which can be guided in it.

A particularly sturdy structure is obtained with plates, each of which is coupled mirror-symmetrically with a mirror-symmetrically shaped second plate.

1 009493 1 6

In yet another embodiment of a building system according to the invention, this comprises coupling elements for coupling structural elements of a first structure extending along a first plane with knot elements of a second structure extending along a second plane transverse to the first plane.

In a further embodiment, the construction system comprises coupling pieces for coupling knot elements of a first structure extending along a first plane with 10 knot elements of a second structure extending along a second plane transverse to the first plane.

In the latter two embodiments it is possible in a simple manner to couple a wall structure according to the invention formed from knot elements and plates with a ditto floor structure.

The modular building system according to the invention is particularly suitable for use in flat structures such as floors and walls, both load-bearing and non-load-bearing, as well as for use in curved structures, such as geodesic domes.

For all these applications, the invention provides inexpensive to produce elements which are light in weight and thus easy and inexpensive to transport and which can be mounted in a simple and quick manner by one person and do not require welding operations. The elements can be produced particularly dimensionally stable, so that alignment, measurement, adjustment, tightening, etc. are unnecessary during installation. Because the elements are suitable for reuse, they have a high residual value.

A structure constructed with the modular building system according to the invention is very accessible with regard to installation technology, such a structure is extremely solid due to its matrix structure and its low own weight, and is furthermore highly resistant to earthquakes.

The invention will be elucidated hereinbelow on the basis of exemplary embodiments, with reference to the drawings.

Show in the drawings

Fig. 1 a longitudinal section of a slotted sleeve (in exploded view) as the first embodiment of a knot element as well as an edge zone of a structural element to be maintained by that sleeve and a coupling element for a building system according to the invention,

Fig. 2 in top view of the bus and (in exploded view) the edge zone of fig. 1, 10 fig. 3 in longitudinal section of the canister of FIG. 1 in a state in which a structural element resp. a coupling element can be coupled,

Fig. 4 in top view the sleeve and the edge zone of the structural element of fig. 3 in coupled condition, fig. 5 shows a top view of a slotted sleeve as a second embodiment of a knot element for a building system according to the invention, and the edge zone of two structural elements in coupled condition,

Fig. 6 is a top plan view of a slotted sleeve as a third embodiment of a knot element for a building system according to the invention, and the edge zone of a structural element in coupled condition,

Fig. 7A is a bottom view of a slotted sleeve as the fourth embodiment of a knot element for a building system according to the invention, and the edge zone of a structural element in coupled condition,

Fig. 7B shows the knot and structural member of FIG. 7A in cross section,

Fig. 7C shows the structural element of FIG. 7B in side view, FIG. 8A in longitudinal section a structural element with four connectable edge zones, coupled to a double knot element according to the invention,

Fig. 8B shows the structural element of FIG. 8A in cross section, FIG. 9A in longitudinal section a structural element with two connectable edge zones,

Fig. 9B shows the cross section of the structural element of FIG. 9A,

Fig. 10 a longitudinal section of a structural element with four connectable edge zones for a curved structure, coupled to a twofold knot element according to the invention, FIG. 11 a longitudinal section of a structural element with two connectable edge zones for a curved structure, coupled between two single knot elements according to the invention,

Fig. 12A in longitudinal section a structural element of extruded plastic with two connectable edge zones, which can be connected to a single knot element according to the invention,

Fig. 12B shows the structural element of fig. 12A in cross section, fig. 13A, in longitudinal section, an extruded aluminum structural element with four connectable edge zones, which can be coupled to double knot elements according to the invention,

Fig. 13B shows the structural element of fig. 13A in cross section,

Fig. 14A in longitudinal section a structural element of aluminum with four connectable edge zones, composed of extrusion profiles with two connectable edge zones, which can be coupled to double knot elements according to the invention, FIG. 14B shows the structural element of Fig. 14A in cross section,

Fig. 15 and 16 in longitudinal section, a further metal structural element with four connectable edge zones, composed of plates with two connectable edge zones, which can be connected to 30 double knot elements according to the invention,

Fig. 17 a longitudinal section of a structural element with two connectable edge zones for a diagonal connection in a spatial structure, diagonally coupled between two single knot elements according to the invention, FIG. 18 a detail of a floor made of structural elements, with in a longitudinal section two mutually coupled structural elements between double knot elements according to the invention,

Fig. 19, in longitudinal section, two dual knot elements in a vertically extending structure, coupled to a dual knot element in a horizontally extending structure,

Fig. 20A in longitudinal section a first in a horizontally extending structure, coupled to a second knot element in a vertically extending structure, FIG. 20B in longitudinal section, longitudinal section of the first knot element of Fig. 20A and the second knot element in rotated position.

Fig. 2IA shows in a front view a certain horizontal structure with binary symmetry axis, with a transition to a certain vertical structure with bilingual symmetry axis, composed of knot elements and structural elements according to the invention,

Fig. 21B is a side view of the structures of FIG. 21A,

Fig. 21C is a top plan view of the structures of FIG. 21A,

Fig. 22A is a front view of a horizontal structure 20 with a hexagonal axis of symmetry, with a transition to a certain vertical structure with a hexagonal axis of symmetry, composed of knot elements and structural elements according to the invention,

Fig. 22B is a side view of the structures of FIG. 22A, FIG. 22C is a plan view of the structures of FIG. 22A,

Fig. 23 a front view of an example of a spatial structure composed of the modular building system according to the invention,

Fig. 24A is a front view of a horizontal structure 30 with a quadrilateral axis of symmetry, partly composed of structural elements according to Fig. 17,

Fig. 24B is a plan view of the structure of FIG. 24A,

Fig. 25A is a front view of a specific horizontal structure with a triangular symmetry axis, partly composed of 35 structural elements according to FIG. 17,

Fig. 25B is a plan view of the structure of FIG. 25A,

Fig. 26A-26D a detail KLMN of structures with a 0 0 949 3-1 10 binary symmetry axis, composed of knot elements and structural elements according to the invention, in top view. Fig. 27A - 27D details PQR of structures with a triangular axis of symmetry, composed of knot elements and 5 structural elements according to the invention, in top view,

Fig. 28 in cross section a structural element according to the invention between a ceiling and a floor, and

Fig. 29A - 29B in longitudinal section different phases of a coupling element which is coupled to a knot element.

In the figures, corresponding parts are designated by the same reference numerals.

Fig. 1 shows in longitudinal section in exploded view a sleeve 1 consisting of an upper disc-shaped part 8 and a lower disc-shaped part 9, which parts 8, 9 are provided with grooves extending radially inward from the edges, which grooves in combination extend radially and form slots 6 extending in the longitudinal direction of the sleeve 1. Between the parts 8, 9 a ring is included, which each bridges the shaped slots in the transverse direction and thus provides a fixing element 7 for attaching the hook-shaped part 5 of a coupling element 3, also shown, to the parts 8, 9. coupled together by means of a screw 10 and threaded bush 11, the center line 4 of which forms the central knot element shaft 4. Figure 1 further shows a longitudinal section through a part of a structural element 2, with a plate part 12 on which a key-shaped insert 15 is fixed by means of a seam pin 17. The insert 15 just fits in an opening provided by the coupling element 3, when this coupling element 30 3 has been hooked onto the ring 7 of the bush 1 with the aid of the hook 5, with openings 20, 21 in coupling element 3 and plate parts 12, 13 respectively being extended in each other in such a manner that a locking pin 18 can be driven through these openings turn into.

FIG. 2 shows the sleeve 1 of FIG. 1 in top view and, in exploded view, the portion of the structural element 2 of FIG. 1 in top view. In addition to the parts already discussed in Fig. 1, the figure shows openings 21 in the plate parts 12, 13 and a seam pin 17. Bush 1 is provided with eight radial slots 6, so that with bush 1 a maximum of eight structural elements 2 can be coupled by means of coupling elements 3 to be. Fig. 1 is a longitudinal section taken on the line I-I.

Fig. 3 shows in longitudinal section the sleeve 1 of FIG. 1 in a state in which a structure plate 2 is coupled in the direction of the vertical arrow to a coupling element 3 (left in the figure) which is already coupled to the sleeve 1.

10 It can also be seen how a coupling element 3 (right in the figure) is coupled to the bush 1 by hooking this element 3 with its hook 5 from the underside of the bush 1 to hook the ring 7, and then clockwise the element 3 according to. turning the curved arrow 90 °, after which the coupling element 3 is locked in the direction parallel to the knot element shaft 4.

Fig. 4 shows the sleeve 1 and the edge zone of the structure plate 2 of FIG. 3 in top view in coupled condition. Fig. 3 corresponds to a longitudinal section through line III-III of FIG. 4.

FIG. 5 is a plan view of a square sleeve 31 provided with six slots 6, on one side of which two structural elements are coupled by means of coupling elements 3. The fasteners 7 bridging slots 6 are provided by four cylindrical pins extending along the side 25 of the sleeve 31.

Fig. 6 shows a top view of an eight-sided sleeve 51 provided with eight slots 6, to which a structural element is coupled by means of a coupling element 3. The fastening elements bridging the slots 6 are formed by separate cylindrical pins 7.

Fig. 7A and 7B show in bottom view respectively. cross-section according to line B-B a casting provided with twelve slots 6 in the form of a round sleeve 41, to which a structural element is coupled by means of a coupling element 3. The fastening elements 7 bridging the slots 6 are formed by elements integrated with the sleeve 41.

The node element axis 4 forms an n-degree axis of symmetry for (in 1 00949 31 12 this example) the values n = 3, 4, 6 and 12, i.e. when the sleeve 41 is rotated about axis 4 through an angle 360 ° / n (in this example 120 °, 90 °, 60 ° or 30 ° respectively) the bus 41 is self-transported. The knot element 41, which comprises an axial bore 44 for the passage of cables or other pipes, is coupled to a coupling element 3 with a structural element 82, which is composed of two mirror-symmetrical strips 12, 13, the edge profiles of which together form a guide trough 83 for slidably receiving a square nut 84, as shown in cross-view in Fig. 7C. The knot element 41 further includes radially evenly spaced holes 54 for receiving dowel pins from, for example, floor panels to be applied to the structure (not shown), which can then be fixed with screws.

Fig. 8A and 8B show in longitudinal and cross-section respectively a structure plate 22 with four connectable edge zones, which is coupled on the right-hand side with a double knot element, which consists of two bushes 1 coupled by means of a threaded bush 11 according to Fig. 1.

The structural element 22 consists of a plate 12 which is coupled in mirror-symmetrical manner with the aid of sleeves 25 to a mirror-symmetrically shaped second plate 13, wherein the plates 12, 13 are each provided with a reinforcing profile 23 and a bent edge profile 24. In the two opposite sides of the essentially quadrilateral plate 22, which can be directed towards the knot elements 1, have recesses 26 formed, on either side of which extends the edge zone which can be coupled to a coupling element 3.

FIG. 9A and 9B show, in longitudinal and cross-section respectively, a simple structural element 2 with two connectable edge zones.

Fig. 10 shows in longitudinal section a structural element 42 with four connectable edge zones for a curved structure, coupled to a twofold knot element.

Fig. 11 shows in longitudinal section a structural element 32 with two connectable edge zones for a curved structure, 1003-19 3 * 13 coupled between two single knot elements 1 according to the invention.

Figures 12A and 12B show in longitudinal and cross-section respectively a structural element 52 which is composed of two mirror-symmetrically shaped extrusion profiles 12, 13 with two connectable edge zones, which can be coupled to a single knot element 1 according to Fig. 1. The plates 12, 13 can be made of plastic or (with heavier loads) aluminum.

Figures 13A and 13B show in longitudinal and cross-section structural element 62 of extruded aluminum with four connectable edge zones, which can be coupled to dual elements, for example as shown in figure 8A. The structural element 62 is composed of 15 mirror-symmetrically shaped aluminum profiles 12, 13, which are mutually connected by a plate 27.

Figures 14A and 14B show in longitudinal and cross-section, respectively, an extruded aluminum structural element 72 with four connectable edge zones, composed of 20 mirror-symmetrically shaped profiles 12, 13, which are mutually connected by cross-coupled connecting strips 28, 29.

Figures 15 and 16 show in longitudinal section a sheet metal structural element 86 with four connectable edge zones, composed of structural elements 82, 82 'according to Figure 7C, which are interconnected by cross-coupled connecting strips 28', 29 'provided at their ends of an open eye 87 that falls about a pin 88 in the respective structural element 82, 82 '. The constituent structural elements 82, 82 'are coupled with the aid of coupling elements 3 to knot elements 41, 41' according to fig. 7A, B, which are mutually coupled with pipe pieces 89 and 8, respectively. 89 '. The position of the pins 88 and the height of the pipe pieces 89 and. 89 'determines the mutual distance of the structural elements 82, 82', between which for example an installation trough 81 or an air duct 85 can be accommodated (fig. 16).

1009493 ^ 14

Fig. 17 shows in longitudinal section a structural element 92 with two connectable edge zones for a diagonal connection in a spatial structure, diagonally coupled between two single knot elements 1. The structural elements 92 5 differ from, for example, the elements 2 of FIG. 9A, in that the surface of the constituent plates is a parallelogram instead of a rectangle. The coupling elements 93 in the shown diagonal connection extend radially upwards (the left element) and radially downwards (the right element), respectively.

Fig. 18 shows a detail of a floor made of structural elements, with in longitudinal section two structural elements 22 which are mutually coupled by means of two single knot elements 1, and are thus IS coupled between double knot elements according to the invention. A cover plate 35 rests on the coupled structural elements 22. The floor is supported by height-adjustable columns 29, the base 30 of which rests on a bottom 34.

FIG. 19 shows in longitudinal section two twin knot elements, each composed of single knot elements 1 ', 1' 'joined together by a threaded sleeve 11' in a vertically extending structure, coupled to a double knot element, which is composed of two single knot elements 1 joined together by a threaded bush 11, in a horizontally extending structure. The knotting elements 1 'and 1 "are coupled to the knotting elements 1 by means of right-angled coupling elements 43, 43' and 33, 33 'respectively, each of which is provided on one side with a hook-shaped part 5 which is hooked around a fastening element 7 and a notch 55 into which a fastening element 7 can be slid.

Fig. 20A shows in longitudinal section a first knot element 41 in a horizontally extending structure 3, 82, coupled by a rotatable coupling piece 73, 74, 75 to a second knot element 41 'in a vertically extending structure 3'. The rotating coupling piece exists; 1009433 ^ 15 from a bottom part 73 fixed in the bore 44 of the first knot element 41 and a top part 74 rotatable with the aid of a fitting bolt 75, which can be coupled to a coupling element 3 'to which a second knot element 41' 5 can be coupled, of which the node element axis is perpendicular to the node element axis of the first node element 41.

Fig. 20B shows the construction of FIG. 20A after rotation of the second knot element 41 'about a vertical axis through an angle of 90 °.

FIG. 2IA shows in a front view a horizontal structure 37, with a transition to a vertical structure 38, both according to the invention composed of structural elements (22, 22 ') and knot elements 1 and both with a binary axis of symmetry.

FIG. 21B shows a side view of the structures of FIG. 21A, in which structural members and coupling members similar to the structural members and coupling members shown in FIG. 19 allow transition from the horizontal structure 37 of FIG. 21A to the vertical structure 38.

FIG. 21C shows the structures of FIG.

2 IA.

Fig. 22A shows in front view a horizontal structure 47, with a transition to a vertical structure 48, both according to the invention composed of structural elements 22 and knot elements 41 and both with a hexagonal axis of symmetry. By using node elements 41, which have a twelve-axis symmetry axis, it is possible to transition from a structure with a six or three-axis axis of symmetry to a structure with a four or two-axis axis of symmetry, ie a structure with mutually perpendicular structural elements. By means of the coupling elements 33, 43 shown in Fig. 19, a horizontal structure 47 is obtained, to which the vertical structure 48 can be connected, as shown in the side view Fig.

35 22B.

Fig. 22C is a plan view of the structures of FIG. 22A.

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16

Fig. 23 shows part of a spatial structure with supporting columns 94, facade parts 95, roof parts 96, ceiling parts 97, floor parts 98 and inner wall parts 99, which are all composed of structural elements, knot elements and coupling elements of the modular building system according to the invention.

Fig. 24A shows in a front view a horizontal structure 45 with a quadrilateral axis of symmetry, composed of strips 92 according to fig. 17, mutually identical strips 2 and 2 'and knot elements 1. The mutually identical strips 2 and 2' are strips with a lengths such that they are compatible with the strips 92 to form the spatial structure 45. The very open structure 45 rests with columns 46 on a bottom 49, and essentially comprises an upper layer composed of strips 2, which are strips 92 are connected to a bottom layer, built up of strips 2 '.

Fig. 24B is a plan view of the structure of FIG. 24A.

Fig. 25A shows in front view a horizontal structure 57 with a triangular axis of symmetry, composed of strips 92 according to fig. 17, mutually identical strips 2 and 2 ', and knot elements 1. The mutually identical strips 2 and 2' are strips with a lengths such that they are compatible with the strips 92 to form the spatial structure 57. The very open structure 57 rests with columns 46 on a bottom 49, and essentially comprises an upper layer, built up of strips 2, which are strips 92 is connected to a bottom layer, built up of strips 2 '

Fig. 25B is a plan view of the structure of FIG. 25A.

Fig. 26A-26D show a detail of a surface equal to the four figures KLMN of structures with a bilingual symmetry axis, composed of knot elements 1 and structural elements (22,36; 22 ', 36'; 22 ", 36"; 22 ^^ 361 11) 35 according to the invention, in top plan view, in which the distance between the knot elements 1 is each time reduced by using shorter structural elements, whereby denser structures are created, which have a higher load-bearing capacity, or in certain circumstances for reasons of, for example, aesthetic nature may be desired.

Fig. 27A-27D show a detail of a surface PQR equal to the four figures of structures with a triangular axis of symmetry, composed of knot elements 41 and structural elements (22; 22 '; 22 "; 22' '') according to the invention, in top view, wherein the distance between the knot elements 41 has been reduced each time by using shorter structural elements.

Fig. 28 shows in cross-section a part of a storey floor, composed of structural elements 22 according to the invention, in which the edge profiles 24 at the top and bottom contain cable trays 69 for the passage of cables 70, which cable trays are closed by a thermal and acoustic insulating rubber profile 64. In the rubber profiles 64 fall the bent edges of ceiling plates 65, against which an insulating layer of, for example, rock wool is applied, or floor plates 67 on which an insulating profile of, for example, polystyrene is applied.

Fig. 29A shows in longitudinal section an embodiment of a coupling element 3 in a state coupled to a knot element 1, in a state before a structural element 2 is coupled to that coupling element 3. In order to prevent deformation of the coupling element 3 under load after attachment of a structural element 2, in which both a tensile stress and a positive bending moment occur in the lower part of the coupling element 3, the coupling element 3 is constructed in such a way that it is elastic when mounted deforms, resulting in a negative bending moment. In the loaded state, the resulting bending moment will therefore be reduced. The figure shows the state in which the structural element 2 with key-shaped insert 15 lies in the opening provided by coupling part 3, but the coupling pin has not yet been arranged in the hole 21.

Fig. 29B shows the components of FIG. 29A after coupling pin 1009433 "18 18 has been inserted into hole 21. In this situation, a negative bending moment has been created, whereby the resulting bending moment M in loaded condition has been reduced from a bending moment in a structural element that does not elastically deform during mounting.

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Claims (22)

Modular building system for a spatial structure, comprising a number of knotting elements, structural elements to be maintained by and between those knotting elements, and coupling elements which can be coupled to a knotting element and a structural element for coupling a knotting element with a knot to be maintained by said knotting element structural element, in which at least three structural elements can be maintained from one knot element and the coupling elements extend substantially radially from a central knot element axis, characterized in that each coupling element (3) has a knot element (1, 31, 41) , 51) coupled state is separately secured against translation in a direction parallel to the node element axis (4). Building system according to claim 1, characterized in that the coupling elements (3) each have an edge zone with a hook-shaped part (5) and the knot elements (1, 31, 41, 51) each comprise a sleeve which is provided of at least three slots (6) distributed substantially radially and in a direction parallel to the node element axis (4), for the purpose of receiving a coupling element (3), said slots (6) each in said direction transverse directions are bridged by a fastening element (7) for fastening a coupling element (3) received on its edge zone in a slot (6) by means of said hook-shaped part (5). Building system according to claim 2, characterized in that the sleeve (1, 31, 41, 51) comprises an upper disc-shaped part (8) and a lower disc-shaped part (9), which parts (8, 9) are provided with grooves extending radially inwardly from the edges, a groove in the upper part (8) in combination with a corresponding groove in the lower part (9) a said being substantially radial and in a direction parallel to the knot element axis ( 4) forms an extending slot (6), and the "r 3" fastening elements (7) are received between the disc-shaped parts (8, 9). Construction system according to claim 3, characterized in that the fastening elements (7) are provided by a ring closed in circumferential direction of the sleeve. Building system according to claim 3, characterized in that the disc-shaped parts (8, 9) and the fastening elements (7) are provided by an integrated casting (41). Building system according to claim 5, characterized in that the knot element (41) comprises an axial feed-through channel. Building system according to claim 6, characterized in that the feed-through channel is cylindrical (44) and is threaded at at least one end. 8. Building system according to any one of claims 2-7, characterized in. that the sleeve (31, 51) has a regular polygon in cross section. Building system according to any one of claims 2-7, characterized. that the sleeve (1, 41) is cylindrical. 10. Building system as claimed in any of the claims 2-9, characterized in. that the number of slots regularly distributed around the circumference is 8. Building system according to any one of claims 2-9, characterized. that the number of slots regularly distributed around the circumference is 12. Building system according to any one of claims 2-9, characterized in that the number of slots regularly distributed over the circumference is 10. Building system according to any one of the preceding claims, characterized in that the structural elements substantially comprise plate-shaped parts (2, 22, 32, 42), each of which can be coupled to at least two edge zones with respective coupling elements (3). Building system according to claim 13, characterized in that the plate-shaped parts are formed by substantially quadrangular plates (22, 32), each of which can be coupled to respective edge zones extending from their four corners with respective coupling elements (3). 1009493 ' Building system according to claim 14, characterized in that recesses (26) are formed in the quadrangular plates (22, 32) on opposite sides thereof to be directed towards the knotting elements (3), one of which is provided with a coupling element (5) on either side. 3) extends linkable edge zone. Building system according to any one of claims 1-12, characterized. that the structural elements (86) substantially comprise two parallel mutually coupled strips (82, 82 '), each of which can be coupled to at least two edge zones with respective coupling elements (41). Building system according to any one of the preceding claims, characterized in that. that the structural elements comprise plates (12), each of which is coupled mirror-symmetrically with a mirror-symmetrically shaped second plate (13). Construction system according to any one of the preceding claims, characterized in that it comprises coupling elements (33, 33 ', 43, 43') for coupling structural elements of a first structure (37, 47) extending along a first plane with knot elements (1, 31, 41, 51) of a second structure (38, 48) extending along a second plane transverse to the first plane. Building system according to any one of the preceding claims, characterized in that it comprises coupling pieces (73, 74, 75) for coupling knot elements (41) of a first structure extending along a first plane with knot elements (41 ') of a second structure extending along a second plane transverse to the first plane. Construction system according to any one of the preceding claims, characterized in that the structural elements comprise plates (2, 22), each of which is provided with a reinforcing profile (23). Building system according to any one of the preceding claims, characterized in that the structural elements comprise plates (2, 22), each of which comprises a bent edge profile (24, 83). Construction system according to claim 21, characterized in that the edge profile (83) provides a guide trough for the conductive reception of a fastening element (84) therein. • :: 'Λ 3 Λ