HUT68418A - Living space arrangement particularly in multistorey buildings - Google Patents

Description

BACKGROUND OF THE INVENTION The present invention relates to a spatial arrangement, in particular to a movable building in a multi-storey construction having a plurality of superposed spatial elements.

Arrangements of spatial elements consisting of several superimposed space elements are basically known. Mobile multi-storey buildings are traditionally erected by stacking space elements. In this case, the spacers themselves are formed as rigid spacers, which are usually constructed as standard building blocks in the form of containers. The individual elements are screwed, welded, etc. permanently bonded.

This traditional construction has a number of disadvantages. Such systems are predominantly statically difficult to calculate, since interpolation is not possible between levels in multi-level designs. In addition, rigid spatial elements alone are structurally laborious and, given the high rigidity required, require considerable amount of material to produce.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a space element arrangement consisting of a plurality of superimposed space elements, which is easy to set up and characterized by a weight-saving design.

In order to solve this problem, a spatial element arrangement, in particular a multi-storey movable building, is provided having a plurality of stacked spatial elements, wherein the spatial unit arrangement according to the invention is provided with a rigid core itself.

By forming a rigid core by itself in accordance with the present invention, it is possible to form individual spatial elements not as rigid elements per se. By providing the rigid core itself with the reinforcement of the spacer arrangement, the bending stress of the struts is reduced and the load bearing characteristics thereof are significantly improved. Thanks to the core, the stability of the spatial arrangement with respect to the displacement of the spatial elements in the horizontal direction is assured. The spatial elements of each level (floors) are connected at least horizontally to the rigid core, for example by means of screws. The distant spatial elements are connected to the adjacent spatial elements so that the distal spatial elements are indirectly connected to the rigid core through other spatial elements. This can be accomplished by interconnecting each spatial element through a statically effective sheet, which is provided by properly formed interconnections within or between the spatial elements, allowing transverse force transmission. The mass of superimposed space elements always bears the space elements underneath. With this in mind, each spatial element is formed with an appropriate support structure.

By securing the floor elements of each floor against slipping in the horizontal direction and securing each floor against displacement only by the rigid core itself, the static calculations are considerably simplified.

Through the use of a rigid core per se, as well as non-rigid space elements or space elements that do not have sufficient rigidity for a multi-storey construction. As a result, the weight of the entire structure is significantly reduced.

While it is possible in principle to form a rigid core by itself with a circular cross-section or other curved cross-section, it is still preferable that the rigid core itself has straight elements.

Also preferred is an embodiment in which the rigid core itself is provided with at least three statically effective plates, the extensions of which do not intersect at one point and which can be formed, for example, as wall elements.

In this way, when straight walls are used, sufficient torsional rigidity of the core is ensured.

In a particularly preferred embodiment of the spatial arrangement according to the invention, the core has a U-shaped, rectangular or triangular cross-section.

The advantage of this embodiment is that, in this arrangement, the core can be connected to other spatial elements without rectangular or transient problems, provided that they have a rectangular cross-section.

In a further preferred embodiment of the spatial arrangement according to the invention, the core is formed as a staircase.

This embodiment provides the advantage that there is no need for special escape routes through the built-in staircases, if the staircase is a so-called. trained as a necessary staircase. In addition, this makes it particularly advantageous to use the rigid core itself, since otherwise the core does not allow any internal subdivision as a steel combined structure or steel structure in a more demanding concrete design.

In a further preferred embodiment of the spacer arrangement according to the invention, at least two spacer elements arranged one above the other are provided with a common floor element.

In this way, additional floor or floor elements between the overlapping space elements can be saved. In particular, this enables the construction of a weight-saving device. In this case, the gaps can be closed in accordance with fire protection regulations.

In a preferred embodiment, the floor or floor element is arranged on the floor of a space element, while the top space elements of the space element arrangement are closed by a floor element.

Although basically an inverse arrangement would be possible, i.e. basically the floor or slab element of each spatial element could be formed as a slab, in the above embodiment the spatial arrangement is particularly easy to install since the lower spatial elements directly on the ground or can be mounted on a properly prepared base structure without the need for a separate base surface. In addition, the individual spacers include lifting devices such as cranes, etc. installation, they can be more easily viewed from above and thus easier to bring to the required mounting position.

In this embodiment, in each case, a ceiling member or roof structure is placed as a closure on the uppermost space elements.

In a further embodiment of the spatial arrangement according to the invention, the floor, slab and / or slab is provided with a slab combined with slab concrete. This feature has the advantage that the required fire resistance between the individual floors is thus ensured without further action. On the other hand, a separate fire protection liner is provided in the area of the side supports and walls. Sufficient sound insulation can be achieved by appropriate measures such as floating estrich.

The structure combined with this type of concrete is advantageously provided by means of a profile sheet on which a concrete layer is applied. In this case, a concrete layer, for example, rests on a steel support and is connected thereto in a statically effective manner, for example, by means of studs.

In this way, a particularly lightweight and space-saving structure can be created, which is characterized by the required floor load and fire safety.

In a further preferred embodiment of the spatial arrangement according to the invention, the concrete layer of the floor, slab and / or slab is comprised of lightweight concrete having a density of not more than about 1700 kg / m ³ .

Such a particularly lightweight structure can be provided by applying the concrete to the profile plate and by means of a statically effective joint.

Particularly preferred is the embodiment where the concrete layer comprises lightweight concrete with a density of up to about 1600 kg / m ³ .

In a particularly preferred embodiment of the invention, there is provided at least one floor-to-floor extension projecting between two adjacent space elements, through which adjacent space elements are connected to one another on the floor side.

Conveyors designed within known spatial arrangements have been implemented in a conventional manner by inserting separate sections into the structure. To this end, suitable plate members are usually inserted between spaced apart elements.

With the arrangement according to the invention, the creation of passageways in the building is considerably simplified, since no additional elements are required and the cost of installation is significantly reduced.

It is to be understood that the above-mentioned features, as further elaborated below, may be used not only in the given combination, but also in other combinations or independently, without departing from the scope of the present invention.

The invention will now be described in more detail with reference to the accompanying drawings in connection with the preferred embodiment below.

We explained, Figure 1 where in the drawing it is movable according to the invention > building- let set up plan, a Figure 2 1 is a bottom view of the space element of FIG Figure 3 Figure III is a line III-III of the space member of Figure 2 along taken in section, a Figure 4 Fig. 2 is a line IV-IV of the spacer member of Fig. 2 along taken with the engraving of the

Figure 5 is a longitudinal sectional view of a slab member that can be mounted on the space member of Figure 2, a

Figure 6 is a cross-sectional view of the slab member of Figure 5.

Figure 1 shows a spatial element arrangement 10 according to the invention.

For example, the building shown here could serve as a multi-storey hotel. The floor plan presented here represents only one of many variations and is intended to illustrate the design principle.

The space element arrangement 10 consists of a predetermined number of space elements 12, 14, 16 having a rectangular base. Of the space elements 12, 14, 16 of the space element arrangement 10, the space element 16 inside the building itself is formed as a rigid core 16 extending in the vertical direction over the entire height of the building. The self-rigid core 16 forms a concrete structure which is provided with three adjacent load-bearing walls 18, 20, 22 to form a generally U-shaped, self-rigid support structure. In addition, the rigid core 16 may be diagonally stiffened and may be constructed as a steel structure or a combination of steel with a light (approved) firewall structure.

Within the core 16 is a staircase which is, of course, connected to the other field elements through appropriate entrances and exits formed in the side walls 18, 22 or the front wall 20. For the sake of clarity, doors and the like are not shown in the figure.

Figure 1 shows the ground level of the space element arrangement 10

The further levels may be constructed in the same way or may be modified from the layout in Figure 1.

As shown in Figure 1, ten to ten spacers 12 are interconnected on their longitudinal sides so that a total of two rows of ten spacers 12 spaced apart are formed. Between these two rows are three rows of six or six rows of longitudinally connected spatial elements. In addition, 23 passageways are arranged between adjacent rows of space elements. The passageways 23 are formed by extending the floor elements of adjacent spatially interconnected spatial elements to protrude outwardly beyond the actual enclosed space of the spatial element, as shown below in FIGS. 2-4. . Figures 4 to 5 are described in more detail.

Each spatial element 12, 14, 16 starts from a rectangular base surface of the same size, but the space enclosed by the spatial elements 12 to which the passageways 23 are connected is always truncated to the width of the passage. Thus, the central transverse rows of the six six spatial elements 14 and 16 interconnected on their longitudinal sides and the two longitudinal rows thus always have a larger interior space which is extended to the width of the passage relative to the other spatial elements.

All spacers that are horizontally connected to the core 16 are secured to the core through suitable attachment points, which may be screw connections, for example, to prevent slipping in the horizontal direction. The other spatial elements of each floor are always attached to these spatial elements at their peripheral sides and are thus secured against displacement in the horizontal direction. In addition, the superposed spatial elements 12, 14 are connected vertically to each other through suitable joining points, for example by twisting. Alternatively or additionally, plug-in connections may be provided through which the placement of the spatial elements can be simplified.

2-4. 1 to 7, the space element 12 is schematically illustrated with a projection 42 for forming a transport element at the front.

Other spatial elements 14 having no such projection 42 are constructed in the same manner, whereby only the interior enclosed by the spatial elements is enlarged by the width of the projection 42.

On the underside of each of the spacers 12 is a profile plate 26, which is formed, for example, by a profile plate marketed by Hoesch under the trademark Holorib. The profile plate 26 rests on two longitudinal rails 28 and two transverse rails 30 defining the underside of the space member 12.

The 26 profiled sheets have a concrete layer of lightweight concrete with a density of less than 1600 kg / m ³ , which provides fire protection. By statically efficiently joining the profile sheet 26 and the lightweight concrete layer thereto, a concrete composite support 38 is provided, which provides sufficient floor load and simultaneously provides the required fire resistance between two superposed spaces.

The floor element 12, which is open at the upper end of the space element and has a fire protection liner attached to a space element, formed as a concrete support element 38 in combination with a floor, ceiling or

5 and 6.

Each spacer 12 is provided with a total of four vertical brackets 36 for receiving vertical forces, two of which are located on the front corners of the spacer 12, while the other two rest on the longitudinal brackets 28 and thus define the space enclosed by the spacer 12. Beyond these contact points of the carrier 36, the floor-to-ceiling member 24 is extended by an outwardly extending projection 42 which serves as a passage and is connected to an adjacent field member.

A support head 34 is provided at the upper ends of the vertical supports 36 and a support base 32 is provided at the lower ends of the supports 36.

Each time the spacer elements are stacked, an upper spacer 32 is placed with four support plates 32 on the support heads 34 of a lower spacer. In this process, the floor element 24 of the upper space element is also a slab of the lower space element.

The four supports 36 of the spacer 12 are further connected to the upper end 40 surrounding the upper end thereof, whereby the spacer 12 obtains some basic stability. These upper belts 40, on the other hand, are considerably weaker than conventional single rigid spacing elements, since these belts 40 need only have relatively low shear strength, since the spatial elements of each level are always attached to the 16 rigid core itself.

The space elements forming the upper part of the building are from above

5 and 6 are closed by a slab 44 formed in accordance with Figs.

The slab 44 also essentially consists of a concrete bracket, the structure of which corresponds to the bracket 38 of the combined floor slab. The bracket 58 is arranged on two longitudinal rails 48 and two lateral cross brackets 50 and is also provided with a profile plate 46 corresponding, for example, to a profile plate marketed under the trademark Holoes Hoesch. Lightweight concrete with a density of up to 1600 kg / m ³ is applied to these 46 profile boards.

In order to connect it to a spacer element below, the longitudinal brackets are provided with four support legs 52 which, when laying the floor element 44, extend into the corresponding support heads 34 of the spacer element below. The slab 44 is additionally surrounded by an outer flange 54 which serves as a formwork for the concrete.

Claims (11)

Claims A spatial arrangement, in particular a movable building in a multi-storey construction having a plurality of superposed spatial elements, characterized in that it is provided with a rigid core (16) on which spatial elements (12, 14) for each level are secured against horizontal displacement. . Spacer arrangement according to Claim 1, characterized in that the rigid core (16) itself is provided with at least three statically effective plates, in particular a wall (18, 20, 22), the extensions of which do not meet on a point. Space element arrangement according to claim 1 or 2, characterized in that the core (16) has a U-shaped, rectangular or triangular cross-section. 4th 1-3. claims planning, with characterized in is designed. 5th 1-4. claims planning, with characterized in The spacer according to any one of said core members (16) is provided with at least two spaced apart (12) floor members (24) arranged on top of each other. 6. Spacer arrangement according to any one of claims 1 to 3, characterized in that the floor, slab (24) is arranged on the floor of a spatial (12) and the uppermost spatial elements are closed by a slab (44) or a roof structure. 7. Spacer arrangement according to any one of claims 1 to 3, characterized in that the floor, floor element (24) and / or the floor element (44) is provided with a support element (38, 58) combined with concrete. 8. Spacer arrangement according to any one of claims 1 to 3, characterized in that the concrete combined support (38, 58) is provided with one or more steel supports on which a concrete layer is applied which is connected statically in an effective manner to the steel carrier or steel supports. 9. Spacer arrangement according to any one of claims 1 to 4, characterized in that the floor, floor element (24) and / or the floor element (44) is provided with a profile plate (26, 46) on which a concrete layer is connected in a statically effective manner. 10. Spacer arrangement according to any one of claims 1 to 3, characterized in that at least one spatial member is provided with a suspended ceiling. 11. Spacer arrangement according to any one of claims 1 to 3, characterized in that the concrete layer of the floor, slab (24) and / or slab (44) consists of light concrete with a density of up to approximately 1700 kg / m ³ . The spatial arrangement according to claim 9, characterized in that the concrete layer of the floor, slab (24) and / or slab (44) consists of lightweight concrete with a density of up to approximately 1600 kg / m ³ . 13. Spacer arrangement according to any one of claims 1 to 4, characterized in that it has at least * · * · 4 «·· projecting (42) on its floor, slabs (24) forming two adjacent spatial members (12, 14, 16). provided through which adjacent space elements (12, 14, 16) are connected on their floor sides.