SE503479C2 - Modular building - Google Patents

Abstract

A modular building comprises a plurality of vertical loadbearing columns (52) and a plurality of prefabricated, essentially identical volume modules (10) which are of rectangular horizontal section and which are vertically supported by the columns (52) on one or more floors in such a manner that each of them carries only its own dead weight and load. This building is distinguished by being, with respect to force take-up, divided into an inner zone (IZ), which takes up forces in the vertical direction and contains the columns (52) and the volume modules (10) suspended therefrom and which essentially does not take up any lateral forces acting on the building, as well as a facade zone (FZ), which is arranged immediately outside the inner zone to take up lateral forces in order to stabilize laterally the inner zone (IZ), and hence the entire building. To this end, the facade zone comprises a plurality of facade panel elements (80) which are distributed along the outside of the inner zone and are vertically oriented in a direction perpendicular to the facade of the building.

Description

10 15 20 25 30 35 2 In order to solve this object, according to the invention a building with the special features specified in the claims Gene.

A building according to the invention is thus characterized that it is divided, with respect to power consumption, in part a vertical force-absorbing inner zone, which holds the columns with the volume modules suspended therein and which inner zone does not produce any significant uptake side forces acting on the building, as well as a directly outside the inner zone arranged lateral force-absorbing sadzone for lateral stabilization of the inner zone and thus the whole building, which façade zone for this purpose holds a majority, facade panel element, distributed along the outside of the inner zone which are vertically oriented angular right towards the building's facade.

An advantage of the invention is that they are avoided traditional hubs and thus the problems that such entails.

Another advantage of the invention is that it avoids the horizontal beams included in known skeletal structures structures, which is an advantage with regard to as well construction cost as total weight and construction time.

A further advantage of the invention is that The particles in the inner zone can be produced with a limited cross section, as they should not be used to form moment-rigid nodes. This means a cost- time and time savings in the construction of the building. One limited cross-section of the pillars also has the essential advantage that the pillars can be effectively hidden behind the life cycle of the volume modules, which increases the practical usability and flexibility.

According to the invention, the volume modules are suspended in and stabilized by linear columns and facade slab ment. These occupy all vertical and horizontal forces. in such a way, of those in the column / disc structure the suspended volume modules are partly stabilizing 10 15 20 25 30 35 sus 479 3 independent of pillars and facade panel elements, partly can be structurally similar. Useful and dead weights, ie the volume modules with their payloads, are distributed over and occupied by the pillars of the inner zone, while the horizontal forces acting on the building, such as wind power completely or at least for the most part occupied by the façade slabs perpendicular to the façade elements in the facade zone. This principle according to the invention differs significantly from the known skeletal structures in which the lateral forces acting on the building occupied in a large number in the volume of the building distributed elements and / or nodes.

The suspension of the volume modules in the load-bearing columns na is a relatively simple construction site operation, among otherwise because some skeletal structure and nodes in concrete is not needed.

It should be emphasized that the term "volume module" in this context should not be construed as a normally closed one volume, but rather an at least initially open space or framework without walls, ie a model delimited by surfaces dul or cassette, An important factor in this structure is that a so-called open system unit. must not be linked to the load-bearing system or to special channeling zones. The light frame the building allows the installations, which now form one essential part of the construction economy, can be drawn out where at any time in the system. Neither bindings to nor there are problems with the load-bearing parts. This is an important advantage of the invention because the relationship load-bearing structure and supply system are important for the construction cost of the building.

The vertical force-absorbing pillars in the inner zone are made of concrete or steel, together or where alone or in connection with other material used brought into the corner points of the volume modules. The volume modules are 503 10 15 20 25 30 35 4 suitably individually suspended in the pillars without to burden each other.

The horizontal forces are absorbed by the facade panel the facade zone, which facade zone can surround the building wholly or partly in the horizontal plane.

According to a preferred embodiment of the invention includes the building, in addition to the above, standardized volume modules that are suspended in the building's inner zone pillars, a number of special, prefabricated volume dules, called facade modules, which are located between and suspended in the facade panel elements in the facade zone of a in such a way that they are each only burdened by their own useful and own weight. These facade modules usually have smaller horizontal section than the volume modules.

Preferably, the facade modules have substantially the same height as the volume modules, so that the facade modules and to adjacent volume modules together can form rooms in the building.

The volume modules in the inner zone that are furthest out towards the façade zone can preferably be suspended both in pillars located in the inner zone and in the facade panel elements located in the facade zone. In this case, the facade panel elements can thus replacing the pillars at the far end of the inner zone and with dual functions: and the vertical force absorption on the one hand, its intended side stability the function of the columns that the facade panel elements replace ter.

According to a preferred embodiment, the volume modulus along its vertical corner edges provided with vertical kala, can be cast in vertical cavities formed between adjacent profiles protruding from the modules, so that the corner profiles of sound volume modules, such as this in and for is known from SE 464 924. From the volume modules suspension plates or equivalent inserts in the pillars for hanging the volume modules. 10 15 20 25 30 35 5.03 479 5 The facade panel elements can be similar formed by casting in vertical, disc-shaped cavities, formed between covered gables of adjacent façade dules of the above kind.

A particularly good lateral stabilization function in the seed plate elements can be achieved if the ends of the facade modules are provided with trapezoidal plates or equivalent, two adjacent trapezoidal panels of facade modules together forms part of a facade panel element. Especially can be a space between two such trapezoidal plates filled with reinforced concrete or other material, but it is also conceivable to omit the casting step if they on the lateral forces acting on the building are limited and / or if the facade panel elements are sufficiently numerous or have one sufficiently large horizontal section. Furthermore, it is possible to reinforce the trapezoidal plates in another way.

Because the facade modules can have a variable width perpendicular to the façade, the gable of these dimensions race for varying side loads. This means that they increasing horizontal forces arising for taller buildings can be accommodated by a simple widening of the facade modules across the facade. The ends thus have a greater length across the facade, which, however, does not adversely affect the building inner zone or standardization.

Another advantage of the invention is that all stabilizing and load-bearing parts, whether or not they are in steel or concrete, The outer insulation can thereby be applied continuously around will be located inside the building. the building so that the traditional problems of cold bridges do not occur.

The volume and facade modules can be manufactured in sheet metal, which is a completely new industrial building material rial. Through constructive design of thin sheet metal strips you achieve high strength and expediency. With linear roll forming, sheet metal components can be made to low costs. 503 479 10 15 20 25 30 6 The invention's use of the new sheet metal technology login allows very light frame elements to be assembled with high accuracy. Together with fireproof composite tiles, a building stock with a greatly reduced material access and low weight. This material reduction is thus a great advantage of the invention.

These and other benefits and features of the invention is apparent from the claims and from the the description.

The invention will now be described in more detail with a non-limiting embodiments, with reference to attached drawings.

Figs. 1A and 1B schematically illustrate the power distribution in a building designed according to the invention.

Fig. 2 is a schematic horizontal section showing an exemplary floor plan of a building according to the invention, corresponding to a horizontal section along line 2-2 of Fig. 1A.

Fig. 3 is a perspective view of an embodiment of a prefabricated volume module.

Fig. 4A is an exploded perspective view of an arrangement. mang for forming a pillar.

Fig. 4B is a plan view corresponding to Fig. 4A.

Fig. 5 is an exploded view of an upper corner of a volume module according to Fig. 3.

Fig. 6A is an exploded perspective view of an arrangement. mang for forming a facade panel element.

Fig. 6B is a plan view corresponding to Figs. Fig. 7 is a perspective view of an exploded, lower part of an embodiment of a facade module seen from the inside.

First, reference is made to Fig. 3, which shows a standard volume module 10 in "clean" design, ie without extra mounted parts and equipment. Module 10 is on in the same way as the cassettes in the said SE 464 924 intended to be manufactured in a place other than the construction site, step in the factory in order to thereby be able to 503 479 7 exploit the advantages of the plant in terms of rational all handling. The volume modules 10 can be tailored to the ken as desired and provided with the required details.

Because the entire internal assembly of infill and installation components can also be done at the factory can own high-tech and precision-demanding work steps rooms within the factory's controllable environment. They can thus equipped as wet room modules, housing modules, etc. as the wall life of the volume modules 10 is completely open, one can finished room consist of one or more volume modules, completely in depending on where wall elements are mounted on the volume modules.

Such wall elements can be factory-mounted or mounted if the installation of the volume modules 10 in the building.

A prefabrication of such building elements presupposes that these are standardized and preferably, but not necessarily, densely identical. Thus, all the volume modules 10 in the embodiment described here has the same dimensions and basic construction and are twice as long in the embodiment shown as wide. Thereby they can be set in the same direction or smiles perpendicular to each other in a grid. In the example i Fig. 2, where each module is marked with a diagonal line, are the four volume modules 10 at the bottom left of the figure is set perpendicular to the other volume modules 10.

The volume module 10 in Fig. 3 consists partly of a top frame formed by two longitudinal ribs 12 joined by a plurality roof slats 14, partly a similar bottom frame formed by two longitudinal ribs 16 connected to a plurality of bottom ribs 18, partly four vertical corner profiles 20 and partly two pairs center profiles 22 joining opposite corners respectively middle parts of the top and bottom frame.

The ribs 12, 14, 16, 18 are made of C-beams steel. The corner and center profiles 20, 22 are angular profiles clay made of preferably sheet metal. A distinctive feature of the invention is that all these ribs 12, 14, 16, 18 and angle profiles 20, 22 can be made of 503 479 8 sheet metal, ie with a thickness of about 2 mm or less.

This applies generally to the invention, not only to the embodiment shown.

Fig. 5 is an exploded view of an upper corner of a volume module 10. The lower corners, center profiles 22 and all roof and bottom ribs 14, 16 are mounted on substantially the same way. The outer roof bar 14 is fixed to the longitudinal bar 12 by means of two mounting brackets 24a, 24b. These fittings are provided with recesses 26 for grips with folded flanges 12 'of the longitudinal ribs 12.

The roof bar 14 is anchored in the mounting fittings 24a, 24b by means of bolted joints via bolt holes 28, 30.

One mounting bracket 24a is torsionally rigidly anchored. at the longitudinal rib 12 and one side 21a of the corner profile 20 by means of bolted joints via bolt holes 32a in the mounting bracket 24a, bolt holes 34a in the longitudinal rib 12 and bolt holes 36a in the filsidan 21a. This bolt joint also holds an L- shaped angle iron 50 on the opposite side of the profile side 2la surface. Function of the angle iron 50 will be described in more detail forward.

The second mounting bracket 24b is bolted joints rigidly anchored to the longitudinal rib 12 and one angle iron 40, which in turn is by bolted joints torsionally rigidly anchored at the other profile side 2lb. For these bolt joints, bolt holes 32b are used in the mounting bracket. stroke 24b, bolt holes 34b in the longitudinal rib 12, bolt holes 42 and 44 in the angle iron 40 and bolt holes 36b in the profile side 2lb.

Fig. 5 also shows one on the upper edge of the profile 20 applicable, specially designed sealing strip 46 for sealing between vertically adjacent volume modules 10. Transverse the section of the sealing strip 46 is shown on an enlarged scale up to the right in Fig. 5.

In the pre-assembled position, the components shown in Fig. 5 assume components the appearance of Figures 4A and 4B, showing an arrangement at four adjacent corners of four volume modules 10A-1OD. The corner profiles 20A-20D 9 borders a vertical, square cavity for casting of a pillar 52 of concrete or other material. In it finished building, these four corners of the volume modu- 10A-D to be supported by the pillar 52 via the concrete inset and rigidly anchored with the volume modules suspension plates, which form part of the angle irons 50 i Fig. 5. It should be noted that there are normally hanging suspension plates at the bottom of the volume modules corner, so that each corner profile 20 is vertically suspended in an upper and a lower point. The center profiles 22 of the volume modules 10 also come to form such cavities for pillars 52 when assembled against other center profiles 22, in the case of volume the modules 10 are placed in the same direction, or against corner files 20, in case the volume modules 10 are set at an angle right against each other. Even with these there are preferably angle iron 50 with suspension plates.

The corner and center profiles 20, 22 are so designed and placed that the cast pillars 52 are completely outside the wall life of the volume modules 10, and also outside the intended extensions of these wall life. This gives great flexibility regarding functional and space requirements. If, for example, two volume modules 10 according to Fig. 3 are set in their longitudinal direction successively, the coincident wall webs of the modulus The walls are provided with walls without obstruction of the pillars 52.

In the embodiment shown, corner and center profiles are assumed 20, 22 be made of 2 mm sheet, and for avoiding deflection of these when the columns 52 are cast each set of four adjacent profiles 20/22, delimiting a pillar cavity, held together by means of anchor 60. Such an anchor 60 comprises a column the cavity located inner portion 62 with substantially cruciform horizontal section, as well as four vertically extending end plate 64, the outsides of two adjacent profi- 4A and 4B) gripping plates or which each one uses is sealing against ler 20, 22 (see fig and which are held tight against 503 479 l0 each other of the inner portion 62 of the anchor 60. The anchor 60 has thus also the function of sealing the gaps between files 20, 22 it includes against concrete leakage. In the embodiment shown inner part rebar, which are threaded at its ends the end plates 64 may be initially slightly outwardly bent for to effectively seal against the profiles 20, 22.

When constructing a building with volume modules 10 to receive clamping nuts 61, while and column 52 as above is first applied to a number volume modules 10 next to each other, after which they coupled to anchor 60 for joining adjacent pro- files 20, 22. Then reinforcing bars 66 are applied to the larhàlrummen, which are then filled with concrete. Suspension the plates of the angle irons 50 are then embedded in them cast pillars 52, as indicated in Fig. 4B. Next spring volume modules 10 can then be applied, thereby utilizes semi-equipped positioning and spacer plates 68. Each volume module has eight plus eight such plates 68, one in each corner and two in the middle of each longitudinal bar 12, with guide pins 69 for precise positioning of 16. The plates 68 are intended to be provided in their holes volume modules arranged one above the other 10. The casting of the next column section is then performed in a corresponding manner.

In order that the volume modules 10 in the finished construction the burden shall be borne only by its own weight, which shall be considered to include payloads therein, arranged between the spacer plates some form of temporary spacer, ex- for example, neoprene washers (not shown), which in the finished the building does not absorb any vertical forces, so that each volume module 10 will be separately suspended in its surrounding pillars 52, without being loaded vertically from the above volume modules 10. The volume modules 10 can thereby be manufactured with identical basic constructions because they are exposed to the same impact regardless of location in the building. 5 0 3 4 79 ll Reference is now made schematically to that of Figs. 1A and 1B showed the building. The pillars 52 described above with the the volume modules 10 suspended separately therein lie within one here referred to as the inner zone (IZ) of the building. As shown schematically with filled force arrows is taken up in the inner zone IZ essentially only vertical forces. Especially missing in the inner zone IZ a side stabilizing skeleton, such as the type as specified in the above-mentioned SE 464 924.

For lateral stabilization of the inner zone, ie the columns 52 and the volume modules 10, are arranged according to the invention a outer facade zone FZ, which in the horizontal plane can completely or partially enclose the inner zone IZ. The structure and functional of existing parts of the façade zone and the coupling between the façade zone and the inner zone shall now be described in the following with reference to Figs. 6A, 6B and 7.

First, reference is made to Fig. 6B, which shows how a seed plate element 80 is cast between two special volumes modules, called facade modules and generally designated with 70. To distinguish the facade modules in the example is these denoted by 70A and 70B, respectively.

Each facade module 70 has, like the volume modules 10, a top frame and an attached bottom frame. Top frame is formed by two transverse ribs 72 joined by two shorter ones end ribs 74 with the same mounting type as in Fig. 5. the ten frame is formed by two transverse ribs 76 joined by two shorter end ribs 78. With regard to the modular principle and standardization are the transverse ribs 72 of the facade modules 70, 76 in the embodiment shown as long as the volume modulus 10 roof and bottom ribs 14, 18, so that it is shorter the wall life of a volume module 10 can be covered by a facade module. dul 70, while the longer wall life of a volume module 10 can be covered by two successive facade modules 70.

The top and bottom frames of the 70 facade modules are joined via partly four corner profiles 82, mounted in the same way 503 479 12 as in Fig. 5, partly two gable trapezoidal plates 84 which are mounted with bolted joints and covering the facade modules 70 gables completely. The two inner corner profiles 82 can may be omitted, but are preferred to provide come standardization. The choice of material in the horizontal the ribs and the vertical profiles can be same in the volume modules 10 and the facade modules 70.

In order to increase stability, a horizontal sontel trapezoidal plate 86 is mounted in either or both of the top and bottom frames, as shown schematically in Fig. 6A.

When, as shown in the figures, two adjacent facades seed modules 70A and 7OB are assembled against two adjacent ones volume modules 10A and 10B, an elongated, disc-shaped cavity 88 between the facade modules, which cavity is bounded horizontally by the two outer corner profiles 82, the two opposite trapezoidal plates 84, the two inner corner profiles 82 and the two internal volume modulators adjacent corner profiles 20A, 20B of adjacent 10A, 10B. These parts are initially locked together by means of an anchor 100, which has essentially the same construction and function as the anchor 60 for the standard pillars, however with the difference that the inner part 102 is longer in the length of the cavity 88 direction.

The elements which in Fig. 6A form the cavity 88 can be in some cases themselves constitute a facade panel element 80, too without casting concrete in the cavity 88 as shown in Fig. 6B. Normally, however, concrete or other material to be cast in the cavity, with the necessary armature ring can also be applied. In this case, the facade modulus 70 to be individually suspended in the facade panel 80 in the same way as the volume modules 10 in the interior are individually suspended in the columns 52. For this purpose, the trapezoidal plates 84 are provided on their insides with angle iron 50 with horizontally projecting suspension plates for engaging the concrete and absorbing 503 479 13 vertical load. Such suspension plates can also be arranged in the corner profiles 82.

It should be noted that the volume modules (10A, 10B) located at the far end of the inner zone and bordering the sad zone is thus partially suspended in the positions not shown. pillar 52 further into the inner zone, partly in the element 80, which thereby takes over the vertical force taking the function of the standard pillars. In the embodiment in Figures 6 and 7, however, constitute the inner part of the facade panel element 80 of what can be described as a standard pillar.

The extent of the façade modules 70 across the façade can easily varied by varying the length of the end ribs. drills 72, 78 for changing the layout of the facade panel elements 80 stretching and thus the degree of stabilization. This can done completely without the standardization in the inner zone IZ affected.

A major advantage of the facade modules 70 is that they the factory can be fitted with facade cladding, which are normally close to the façade, etc. Fig. 7 shows how the façade module 70B on its against the façade of the building facing long side is provided with a facade insulation 90, wall-forming material 92, a window opening 94, a frame diator 96 and piping 98. Possibly, 98, electrical wires, etc. are routed in the vertical ones channels formed between the ridges of the trapezoidal 84 on the side of the gable end panels that is facing from the cavity 88.

Claims (13)

503 10 15 20 25 30 479 14 Patent claims comprising a plurality of bearings and a plurality of prefabricated Modular building, curved, vertical pillars (52) lined up, substantially identical volume modules (10) with rectangular horizontal section, which are so vertically up- (52) that they are each loaded only by their own weight and carried by the pillars in one or more storeys, payload, characterized in that the building is divided, with respect to power absorption, into a vertical force-absorbing inner zone (IZ), which contains the columns (52) with the volume modules (10) suspended therein and which inner zone does not provide any significant uptake of lateral forces acting on the building, partly a side force uptake (FZ) (IZ) arranged directly outside the inner zone and thus the whole building, which façade zone for this purpose contains a plurality, along the outside of the inner zone (80), entered perpendicular to the facade of the building. facade zone for lateral stabilization of the inner zone distributed facade panel elements which are vertically oriented Building according to claim 1, characterized in that the building, in addition to said volume modules (10), comprises a plurality of special, prefabricated volume modules (70), called facade modules, which are located between and suspended in the facade panel elements (80). in the façade zone in such a way that they are each only loaded by their own weight and payload. Building according to claim 2, characterized in that the facade modules (70) (10). Building according to claim 2 or 3, has a smaller horizontal section than the volume modules - characterized in that the height of the facade modules is substantially (10) height, na (70) and adjacent volume modules (10) in addition to the volume modules so that the facade modules together can form rooms in the building. 10 15 20 25 30 35 503 479 15 Building according to any one of claims 2-4, characterized - drawn (70) stretch perpendicular to the façade which substantially exceeds that each façade module has a correspondence with the extent perpendicular to the façade of the façade panel element (80) which adjacent to the façade module (70). A building according to any one of claims 2-5, characterized in that (80) are formed disc-shaped cavities (88), characterized in that the facade panel elements are cast by vertical, delimited between covered gables of adjacent facade modulus (70). Building according to one of Claims 2 to 6, characterized in that the facing (84) of the façade modules face each other (84), wherein two adjacent gable stair slabs or equivalent (84) together form or form part of a façade slab (80) . Building according to one of the preceding claims, (10) projecting ends are provided with trapezoidal plates, characterized in that the volume modules (10) are cast in vertically provided with profiles (20, 22) (52) from the modules. technical cavities formed between adjacent volume modules (10) (20, 22). Building according to claim 8, and that the column profiles are characterized in that each set of four adjacent vertical profiles (20, 22), which delimit a cavity in which a column (52) is cast, are held together by means of a anchor (60), which comprises an inner part (62) located in the cavity and four vertically extending engaging elements (64), each of which abuts sealingly against the outer (20, 22) (60) members of two adjacent profiles and which are held tight against each other by the inner part of the anchor (62). Building according to claim 9, (10) are made of sheet metal. k n e n e t e c k - n a d of the vertical profiles of the volume modules (20, 22) 503 479 10 15 16 ll. Building according to one of the preceding claims, characterized in that the cross section of each (52) is located entirely within an area defined by (10) pillars by imaginary extensions of the wall life of the volume modules. characterized in that said vertical profiles (20, 22) of one (10) (20), each of which consists of two flanges which form an essential Building according to claim 11, volume module comprises four corner profiles as a right angle, the tip of which faces the volume element (10). Building according to one of the preceding claims, (80), also characterized in that the facade panel elements, in addition to functioning as side stabilizing elements, function as vertical supporting pillars for the inner zone (IZ) (FZ) (10). volume elements located closest to the façade zone