NL8503110A - Prefabricated reinforced concrete building - has stabilising walls in lengthwise direction in ground floor adjacent to transverse walls - Google Patents

Abstract

The building (1) comprises a series of compartments (4) alongside each other, separated by walls (3) formed by prefabricated reinforced-concrete sections (10) whose height (h) is equal to that of a storey. Reinforced-concrete floor plates (9) rest at the ends on the top edges of the wall sections. In the ground floor and adjacent to two or more transverse walls (3) are one or more prefabricated reinforced-concrete stabilising walls (16 - 18) extending in the lengthwise direction of the building (2), whose length (c) in this direction is appreciably less than that (d) of a compartment. Each of two or more stabilising walls has near three of its four corners a coupling forming a rigid right-angled triangle, whose sides extend for the height and length of the wall, while the hypotenuse forms its diagonal. The right-angle corner is coupled to the transverse wall, the acute-angled bottom corner to the foundations and the transverse wall and the acute angle top corner to the floor above. The end edges of the floor plates above this floor are coupled to the top edges of wall sections by devices absorbing horizontal loads in the lengthwise and transverse directions of the building.

Description

M Kon / mf / 1 Elementum -1-

Building and stability wall for that

The invention relates to a building with a series of adjacent compartments # which are separated from one another by transverse walls.

In the conventional architecture, the longitudinal stability of the building is realized by means of interior walls and longitudinal facades with rather small windows. There are also conventional buildings, the longitudinal facades of which have a considerable surface area between wall sections arranged near the transverse walls, which provide the necessary longitudinal stability. These wall pieces are joined to the transverse wall on their entire vertical side and are anchored at their entire bottom edge with the foundation underneath and at their entire top edge with the floor above.

With the aim of even more light and a simpler construction method in a somewhat more recent construction era, both longitudinal facades are made of glass panels, at least of panels, which are no longer able to provide longitudinal stability. The required longitudinal stability in these buildings has been realized with the inner walls arranged in the longitudinal direction of the building.

In a somewhat more recent construction era, the so-called doorzon home has arisen, which is wholly or almost entirely wall-free, so that sun and light can radiate from both longitudinal facades, but above all in order to be able to divide each compartment 25 undisturbed by existing construction walls as required. . This resulted in the so-called cast construction, in which a reinforced concrete, in itself form-rigid tunnel was poured out of concrete on the construction site by means of expensive tunnel formwork. In addition, the longitudinal stability was achieved by a rigid connecting transition between transverse walls and floors.

With the insight that construction can be simplified by factory construction methods, whereby the work on the construction site is kept to a minimum, the cast construction

V »V V W J i V

-2- * Λ * · t Ψ i partly replaced by an assembly construction, in which as many prefabricated, large but still transportable construction elements are combined on the construction site. A building then arises, as indicated in the preamble of claim 5 1.

In order to ensure the necessary longitudinal stability, in this known assembly construction, the wall plates of the transverse walls and the floor plates are interconnected at their connection joints, a great deal of reinforcing steel being used in these connection joints 10 to obtain a rigid connection between transverse walls and floors again after hardening. to thereby achieve the necessary longitudinal stability. The realization of these rigid connection joints is a costly and time-consuming activity, which detracts from the general great advantage of building by combining large prefabricated building elements.

The object of the invention is to provide a building of the type indicated in the preamble of claim 1, the supporting construction of which consists mainly of prefabricated large elements, which can be assembled in a sufficient longitudinal stability without or with little castings. while retaining the possibility of a lot of light and while retaining unlimited layout possibilities of the useful space of the compartments.

This building can be assembled from prefabricated elements, whereby little or no concrete mortar or sand cement mortar needs to be processed on the construction site. Moreover, it is possible to install the front and rear facades afterwards, whereby no requirements have to be imposed on those facades, relating to a contribution to longitudinal stability.

The invention also relates to and provides a stability wall according to the invention, as indicated in claims 13 and 14. Preferred measures are indicated in claims 2-12.

The invention will be elucidated in the following description with reference to a drawing.

The drawing schematically shows:

s + t S3 "I" X

v v V * '^ »% -3-

Fig. 1 and 12 a perspective view of different buildings according to the invention during their construction, fig. 2 a schematic view of a detail of the building of fig. 1 according to arrows II-II of fig. 1 or of an even more building layers existing building, fig. 3 a power diagram in the plane of the building shown in fig. 2, fig. 4, 5 and 6 on a large scale, each time a perspective view of detail IV, V resp. VI of fig. 2, fig. 7 is a larger-scale section along the line VII-VII of fig. 1, fig. 8 and 9 diagrams corresponding to fig. 2 and 3 concerning a two-storey building, fig. 10 and 11 are diagrams corresponding to FIGS. 2 and 3 concerning a single-storey building, FIG. 13 is a large broken away perspective view of detail XIII of FIG. 12, and FIG. 14 is a large broken away perspective view. of detail XIV of fig. 12.

The building 1 of fig. 1 has a series of compartments 4 arranged side by side in longitudinal direction 2, compartments 4 mutually separated by transverse walls 3, for instance homes or offices. In addition to a floor 5, the building 1 has two intermediate floors 6 and 7, which extend along the longitudinal direction 2 through the compartments 4 and thus each separate two building layers 8. Each intermediate floor 6, 7 mainly consists of prefabricated, reinforced concrete floor slabs 9. The transverse walls 3 in fig. 1 each consist of two cavity walls, each of which is mainly composed of two prefabricated, reinforced concrete, rectangular, plate-shaped wall elements 10 and one roof-shaped wall element 13. The side walls 11 each have an inner cavity leaf of such wall elements and another outer cavity leaf 35. In order to give the building 1 the necessary stability, each compartment 4 is preferably at considerable distances a and b from the facade 14 and 14, respectively. rear facade 15 in each case adjacent to transverse walls 3 and on the side wall 11 5592110 * s -4- shown, three stability walls 16, 17 and 18 are arranged one above the other. An intermediate floor 6, 7 between stability walls 16, 17, respectively. 17, 18 added. Each stability wall 16-18 is a prefabricated reinforced concrete slab, arranged in the longitudinal direction 2 of the building 1 and having a length c which is considerably shorter than the length d of a compartment 4. The length c is preferably chosen such that the stability wall 16-18 can delimit a staircase space and / or form a wall of a sanitary space, for instance a toilet or bathroom. Each pair 16, 17 resp. 17, 18 of stability walls 16-18, between which an intermediate floor 6, resp. 7, is mutually coupled by means of a coupling 20 at a considerable distance f from the associated transverse wall 3 and at a short distance j thereof by means of a coupling 21.

Each stability wall 16 (Fig. 4) and each stability wall 18 (Fig. 6) has an anchoring element 23 near only three of its four corners, while each stability wall 17 has a coupling plate 23 near each of its four corners.

Each anchoring element 23 defines a recess 24 and is welded to anchor rods 25, which have collapsed into the concrete of the stability wall 16-18, whereby a shape for the recess 24 against the associated anchoring element 23 adjoins the respective mold for the stability 25 wall 16-18 is installed before filling this mold with concrete mortar.

The couplings 21 also serve each time to couple the stability walls 16-18 with the associated transverse wall 3. Furthermore, the stability walls 16-18 are connected by means of couplings 26 resp. 27 coupled to the transverse wall 3. This is such that the building 1 obtains its necessary stability in the longitudinal direction 2 according to the force diagram of Fig. 3, wherein vertical compressive and tensile forces 28 pass a considerable distance from the transverse wall 3 through the stability wall 35 and are taken up by the stability walls 16 and 18 via the couplings 20 and in diagonal direction as compressive and tensile forces 29 via the couplings 26 and 27 to the local foundation 44, respectively. the transverse wall 3 are passed through.

n z λ ί 1 1 0

* ιί - \ j; » "W" & V

-5- "sr ·· ~ *>

In the transverse wall 3, the downward compressive forces 30 are guided into the local foundation 44, while compressive and tensile forces 31 are also guided at a small distance j from the transverse wall 3 through the couplings 21 and the stability walls 16-18.

According to Fig. 4, a wall element 10 is always set to the required level on an already laid floor 5, for example by means of bobbins 35, while this wall element 10 is held by means of braces (not shown).

Thereafter, horizontal legs 39 of metal corner pieces 36 serving as book plates are slid into the joint between the bottom edge of this wall element 10 and the floor 5 and this joint is filled with fast-setting mortar 38, while the legs 39 are held against the bottom edge 37.

At the location of stability walls 16 to be fitted, a horizontal metal plate 33 is arranged on the concrete floor 5, which is anchored in the floor 5 with dowel pins 34. Subsequently, a stability wall 16 is placed above the plate 33, again for instance with the aid of wooden blocks 20 and held with braces (not shown). Subsequently, floor plates 9 of the intermediate floor 6 are placed on the wall elements 10 with the insertion of a pressure-distributing strip 46 (fig. 5). Again, here on framing elements 10 and stability walls 17 are set and braced, with the corner pieces 36 being arranged underneath, as described with reference to the ground floor construction layer, and the same is done for the top construction layer with floor 7 and stability walls 18.

Subsequently, the couplings 26 are completed, by means of which the anchoring element 23 is welded to the plate 33 by means of a welding plate 40 and two horizontal welding seams 41 and by means of a vertical welding seam 42 to the vertical leg 43 of the corner piece 36. Furthermore, the two upper anchoring elements 23 of stability wall 35 16, which are intended as coupling elements, are inserted by means of metal bars 45, which are inserted through recessed holes 47 of the floor plates 9. The remaining space between floor 5 and stability wall 16 is made with a hardening material 38, for example cement mortar 8003110

a

-6- of a covering layer 32 coated over the floor 5. Likewise, on the other building layers, couplings 20, 21 are completed by welding operations and the joints with hardening material 38 are added, into which a coating 32 is applied.

According to Fig. 6, the relatively low stability wall 18 is coupled with its top end 50 to the transverse wall 3 by means of couplings 27 consisting of an anchoring element 23 present there and an anchor plate 52 anchored to the wall plate 13 by means of anchor pins 51, which Welding seam 53 is welded to this anchoring element 23.

According to Fig. 7, the wall elements 10 and 10 respectively. 13 to be mutually adjusted and coupled by means of adjusting and fastening means 60. In Figs. 1 and 7, the transverse wall 3 consists of two cavity blades 61, each with wall elements 10. The top 15 ends of the wall elements 10 have anchored therein, protruding set screws 62, which pass through recesses 63 of floor plates 9. Thus, end edges 73 of floor plates 9 are attached to top edges 74 of wall elements 10 by means of the set screws 62, which can absorb horizontal forces both in transverse and longitudinal direction of the building 1. This prevents the spacing of adjacent floor plates 9 from separating. Also, horizontal forces are now transferred via the floor plates 9 and in the case of cavity walls via anchoring elements 64 from transverse wall to transverse wall, so that the plurality of stability walls 16-18 of a common building layer 8 together provide the required stability of this building layer 8.

An anchoring element 64 with two spaced holes is threaded onto the set screws 62, and set nuts 65 are again located above it on the set screws 62, which are adjusted to adjust the level of the wall elements 10 to be placed thereon. These wall elements 10 have hollow metal recesses 66 collapsed into the concrete on their undersides, each with an opening 67 for receiving the top end of an adjusting screw 62.

In a building 1 consisting of only two living layers 8 according to Fig. 8, a force diagram according to Fig. 9 can apply per transverse wall 3 for longitudinal stabilization, wherein two stabilizers 1 1 n

V -y J i j V

Φ '.

-7- the walls of walls 16 and 18 have their diagonal longitudinal and compressive forces 29 from couplings 20 via coupling means 26 and 26 respectively. 27 transfer to the cross wall 3.

The building of Figs. 10 and 11 has only a ground-floor construction layer 8 between a floor 5 and a roof floor 49. The simplest embodiment of a building 1 according to the invention is shown here. Here, again, each stability wall 16 has a coupling 72/71, 26 near only three of its four corners, which three corners define a rigid triangle 54, which is hatched in Fig. 10. This substantially straight triangle 54 has straight sides 55, 56 substantially corresponding to the height and length of the stability wall 16 and with a hypotenuse 57, which substantially corresponds to the diagonal 58 of the stability wall 16. Of this triangle 54, 15 the right upper corner 68 by means of a coupling 72, as described with reference to Fig. 14, with the roof floor 49 and thereby indirectly coupled to the transverse wall 3. Furthermore, the sharp lower corner 69 is coupled to the foundation 44 by means of a coupling 26 and is thereby coupled indirectly to the transverse wall 3. The sharp top corner 70 as well as the right top corner 68 of this triangle 54 are each by means of a coupling 72 and 50, respectively, described below with reference to Fig. 14. 71 coupled to the roof floor 49.

The building 1 of fig. 12 substantially corresponds to that of fig. 1, with the proviso that the facade 11 and the transverse walls 3 are single, thus have thicker wall elements 10. Furthermore, the stability walls 17 and 18 are now staggered relative to each other, on both sides and adjacent to a stairwell 75, which is located in a stairwell floor plate 76, in the plane of a reinforcement basket 77, so that the coupling 78 underneath the stability wall 18 and the coupling 79 on the top of the stability wall 17 engage on a beam piece 80 of the stairwell floor plate 76, which beam piece 80 defines the stairwell 75.

Fig. 13 further shows that a coupling rod 81 in the chalice-shaped joint 82 between adjacent floor plates 9 and 10 respectively. 76 is applied and embedded in the joint mortar 83.

- «Λ - Ί Λ A

giuol I ο -8- * · l t J «

This coupling rod 81 extends through the transverse wall 3 through two aligned joints 82.

Fig. 14 shows the foundation 44 with a cross beam 86 on foundation piles 87 / supporting beams 88. These longitudinal beams 88 are not loaded by the stability walls 16 outside the plane of the cross beams 86, thanks to the arrangement of the stability triangle 54 as shown in Fig. 10. In short, the floor 5 is not loaded by longitudinal stability forces.

According to Fig. 13, the stability wall 16 is attached to a stairwell floor plate 76, adjacent to a stairwell 75 where a beam piece 80 is located. In Figs. 13 and 14, a coupling bolt 90 welded to an anchoring plate 23 for each coupling protrudes through a recess of this beam piece 80, which is provided with a nut 91. This applies to both a top wall and a stability wall 16 arranged under the floor slab.

Thanks to the use of metal corner pieces 36 as coupling elements for coupling the stability wall 16-18 to the transverse wall 3 by hooking the corner plate 20 39 under the wall elements 10, the construction of these wall elements 10 is not influenced by the location of the stable Longitudinal walls 16-18 in the longitudinal direction of the transverse wall 3. As a result, it is economically advantageous to manufacture wall elements 10 in series in advance from the factory and keep them in stock. The wall elements are not bound to a construction project.

'& 0' J o I JU

Claims (14)

Building (1) with a series of juxtaposed compartments (4) separated from each other by transverse walls (3), consisting mainly of reinforced concrete, prefabricated cutting elements (10, 13), the height of which is 5 substantially corresponds to a building layer height (h), wherein at least one floor (6, 7) arranged below and at least one above at least one building layer (8) each substantially consists of a plurality of adjacent, prefabricated bridging a compartment (4) reinforced concrete floor slabs (9) and in which floor slabs (9) of a floor (6) located above a building layer (8) are laid with their two end edges (73) on top edges (74) of wall elements (10) characterized in that at least one reinforced concrete prefabricated stability wall (16-18) in longitudinal direction (2) of the building (1) is arranged in the ground-floor construction layer adjacent to at least two transverse walls (3), which stability wall ( 16-18) - viewed in the longitudinal direction (2) of the building (1) - has a length (c) which is considerably shorter than the length 20 (d) of a compartment (4); that each of at least two stability walls (16-18) has in each case a coupling (72, 71, 26) near only three of its four corners, the three corners of which are a rigid triangle (54) with straight sides (55, 56) substantially corresponding 25 determine with the height and the length of the stability wall (16-18) and with the hypotenuse (57) substantially corresponding to the diagonal (58) of the stability wall (16-18)? that the right upper corner (68) of this triangle (54) is coupled directly or indirectly to the transverse wall (3) by means of a coupling (72), the sharp lower corner (69) directly by means of a coupling (26) or is coupled indirectly to the foundation (44) and the transverse wall (3), while the sharp top corner is coupled at least to the floor (6) above by means of a coupling (71)? and "J." 110 -10- • I 4 that the two end edges (73) of floor plates (9) of the floor (6) located above this construction layer (8) are at top edges (74) of wall elements (10). fastened by means of both horizontal and longitudinal direction of the building (1) 5 horizontal force-absorbing fasteners (60). Building (1) according to claim 1, characterized in that stability walls (16-18) are arranged at distances (a, b) from the two longitudinal sides (14, 15) of the building (1). Building (1) according to claim 1 or 2, characterized in that the stability walls (16-18) are arranged adjacent to a stairwell (75). Building (1) according to any one of the preceding claims, characterized in that at least two stability walls (16-18) in different building layers (8) are arranged directly above each other and directly connected to each other by means of couplings (20, 21) are linked. Building (1) according to one of the preceding claims, characterized in that at least two stability walls (16-18) are arranged staggered one above the other in different building layers (8) over a stairwell width (k). Building (1) according to one of the preceding claims, characterized in that at least one stability wall (16-18) is arranged next to a stairwell (75) of a stairwell floor plate (76) above a longitudinal edge (80) of this stairwell floor plate 25 (76) and thus by means of a coupling (78, 79) on a large resp. is coupled a short distance (f or j) from the associated transverse wall (3). Building (1) according to any one of the preceding claims, characterized in that a pair of stability walls (16-18) arranged one above the other with the insertion of an intermediate floor (6, 7) are mutually coupled by means of couplings (20, 21), each comprising at least one steel anchoring element (23) cast into the concrete of this stability wall (16-18). Building (1) according to claim 7, characterized in that a coupling element (45) extending through the intermediate floor (6,7) to the anchoring element (23) of each of the two stability walls (16-18) is welded. · «" * - · - * S * \ ** * * -11- -v · .. V Building (1) according to any one of the preceding claims, characterized in that an anchoring element (23) cast into the concrete of a stability wall (16-18) consists of a metal plate anchored in the concrete, consisting of a - delimits 5 recess (24) of this stability wall (16-18). Building (1) according to any one of the preceding claims, characterized in that there is at least one intermediate floor (6, 7), wherein stability walls (16-18) are arranged one above the other, the upper and the lower stability wall being (18 and 16, respectively) near their top or bottom. bottom end are anchored substantially only near the associated transverse wall (3). Building (1) according to any one of the preceding claims, characterized in that the lower end of at least one stability wall (16-18) is coupled to the associated transverse wall (3) by means of a coupling (21), comprising at least one horizontal metal corner plate (39), which is located under a scraper element (10, 13), which corner plate (39) is connected via at least one weld to an anchoring element 20 (23) of the stability wall (16-18). Building (1) according to any one of the preceding claims, characterized in that the stability wall (16-18) forms a wall of a sanitary room. Prefabricated reinforced concrete stability wall 25 (16-18), characterized in that near each of three of the four corners of this stability wall (16-18) there is an anchoring element (23) anchored in its concrete to complete couplings (20, 21) of a building according to any of the preceding claims. Stability wall (16-18) according to claim 13, characterized in that the three anchoring elements (23) cast in concrete of the stability wall (16-18) each consist of a plate anchored in the concrete, which recess (24) of this stability wall (16-18). OS <3 31 10