DE2611479A1 - Wall concrete elements prefabricated sheathing component - has inner and outer sheath with external surfaces connectable to surrounding wire mesh - Google Patents

Abstract

The sheating concrete prefabricated element can be of any height, up to storey height, as used in constructing walling round the outside of a building. Inner and outer sheaths (1, 2) are made of concrete slabs, or concrete building blocks individually in rows one above another. They are surrounded on the external surface by a wire mesh (4), and the external surfaces can be connected with this. Clamps may be used for this connection. The wire mesh may protrude beyond the top row of the sheath, and be shaped into a loop-shackle-shaped connecting unit. It may also serve as reinforcement for a rendering, and may be carried down round the bottom block of the sheath.

Description

Shell concrete - prefabricated part - elements The previously known shell concrete construction methods consist of two different types of work.

First, it is known that building blocks or building panels at the construction site Set in droves on top of each other and continuously fill the cavities with concrete so that a coherent core concrete is created, which acts as a load-bearing element works.

In the second embodiment, prefabricated floor-to-ceiling shell concrete elements are used used which made of panels or boards and on the construction site put together to form a comprehensive masonry shell and then poured with core concrete will.

The first embodiment has the major disadvantage that the building blocks or panels are not prefabricated floor-high and as floor-to-ceiling Unit are transportable.

While in the second previously known embodiment, a rational one Construction is possible here; the following disadvantages are associated with it: 1. The connection between the outer and inner shell concrete shell requires its own construction, is therefore more difficult to accomplish and therefore more expensive.

2. The corner joints and connections of load-bearing partition walls are cumbersome to manufacture.

3. The stiffening of the elements and the connection of the individual panels are not optimally resolved, especially in the case of elements with wall openings, so that this has a strong influence on manufacture.

4. The relocation of the individual elements on the construction site, as well the connection between the individual elements is not particularly easy in the execution and therefore also associated with driving costs.

The object of the preceding invention is therefore to provide the to avoid the disadvantages described and the advantages of the conventional and known Shell concrete block or slab construction with the advantages of the already known system the floor-to-ceiling concrete cladding construction. Another task of the Invention is to create large-scale floor-to-ceiling concrete elements in which to relocate as much work as possible to a permanent manufacturing company and thus a factory standard and therefore to achieve efficient production, however, on the other hand, to achieve the lowest possible transport weight and still be able to create a massive monolithic structure. this will achieved by the fact that only the relatively light concrete shell is factory-made in larger ones Elements is prefabricated, but the load-bearing, massive core concrete only on the Construction site is brought in.

In the case of a cladding brick prefabricated wall element of any height, preferably up to floor level, the object is achieved according to the invention in that the interior and outer jacket made of concrete cladding slabs or concrete cladding blocks, which are individually in droves are layered on top of each other, on the outer surface of which is spanned by a wire mesh are.

According to the invention, the solution to this problem is to provide larger precast concrete cladding elements any known type z.3. to be produced with conventional spacers in such a way that that already in the prefabrication section, clad concrete blocks or slabs in droves be stacked on top of each other, but the outer surfaces of the so joined Element spanned by a 3-wire pierced and this possibly with the outer surfaces the stones or flats are connected by means of clamps in such a way that one firmly connected Element is created even before the core concrete is poured in.

Another feature of the invention is that the wire mesh protrudes over the top share, so that a transport bar can be attached here can or the grid (wire mesh) to a bow-shaped transport device is shaped.

According to the invention, the wire mesh can be a commercially available mesh, Expanded metal, lattice or uahitzwlecht and in it at the same time as plaster annealing to serve, the common plaster cracks, especially in the Sheathed concrete plst construction, to be avoided.

The wire mesh can also according to the invention around the lower crowd Cladding stones or plates can be led around the bottom.

Advantageously, the grille protrudes from the element joints (laterally upwards) beyond the elements to make the joints seamless.

The invention offers the advantages of shell concrete construction (heat-insulating Shell as formwork for the concrete core functioning as a load-bearing component) as well as that of prefabricated construction (prefabrication of larger wall elements, possibly including Installation of the necessary installations and application of the plaster ih rational working production facilities) in a very favorable connection, because of the transport weight very crucial concrete core only on the construction site after moving the elements is introduced.

The invention is illustrated in the following section with reference to drawings explained, in which illustrative examples are clarified; It shows: Fig. 1 an inventive Element in an oblique view Fig. 2 shows a corner element or wall connection element according to the invention 3 shows a wall element according to the invention with a plate construction in a perpendicular section FIG. 4 shows a wall element according to the invention with a stone construction in a perpendicular section in FIG. 5 a Viand element according to the invention with a panel construction (horizontal section) Fi ,. 6 an according to the invention Wall element with stone construction (151a section), In Fig. 1 is-a Floor-high Manteloeton .xiand element (panel construction) shown according to the invention, which is composed of the outer jacket 1 and the inner jacket 2. The two coats which are supported with connecting brackets 3 or webs of conventional design, have an opening serving as a window. The outer surfaces of the two coats will be enclosed by a wire mesh 4, which protrudes upwards and laterally. In the examples shown, the wire mesh 4 consists of a conventional structural steel grid, the wire mesh end protruding in height is as. hilly connection 5 formed so that for transport purposes, for example, a support beam, bracket or Rail can be inserted.

The wire mesh protruding to the right serves as an overlap for the next '-and element, which is connected seamlessly by this measure.

Of course, the nacn ooen outstanding wire mesh is also used used for overlapping in the case of multi-storey construction. The wire mesh 4. the initially extends over the entire outer surfaces of the jacket 1, 2, is subsequently in the case of the Benster iSnrng 5 cut out so that the ends are folded in can.

In order to achieve a high degree of dimensional stability during the filling with core concrete To ensure V1antels, cutting out is preferred after solidification. of Concrete passed through.

In Fig. 2 is an embodiment of a corner element and a Wall connection shown.

This example differs from that described in FIG land element according to the invention only in that the wire mesh 4 is angled. In the corner there is both a continuous and an overlapped wire mesh possible. All other elements correspond those shown in FIG.

Fig. 3 shows the wall element described in Fig. 1 and Fig. 2 in Cut (plumb cut).

The inner and outer jacket 1, 2 standing on the floor is made of several plate groups built up, also in groups by common spacers (Connecting brackets 3) are connected or held exactly. The one on the outside and wire mesh 4 surrounding the bottom is also clamped to the plates tied together; the sheath 1, 2 is rather more stable due to the wire mesh Location held. The wire mesh 4 protrudes over the top group of the inner and outer sheath 1, 2 addition, so that the wire mesh end has a bow-shaped connection 5 for the Introducing a supporting timber 7 represents.

The element shown in Fig. 4 consists of commercially available Stones 8 together that 1tu the inner and outer jacket. 2 'form. The stones are like the plate elements (Fis. 1-3) built into a storey-high wall element.

The connecting brackets 3! also ensure greater stability of the element (e.g. during transport). The wire mesh 4 also encloses here the outer surfaces of the jacket 1, 2 '. The wire mesh end protruding over the top stone flock is hung in a support device 10 in this example. This consists of a U-beam 11 with hooks (cross bars), which are at any distance in the wire mesh hook up. The device 10 can be connected to any transport device (ran, etc.) be made.

In FIGS. 5 and 6, the peripheral elements are shown in horizontal section. In Fig. 5 it is made of plates, in Fig. 6 the Jana element made up of stones shown.

The inner and outer sheaths are marked with 1, 2 and 1 ', 2, respectively. at the plate construction Fig. 5 preferably come in addition to the usual connecting brackets 3, which run perpendicular to the two wire meshes 4 and connect them, Diagonal connecting brackets 3a are also used. The brackets can also be used as be designed torsion-resistant rectangular brackets. The brackets 3, 3a are for example inserted between the Sharan. The brackets are used to stiffen the elements during transport and for connecting the elements to one another at the element joint.

In FIGS. 5 and 6 there is also the overlap of the wire mesh over which it passes 4 of an element visible at the element joints, the one bent down in the direction of the arrow and is connected. Naturally are in a wall element made of stones no additional diagonal connecting brackets necessary than the one shown Element impact.

Claims (8)

PATENT CLAIMS 1. precast concrete cladding element of any height, up to Storey height, characterized in that interior u. Outer jacket (1,1,1 ', 2') made of concrete slabs or concrete blocks, which are individually stacked in groups, on the outer surface of one Wire mesh (4) is spanned (surrounded) and the outer surfaces with the wire mesh (4) can be used. 2. Element according to claim 1, characterized in that the wire mesh is connected to the outer surfaces of the jacket (1, 2) with clips. 3. Element according to claims 1 and 2, characterized in that the wire mesh (4) protrudes over the top group of the jacket (1, 2) and closes a bow-shaped connection (5) is formed. 4. Element according to claims 1 to, characterized in that the wire mesh (4) is a commercially available V braid, expanded metal, screed grating or can be rabid, braid. 5. Element according to claims 1 to 4, that the wire mesh (õ) is also a plaster reinforcement. 6. Element according to claims 1 to 5, characterized in that the wire mesh (4) on the bottom around the lower shell stones of the jantele (1, 2) being led around. 7. Element according to claims 1 to 5, characterized in that wire mesh (L) on the outer surfaces through connecting clips (7) connected to the element eyelets as diagonal brackets (5a) or torsionally rigid Rechtce mern from forms are. 8. Element according to claims 1 to 7, characterized in that the wire mesh (4) is overlapped at the element joints (Fig. 5, -6),