DE10004640A1 - Hollow body with spacers - Google Patents

Abstract

The invention relates to a hollow-block concrete floor or hollow-block concrete slab that consists of concrete provided with reinforcements and conical hollow blocks (1) that have a substantially round, oval or more than tetragonal cross-section. Said hollow blocks (1) are at least partially interdisposed between an upper and a lower reinforcement layer (15, 16) substantially in the form of highest-possible packing, whereby sections without a hollow-block structure (1) can be provided between the upper and the lower reinforcement layer (15, 16). The aim of the invention is to improve conventional hollow-block concrete floors. To this end, spacers (8, 9) are provided between the upper reinforcement layer (15) and the hollow-block (1) and between the lower reinforcement layer (16) and the hollow-block (1). At least some of the compartments formed by three adjoining hollow blocks (1) each are provided with vertical reinforcements (17).

Description

The invention relates to a buoyancy-free hollow body for the production of Reinforced concrete hollow slabs and ceilings, which as open and downwards circumferentially closed container is formed and possibly in the top wall Vent holes are provided.

Such buoyancy-free hollow bodies are known from DE 298 21 000. in the In contrast to other systems, the known hollow bodies do not have to Buoyancy can be secured. These are only on the lower reinforcement layer posed. So that the arrangement of the hollow body in precisely defined positions can be done, the invention proposes to create a reinforcement cage with at the same time a constant concrete coverage of the surface and Shear reinforcement is ensured. The proposed reinforcement cage exists of an upper ring bent from round steel and a corresponding one lower ring, which is fixed coaxially at a distance by means of standing struts are. In this reinforcement cage there is a circumferentially closed one that is open at the bottom Can be suspended, the top wall of which has ventilation holes.

The disadvantage of this system is that the reinforcement cage is made of round steel must be manufactured. Furthermore, the fixation of the hollow body in the Reinforcement cage is relatively complex.

The object of the invention is therefore the cost of producing To reduce hollow ceiling and increase the functionality of the hollow body.

This object of the invention is achieved in that the Containers spacers.  

With the invention it is achieved that on reinforcement cages for fixing the Hollow body can be dispensed with. The hollow body can be thanks to the spacers be positioned very precisely. The with the hollow bodies according to the invention manufactured ceiling has a honeycomb shape that allows minimal wall thicknesses and is optimally designed with regard to the buckling surfaces. It is of great advantage that as Hollow body commercially available plastic buckets can be used, which are cheap in Mass production can be made.

The hollow body according to the invention with a spacer simultaneously meet the Cavitation functions serve as a working level since they are walkable and serve as spacers for the top layer and among each other. You are without Measuring contact to contact can be laid. Another advantage is that if no reinforcement of the webs is required, this is also not available, such as this is the case when using reinforcement cages. This will Material and thus costs saved. Installation on site is not necessary.

In areas where the ceiling must be solid, plastic or reinforcing steel rings of the same external dimensions as the hollow body, so that a stringing in this area can be done without any problems. Only in these areas are reinforcement cages when using plastic rings required to ensure accessibility and the spacer function.

According to a particularly advantageous embodiment, the spacers are ring-shaped. When using conical plastic containers as Hollow bodies, the spacers of this shape are well adapted.

Characterized in that the spacers outside, up and / or down and / or aligned to the side ensures that the distance of the hollow body in all directions can be followed. By varying the size of the  Spacers, the distances can be adjusted as needed. This is given a flexible design option.

A particularly advantageous development provides that the spacers Have openings that are in a cylindrical surface, concentric to the Hollow body axis lie. The concrete penetrates through these openings and can Reinforcement bars need to be inserted.

It is advantageous that the spacers have openings that are in a annular surface lie radially to the axis of the hollow body. These are used for Concrete conduction and to hold reinforcement bars and guarantee one firm position in the concrete ceiling as the concrete fills the openings.

It is particularly advantageous that means for attaching the spacers on Containers are provided. So the spacers can be separated from the Hollow bodies are made. It can therefore be commercially available Plastic containers are used. The spacers only need to be on site the containers are attached. It is conceivable that the spacers simply open the hollow body can be plugged on.

A particularly advantageous embodiment provides that the spacers by means of a clip mechanism are attached to the hollow body. For this purpose, in openings are introduced at regular intervals on the circumference of the hollow body, in which the spacers can be clipped on. The clip mechanism ensures a firm hold and sufficient stability.

A particularly advantageous development of the invention provides that the Spacers are composed of individual parts. This measure will Space saved in the storage and transportation of the spacers. The  Clip on the spacers is much easier, since not the whole Weight of the spacer must be moved when clipping onto the hollow body.

An advantageous development provides that the hollow body is conical are to stack them into each other. This saves space and facilitates storage and Transport.

The invention also includes a concrete ceiling using buoyancy-free Hollow body, it being provided that vertical reinforcement bars, in particular Nelson head bolts, between the hollow bodies, preferably in areas required shear reinforcement are attached. So it is easy for adequate reinforcement is ensured in these areas. It is special Advantage if the Nelson head bolts are attached using a three-point bearing on three adjoining spacers.

The fact that means for connecting the hollow bodies to one another are provided, their position can be fixed. This ensures that the honeycomb ceiling does not move when pouring the concrete.

The position of the hollow body is particularly easily fixed by means of wire. This Embodiment is cheap and can be done quickly and easily.

Exemplary embodiments of the invention are described in more detail with the aid of drawings described.

Show it:

Fig. 1 is a perspective view of the hollow body with spacers,

FIG. 2 shows a perspective of the hollow body with anklipbaren spacers,

Fig. 3 is a representation of the Anklipsmechanismus,

Fig. 4 is a schematic representation of the hollow body in the composite,

Fig. 5: a perspective view of a Nelson headed stud and

FIG. 6 is an illustration of a hollow composite.

In Fig. 1, a buoyancy-free hollow body 1 is shown, the top wall 2 has ventilation holes 3 . On the hollow body floor side, circumferentially and on the top wall 3 opposite bottom side attached spacer 4. 5 The spacers are ring-shaped. Openings 6 are cut out around the entire circumference of the spacers. These lie on the one hand in a concentric cylindrical surface 20 or in a radial annular surface 21 . The openings 6 serve to receive reinforcing bars. The reinforcement bars can be guided horizontally and vertically or obliquely through the openings 6 . The fixation of the hollow body in the concrete through the openings is significantly improved since the concrete penetrates the openings 6 . The hollow body 1 consists of a conically shaped container made of plastic. This enables the hollow bodies 1 to be stacked one inside the other. The weight is significantly reduced by using plastic.

A hollow body 1 is also shown in FIG. 2. The difference from FIG. 1 is that the spacers 7 , 8 , 9 can be clipped onto the hollow body 1 . The circumferential spacer 8 is composed of four sections that are to be clipped on individually. The spacers 7 and 8 are attached to the hollow body from above and from below. In this embodiment, the spacers 7 and 8 are shown in one piece. But it is also possible to put the spacers 7 and 8 together from several sections.

The principle of a possible clip mechanism 11 is explained in FIG. 3. Bores 10 are made in the hollow body. The spacers 8 and 9 are inserted into these holes by means of a clip mechanism 11 in the holes. The clip-on mechanism consists of a web 12 , at the end 13 of which is remote from the spacer 7 , 8 , an elastic wedge 14 is attached, which engages against the 12 when inserted into the bore 10 , and straightens up again after insertion into the bore 10 , whereby the spacers 7 , 9 are fixed.

In FIG. 4, a hollow body 1 is shown in a hollow body composite. The necessary spacing from the adjacent hollow bodies is kept by the circumferential spacer. The upper spacer 8 and the lower spacer 9 keep the distance to the upper and lower reinforcement layers 15 , 16 .

In FIG. 5, a Nelson is - headed bolts 17 illustrated. This can be hung between adjacent hollow bodies in areas where shear reinforcement is required.

In FIG. 6, a composite hollow body is illustrated. The hollow bodies 1 with spacers are joined together in the smallest possible packing density. In areas of required shear reinforcement, Nelson headed bolts 17 are suspended between adjacent hollow bodies. In areas 18 where the ceiling must be solid, reinforcement cages 19 with the same dimensions as the hollow body 1 are installed.

REFERENCE SIGN LIST

1

Hollow body

2

Ceiling wall

3rd

Ventilation holes

4

Bottom side

5

Spacers

6

openings

7

circumferential spacer

8th

upper spacer

9

lower spacer

10th

Holes

11

Clip mechanism

12th

web

13

The End

14

wedge

15

upper reinforcement layer

16

lower reinforcement layer

17th

Nelson head bolt

18th

solidly designed ceiling area

19th

Reinforcement cages

20th

concentric area

21

radial surface

Claims (12)

1. buoyancy-free hollow body ( 1 ) for the production of reinforced concrete hollow body slabs and ceilings, which is designed as a downwardly open and circumferentially closed container and in the top wall ( 2 ) of which vent holes ( 3 ) are provided, characterized in that the container Has spacers ( 5 , 7 , 8 , 9 ). 2. Buoyancy-free hollow body according to claim 1, characterized in that the spacers ( 5 , 7 , 8 , 9 ) are annular. 3. Buoyancy-free hollow body according to claim 1 or 2, characterized in that the spacers ( 5 , 7 , 8 , 9 ) are aligned upwards and / or downwards and / or circumferentially. 4. buoyancy-free hollow body according to one of claims 1 to 3, characterized in that the spacers have openings ( 6 ) which are concentric to the hollow body axis in a cylindrical surface ( 20 ). 5. buoyancy-free hollow body according to one of claims 1 to 4, characterized in that the spacers have openings ( 6 ) which lie in an annular surface ( 21 ), radially to the hollow body axis. 6. Buoyancy-free hollow body according to one of claims 1 to 5, characterized characterized in that means for attaching the spacers to the container are provided.   7. buoyancy-free hollow body according to one of claims 1 to 6, characterized in that the spacers ( 5 , 7 , 8 , 9 ) are attached to the hollow body ( 1 ) by means of a clip mechanism ( 11 ). 8. buoyancy-free hollow body according to one of claims 1 to 7, characterized in that the spacers ( 5 , 7 , 8 , 9 ) are composed of individual parts. 9. buoyancy-free hollow body according to one of claims 1 to 8, characterized in that the hollow body ( 1 ) are conical in order to saddle them into one another. 10. Concrete ceiling using buoyancy-free hollow bodies, characterized in that vertical reinforcement bars, in particular Nelson head bolts ( 17 ), are hung between the hollow bodies ( 1 ), preferably in areas of required shear reinforcement. 11. Concrete ceiling using buoyancy-free hollow body according to claim 10, characterized in that means for connecting the hollow body ( 1 ) are provided with one another. 12. Concrete ceiling using buoyancy-free hollow body according to one of claims 10 or 11, characterized in that several hollow bodies are connected by means of wire to fix the position of the hollow body ( 1 ).