DE3308156A1 - Structure (building or civil engineering structure) - Google Patents

Abstract

Load-bearing structure (building or civil engineering structure), having load-bearing beams (11) and ceilings comprising ceiling slabs (12) which rest on the beams (11), both the beams (11) and the ceiling slabs (12) consisting of asbestos cement for the purpose of increased corrosion and ageing resistance. To achieve an increased load-bearing capacity, the beams (11) each consist of a plurality of board- or plate-shaped lamellae (14) made of asbestos cement and preferably extending in an approximately upright plane, whereas the ceiling slabs (12) are for this purpose designed as composite slabs, consisting of at least two asbestos-cement slabs (24) spaced apart by means of distance pieces (23). The distance pieces (23) are preferably strips of asbestos-cement slabs which are cut from the same flat slabs made of asbestos cement as the two outer asbestos-cement slabs (24) of the ceiling slab composite construction (12). <IMAGE>

Description

Structure (building or engineering structure)

Description of the (load-bearing) structure (building or engineering structure) with load-bearing beams (girders) and / or ceilings made from ceiling panels that rest on the beams rest.

For such structures, in particular engineering structures, such as large water tanks Od. Like. So far, reinforced concrete structures are primarily used, and usual reinforced concrete skeleton structures with columns, beams and ceilings Reinforced concrete. This construction has the disadvantage that it is very susceptible to corrosion is, ins- special due to the steel reinforcement. The risk of corrosion is especially great when the building structure is used to store liquids serves with increased aggressiveness.

The present invention is based on the object of a load-bearing To create a structure of the type mentioned above, with an unchanged load-bearing capacity characterized by high corrosion resistance. This object is achieved according to the invention solved by the measures of claims 1 to 18.

The building material "asbestos cement" used according to the invention is characterized high resistance to corrosion, strength and ease of processing the end. Preferably, the bars each consist of several, approximately more upright Flat, board-shaped or plate-shaped slats made of asbestos cement, the are connected to each other by transverse connecting bolts. Through the lamellar Structure of the beams or girders will have a high load-bearing capacity or load-bearing capacity given construction height. The load capacity or resilience can the number of lamellas in a simple manner to the desired proportions adjust. The number of transversely directed connecting bolts can be reduced by the advantageous Reduce the arrangement of the same according to claim 4 to a minimum.

The design of the ceiling panels according to the invention is also a special feature to be viewed, regardless of the beam construction mentioned. The ceiling tiles are designed according to claim 12 as composite panels consisting of at least two Asbestos cement panels held at a distance by spacers. These are due to this with bending loads in the tension and compression zones, while the spacers in the Phase of the shear stresses. Preferably are the spacers strip-shaped and extend essentially over the entire Length of the ceiling panels. They are also made of asbestos cement, which -as already explained - is very corrosion and aging resistant and without special reinforcement A high tensile and compressive strength is guaranteed due to the asbestos fibers (fiber reinforcement).

If the structure is a large water tank or the like, at least the insides of the basic structure, such as the floor and / or side walls, are preferred each with an asbestos cement plate and, if necessary, a plastic layer (plastic skin) covered. This increases the corrosion resistance of the basic structure, which usually (for reasons of compressive strength) consists of reinforced concrete.

The following is an example of a building structure according to the invention explained in more detail with reference to the accompanying drawing. They show: FIG. 1 one in the ground Sunk arranged large water tank with a ceiling construction according to the invention in a schematic longitudinal section; Fig. 2 the ceiling construction according to Fig. 1 in plan view, with part of the ceiling panels broken away; 3 shows part of the ceiling construction according to Figure 2 on an enlarged scale and plan view; FIG. 4 that shown in FIG. 3 Part of the ceiling construction in section along line IV-IV in FIG. 3; Fig. 5 partially shows the connection of the beams designed according to the invention to a support bearing in section and partially in view and on an enlarged scale; Fig. 6 shows the connection according to Fig. 5 in plan view; 7 shows the connection of a device designed according to the invention Beam on the side wall of the basic construction in side view and in section; 8 shows a part of a ceiling panel according to the invention in section; and FIG. 9 the Ceiling plate according to FIG. 8 in plan view.

The building structure according to the invention is based on an in the ground sunk arranged large water tank 10 with a base structure Reinforced concrete (floor 26 and side walls 27) described. The ceiling construction as well the support of the same is part of the invention and is now based on FIG. 2 to 9 described in more detail: The ceiling construction consists of a cross Beams 11 on which ceiling panels 12 rest. The beams 11 and ceiling panels 12 each consist of asbestos cement, a material that is absolutely corrosion and is resistant to aging, especially against aggressive water and vapors. Furthermore, asbestos cement without special reinforcement is characterized by high tensile and Pressure resistance, through the asbestos fibers.

According to FIGS. 3 to 6, the bars 11 each consist of several board-shaped slats 14 made of asbestos cement, extending in an upright plane, across the aligned connecting bolt 15 made of corrosion-resistant Steel are connected to each other. As can be seen in FIG. 4, the connecting bolts are 15 arranged in the area of higher shear or shear stresses, d. H. adjacent to the end supports 16 and 17 of the beams 11 distributed towards.

In the illustrated embodiment, the bars 11 and the ceiling structure 11, 12 not only on the side walls 27 of the basic structure, but additionally in the area of the crossing points of the bars 11 by upright columns or Supports 13 supported, with the supports at the upper ends of the supports 13 16 for the beams 11 are arranged. On these supports 16 and on the side wall supports 17, the bars 11 are statically free, that is, without restraint in the static sense. Those at the upper ends of the upright supports 13, which are made from asbestos-cement pipes are, arranged end supports 16 for the beams 11 each consist of one for several beams 11 common bearing plate 18 and upright, each one end of one Beam 11 laterally supporting side brackets 19 in the form of angle profiles, with the legs 20, 21 of which are connected to the ends of the beams 11 by connecting bolts 22 are. The bearing plate 18 and the side holder designed as angled profiles 19 and connecting bolts 22 are each made of non-corrosive material, preferably Stainless steel. The holes arranged in the beam 11 for the passage the connecting bolts 22 each have a larger diameter than the connecting bolts 22 so that the arrangement of the connecting bolts 22 in the area of the upright supports does not lead to a clamping of the beams 11 in the static sense. Similarly tension-free is the connection of the beams 11 to the end supports 17 in the area of the side walls 27 (Fig. 7).

The training according to the invention is of very particular importance of the ceiling panels 12, each as composite panels educated consist of at least two spaced apart by spacers 23 Asbestos cement sheets 24 (see Figs. 4 and 7-9). The spacers 23 are each strip-shaped and extend essentially over the entire Length of the ceiling panels 12 (see Fig. 9) The spacer strips 23 are just like the Panels 24 made of asbestos cement. According to FIGS. 4, 8 and 9 are several, Spacer strips 23 lying parallel to one another over the width of a ceiling plate 12 distributed or arranged at a distance from one another. The connection between the Spacer strips 23 and asbestos cement panels 24 are made through each length of the ceiling panels 12 or

Spacer strips 23 distributed connecting bolts 25 (Fig. 9), which are made of stainless steel, preferably stainless steel. Thereby are in the End areas of the ceiling panels 12 or spacer strips 23 each have a larger number arranged by connecting bolts 25, so in the areas for shear or shear stresses. The ceiling panels 12 designed according to the invention are extremely lightweight constructions with high load-bearing capacity, as tests have shown. According to Figs. 4 and 7, 8 are as spacers 23 each two superimposed asbestos cement plate strips intended. With a plan dimension of a ceiling plate 12 of 250 cm x 62.5 cm is the thickness of the asbestos cement panels 24 and the asbestos cement panel strips preferably 20 mm each, so that a total height of the ceiling plate 12 of about 8 cm is obtained. The width of the asbestos cement panel strips or spacers 23 is about 100 mm. The center distance of the spacers 23 from the longitudinal edges of the ceiling panels 12 in the example mentioned is about 125 mm and one below the other about 375 mm. M10 screws made of stainless steel are used as connecting bolts 25. The distance between the screws is preferably 150 to 300 mm, with the screw distance in the two end regions of the spacers 23 is smaller than in the middle area (see Fig. 9). The screws are preferably even strong tightened, with the selected dimensions in each case with a torque of about 50 Nm.

About the corrosion resistance of the overall construction, including the To raise the basic structure 26, 27 are the bottom 26 and side walls 27 of the basic structure both inside and outside each with at least one asbestos cement panel 28 and optionally provided with a plastic skin 29, with the embodiment according to FIG only the inside of the side walls 27 and the bottom 26 (not shown) with a plastic skin 29 is covered.

According to Fig. 1, the ceiling 11, 12 of the large water container 10 is with soil covered, with the purpose of sealing (smell!) before backfilling with earth A sealing membrane 30 is placed over the ceiling panels 12, with between Sealing membrane 30 and the ceiling panels 12 are additionally arranged rigid foam panels 31 could be. These are used for thermal insulation, so that there is a risk of frost in the event of frost Icing of the water or the like in the container 10 is considerable is reduced.

LIST OF REFERENCE NUMERALS 10 large water tank 11 beam (carrier) 12 ceiling plate 13 Support (column) 14 Lamella 15 Connecting bolt 16 (end) support 17 (end) support 18 bearing plate 19 side bracket (angle profile) 20 legs 21 legs 22 connecting bolts 23 Spacer (asbestos-cement plate strip) 24 asbestos-cement plate 25 connecting bolt 26 Floor 27 Side wall 28 Asbestos cement panel 29 Plastic skin 30 Sealing membrane 31 rigid foam board

Claims (18)

Structure (building or engineering structure) Patent claims 1. (load-bearing) Structure (building or engineering structure), with load-bearing beams (girders) and / or Ceilings made from ceiling panels that rest on the joists, which are not possible n z e i c h n e t that the beams (11) and ceiling panels (12) made of asbestos cement exist. 2. Structure according to claim 1, characterized in that each beam (11) of several, preferably extending in an approximately upright plane, board- or plate-shaped lamellae (14) made of asbestos cement. 3. Structure according to claim 2, characterized in that the slats (14) are connected to one another, in particular by transverse connecting bolts (15). 4. Structure according to claim 3, characterized in that the connecting bolts (15) in the area of higher thrust or. Shear stresses, especially adjacent to the (End) supports (16; 17) of the bars (11) distributed towards, are arranged. 5. Structure according to claim 4, characterized in that the beams (11) rest statically freely on the (end) supports (16; 17). 6. Structure according to claim 4 or 5, characterized in that the (End) supports (16; 17) made of non-corrosive material, in particular stainless Steel. 7. Building according to one of claims 4 to 6, characterized in that that the (end) support (16) consists of a bearing plate common to several beams (11) (18) and upright, each at the end of a beam (11) laterally supporting side brackets (19) exists. 8. Structure according to claim 7, characterized in that the side holder (19) consist of angle profiles, with the legs (20, 21) of the ends of the beams (11) are connected by connecting bolts (22). 9. Building according to one of claims 1 to 8, characterized in that that the bars (11) rest on upright columns or supports (13), in particular the bearing plates (18) are arranged at the upper end of the upright supports (13) or are attached. 10. Structure according to claim 9, characterized in that the upright Supports (13) consist of asbestos cement. 11. Structure according to claim 9 or 10, characterized in that the Upright supports (13) are asbestos-cement pipes. 12. Building, in particular according to one of claims 1 to 11, characterized characterized in that the ceiling panels (12) are designed as composite panels, each consisting of at least two spaced apart by spacers (23) Asbestos cement panels (24). 13. Structure according to claim 12, characterized in that the spacers (23) also consist of asbestos cement. 14. Structure according to claim 12 or 13, characterized in that the spacers (23) are strip-shaped (asbestos-cement plate strips) and each extending over substantially the entire length of the ceiling panels (12). 15. Structure according to claim 14, characterized in that several spacers (23) lying parallel to one another over the width of a ceiling plate (12) are distributed or arranged at a distance from one another. 16. Structure according to one of claims 12 to 15, characterized in that that the spacers (23) and asbestos-cement plates (24) are connected to one another, in particular by each over the length of the ceiling panels (12) or spacers (23) distributed connecting bolts (25). 17. Structure according to claim 16, characterized in that in the end regions the ceiling panels (12) or Spacers (23) each have a larger number of connecting bolts (25) is arranged. 18. Building, in particular according to one of claims 1 to 17, characterized characterized in that the basic construction, such as the bottom (26) and / or side walls (27), with at least one asbestos cement plate (28) and possibly with a plastic layer (Plastic skin 29) is covered.