DE2200156A1 - SEMI-SHELL PRE-FABRICATED ELEMENTS WITH LOCAL CORE FILLING - Google Patents

Description

Half-shell prefabricated building elements with local core filling The invention concerns semi-shell-shaped prefabricated construction elements whose enclosed cavities @ according to the moniage must be filled in a load-bearing manner.

The invention has the purpose of making the unsatisfactory on the market Solutions for prefabricated construction methods and elements, especially in prefabricated house construction, are essential to simplify and thus to improve their profitability.

The conventional prefabricated houses have according to the known Manufacturing methods essentially include the following construction principles: Flat precast concrete elements with internal thermal insulation, so-called sandwich panels; Wooden or steel framework with heat-insulating infills and wall cladding made of wood, steel, plastic panels, plaster elements, plasterboard panels etc .; Scarf stones for concrete filling (Isospan, Durisol or similar) for internal and external plaster; Aerated concrete elements or floor-to-ceiling panels with coating on the wall surfaces.

All known prefabricated construction methods are based on historical development more or less taken from the solid construction. It just becomes part of the manufacturing process Relocated to the weather-independent workshop and assembly on the building site Minimum restricted; What remains is a multitude of individual elements and details. for the production of which expensive skilled workers are required, the precast concrete elements are heavy and have high freight costs; the local assembly is cumbersome and requires expensive tools in the form of assembly equipment; the joint problem is technically only incompletely solved and gives cause for ongoing repairs; building physics Concrete is not very suitable for living areas because of its low diffusibility. The components of the so-called.

Prefabricated houses @ are usually extremely unstable from a technical point of view; the different, Building materials arranged one behind the other cause different movements Influence of temperature and are therefore susceptible to repair; the joint problem is also here technically unsolved; the small building mass has one as well low heat storage and insufficient sound insulation result. The scarf stones with local concrete filling contribute to the simplification of the shell construction, However, they are wage-intensive and generally have to be plastered on both sides: they can therefore make no claim in terms of prefabricated components.

The main disadvantage of conventional prefabricated construction methods is the restriction to a few, standardized building complexes and floor plans for reasons of economy. The shell construction according to the invention is applicable to both standardized standard houses Can also be used on individually planned buildings without reducing profitability.

The invention has set itself the task of a large number of components and manufacturing processes, especially in residential construction, to save both to reduce the cutting time itself as well as the construction costs considerably.

This object is achieved according to the invention in that easy-to-use and to be transported, inherently stable components, locally in a few simple steps be put together. The elements already have the necessary thermal insulation to the content and obtained by the local filling of the enclosed cavities the required massiveness in terms of good sound insulation and heat storage, combined with the statically required strength or load-bearing capacity; from the The original assembly building is therefore a solid structure with all the advantages of durability and stability emerged. There is no need for internal and external plastering. All Installations related to electrification and sanitary facilities of the building can be preassembled on half-sided shells before the core filling and later poured in; Slots and recesses are therefore unnecessary.

The construction corresponds to all with correctly dimensioned core filling Relevant DIN standards and government regulations, so that there are special approval procedures unnecessary for special constructions.

The main feature of the invention are the half-shells in the form of large-format, Plate-shaped elements with any flat extension, with over the plate plane Perforated anchoring webs that extend out to cantilever and determine the wall thickness molded in the same material with predetermined distances. The production takes place in a single form, with special fittings, such as end parts on soffits and Cornices placed within this form or by cutting out from already prefabricated half-shells are obtained. The material used is preferably flame retardant adjusted polyurethane or another raw material with similar properties, poured into the mold or foamed or extruded. The use of extruded Polyurethane combines the advantages of a diffusible, but largely waterproof Cell structure with excellent thermal insulation properties and high strength properties, with or without reinforcement by fabric made of glass fibers or plastics.

The half-shells are generally storey high and arbitrarily wide.

The areal expansion is independent of the relatively light Weight limited only by the given transport options. The transport of bulky goods can be achieved through the use of collapsible molds and production can be avoided directly on the construction site. Of particular economic advantage is the absolute equality of the half-shells on both sides of a wall, as well as the Use of the same half-shells through multiple holes in the connecting webs for different wall thicknesses The half-shells are preferably used in room-sized elements pre-assembled on one side. In this state, the installation work for electrical and plumbing in a concealed arrangement, d. in. in the area of cavities the later core filling. Steel mesh can also be used as reinforcement The core filling is threaded onto the connecting webs of the elements and with wire loops attached to the free holes. All of these assembly processes make one too be pre-measured beforehand on 1 lying half-shells. The bars are asymmetrical arranged on the half-shells in such a way that the opposite side is reversed the Half-shells can be inserted into the composite by 180 without difficulty. the mechanical connection is made by inserting a retaining iron from above. The perforation of the connecting webs, possibly @. with hole reinforcement, is slightly larger than the diameter of the sticks and also widened upwards in a funnel shape, so that construction tolerances can be included. Wall ends or reveals as well Wall connections, corners and derken connections on false ceilings or cornices are can be produced therefrom with the same elements or parts. For sticking together of the elements is expediently the middle perforation of the preferably three-part Perforation used in the connecting webs. If the wall is chosen wider and the Perforation placed at a greater distance, the webs of a half-shell must be glued on additional spacers can be extended.

The function of these spacers is to facilitate the import the plug and is finished after the plug connection has been established. nns ceiling end piece in the area of the false ceiling or on the cornice is secured by the hook of the plug-in iron secured against tipping.

Before inserting the core filling, all joints are impervious to fluids to be filled or simply glued from the outside with strips of crepe paper. Thereafter the backfilling of the enclosed cavities can be carried out from the top of the storey will. In the case of solid core fillings, medium-grain concrete is preferred Liquefiers used as additives in the sliding or pumping process. In the case of non-load-bearing Inner walls can be made of slow-setting plaster, possibly plastic-coated, anhydrite or other water-soluble binders with fillers are used depending on economic efficiency will. In the case of a multi-storey design, the same procedure is repeated one on top of the other, the individual construction sections in the area of the web perforations by means of pins be connected in a sustainable manner. Reinforced concrete ceilings or load-bearing ceilings are used as false ceilings Trapez @ leche possible; as are all other ceiling systems available on the market.

In this construction, the individual building materials or elements different functions assigned to them, namely the thermal insulation of the half-shells as well as the function of the substrate for direct painting or wallpapering Strengths in the area of Bowls and sler bridges, limited to the absorption of the hydrostatic pressure of the core filling up to the statically stable Hardening of the core. The latter then takes over the stability of the building.

It is possible to equip the half-shells with less thermal insulation and as material e.g. B. glass fiber reinforced polyester resins or meth-acrylate resins with fillers made of quartz sand and quartz powder or other substances with similar properties to use. In this case it is necessary to have the core filling / was viable, however, to a certain extent also to be trained in warming, what can be achieved by pore formers in concrete. When using this construction in the case of interior walls, the thermal insulation and, above all, any tile coverings can be omitted, as the nature and optical effect of these materials ien z. B. in cakes and bathrooms such tile coverings fully replaced. The wall surface is here final and needs neither painting nor wallpaper.

The captivating simplicity and versatility of one and of the same half-shell element are in the 4 sheets of drawings with the figures 1 to @@ and are shown as exemplary embodiments of the invention in the following described in more detail.

FIG. 1 shows the horizontal section of part of the half-shell element mi @ the preferably flat facing shell 1 with the connecting webs 2 and preferably vertical and three-part perforation 5 Fig. 2 shows the horizontal section of the same half-shell element on both sides of a wall with the cavities enclosed by the elements 4 and the mechanical connection with plug 5 den? the horizontal section a finished wall made of half-shells with connecting webs with the Local massive core filling 6 4 shows the vertical section of the half-shell elements on both sides of a wall, with the asymmetrical bar arrangement 2, 2a and 2b for Facilitating the mirror-image assembly of the same element and the connecting iron connection 5 in the middle perforation of the connecting webs FIG. 5 shows a connection cutout from Fig. 4 with a widened wall cross-section through plug connection of the edge perforation of the left element with the middle perforation of the right element with the glued-in Bar extension 7 Fig. 6 is a view of an Ilalh shell seen from the inside of the wall with cut webs 2, the plug connections 5 and the reinforced reinforcement from structural steel fabric 8 Fig. 7 the horizontal section of a wall end with the hatched Wall termination la cut out vertically from the base element 1, with plug-in iron connection 5 in the webs 2 FIG. 8 shows the horizontal section of a lateral wall connection with hatched main wall with half-shell elements, webs and plug connections normal and manufactured without the use of additional parts Fig. 9 the vertical section a ceiling connection with cornice formation with the half-shells 1, the connecting webs 2, the iron 5, the core filling 6, the ring anchor reinforcement 9, the one from a Half-shell 1 horizontally cut ceiling end piece 1b with the iron bracket 5a anchored against tilting, the reinforced concrete ceiling 10, above the vapor barrier 11, the Thermal insulation 12, the roof skin 13, the gravel 14, the filling of the roof skin connection to the cornice 15, the glued-on cornice molding 16 Fig. 10 the llorizontalschnitt a wall corner with hatched wall connection, with half-shells, webs and connections manufactured without the use of additional parts.

Claims (12)

Claims 1. Half-shell prefabricated building elements with local core filling. characterized in that prefabricated half-shells with heat insulating Base plate and any surface extension molded over the plane of the plate connecting webs extending out or perpendicular thereto in predetermined Get distances, which in turn are horizontal or vertical or @n both Directions are punched once or several times, with plug connections across them Perforations to connect half-shell elements on both sides of a Wall, with local core filling through the half-shell elements and connecting webs cavities enclosed after assembly as a load-bearing and stable connection of the overall construction. 2. Half-shell prefabricated elements with local core filling according to claim 1, characterized by the use of leached, perforated connecting webs as reinforcement or stiffening ribs for the base plate of the half-shells. 3. Half-shell prefabricated components with local core filling according to claim 1 and 2 characterized in that the perforation of the web connections on the Insertion device facing the side a funnel-shaped or trumpet-shaped extension for easier introduction of the plug-in connection with tolerance recording and for ease of assembly attains. 4. Half-shell prefabricated components with local core filling according to claim 1 to 3, characterized by predetermined distances between the connecting webs and pins, with toler @ erender Einfadelungsmogl @ chke @@ of structural steel mesh mats with Loop fastening to free holes in the connecting webs as reinforcement of the Core filling. 5. Half-shell prefabricated elements with local core filling according to claim 1 to 4, characterized by the use of a vertical section of the half-shell prefabricated component as a fitting piece at the end of wall ends and soffits with connecting webs and Plug connections. 6. Half-shell prefabricated elements with local core filling according to claim 1 to 5, characterized by the use of a horizontal section of the Half-shell prefabricated construction element as a fitting piece in the conclusion of storey ceilings and on Gesim @ en. 7. Half-shell prefabricated elements with local core filling according to claim 1 to 6, characterized by the bending of the plug with the ability to fit two holes in the connecting webs for a tilt-free connection of the end piece according to claim 6 in storey ceilings and on cornices. 8. Half-shell prefabricated elements with local core filling according to claim l to 7, characterized by the asymmetrical arrangement of the connecting webs with Perforations in a predetermined shape so that the half-shell elements to both Sides of a wall fitted in mirror image without additional parts and plugged together can be. 9. Half-shell prefabricated components with local core filling according to claim 1 to 8, characterized by the arrangement of the connecting webs and holes in predetermined shape so that they are adjacent to wall corners and connections be arranged in such a way that rigid connections are made through the pins, which make the use of additional parts superfluous. 10. Half-shell prefabricated elements with local core filling according to claim 1 to 9, characterized in that the connecting webs from the upper wall termination Get a distance in which a ring anchor reinforcement below the ceiling can be accommodated, either with a solid concrete ceiling with potted or in the case of other ceiling systems such as the underlying wall, a core filling receives. 11. Half-shell prefabricated elements with local core filling according to claim 1 to 10, characterized by the angular piece of cornice made of the same material like the half-shells, with a bulge-shaped approach on the roof skin side for liquid-tight Connection of the roof cladding, with an upper slope and bevel on the wall side as Drip edge. 12. Half-shell prefabricated elements with local core filling according to claim 1 to 11, characterized by the reversal of function to such an extent that the half-shell elements are not designed to be heat-insulating and have final surfaces as a substitute for Paints and tiles, while the core filling, if required, in addition to the Load capacity also takes on the heat insulating function.