WO2000017461A1

WO2000017461A1 - Formwork wall consisting of insulating material

Info

Publication number: WO2000017461A1
Application number: PCT/DE1999/002967
Authority: WO
Inventors: Burkhart Schurig
Original assignee: Burkhart Schurig
Priority date: 1998-09-17
Filing date: 1999-09-17
Publication date: 2000-03-30
Also published as: AU1767800A; DE19944765A1

Abstract

The invention relates to a dead formwork wall consisting of insulating material, for pouring concrete between levels, and to a method for producing the same. In order to control the formwork forces, the insulating material element is reinforced with a continuous profile (2) on the inner surface of the insulating material in such a way that there are no thermal bridges, and is pre-manufactured with fixing profiles (4), which are maintained at a distance. This light wall section for use between levels is logistically processed and erected separately. The heavy, dead inner forms (5) consisting of gypsum plaster boards are fixed to the level surfaces of the fixing profiles arranged in the grid on site. Recesses in the insulating material (6) and additional reinforcements permit variable static dimensioning.

Description

Formwork wall made of insulating material

description

The invention relates to a lost formwork wall for pouring concrete, consisting of a storey-high self-supporting and thermal bridge-free insulation board, which can absorb the formwork forces for a storey-high filling with in-situ concrete with a formwork attached to it at a distance, and methods for producing triple-shell walls. The factory-made formwork wall is very load-bearing and highly insulated outer walls suitable for energy-saving houses

Various jacketed concrete wall systems are known, which consist of small-sized stackable dam material elements and serve as a concrete formwork element for a three-shell wall. The dam material encloses the concrete on both sides

In other wall construction systems, different types of spacers made of different materials are used, which are glued in the factory between two formwork panels in the form of local knobs.The formwork panels can also consist of insulation panels.But both formwork halves always belong together at the factory.The system therefore has a high mass and is difficult to customize Adapt the requirements in the wall structure

The invention is based on the object of recommending a material-saving and easy-to-use highly insulated formwork wall of the type mentioned at the outset, with which solid walls which are free of thermal bridges and optimal in terms of building physics and with a variable degree of prefabrication can be created for all areas of use, even in self-construction, and with which low labor costs can be used on site an overall inexpensive construction can be realized

The invention achieves the object in claims 1 to 26

The invention is to be explained using three exemplary embodiments

Figure 1 shows a view and top view of a section of a storey-high formwork wall element. The width of the large-format or individual composite rigid foam dam panel made of EPS 20 (1) is 1200 mm or 2400 mm and the system center distance (a) is 300 mm on the dam panel T-shaped floor-to-ceiling steel sheet profiles as reinforcement (2), each with a width of 60 mm and the material thickness of 0.6 mm, glued evenly distributed.The hat-shaped retaining profiles (4), which are also floor-to-ceiling, are perforated on the side and are made of sheet steel The spacers (3 ) consist of chamfered round bars, which are joined and held by the punched holes in the hat profile. The resilient bow ends engage in two adjacent reinforcement profiles and thus keep the holding profile at a distance. The rigid holding profiles with the flat building board contact width of 50 mm ensure good load distribution and a flat and parallel screw or adhesive surface for the building boards to be assembled on site as internal formwork (5). During transport and in the warehouse, the holding profiles (4) can be placed between the Swing the dam reinforcement (2) The inner formwork (5) is not part of the factory-made formwork wall, but can also be prefabricated if necessary. The building boards can be fastened with sheet metal screws using the usual drywall technology. If less stable plasterboard panels are to be used as inner formwork, they are primarily used to glue the holding profiles At the shaded locations (6) the insulation is set 5 cm lower to form columns and supports in the future concrete wall. FIG. 2 shows a view and a top view of part of a formwork wall element with two profile variants of a combination profile. Both combination profiles are rigidly fixed in the slots of the EPS 20 insulation board with a thickness of 150 mm by means of a hardenable polyurethane casting compound. The slot width is 1.5 mm and the depth is approximately 75 mm. The bond depth of the fabric in the slot has a significant influence on the formwork forces that can be borne. In the illustration on the left, the holding profile section is made of wood (4a) and the glass fiber mesh fabric (3a) glued into it forms the "reinforcement profile and the spacer". The plastic casting compound and the glass fiber fabric are insignificant with regard to the weakening of the insulation effect. The liquid concrete The mesh profile can be penetrated well to improve the transverse distribution of the concrete The cut-out part of the profile has smaller and staggered punch-outs. The latter ensure only minimal heat exchange. The contact surface for the inner formwork is flat and unperforated oak clearances to the internal formwork. The combination profile creates a very rigid formwork wall.

Figure 3 shows the cross section of a formwork wall with internal formwork and without concrete grouting in two variants. In the illustration on the left, slots are formed in the foam polystyrene insulation board (1) at a grid spacing, into which floor-level continuous reinforcement material reinforcements (2a) made of sheet steel are glued approx. 70 mm deep. The undercut dam reinforcement with the depth-limiting fold is rigidly fixed in the undercut-free groove by means of plastic potting compound. Spacers (3) made of round steel can be moved between the dam reinforcement and the continuous holding profile (4) made of sheet steel and hooked into the cutouts in a positive manner. The inner formwork (5) is realized by horizontally or vertically inserted panel-like building boards, which are positively fixed in their position by the T-shaped holding profiles (4). The reinforcement profile shown on the right has already been incorporated in the foaming process in the manufacture of insulation boards. It is made of polystyrene.

Claims

claims

1. Formwork wall element of a three-shell wall system for storey-high concrete grouting, consisting of a penetration-free and storey-high, lost outer formwork made of dimensionally stable insulation material, several thermal bridge-free insulation reinforcements attached to it, local spacers and grid-like holding profiles for fastening the internal formwork, characterized by the fact that the formwork is attached to the interior formwork the surface of the outer formwork, which can be fogged from the inside, is rigidly connected on all sides and the holding profiles in the level of the inner formwork have flat contact surfaces for fastening the inner formwork, without penetrating the wall cross-section into the layer of the inner formwork, and the holding profiles and the insulation reinforcements are floor-to-ceiling or continuous Width of the wall element run continuously.

2. Formwork wall element according to claim 1, characterized in that the insulation reinforcements are glued into aligned slots or undercut-free grooves in the insulation.

3. Formwork wall element of a three-shell wall system for storey-high concrete grouting, consisting of a penetration-free and storey-high, lost outer formwork made of dimensionally stable insulation material, several thermal bridge-free insulation reinforcements attached to it, local spacers and grid-like holding profiles for fastening the internal formwork, characterized by the fact that the internal formwork is attached to the formwork the surface of the outer formwork, which can be joined from the inside, is rigidly glued into insulation slots on all sides and the holding profiles in the level of the inner formwork have flat contact surfaces for fastening the inner formwork, and the holding profiles and the reinforcement of the insulating material are continuous at floor level or in the width of the wall element.

4. Formwork wall element according to claim 1 or 3, characterized in that the holding profiles and insulation reinforcements run vertically in the wall.

5. Dammstoffreinforcement according to claim 2 or 3, characterized in that there is a positive limitation of the joining depth in the groove on the profile.

6. Dam reinforcement for fastening the spacers according to claim 2 or 3, characterized in that the part of the dam reinforcement glued inside the outer formwork has openings or undercuts in the joining direction.

7. Reinforcement material according to claim 6, characterized in that the part glued into the slot of the insulating material consists of expanded metal or of metal mesh or textile mesh.

8. Formwork wall element according to one of the preceding claims, characterized in that the spacers can be pivoted relative to the outer formwork in the vertical plane and the holding profiles are guided parallel to the outer formwork.

. Formwork wall element according to one of the preceding claims, characterized in that holding profiles and insulation reinforcements are arranged in different directions to one another.

10. Retaining profile or reinforcement according to one of the previous claims, characterized in that geometrical undercuts are realized in the concrete by the shape or openings in the material.

11. Formwork wall element according to claim 1 or 3, characterized in that the holding profile, spacer and reinforcement material consist of a combination profile prefabricated in the factory and large openings for concrete penetrations are available.

12. Combination profile according to claim 11, characterized in that all profile parts consist of the same homogeneous material.

13. Holding profile or combination profile according to one of the preceding claims, characterized in that the fastening locations of the spacers on the holding profile or the geometric shape of the combination profile are determined constructively such that the tensile forces caused by the form pressure of the concrete in the static system as a resultant approximately in the middle by planar contact surfaces of the holding profiles.

14. Spacer with fixation to a holding profile or a reinforcement according to one of the preceding claims, characterized in that the positive connection with the dam reinforcement or the holding profile is made possible by the resilient provision and is retained by an elastic design of the component. The spacer is clipped or hooked on.

15.Formwork wall system for pouring concrete, consisting of a penetration-free and storey-high, lost outer formwork made of dimensionally stable insulation material, several grid-like insulation and reinforcement reinforcements, local spacers and the inner formwork attached to it from the inside and with the same center distance, characterized in that the spacers consist of screws have a positive stop between the thread and shaft, which acts as a screw-in limitation and the screw shaft is guided through a hole in the inner formwork.

16. Screw according to claim 15, characterized in that a perforated disk guided over the thread produces a widened support on the positive stop.

17. Formwork wall system for pouring concrete, consisting of a penetration-free and storey-high, lost outer formwork made of dimensionally stable insulation material, several thermal bridge-free insulation reinforcements attached to it, spacers and the inner shell, characterized in that the dimensionally stable insulation material of the outer formwork has locally strip-like recesses or shoulders on the inside locally increase the concrete thickness. This creates columns or beams in the wall system.

18. Formwork wall element according to one of the preceding claims, characterized in that guide profiles are attached to the edge-delimiting inner side of the insulating outer formwork, which ensure correct positioning and positive connection with adjacent formwork wall elements.

19. Guide profile according to claim 18, characterized in that the guide profile fixed to the lower end of the wall element engages in a form-fitting manner in a plurality of reinforcing reinforcements running orthogonally thereto.

20.Procedure for the production of a formwork wall panel for concrete grouting, characterized in that narrow and undercut-free, aligned grooves are worked into a large-area and thermal bridge-free insulation board, in which the partially flat insulation reinforcement is inserted and rigidified in the groove by means of solidifying adhesive by gravity casting be locked.

21. A process for the production of three-shell solid walls according to one of claims 1, 3, 15 or 17, characterized in that the factory-made outer formwork is first made of thermal bridge-free insulation material, on which spacers and holding profiles for the inner formwork are already attached at the factory, and only then is the internal formwork installed on site.

22. The method for fastening the inner formwork according to claim 21, characterized in that the inner formwork is always locked as a panel with the width of the center distance of the holding profiles between and on the holding profiles.

23. A method for the production of three-shell solid walls according to one of claims 1, 3, 15 or 17, characterized in that the connection of the inner formwork with the holding profiles is carried out on site and is realized by screws or clamps or / and gluing.

24. A process for the production of a formwork wall for a three-shell wall system for concrete grouting, consisting of a penetration-free and storey-high, lost outer formwork made of rigid plastic foam and several heat-bridge-free insulation reinforcements attached to it for locking the spaced inner formwork, characterized in that the insulation reinforcements in the process of Production of the outer shell body foamed and thus rigidly attached.

25. Reinforcement reinforcement according to claim 24, characterized in that the reinforcements are penetrated by the hard foam, are arranged vertically in the wall and have positive locking means on the insulation surface for anchoring the spacers and do not protrude from the inner surface plane of the outer formwork.

26. Damage reinforcement according to claim 25, characterized in that the insulation reinforcements consist of the same plastic base material as the rigid foam.