DE3614367A1 - Concrete slab with heat insulation for building construction and civil engineering - Google Patents

Abstract

The concrete slab with heat insulation for building construction and civil engineering, which is used preferably for erecting exterior walls, is configured as a composite slab (1) having an outer slab (6), an inner slab (3) with a rib reinforcement (4), and heat insulation (2) which is concreted on on the inner side and has a ventilation chamber. Owing to the configuration, according to the invention, of the insulating composite body according to Figures 5 and 6, said body is capable of transmitting the fresh-concrete loads of the top slab to the slab border, with the result that it is possible to produce the slabs one after the other without stoppage times. The anchoring of the wall slabs (1) onto the reinforcing structure takes place via steel plates (16), in accordance with Figures 10 and 11, by friction bonding. The dead-weight loads are channelled away via integrated supports (5). <IMAGE>

Description

Composite panels with an outer and inner concrete panel are known and a foam core for thermal insulation. Outer and inner plate are connected by stainless steel tension and compression anchors bound, which penetrate the foam core. Such composite panels are preferred for creating external facades.

The plates are manufactured separately with a time offset so that a hardened slab on the second concrete slab can be placed with the interposition of thermal insulation. To carry out this process, an increased material and labor costs necessary.

The invention has for its object a thermally insulated composite to develop concrete slab with a minimum wage and Material costs can be manufactured.

This object is achieved by the features in the license plate of claim 1 and claim 9 solved.

Appropriate embodiments of the invention are the subject of the sub Expectations.

In addition to the advantages that can be gathered from the task, it also stands out the composite panel according to the invention over the known panels of this type due to its light weight, simple and quick assembly, rear-ventilated outer panel, better thermal insulation, and the manufacturer development of the composite panel in successive operations without Relocate a single panel.

The invention is based on various in the drawing illustrated embodiments explained; it shows

Fig. 1 a cross section of the composite panel according to the invention,

Fig. 2 shows a partial longitudinal section along line II,

Fig. 3 is a partial cross section along line III-III,

Fig. 4 is a partial longitudinal section in the center of the plate along line II,

Fig. 5 is a cross section through the composite thermal insulation member according to claim 2 and 3

Fig. 6 is a plan view of the composite thermal insulation member according to claim 2 and 3,

Fig. 7 shows the cross section through the end plate along the line IV-IV,

Fig. 8 is a partial longitudinal section through the end plate taken along the line II,

Fig components. 9 is a partial longitudinal section through the end plate with the anchor,

Fig. 10 is a partial cross section through the plate end with an anchor plate,

Fig. 11 is a top view of the anchor plate at the plate end.

The same or similar in the various exemplary embodiments Liche components identified by the same reference numerals.

The composite panel ( 1 ) according to Fig. 1 has an outer panel ( 6 ), an inner panel ( 3 ), reinforcing ribs ( 4 ) on the inner plate made of steel concrete, as well as a thermal insulation ( 2 ) adjoining the inner panel and thermal insulation strips adjoining the ribs ( 8 ) off. The space between the thermal insulation ( 2 ) and the outer panel ( 6 ) is used for rear ventilation.

The outer plate ( 6 ) is in the middle of the plate according to Fig. 4 firmly over the wooden rib ( 18 ) in the longitudinal direction of the plate to the reinforced concrete rib ( 4 ), while all other supports ( 7 ) according to Figs. 2 and 3, which are arranged at regular intervals are, are displaceable in the longitudinal direction of the plate, so that thermal expansion does not create any constraining forces.

The dead weight load of the outer plate ( 6 ) is transferred to the integrated supports ( 5 ) according to FIG. 7 via tension anchors ( 21 ) at the end of the plate. Steel plates ( 16 ) arranged between the supports ( 5 ) and connected to the stiffening supports ( 23 ) anchor the wall ( 1 ) by means of a friction bond.

The wall plate ( 1 ) is produced by successively manufacturing the lower plate ( 6 ), placing the thermal insulation composite plate ( 2, 8, 9, 10 ) according to FIGS. 5 and 6 on the formwork cantilever and concreting the upper plate ( 3 ) becomes. The fresh concrete loads are transferred from the thermal insulation composite panel to the formwork edge. To reduce the deflection, pieces of foam that fill the air space between the plate ( 6 ) and insulation ( 2 ) can be placed on the fresh concrete of the plate ( 6 ).

Claims (9)

1. Concrete slab ( 1 ) with thermal insulation ( 2 ) for building and civil engineering, in particular for creating external walls, characterized by an inner plate ( 3 ) made of reinforced concrete, which is reinforced by horizontally running reinforced concrete ribs ( 4 ) that end at the plates open into a vertically extending support ( 5 ), and an outer plate ( 6 ) made of reinforced concrete, lightweight concrete or polymer-modified concrete with thermal insulation ( 2 ) adjoining the inner plate ( 3 ) with an air layer to the outer plate ( 6 ). The outer plate ( 6 ) is connected to the ribs via displaceably mounted support parts ( 7 ). The supports ( 5 ) located at the plate ends transfer the dead weight loads to the support ( 5 ) of the plate ( 1 ) below. 2. Thermal insulation according to claim 1, characterized in that foam strips ( 8 ) glued to the thermal insulation ( 2 ) form the formwork of the concrete slab ( 3 ) and ribs ( 4 ). 3. Thermal insulation according to claim 1 and 2, characterized in that hardboard strips ( 9 ) and underside wood slats ( 10 ) are glued so that the fresh concrete loads of the inner panel ( 3 ) and ribs ( 4 ) are transferred to the panel edge where the slats can be supported on the boundary formwork. 4. Support parts ( 7 ) according to claim 1, characterized in that between the concrete ribs ( 4 ) and the outer plate ( 6 ) veneer strips ( 14 ) are arranged at a constant distance, which is articulated with nails ( 12 ) with sheets ( 11 ) are connected. The sheets ( 11 ) are connected to the plate reinforcement ( 17 ) or beam reinforcement. To ensure the movability and as moisture protection, a soft PVC hose ( 13 ) envelops the supporting part ( 7 ); At the end of the hose ( 13 ) a hard fiber strip ( 15 ) prevents fresh concrete from penetrating. 5. Wooden ribs ( 18 ) in the middle of the plate between the rib ( 4 ) and outer plate ( 6 ), characterized in that the wood is sawtooth-like ( 19 ) milled out on the connecting sides and engages similarly in the concrete dowel. In addition, grooved nails ( 20 ) are used for the connection. The wooden ribs stabilize the outer plate ( 6 ) against the reinforced concrete ribs ( 4 ) in the longitudinal direction. 6. tie rod ( 21 ) according to claim 1, characterized in that they are inclined, in the support ( 4 ) and outer plate ( 6 ) are concreted. The tie rods ( 21 ) consist of resin-coated, galvanized ribbed steel. 7. tie rod ( 21 ) according to claim 1 and 6, characterized by synthetic resin-coated glass fiber mat. 8. tie rod ( 21 ) according to claim 1, 7 and 8, characterized by alkali-resistant glass fiber. 9. Process for the production of a concrete slab according to claims 1-8, characterized by the following process steps:

• a) Attach the connecting anchor ( 7 ) to the plate reinforcement of the plate ( 6 ).
• b) Concreting the lower concrete slab ( 6 ) in the lying state.
• c) Place the prefabricated composite insulation board ( 2, 8, 9, 10 ) over the wooden strips ( 10 ) on the boundary formwork.
• d) concreting the upper concrete slab.
• e) compacting the concrete by shaking.