LV11349B - Building method of external wall - Google Patents

Abstract

The application field of this invention is construction engineering. Its object is an outside wall construction technique, according to which the wall bearing material - concrete or reinforced concrete - is filled into permanent moulds, the outer surface of which is made from a thermo-insulating layer, while the inner surface is made of a hard finishing layer. The bearing material layers are placed on the inner surface of the outside wall. The thermo-insulating layers from the outside are covered with a facade finishing layer reinforced with anchors, the inner tips of which are installed into the bearing material layer. The bearing material layer is made in the form of either flat plates or ribbed plates with pilasters and racks installed into the thermo-insulating layer. It can also be made in the form of flat lattice with a rectangular or triangular net structure.

Description

Exterior wall construction method

The area of use of the AizsarqSjam3 site is the construction of residential, heated industrial, agricultural and public buildings.

The object to be protected is the method of building insulated external walls.

Methods of sealing heat-insulated exterior walls are known, in which the load-bearing material of the external wall, concrete or reinforced concrete, is poured between two layers of foam of the heat-insulating material. As the concrete hardens, these foam molds remain in the wall and serve as thermal insulation of the building (1,2,3). The walls are then covered with a protective layer of plaster, finish brick, or panel material, both inside and outside the foam.

These known techniques have several common disadvantages:

(1) In all known ways, load-bearing material is poured into the middle of the wall symmetrically against the median plane of the wall. However, due to the eccentric loads of the slabs, the actual loading of the exterior walls is always asymmetric with respect to the median planes of the wall, and therefore also in the load-bearing material is not uniform. This circumstance does not allow for stress distribution in the wall but is with trapezoidal wall-bearing material.

eg concrete, full use of load-bearing potential.

2) Thermal insulation material, on the other hand, works better in the cold area of the wall, outside it. It is not useful to use it indoors, as condensation of the indoor vapor, its loss of heat resistance due to humidity, and even damage can occur.

3) The labor-intensive and costly qan interior, qan exterior finishing, mainly in the form of wet process plastering, is still envisaged in all known techniques. It is difficult to apply on ordinary thermal insulation materials (foam, mineral wool) and requires additional expensive measures.

The purpose of the present invention is therefore to achieve a more rational placement of load-bearing materials in the wall and to provide better working conditions for the heat insulating material, a better heat flow regime, and to eliminate steam condensation, lower material costs and technology for exterior walls, and significantly and exterior finishing work.

This goal is achieved by the following method of external wall construction (sk.fiq. 1,2 and 3);

The waterproofing substrate or surface of the exterior wall shall be installed and the outside shall be vertically reinforced with a heat-insulating layer (1) and a solid finishing layer (2) or its backing layer inside. This may also include the installation of an external protective layer on the thermal insulation layer (3). In this case, special anchors (4) are passed through the facade finishing layer and the thermal insulation layer through the facade finishing holders. Between the thermal insulation layer and the interior finishing layer is left a sprauqu (5), the width of which corresponds to the designed thickness of the carrier material layer. This gap can be either flat (fig.l) or qan with vertical and horizontal grooves (fiq.2) created in the insulation material. This span may also be qan continuous, qan also containing vertical, horizontal, or oblique channels (fiq.3). In order to keep the gaps' qeometry unchanged during concreting, stock-type, non-structural and reusable fasteners, such as arrows, are used to fix them. They can also be used to fix reinforcement, such a layered wall molded special mold can be pre-fabricated outside the building site, eg in factory conditions; it would improve the quality of work, increase productivity, and lower the cost of labor.

If the adhesion of the concrete to the interior finishing material is not sufficient, the anchors (6) are also inserted in the gap between the thermal insulation layer (1) and the interior finishing (2) to secure it.

If the interior finish is porous, a film of water and vapor barrier material is placed between it and the concrete to be filled to prevent water absorption.

If necessary, according to the design, the strings shall be inserted and fixed in the gap of such a mold.

Subsequently, this carrier (5) holds and seals the carrier material and cures it. In this way, either a vertical flat plate (Fig. 1) or a ribbed plate with pilasters and shelves (Fig. 2) or a rectangular (Fig. 3) or triangular structure grid are formed from the carrier material in this mold.

After the necessary hardening of the load-bearing material, the fixtures and fixings of the equipment are removed, and the horizontal surface of the concrete wall layer thus reinforces the upper layers of heat insulation and finishing materials, preferably in the form of pre-assembled blocks, inserts therein allows the carrier material to solidify. When filled with sprauqu, it forms a load-bearing part of the wall in the form of a flat plate, ribbed (with pilasters), or grid. Afterwards, the described moldings are repeated in the following, and the cycle described is repeated until the required wall height is reached.

In this way, constructive solutions for supporting the flooring can be envisaged when constructing the wall in the load-bearing layer. For beams they can be special sockets, qan also anchors, for slabs they can be horizontal qropes, or shelves for supporting qalu of slabs, with or without anchors.

£> The size of the special, concreted and wall-molded blocks of leather can be customized for each building project.

boards are installed in the top row, either universal or in multi-project or group of projects. They can be made in the form of blocks or panels, both horizontal and vertical (including the whole floor).

Compared to its counterparts (1,2,3), the practical application of a pre-wall technology in construction will allow better use of the most expensive components of the wall - the structural potential of the load-bearing material - either by increasing its load-bearing capacity or reducing its consumption. This technique will also allow the volume of the wall to accommodate a much more realistic insulation material and functionally position it in the cold area of the wall.

Comparing the technique allows the cost, the same thermal resistance of the front and its wall masonry is a technique, using traditional technology, to reduce the thickness of the outer wall over time by significantly increasing

For example, to obtain a wall heat of 5.0 m2 / WK (Danish construction standard), the aerated concrete block must have a thickness of 0.8-0.9 m, but the front used for thermal insulation with polystyrene foam allows the same result at a wall thickness of 25- 30 cm.

In addition, the inclusion of not only heat-insulating materials but also interior and exterior materials in the construction of pre-insulated molds eliminates the need for special finishing work, which is often a wet and expensive process, and can do without the process; using wallpaper or painting on the inside surface in front.

Information Used 1. AAB Building System. Innovative Concrete Form Technology. Prospectus of the Canadian company AAB, 1994. Business address - 840 Divission Street, Coburg, Ontario, Κ 9A 4J9, Canada.

2. Termotech Byggsystem. Prospectus of Swedish company Termotech Byggsystem HB, 1993. Company address - Artilerigatan 25, 41503 Goteborg, Sverige.

3. Sismo Building Systems. Prospectus for Belgian company SISMO 1992. Company address: SISMO Drapstraat 1, B-92 88 Laarne Kalken, Belgie.

Claims (5)

Formula of the Invention 1. A method of constructing exterior walls, comprising installing molds made of heat-insulating material and remaining in the wall structure and filling the load-bearing material, concrete or reinforced concrete, by placing the wall-bearing material on the inner surface of the outer wall between the heat-insulating layer. the outer surface, and the solid interior finishing layer or base layer serving as the inner surface of the molds. 2. The method of constructing exterior walls according to claim 1, characterized in that before or after filling of the load-bearing material, the thermal insulation layer is covered from the outside with a facade finishing layer and fixed with anchors whose inner ends extend into the load-bearing material layer. 3. A method of constructing an exterior wall as claimed in claim 1 or 2, characterized in that the layer of the carrier material is formed in the form of a vertical plate. 4. The method of constructing an exterior wall according to claim 1 or 2, characterized in that the layer of supporting material is formed in the form of a vertical ribbed plate with pilasters and shelves guided in the insulation layer. 5. A method of constructing an outer wall according to claim 1 or 2, characterized in that the layer of supporting material is formed in the form of a flat grid with a rectangular or triangular mesh structure.