RU2190523C1 - Method for manufacture of three-layered wall panel - Google Patents

Abstract

FIELD: manufacture of sandwich concrete and reinforced concrete. SUBSTANCE: method consists in successive placement of reinforcement rigging and concrete of the outer layer on a preheated bottom plate under the action of vibration. Then, a heat-insulating layer in the form of a core of expandable polystyrene plates framed by mineral wool elements around the outer and inner edges is installed on it, the reinforcement and concrete of the inner layer are placed on the heat- insulating layer under the action of vibration, the concrete of the inner layer is rubbed down manually. Subsequent heat-moisture treatment under the heat- insulating canopy, dismantling of the forms, turning-over to the vertical position and installation of a ready-made window block are accomplished. EFFECT: enhanced indices of power intensity. 3 cl, 3 dwg

Description

 The invention relates to the construction and manufacture of precast concrete and reinforced concrete and can be used in the manufacture of precast concrete and reinforced concrete.

 Known patent of the Russian Federation 2072412, class. E 04 C 2/26, 1997, which describes a method of manufacturing a three-layer wall panel by sequentially laying in the form of the outer structural layer of reinforced concrete, a heat-insulating layer of light concrete with monolithic flexible connections protruding from it, foaming light concrete, laying on the last structural inner layer of reinforced concrete.

 The disadvantages of this method of manufacturing three-layer wall panels are the lack of reliability of the anchoring of flexible bonds in lightweight porous concrete of the heat-insulating layer, which leads to a decrease in the shear strength of the three-layer wall panel during transportation, installation and operation.

 Closest in its technical essence to the proposed method for the manufacture of three-layer wall panels is known from the patent of the Russian Federation 2033504, class. E 04 С 2/26, 1993. a method of manufacturing a three-layer wall panel, which includes sequential laying of the outer structural layer with reinforced concrete and aperture openings in a boring tool, installing it, installing flexible joints and a heat-insulating layer, reinforcing concrete and structural inner layer, leveling and grouting its outer surface, heat and humidity treatment of the molded wall panel, at the end of which they are stripping, tilting in a vertical position and installing the finished window block in the opening.

 The disadvantages of this method are the high energy costs for heat and moisture treatment, insufficiently high quality of the front surfaces, the presence of cold bridges and the need for a heat and moisture treatment chamber and technological vehicles for moving forms.

The aim of the invention is to provide the possibility of forming a three-layer wall panels with high quality of the outer and inner surfaces without the presence of cold bridges, reducing the energy intensity of heat and moisture treatment through the use of heat generated during crystallization of cement, used as a mineral binder in concrete of the outer and inner structural layers and increasing removal of the finished product with ² m 1 of production space by eliminating the need to Thermo-chamber processing the second.

This goal is achieved by the fact that in the method of manufacturing a three-layer wall panel, which includes sequential laying of the outer structural layer in the rigging with the opening of reinforcement and concrete, installing it, installing flexible joints and a heat-insulating layer, reinforcement and concrete of the structural inner layer, leveling and grouting its outer surface , moisture and moisture treatment of the molded wall panel, at the end of which its stripping, tilting in a vertical position and installation of the finished of the horse block, before laying the reinforcement and concrete of the outer structural layer into the rigging, the pallet of the latter is heated by means of closed thermal registers placed under it to 30-45 ^o С, and the concrete of each structural layer is laid under vibration for 80-140 s with an oscillation amplitude of 0 , 3-1.8 mm, while the heat-moisture treatment is carried out continuously during the entire process of forming and holding the wall panel in the rigging, covered with a heat-insulating canopy to a set of stripping strength at a temperature Ur insulating medium under canopy, 90-94 ^o C, the inner and outer concrete structural layers is heated in the cooling process at a rate respectively of 7-12 and 3-10 ^o C / h for 2-8 hours.

 In addition, in the method of manufacturing a three-layer wall panel, the heat-insulating layer can be assembled in the form of a core of polystyrene foam boards with its edges surrounded by semi-rigid mineral-wool elements with synthetic surfaces protected by a synthetic film, and before the formwork is covered with a heat-insulating canopy, on the surface of the internal structural layer a heating shield should be installed.

 The essence of the claimed method is illustrated by drawings, where figure 1 shows a stand for the manufacture of a three-layer wall panel; figure 2 - three-layer wall panel in section; figure 3 is a diagram of the growth of concrete strength at the stated modes of heat and moisture treatment.

 The claimed method of manufacturing a three-layer wall panel is as follows.

On the pallet 1 side rigs, heated with the help of heat registers 2 (for example, steam) placed under it to 30-45 ^o С, fittings are mounted on which then under vibration for 80-140 s with an oscillation frequency of 0.3-1.8 mm the concrete of the outer structural layer is laid 3. For vibration effects on the concrete mixture, mounted vibrators, vibration nozzles or depth vibrators can be used.

 Then, a heat-insulating layer with flexible connections is installed 4. The heat-insulating layer can be formed as a core from polystyrene foam boards 5 bordered on the outer and inner perimeters by semi-rigid mineral-wool elements 6, the outer surface is protected by a synthetic film 7. This embodiment of the heat-insulating layer makes it possible to produce a three-layer wall panel with increased thermal performance without cold bridges due to the deformation of semi-rigid mineral wool elements 6, forming dense and strong joints between three-layer wall panels in the process of installing them on each other during the installation of building walls, and the waterproofing of the joints is provided by the synthetic film 7 protecting the outer surfaces of the semi-rigid myralous elements 6.

 After installing a heat-insulating layer, reinforcement is installed on it, onto which concrete is then laid under the vibration for a period of 80-140 s with a vibration frequency of 0.3-1.8 mm of the inner structural layer 8, and then the leveling and grouting of the outer surface of the inner structural layer is done manually 8. The heating of the pallet 1 by thermal registers 2 is carried out during the entire process of forming a three-layer wall panel.

As the heat carrier, hot steam (120-140 ^o C) can be used, which is fed into closed registers 2 located below the pallet 1 of the toolkit at the floor level or deepened by at least 30 cm. Around the perimeter is a toolkit with steam registers 2 are not deepened; they are framed below with aprons to avoid heat loss.

 The outer structural layer 3 and the inner structural layer 8 are concreted using a paver 9. The molded three-layer wall panel is kept on the pallet 1 of the rigging until the stripping strength is set, while the rigging is covered with a heat-insulating canopy 10, for example, from a polymer material, under which the greenhouse effect is created - heat and moisture are retained, and the concrete hardening process proceeds along a controlled isotherm. Control is carried out in the body of concrete layers and under the canopy.

The temperature of the environment under the canopy 10 is maintained equal to 90-94 ^o C. This solution allows you to use the heat generated during exothermy of cement, which is 30-40% of the total flow in the heat balance. Therefore, a soft heat-moisture treatment mode is created, in which, during the exposure process, carried out for 2-8 hours, the concrete of the outer structural layer 3 is heated at a speed of 7-12 ^o C / h, and the concrete of the inner structural layer 8 is heated at a speed of 3-10 ^o C / h

Under these conditions, the temperature under the canopy 10 reaches 90-94 ^o C, the hardening process of the outer structural layer 3 occurs at a maximum temperature of 70-75 ^o C, and the inner structural layer 8 at 45-60 ^o C.

 Due to the mild heat and humidity treatment, the lower surface of the three-layer wall panel (the outer side of the building wall) is glossy with acceptable small pores.

 Due to the soft heat and humidity treatment, the lower surface of the three-layer wall panel (the outer surface of the building wall) is glossy with acceptable fine pores having a maximum diameter of 0.8-1.0 mm, and the upper surface (inner surface of the building wall) after leveling and grouting manually It turns out extremely smooth without pores and shrinkage cracks.

As can be seen from the diagram of the increase in concrete strength depending on the temperature and time of heat and moisture treatment, the concrete strength R _φ in a day reaches 55-70% in the warm period and 80-90% in the winter period with the use of a heat-insulating canopy 10 and after 2-3 days without using a heat-insulating canopy 10.

 To accelerate the hardening process, depending on the type of cement and concrete strength of the structural layers, especially the inner structural layer 8, a heating shield 11, for example, with electric heating, can be installed on its surface before covering the side rig with a pallet 1 with heat-insulating canopy 10.

 After the end of the moisture and moisture treatment of the three-layer wall panel, it is dismantled, tilted to a vertical position and installation of the finished window block in the opening 12.

The claimed method of manufacturing a three-layer wall panel allows you to get it with smooth outer and inner surfaces, with improved thermal performance. Due to the lack of cold bridges in them, and also due to the selection of optimal heat and humidity treatment modes, reduce the energy intensity of the process and increase the removal of finished products from 1 m ^{2 of} production areas due to the absence of the need for a heat and moisture treatment chamber.

Claims (3)

1. A method of manufacturing a three-layer wall panel, which includes sequential laying of the outer structural layer with reinforcing reinforcement and concrete in the receiver tool, installing flexible joints and a heat insulating layer, reinforcing concrete and structural inner layer, leveling and grouting its outer surface, heat and moisture treatment of the molded wall panel, according to the end of which is its dismantling, tilting in a vertical position and installation in the opening of the finished window unit, characterized in that before laying minutes board equipment in reinforcement and concrete outer structural layer is heated by the last pallet placed underneath closed heat registers to 30-45 ^o C and stacking concrete each structural layer produced by a vibration within 80-140 with a vibration amplitude of 0.3-1, 8 mm, while the heat-moisture treatment is carried out continuously throughout the entire process of forming and holding the wall panel in the rigging covered with a heat-insulating canopy, until the stripping strength is set at a temperature of the medium under the heat-insulating conductive canopy 90-94 ^o C, the inner and outer concrete structural layers is heated during exposure at a rate respectively of 7-12 and 3-10 deg. / h for 2-8 hours.  2. The method according to claim 1, characterized in that the insulating layer is collected in the form of a core of polystyrene foam boards bordered on the outer and inner perimeters by semi-rigid mineral wool elements with outer surfaces protected by a synthetic film.  3. The method according to p. 1 or 2, characterized in that before the shelter is covered with a heat insulating canopy, a heating shield is installed on the surface of the inner structural layer.

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