RU2166591C2 - Facing of building walls - Google Patents

Abstract

FIELD: construction engineering; erection of heat-resistant buildings made of small-size structural units. SUBSTANCE: facing of building walls has alternate rows of main and dressing facing slabs. The latter are made of protective and heat-insulating members permanently joined during their manufacture so that heat-insulating member in each dressing slab occupies one part of internal space of protective member; mentioned part abuts against external butt-end edge of dressing facing slab; other part is monolithic structure; facing center of gravity is in monolithic part of protective members of dressing slabs. Thickness of facing dressing slabs equals that of main wall laying. EFFECT: improved heat insulation of building. 9 cl, 3 dwg

Description

 The invention relates to the field of construction and can be used in the construction of heat-resistant buildings from small-sized building elements, such as stones.

 Known cladding of external walls for heated buildings, including cladding tiles with fasteners and a layer of effective insulation, filling the gap between the wall and cladding tiles (patent of the Russian Federation N 2116410, class IPC 6 E 04 B 1/78, publ. 27.07.98, Bull. N 21).

 The disadvantage of this method is the need for fasteners that require corrosion protection, as well as the complexity of fastening and the manufacture of a heat-insulating layer.

 Known as the closest analogue is the cladding of building walls with concrete slabs (Tsyurupa A.L., Neelov V.A. Illustrated manual for the preparation of masons.- M .: Stroyizdat, 1984, pp. 101-102, Fig. 229). The cladding contains alternating rows of main and dressing concrete cladding tiles fastened with mortar. In this case, the facing plates are bandaged with masonry in dressing rows, located after each row of the facing along the height of the wall.

 This cladding is simple, reliable, since it does not require additional fasteners, however, when it is used, the thermal protection of buildings decreases, due to the high thermal conductivity of concrete slabs.

 The invention is aimed at solving the problem of increasing the heat resistance of buildings by improving the heat-insulating properties of the cladding installed without fasteners.

 The essence of the invention lies in the fact that in the wall cladding of buildings containing alternating rows of main and dressing cladding panels, it is proposed that the cladding plates be made of protective and heat-insulating elements connected inextricably during their manufacture so that in each of the dressing cladding panels the heat-insulating element occupies one part of the inner area of the protective element adjacent to the outer end face of the dressing cladding plate, while the other part of the protective element is made m onolithic, while the center of gravity of the cladding is located in the monolithic part of the protective elements of the dressing cladding plates.

 The thickness of dressing cladding plates may be equal to the thickness of the stone of the main masonry wall.

The heat-insulating element of the dressing cladding plates can be located in the inner region of the protective element so that all its edges, except the lower one, are connected to the corresponding surfaces of the inner region of the protective element, while the edges of the heat-insulating element are made in the form of a trapezoid with an angle of inclination of 70-80 ^o , so that the larger side of the trapezoid is facing inside the protective element.

 The heat-insulating element of the dressings can go deeper into the masonry wall no more than 1/3 of the length of the stone.

The heat-insulating and protective elements of the main plate can be arranged in layers and the volume of the heat-insulating element is 70-90% of the volume of the main plate, while the heat-insulating element has a perimeter selection of angular edges with a bevel inwardly at an angle of 70-80 ^o to anchor it in the protective element, moreover, the depth and width of the sample are equal to the thickness of the protective element, comprising 10-30 mm

 The protective elements of the facing plates can be made of polymer-cement mortar in the following ratio of components taken in parts by weight: Portland cement 100; sand 100-300; synthetic latex 6-30; stabilizer 3-15; filler 20-50; water is the rest.

 As a filler, one or several components from the series can be used, including expanded clay dust, asbestos-cement waste, crushed stone crushing waste. Albitofir rock crushing bends can be used as crushed stone crushing waste.

 Brown coal ash and / or ground wood can also be used as a filler, while the polymer-cement solution additionally contains a hardening activator in the form of a chlorine-containing additive.

 In the present invention, the implementation of the cladding plates of protective and heat-insulating elements connected inextricably during their manufacture, allows to increase the heat-insulating properties of the cladding, and therefore the heat resistance of buildings.

 The location of the heat-insulating element of the dressing plate in that part of the inner area of the protective element that is adjacent to the outer end face of the dressing cladding plate, and the rest of the protective element is monolithic so that the center of gravity of the cladding is in the monolithic part of the protective elements of the dressing claddings, allows to increase the thermal insulation properties in places of dressing without deterioration of the strength properties of the lining.

 The design of the dressing plate so that its thickness is equal to the thickness of the stone of the main masonry of the wall, helps to simplify the facing work and allows facing in the process of laying the walls of buildings.

 The location of the heat-insulating element of the dressing cladding plate in the inner region of the protective element in such a way that all its edges except the bottom are connected to the corresponding surfaces of the inner region of the protective element, simplifies the manufacturing process of the dressing plate.

The edges of the heat-insulating element of the dressing cladding plate in the form of a trapezoid with an angle of inclination of 70-80 ^o , so that the greater side of the trapezoid is turned inside the protective element, allows to increase the strength of the lining by increasing the strength of the connection of the heat-insulating element with the protective element.

 The implementation of the heat-insulating element of dressing cladding panels so that it can go deeper into the masonry wall no more than 1/3 of the length of the stone, helps to increase the reliability and strength of the cladding.

 The implementation of the heat-insulating element of the main facing plates so that the heat-insulating and protective elements are arranged in layers, and the volume of the heat-insulating element is 70-90% of the volume of the main plate and provides an increase in thermal insulation properties over the entire surface of the facing plate.

The implementation of the insulating element of the main cladding panels so that it has a perimeter of a selection of angular edges with a bevel inward at an angle of 70-80 ^o to anchor it in the protective element, and the depth and width of the sample are equal to the thickness of the protective element, component 10-30 mm, allows you to increase lining strength by increasing the strength of the connection of the insulating element with the protective element.

 Use for the manufacture of protective elements for facing plates of polymer-cement mortar in the following ratio of components taken in parts by weight: Portland cement 100; sand 100-300; synthetic latex 6-30; stabilizer 3-15; filler 20-50; water - the rest - allows to increase the strength and reliability of the connection of the protective element with the heat-insulating element in the process of manufacturing of facing plates.

 The possibility of using one or several components from the series as filler, including expanded clay dust, asbestos-cement waste, crushed stone crushing waste, as well as brown coal ash and / or ground wood, in the latter case with the addition of a hardening activator in the form of a chlorine-containing additive, expands the range of components, used as fillers, and allows you to increase the manufacturability of the process of manufacturing tiles.

 The use of rock crushing wastes as rock crushing waste albitofir also expands the range of components used as fillers.

 In FIG. Figure 1 shows a fragment of the wall cladding of buildings (sectional view). In FIG. 2 shows the main facing plate (sectional view). In FIG. 3 shows the dressing facing plate (sectional view).

 The wall cladding of buildings contains alternating rows of main cladding plates 1 and dressing cladding plates 2, which are attached to the stones 3 of the main masonry using masonry mortar 4. The thickness of the dressing cladding plates 2 is equal to the thickness of the stone 3 of the main masonry wall.

The main cladding plate 1 contains a protective element 5 and a heat-insulating element 6, connected inextricably during their manufacture. The heat-insulating element 6 and the protective element 5 are arranged in layers, while the volume of the element 6 is 70-90% of the volume of the main plate 1. The heat-insulating element 6 has a selection of the angular edges along the perimeter with an inward inclination at an angle of 70-80 ^o to anchor the protective element in it 5, the depth h and the width b of the sample equal to the thickness a of the protective element 5, comprising 10-30 mm

The dressing cladding plate 2 contains a heat-insulating element 7, which occupies one part of the inner region of the protective element 8, adjacent to the outer end face of the dressing cladding plate 2, while the other part of the protective element 8 is made monolithic. The ratio of the length l _{1 of the} insulating element 7 to the length l _{2 of the} monolithic part of the protective element 8 is, for example, 0.3. All faces of the heat-insulating element 7, except for the lower one, are connected to the corresponding surfaces of the inner region of the protective element 8. The edges of the heat-insulating element 7 are made in the form of a trapezoid with an angle of inclination of 70-80 ^° so that the greater side of the trapezoid is turned inside the protective element 8. The center of gravity of the cladding is in the monolithic part of the protective elements 8 dressing cladding plates 2. The heat-insulating element 7 dressing plates 2 goes into the depths of the wall masonry no more than 1/3 of the length l of the stone 3.

 The protective element 5 of the main facing tile 1 and the protective element 8 of the dressing facing tile 2 can be made of a polymer-cement mortar, including, for example, the following components: Portland cement grade M400, synthetic latex grade SKS-65GP or DMMA-65PG, water glass, sand, expanded clay dust and crushed stone crushing waste. To increase the strength of the lining, the protective element 5 of the main facing tile 1 can be reinforced with a mesh (not shown in the figures). The heat-insulating element 6 of the main plate 1 and the heat-insulating element 7 of the dressing plate 2 can be made, for example, of expanded polystyrene. The heat-insulating elements 6, 7 can be permanently connected with the corresponding protective elements 5, 8 during the manufacture of facing plates 1, 2, for example by molding them.

 The dimensions and shape of the facing plates depend both on the type of the main masonry of the walls of the buildings, and on the requirements for their thermal resistance. So, for example, for brick walls, the dimensions of the facing plates 1 and dressings 2 are selected in multiples of the dimensions of the brick. The thickness of the heat-insulating elements 6, 7 is calculated according to the standard method, based on the requirements for the heat-insulating properties of the walls of buildings.

 Thus, the proposed cladding allows to increase the heat resistance of buildings from small-sized building elements such as bricks, stones, etc., by increasing the heat-insulating properties not only in the locations of the main cladding plates, but also in the dressing places. At the same time, fastening the cladding with a mortar without using special fasteners allows facing work in the process of laying walls of buildings and thereby reduce both time and material costs for facing work.

Claims (8)

 1. Wall cladding of buildings, containing alternating rows of main and dressing cladding panels, characterized in that the cladding panels are made of protective and heat-insulating elements connected inextricably during their manufacture so that in each of the dressing cladding panels the heat-insulating element occupies one part of the inner area a protective element adjacent to the outer end face of the dressing cladding plate, while the other part of the protective element is made monolithic, while the center of gravity litsovki is located in the monolithic part of the protective elements of dressing cladding plates.  2. The wall cladding of buildings according to claim 1, characterized in that the thickness of the dressing cladding plates is equal to the thickness of the stone of the main wall masonry. 3. Wall cladding of buildings according to any one of claims 1 to 3, characterized in that the heat-insulating element of the dressing cladding plate is located in the inner region of the protective element so that all its edges except the lower one are connected to the corresponding surfaces of the inner region of the protective element, while the edges the heat-insulating element is made in the form of a trapezoid with an angle of inclination of 70 - 80 ^o so that the greater side of the trapezoid is turned inside the protective element.  4. The wall cladding of buildings according to any one of claims 1 to 4, characterized in that the heat-insulating element of the dressing plates extends into the depths of the wall masonry no more than 1/3 of the length of the stone. 5. The wall cladding of buildings according to claim 1, characterized in that the heat-insulating and protective elements of the main plate are located in layers and the volume of the heat-insulating element is 70 - 90% of the volume of the main plate, while the heat-insulating element has a selection of angular edges along the perimeter with a bevel inside under angle of 70 - 80 ^o to anchor it in the protective element, and the depth and width of the sample is equal to the thickness of the protective element, component 10 - 30 mm 6. The wall cladding of buildings according to any one of claims 1 to 5, characterized in that the protective elements of the tiles are made of polymer-cement mortar in the following ratio of components, parts by weight:
Portland cement - 100
Sand - 100 - 300
Synthetic latex - 6 - 30
Stabilizer - 3 - 15
Filler - 20 - 50
Water - Else
7. The wall cladding of buildings according to claim 6, characterized in that as a filler for the polymer-cement mortar, one or more components from a series including expanded clay dust, asbestos-cement waste, crushed stone crushing waste are used.  8. The wall cladding of buildings according to claim 7, characterized in that albitofire rock crushing waste is used as crushed stone crushing waste.  9. The wall cladding of buildings according to claim 6, characterized in that brown coal ash and / or ground wood is used as a filler for the polymer-cement mortar, while the polymer-cement mortar additionally contains a hardening activator in the form of a chlorine-containing additive.

Images