RU48554U1 - MULTILAYERED OUTDOOR WALL - Google Patents

Abstract

The utility model relates to construction and can be used in the construction of walls of various multi-story buildings and structures.

The multilayer outer wall contains the outer facing layer supported by the floor-by-floor slab, the inner layer and the heat-insulating layer made of monolithic foam concrete placed between them, as well as the means for transferring the load on the floor slabs set in a predetermined manner, while the outer facing layer is made of brickwork alternating with a given step rows of bricks laid with a spoon and rows of bricks laid with a poke. The alternation step is four or five rows of bricks laid with a spoon on one row of bricks laid with a poke.

The load transfer means is made in the form of a support element rigidly connected with a predetermined floor slab and a facing layer, and the inner layer, at least partially, can be made of block foam.

The average density of foam concrete is 400-600 kg / m ³ .

A useful model solves the problem of creating the design of a multilayer monolithic wall with an increased level of heat-shielding qualities with technological simplicity and cost-effectiveness of its construction.

Description

The utility model relates to construction and can be used in the construction of walls of various multi-story buildings and structures, in particular monolithic housing construction.

Currently, in the practice of construction, the implementation of multilayer exterior walls has become widespread.

It is known from patent RU 2243336 (publ. 2004.12.27) a three-layer outer wall containing an outer facing layer, an inner supporting layer and a middle heat-insulating layer made of polyurethane foam or other similar material, to ensure a stable position of which reinforcing rods with protrusions pass inside the heat-insulating layer on their outer surface along their length, some ends of which are fixed in the inner supporting layer, and others in the outer layer. However, the known wall has a number of disadvantages, consisting in a large number of used component parts, assemblies, materials, which in turn requires considerable labor and assembly time.

It is known from patent RU 2215097 (publ. 2003.10.27) a multilayer monolithic wall containing the outer and inner walls of fixed formwork, which can be made of plates, bricks, blocks or similar piece elements, between which a layer of aggregate made of polystyrene concrete is placed, while in the layer a filler with a gap relative to the outer wall of the fixed formwork is additionally equipped with a frame made of metal profiles, which is attached to the inner wall of the fixed formwork and connected to the outer wall of the fixed formwork soup flexible links, wherein the size of the gap between the frame of metal profiles and the outer wall of the permanent formwork is 0.2-0.5 of the thickness of the filler layer. The erection of such a wall is labor intensive, as well as high cost due to the use of expensive materials.

It is known from patent RU 2105109 (publ. 1998.02.20) a three-layer wall with a self-supporting stone cladding containing a main supporting wall with pilasters, a layer of insulation and a facing layer made of spoon rows of bricks and double butt rows reinforced with flat welded frames and connected to the main bearing wall with steel anchors. This wall is characterized by its heterogeneity, different coefficients of thermal resistance, which reduces the quality and thermal characteristics of the wall.

The closest in design features is the exterior three-layer wall of a multi-storey building, known from RF patent No. 2187606 (publ. 2002.08.20), based on floor slabs. The wall is made with an inner layer, for example, of cellular concrete, and an outer lining, for example, of brick, between which there is a layer of effective insulation. The outer and inner layers are interconnected by bonds. The cantilevered protrusions at the ends of the floor slabs are trimmed to the thickness of the outer lining, and the ends of the protrusions protrude outward. The protrusion of the end face of the cantilevered protrusion is carried out by a layer of decorative cladding, which can sink over the plane of the facade, coincide with it or protrude from its plane.

A significant drawback of the known wall is the presence of a sufficiently large contact area of the floor slab with the outside air, which necessitates the application of external protective layers, which, together with the use of rather expensive effective heat insulation materials and the need for a ventilated air gap, necessitates high labor costs and the cost of construction and repair work.

The utility model is based on the task of creating such a construction of a multilayer monolithic wall, which allows to increase the level of heat-shielding qualities and strength with the technological simplicity and cost-effectiveness of its construction, as well as to improve operational characteristics by maintaining the geometric stability of thermal insulation under conditions of variable mechanical and temperature-humidity effects.

The problem is solved in that in a multilayer wall containing floor-mounted around the perimeter of the building on the floor slab and interconnected, at least indirectly, the outer facing layer, the inner layer and the heat-insulating layer placed between them, while the outer facing and inner layers, at least partially made of small-sized building materials, with the outer facing layer made of masonry, new is that the insulating layer is made of monolithic foam EtOH and the outer cladding layer is formed at a predetermined pitch in alternating rows of bricks stacked spoons, and the rows of bricks laid poking. At the same time, the wall contains means arranged in a predetermined manner for transferring the load from the facing and heat-insulating layers to the floor slabs.

It is advisable in the front facing layer to alternate the rows of bricks laid with a spoon and the rows of bricks laid with a poke, to perform through four or five rows of brickwork.

It is advisable, based on the calculation of thermal characteristics, to choose the density of foam concrete in the range of 400-600 kg / m ³ .

It is advisable to reduce the cost, increase the heat-shielding properties and ensure reliable permanent connection of the enclosing layers with the insulating layer directly on their contact surfaces, to use foam concrete blocks as the material of the inner layer. Preferably, the inner and thermal insulation layers are made of foam concrete of the same density.

Variants of the external wall solutions are possible: either with the floor-mounted transfer of the load from the external walls (both from the cladding layer and the heat-insulating layer) to the floor slabs through the support element, or with the floor-mounted transfer of the load from the heat-insulating layer to the floor slabs and the load transfer from the cladding layer through supporting element on floor slabs over several floors. It is possible to place means for transferring the load every two floors or at the level of the third, fifth and ninth floors.

Advantageously, the means for transferring the load is carried out in the form of a rigidly connected to a given floor slab and a facing layer

a supporting element, for example, in the form of a steel table recessed into the masonry, acting as a temperature seam for perceiving the thermal expansion of the brickwork and being an unloading element during the period of facing.

Applying a monolithic material for floors, it is possible to reduce the load on the supporting structures and obtain additional thermal insulation.

It is advisable to reduce the heat sink along the main heat-conducting inclusions (cold bridges) by insulating the places of heat sink. To do this, in the supporting sections of the floor slabs, it is possible either to use thermal liners (formed during concreting), or to insulate the end faces of the plates with effective heat-insulating materials (expanded polystyrene, penofol). In the case of a floor slab made of structural expanded clay concrete, such insulation is not required.

Further, the essence of the proposed utility model is illustrated by the drawing, which shows a fragment of the wall in a perspective view.

The three-layer wall contains a facing layer 1 of masonry on mortar, an internal supporting layer 2 (forming a fixed formwork) and a heat-insulating layer 3 placed between them, made of monolithic foam concrete with a density of 500 kg / m ³ . The thickness of the foam concrete layer is selected from the heat engineering calculation of the wall.

The brickwork of the facing layer 1 is made of rows of 4 bricks laid with a spoon, and rows of 5 bricks laid with a poke, while it is possible to support rows of 5 bonded bricks on monolithic reinforced concrete slabs 6 of the floor. The constructive solution provides reliable communication of the facing and heat-insulating layers with bump rows 5 of brick either through four (as shown in FIG. 1) or through five rows of brickwork. In this case, when pouring monolithic foam concrete, a scheme with rigid bonds is implemented, in which it is possible to redistribute the load on the more durable brickwork of the facing layer 1. Rows of 5 bonded elements divide the height of the brickwork layer into separate independent sections and

perceive the weight of each section, unloading the underlying part of the facing layer 1 from the vertical load, which allows you to build a three-layer wall of any height.

The inner layer 2 is made of foam concrete blocks 7, with cement-sand mortar applied to it 8. The strength and stability of the wall is ensured by the joint monolithic work of the layers in the wall section.

Using high-quality foam concrete blocks, you can get walls that require only finishing.

In the level of the floors of the first, third and fifth floors, support elements 9 are mounted in the form of steel tables welded to embedded parts of the slabs 6 of the floors. At the level of the rest of the ceilings, reinforcement is provided along the width of the brick facing layer 1 in two joints through two rows of masonry with reinforcing meshes 10 and insulation of the end face 11 of the plate 6 with heat-insulating material 12, designed to reduce the heat sink along the main cold bridges. As such materials can be used, for example, polystyrene foam, penofol or polystyrene. The overall stability of the wall and the joint deformation of the layers are ensured by bonds established with a regular step along the height of the wall.

The calculated values of the specific heat energy consumption for heating 1 m ^{3 of the} heated area of a 9-story residential building with a monolithic reinforced concrete frame and a total wall thickness of 0.62 m (0.12 front layer; 0.4 monolithic foam concrete; 0.1 foam concrete blocks) and a floor height of 3 m is significantly lower than normalized values.

The proposed wall design allows you to get a monolithic thermal insulation over the entire contour of the building in any configuration, as well as to carry out all the operations necessary for the construction of the wall from the inside of the building and organize continuous process flows for various types of work, to carry them out in a convenient position from the installed ceilings, which reduces the overall complexity of the construction of the building.

Compared with the known structures, the wall proposed according to the utility model improves the heat-shielding properties of the structure while ensuring reliability and strength, and therefore

to improve its operational characteristics (the wall "breathes" with high wind resistance), as well as reduce the complexity of the erection of the walls of buildings in conditions of variable mechanical and temperature-humidity effects.

At present, experimental construction of residential buildings with the proposed technology for wall construction in the Siberian climate zone has begun.

Claims (13)

1. A multilayer outer wall comprising an outer facing layer, an inner layer and a heat-insulating layer interposed between the floor slabs, floor-by-floor, the outer facing layer being made of masonry, characterized in that it comprises means for transferring the load on the floor slabs in a predetermined manner, the heat-insulating layer is made of monolithic foam concrete, and the outer facing layer is formed by alternating rows of bricks laid with a spoon and rows of bricks alternating with a given step, wives with a poke. 2. The wall according to claim 1, characterized in that the said means for transferring the load is made in the form of a supporting element, rigidly connected with a given floor slab and a facing layer. 3. The wall according to claim 1, characterized in that the said means for transferring the load placed on the floor. 4. The wall according to claim 1, characterized in that the said means for transferring the load is placed every two floors. 5. The wall according to claim 1, characterized in that the said means for transferring the load is placed at the level of the third, fifth and ninth floors. 6. The wall according to claim 1, characterized in that the average density of the aforementioned foam concrete is 400-600 kg / m ³ . 7. The wall according to claim 1, characterized in that the inner layer is at least partially made of block concrete. 8. The wall according to claim 7, characterized in that the inner and thermal insulation layers are made of foam concrete of the same density. 9. The wall according to claim 1, characterized in that said step of alternation is four rows of bricks laid with a spoon on one row of bricks laid with a poke. 10. The wall according to claim 1, characterized in that said step of alternation is five rows of bricks laid with a spoon on one row of bricks laid with a poke. 11. The wall according to claim 1, characterized in that a means is provided for reducing heat sink through heat-conducting inclusions. 12. The wall according to claim 1, characterized in that it is provided that the floor slab is made of structural expanded clay concrete. 13. The wall according to claim 1, characterized in that it provides for the execution of a slab monolithic.