RU147338U1 - MONOLITHIC BUILDING - Google Patents

Abstract

1. A monolithic building, including walls formed by the outer and inner layers of reinforced concrete, a layer of plate insulation placed between the layers of reinforced concrete adjacent to them, and rod connections connected to reinforcement of the outer and inner layers of reinforced concrete and passed through the layer of plate insulation, characterized in that the building includes a foundation formed by the outer and inner layers of reinforced concrete, a layer of plate insulation, placed between the layers of reinforced concrete adjacent to them, and rod connections connected to reinforcement of the outer and inner layers of reinforced concrete and passed through the layer of slab insulation, while the rod connections of the walls and the foundation are made of reinforcement made of composite materials, and the outer and inner layers of reinforced concrete are interconnected by reinforced concrete at the point of abutment in the ground and are completely isolated from each other by a layer of slab insulation in any other section of the wall. 2. The building according to claim 1, characterized in that the layer of plate insulation is made with a thickness of 0.15 m. 3. The building according to claim 1, characterized in that an additional reinforced concrete frame is placed inside the layer of plate insulation with the reinforcement of the inner layer of reinforced concrete attached. 4. The building under item 3, characterized in that the layer of plate insulation is made with a thickness of 0.2 m. 5. The building according to one of paragraphs. 1 or 3, characterized in that the rod connections of the walls and the foundation are made of carbon fiber reinforcement. 6. The building according to one of paragraphs. 1 or 3, characterized in that the rod ties of the walls and the foundation are made of basalt-plastic reinforcement. 7. The building according to one of paragraphs. 1 or 3, characterized in that the rod connection of the walls and f

Description

The utility model relates to construction and can be used in the construction of residential, social and industrial buildings with the requirements of maximum energy conservation. The utility model relates to the special construction of the wall and foundation, the erection of a monolithic three-layer structure of the walls of the building and the formwork system for its implementation, and is intended for the construction of frame and frameless buildings and structures made of monolithic reinforced concrete with improved thermal characteristics.

From the prior art (presentation "Basaltoplastics: creating a modern production of composite nanostructured polymer reinforced with basalt fibers", LLC "Galen", author V.N. Nikolaev, published on 04/11/2011, http://www.rusnanonet.ru/download/presentation /galen_jpresent.pdf) a building is known, which includes walls and a foundation formed by the outer and inner layers of reinforced concrete, a layer of insulation and core ties. A layer of insulation is placed between the layers of reinforced concrete close to them. Rod connections are passed through a layer of insulation and made of composite materials - carbon fiber, basalt plastic and fiberglass reinforcement.

The disadvantage is the high investment associated with the fact that the construction of this decision involves the use of prefabricated panels or blocks (bricks). Investments are needed in the production of prefabricated panels, the delivery of such materials to remote regions is difficult, and large transportation costs arise.

The prior art monolithic building, adopted as a prototype (patent No. 2032032, ΜΠΚ E04B 1/16, published 03/27/1995). The well-known monolithic building contains walls formed by the outer and inner layers of reinforced concrete, a layer of plate insulation and rod ties. A layer of plate insulation is placed between the layers of reinforced concrete close to them. Rod connections are connected to the reinforcement of the outer and inner layers of reinforced concrete and passed through a layer of plate insulation.

The disadvantages are the low energy passivity effect and the high cost level.

The technical result of the utility model is to achieve the energy passivity of the wall structure and the foundation of monolithic buildings, to save investment by optimizing the use of materials, reduce the complexity and cost of construction work, and avoid waste.

The essence of the utility model is that a monolithic building includes walls formed by the outer and inner layers of reinforced concrete, a layer of tile insulation placed between the layers of reinforced concrete adjacent to them, and rod connections connected to reinforcement of the outer and inner layers of reinforced concrete and passed through the layer of tile insulation . In addition, the building includes a foundation formed by the outer and inner layers of reinforced concrete, a layer of slab insulation placed between the layers of reinforced concrete close to them, and rod ties connected to reinforcement of the outer and inner layers of reinforced concrete and passed through the layer of slab insulation. The rod connections of the walls and the foundation are made of reinforcement made of composite materials. The outer and inner layers of reinforced concrete are interconnected by reinforced concrete at the point of support in the ground and are completely isolated from each other by a layer of plate insulation in any other place of the wall section. In this case, the layer of plate insulation can be made with a thickness of 0.15 m or more. Inside the layer of plate insulation with the reinforcement of the inner layer of reinforced concrete attached, an additional reinforced concrete frame can be placed, in which case the layer of plate insulation can be made with a thickness of 0.2 m or less. This rod connection of the walls and the foundation can be made of carbon fiber, basalt-plastic and fiberglass reinforcement. To achieve energy passivity, the layer of plate insulation can be made with a thickness of 0.3 m or more. The outer layer of reinforced concrete can be made with a thickness of 0.1 m or more. The inner layer of reinforced concrete can be made with a thickness of 0.1 m or more. The outer layer of reinforced concrete can contain a water-repellent additive. The underground part of the walls can be isolated from the ground with a layer of roll waterproofing. A sand bed may be located under the base of the foundation.

The utility model is illustrated by the following drawings.

In FIG. 1 shows a longitudinal section of the wall of a monolithic building with a frame, where 1 is the reinforcement, 2 is the inner layer of reinforced concrete, 3 is the outer layer of reinforced concrete, 4 is the core connection, 5 is the layer of plate insulation, 6 is the additional reinforced concrete frame, 7 is the bearing point in the ground. 8 - roll waterproofing, 9 - sand bedding, 10 - soil, 11 - reinforced concrete floors.

In FIG. 2 shows a cross-section of a fragment of a wall of a monolithic building without a frame, where: 1 - reinforcement, 2 - the inner layer of reinforced concrete, 3 - the outer layer of reinforced concrete, 4 - rod ties, 5 - a layer of plate insulation.

In FIG. 3 shows a cross section of a wall fragment of a monolithic building without a frame in the place of a window or doorway, where: 1 - reinforcement, 2 - the inner layer of reinforced concrete, 3 - the outer layer of reinforced concrete, 4 - rod ties, 5 - a layer of plate insulation.

In FIG. 4 shows a cross-section of a fragment of a wall of a monolithic building with a frame, where: 1 - reinforcement, 2 - the inner layer of reinforced concrete, 3 - the outer layer of reinforced concrete, 4 - rod ties, 5 - a layer of plate insulation, 6 - additional reinforced concrete frame.

In FIG. 5 shows a cross-section of a fragment of a wall of a monolithic building with a frame in place of a window or doorway, where: 1 - reinforcement, 2 - the inner layer of reinforced concrete, 3 - the outer layer of reinforced concrete, 4 - rod ties, 5 - layer of insulated tiles, 6 - additional reinforced concrete frame.

The monolithic building contains walls and a foundation formed by the outer layer 3 of reinforced concrete (facing), the inner layer 2 of reinforced concrete (structural), the layer of plate insulation 5 (heat-insulating) and the rod connections 4 (see Fig. 1, 2, 3).

A layer of plate insulation 5 is placed between the outer 3 and inner 2 layers of reinforced concrete close to them, that is, the outer 3 and inner 2 layers of reinforced concrete are placed on both sides of the layer of plate insulation 5 parallel to it.

The rod connections 4 are connected to the reinforcement 1 of the outer 3 and inner 2 layers of reinforced concrete, passed through the layer of plate insulation 5 and are evenly distributed over the entire area of the plate insulation.

The outer 3 and inner 2 layers of reinforced concrete are interconnected by reinforced concrete at the point of support 7 in the soil 10 and are completely isolated from each other by a layer of plate insulation 5 in any other place of the wall section.

In this case, it is possible to combine the thicknesses of the layer of plate insulation 5, outer 3 and inner 3 layers of reinforced concrete. The layer of tile insulation 5 for the frameless walls and foundation of the monolithic building described above can be made with a thickness of 0.15 m or more. The required thickness of the layer of tile insulation 5 for the frameless building is provided by the use of insulation with a plate thickness that is a multiple of the manufactured range. Insulation plates of non-standard thickness are not produced and can only be made to order, which is impractical. In addition, designers often recommend replacing one required layer of plate insulation with several to offset joints of the insulation and eliminate the possibility of cold bridges. Thus, for example, for the formation of a layer of plate insulation 5 with a thickness of 150 mm, three insulation plates of 50 mm each can be used with a dressing of the joints of the insulation between the plates in a checkerboard pattern.

To increase the bearing capacity of the inner layer of reinforced concrete 2 and the use of reinforced concrete floors 11, an additional reinforced concrete frame 6 can be installed (see Fig. 1, 4, 5). In this case, an additional reinforced concrete frame 6 is placed inside the layer of plate insulation 5 with the reinforcement 1 attached to the reinforcement 1. Reinforced concrete floors 11 are mounted on top of the additional reinforced concrete frame 6. The additional reinforced concrete frame 6 allows the belt molding of concrete into the formwork with a layer of plate insulation 5 pre-installed in it, reinforcement 1 and rod connections 4.

For the walls and foundation of a monolithic building using the additional reinforced concrete frame 6 described above, the layer of plate insulation 5 can be made with a thickness of 0.2 m or more.The required thickness of the layer of plate insulation 5 for the frame building is provided by using insulation with a plate thickness that is a multiple of the manufactured range. For example, to form a layer of plate insulation 5 with a thickness of 200 mm, you can use two insulation plates of 100 mm each with ligation of the joints of the insulation between the plates in a checkerboard pattern.

Rod connections 4 for both frame and frameless walls and foundations are made of reinforcement made of composite materials - in particular, carbon fiber, basalt-plastic and fiberglass reinforcement. Composite fittings improve the thermal performance of the entire building, its use reduces the number of insulation boards.

To achieve energy passivity, the layer of plate insulation 5 is made with a thickness of 0.3 m or more in combination with rod ties 4 made of composite reinforcement. For energy passivity of the entire building, it is recommended to comply with the requirements for energy-passive buildings: namely, the glazing should be using low-emission glass, the roof with an additional layer of insulation, the doors are heat-saving.

The outer layer 3 of reinforced concrete can be made with a thickness of 0.1 or more; the inner layer 2 of reinforced concrete can be made with a thickness of 0.1 m or more. The thickness of the layers of reinforced concrete is a calculated value, since the thickness of the reinforced concrete layer suitable for small and light houses will be insufficient for large and heavy buildings. In turn, the thickness of the reinforced concrete layer, suitable for large and heavy buildings, will lead to cost overruns for small and light buildings.

Any configuration of walls and molding of architectural elements is also possible when arranging the outer layer of reinforced concrete 3. The thickness of the outer layer 3 of reinforced concrete and the frequency of reinforcement with reinforcement 1 are determined by the project. Moreover, in the most loaded parts of the foundation and the wall, the thickness of the outer layer 3 of reinforced concrete and the frequency of reinforcement can be increased to the required load capacity. Such an increase in the thickness of the outer layer 3 of reinforced concrete can be carried out both in the direction of the layer of plate insulation 5, and outside the wall.

To increase the strength and durability of the outer layer of reinforced concrete 3, a hydrophobizing additive is added to it.

The underground part of the walls can be isolated from the soil 10 with a layer of rolled waterproofing 8, which protects it from moisture. A sand bed 9 may be located under the base of the foundation.

The gap in the outer 3 and inner 2 layers of reinforced concrete in the places of window and door openings allows to further improve the thermal characteristics of the entire building and reduce costs during subsequent operation.

Monolithic three-layer walls and the foundation of the building are erected using formwork vertically mounted inside the racks of the spatial frame, mounting layers of plate insulation 5, reinforcing with reinforcement 1 and subsequent laying in the formwork layer of the moldable mixture, its compaction, achieving the specified strength by the mixture, dismantling the frame and formwork . When pouring concrete, it is possible to install the finishing finishing material in the form of clinker tiles, plastic panels and another. Introduction to the building structure of the above structural elements with their interconnection allows you to create a warm, strong and durable building.

Thus, the utility model allows to achieve maximum energy passivity of wall structures and the foundation of monolithic buildings, reduce investment by optimizing the use of materials, reduce the complexity and cost of construction work. By optimization, it was possible to reduce the amount of heavy, expensive inert materials and increase the amount of light, cheap insulation layer in the form of a plate insulation.

The analysis of the identified sources of information showed that the monolithic building having a structure similar to the proposed technical solution is not known from the technical field.

Claims (13)

1. A monolithic building, including walls formed by the outer and inner layers of reinforced concrete, a layer of plate insulation placed between the layers of reinforced concrete adjacent to them, and rod connections connected to reinforcement of the outer and inner layers of reinforced concrete and passed through the layer of plate insulation, characterized in that the building includes a foundation formed by the outer and inner layers of reinforced concrete, a layer of plate insulation, placed between the layers of reinforced concrete adjacent to them, and rod connections connected to reinforcement of the outer and inner layers of reinforced concrete and passed through the layer of plate insulation, while the core connections of the walls and the foundation are made of reinforcement made of composite materials, and the outer and inner layers of reinforced concrete are interconnected by reinforced concrete at the point of abutment in the ground and are completely isolated from each other by a layer of slab insulation in any other section of the wall. 2. The building under item 1, characterized in that the layer of plate insulation is made with a thickness of 0.15 m 3. The building according to claim 1, characterized in that an additional reinforced concrete frame is placed inside the layer of plate insulation with the reinforcement of the inner layer of reinforced concrete attached. 4. The building under item 3, characterized in that the layer of plate insulation is made with a thickness of 0.2 m. 5. The building according to one of paragraphs. 1 or 3, characterized in that the rod connection of the walls and the foundation are made of carbon fiber reinforcement. 6. The building according to one of paragraphs. 1 or 3, characterized in that the rod connection of the walls and the foundation are made of basalt-plastic reinforcement. 7. The building according to one of paragraphs. 1 or 3, characterized in that the rod connection of the walls and the foundation are made of fiberglass reinforcement. 8. The building according to one of paragraphs. 1 or 3, characterized in that the layer of plate insulation is made with a thickness of 0.3 m or more to achieve energy passivity. 9. The building according to one of paragraphs. 1 or 3, characterized in that the outer layer of reinforced concrete is made with a thickness of 0.1 m 10. The building according to one of paragraphs. 1 or 3, characterized in that the inner layer of reinforced concrete is made of a thickness of 0.1 m 11. The building according to one of paragraphs. 1 or 3, characterized in that the outer layer of reinforced concrete contains a water-repellent additive. 12. The building according to one of paragraphs. 1 or 3, characterized in that the underground part of the walls is isolated from the ground by a layer of roll waterproofing. 13. The building according to one of paragraphs. 1 or 3, characterized in that under the base of the foundation is a sand bed.

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