RU118656U1 - FLOOR COVERAGE AND ITS OPERATION NODE - Google Patents

Abstract

The utility model relates to the field of construction of frame buildings for various purposes on durable permafrost soils. A complex precast-monolithic basement is formed by monolithic complex three-layer precast concrete elements - slabs, crossbars or randbalks. Thus obtained continuous disk overlap freely rests on the grillage of pile foundations. The technical result is an increase in the efficiency of the prefabricated structure of a complex prefabricated monolithic basement, as well as a reduction in the efforts on pile foundations from significant temperature deformations. 20 s.p. crystals, 2 tab.

Description

The utility model relates to the field of construction of frame buildings for various purposes (industrial, auxiliary, administrative, etc.) on durable permafrost soils and is intended for installation of basement ceilings, which reduce the thermal effect of such buildings on the temperature regime of soils and preserve their frozen state.

Known constructions of basement ceilings of prefabricated reinforced concrete slabs supported on grillages or foundation beams, beams or walls, on top of which a layer of heat-insulating material with a protective multilayer coating is laid (see. Handbook on construction on permafrost soils. Leningrad, Stroyizdat, 1977).

Also known are the constructions of basement ceilings of frame buildings, including load-bearing elements from monolithic and precast concrete (rand beams, crossbars and plates), welded elements from rolled steel and layers of one or more types of insulation (see Typical constructions, series 1.440-3m / 92. Reinforced concrete floor structures over cold ventilated undergrounds of single-storey and multi-storey industrial buildings for construction in permafrost areas. Issues 1 ... 6. - M.: TsNIIIPROMzdaniy, 1992).

The disadvantage of such basement ceilings is a lack of factory readiness, oversized seams, gaps and bearing areas of prefabricated elements, leading to an ineffective consumption of heat-insulating materials and the considerable complexity of their sealing.

The basement structure for buildings erected in permafrost regions is known, consisting of a supporting steel beam cage with steel flooring directly rigidly fixed to the grillages of pile foundations, a suspended welded pallet filled with heat-insulating materials and with an upper protective layer of cast concrete (see Arrangement of the Zapolyarnoye gas-oil-condensate field. Industrial base in Tazovsky. Foundations and foundations, inventory No. 18731 "Fundamentproekt", - M., 1994).

The disadvantages of this design, along with the increased laboriousness of its manufacture directly at the construction site, are low heat-shielding characteristics, low fire resistance, the presence of numerous “cold bridges” and considerable efforts in the load-bearing elements from deformations caused by a large difference in outdoor temperature (up to 90 ° C during of the year).

The objective of the utility model is to create an energy-efficient and fire-resistant prefabricated complex integrated precast monolithic basement, as well as reduce labor costs during construction and installation works associated with the construction of frame buildings for various purposes on durable permafrost soils.

The technical result achieved by the utility model consists in increasing the efficiency of the prefabricated structure of the integrated precast-monolithic basement, including through the use of new types of reinforcement and high-strength concrete, as well as reducing the efforts on pile foundations from significant temperature deformations.

The indicated task and technical result is solved and achieved by the fact that the complex prefabricated-monolithic basement overlap contains complex three-layer prefabricated elements - plates and beams, consisting of an upper supporting layer, a middle heat-insulating layer and a lower protective layer made in the form of a reinforced concrete plate fixed at the bottom middle heat-insulating layer using flexible connections with the upper bearing layer, which is a reinforced concrete slab; the upper face of the upper supporting layer of the slab is made with an open rectangular groove along its contour, and on the lateral faces of the upper supporting layer there are horizontal open grooves of a triangular section, which, when mating plates and beams, makes it possible to combine the plates in a continuous disk of overlapping by laying in the open rectangular grooves of the upper the bearing layer of the reinforcement plates forming the support reinforcement, and filling with concrete monolith; at the corners of the plates are box-shaped supporting tables that are freely adjacent to the lower protective layer of the plate; box-shaped support tables are supported on the foundation grouts through a connecting sheet, which is provided on top with at least two locking pins and a cushioning layer fixed to it from below.

It is preferable that the beams are made in the form of crossbars or randbalks with consoles on the side faces.

The upper bearing layer and the lower protective layer of complex precast elements can be made of fine-grained heavy concrete of classes of compressive strength B25 or VZO.

The middle heat-insulating layer can be made of Penoplex extruded polystyrene foam and has a thickness of 100, 150 and 200 mm.

The cushioning layer can be made of fluoroplastic, teflon or kapron and has a thickness of at least 2 mm.

The reinforcing reinforcing reinforcement can be made in the form of flat welded meshes or welded frames made of welded reinforcement of periodic profile of class A500C or of cold-deformed reinforcement of periodic profile of class B500C.

Flexible connections can be made of basalt plastic or metal rods.

The connecting sheet may be made of metal or plastic.

Thus, KSMTSP is formed by monolithic complex three-layer prefabricated reinforced concrete elements - slabs, crossbars or randbalks. Thus obtained continuous disk overlap freely rests on grillages (heads) of pile foundations.

The use of complex prefabricated elements (plates, crossbars, randbalks) with an upper bearing layer, an average heat-insulating and a lower protective layer allows you to discretely change the allowable payload and increase the heat-shielding qualities of the floor.

The design of the crossbars provides for the implementation of the lower protective layer in the form of a reinforced concrete flat plate fixed to the bottom of the middle heat-insulating layer using flexible connections made, for example, of basalt plastic or metal rods, with an upper bearing layer having consoles (shelves) on their side faces, which designed to support the upper bearing layer of plates on them. At the same time, box-shaped supporting tables freely adjoin the lower protective layer of plates and additional thermal insulation of the side edges of the crossbar is excluded.

Slabs include three parts connected by flexible connections: upper reinforced concrete bearing layer with an open rectangular groove along the contour; a middle heat-insulating layer of effective heat-insulating material, for example, Penoplex extruded polystyrene foam and a lower reinforced concrete protective layer.

On the side faces of the upper bearing layer there are horizontal open grooves of a triangular section. To join the slabs, flat welded meshes and frames forming supportive reinforcement are laid in the upper rectangular grooves in a continuous overlapping disk. Then the upper and side grooves are filled with monolithic concrete.

Box-shaped base tables of the plates are supported on the foundation grilles through the connecting sheet. The latter is equipped on top with at least two locking pins and a cushioning layer of fluoroplastic, teflon or nylon with a thickness of at least 2 mm, mounted on it from below.

Supporting plates through a connecting sheet made of metal or plastic, with a cushioning layer of fluoroplastic, teflon or kapron provides a fairly accurate installation on the assembly and almost completely eliminates the transfer of friction forces to the foundations from thermal deformations of the floor, as well as the occurrence of shocks and noise from “pulling” »Basement overlap.

This solution of the support unit provides an increase in the pace and quality of work during the installation of basement ceilings.

To ensure what is required by SNiP 23-02-2003. Thermal protection of buildings. Gosstroy of Russia. - M., FSUE TsPP, 2004 - 25s. the heat transfer resistance of building envelopes in basement ceilings, the thickness of the middle heat-insulating layer, for example, from Penoplex extruded polystyrene foam, is 100, 150 or 200 mm.

Since the middle heat-insulating layer is located outside the building, underneath between the upper bearing and lower protective reinforced concrete layers, the construction of KSMTSP fully meets the requirements of the type 1 fire barrier, which confirms its full compliance with the requirements of SP 4.13130.2009 and SP 2.13130.2009 (SP 4.13130. 2009. Fire protection systems - Restriction of the spread of fire at protection facilities - Requirements for space-planning and structural solutions, EMERCOM of Russia, - M, FGU VNIIPO EMERCOM of the Russian Federation, 2009 and SP 2.13130.2009. Ensuring the protection of fire protection facilities of EMERCOM of Russia, -.. M., Federal EMERCOM of Russia, 2009).

To evaluate the effectiveness of the KSMTSP, its technical and economic indicators were compared on the basis of working documentation and estimates with a basement with a traditional welded beam supporting structure along the headers of the foundation piles.

The influence of the compared structures of basement ceilings on the energy efficiency of buildings was determined on the basis of specially developed energy passports. For comparison, the estimated data and design decisions were given in a comparable form with the exception of specific details, for example, leveling screeds made of cement-sand mortar for leveling floors. Based on appropriately adjusted estimates, a comparison was made of the main technical and economic indicators (per 1 m of the total area), the results of which are shown in table 1.

Table 1 Comparison of specific technical and economic indicators of basement ceilings Naming of expenditures unit of measurement Type of overlap Traditional KSMTSP Indicator % 1. Consumption of reinforced concrete, including monolithic M / m 0,200 0,042 0.220 0.032 110 79 2. Consumption of rolled steel (construction site) kg / m ² 34,4 4.0 12 3. Labor costs for construction and installation work man hours / m ² 6.32 1.76 28 4. The cost of construction and installation work rub / m ² 1573 631 40

The data in table 1 confirm that the use of complex prefabricated elements in the KSMTSP system, combined into a continuous basement disk by monoling, reduces steel rolling consumption by 8 times, labor costs at the construction site by 3.6 times and, accordingly, reduce by 60 % the cost of construction and installation works (SMR) at an accelerated pace of their implementation (200-300 m of total area in 1 shift).

The calculations of energy efficiency also confirmed the significant advantages of the KSMTSP system (table 2).

table 2 Energy Efficiency Indicators for Buildings with Different Types of Ceilings The name of indicators unit of measurement Basement Type Traditional KSMTSP Indicator % 1. Thermal resistance to basement m ^{2 °} C / W 3,54 6.28 178 2. Specific heat energy consumption for heating a building kJ / (m ³ ° C · day) 25.18 22.73 90 3. Energy demand for heating a building GJ / year 1421 1282 90 4. The cost of heating the building thousand rubles / year 1286.3 1161.0 90

As can be seen from table 2, with the traditional design of the basement with a heat transfer resistance of 3.54 m ^{2 °} C / W, the specific heat consumption for heating the building is 25.18 kJ / (m ^{3 ·} ° C · day), which is 15% higher standardized according to SNiP 23-02-2003 (SNiP 23-02-2003. Thermal protection of buildings. Gosstroy of Russia. - M., FSUE TsPP, 2004) and the building has a low energy efficiency class “D”.

When the KSMTSP heat transfer resistance is equal to 6.28 m ² ° C / W, the specific heat consumption for heating the building is 22.73 kJ / (m ³ · ° C · day), therefore, the increase in the KSMTSP heat transfer resistance compared to the traditional one, 8 times provides a 10% reduction in energy demand for heating the entire building and a corresponding reduction in operating costs over its entire service life of more than 30 years.

This significantly reduces or eliminates the risk of thawing and thawing of permafrost soils under the basement, reducing the reliability of the foundations.

The constructive principle of KSMTSP is the creation of a single continuous cutting disk by reinforcing and monolithic special open grooves on the upper bearing face of the precast elements. Overlappings are freely supported on grillages of pile foundations, which allows to significantly reduce efforts from significant temperature deformations and increase the durability of KSMTSP.

When calculating KSMTSP in accordance with SNiP 52-01-2003 (SNiP 52-01-2003. Concrete and reinforced concrete structures. Basic provisions. Gosstroy of the Russian Federation, - M., FSUE TsPP, 2004) considered two stages of its work:

- the first stage (installation) - until the concrete acquires design monolithic strength;

- the second stage (operational) - after gaining concrete monolithic design strength.

Each stage has its own design scheme and load.

At the first stage, the elements of the KSMTSP work according to a split design and the floor takes on its own weight of prefabricated structures and concrete monolithic, as well as mounting loads. The total design load is taken equal to 6 kN / m.

At the second stage, the KSMTSP elements work according to a continuous scheme, the overlap turns into a single monolithic multi-span disk, which perceives the calculated constant and temporary load - the weight of floors, partitions, equipment, etc. or moving temporary load from trucks.

The calculation included two groups of the main product sizes - extreme, single-cantilever (single-shelf) and medium double-console (two-shelf) crossbars.

In this system, the overlap is designed as a bezel-free continuous multi-span structure, the pillars of which are located on a grid of 3 × 3 m and (or) 4.2 × 3 m pile foundations, and along the extreme axes and in the temperature seam (along the disk contour) are single-cantilever (single-deck ) random beams.

An important criterion when choosing basement floor structures is their fire resistance. KSMTSP provides for the integration of complex three-layer prefabricated elements by monopolizing in continuous in two directions a multi-span continuous concrete disk.

The fire resistance of such statically indeterminate structures is significantly higher than that of statically definable beams and, especially, traditional steel beam cells in basement ceilings.

The calculation showed that the value of the fire resistance limit of KSMTSP after monolithic on the basis of loss of bearing capacity is 206 minutes, which is 1.7 times higher than the regulatory requirements for the fire resistance of load-bearing structures of buildings of I degree of fire resistance. At the same time, the KSMTSP design for fire hazard belongs to the KO class (non-fire hazardous) due to the fact that the layer of low combustible middle heat-insulating layer is located outside the building (under the upper bearing reinforced concrete layer) and is closed from below by the lower protective reinforced concrete layer. Thus, KSMTSP fully meets the requirements of the type 1 fire barrier and complies with the instructions of SP 4.13130.2009 and SP 2.13130.2009.

The use of welded reinforcement of the A500C periodic profile (see I.N. Tikhonov, V.Z. Meshkov, I.N. Surikov (NIIIZhB), A.Z. Belousov, E. S. Savokhin (Mosgorekspertiza) is used as reinforcement. new types of fittings - an important resource for reducing costs. Journal. Bulletin of construction equipment "No. 5 (885), - M., publishing house" BST ", 2008) with the estimated tensile strength R _s = 4430 kgf / cm. This will reduce the consumption of steel with equal strength of the sections of the elements up to 20%. It also provides for the use of cold-deformed reinforcement of the periodic profile of class B500C, the expanded range of which includes a number of intermediate small diameters, which provides additional savings of up to 15% of steel.

For the manufacture of complex prefabricated reinforced concrete elements (crossbars, randbalks and slabs), the use of fine-grained heavy concrete of classes of compressive strength B25 or B30 is provided. The use of concrete of class B30 is advisable for products under standardized payloads of 12 kN / m ² and 16 kN / m ² in order to increase their bearing capacity and rigidity.

The high technical and economic efficiency of the KSMTSP design was established. Its application provides a significant reduction in material and labor costs, the cost of construction and installation works at high rates of their implementation.

With high resistance to heat transfer, KSMTSP provides a reduction of up to 10% in energy consumption for heating a building and provide an increase in its fire resistance.

Claims (22)

1. A basement containing complex three-layer prefabricated elements - slabs and beams, consisting of an upper supporting layer, a middle heat-insulating layer and a lower protective layer made of reinforced concrete and fixed to the bottom of the middle heat-insulating layer using flexible connections with the upper bearing layer made of reinforced concrete; the upper face of the upper bearing layer of the plate is made with an open groove along its contour, and on the side faces of the upper bearing layer are horizontal open grooves, which when mating plates and beams provide the possibility of combining the plates in a continuous disk of overlap by laying in the open grooves of the upper bearing layer of reinforcement plates forming abutment reinforcement, and filling with concrete monolithic. 2. The overlap according to claim 1, in which the beams are made in the form of crossbars with consoles on the side faces. 3. The overlap according to claim 1, in which the beams are made in the form of random beams with consoles on the side faces. 4. The overlap according to claim 1, in which the upper bearing layer and the lower protective layer of the three-layer precast elements are made using fine-grained heavy concrete of classes of compressive strength B25. 5. The overlap according to claim 1, in which the upper bearing layer and the lower protective layer of the three-layer precast elements are made using fine-grained heavy concrete of classes of compressive strength B30. 6. The overlap according to claim 1, in which the middle thermal insulation layer is made of extruded polystyrene "Penoplex". 7. The overlap according to claim 1, in which the middle heat-insulating layer has a thickness of 100 mm 8. The overlap according to claim 1, in which the middle heat-insulating layer has a thickness of 150 mm 9. The overlap according to claim 1, in which the middle heat-insulating layer has a thickness of 200 mm 10. The overlap according to claim 1, in which the reinforcement forming abutment reinforcement is made in the form of flat welded meshes. 11. The overlap according to claim 1, in which the reinforcement forming abutment reinforcement is made in the form of flat welded frames. 12. The overlap according to claim 1, in which the reinforcement forming the support reinforcement is made of welded reinforcement of a periodic profile of class A500C. 13. The overlap according to claim 1, in which the reinforcement forming abutment reinforcement is made of cold-deformed reinforcement of a periodic profile of class B500C. 14. The overlap according to claim 1, in which the flexible connections are made of basalt plastic. 15. The overlap according to claim 1, in which the flexible connections are made in the form of metal rods. 16. The support basement of the basement, characterized in that at the corners of the plates are box-shaped supporting tables, freely adjacent to the lower protective layer of the plate, and which are supported on the foundation grilles through a connecting sheet provided with at least two fixing pins and a cushioning pin layer attached to it from below. 17. The node according to clause 16, in which the cushioning layer is made of fluoroplastic. 18. The node according to clause 16, in which the cushioning layer is made of Teflon. 19. The node according to clause 16, in which the cushioning layer is made of nylon. 20. The node according to clause 16, in which the cushioning layer has a thickness of not less than 2 mm 21. The node according to clause 16, in which the connecting sheet is made of metal. 22. The node according to clause 16, in which the connecting sheet is made of plastic.