RU105637U1 - BASE FOR LOW-STOREY CONSTRUCTION ON WEAK SOILS - Google Patents

Abstract

 1. The foundation for low-rise construction on soft soils, including a strip reinforced concrete foundation under all the bearing walls of the building, from interconnected and combined into a system of cross tapes, characterized in that the foundation for low-rise construction in monolithic or precast-monolithic execution is made in the form of slabs -frame foundation under all the bearing walls of the building, laid on a leveled base without reinforcing it with special means on a waterproofing layer in the form of a film under the entire building, including the remainder, the cross-section of the elements of the slab-frame foundation has a closed box-shaped shape, consisting of upper and lower reinforced concrete slabs combined with extreme lateral and middle thickened ribs, between which the insulation is laid, the protruding part of the slab-frame foundation outside the plane of the outer walls acts as a socle and docked with the blind areas laid on the insulated base in the case of heaving soils, the space between the frame elements is laid by the earthen mass and a layer of insulation on top, forming suschuyu first floor floor structure. ! 2. The foundation for low-rise construction on soft soils according to claim 1, characterized in that in the prefabricated-monolithic version, the elements of the slab-frame foundation are made in the factory version as prefabricated with releases of reinforcement for joining adjacent elements with reinforcement with monolithic assembly.

Description

The utility model relates to the construction of foundations of low-rise buildings on soft soils, which are characterized on the one hand by the low weight of the low-rise building, and on the other hand, by the weak bearing properties of the base (less than 1 kg / m ² ).

In traditional solutions, according to the building rules (SP-50-101-2004 of clause 8.3, it is indicated that "in difficult engineering and geological conditions (specific soils, high groundwater levels, etc.), the types of foundations specified in clause 8.2 can be used b and c ”, that is,“ foundations on locally sealed foundations (in rammed or stamped pits, driven blocks, etc.), short piles. ”Section 8.9 of the same joint venture states“ precast-monolithic and monolithic foundations of all walls must be rigidly interconnected and combined into a system of cross ribbons. ”Specific soils also include bulk, waterlogged, peat, etc.

Buried strip foundations are known in which the sole is located at or below freezing depth (Yakovlev R.N. Universal foundation. TISE technology, 2006).

Known columnar-tape foundations, including columns laid to the depth of freezing, and a ribbon grillage connecting the upper ends of the posts in a single design. A distinctive feature of such a foundation is the presence of an air gap of 10 ... 15 cm under the tape. Outside, the gap is closed by a blind area not connected to the grillage tape. When installing the foundation on heaving soils, the air gap compensates for the expansion of the heaving soil, and on non-heaving soils it provides a “soft” support of the house on the base. (Yakovlev R.N. Universal foundation. TISE technology, 2006)

Known shallow foundation, which is a concrete or reinforced concrete element, usually laid on a pillow or bed of non-porous material, which reduce the movement of the foundation both during freezing and thawing. As the material for the device pillows (filling) can be used sand gravel, coarse or medium-sized, fine gravel, boiler slag, as well as non-porous soils. (BCH 29-85. Designing the shallow-footed foundations of low-rise rural buildings on heaving soils. Moscow 1985, Clause 3.2-3.4, Fig. 2).

Known shallow tape reinforced concrete foundation with a continuous cross-section, mounted on a bed of sand laid in a trench. (RN Yakovlev, “New Construction Methods” - TISE Technology of Adelant LLC, 2006. - 480 p. Fig. 4.14. P. 84).

The disadvantages of the known analogues of foundations are the lack of reliability for construction on weak, subsidence, heaving soils and in seismic zones due to sensitivity to uneven soil deformations, significant heat loss through the foundation, increased material consumption and high labor costs associated with hardening the foundation and using specialized equipment.

Known shallow foundation, taken as a prototype, laid on a locally compacted base, made in the form of reinforced concrete and concrete element, placed on a pillow of non-porous material - sand of large and medium size, fine gravel, etc. This material is filled (with a layer-by-layer seal, as with a pillow device) and the sinuses of the trench. The foundation elements are interconnected by welding or twisting through the outlets of reinforcement, filled with concrete and form a precast-monolithic horizontal frame redistributing uneven soil deformations. (Bodanov Yu.F. Foundation from A to Y. Moscow, 2005, Fig. 39 p. 75, prototype).

The disadvantages of the prototype are: firstly, the high labor costs due to the need for preliminary local strengthening of the base using special equipment with various special means up to replacing weak and heaving soils, while neglecting the natural bearing properties of soft soils, which leads to environmental damage and natural the natural structure of soils and the existing hydrological regime of groundwater; secondly, insufficient rigidity of the frame to ensure low sensitivity to uneven soil deformation due to the continuous rectangular cross-section of the reinforced concrete element, thirdly, low heat-shielding properties that do not prevent the possibility of frost heaving, and increased consumption of concrete to increase the height of the reinforced concrete element for providing sufficient rigidity. In general, the construction of such foundations is not economical, laborious, and ineffective in operation, and to provide the required stiffness makes them heavy (i.e., the load from the foundation weight in relation to the upper structure makes up a significant part of the payload, of the order of 20% or more), which not beneficial for soft soils.

The objective of the utility model is to reduce labor costs during the construction of the foundation, increase rigidity, reliability of operation, improve heat-shielding properties and reduce the consumption of concrete and reinforced concrete.

To solve this problem, in the foundation for low-rise construction on soft soils, including a strip reinforced concrete foundation under all the bearing walls of the building, from interconnected and combined into a system of cross tapes, according to a utility model, the foundation for low-rise construction in monolithic or precast-monolithic execution in the form of a slab-frame foundation under all the bearing walls of the building, laid on a leveled base without reinforcing it by special means on a waterproofing layer in the idea of a film for the entire building, including the blind area, the cross-section of the elements of the slab-frame foundation has a closed box-like shape, consisting of upper and lower reinforced concrete slabs combined with extreme lateral and middle thickened ribs, between which the insulating layer is laid, the protruding part of the slab-frame foundation beyond the plane of the outer walls, it acts as a socle and is joined with the blind areas laid on the insulated base in the case of heaving soils, the space between the frame elements is laid by the earthen mass and insulation layer on top, forming the supporting floor structure of the first floor.

According to the utility model, in the prefabricated-monolithic version, the elements of the slab-frame foundation are made in the factory version as prefabricated with reinforcement releases for joining adjacent elements with reinforcement with monolithic assembly.

Figure 1 schematically shows the foundation for low-rise construction on soft soils in a monolithic design, axonometry; figure 2 is a section aa in figure 1; figure 3 - node B in figure 2; figure 4 - the foundation for low-rise construction on soft soils in a precast-monolithic design, axonometry; figure 5 is an element of a slab-frame foundation with releases of prefabricated reinforcement for prefabricated monolithic construction.

The foundation for low-rise construction on soft soils, shown in figure 1, is made in the form of a slab-frame foundation 1 in a monolithic design of elements 2 and is located under the supporting walls of the building (not shown conditionally). The plate-frame foundation is laid on a leveled base 3 without reinforcing it with special means with laying on it a waterproofing layer 4 in the form of a film under the entire building. The cross section of the elements 2 of the slab-frame foundation 1 has a closed box-shaped shape (Fig. 2), consisting of upper 5 and lower 6 reinforced concrete slabs combined with extreme lateral 7 and middle reinforced 8 reinforced ribs (Fig. 3). Between the ribs 7, 8, a plate insulation 9 is laid, which is a fixed formwork of the side ribs 7. The protruding part of the plate-frame foundation outside the plane of the outer walls acts as a socle and is joined to the blinds 10, laid on the base covered with a waterproofing layer 4, equipped with a heater 11 in case of heaving soil. The space between the elements 2 of the slab-frame foundation is laid with an earthen mass 12 and a layer of insulation 13 on top, forming the supporting structure of the floor of the first floor.

The foundation for low-rise construction on soft soils, depicted in Fig. 4, is made in a prefabricated-monolithic version and contains elements of a plate-frame system 14, manufactured at the factory in the required dimensions with the outlets of the reinforcement 15 at the ends (Fig. 5). During assembly, the valve outlets are connected, and the nodes are monolithic. In addition, joints can be performed by welding embedded parts installed in the elements of the plate-frame system 14 (not shown conditionally).

The presence of a waterproofing layer in the form of a film under the entire building, isolating the foundation structure from the base and acting as a sliding layer, helps to reduce the transmission of horizontal seismic effects on the foundation and the entire structure.

The construction of the foundation for low-rise construction on soft soils in monolithic execution is as follows.

Several layers of waterproofing film 4 with a low coefficient of friction are laid on the leveled base 3 under the entire area of the building, including the blind area 10. A formwork is installed on it to form the slab-frame foundation 1 under the supporting walls. The reinforcement of the bottom plate 6 is laid and welded into the formwork with reinforcement outlets for the side 7 and thickened 8 ribs (not shown conditionally). The bottom plate 6 is concreted. A plate insulation 9 is installed on it, which serves as a fixed formwork of the side ribs 7 and the thickened rib 8. Next, the reinforcement of the top plate 5 is installed and the ribs 7, 8 and the top plate 5 are jointly concreted. The space between the molded elements 2 is filled with earthen mass 12, on the surface of which a layer of insulation 6 is laid, for example expanded clay or slab. The protruding part of the slab-frame foundation beyond the plane of the outer walls, acting as a socle, joins the blind areas 10, which are laid on a base covered with a waterproofing layer 4, insulated in the case of heaving soils. Moreover, thermal insulation 11 is laid on the waterproofing film 4 along the perimeter of the foundation, followed by concreting of the blind area 10.

The construction of the foundation for low-rise construction on soft soils in a precast-monolithic version is carried out as follows.

Several layers of waterproofing film 4 with a low coefficient of friction are laid on the leveled base 3 under the entire area of the building, including the blind area 12. Elements 2 of the slab-frame system 14 with releases of reinforcement 15 made at the factory are laid on it under the bearing walls. In abutting places, the outlets of the reinforcement 15 are bonded or welded. Further, the interface between the elements monolith. The space between the elements 2 is filled with a layer of soil 12, on the surface of which a heater 13 (expanded clay or slab, etc.) is laid. Thermal insulation 11 is laid on the waterproofing film 4 along the perimeter of the foundation with subsequent concreting of the blind area 10.

If necessary, for household and operational needs in the interval between the frame elements, an underground room (technical cavity) can be arranged, which has independent structural solutions from the slab-frame foundation. This is very important for soft soils, since the room is actually in favorable insulated conditions and is used for household needs.

Technical appraisal and economic advantage:

The use of the foundation for low-rise construction on weak soils in monolithic or precast-monolithic versions allows you to build in difficult soil conditions (on very weak, subsidence, heaving soils, etc.) without preliminary hardening of the soil, using the natural properties of soils that combine structural and functional properties and providing strength, rigidity, allows you to use any insulation. Due to the spatial rational shaping, bending stiffness is increased, due to this the design becomes insensitive to uneven deformations of the base, thereby increasing the reliability of operation without preliminary significant excavation and cushioning.

This design helps to reduce labor costs and reduce the cost of construction by reducing the volume of earthworks, which are minimized, the device does not require an earth cushion and the use of specialized equipment, and additional insulation of the base is not required.

This design provides rigidity due to the spatial shaping of the elements of the slab-frame foundation.

This design helps to improve heat-shielding properties by reducing heat loss through the floor and foundation by 10-15%. The insulation is protected from moisture and destruction, i.e. its durability is provided, and, therefore, reliable protection of the soil from frost heaving. In addition, the insulated soil mass forms the supporting structure of the floor foundation.

A sliding layer in the form of several layers of film under the foundation system performs waterproofing functions, creates the possibility of slipping a powerful seismic wave under the foundation.

Thus, this foundation design for low-rise construction on soft soils in monolithic or precast-monolithic versions has reliability, durability, and economy.

Claims (2)

1. The foundation for low-rise construction on soft soils, including a strip reinforced concrete foundation under all the bearing walls of the building, from interconnected and combined into a system of cross tapes, characterized in that the foundation for low-rise construction in monolithic or precast-monolithic execution is made in the form of slabs -frame foundation under all the bearing walls of the building, laid on a leveled base without reinforcing it with special means on a waterproofing layer in the form of a film under the entire building, including the remainder, the cross-section of the elements of the slab-frame foundation has a closed box-shaped shape, consisting of upper and lower reinforced concrete slabs combined with extreme lateral and middle thickened ribs, between which the insulation is laid, the protruding part of the slab-frame foundation outside the plane of the outer walls acts as a socle and docked with the blind areas laid on the insulated base in the case of heaving soils, the space between the frame elements is laid by the earthen mass and a layer of insulation on top, forming suschuyu first floor floor structure. 2. The foundation for low-rise construction on soft soils according to claim 1, characterized in that in the prefabricated-monolithic version, the elements of the slab-frame foundation are made in the factory version as prefabricated with releases of reinforcement for joining adjacent elements with reinforcement with monolithic assembly.