SUBSTANCE: basement comprises a natural or an artificial base with a curvilinear cylindrical surface, a membrane laid onto the base and a support contour in the form of a system of cross beams. The membrane is laid via gaskets made of two layers of the material sliding relative to each other, onto the curvilinear cylindrical surface of the natural or artificial base arranged in a pit and turned upwards with a convexity. In the transverse direction the membrane is attached by edges to the support contour in the form of a system of cross beams, which is submerged into the natural base.
EFFECT: reduced subsidence of a basement, higher reliability of a structure above the basement, creation of an efficient membrane basement, reduced material intensity.
The invention relates to the construction involves the installation of membrane foundations for buildings and structures.
The Foundation contains artificial or natural base with a curved cylindrical surface which is convex upward, forming the shape of the membrane, a solid membrane support contour in the form of a system of cross beams.
What's new is that the solid membrane is placed on an artificial or natural basis directly through the strip, consisting of two layers of material, moving relative to each other thus reducing friction between the membrane and the substrate. In this membrane has no bending stiffness.
The technical result of the invention is to reduce the residue of the Foundation, reducing material consumption, more involvement in the work of the soil under the membrane due to the curved shape of the surface of the base, and a uniform distribution efforts tension in the membrane, that allows full use of its strength.
Known Foundation in the form of a shell finite stiffness, convex upward (EN 2223367 C2, MKI 02D 27/01, publ. 10.02.04). When given constructive scheme shell works predominantly in tension.
The disadvantage of this design is the presence of reinforcement in the center section of the shell cracks, the cat is which can be formed under the action of stretching and bending and lead to corrosion of steel reinforcement.
Closest to the present invention are the foundations in the form of reticulated shells (EN 2393297 C1 IPC 02D 27/01, publ. 27.04.09)containing artificial base with a curved surface which is convex upward, the system of load-bearing tapes reticulated shells, laid over the strip, consisting of two layers of material, moving relative to each other, on a concrete surface, formed on the curved surface of the artificial base, support contour in the form of a system of cross-beams or support ring. Between the concrete shell and the reference circuit is a strip of elastic material (EN 2393297 C1 IPC 02D 27/01, publ. 27.04.09).
The disadvantage of this design is the presence of a concrete shell, which increases the complexity of manufacturing and material Foundation.
The purpose of the invention is to create an effective membrane of Foundation compliance with specified reliability advancements design.
Proposed Foundation containing artificial or natural base with a curved surface, a continuous membrane laid on the base and the support contour in the form of a system of cross beams. According to the invention the membrane is laid over the strip, consisting of two layers of material, moving relative to each other, on a curved cylindrical surface is of synthetic or natural origin, located in the pit and is convex upward, and in the transverse direction of the membrane attached edges to a reference contour in the form of a system of cross-beams, which are embedded in the natural basis.
As the bases used membrane, forming a concave cylindrical surface with a ratio of boom lift span
Figure 1 shows the membrane base with a reference contour in the form of a system of cross beams. The Foundation presented in the form of a continuous membrane 1. In the transverse direction of the membrane 1 is limited to the reference circuit 2, which is a system of cross beams. Membrane 1, placed on a natural or artificial base 5, 3 through the strip 4, consisting of two layers of material, moving relative to each other. In this constructive form membrane 1 on the surface of natural or artificial base 5, 3 work in tension without friction on the contact base 5, 3 - membrane 1. As the membrane 1 can be used fabrics from glass, aramid, carbon and other fibers of high strength and high modulus of elasticity. Reference circuit 2 are embedded in the natural basis. Perception is aspora in membrane foundations is due to the Flexural rigidity of the support circuit 2 and the lateral resistance of the soil along the reference path 2. The attachment of the membrane 1 in the transverse direction is performed to the control circuit 2.
The method of basement membrane is as follows.
Developed pit planning to mark. Planned natural or artificial curved base 5, 3 of mineral materials. On the surface of the base 5, 3 stacked membrane 1 via spacers 4, consisting of two layers of material, moving relative to each other. Formwork and install reinforcing cages in the reference circuit 2. Is the concreting of the reference circuit 2. Is the attachment of the membrane 1 in the transverse direction to the control circuit 2.
In the process sediment reference circuit 2 of the Foundation is the involvement of natural or artificial curved base 5, 3, and membrane 1 in the transfer of most of the external load on natural or artificial curved base 5, 3 under the Foundation. This significantly increases the resistance of the soil in the most loaded area under the reference circuit 2. In this case, resistance to natural or artificial curved base 5, 3 is also increasing due to its compression in the horizontal direction of the reference circuit 2. Jet pressure of natural or artificial curved founded the I 5, 3 are transmitted and distributed on the membrane 1. Spacer efforts, which appear in the membrane 1 perceived Flexural rigidity of the cross tapes and reactive pressure natural or artificial base in a horizontal direction.
The Foundation contains natural or artificial base with a curved cylindrical surface, the membrane is laid on the base and the support contour in the form of a system of cross-beams, characterized in that the membrane is laid over the strip, consisting of two layers of material, moving relative to each other on the curved cylindrical surface of natural or artificial base, located in the pit and is convex upward, and in the transverse direction of the membrane attached edges to a reference contour in the form of a system of cross-beams, which are embedded in the natural basis.
SUBSTANCE: method for construction of a foundation includes preparation of a pit bottom for a foot, production of its rigid filler and an external shell of truncated cone shape with expansion of the lower part of its wall and formation of a compacted soil core. The foundation is erected from structural and soil construction elements. The bottom of the pit is prepared for the foot of the structural element with a groove in soil with the specified geometric shape, its rigid filler is made in a sectional conical form from fractions of lumpy clay and cement-sand mortar with the foot of the specified geometric shape. Expansion of the lower part of the wall in the external monolithic reinforced concrete shell is carried out with a foot with the specified geometric shape as well. A soil construction element is formed under a foot of a structural element with a rated pushing load from a structure, as a rigidly coupled compacted core in the form of a circular cone.
EFFECT: improved quality, reliability, bearing capacity of a base, performance, provision of foundation interaction with a base.
8 cl, 2 dwg
SUBSTANCE: lock prefabricated strip footing includes a support slab and rows of foundation slabs arranged on it. The support slab has a face inclined and bonder surfaces, the upper rib for a slot fixation into a lock of the above block. Foundation units have vertical and horizontal slots, protruding beyond faces of the bed and outbond surface by 1/3 of the width, at the same time the last row of the strip footing is arranged from a block, having a flat upper horizontal surface for resting of wall materials when erecting above walls.
EFFECT: reduced labour intensiveness of foundation blocks assembly, increased accuracy of foundation blocks installation, reduced deviations from horizontal and vertical planes, higher resistance of foundation blocks to displacement due to application of geometric parameters of a foundation block.
5 cl, 1 ex, 6 dwg
SUBSTANCE: foundation includes boards arranged on a levelling sand preparatory base, having limiters under a foot. Boards have through slots along edges, and limiters are arranged in the form of flat plates, as capable of their insertion into through slots.
EFFECT: increased rated resistance of base soil, increased bearing capacity and reduced subsidence of a structure.
3 cl, 3 dwg
SUBSTANCE: prestressed shallow foundation formed by a foundation slab, a ground base and a support board installed under the foundation slab and under the ground base at the optimal depth. On the foundation slab there are jacks arranged, which are connected with traction rods and with ground anchors, inserted into the support board and stressed with a total force, which is equal to or is slightly higher than the weight of the erected structure. Anchor traction rods are arranged with tubular section to supply mortar during arrangement of a support board.
EFFECT: invention provides for minimisation of ground base deformation and for elimination of bases and foundations of nearly located buildings and structures, reduction of material intensity and labour intensiveness in construction of foundations.
2 cl, 1 dwg
SUBSTANCE: method to erect a foundation on heaving soils includes installation of a foundation slab and heat insulation material onto a levelled base. A sliding layer is laid on the prepared base, and a multi-layer spatial foundation platform, comprising heat insulation material, is erected in a monolithic manner. The lower reinforced concrete slab is formed with vertical reinforcement rods protruding into crossing ribs along the entire height of the platform. Heat insulation material is laid onto the lower reinforced concrete slab with the possibility to arrange a system of crossing ribs. Crossing ribs are formed. An intermediate reinforced concrete slab is formed, the second layer of heat insulation material is set on it. Cross ribs are formed, and the upper reinforced concrete slab is formed, besides, the vertical reinforcement rods are connected to reinforcement of all slab layers.
EFFECT: reduced labour costs, provision of heat insulation material durability against potential damage, higher spatial stiffness of the foundation slab and its distributing capacity, provision of protection against frost swelling.
3 cl, 1 dwg
SUBSTANCE: heat-insulation foundation comprises wall, foot, insulator of wall, additional insulator of foundation connected to insulators of foot and blind area. Lower edge of foundation insulator is below the level of freezing of soil, and external moistureproof gasket is arranged at the edge of blind area insulator. Additional moistureproof gasket is also located under foot, connected to external moistureproof gasket, and fill is provided between foundation insulator and external moistureproof gasket.
EFFECT: improved operational properties of heat insulation foundation, simplified design, saving of energy resources.
3 cl, 2 dwg
SUBSTANCE: foundation comprises artificial bed with curvilinear surface, bearing elements and shell arranged on bed. Bearing elements are arranged in the form of radial and circular tapes for shells with positive Gauss curvature or transverse and longitudinal tapes for shells with zero Gauss curvature, forming meshy shell and laid through gaskets made of two layers of material, which slide relative to each other, onto concrete surface formed on curvilinear surface of artificial bed arranged in pit and inverted upwards with its convexity. Radial or transverse tapes are fixed by their edges to support contour in the form of support ring or a system of cross beams, which is deepened into natural bed, and gasket of elastic material is located between concrete of shell and support contour.
EFFECT: reduced settling of foundation, lower material intensity, provision of efficient and reliable protection of above-foundation structure.
SUBSTANCE: foundation comprises support part, vertical stiffening ribs installed in it, which form square metal frame, under-column part arranged on vertical stiffening ribs - metal frame and equipped with elements of column structure connection. Support part is equipped with lower and upper reinforcement grids, and stiffening ribs are arranged in the form of at least three beams coming out of a single centre located on vertical axis of foundation, are arranged in the form of bent profiles and equipped with stiffening elements. Stiffening ribs are installed between lower and upper reinforcement grids, and elements of column structure connection to support part are arranged in the form of reinforcement leads.
EFFECT: reduced metal intensity and increased bearing capacity of foundation, simplified design.
2 cl, 4 dwg
SUBSTANCE: monolithic foundation for column erected on natural or manmade basement, for instance rammed in the form of truncated cone, comprises support part with metal frame and under-column part installed on metal frame and equipped with elements of column structure connection. Support part is equipped with lower and upper reinforcement grids, and metal frame is made in the form of rigid inserts, which are symmetrically arranged versus vertical axis of foundation and are installed between lower and upper reinforcement grids. Elements of column structure connection to support part are arranged in the form of reinforcement leads.
EFFECT: simplified design, reduced metal intensity and increased bearing capacity of foundation erected under column.
3 cl, 4 dwg
FIELD: construction industry.
SUBSTANCE: foundation includes natural base with curved surface, load-carrying members and cover located on base. Load-carrying members are made in the form of orthogonal bands forming a meshed cover and laid on system of blocks installed on natural curved base located in ditch and the bulge of which is directed upwards; at that, ends of bands are attached to support outline made in the form of two-way beam system, which is embedded in natural base.
EFFECT: effective and reliable protection of the construction above foundation, reducing material consumption.
FIELD: construction, particularly new building erection and existent building reconstruction under any engineering-geological circumstances.
SUBSTANCE: foundation structure comprises shallow foundation and reinforcement members. Reinforcement members are made as vertical bars of precast or cast-in-place piles having diameters less than 200 mm and arranged along foundation perimeter. The piles are spaced a distance from outer foundation faces. The distance is equal to 0.1-0.5 of reinforcement member diameter. Distance between neighboring piles is equal to 2-4 reinforcement member diameters and reinforcement member length is 15-20 diameters thereof.
EFFECT: increased load-bearing capacity due to creating compressive operational conditions under different engineering-geological circumstances, increased dynamic rigidity of foundation base and reduced foundation deformation and vibrational amplitude.
FIELD: building, particularly panel foundations for multistory buildings and structures, which apply non-uniform loads to ground base.
SUBSTANCE: method involves forming crossing slots in ground; reinforcing the slots with frames and concreting the slots. For panel foundation erection in clay ground pit is preliminarily dug in ground. Then crossing slots adapted for reinforcing frames receiving are created in pit ground, wherein the reinforcing frames have projected parts. Areas of reinforcing frames intersection are additionally reinforced along with connecting projected parts and concreting thereof to fill the slots.
EFFECT: increased operational effectiveness and reduced costs.
FIELD: building, particularly to erect bored cast-in-place foundations of increased load-bearing abilities including ones having bottom marks typical to shallow foundations.
SUBSTANCE: stepped foundation comprises bored cast-in-place sections formed with the use of auger. Lower foundation step includes four peripheral cylinders of Dp.l. diameters and heights equal to above diameters. Peripheral cylinder centers are located at apexes of square having side lengths equal to Dp.l.. Square center coincides with center of support. Central support abutting four peripheral cylinders of lower foundation step has four expanded parts with Dc.exp diameters determined as Dc.exp=(1.0-1.2)Dp.l. and cylindrical bore having diameter Dp.up determined as Dp.up=(0.6-0.8)Dp.l.. Foundation bottom is 0.7 m below ground surface. Foundation erection method involves forming drilled pile sections; serially drilling wells having daug.1 diameters as each peripheral cylinder having Dp.l. is forming; creating each peripheral cylinder having height equal to Dp.l. by supplying working material for above cylinder forming; filling remainder well section with ground material, particularly with ground excavated from above object. Auger having diameter, which provides necessary Dp.l. diameter is used. The auger provides usage of technological processes, which provides 1.05-1.1 increase of pile diameter in comparison with auger diameter daug.1 and 1.1-1.2 increase of ground pile diameter in comparison with daug.1 diameter. After four peripheral cylinders of lower foundation step creation well having daug.2 diameter is drilled by means of direct auger rotation and ground excavation to day surface. The well has center coinciding with central support center and depth selected so that the well reach tops pf peripheral lower step cylinders. Then lower expanded part of central support is formed, wherein the expanded part has expansion degree Bc.exp./daug.2 equal to 1.5-2.0. During cylindrical bore drilling the expanded part has expansion degree Dp.up/daug.2 equal to 1.2-1.5.
EFFECT: increased load-bearing capacity per foundation volume unit, extended field of technical means.
3 cl, 4 dwg
FIELD: construction, particularly to erect foundations in natural base.
SUBSTANCE: method involves driving pair of members pivotally connected with each other and provided with single bevels at lower ends thereof in ground; digging-out trench; installing guiding member on trench bottom; forcing plate members in ground up to plate members abutting upon guiding member and closing of beveled upper ends thereof; installing the similar pair of members having lengths exceeding that of the first pair in trench; driving above pair in ground up to upper beveled ends closing; concreting the trench.
EFFECT: increased load-bearing capacity of the foundation due to inclined members embedding and ground compaction under foundation bottom.
FIELD: construction, particularly to erect multistory buildings on non-uniformly compressible clay base.
SUBSTANCE: method involves excavating crossing trenches in ground; filling the trenches with concrete and joining thereof with slab covering the trenches. Trenches are excavated from pit bottom for different depths. Lower trench parts are provided with widened abutment sections having reinforcement bars included therein. The reinforcement bars are used as non-stretched threads. Trenches and slab are reinforced with nettings. Cell centers of the slab are anchored.
EFFECT: increased rigidity of foundation slab due to provision of ribs in ground.
FIELD: construction, particularly to erect foundations on natural bases.
SUBSTANCE: shallow foundation comprises support mats and foundation building blocks. Support mats have through orifices along mat perimeters. Upper parts thereof have extensions shaped as truncated cones and adapted to immerse piles in ground as load increases during structure overbuilding.
EFFECT: increased load-bearing ability.
FIELD: construction, particularly to reconstruct buildings and building structures.
SUBSTANCE: foundation comprises supports, sheath freely formed in ground inside area defined by foundation so that convexity thereof faces upwards and connected to supports by means of flexible ties. Cement mix layer, metal arch trusses and reinforced concrete layer are serially arranged on ground inside area defined by foundation. Metal sheets are laid on arch trusses and connected with each other through welded joints to create flexible sheath. Pre-stressed flexible ties inserted in through support orifices and provided with fixing anchors are placed over the sheath. In the second embodiment foundation comprises support, sheath freely arranged in ground inside area defined by foundation so that convexity thereof faces upwards and connected to supports by means of flexible ties. Ground mix layer reinforced with cement mix, metal sheets and reinforced concrete layer are serially located on ground inside area defined by foundation. Metal sheets are bent along predetermined profile and connected with each other to create sheath. Relaxed flexible ties inserted in through support orifices and provided with fixing anchors are placed over the sheath.
EFFECT: increased operational reliability.
4 cl, 1 dwg, 1 ex
FIELD: construction, surface mounted structures.
SUBSTANCE: invention pertains to construction and can be used when erecting buildings with considerable loading on a compressed clay bed. The technique for erecting a solid core foundation slab with closed vertical walls, directed downwards, involves designing a foundation pit, trenches, reinforcing them with frames and filling with concrete, and joining the surface with a slab. The trenches are dug from the bottom of the foundation with different depths. The trenches are then joined, thereby forming several closed contours, whose depth increases from the central part of the slab to the edges. The technical outcome is increase in strength of the foundation slab due to effect of the square shaped closed edges in the ground.
EFFECT: increased strength of the foundation slab.
FIELD: constructional engineering.
SUBSTANCE: invention refers to constructions on heaving soils. House footing based on freezing through soils includes a rigid body with flanges and indents from soil side, footing indent inserts made of heat-insulating material, e.g. polystyrene foam at such ratio of flange and footing indent areas that soil pressure from the lower flange surface is not less than standard pressure of frost soil heaving, soil pressure from the lower insert surface is not exceeding design compression resistance of insert material. Also, the said footing contains supplementary heat insulation laid outside of the footing. The upper edge of supplementary heat insulation is passed from external edge of the footing in the form of interrupted inserts through rigid body of the footing and connected to supplementary heat insulation of opposite external edge of the footing. Relative area of interrupted inserts (β=Aint.ins./A0) is given by the relation β≤1-σmax/R, where Aint.ins. is sectional area of interrupted inserts, m2, A0 is gross sectional area of the footing within inserts arrangement regions, m2, σmax is maximum external load pressure in footing material, MPa, R is design resistance of footing material, MPa. Indents and flanges of the footing from soil side are alternating along footing length. Indents centres from soil sides are provided under interrupted inserts centres of supplementary heat insulation from each external edge of the footing.
EFFECT: possibility to lay foundation above the design depth of heaving soil frost penetration level.
4 dwg, 1 tbl
SUBSTANCE: invention refers to construction of the basements of buildings. The basement structure of a building includes heat - and waterproofing layer (17, 18, 40) which is laid on a flat horizontal surface (51) layer of the material breaking capillary action. The basement structure includes a frame (31) which surrounds specified heat - and waterproofing layer (17, 18, 40), at least, in its top part, thus fixing integrity of basement structure in a horizontal plane and which serves for punctiform bracing of the building supported by basement structure. The specified basement structure is encapsulated with foil (111) from a metal material.
EFFECT: prevention of smell penetration in a building and water-proofing maintenance; possibility of fast and energy conserving erection of the basement.
8 cl, 8 dwg