RU2009109325A - RIGIDITY STRUCTURE FOR BUILDING FLOOR SLABS IN BUILDINGS - Google Patents

Abstract

1. The design of load-bearing floor slabs in buildings with a frame containing ! load-bearing columns (10) located at least in predetermined corners of the building; ! a reinforced concrete floor slab (9) located in the area defined by said columns, consisting of one or more elements and having two longitudinal sides (Sa), two transverse sides (Sb) and first angles (K1) between them; ! longitudinal steel beams located on the longitudinal sides of the specified floor slab, and the floor slab is in contact with the longitudinal beams; and ! transverse steel beams located on the transverse sides of the specified floor slab, and the floor slab is in contact with the specified transverse beams (1b); ! connecting elements (30) located in the area of said columns (10), having a first arm (31), a second arm (32) and a second angle (K2) between the two arms equal to the first angle (K1); ! wherein the first arm (31) is attached to said longitudinal beam and the second arm (32) is attached to said cross beam, ! characterized in that said floor slabs contain a stiffness structure in which ! said longitudinal steel beams are steel edge beams (1a) comprising at least a wider bottom flange (12) and web or walls (13), or a combination of longitudinal steel edge beams (1a) and longitudinal composite beams (3a) of concrete and steel sheet, or longitudinal composite beams (3a) of concrete and steel sheet; ! said transverse steel beams are load-bearing steel edge beams (1b) comprising at least a wider bottom flange (12) and a web or web

Claims (11)

1. The design of the supporting floor slabs in buildings having a frame containing load-bearing columns (10) located at least in predetermined corners of the building; reinforced concrete floor slab (9), located in the area defined by these columns, consisting of one or more elements and having two longitudinal sides (Sa), two transverse sides (Sb) and the first corners (K1) between them; longitudinal steel beams located on the longitudinal sides of said floor slab, the floor slab in contact with the longitudinal beams; and transverse steel beams located on the transverse sides of said floor slab, wherein the floor slab is in contact with said transverse beams (1b); connecting elements (30) located in the region of said columns (10) having a first arm (31), a second arm (32) and a second angle (K2) between two arms equal to the first angle (K1); moreover, the first shoulder (31) is attached to the specified longitudinal beam, and the second shoulder (32) is attached to the specified transverse beam, characterized in that said floor slabs contain a stiffness structure in which said longitudinal steel beams are steel edge beams (1a) containing at least a wider lower shelf (12) and a wall or walls (13), or a combination of longitudinal steel edge beams (1a) and longitudinal composite beams (3a) from concrete and steel sheet, or longitudinal composite beams (3a) from concrete and steel sheet; said transverse steel beams are load-bearing steel edge beams (1b) containing at least a wider lower shelf (12) and a wall or walls (13), or a combination of load-bearing transverse steel edge beams (1b) and transverse composite beams ( 3b) from concrete and steel sheet, said connecting elements (30) are effectively L-shaped or Δ-shaped elements (30) for transmitting tensile stresses that perceive at least deflecting horizontal tensile forces (F), said shoulders (31, 32) being stress transmission arms extending in the directions of said longitudinal / transverse sides (Sa, Sb) of the floorboard and attached to said longitudinal / transverse edge beams (1a, 1b) and / or to said longitudinal / transverse composite beams (3a, 3b), the transverse sides (Sb) of one or more reinforced concrete floor slabs (9) are supported by their lower surfaces (Pd) on the wider lower shelves (12) of the transverse edge beams (1b), and the longitudinal sides (Sa) of one or more reinforced concrete floor slabs (9 ) are in contact with the longitudinal edge beams (1a) and / or with the longitudinal composite beams (3a). 2. The construction according to claim 1, characterized in that said L-shaped or Δ-shaped tensile stress transmission elements (30) have a cross-sectional shape of strip or corner steel and form said first angle (K1) in the plane of its surface or in the plane one flange of the corner, and the shoulders (31, 32) of the L-shaped or Δ-shaped elements (30) of the transmission of tensile stresses are attached either directly to the edge beams (1a, 1b) or to the supporting elements (14) welded to the composite beams ( 3a, 3b), wherein said shoulder attachment (31, 32) the transmission elements of tensile stresses to the edge beams or to the composite beams are made with bolts (15) and / or by welding (16) and / or by rivets (17). 3. The construction according to claim 1 or 2, characterized in that the transverse steel edge beams (1b) and, possibly, the longitudinal steel edge beams (1a) contain a narrower upper shelf (11) and either one wall or two walls (13 ), which extend at a variable or constant distance from each other between a wider lower shelf (12) and a narrower upper shelf (11), and one or more reinforced concrete floor slabs (9) are supported by their lower surfaces (Pd) on wider lower flanges (12) of the transverse edge beams (1b) in order to absorb loads and in contact with the wider lower shelves (12) of the longitudinal edge beams (1a) without transmitting a vertical load. 4. The construction according to claim 1 or 2, characterized in that the longitudinal composite beams (3a) of concrete and steel sheet contain channel beams (2a) having a wider horizontal lower shelf (22) and the opposite narrower upper edge shelf (21 ) and the side wall connecting them (23), moreover, the reinforced concrete slab (9) on its lower surface (Pd) is in contact with the lower shelves (22) of the longitudinal composite beams, or the lower shelves (12) of these longitudinal composite beams are in contact with the wider lower shelves (12) longitudinal steel cr evyh beams (1a). 5. The construction according to claim 1 or 2, characterized in that the transverse composite beams (3b) of concrete and steel sheet are channel beams (2b), which have a wider horizontal lower shelf (22) and the opposite narrower upper edge shelf (21) and the side wall (23) connecting them, wherein the lower flanges (22) of these transverse composite beams are in contact with at least the wider lower flanges (12) of the transverse steel edge beams (1b). 6. The construction according to claim 1 or 2, characterized in that the said composite beams (3a, 3b) of concrete and steel sheet surround the entire reinforced concrete floor slab (9) and columns supporting it (10), and channel beams (2a and 2b ) of these composite beams (3a, 3b) made of concrete and steel sheet, together with L-shaped or Δ-shaped elements (30) of the transmission of tensile stresses connecting the channel beams together, without additional reinforcing for concrete, form a stiffness structure for each floor slab, wherein the edge beams (1a, 1b), partially closed by the indicated composite beams made of concrete and steel sheet, together with L-shaped or Δ-shaped elements (30) of the transmission of tensile stresses connecting the channel beams together, without additional reinforcement for concrete, form a stiffness structure for each floor slab. 7. The construction according to claim 3, characterized in that said support elements (14) are steel strips or angles that extend in the length direction of the channel beams (2a, 2b) and are welded to the side walls (23) of the channel beams, and the shoulders (31, 32) of said L-shaped or Δ-shaped tensile stress transmission elements (30) are attached to at least said strips or corners of channel beams. 8. The construction according to claim 1 or 2, characterized in that the longitudinal sides (3a) of the floor slab (9) are formed by longitudinal steel edge beams (1a), and the transverse sides (Sb) of the floor slab (9) are formed by transverse steel edge beams ( 1b), the shoulders (31, 32) of said L-shaped or Δ-shaped tensile stress transmission elements (30) attached to the lower shelves (12) or to the upper shelves (11) of the edge beams. 9. The construction according to claim 1 or 2, characterized in that the columns (10) are steel columns having angular fasteners (18) for edge beams and / or channel beams, or reinforced concrete columns having fixing consoles (19) for edge beams and / or channel beams. 10. The construction according to claim 1 or 2, characterized in that it further comprises pipe holders (50), which are attached to the upper edge flanges (21) of the channel beams (2a, 2b) at least in their upper sections; the lower end (51) of the pipe holders is closed, and their upper end (52) is open or can open upward. 11. The method of stiffening the bearing floor slabs in buildings, which includes the following steps at the construction site during installation of the frame, independent of the cladding of the building (100): mounting bearing columns (10) in at least predetermined corners of the building; installation on columns or at least bearing transverse steel edge beams (1b) having a narrower upper shelf (11) and a wider lower shelf (12) and containing one wall or two walls (13) between them or at a constant distance from each other, or combinations of at least load-bearing transverse steel edge beams (1b) having a narrower upper shelf (11) and a wider lower shelf (12) and containing one wall or two walls between each other ( 13) passing on alternating or constant distance dr d from each other, and transverse channel beams (2b) having a wider horizontal lower flange (22), a narrower upper edge flange (21) opposite it and connecting their side wall (23), without additional reinforcing concrete in the direction of their length, wherein said lower shelf (22) in combination of beams is in contact with the lower shelves (12) of said transverse edge beams (1b); and then performing the following steps in a predefined sequence: a reinforced concrete floor slab (9) is placed on the transverse steel edge beams, having upper and lower surfaces (Pc, Pd), two longitudinal sides (Sa), two transverse sides (Sb) and the first angle (K1) between them, and consisting of one or more elements, so that its transverse sides (Sb) rest on the upper part of the lower shelves (12) of the transverse edge beams (1b); longitudinal steel edge beams (1a) are mounted on the columns if these longitudinal edge beams are included in the stiffness structure, and the edge beams (1a) contain a narrower upper shelf (11), a wider lower shelf (12) and one wall or two walls ( 13) located between them and passing at an alternating or constant distance from each other, with the specified lower shelf in contact with the lower surface (Pd) of the floor slab (9); install longitudinal steel channel beams (2a) on the longitudinal sides (Sa) of the floor slabs, if they have not been previously installed, and install transverse channel beams (2b) on the transverse sides (Sb) of the floor slab, and the channel beams contain a wider horizontal lower shelf (22) opposite the narrower upper edge flange (21) and connecting their side wall (23), without additional reinforcement for concrete in the direction of their length, so that the specified lower shelf (22) is in contact with the lower surface the stability (Pd) of the reinforced concrete floor slab (9) and / or with the lower shelves (12) of said edge beams (1a, 1b); fasten between the transverse channel beams and the longitudinal channel beams effectively L-shaped or Δ-shaped tensile stress transmission elements (30) containing the first shoulder (31) of the stress transmission, the second shoulder (32) of the stress transmission and the second angle (K2) between the two shoulders Thus, the first shoulder (31) is located in the direction of the longitudinal side (Sa) of the floor slab and the longitudinal channel beam (2a) with attachment to this longitudinal channel beam, and the second shoulder (32) is located in the transverse side direction (Sb) floor slabs and the cross channel beam (2b) with attachment to this cross channel beam, or fasten between the transverse edge beams and the longitudinal edge beams effectively L-shaped or Δ-shaped tensile stress transmission elements (30) comprising a first stress transmission arm (31), a second stress transmission arm (32) and a second angle (K2) between the two arms so that the first shoulder (31) is located in the direction of the longitudinal side (Sa) of the floor slab and the longitudinal edge beam (1a) with attachment to this longitudinal edge beam, and the second shoulder (32) is located in the direction of the transverse side (Sb) of the plate re rytiya and transversal edge beam (1b) with the attachment to the edge of this transverse beam, and, in conclusion, pour concrete (B) so that concrete fills at least the intermediate spaces between the steel channel beams and the reinforced concrete floor slab, and the channel beams together with the concrete form longitudinal composite beams (3a) of concrete and steel sheet and transverse composite beams ( 3b) of concrete and steel sheet on the longitudinal sides (Sa) and on the transverse sides (Sb) of the ceiling surrounding the columns (10).