FR2879636A1 - Slab support assembly for e.g. office building, has beams comprising reinforcement armatures with coupling bars, and columns with corbels supporting end of each beam so that beams are placed side by side by longitudinal projecting portion - Google Patents

Abstract

The assembly has two longitudinal prestressed beams (1) between which floors are laid, and two columns (11) made of reinforced concrete. Each beam has a reinforcement armature with transversal coupling bars (9) extending in a reserve from a corresponding side of a main section. Each columns has a corbel (13) supporting an end of each beam so that the beams are placed side by side by their longitudinal projecting portion. An independent claim is also included for a method for manufacturing a slab using a slab support assembly.

Description

The present invention relates to a support assembly for a slab and a

  method of producing such a slab.

  BACKGROUND OF THE INVENTION Buildings constructed of concrete, including residential buildings or office buildings, generally have a structure comprising slab-shaped floors supported by posts. The columns and slabs are made of reinforced concrete either from prefabricated elements or pouring concrete into formwork directly on the site. Reinforced concrete beams are generally arranged between the posts to support lost formwork plates on which concrete is poured to form the slab.

  It is now common to space poles as much as possible in order to limit the constraints related to their presence. This results in an increase in the range of the beams whose thickness also increases in order to have sufficient inertia for such a range. For example, considering the expected loads in these buildings, a floor can have a thickness of 1.10 m with a beam thickness of 0.90 m and a slab thickness of 0.20 m. The minimum free height of a level being 2.20 m, it is found that the cumulative thickness of two floors corresponds to the height of a level.

  It would therefore be advantageous to have a means of limiting the thickness of the floors so as to achieve higher levels of height or a greater number of levels for the same building height.

  It was thought to use beams having a structure identical to that of prefabricated bridge spars whose spans are generally very important. However, such beams would have a relatively high weight, so that this solution would encounter, especially on urban construction sites, the absence of handling equipment having sufficient lifting capacity to move these beams.

  OBJECT OF THE INVENTION An object of the invention is to provide a means for limiting the thickness of floors, which can be implemented on most construction sites.

BRIEF DESCRIPTION OF THE INVENTION

  For this purpose, there is provided, according to the invention, a support assembly of a slab, comprising at least two prestressed beams and two vertical supports of reinforced concrete. - each beam having a main section and a flange having a longitudinal portion projecting from one side of the main section to define a reserve with the main section, a reinforcement structure embedded in the beam and hitching irons having a portion embedded in the beam and a projecting portion in the reserve, - each vertical support having at least one raven arranged to support an end of each beam so that the beams are contiguous by their longitudinal portion protruding.

  Thus, individual beams can be lifted by conventional handling equipment such as tower cranes which are common on building construction sites. After filling the lateral reserves with concrete, the two beams form a single beam whose mechanical characteristics combine to support a slab.

  According to a particular embodiment, at least one of the vertical supports is a post comprising two opposite crunches arranged to support an indented end of each beam so that the beams are contiguous by their longitudinal protruding portion.

  It is thus possible to have a good connection of the beams to the post.

  The invention also relates to a method of producing a slab by means of support assemblies of the above type comprising the steps of: - erecting the vertical supports, - arranging the pairs of beams between the vertical supports, - spread concrete in the reserves, mount the slab on the beams.

  The transverse drawbar and the concrete dissolved in the reserves allow the recovery by the two beams of the forces exerted by the slab or the elements that it supports.

  Preferably, beams are abutted on the crows and the method comprises, prior to the filling of the reserves, the step of arranging longitudinal fastening irons between the abutment beams.

  Thus, when beams are abutted, the longitudinal hitch bars ensure the continuity of the reinforcement between the abutment beams.

  Advantageously, prior to the filling of the reserves the method comprises the step of arranging between the beams of the plates, and during the filling of the reserves, spreading concrete on the plates to form the slab.

  The process is then particularly simple and economical.

  Other features and advantages of the invention will emerge on reading the following description of a particular non-limiting embodiment of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

  Reference is made to the accompanying drawings, in which: FIG. 1 is a partial schematic representation of a floor according to the invention, seen from above with cutaway, FIG. 2 is a partial schematic view of this floor, in section along line II-II of Figure 1, - Figure 3 is a partial schematic view of the floor, in section along the line III-III of Figure 1.

  DETAILED DESCRIPTION OF THE INVENTION

  With reference to the figures, the support assembly of a slab according to the invention comprises pairs of beams generally designated 1.

  Each beam 1 is made of concrete and has a main section 2 and a sole 3 extending under the main section 2.

  The sole 3 has a longitudinal portion 4 projecting laterally from one side of the main section 2. The longitudinal portion 4 has a substantially planar and vertical lateral approach surface 5 and defines with the main section 2 a lateral reserve 6.

  The longitudinal portion 4 stops at the ends of the main section 2 and the sole 3 to define a notch 10.

  The main section 2 has an upper surface 15 along which extends a rabbet 16 at the opposite of the protruding longitudinal portion 4.

  Each beam 1 comprises prestressing elements 7 (visible only on one of the beams of FIG. 3) extending longitudinally in the portion of the beam 1 extending under the neutral fiber thereof (the position of the neutral fiber is determined in a manner known per se) for compressively compressing this portion of the beam 2. The prestressing elements 7 are for example cables, bars or son adherent steel which are tensioned before being drowned in the concrete constituting the beam 1. The prestressing part here comprises the sole 3 and the portion of the main section 2 adjacent to the sole 3. The distribution of the prestressing elements is determined so that the prestressing increases in a sense of distance compared to the neutral fiber. The value of the preload to be exerted is calculated according to the bending forces that the beam 1 is intended to support.

  Each beam 1 comprises a reinforcing reinforcement 8 (visible only on one of the beams of FIG. 3) embedded in the concrete constituting the beam 1. The reinforcing reinforcement 8 is here designed to reinforce the main section 2, the sole 3 and the connection of these. The reinforcing armature 8 is arranged and dimensioned in a manner known per se according to the stresses that the beam 1 is intended to undergo. The reinforcing reinforcement 8, made by assembling steel rods, comprises transverse hitching bars 9 which protrude into the lateral reserves 6 from the corresponding side of the main section 2. The hitching irons transversely 9 extend projecting from the lateral side 5 docking. Alternatively, the concrete constituting the beam 1 may incorporate, in substitution or in addition to the frame 8, fibers or particles in metal or other forming a reinforcement structure of the beam in the same way as the reinforcing reinforcement 8. The transverse hitch bars then have a part anchored in the concrete of the beam and preferably in the main section thereof and an opposite part in protrusion of the lateral landing face 5.

  The support assembly according to the invention also comprises posts 11 made of reinforced concrete having a rectangular cross-section and having two opposite faces 12 provided with crows 13. Significantly at the crows 13, the posts 11 comprise ducts 14 which are extend parallel to the faces 12 and corbel 13 to open into the side reserves 6 of the beams when they will be supported by the corbels as will be explained below. The posts 11 are made in conventional reinforced concrete prefabricated or not.

  The method of producing a slab 19 by means of support assemblies according to the invention will now be described.

  The process begins with the step of erecting the posts 11 and arranging on the crows 13 thereof the ends of the beams 1 so that two beams 1 are contiguous by their longitudinal portion 6 projecting. The beams 1 rest on the crows 13 by the soles 3.

  The cross section of each post 11 is then received in the notches 10 of the pair of beams 1. When pairs of beams 1 are abutted, the cross section of the posts 11 is received in the housing delimited by the notches 10 of the four for 1.

  Longitudinal hitching bars 17, 17 'are then respectively placed in the lateral reserves 6 via the ducts 14 and on the upper faces 15 of the main sections 2 of the abutting beams 1 in order to ensure the continuity of the longitudinal reinforcement. between the beams 1 butted. The presence of longitudinal hitching irons and in particular irons 17 strengthens the connection of the beams 1 to the posts 11.

  Plates 18 are arranged between the pairs of adjacent beams 1 so that the edges of the plates 18 are received in the rabbets 17 which thus ensure the lateral positioning of said plates 18.

  After the setting of reinforcements on the plates 18, the process continues by spreading concrete in the lateral reserves 6 and on the plates 18 to form the slab 19.

  The plates 18 may be lost co-forming plates. The plates 18 may also be made of reinforced concrete possibly prestressed or cellular concrete and arranged to contribute to the strength of the slab. In this case, the plates 18 (called predalles in the technical language) have a rough surface to present a relative cohesion with the slab and are said to be collaborating. The plates 18 are then an integral part of the slab 19.

  As an indication, with such a construction, a floor having a thickness of about 0.60 m can be obtained, with a thickness of 0.20 m for the slab. The beam 1 has a thickness (or height) of the order of 0.40 m, a width of the order of 0.60 m and a range of about 16 m.

  Of course, the invention is not limited to the embodiment described and it can provide variations of embodiment without departing from the scope of the invention as defined by the claims.

  In particular, the reinforcing armature can be arranged differently and comprise, for example, transverse drawbars forming a complete loop instead of an open loop. The reinforcing reinforcement preferably has irons projecting from the upper surface of the main section 2 to provide a connection with the concrete and the reinforcement of the slab and the longitudinal hitch irons. Longitudinal hitching irons can be arranged differently from those described: it is thus possible to use only irons 17 or irons 17 '.

  Crows may also extend from the faces of posts perpendicular to the beams. It is possible to provide a threaded rod protruding from the crows to be received in an oblong slot formed longitudinally in the projecting portions to allow attachment of the beams to the crows by bolting. This is useful for maintaining the beams on the crows before pouring concrete which will ensure their final fixation.

  The vertical supports of the beams may have a structure different from that of the poles described and include for example a wall.

Claims (10)

  Supporting assembly for a slab, comprising at least two longitudinally prestressed beams (1) and two reinforced concrete vertical supports (11), characterized in that.   - each beam has a main section (2) and a sole (3) having a longitudinal portion (4) projecting from one side of the main section to define a reserve (6) with the main section, a reinforcing structure ( 8) embedded in the beam and coupling irons (9) having a portion embedded in the beam and a portion projecting into the reserve, - each vertical support comprises at least one raven (13) arranged to support one end of each beam so that the beams are contiguous by their projecting longitudinal portion.   2. support assembly according to claim 1, characterized in that at least one of the vertical supports is a post (11) having two crows (19) opposite arranged to support a notched end of each beam so that the beams are joined by their longitudinal portion (4) projecting.   3. support assembly according to claim 2, characterized in that the pole (11) comprises at least one conduit (14) transverse and parallel to the crows to open into the reserves (6) and allow the passage of at least one iron longitudinal coupling (17).   4. Support assembly according to claim 1, characterized in that, the pole (11) having a rectangular section, the crows (13) extend over two fa-ces (12) opposite to each other and parallel to the longitudinal di-rection of the beams (1).   5. Support assembly according to claim 1, characterized in that the main section (2) has an upper surface (15) having a rabbet (16) opposite the longitudinal portion (4) projecting.   6. A method of producing a slab (19) by means of support assemblies according to claim 1, comprising the steps of: - erecting the vertical supports (11), - arranging the pairs of beams (1) between the vertical supports, - spread concrete in the reserves (6), - mount the slab on the beams (1).   7. Method according to claim 6, characterized in that beams (1) are abutting on crows 13 and in that the method comprises, prior to filling reserves (6), the step of arranging the hitching irons longitudinals (17, 17 ') between the butted beams.   8. A method according to claim 6, characterized in that, prior to the filling of the reserves, the method comprises the step of arranging between the beams of the plates (18), and when filling reserves (6), spreading concrete on the plates to form the slab.   9. Method according to claim 8, characterized in that the plates (18) are lost formwork plates.   10. The method of claim 8, characterized in that the plates (18) are arranged to contribute to the strength of the slab (19).