FR3127240A1 - Prefabricated finished floor element, process for manufacturing a floor and floor obtained - Google Patents

Abstract

The invention relates to a finished prefabricated floor element (1), consisting of a panel made of a structural material (MS), comprising in its thickness building blocks (5) and reinforcements (6, 7). The lightening blocks (5) form a grid and define between them a network of ribs (8, 9) extending in two intersecting directions (X, Y). The reinforcements (6, 7) are arranged in two parallel layers (10, 11) on either side of the building blocks (5). They protrude from the edges (4) of the floor element (1) to ensure mechanical continuity with adjacent floor elements (1). A floor (20) is obtained by juxtaposition of floor elements (1) separated from each other by a junction zone (ZJ) delimited by an integrated formwork spoiler (12), and by casting only in the junction zones (ZJ) of a very high performance keying material (MC), for sealing said floor elements (1) between themselves and to the load-bearing elements of a construction, making it possible to produce a load-bearing structure of a building without a compression slab cast on worksite. Figure for abstract: Fig 2

Description

Prefabricated finished floor element, process for manufacturing a floor and floor obtained

The present invention relates to a prefabricated finished floor element, consisting of a panel made of a structural material, defined by a plane, a width, a length, a thickness, a lower face, an upper face, and edges which connect the lower and upper faces, said floor element comprising in its thickness building blocks and frames.

The invention also relates to a method of manufacturing a floor from prefabricated finished floor elements and a floor obtained.

Precast finished floor elements have existed for many years in the form of hollow core slabs, in prestressed concrete or reinforced concrete, to make dry floors, i.e. floors that do not require a poured compression slab. On the worksite. There have also been prefabricated élégis floor elements for many years, to manufacture semi-finished floors in the same way as floor pre-slabs, requiring a compression slab cast on site. An example is described in the publication FR 2 856 092 B1 belonging to the applicant, in which the prefabricated élégis floor elements can include passages to allow the crossing of technical networks.

In general, finished or semi-finished prefabricated floor elements must have a surface weight lower than the weight of a solid floor cast in place. This result is achieved by voids (hollow slab), blocks of lightweight material (elevation), and/or lightweight structural material. The main disadvantage of hollow core slab or elegie slab floors is that they bear only in the main direction of the floor. They can only rest on linear load-bearing elements such as walls or beams. These floors cannot therefore be used on point supports, such as posts or pillars, without the use of flat beams called “embedded strips” in the thickness of the floor. In addition, the crossing of the technical networks perpendicular to the direction of span is also problematic in this type of floor, in particular in the case of hollow core slabs.

The current solutions of finished prefabricated honeycomb or elegis floor elements are therefore not satisfactory.

The present invention aims to overcome these drawbacks by proposing a new solution of a floor element, finished and prefabricated, which has the advantage of offering a favorable compromise between a greatly reduced total weight of the floor, a quantity of concrete poured in space reduced to a minimum, guaranteed mechanical continuity between the floor elements in two intersecting directions of the floor, and a low carbon floor. The invention also relates to the manufacture of a floor by juxtaposition of floor elements, and keying of the latter, said finished floor elements comprising the entire structural part of the floor. The invention also relates to the floor obtained, which can be laid with or without a prop, can bear in one or two directions, can rest either on the heads of posts, beams or walls (veils), and can incorporate technical networks (electricity, weak currents, water).

For this purpose, the invention relates to a floor element of the kind indicated in the preamble, characterized in that characterized in that said blocks of elegance have a width and a length less than the width and length of said floor element, in that said lightening blocks are arranged relative to each other in the plane of said floor element, with a predefined interval, so as to define between them a network of ribs made of said structural material, said ribs extending in two intersecting directions of said plane to bear in said two directions, and in that at least part of said reinforcements protrude from the edges of said floor element to ensure mechanical continuity with adjacent floor elements when they are juxtaposed to make a floor.

Thus, the floor element obtained constitutes a complete and finished element, which integrates all the characteristics and performances necessary to constitute a floor having a load-bearing capacity in two intersecting directions, ready to install and ready to seal to other identical floor elements. or similar, making it possible to considerably shorten the duration of the construction site.

Depending on the embodiment variants, the ribs forming said network may or may not be mutually perpendicular.

Said lightening blocks advantageously have a thickness less than the thickness of said floor element, and can be positioned so that they are flush with the underside of said floor element, or that they are completely embedded in the thickness of said element. floor.

Said reinforcements can advantageously be arranged in at least two layers parallel to said plane, including a lower layer and an upper layer, said lower layer possibly being located between said blocks of lightening or below said blocks of lightening, and said upper layer preferably being located above said building blocks.

Said layers may comprise reinforcements extending in at least two intersecting directions from said plane, and the reinforcements of the two layers advantageously protrude from the edges of said floor element to ensure mechanical continuity with adjacent floor elements when they are juxtaposed for build a floor.

In a preferred form of the invention, said floor element comprises a formwork spoiler extending the underside of said floor element, on at least two of said edges to create junction zones between adjacent floor elements when they are juxtaposed. to make a floor.

Said reinforcements can consist of rigid bars, the protruding part of which can be straight or curved like a hook, and/or of flexible cables, the protruding part of which can form a closed or open loop.

Depending on requirements, said floor element may comprise at least one sheath, which crosses said floor element perpendicularly, to delimit a reservation intended to receive at least one reinforcing bar in line with a load-bearing element of a construction. In this case, said floor element may comprise around said sheath a support zone full of structural material, without any thinning block.

The ribs provided in said floor element may have a variable width, preferably increasing in the direction of said sheath or of said solid support zone.

In the same way, said floor element may comprise at least one passage intended to receive a sheath or a technical conduit, said passage being made by a groove and/or a perforation provided in said building blocks and by a passage sheath in said ribs between the adjacent building blocks concerned.

The object of the invention is also achieved by a process for manufacturing a floor consisting of:
- juxtaposing floor elements on carrying elements of a construction to form the surface of the floor to be manufactured, said floor elements being separated from each other by junction zones,
- interlock the protruding parts of the reinforcements of the adjacent floor elements in said junction zones, and
- Pouring a keying material only in said junction zones to seal said floor elements between them and to said load-bearing elements of the construction to complete said floor without a compression slab cast on site, said floor bearing in two intersecting directions.

In this method, said junction zones are advantageously delimited by formwork spoilers integrated into said floor elements.

The method further provides for casting a keying material having a very high compressive strength in said junction zones, said material being chosen from the group comprising high-performance concretes or micro-concretes, very high-performance concretes or micro-concretes, ultra-high performance fiber-reinforced concrete or microconcrete. It plans to preferentially use microconcretes, whose aggregates have a size less than or equal to 10mm.

The object of the invention is also achieved by a floor obtained by said manufacturing process, without a compression slab cast on site.

The present invention and its advantages will appear better in the following description of several embodiments given by way of non-limiting examples, with reference to the appended drawings, in which:

is a perspective view of a finished prefabricated floor element according to the invention,

is a cross-sectional view of the floor element of the according to section plan II-II,

is a cross-sectional view of two floor elements before assembly,

is a cross-sectional view of the two floor elements of the after assembly,

is a perspective and transparent view of a floor made by juxtaposing six floor elements according to the ,

is a top view of detail VI of the floor of the showing protruding reinforcement in the junction area between adjacent floor elements,

is an enlarged view of detail VII of the showing a bearing area on a load-bearing post, provided in a floor element,

is a cross-sectional view of the floor element of the , in line with the support zone on the load-bearing post,

is a top view of a floor element provided with ribs of increasing thickness in the direction of the support zone,

is a sectional view of a junction between a floor element and a trumeau,

is a sectional view from the side of the junction of the ,

is a sectional view of two floor elements assembled according to a variant embodiment of the ,

is a sectional view of two floor elements assembled according to a variant embodiment of the ,

is a perspective view of a floor element according to the alternative embodiment of the ,

is a partial perspective view of the floor element of the ,

is a top view of part of a floor element provided with reservations for the passage of technical networks in the thickness of the floor,

is a cross-sectional view in a first cutting plane of the floor element of the , And

is a cross-sectional view in a second sectional plane of the floor element of the .

Claims (19)

Prefabricated finished floor element (1, 1'), consisting of a panel made of a structural material (MS), defined by a plane (XY), a width, a length, a thickness, an underside (2) , an upper face (3), and edges (4) which connect the lower and upper faces, said floor element (1, 1') comprising in its thickness lightening blocks (5) and reinforcements (6, 7), characterized in that said accommodation blocks (5) have a width and a length less than the width and length of said floor element (1, 1'), in that said accommodation blocks (5 ) are arranged relative to each other in the plane (XY) of said floor element (1), with a predefined interval (I), so as to define between them a network of ribs (8, 9) made in said structural material (MS), said ribs (8, 9) extending in two intersecting directions (X, Y) from said plane to bear in said two directions, and in that at least part of said reinforcements (6 , 7) protrudes from the edges (4) of said floor element (1, 1') to ensure mechanical continuity with adjacent floor elements (1) when they are juxtaposed to make a floor (20). Floor element according to Claim 1, characterized in that the ribs (8, 9) forming the said network are mutually perpendicular. Floor element according to any one of the preceding claims, characterized in that the said building blocks (5) have a thickness less than the thickness of the said floor element (1, 1'), and are positioned so that they are flush with the underside (2) of said floor element (1, 1'), or they are completely embedded in the thickness of said floor element (1, 1'). Floor element according to Claim 3, characterized in that the said reinforcements (6, 7) are arranged in at least two layers (10, 11) parallel to the said plane (XY), including a lower layer (10) and an upper layer ( 11), and in that said lower ply (10) is located between said bridging blocks (5) or below said bridging blocks (5), and said upper ply (11) is located above said building blocks (5). Floor element according to Claim 4, characterized in that the said layers (10, 11) comprise reinforcements (6, 7) extending in at least two intersecting directions (X, Y) of the said plane, and in that the reinforcements (6, 7) of the two layers (10, 11) protrude from the edges (4) of said floor element to ensure mechanical continuity with adjacent floor elements (1, 1') when they are juxtaposed to make a floor (20). Floor element according to any one of the preceding claims, characterized in that the said floor element (1, 1') comprises a formwork spoiler (12) extending the lower face (2) of the said floor element (1, 1' ), on at least two of said edges (4), to create junction zones (ZJ) between adjacent floor elements (1, 1') when they are juxtaposed to produce a floor (20). Floor element according to any one of the preceding claims, characterized in that the said reinforcements (6, 7) consist of rigid bars, the projecting part of which is straight or curved like a hook, and/or of flexible cables, the part of which protruding form a closed or open loop. Floor element according to any one of the preceding claims, characterized in that the said floor element (1, 1') comprises at least one sheath (16), which crosses the said floor element (1, 1') perpendicularly, to delimiting a reservation intended to receive at least one reinforcing bar (22) in line with a load-bearing element (21, 23) of a construction. Floor element according to Claim 8, characterized in that the said floor element (1, 1') comprises around the said sheath (16) a solid support zone (ZP) of structural material (MS), without block of elegance. Floor element according to either of Claims 8 and 9, characterized in that the ribs (8, 9) have a variable width, preferably increasing in the direction of the said sheath (16). Floor element according to any one of the preceding claims, characterized in that the said floor element (1, 1') comprises at least one passage intended to receive a sheath or a technical conduit, the said passage being produced by a groove (18 ) and/or a perforation (19) provided in said building blocks (5) and by a passage sheath (17) in the ribs (8, 9) between the adjacent building blocks (5) concerned. Process for manufacturing a floor (20) from finished prefabricated floor elements (1, 1') according to any one of the preceding claims, characterized in that the steps of said process consist of:
- juxtaposing floor elements (1, 1') on bearing elements (21, 23) of a construction to form the surface of the floor (20) to be manufactured, said floor elements (1, 1') being separated between them by junction zones (ZJ)
- nesting between them the projecting parts of the reinforcements (6, 7) of the adjacent floor elements (1, 1') in the said junction zones (ZJ), and
- pouring a keying material (MC) only in said junction zones (ZJ) to seal said floor elements (1, 1') between them and to said load-bearing elements (21, 23) of the construction to finish said floor (20 ), without a compression slab poured on site, said floor bearing in two intersecting directions (XY). Method according to Claim 12, characterized in that the said junction zones (ZJ) are delimited by formwork spoilers (12) integrated into the said floor elements (1, 1'). Process according to Claim 12, characterized in that it consists in casting a keying material (MC) having a very high resistance to compression in the said junction zones (ZJ), the said material being chosen from the group comprising concretes or high-performance micro-concretes (BHP), very high-performance concretes or micro-concretes (BTHP), ultra-high-performance fiber-reinforced concretes or micro-concretes (BFUHP). Process according to Claim 14, characterized in that it consists in using microconcretes, the aggregates of which have a size less than or equal to 10 mm. Floor (20) obtained by the manufacturing process according to any one of Claims 12 to 15, characterized in that it comprises floor elements (1, 1') according to any one of Claims 1 to 11, the said floor elements (1, 1') being juxtaposed to form the surface of said floor (20), and separated from each other by junction zones (ZJ), in that the projecting parts of the reinforcements (6, 7) of said adjacent floors (1, 1') are nested together in said junction zones (ZJ), and in that only said junction zones (ZJ) are sealed by a keying material (MC) cast in place to seal said floor elements (1, 1') to each other and to said bearing elements of the construction to complete said floor (20), without a compression slab cast on site, said floor bearing in two intersecting directions (XY). Floor according to Claim 16, characterized in that the said junction zones (ZJ) are delimited by formwork spoilers (12) integrated into the said floor elements (1, 1'). Floor according to Claim 16, characterized in that the said keying material (MC) has a very high compressive strength and is chosen from the group comprising high performance concretes or microconcretes (BHP), very high performance concretes or microconcretes (BTHP), ultra-high performance fiber-reinforced concrete or microconcrete (BFUHP). Floor according to Claim 18, characterized in that the microconcretes have aggregates having a size less than or equal to 10 mm.