JP2015514169A - Improved modular assembly for manufacturing floors - Google Patents

Abstract

The present invention relates to an assembly comprising a plurality of support modules (10) which are combined together to form a lower flat support. The lower flat support can be inserted between the floor and the modular upper cover in the vertical direction. The modular top cover has a plurality of cover elements (102) that are affixed to the top surface (12) of the support module (10). Each modular cover element (102) used positive means (118, 50) which cooperate in a complementary shape with the upper surface (12) of the support module (10) in the vertical direction (V). Affixed by an elastic interlocking structure.

Description

  The present invention relates to an assembly for producing a floor covering. The present invention complements in particular the modular support structure of the floor covering described and illustrated in FR 2955601A.

  This document describes and illustrates a modular support structure for floor coverings. The floor covering has a plurality of adjacent modular covering elements such as slabs and boards. The modular covering element is fixed to the upper surface of the lower flat support arranged between the modular element constituting the floor and the ground.

  This document proposes a method of fixing a plurality of modular covering elements themselves constituting a floor covering. That is, elements such as screws and claws are fixed to the studs provided on the plate of the lower modular support structure of the floor disposed between the ground and the floor.

  The present invention relates to an assembly for producing a floor covering. The assembly is a plate having a polygonal outer shape, having a flat and horizontal upper surface, and a plurality of supports that are combined to form a flat support that can be placed between the floor and the upper covering material in the vertical direction. A lower modular support structure including a module, and a modular upper covering material including a plurality of adjacent modular covering elements, such as slabs and boards, fixed to the upper surface of the support module.

  An object of the present invention is to propose a novel fastening means for a modular covering element that eliminates the need for screws and claws when mounted, assembled and fixed.

For this purpose, the present invention proposes the assembly described below. That is,
Each modular covering element is fastened to the upper surface of the support module in the vertical direction by snap-fitting using fastening means that cooperate in a complementary shape.

  According to this design, for example, modular covering elements such as slabs and boards can be positioned, assembled and arranged by simple snap fitting, eliminating the need for special fixing tools such as screwdrivers and screws. be able to.

Other features of the present invention include:
The fastening means is formed on the lower surface of each modular covering element and has at least one fixed rail having two oppositely oriented depth hook grooves and is formed on the upper surface of each support module so as to face each other. A plurality of elastically deformable hooks, wherein the pair of hooks are aligned in the depth direction and when the modular covering element is secured to the upper surface of the support module; Two opposing hooks constituting the pair of hooks are arranged to be received in two oppositely facing grooves of the fixed rail, respectively.
The cross-sectional shape of each fixed rail is a dovetail shape.
A plurality of fixed rails are provided in parallel at a constant lateral pitch on the lower surface of each modular covering element, and a plurality of pairs of hooks aligned in the depth direction are provided on the upper surface of each support module. Arranged in rows, and a plurality of parallel rows are arranged at the same lateral pitch,
Each stationary rail extends over the entire length of the modular covering element,
A plurality of positioning pins are provided on the upper surface of the support module,
The plurality of positioning pins are formed so as to float from the upper surface of the support module, and cooperate with positioning ribs protruding downward from the lower surface of the modular covering element.
Each modular covering element has a certain polygonal profile, in particular a rectangle,
Each fixed rail extends parallel to the longitudinal direction of the outer shape of the modular covering element,
The maximum length of each modular covering element is greater than the maximum length of the support module;
Each support module and / or each modular covering element is a single casting, in particular of a resin material.

  Other features and advantages of the present invention will be derived from the following detailed description with reference to the accompanying drawings for better understanding.

FIG. 1 is a perspective view of a plate belonging to the lower modular support structure. FIG. 2 is an elevational sectional view showing the opposing lower plate and upper module elements with complementary assembly means. The state before assembly is shown. FIG. 3 is a view similar to FIG. 2 and shows the state after assembly of the two elements. FIG. 4 is a schematic perspective view of the assembly in the embodiment of the present invention.

  In the following description, the same or similar elements are denoted by the same reference numerals.

  In order to better understand the specification and the claims, by way of example, vertical, horizontal, depth direction, and horizontal direction are used in correspondence with the trihedron composed of gravity on the earth and L, V, T shown in the drawing.

  The lower modular support structure 100 corresponds to that described in FR2955601A.

  The lower structure 100 includes a plurality of modules 10, and the lower modular support structure is configured by assembling the plurality of modules 10.

  Each module 10 is a plate having a square outer shape, and its main surface is horizontal during use. That is, the main surface is parallel to the ground on which the main surface is installed.

  Each plate 10 has a horizontal flat upper surface 12 and an opposite, horizontal flat lower surface 14 that rests on the ground.

  Combining the horizontal flat upper surface 12 of the plate 10 constitutes the flat horizontal upper surface 12 of the lower modular support structure in the present invention.

  A flat support is configured by combining the modules 10. The flat support has a horizontal flat upper surface 12. The flat support is disposed between the ground and the upper covering material constituting the floor in the vertical direction.

  By way of example only, each modular element 102 of the upper covering material is a slab or board having a rectangular outer shape, and extends so as to have a maximum length in the depth direction L.

  Each element 102 is formed as a board. A groove 105 extending in the depth direction is formed on the upper surface 104 of each element 102.

  The board 102 is larger than the modular element 10 in the longitudinal direction. In particular, the board 102 has such a length as to simultaneously cover a plurality of adjacent lower modules 10 in the depth direction (see FIG. 4).

  Each board 102 has a lower horizontal surface 106. Two opposing side ribs 110 extend from the lower horizontal surface 106 on either side of the side edge 108 of the board 102.

  Each rib 110 has an outer vertical side 114 at the edge 108. Each rib 110 has a lower horizontal surface 112. The lower horizontal surface 112 can be supported by the horizontal upper surface 12 of the lower module 10 with the board 102 assembled and secured to the lower modular structure.

  Finally, each lateral rib 110 has an inclined inner depth surface 116. The function of the inner depth surface 116 will be described later.

  At the center, that is, at a point substantially half the distance between the two ribs 110, the board 102 has a center fixed rail 118.

  The rail 118 has a dovetail shape with two oppositely facing side grooves 120, particularly in an elevational cross-sectional view and as is apparent from FIGS.

  The fixed rail 118 similarly has a lower flat surface 122. The lower plane 122 is on the same plane as the lower horizontal plane 112 of the rib 110. The lower plane 122 is supported vertically on the upper surface 12 of the modular element 10 with the board 102 combined on the modular structure 100.

  The vertical downward support of the board or slab 102 by the flat surfaces 112, 122 that are horizontal in the depth direction provides a very stable support on the horizontal upper surface 12 of the lower modular structure.

  The lower horizontal plane 122 in the depth direction of the fixed rail 118 is connected to each of the opposite grooves 120 extending in the depth direction via facets 124 extending in the depth direction inclined in a bevel shape. The functional aspect will be described later.

  The side ribs 110 and the central fixed rail 118 are merely examples, but extend over the entire length of the board 102 and have a continuous cross-sectional shape in the depth direction L.

  For illustrative purposes only, the width of the board 102 is such that its lower surface has exactly one fixed rail 118. The board may have several parallel fixed rails distributed laterally at a defined pitch below the lower surface 106 without departing from the scope of the present invention.

  The fixing complement means fixes the slab or board 102 to the lower modular structure 100 constituted by the assembly of the lower modules 10 by a complementary shape and snap fitting. The fixed rail 118 constitutes a part of the fixing complement means.

  For this purpose, the complementary means of the lower modular structure 100 have a plurality of elastically deformable hooks formed on the upper surface 12 of each modular support element 10.

  More precisely, each modular support element 10 has a plurality of pairs of hooks 50 facing each other. The hook 50 extends so as to protrude vertically from the horizontal plane 12.

  Each hook 50 has an elastically deformable blade 52. The blade 52 extends as a whole in the vertical direction and in the depth direction, and a rib 56 constituting a hook is formed at the upper free end thereof. The blade 52 can be received in the complementary groove 120 in the assembled state.

  The blade 52 constitutes a hook with ribs 56 and is elastically deformable, thereby constituting a pair of elastically deformable hooks. When snapping is performed by applying vertical pressure and the rail 118 is guided between a plurality of pairs of hooks 50 aligned in the depth direction, the beveled facet 124 of the rail 118 and the bevel of the hook 50. The elastic deformation is performed in cooperation with the upper surface 58 of the shape.

  Each blade 52 is connected to the skeleton of the module 10 via a lateral and vertical reinforcing groove 54 so that the hook 50 is not easily broken.

  Naturally, the relative size and position of the two hooks 50 constituting the pair of hooks are complementary to the width of the fixed rail 118 having the two grooves 120 opposite to each other.

  As is apparent from FIG. 1, each upper surface 12 has a plurality of pairs of hooks 50 aligned in the depth direction. These are arranged at a lateral pitch that is the same as the lateral pitch of the fixed rails so that the module 10 can accept a slab or board 102 having several parallel fixed rails. Similarly, these are the dimensions and position of the fixed rails so that the module 10 can be received by multiple pairs of hooks aligned in the depth direction, with two parallel fixed rails 118 each belonging to two adjacent boards 102. Are arranged at a lateral pitch equal to the lateral pitch of the fixed rails so that several slabs or adjacent boards can be received.

  In addition, a plurality of positioning pins 60 are provided on the upper surface of each support module 10 for easier positioning and for holding the board 102 in the lower modular structure 100 in an assembled state. . The plurality of positioning pins 60 are formed so as to float from the horizontal upper surface 12.

  Each pin 60 has a laterally inclined outer side surface 62 on the side. The degree of inclination of the outer side surface 62 corresponds to that of the inclined inner side surface 116 of the rib 110 of the board or slab 102.

  As is apparent from FIG. 3, the inclined outer side surface 62 of the pin 60 cooperates with the inner inclined surface 116 of the rib 110 in the assembled state.

  Therefore, all assembly and high-precision positioning of the floor covering constituted by the adjacent upper modular elements 102 is performed by simple alignment and snap fitting, i.e. requiring no special tools. Absent.

  If necessary, additionally, as pointed out in FR 2955601A, for this purpose, after positioning and assembling, screws and pawls are attached to the stud 30 of the lower member 10 plate 5, or the fixed rail 118 and stud. Full fixation may be performed by engaging the core of material comprising 30. Also, for this purpose, complete fixing may be performed in the middle between a pair of opposing hooks 50, i.e. on the lower surface 122 of the fixing rail 118.

Claims (9)

An assembly for producing a floor covering,
A plurality of supports having a polygonal outer shape and having a flat and horizontal upper surface (12), which, when combined, form a flat support that can be placed between a floor and an upper covering in the vertical direction. A lower modular support structure (100) with a module (10);
A modular upper covering comprising a plurality of adjacent modular covering elements (102), such as slabs or boards, fixed to the upper surface (12) of the support module (10);
With
Each modular covering element (102) is attached to the upper surface of the support module (10) by snap-fitting using fastening means (118, 50) that cooperate in a complementary shape in the vertical direction (V). Fixed,
Assembly. An assembly according to the immediately preceding claim,
The fastening means (118, 50)
At least one fixed rail (118) formed on the lower surface (106) of each modular covering element (102) and having two opposing depth hook grooves (120);
A plurality of elastically deformable hooks (50) formed on the upper surface (12) of each support module (10) and arranged in pairs to face each other;
With
The paired hooks (50) are aligned in the depth direction and the paired hooks (50) when the modular covering element (102) is secured to the top surface (12) of the support module (10). The two opposing hooks constituting the two are arranged to be received in the two oppositely facing grooves (120) of the fixed rail (118), respectively.
Assembly. An assembly according to the immediately preceding claim,
The cross-sectional shape of each fixed rail (118) is a dovetail shape,
Assembly. The assembly according to claim 2,
A plurality of fixed rails (118) are provided in parallel at a constant lateral pitch on the lower surface (106) of each modular covering element (102),
On the upper surface (12) of each support module (10), pairs of the hooks (50) aligned in the depth direction are arranged in a plurality of parallel rows, and the plurality of parallel rows are the same. Arranged at a horizontal pitch of
Assembly. The assembly according to any one of claims 2 to 4,
Each fixed rail (118) extends over the entire length of the modular covering element (102),
Assembly. An assembly according to any of the above,
A plurality of positioning pins (60) are provided on the upper surface (12) of the support module (10),
The plurality of positioning pins (60) are formed so as to float from the upper surface (12) of the support module (10), and project downward from the lower surface (106) of the modular covering element (102). Cooperating with positioning ribs (110, 116);
Assembly. The assembly according to any one of claims 2 to 6,
Each modular covering element (102) has a polygonal outer shape, in particular a rectangle,
Each fixed rail (118) extends parallel to the longitudinal direction of the contour of the modular covering element (102),
Assembly. An assembly according to the immediately preceding claim,
The maximum length of each modular covering element (102) is greater than the maximum length of the support module (10);
Assembly. An assembly according to any of the above,
Each support module (10) and / or each modular covering element (102) is a single casting, in particular of a resin material,
Assembly.

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