FR2901297A1 - Shelter structure for swimming pool, has connection unit ensuring connection between column and junction piece made of wood by machining, and between junction piece and rafter, where column and rafter are made of wooden pieces - Google Patents

Abstract

The structure has a curved junction piece (2) extending between a column (1) and a rafter, where the column and the rafter are respectively made of wooden pieces (1a, 1b, 2a, 2b) and the piece (2) is made of wood by machining. The column has an upper groove (8) for receiving a rectilinear flange (9a) of a connection unit (9), where the connection unit ensures a connection between the column and the junction piece, and between the junction piece and the rafter.

Description

a connection between on the one hand the first rectilinear beam and the piece of

  curved junction, and secondly between the curved junction piece and the second rectilinear beam.

  Thus, the first beam serves as a pillar, the second beam serves as a crossbow, while the junction allows for continuity between the pillar and the rafter, very aesthetic, while having a radius of curvature much lower than in the case of laminated wood shelters. These three elements are easily achievable and can be stored flat, which facilitates their transport. In addition, the space near the pillar is usable, even if the pillar is slightly leaning towards the inside of the shelter.

  BRIEF DESCRIPTION OF THE DRAWINGS The invention will be better understood in the light of the description which follows with reference to the figures of the appended drawings in which: FIG. 1 is a front view of a shelter structure element according to a particular embodiment embodiment of the invention; FIG. 2 is an exploded view of part of the structural element of FIG. 1; - Figure 3 is a perspective view of a keystone fitted to the structural element of Figure 1; FIG. 4 is a perspective view of a shelter made with structural elements similar to that of FIG. 1; - Figure 5 is a front view of the shelter of Figure 4 equipped with a pinion; FIG. 6 is a section of one of the elements of a current structure of the shelter of FIG. 4; FIG. 7 is a section of one of the elements of an end structure of the shelter of FIG. 4; FIG. 8 is a front view of a shelter of another type made from the elements of the structure of FIG. 1. DETAILED DESCRIPTION OF THE INVENTION With reference to FIG. a shelter comprising a number of arch-shaped structures and composed here: of a rectangular parallelepipedal beam forming a pillar 1; a curved junction piece 2; a rectangular parallelepipedic beam forming a rafter 3; - a keystone 4; a second crossbow 3; a second junction piece 2; a second pillar 1. In Figure 2 is illustrated the method of manufacture and assembly of the elements of the arch. Each structural element, namely the pillars 1, the curved connecting pieces 2 and the rafters 3 (not shown here) are made of two pieces of wood contiguous, for example la and lb for the pillar 1, 2a and 2b for the piece junction 2, so that their joint plane P (shown in thick line) extends, in use, in a vertical plane forming a plane of symmetry of the hoop. It should be noted that one of the advantages of these wooden pieces lies in their ease of manufacture. In particular, the curved junction piece is a piece cut in a mass of wood by machining, which allows to obtain a much smaller radius of curvature than in laminated wood constructions. The lower limit of the radius of curvature is dictated by the radius of curvature that can elastically take a polycarbonate panel in flexion (175 times its thickness). Each of these structural elements is then machined to present at each end a central mortise. Thus, the abutment 1, bevelled at the bottom, has a lower mortise 5 adapted to receive the rectilinear vertical wing 7 of a fixing foot 6 of the arch to the ground.

  The pillar 1 also has an upper mortise 8 for receiving a first straight wing 9a of a connecting member 9. The connecting member 9 has in the extension of the rectilinear wing 9a a curved wing 9b which is received in a mortise 10 of the connecting piece 2.

  In the same way, the connecting piece 2 comprises another mortise 11 adapted to receive the curved wing of a connecting member in all respects identical to the connecting member 9, the other straight wing is received in the mortise of a crossbowman 3.

  As for the keystone 4, it comprises two ai-the rectilinear 13 which, like the wings of the connecting members 9, are received in the mortises of the rafters 3. The attachment of the assembly is done by means of bolts 12 introduced in orifices formed in the cheeks of the mortises as well as in the wings of the connecting members 9 in the wing 7 of the fixing foot 6 and in the wings 13 of the keystone 4. All the structural elements have the same dryness - tion, so that one obtains a continuous arch with a curve between the pillar and the crossbow, very aesthetic. The curved junction elements 2 because entirely manufactured by machining have a small radius of curvature, for example of the order of 50 centimeters, which would be impossible to achieve with bonded laminated elements. We see in Figure 1 that a person can stand easily to the right of the connecting piece 2, even as the pillar is leaning inwards.

  For example, the pillar, which makes an angle (imposed by the foot 6) of 15 degrees with the vertical, has a height of 180 centimeters. The junction piece 2 has an average radius of 60 centimeters and extends along 70 arc-de-grés. The rafter has a length of 260 centimeters, and is thus at an angle of 5 degrees with the horizontal horizon. This provides a shelter with a wheelbase of 7 meters. Here, the connecting member 9 is constituted by a flat member forming the two wings 9a and 9b, for example stainless steel or pultruded plastic material. The joining member 9 is invisible when the bow is assembled (except by its edge). As for the keystone 4, it comprises a flat element forming the two wings 13, as well as veneers 14 on either side of the flat element making it possible to ensure a structural and visual continuity between the supports of 3. In FIG. 2, it can be seen that the structural elements have on their flanks an outer groove 15 and an inner groove 16, the grooves 15 and 16 being arranged to extend in continuity from one element to the other . Such arches can be used to assemble a shelter such as that illustrated in Figure 4. The shelter comprises a plurality of arches 20, identical to that shown in Figure 1. The shelter is mounted as follows. First of all, the two rafters 3 of a first arch are assembled by means of a keystone 4. The two rafters 3 of a second arch are likewise assembled by means of another keystone 4. installs spacers (not visible here) between the two portions of hoops thus assembled, and sliding roof panels, for example transparent polycarbonate panels 21 of a thickness of 8 millimeters in the outer grooves 15. is installed a butt joint 22 to seal the roof thus formed. The roof panels are for example fixed by being screwed on the spacers. This is done for each span of the shelter. Then the joining pieces 2 are assembled at the ends of the rafters 3. By raising the assembly thus formed on one side, the pillars 1 are assembled to the corresponding junction pieces 2. It is therefore sufficient to raise the other side to assemble the remaining pillars 1.

  Then introduced into the inner grooves 16 a flexible wall 23, for example a polycarbonate panel with a thickness of 2 millimeters, having a length sufficient to extend from the base of the pillars 1 to below the roof panels 21 The flexible walls 23 can slide freely in the inner grooves 16 to be raised, as shown in Figure 4, thus clearing openings between the arches. FIG. 5 illustrates how to make a pinion for the shelter of FIG. 4. For this purpose, the end hoop comprises, as illustrated in FIG. 7, a lower groove 17 made on the underside of the elements. constituting the end hoop (note that the end hoop has lateral grooves 15 and 16, but only on one side, whereas, as shown in Figure 6, the common hoops have lateral grooves 15,16 on both flanks). In the lower groove 17 are introduced vertical panels, for example polycarbonate panels 24 cut form whose lower ends are received in a profile 25 fixed to the ground. Between the panels 24, junction profiles 26 are installed. The structural elements of the invention make it possible to produce other types of shelters.

  In Figure 8 is illustrated a shelter to be attached to a building. The structures of this shelter, which no longer strictly form a hoop, comprise a fixing foot 6, a pillar 1, a connecting piece 2, a raft 3, and finally an anchoring tab 30 to the frame, Like the fastening foot 6. Thus, the structural elements of the invention make it possible to make shelters of various widths, while allowing easy transport of the shelter in disassembled form. Thus, it is estimated that a shelter of about 7 m x 14 m, including 7 arches as illustrated in Figure 1 could be packaged, walls and panels included, in a package of dimensions smaller than 3 mx 2m x 1 m. Such a shelter is then in the form of a kit to be assembled, all of which are easily manipulable and mountable by non-specialists, without special equipment. The invention is not limited to what has just been described, but on the contrary encompasses any variant within the scope defined by the claims. In particular, although distinct structural elements have been illustrated to form common structures or end structures, it will of course be possible to provide identical structural elements, all of which will have external and internal grooves on both flanks. as well as a lower groove. Although it has been stated that the structural elements consist of two pieces of wood joined together, it is possible to manufacture the structural parts differently, in particular by providing monobloc elements.

Claims (10)

  1. Swimming pool shelter structure or the like, comprising at least the following structural elements: a first parallelepipedal straight beam (1); a second parallelepipedal rectilinear beam (3); a curved junction piece (2) extending between the first rectilinear beam and the second rectilinear beam; as well as identical connecting members (9) to ensure a connection between firstly the first straight beam and the curved junction piece, and secondly between the curved junction piece and the second straight beam.   2. Structure according to claim 1, wherein the structural elements are made of two pieces of wood (la, lb; 2a, 2b) contiguous according to a joint plane which extends vertically in use.   3. Structure according to claim 1, wherein the structural elements have machined ends to present mortises (5,8,10,11).   4. Structure according to claim 3, in which the connecting members comprise a flat element (9) comprising a rectilinear wing (9a) and a curved wing (9b) adapted to be received in the mortises of the structural elements.   5. Structure according to claim 3, comprising two second beams (3) and a keystone (4) which comprises two rectilinear wings adapted to be received in the mortises facing the two second beams.   6. Structure according to claim 3, further comprising a fixing foot (6) having a rectilinear wing (7) adapted to be received in a mortise of the first beam.   7. Structure according to one of claims 4 to 6, wherein the wings are fixed to the structural members by bolts (12) extending through the cheeks mortises and wings.   8. Structure according to claim 1, wherein the structural elements comprise at least one groove (16) extending continuously on all the structural elements when they are assembled.   9. Structure according to claim 1, wherein the structural elements comprise at least one lower groove (17) extending continuously on the underside of all the structural elements when they are assembled.   Shelter comprising a structure according to one of the preceding claims.