FR2488314A1 - Prefabricated frame section for naturally ventilating cooling tower - has rhomboid frame with edge rib joint for site fixing without welding - Google Patents

Abstract

The building element frame is quadrilateral in shape and formed from two isosceles triangles joined by a common base. Each element has a concave face and an opposite convex face symmetrical with respect to a bisector plane passing through the opposed summits of the two isosceles triangles. The element has, along each edge of one of its faces, a projecting rib with holes for bolts or screws for fixing adjacent elements, while a diagonal projecting rib extends between the edge ribs bracing the element.

Description

 The present invention relates to prefabricated elements for the realization of constructions of the tower or similar type, in particular for atmospheric refrigerant, as well as constructions of the aforementioned type made with such prefabricated elements.

 The two most commonly used types of atmospheric refrigerants are natural draft refrigerants in which ventilation is provided by natural draft in a chimney tower and forced ventilation refrigerants in which suction or blower fans provide ventilation. high maintenance cost of mechanical parts and the rapidly increasing cost of energy required to drive fans, natural draft refrigerants, in the range of small units, can again become economical compared to forced ventilation refrigerants provided that the necessary construction of atmospheric refrigerants with natural draft solutions whose cost of investment would be very close to that of refrigerants with forced ventilation in concrete and which would however have a sufficient lifespan.

 Such requirements therefore exclude concrete constructions poured on site or constructions in masonry and reinforced keyboards.

 A known solution in an attempt to solve this problem consists in making the towers of natural draft refrigerants by means of prefabricated concrete elements of triangular shape, which are arranged in rows su perposed according to the height of the tower, each row comprising a succession adjacent triangular prefabricated elements alternately arranged point up and point down.

 However, this solution is not satisfactory because, to ensure the desired resistance of the tower, it is necessary to provide at the angles of the triangular elements of the reinforcements intended to be welded, which poses serious corrosion problems aggravated by the complication of the joints that must be provided between the elements. Finally, the installation of these triangular elements is tricky because, once the establishment of a row of triangular elements is completed, it is necessary to use templates or other similar means to set up an isolated triangular element. above the previously completed row.

 The invention aims to eliminate these drawbacks by means of a prefabricated element for the production of tower or similar constructions, which is simple to manufacture and install, while ensuring the desired rigidity of the construction, without resorting to delicate operations such as welding or the like.

For this purpose, the invention relates to a prefabricated element for the realization of constructions of the tower type or the like, in particular for atmospheric refrigerant.
that, which presents in planar projection the form of a quadrilateral consisting of two isosceles triangles juxtaposed by their bases and has a concave face and an opposite convex face which are symmetrical with respect to a bisector plane passing through the opposite vertices of the two triangles isosceles, said element having, on one of these faces, along each of its edges, a projecting rib for its attachment to an adjacent prefabricated element.

 According to a characteristic of the invention, said element comprises on said face a projecting diagonal rib extending between the ribs of the edge of the element, along the bases of said isosceles triangles.

 According to another characteristic of the invention, each part of the quadrilateral having in planar projection the shape of an isosceles triangle consists of two planar panels forming a dihedron whose edge is disposed in said bisector plane.

 To achieve the aforementioned aims, the invention also relates to a prefabricated element for the realization of constructions of the tower or similar type, comprising two planar panels forming a dihedron having in plan the shape of an isosceles triangle and, on one of its faces, along each of its edges, a projecting rib for its attachment to an adjacent prefabricated element.

 The subject of the invention is also a construction of the tower or similar type, in particular for atmospheric refrigerant, the wall of which consists at least in part of prefabricated elements assembled two by two to each other, this construction comprising, at least at its lower periphery, a row of prefabricated elements of triangular shape arranged point up and side by side, so as to form between them spaces of triangular shape and, depending on the height of the construction, successive rows of prefabricated elements in shape of quadrilaterals, as defined above, which are arranged such that each isosceles triangle-shaped part of each quadrilateral element of a row is housed in a triangle-shaped space formed between two adjacent elements of the lower row and that the other isosceles triangle-shaped part of said quadrilateral element is housed in a triangle-shaped space formed between two adjacent elements of the upper row, each quadrilateral element being fixed to two adjacent prefabricated elements of the lower row and to two adjacent prefabricated elements of the upper row.

 Thanks to this arrangement, once the triangular elements provided at the lower periphery of the construction are in place, the installation of quadrilateral elements is extremely easy, because they each get stuck in the space in the shape of a triangle. formed between two adjacent elements of the lower row, after which they can be fixed to the latter very easily, for example by means of fixing devices of the bolt-nut type extending through holes made in the ribs formed along edges of the elements. A connection is thus made step by step between the elements in the form of a quadrilateral of the different rows which, once all the elements have been put in place, ensures very good resistance of the construction.

Other characteristics and advantages of the invention will emerge from the description which follows, made with reference to the appended drawings given solely by way of example and in which
- Fig.l is a schematic perspective view of a frustoconical tower terminated by a cylindrical crown and produced by means of prefabricated elements according to the invention;
- Fig.2 is a perspective view of a prefabricated element, used in the frustoconical part of the tower of Fig.l;
- Fig.3 is a sectional view along line 3-3 of Fig.2;
- Fig.4 is a schematic perspective view of a prefabricated element used to ensure the junction between the frustoconical and cylindrical parts of the tower of Fig.l;
- Fig.5 is a sectional view along line 5-5 of Fig.4; and
- Fig.6 is a sectional view along line 6-6 of Fig.4.

 Referring first to Fig.l, the tower 1 shown comprises at its lower periphery a row of prefabricated elements El having in planar projection a triangular shape and arranged pointed up and side by side so as to provide between them triangular spaces. These elements El form a first lower row RO which is surmounted and nested with a second row R1 of prefabricated elements E2 which, themselves, have in planar projection the form of a quadrilateral consisting of two isosceles triangles juxtaposed by their base. Thus, the lower isosceles triangle-shaped part of each element E2 of row R1 is housed and wedged in a triangle-shaped space formed between two adjacent elements El of the lower row RO. Row R1 is itself nested with a row R2 which surmounts it and also consists of elements E2 in the form of a quadrilateral whose lower triangle is housed and wedged between the upper triangles of two adjacent elements E2 in the form of a quadrilateral in the row R1.

As shown in Fig.l, tower 1 thus has four rows R1, R2, R3 and R4 of elements E2 superimposed and nested.

 Between the triangle-shaped spaces formed between the quadrilateral elements E2 of the upper row R4 are arranged other elements E3 having in planar projection the form of a quadrilateral and which are shown in more detail in FIGS. 5 and 6. Finally, tower 1 is completed by a row R5 of elements El which are housed in the triangle-shaped spaces formed between the adjacent elements E3.

 As shown in Fig. 2 and 3, the element E2 comprises two planar panels 2 and 3 forming a dihedral as well as peripheral ribs 4 projecting from one of the faces of the panels 2 and 3. Preferably, the panels 2 and 3 are made of cement reinforced with glass fibers and the ribs 4 comprise a rib 4a of concrete, for example of reinforced concrete, coated with the material of which the panels 2 and 3 are made. Such a dihedral structure having in planar projection the shape of an isosceles triangle constitutes the basic geometrical configuration from which the elements E1, E2 and E3 are made.

 Thus, in ia Fig.2, the element E2 comprises two parts D1 and D2 having the above configuration, which are juxtaposed along the bases of the two isosceles triangles along which is formed a diagonal rib projecting 5 s' extending, on the same side of the walls 2 and 3 as the ribs 4, between the latter.

The rib 5 is constituted identically to the ribs 4 and, of course, the corresponding panels 2 and 3 of the parts D1 and D2 of the element E2 form a single piece. In other words, the element E2 has in planar projection the form of a quadrilateral consisting of two isosceles triangles (parts and D2) juxtaposed by their bases and has a concave face F1 and a convex face F2 which are each vertical by relation to a bisector plane passing through the opposite vertices S1 and S2 of the two isosceles triangles and containing the aligned edges A of the two parts or dihedrons D1 and D2 of the element E2.The element El differs from the element E2 in that 'It consists of a single part or dihedral D1 and D2, so that it presents well in planar projection the aforementioned triangular shape. Of course, the element El has a rib 4, 5 along each of its edges.

Finally, the element E3 represented in FIGS. 4 to 6 differs from the element E2 by the fact that the edges Al and A2 of the dihedrons or parts D1 and D2 respectively are not aligned and form an obtuse angle between them, each edge a dihedral extending in the bisector plane of the two dihedrons on the side of the convexity of the other dihedral. As shown in Figs 5 and 6, it follows that the angle p of the dihedral D1 is different from the angle r of the dihedral D2. Thus, by choosing the angles,, and r, the elements E3 make it possible to ensure the junction between the cylindrical part and the frustoconical part of the tower 1. As indicated above, the triangular spaces formed between the upper dihedrons
elements E3 are filled with elements El of triangular shape.

 It will be understood that by triangular shape and quadrilateral shape is meant the shape which the prefabricated elements according to the invention have when they are seen in planar projection. I1 is the same for the isosceles triangle shape of the dihedrons D1 and D2.

 Furthermore, it should be noted that, in the case of a frustoconical wall as shown in Fig.l, the perimeter of the tower decreases when going from one row of elements to an upper row. Consequently, the elements E2 do not have the same dimension from one row to another and at least one of their diagonal dimensions decreases from one row of elements E2 to the upper row. Thus, as shown in Fig.l, the elements E2 can have a constant height (distance S1 S2) and a width which decreases from one row to the upper row. However, both the height and the width of the elements E2 can differ from one row to another.

 Finally, in the case of a cylindrical wall, the elements may have in planar projection a shape of a losahge, so as to use elements which are all identical.

To mount the tower 1 in Fig.l, first of all put the elements El in place using templates or other suitable similar means. The elements E2 are then placed, for example by means of a crane, between the adjacent elements El. Thanks to the triangular shape of their lower part D2, the elements E2 are wedged between the neighboring elements El. They are then fixed to the latter by means of fixing devices of the bolt-nut type (not shown) which are engaged through holes 6 formed in the ribs 4 formed along the edges of the adjacent elements.
El, E2.We then continue these operations of setting up and fixing with the elements E2, then the elements E3, and finally again with elements El of appropriate size to complete the part or cylindrical crown corresponding to the row upper R5. Of course, all of the elements El, E2 and E3 have been dimensioned beforehand so as to fit perfectly with each other at the different levels of the tower at which they are called to be installed.

 The construction method which has just been described is particularly suitable for the production of small atmospheric refrigerants with natural draft having heights of the order of approximately 35 to 55 m. Of course, the invention is not limited to the embodiments described above and numerous modifications can be made without departing from its scope.

Claims (15)

 1. Prefabricated element for the realization of constructions of the tower or similar type, in particular for atmospheric refrigerant, characterized in that it presents in planar projection the shape of a quadrilateral consisting of two isosceles triangles juxtaposed by their bases and has a concave face and an opposite convex face which are symmetrical in relation to a bisector plane passing through the opposite vertices (S1, S2) of the two isosceles triangles, said element (E2, E3) having on one of its faces, along each of its edges, a rib (4) projecting for attachment to an adjacent prefabricated element (E1, E2, E3).  2. Element according to claim 1, characterized in that it comprises on said face a diagonal rib (5) projecting extending between the ribs (4) of the edge of the element (E2, E3), along the bases of said isosceles triangles.  3. Element according to any one of claims 1 and 2, characterized in that each part of the quadrilateral having in planar projection the shape of an isosceles triangle consists of two planar panels (2,3) forming a dihedral (D1, D2) whose edge is disposed in said bisector plane.  4. Element according to claim 3, characterized in that the edges of the two dihedrons (D1, D2) of said element (E2) are aligned.  5. Element according to claim 3, characterized in that the edges of the two dihedrons (D1, D2) of said element (E3) form an obtuse angle between them, each edge of a dihedron (D1) extending in said bisector plane on the convexity side of the other dihedral (D2).  6. Prefabricated element for the realization of constructions of the tower or similar type, characterized in that said element (El) comprises two flat panels (2,3) forming a dihedral presenting in planar projection the shape of an isosceles triangle and, on one of its faces, along each of its edges, a rib (4) projecting for its attachment to an adjacent prefabricated element (E2, E3).  7. Prefabricated element according to any one of claims 3 to 6, characterized in that said panels (2,3) are made of cement reinforced with fiberglass and said ribs (4,5) are made of concrete.  8. Element according to claim 7, characterized in that the ribs (4,5) of concrete are coated in the cement reinforced with fiberglass constituting said panels (2,3).  9. Construction of the tower or similar type, in particular for atmospheric refrigerant, the wall of which consists at least in part of prefabricated elements assembled in pairs to each other, characterized in that it comprises, at least at its lower periphery , a row (RO) of prefabricated elements (El) of triangular shape arranged pointed at the top and side by side, so as to form spaces of triangular shape between them, and, depending on the height of the construction, rows (R1 , R2, R3, R4) successive prefabricated elements (E2, E3) according to any one of claims 1 to 5, arranged such that a part in the form of an isosceles triangle of each element (E2, E3) d one row is housed in a triangle-shaped space formed between two adjacent elements (E1, E2) of the lower row and that the other isosceles triangle-shaped part of said element is housed in a triangle-shaped space formed between two adjacent elements of the upper row, each element (E2, E3) in the form of a quadrilateral being fixed to two adjacent prefabricated elements of the lower row and to two adjacent prefabricated elements of the upper row.  10. Construction according to claim 9, characterized in that it also comprises at its upper part prefabricated elements (El) of triangular shape filling the triangle-shaped spaces formed between the elements of the upper row of prefabricated elements ( E3) in the form of a quadrilateral.  11. Construction according to claim 10, ca acterized in that said prefabricated elements in the shape of a triangle are constituted by elements (El) as defined in claim 6.  12. Construction according to any one of claims 9 to 11, characterized in that, in the case od said wall has a cylindrical shape, said elements in the form of a quadrilateral (E2) are prefabricated elements as defined in claim 4 and having a diamond shape.  13. Construction according to any one of claims 9 to 11, characterized in that, in the case where said wall has a frustoconical shape, said elements in the form of a quadrilateral (E2) are elements as defined in claim 4 and of which at least one of the diagonal dimensions decreases from one row of elements to the upper row.  14. Construction according to any one of claims 9 to 13, characterized in that, in the case where the wall comprises at least a frustoconical part and a cylindrical part, prefabricated elements (E3) as defined in claim 5 are arranged at the junction between said frustoconical and cylindrical parts.  15. Construction according to any one of claims 9 to 14, characterized in that said prefabricated elements (E1, E2, E3) are fixed two by two to each other by means of fixing devices of the bolt-nut type. extending through holes (6) in the ribs formed along the edges of said elements.