FR2862676A1 - Rainwater evacuation device, has liquid guiding device with plate having peripheral zone with evacuation openings, and two liquid guiding units provided for each opening, where each unit has radial branch and circumferential branch - Google Patents

Abstract

The device has an evacuation tube (6) forming an inlet (12) for evacuation, a collector tub (8) and a liquid guiding device (10). The device (10) has a plate (20) to cover the inlet, and having a peripheral zone. Evacuation openings (26) are arranged in the zone. Two liquid guiding units (40) are provided for each opening in the annular space between the plate and a flange. Each unit has a radial branch and a circumferential branch.

Description

to manufacture and have a significant cost, particularly because of

  many pieces of which they are made up.

  From this state of the art, the object of the invention is to propose a liquid evacuation device that has a large liquid flow rate for given dimensions.

  For this purpose the invention relates to an evacuation device of the aforementioned type, characterized in that the cover plate comprises a peripheral zone surrounding the central zone and extending opposite the collar in which zone device is provided at least one through opening of liquid discharge defining an edge, in that for each opening at least one liquid guiding member is provided in the annular space between the cover plate and the flange, the organ guide member extending along a portion of the edge and comprising a radial branch which extends substantially radially with respect to the axis and a circumferential branch which extends the radial branch and which extends substantially circumferentially with respect to the 'axis.

  According to particular embodiments, the assembly according to the invention comprises one or more of the following characteristics: for each opening two liquid guiding members are provided in the annular space between the cover plate and the collar and extend along a portion of the edge, on each circumferential side of the discharge opening, and each guide member comprises a radial branch extending substantially radially and a circumferential branch extending the radial branch e extending substantially circumferentially with respect to the axis XX; the circumferential branch of the or each guide member extends the radial branch of the radially inner side; the length of the radial branch is substantially identical to the length of the circumferential branch; the guide members extend from the surface of the cover plate to the surface of the collar; the discharge opening is of oblong shape whose circumferential extent is greater than the radial extent; the cover plate comprises at least two, preferably three, discharge openings; - The cover plate comprises filtering means disposed on the side of the plate opposite the collecting tray, and extending over the or each discharge opening; the filtering means comprise ribs extending radially with respect to the axis; - The ribs have a radial width which is greater than a radial width of the discharge opening, in particular between 1.5 and 2.5 times the radial width of this opening; - The ribs have an axial height which is greater than an axial height of the liquid guiding members, in particular between 1.5 and 4 times this height; the ribs comprise cavities open towards the discharge opening, in particular circumferentially through therethroughs; the ribs comprise lateral ribs, which are ribs located at the circumferential ends of the discharge openings, and the lateral ribs comprise cells whose axial height is less than the axial height of the other cells; - Between two ends of discharge opening extends a radial passage of unfiltered liquid to allow a flow of liquid to the central zone; and - the liquid guiding device and the or each liquid guiding member are made in one piece, preferably in one piece and in particular by molding.

  The invention further relates to a guiding device for an evacuation device as defined above.

  The invention will be better understood on reading the description which follows, given solely by way of example and with reference to the appended drawings, in which: FIG. 1 is a broken axial sectional view along line II; of Figure 2 a device 20 for discharging water according to the invention; - Figure 2 is a top view of the discharge device according to the invention; - Figure 3 is a bottom view of the liquid guiding device of the device according to the invention; and - Figure 4 is a perspective view of the guiding device of Figure 3.

  In Figure 1 is shown a liquid discharging device, designated by the general reference 2.

  The device 2 is installed on a roof 4 horizontal or low slope of a building, and serves to evacuate rainwater accumulating on the roof, when they exceed a first level Ni.

  The device 2 comprises a discharge pipe 6, a collecting tank 8 and a liquid guiding device 10.

  The discharge pipe 6 extends vertically, along a vertical axis X-X, and defines, at its upper end, a discharge outlet 12 circular diameter Dl.

  In what follows, the expressions axial, radial, and circumferential will be used with respect to the axis X-X.

  The collecting tray 8 comprises a bowl 14. The discharge inlet 12 opens at the center of the bottom of the bowl 14. A collar 16 is connected to the upper edge of the bowl 14. The collar 16 extends at the level N1 and forms an annular surface having an inner diameter D2 and an outer diameter D3.

  Three threaded rods 18 project on the surface of the flange 16, on the opposite side to the pipe 6.

  The pipe 6 and the collecting tank 8 are of revolution about the axis X-X.

  The guide device 10 serves to guide the water into the exhaust inlet 12 without inclusion of air and to retain impurities, such as leaves.

  The guide device 10 comprises a circular flat cover plate 20. It extends perpendicularly to the X-X axis at a level N2. The diameter of the plate 20 is identical to the outside diameter D3 of the flange 16. The plate 20 is spaced from the flange 16 by a distance d. The distance d is the filtering distance, which is for example 15 mm. Thus, objects whose smallest dimension is greater than d are retained. The edges of the plate 20 and the flange 16 delimit between them a flow mouth 21 extending circumferentially around the axis X-X.

  As shown in FIG. 2, the plate 20 consists of a central zone 22 extending vis-à-vis the discharge inlet 12 and a peripheral zone 24 surrounding the central zone 22. Central 22 is formed of a solid wall and has a diameter which is equal to the diameter D2.

  The peripheral zone 24 is provided with three through evacuation openings 26 as well as three fixing holes 28 (FIG. 3).

  The discharge openings 26 are entirely in front of the flange 16 and have an oblong shape extending along the periphery of the plate 20. In axial view, each opening has a circular ring sectional shape. Each opening has a constant width and has an arcuate shape centered on the X-X axis. The openings 26 are evenly distributed about the axis X-X and each opening extends over the same angular range a, which is 90. The discharge openings 26 preferably extend in total over an angular range of between 240 and 300. The width L1 measured radially of the opening 26 is smaller than the radial width D32-D2 of the flange 16. The notch noted 30 of each opening 26 consists of two radial end sections 32, 34 and two outer circumferential sections. 36 and inside 38.

  Liquid guiding protrusions 40 protrude from the face of the plate 20 facing the tray 8. They extend as far as the flange 16 (FIG. 1) through the mouth 21. As illustrated in FIG. each opening 26 is provided with two of these projections 40. Each projection 40 comprises a radial branch 44, extending along the corresponding radial end section 32, 34, and a circumferential branch 48, extending along of a portion of the inner circumferential circumference portion 38. The circumferential branch 48 is adjacent to the radial branch 44. The length of the two branches 44, 48 is substantially identical so that each projection 40 has, in axial view, a shape The guiding device 10 further comprises filtering means adapted to filter the liquid flowing in the openings 26. As shown in FIGS. 2 and 4, these filtering means comprise a plurality of ribs 50a. diales arranged on the plate 20 and protruding axially on the opposite side to the tray 8.

  The ribs 50 extend over the discharge openings 26 and at a mutual distance d at their radially outer ends. This distance d is therefore equal to the filtering distance. The radial width L2 of the ribs 50 is preferably between 1.5 times and 2.5 times the radial width L1 of the discharge opening 26. In this case, the radial width L2 is substantially twice the width L1 .

  The axial height H of each rib 50 is between 1.5 times and 4 times the axial height d of the projections 40. The axial upper end of the ribs 50 defines a level N3.

  Each rib 50 is provided with a cell 52 axially open towards the discharge opening and 25 circumferentially through.

  The ribs 50 of each opening 26 comprise two lateral ribs 50A, which are arranged at the circumferential end of each opening 26. The height of the cell 52A of each of these ribs 50A is equal to d, therefore identical to the distance of filtering.

  The height of the cells 52A of these lateral ribs is less than the height of the cells 52 of the ribs 50 located between the lateral ribs 50A.

  The cells 52, 52A make it possible to reduce the quantity of material necessary for the manufacture of the guiding device 10.

  The lateral ribs 52A of two adjacent openings 26 are disposed at a mutual distance greater than the filtering distance d. The guiding device thus forms a radial passage of liquid 54 without filtering means. When the liquid level is located between the levels N2 and N3, unfiltered liquid can flow into the central zone 22 and is filtered by the radially inner portion of the ribs 50.

  The device 2 also comprises three nuts 60 screwed onto the rods 18 and clamping the guiding device against the flange 16.

  The guide device 10 is manufactured by molding in one piece.

  The evacuation device is manufactured in the following manner: The guiding device 10 is molded in one piece.

  The collecting pan 8 is welded to the upper end of the discharge pipe 6.

  Then, the guiding device 10 is placed on the flange 16 and fixed on it by the nuts 60.

  It is found that the assembly 2 is easy and quick to assemble.

  The evacuation assembly operates as follows.

  The ribs 50 form a large filtration area.

  When the water level is located above the flange 16 and below the plate 20, therefore between the level N1 and the level N2, the water flows laminarly between the flange 16 and the plate 20 and is discharged through the inlet 12. In this operating condition, the discharge openings 26 and the ribs 50 are not in contact with water.

  When the water level is located above the plate 20, but below the upper end of the ribs 50, so between the levels N2 and N3, a first portion E1 of the water flows radially between the collar 16 and a plate 20. A second portion E2 flows radially inwardly through the interstices between the ribs 50. A third portion E3 flows radially inwardly through the passages 54 and radially outwardly through through the interstices between the ribs 50.

  After passing the interstices between the ribs 50, the water flows axially through the discharge openings 26 and is deflected radially towards the X-X axis (arrow E).

  In the case where the water level is higher than the level E3, the side of each rib 50 situated opposite the plate 20 also contributes to the filtering.

  The radial branches 44 of the projections 40 prevent the generation of a vortex, while the circumferential branches 48 lead to a uniform distribution of the water pressure on the plate 20. As a result, the water flows laminarly between the plate 20 and the collar 16 and does not cause air in the pipe 6. The device 2 therefore has a so-called siphoid operation.

  The device 2 according to the invention is easy to manufacture and assemble thanks to the one-piece manufacture of the guiding device 10. In addition, the device 2 makes it possible to achieve a high flow rate of water for a given diameter of the pipe due to the laminar flow of the liquid and the large filtering surface.

  The arrangement of the ribs 50 further facilitates the cleaning of the device.

  Furthermore, the liquid guiding device 10 according to the invention makes it possible to use pipes of different diameters while keeping good evacuation properties.

Claims (16)

  1. Device for discharging a liquid, especially rainwater, of the type comprising a discharge pipe (6) extending along an axis (XX) and forming an exhaust inlet (12), a tank manifold (8) extending around the discharge inlet (12) and being provided with a flange (16), and a liquid guiding device (10) comprising a cover plate (20), the plate cover plate (20) comprising a solid central area (22) covering the discharge entrance (12), characterized in that the cover plate (20) comprises a peripheral area (24) surrounding the central area (22) and extending in relation to the flange (16) in which the peripheral zone (24) is provided at least one through opening for evacuation (26) of the liquid delimiting an edge (30), in that for each opening (26) at least one liquid guiding member (40) is provided in the annular space between the cover plate (20) and the flange (16), the guide member (40) extending along a portion of the edge (30) and comprising a radial branch (44) which extends substantially radially with respect to the axis (XX) and a circumferential branch ( 48) which extends the radial branch (44) and which extends substantially circumferentially with respect to the axis (XX).   2. Evacuation device according to claim 1, characterized in that for each opening (26) two liquid guiding members (40) are provided in the annular space between the cover plate (20) and the collar (16). ) and extend along a portion of the edge (30), on each circumferential side of the discharge opening (26), and in that each guide member (40) comprises a radial branch (44) extending substantially radially and a circumferential leg (48) extending the radial branch (44) and extending substantially circumferentially with respect to the axis XX.   3. Evacuation device according to claim 1 or 2, characterized in that the circumferential arm (48) of the or each guide member extends the radial branch (44) of the radially inner side.   4. Evacuation device according to any one of claims 1 to 3, characterized in that the length of the radial branch (44) is substantially identical to the length of the circumferential branch (48).   Evacuation device according to one of Claims 1 to 4, characterized in that the guide members (40) extend from the surface of the cover plate (20) to the surface of the collar (16).   6. Evacuation device according to any one of claims 1 to 5, characterized in that the discharge opening (26) is oblong in shape whose circumferential extent is greater than the radial extent.   7. Venting device according to any one of claims 1 to 6, characterized in that the cover plate (20) comprises at least two, preferably three, discharge openings (26).   8. Evacuation device according to any one of claims 1 to 7, characterized in that the cover plate (20) comprises filtering means (50) arranged on the side of the plate (20) opposite the collecting tray ( 8), and extending over the or each discharge opening (26). 9. Evacuation device according to claim 8, characterized in that the filtering means comprise ribs (50, 50A) extending radially relative to the axis (X-X).   Evacuation device according to Claim 9, characterized in that the ribs (50, 50A) have a radial width (L2) which is greater than a radial width (L1) of the discharge opening (26), in particular between 1.5 and 2.5 times the radial width of this opening.   Evacuation device according to Claim 9 or 10, characterized in that the ribs (50, 50A) have an axial height (H) which is greater than an axial height (d) of the liquid guiding members (40). , in particular between 1.5 and 4 times this height.   12. Venting device according to any one of claims 9 to 11, characterized in that the ribs (50, 50A) comprise cells (52, 52A) open towards the discharge opening (26), in particular circumferentially through.   Drainage device according to Claim 12, characterized in that the ribs comprise lateral ribs (50A), which are ribs at the circumferential ends of the discharge openings (26), and that the lateral ribs ( 50A) comprise cells (52A) whose axial height (d) is less than the axial height of the other cells (52).   14. Venting device according to any one of claims 8 to 13, characterized in that between two ends of the discharge opening (26) extends a radial passage (54) of unfiltered liquid to allow a flow of liquid to the central zone (22).   Evacuation device according to one of Claims 1 to 14, characterized in that the liquid guiding device (10) and the or each liquid guiding member (40) are made in one piece. preferably in one piece and in particular by molding.   16. A liquid guiding device (10) comprising a cover plate (20), the cover plate (20) comprising a solid central area (22) for covering the exhaust inlet (12) a discharge pipe (8), characterized in that the cover plate (20) comprises a peripheral zone (24) surrounding the central zone (22) and adapted to extend in relation to a flange (16) of a collecting pan (8), in which peripheral zone (24) is provided at least one through-opening for evacuation (26) of the liquid defining an edge (30), in that for each opening ( 26) at least one liquid guide member (40) is provided, the guide member (40) extending along a portion of the edge (30) and including a radial branch (44) which is adapted for extending substantially radially with respect to an axis (XX) of the discharge pipe (8), and a circumferential branch (48) extending the radial branch (44) e t which is adapted to extend substantially circumferentially with respect to the axis (X-X).