FR2927135A1 - Mechanical piece's e.g. lid, pivoting movement limiting device for lavatory, has flow unit permitting limited flow of air in chamber or outside chamber for pivoting direction of piece, and shafts and pistons made of plastic material - Google Patents

Abstract

The device (50) has pistons (70A, 70B) defining chambers (64A, 64B) with an enclosure (62). A transformation device transforms a rotational movement of a mechanical piece e.g. lid, into a translational movement of the pistons along an axis (delta) so as to modify the volume of the chamber. A flow unit permits the limited flow of air in the chamber or outside the chamber for a pivoting direction of the piece. The transformation device is constituted of helical shafts (120A, 120B) and tubular elements (58A, 58B). The shafts and the pistons are made of plastic material i.e. polyacetal. An independent claim is also included for a lavatory comprising a mechanical piece's pivoting movement limiting device.

Description

B8716 1 DEVICE FOR SLOWING THE PIVOTING OF A MECHANICAL PART

FIELD OF THE INVENTION The present invention relates to a device for slowing the pivoting of a mechanical part, in particular a lid or a window of a toilet, or WC.

DESCRIPTION OF THE PRIOR ART Generally, a toilet comprises a bowl whose seat can be covered with a bezel and a lid, the bezel and the lid being fixed to the bowl by means of pivoting connections which allow to rotate the telescope and / or the lid between a covering position in which the bezel and / or the lid covers the bowl and an open position in which the bowl is accessible. In general, the cover can be pivoted between the open and the cover positions while the bezel is in the overlap position and the bezel can be pivoted between the open and the cover positions while the cover is in position d 'opening. In addition, the lid and the bezel can be rotated simultaneously between the open and the cover positions.

In general, the pivoting of the telescope and / or the lid between the opening and the covering positions is performed by the user of the WC. In particular, when a B8716

2 user wants to fold down the telescope and / or lid from the open position to the overlap position, it can initiate the tilting movement of the bezel and / or lid until the moment due to the weight of the bezel and / or cover is sufficient to rotate the telescope and lid to the recovery position. The pivoting of the telescope and the lid is generally stopped abruptly by the bowl, which can cause the emission of an unpleasant noise or damage the bezel and the bowl. To avoid this violent shock, the user must accompany the pivoting of the bezel and / or cover to the recovery position, which can be undesirable, especially for reasons of hygiene. To avoid any violent shock without user intervention, some toilets. are provided at the level of the pivoting connections connecting the bezel and the lid to the bowl, a device for slowing the pivoting of the bezel and cover from the open position to the recovery position, in particular at the end of the race . The slowing device may correspond to a hydraulic device comprising a viscous liquid capable of flowing between two chambers via an opening provided in a movable wall which pivots simultaneously with the lid and / or the telescope. The diameter of the opening is determined so as to obtain, during the pivoting of the movable wall, a resistance to displacement of the movable wall, which results in a slowing of the pivoting of the telescope and / or the bowl. A hydraulic slowing device must be perfectly sealed to prevent leakage of the viscous liquid.

It is therefore usually a product whose manufacturing cost is high. In addition, the viscosity of the liquid of the hydraulic slowing device decreases with temperature. The slowing provided by the hydraulic slowing device therefore decreases as the temperature increases, which is undesirable.

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SUMMARY OF THE INVENTION An object of the invention is to provide a device for slowing the pivoting of a mechanical part exerting a braking torque which is substantially independent of the temperature. According to another object, the slowing device can be produced at a reduced cost. According to another object, the slowing device does not use liquids.

To achieve all or part of these objects as well as others, one aspect of the present invention provides a device for slowing a pivoting movement of a mechanical part about an axis, comprising an enclosure, a piston delimiting with the enclosure a chamber, a device for transforming the rotational movement of the mechanical part into at least one translational movement of the piston in the enclosure along said axis so as to modify the volume of the chamber, and a means of limited flow of air into or out of the chamber for at least one pivoting direction of the mechanical part. According to one embodiment, the transformation device comprises a shaft intended to be rotated by the mechanical part and comprising first external and straight teeth, and a tubular element comprising second internal and helical teeth. The piston comprises a cylindrical portion having third external teeth cooperating with the second teeth and fourth internal and straight teeth cooperating with the first teeth, the piston being adapted to slide relative to the shaft.

According to one embodiment, the piston comprises an annular groove comprising a base, an O-ring disposed in the groove in sealed contact with the enclosure, and a hole connecting the base of the groove to the chamber. According to one embodiment, the groove comprises first and second walls, the second wall being the most B8716

4, the piston further comprising a groove on the first wall and extending from the base to the outer edge of the first wall, the section of the hole being greater than the section of the groove.

According to one embodiment, the piston comprises a first cylindrical portion extending at a first axial end by a second cylindrical portion delimiting the chamber and extending at a second axial end by a third cylindrical portion comprising a first external cylindrical wall comprising the third teeth, and a non-through opening extending along said axis on the first and second cylindrical portions and having the fourth teeth. According to one embodiment, the second cylindrical portion comprises a second outer cylindrical wall comprising said groove. Another aspect of the present invention provides a lavatory including a bowl, first and second slug devices attached to the bowl, a rotatable lid about an axis and connected to the first slugging device, and a bezel pivotable about the axis and connected to the second deceleration device. According to one embodiment, the cover comprises a first connecting portion rotating the shaft of the first retarding device and a second connecting portion rotatably mounted on the shaft of the second retarding device. The bezel comprises a third connecting portion rotating the shaft of the second slowing device and a fourth connecting portion mounted at least partially free to rotate on the shaft of the first slowing device. According to one embodiment, the lavatory further comprises a compressed air supply system in the B8716

chamber of the first slowing device and / or in the chamber of the second slowing device. BRIEF DESCRIPTION OF THE DRAWINGS These and other objects, features, and advantages will be set forth in detail in the following description of particular embodiments in a non-limitative manner with reference to the accompanying figures in which: FIG. schematic section of a lid of a toilet at the connection between the lid and the toilet bowl; Figures 2 and 3 are sections of Figure 1 along lines A-A and B-B; Figure 4 is a schematic section of a telescope of a toilet at the connection between the bezel and the toilet bowl 15; Figures 5 and 6 are sections of Figure 4 along lines C-C and D-D; Figure 7 is a schematic sectional view of an exemplary embodiment of a slowing device according to the invention; Figures 8, 9 and 10 are respectively a side view, a front view and a rear view of a part of the slowing device of Figure 7; Figure 11 is a detail section of Figure 10 along line G-G; Figure 12 is a detail view of Figure 8; Figures 13 and 14 are respectively a side section and a rear view of another part of the slowing device of Figure 7; Figure 15 is a schematic axial section of another part of the retarder of Figure 7; Figure 16 is a top view of the part of Figure 15; Figures 17 to 19 are schematic sections of Figure 15 along the lines K-K, L-L and M-M, respectively; B8716

Figure 20 is an axial schematic sectional view of another part of the retarder of Figure 7; Figures 21 to 23 are schematic sections of Figure 20 along lines N-N, 0-0 and P-P; Figure 24 is a section of the assembly formed of the lid, the bezel and the slowing device when the lid and the bezel are in the position of recovery and opening; Figures 25 and 26 are sections similar to Figure 11 during the pivoting of the cover respectively of the open position to the cover position and the cover position to the open position; Figure 27 is a schematic section of the slowing device and the telescope illustrating the mounting of the telescope on the slowing device; and Figure 28 is a section of Figure 27 along the line Q-Q. DETAILED DESCRIPTION For the sake of clarity, the same elements have been designated with the same references in the various figures. The present invention relates to a device for slowing the pivoting of a mechanical part. An exemplary embodiment of the slowing device will be described for slowing the pivoting of a lid and a telescope 25 of a toilet or toilet. However, it is clear that the present invention can be applied to slowing down the pivoting of any mechanical part, for example a swinging door, an oscillating panel, etc. In the following description, when considering a mechanical part at least partially symmetrical with respect to a plane P, is added to the references designating elements of the mechanical part which are symmetrical or generally symmetrical with respect to the plane P the suffix "A" when the element is shown in a figure to the left of the plane P and the suffix "B" 35 when the element is shown in a figure to the right of the plane B8716

Non-suffixed references "A" or "B" are used to designate elements of a mechanical part which are not symmetrical with respect to the plane P. FIG. 1 represents a schematic section of a cover 10 of FIG. a toilet at the connection between the lid 10 and the toilet bowl, not shown and Figures 2 and 3 are sections of the lid 10 of Figure 1 respectively along lines AA and BB. The lid 10 is pivotable about an axis A, perpendicular to the plane P, which can be vertical. The lid 10 comprises a body 12, slightly curved and two lateral portions 14A, 14B. Each connecting portion 14A, 14B comprises a flat face 15A, 15B perpendicular to the axis A and having an aperture 16A, 16B symmetrical of revolution about the axis A and intended to receive a shaft, not shown. D1 is the distance between the faces 15A and 15B. The opening 16B comprises a frustoconical portion 18B, of axis A, which is extended by a cylindrical portion 20 of axis A. The opening 16A comprises a frustoconical portion 18A, of axis A, extending through an opening 22 s extending along the axis A and provided with an internal toothing. In the present embodiment, the opening 22 comprises four teeth 24 which extend parallel to the axis A and which delimit four grooves 26 extending parallel to the axis A.

FIG. 4 represents a diagrammatic section of a telescope 30 of the WC at the connection between the telescope 30 and the toilet bowl, not shown, and FIGS. 5 and 6 are sections of the telescope 30 respectively along the lines CC and DD. The telescope 30 is capable of pivoting about the axis A.

It comprises an annular body 32 and two connecting lateral portions 34A, 34B. Each connecting portion 34A, 34B comprises two planar faces 35A, 35B, 36A, 36B perpendicular to the axis A. D2 is the distance separating the faces 35A and 35B and D3 the distance separating the faces 36A and 36B. The distance D2 is slightly less than the distance D1.

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The connecting portion 34A comprises a cylindrical through hole 37, of axis A, extending from the face 35A to the face 36A and at which a tooth 38 extending parallel to the axis A is provided. connecting portion 34B comprises a through opening 40 extending along the axis A of the face 35B to the face 36B and provided with an internal toothing. In the present embodiment, the opening 40 comprises four teeth 42 which extend parallel to the axis A and which delimit four grooves 44 extending parallel to the axis A. The diameter of the opening 40 of the connecting portion 34A of the telescope 30 is substantially equal to the diameter of the opening 30 of the connecting portion 14A of the cover 10. FIG. 7 shows an exemplary embodiment of the retarding device 50 according to the invention to which they are intended to be In the present embodiment, the slowing device 50 is substantially symmetrical with respect to the plane P and comprises two braking devices 52A, 52B. Each braking device 52A, 52B comprises a fixing support 54A, 54B comprising a base 56A, 56B intended to be fixed to the toilet bowl, not shown, and extending by a tubular portion 58A, 58B comprising a cylindrical internal opening 60A , 60B of axis A and diameter D4. The slowing device 50 comprises a tubular central body 62 of axis A fixed at each end to one of the tubular portions 58A, 58B, for example by snapping. The body comprises two cylindrical chambers 64A, 64B of axis A separated by a central partition 68. Each chamber 64A, 64B is delimited by a cylindrical wall 66A, 66B, of axis A and of diameter D5, and by a face 67A, 67B of the partition 68, perpendicular to the axis A. The diameter D5 is greater than the diameter D4. Each chamber 64A, 64B is located in the extension of the corresponding cylindrical opening 60A, 60B. Each braking device 52A, 52B comprises a piston 70A, 70B capable of B8716

9 to move in the chamber 64A, 64B and the cylindrical opening 60A, 60B. Figures 8, 9 and 10 are respectively a side view of the piston 70A, a view of the piston 70A in the direction E and a view of the piston 70A in the direction F. The piston 70B substantially corresponds to the symmetrical piston 70A relative to the plane P. The piston 70A comprises a central cylindrical portion 72A of axis A and of diameter D6 extending at one end by a cylindrical portion 74A of axis A and extending at the opposite end by a cylindrical portion 76A of axis A The cylindrical portion 76A comprises an outer cylindrical wall 78A and two lateral faces 79A and 80A, perpendicular to the axis A, the face 80A being the closest to the partition 68. The outer cylindrical wall 78A comprises a groove 81A in which is has an O-ring 82A. The cylindrical portion 74A includes an outer cylindrical wall 84A and a side face 86A perpendicular to the axis A. 88A teeth are distributed on the outer cylindrical wall 84A (six teeth 88A being shown by way of example in Figure 9). Each tooth 88A comprises two working faces 90A, 92A. The reference numeral D7 designates the diameter of the outer casing of the teeth 88A and denotes by the reference D8 the diameter of the cylindrical portion 76A. The diameter D8 is greater than the diameter D7. In addition, the diameter meter D8 is slightly smaller than the diameter D5 and the diameter D7 is slightly smaller than the diameter D4. In the present embodiment, the teeth 88A have the same dimensions with the exception of a tooth 89A which occupies a larger angular sector. The piston 70A comprises a non-through opening 94A which extends along the axis A from the face 86A and which stops before reaching the face 80A at a bottom wall 95A. The opening 94A is provided with an internal toothing. In the present exemplary embodiment, the opening 94A comprises four teeth 96A which extend parallel to the axis A and which B8716

10 delimit four grooves 98A extending parallel to the axis A. FIG. 11 is a partial section of the piston 70A of FIG. 10 along the line GG and FIG. 12 is a partial view of the piston 70A of FIG. direction H. The groove 81A has a substantially rectangular section and is delimited by a bottom 100A and two side walls 102A, 104A, the wall 104A being closest to the face 80A. The cylindrical portion 76A comprises a cylindrical through opening 106A extending parallel to the axis A. The opening 106A opens on one side on the face 80A, opens on the opposite side in the groove 81A at the bottom 100A and then forms a groove that extends at the bottom 100A substantially to the wall 102A. The cylindrical portion 76A further comprises a groove 108A in the wall 102A which extends substantially perpendicular to the axis A from the outer cylindrical wall 78A to the level of the bottom 100A. FIG. 13 is a section of the support 54A and FIG. 14 is a view of the support 54A in the direction I. The tubular portion 58A comprises, at the farthest end of the partition 68, a flange 110A defining a face 111A perpendicular to the axis A and a transverse cylindrical opening 112A of axis A and diameter D9. The diameter D9 is smaller than the diameter D4 and is substantially equal to the diameter of the opening 37 of the connecting portion 34A. In FIG. 7, the reference D10 designates the distance between the face 111A of the support 54A and the face 111B of the support 54B. The distance D10 is slightly less than the distance D3. The opening 60A comprises a helical internal toothing. The toothing is constituted by teeth 114A, each tooth 114A winding around the axis A in a helix. Six teeth 114A are visible in FIG. 14. The teeth 114A are defined to cooperate with the teeth 88A, 89A of the piston 70A as the piston 70A moves into the opening 60A. The six teeth 114A are distributed every N * 360/7 degrees around the axis A, N being an integer B8716

11 between 1 and 6. As a result, the teeth 114A are angularly equidistant with the exception of two teeth that are angularly more spaced apart. The angular sector occupied by the tooth 89A is greater than 360/7 degrees so that the tooth 89A can be housed only between the teeth 114A angularly spaced apart. The tooth 89A then acts as a positioning index during the assembly of the retarding device 50. FIG. 15 is a section along the axis A of an exemplary embodiment of a shaft 120A intended to cooperate with the portion of 14A of the lid 10, the connecting portion 34A of the telescope 30 and the piston 70A. Figure 16 is a view of the shaft 120A in the direction J and Figures 17 to 19 are sections of the shaft 120A along lines K-K, L-L and M-M. The shaft 120A comprises a cylindrical body 122A (whose periphery is delimited by dashed lines in FIG. 15) having two axial ends 124A, 126A, the axial end 126A being intended to be the closest to the connecting portion 14A. operation. The shaft 120A is provided with an external toothing. In the present embodiment, the toothing consists of teeth 128A, 130A, 132A, 134A which extend parallel to the axis A. In the present embodiment, the teeth 128A, 130A and 132A extend substantially over the entire length of the shaft 120A. Near the axial end 126A, an opening 136A is provided in the tooth 128A so that a portion of the tooth 128A forms a flexible finger 138A which, in the absence of external stresses, radially exceeds the rest of the tooth 128A. The tooth 134A is not present on the part of the shaft 120A located, in operation, at the connecting portion 34A of the bowl 30. The reference 139A designates the missing portion of the shaft 120A. Figure 20 is a section along the axis A of an exemplary embodiment of a shaft 120B for cooperating with the connecting portion 14B of the cover 10, the connecting portion 34B of the bezel 30 and the piston 70B. Figures 21 to 23 are B8716

12 cuts of the shaft 120B along lines N-N, 0-0 and P-P. The shaft 120B has the same structure as the shaft 120A with the difference that the tooth 134B extends over the entire length of the shaft 120B.

FIG. 24 represents two half-sections made at the level of the connection between the lid 10, the telescope 30 and the slowing device 50. On the half-section located in the right-hand part of FIG. 24, the lid 10 and the telescope 30 are in the recovery position, that is to say completely folded down on the toilet bowl. On the half-section on the left-hand side of FIG. 24, the lid 10 and the bowl 30 are in the open position. Furthermore, in the left-hand part of FIG. 24, there is shown a variant of the slowing device 50 according to which a housing 140 encapsulates the slowing device 50. In operation, each shaft 120A, 120B extends into the opening 16A, 16B corresponding to the connecting portion 14A of the cover 10, the corresponding opening 36, 40 of the connecting portion 34A of the telescope 30 and at least partly in the corresponding opening 94A, 94B of the piston 70A, 70B. For each shaft 120A, 120B, the end of the flexible finger 138A, 138B of the shaft 120A, 120B bears against the face 35A, 35B of the connecting portion 34A, 34B of the telescope 30 so as to prevent the translation of the shaft 120A, 120B along the axis A relative to the cover 10. The shafts 120A, 120B, the pistons 70A, 70B and the supports 54A, 54B may be made of plastic materials, for example polyacetal. O-rings 82A, 82B may correspond to polymer gaskets. This makes it possible to manufacture the slowdown device 50 at low cost. The operation of the retarding device 50 according to the invention is as follows. In general, a rotation of the shaft 120A about the axis A tends to rotate the piston 70A by cooperating the teeth 128A, 130A, 132A and 134A of the shaft 120A with B8716

13 teeth 96A of the internal opening 94A of the piston 70A. The rotation of the piston 70A causes its translation along the axis A by cooperation of the teeth 88A located on the periphery of the cylindrical portion 74A of the piston 70A with the helical teeth 114A of the opening 60A of the support 54A, fixed with respect to the bowl. The piston 70A then pivots around the axis A while moving along the axis A to move towards or away from the partition 68 in the direction of rotation of the shaft 120A. As it moves, the piston 70A slides on the shaft 120A. Thus, the transformation of the rotational movement of the shaft 120A into a rotational and translational movement of the piston 70A is obtained. The kinematic transformation of the rotational movement of the shaft 120B in rotational and translational movement of the piston 70B is obtained in a similar manner.

The rotation of the shafts 120A, 120B is carried out as follows. Rotation of the cover 10 about the axis A causes rotation of the shaft 120A about the axis A by cooperation of the teeth 24 of the connecting portion 14A of the cover 10 with the teeth 128A, 130A, 132A and 134A of the shaft 120A. The rotation of the shaft 120A does not cause rotation of the telescope 30 since the single tooth 38 of the connecting portion 34A of the telescope 30 is located at the portion of the shaft 120A where the tooth 134A is not present. The pivoting of the lid 10 from the open position to the covering position results in the piston 70A coming closer to the partition 68. Similarly, a rotation of the telescope 30 about the axis A causes a rotation of the shaft 120B about the axis A by cooperation of the teeth 42 of the connecting portion 34B of the bezel 30 with the teeth 128B, 130B, 132B and 134B of the shaft 120B. The rotation of the shaft 120B does not cause rotation of the cover 10 because the teeth 128B, 130B, 132B and 134B do not cooperate with the cylindrical opening 20 of the connecting portion 14B of the cover 10. The pivoting of the bezel 30 from the open position to the recess position B8716

14 vement results in the approximation of the piston 70B of the partition 68. Obtaining a braking torque will now be described for the piston 70A during the pivoting of the cover 10. A braking torque is obtained in a similar way with the 70 is a partial section of the piston 70A similar to FIG. 11 when the piston 70A approaches the partition 68, that is to say when the lid 10 is pivoted. the recovery position. The seal 82A providing a substantially sealed connection between the piston 70A and the cylindrical wall 66A of the central body 62, the air present in the chamber 64A between the face 80A of the piston 70A and the partition 68 tends to be compressed and exerted on the face 80A a force parallel to the axis A opposing the displacement of the piston 70A. This force is transmitted through the piston 70A to the shaft 120A and results in the application of a braking torque when folding the lid 10 to the overlap position. To prevent blockage of the retarder 50, the passage of air through the opening 100A and the groove 102A is allowed. As the piston 70A approaches the bulkhead 68, the O-ring 82A tends to be rubbed against the side wall 102A of the groove 81A (the deformations of the gasket 82A have been exaggerated in FIG. 25). The air can then flow only through the groove 108A. The dimensions of the groove 108A impose the maximum possible air flow and therefore the force opposing the displacement of the piston 70A, that is to say the braking torque exerted on the cover 10. FIG. piston 70A similar to Figure 11 when the piston 70A away from the partition 68, that is to say, when pivoting the cover 10 to the open position. The O-ring 82A then tends to be rubbed against the side wall 104A of the groove 81A (the deformations of the seal 82A have been exaggeratedly shown in Fig. 26) and to move away from the side wall 102A. It's B8716

15 then the section of the opening 106A which determines the maximum possible air flow. An opening 106A having a diameter greater than one millimeter is sufficient to avoid that a braking torque is exerted on the cover 10.

Figures 27 and 28 illustrate an intermediate step during assembly of the bezel 30 and the cover 10 on the slowing device 50. Initially, the pistons 70A, 70B are introduced substantially halfway in the chambers 64A, 64B. The cover 30 is adjusted relative to the braking device 50 and is rotated to be slightly inclined at an angle θ relative to the overlap position as shown in FIG. 28. The shafts 120A, 120B are then introduced into the openings 36, 40 of the connecting portions 34A, 34B of the cover 30 and the openings 94A, 94B of the pistons 70A, 70B. In this configuration, the axial end portions 126A, 126B of the shafts 120A, 120B are flush with the lateral faces 35A, 35B of the connecting portions 34A, 34B of the telescope 30. In addition, the axial ends 124A, 124B are bearing against the bottom 95A, 95B of the openings 94A, 94B. The cover 10 is then put in place with the same inclination as the telescope 30 with respect to the covering position. The telescope 30 and the lid 10 are then rotated to the open position. The rotation of the telescope 30 causes the rotation of the shaft 120B by cooperation of the teeth 42 of the connecting portion 34B of the telescope 30 with the teeth 128B, 130B, 132B and 134B of the shaft 120B. The rotation of the telescope 30 also causes the rotation of the shaft 120A by cooperation of the single tooth 38 of the connecting portion 34A of the telescope 30 with the tooth 132A of the shaft 120A. The rotation of the shafts 120A, 120B results in a displacement of the pistons 70A, 70B which move away from the partition 68. The displacement of the pistons 70A, 70B causes a displacement of the shafts 120A, 120B which penetrate the openings 16A, 16B of the connecting portions 14A, 14B of the cover 10. In particular, the teeth 128A, 130A, 132A and 134A of the shaft 120A cooperate with the teeth 24 of the B8716

16 connecting portion 14A of the cover 10 which then provide the rotational drive of the shaft 120A. When the flexible fingers 138A, 138B protrude completely from the faces 35A, 35B of the connecting portions 34A, 34B of the telescope 30, they are detained and then bear against the lateral faces 35A, 35B preventing any future translation of the shafts 120A. 120A relative to the cover 10. When the shaft 120A is completely inserted into the opening 16A of the connecting portion 14A of the cover 10, the shaft 120A occupies a position relative to the bezel 30 to which the tooth 134A is interrupted (tooth 134A is shown in dotted lines in FIG. 28). Therefore, when the bowl 10 is in the open position, the bezel 30 can be rotated between the opening and covering positions without the tooth 38 cooperates with the teeth 128A, 130A, and 132A. An advantage of the retarding device 50 according to the embodiment described above with reference to Figures 1 to 28 is that the relative movement between the piston 70A, 70B and the associated shaft 120A, 120B is a simple translational movement. This makes it possible to reduce the risk of blocking of the retarding device 50 which could result from parasitic inclinations of the shafts 120A, 120B with respect to the axis A, notituttuttent because of the weight of the bowl 10 and the telescope 30. According to the In this exemplary embodiment, the braking torque is obtained by bringing the piston 70A, 70B of the partition 68 closer together. According to an alternative embodiment, the braking torque can be obtained by moving the piston 70A, 70B away from the partition 68. In this case, the pivoting of the cover 10 and the telescope 30 from the covering position to the open position causes the associated piston 70A, 70B to move away from the partition 68. In addition, the groove 108A can then be provided on wall 104A and opening 106A can connect base 100A to face 79A. According to a variant of the invention, the teeth 128A to 134A and 128B to 134B of the shafts 120A, 120B have, at least in B8716

Partly, a helical shape and the teeth 96A, 96B of the pistons 70A, 70B have a shape similar to the teeth 88A, 88B to cooperate with the helical teeth of the shaft 120A, 120B. Conversely, the teeth 96A, 96B of the pistons 70A, 70B may have a helical shape and the teeth 128A to 134A and 128B to 134B of the shafts 120A, 120B may have a shape similar to the teeth 88A, 88B for cooperating with the helical teeth of the pistons 70A, 70B. According to these variants, the translational movement of the piston 70A, 70B during the rotation of the corresponding shaft 120A, 120B is obtained directly by the cooperation of the shaft 120A, 120B and the piston 70A, 70B. The teeth 114A, 114B of the supports 54A, 54B and the teeth 88A, 88B of the pistons 70A, 70B are then not present. The piston 70A, 70B may then not have a cylindrical shape and may have a rectangular outer section.

According to a variant of the embodiment of the slowing device 50 according to the invention, an air supply system in the chambers 64A, 64B is provided between the faces 80A, 80B of the pistons 70A, 70B and the partition 68 The air supply system may comprise a source of compressed air.

When the cover 10 and the bezel 30 are in the overlap position, air can be introduced into the chambers 54A, 54B, which forces the pistons 70A, 70B away from the partition 68 causing the cover 10 to pivot. and the telescope 30 to the open position.

Particular embodiments of the present invention have been described. Various variations and modifications will be apparent to those skilled in the art. In particular, for each shaft 120A, 120B, the tooth 134A, 134B may extend only on the part of the shaft 120A, 120B which, in operation, is likely to be in the opening 94A, 94B of the piston 70A, 70B corresponding. In addition, the number of teeth of the teeth of the connecting portions 14A, 14B, 34A, 34B, the shafts 120A, 120B, the pistons 70A, 70B and the tubular portions 58A, 58B may be greater or smaller than the exemplary embodiments. previously described.

Claims (9)

A device (50, 52A, 52B) for slowing down a pivotal movement of a mechanical part (10, 30) around an axis (A), comprising: a housing (62); a piston (70A, 70B) defining with the chamber a chamber (64A, 64B); a device (120A, 120B, 70A, 70B, 58A, 58B) for transforming the rotational movement of the mechanical part into at least one translational movement of the piston in the chamber along said axis so as to modify the volume of the chamber ; and at least one limited air flow means in the chamber or out of the chamber for at least one direction of rotation of the mechanical part. 2. The device according to claim 1, wherein the transformation device comprises: a shaft (120A, 120B) to be rotated by the mechanical part (10, 30) and including first teeth (128A, 130A, 132A); , 134A) external and straight; and a tubular member (58A, 58B) comprising inner and helical second teeth (114A), and wherein the piston (70A, 70B) comprises a cylindrical portion (74A) having external third teeth (88A) cooperating with the second teeth and fourth teeth (96A) internal and straight cooperating with the first 25 teeth, the piston being adapted to slide relative to the shaft. The device of claim 1 or 2, wherein the piston (70A, 70B) comprises: an annular groove (81A) comprising a base (100A); an O-ring (82A, 82B) disposed in the groove in sealing contact with the enclosure (62); and a hole (106A) connecting the base of the groove to the chamber. 4. Device according to claim 3, wherein the groove (81A) comprises first and second sidewallsB8716 19 (102A, 104A) extending from the base (100A), the second wall (102A) being closest to the chamber (64A), the piston (70A) further comprising a groove (108A) on the first wall and extending from the base to the outer edge of the first wall, the section of the hole (106A) being greater than the section of the groove. 5. Device according to claim 2, wherein the piston (70A, 70B) comprises: a first cylindrical portion (72A) extending at a first axial end by a second cylindrical portion (76A) delimiting the chamber (64A) and extending at a second axial end by a third cylindrical portion (74A) comprising a first outer cylindrical wall (84A) having the third teeth (88A); and a non-through opening (94A) extending along said axis (A) on the first and second cylindrical portions and having the fourth teeth (96A). 6. Device according to claims 3 and 5, wherein the second cylindrical portion (76A) comprises a second outer cylindrical wall (78A) having said groove (81A). 7. A lavatory comprising: a bowl; first and second retarders (50, 52A, 52B) according to any one of claims 1 to 6 attached to the bowl; a cover (10) pivotable about an axis (A) and connected to the first retarder (52A); and a telescope (30) pivotable about the axis (A) and connected to the second retarder (52A). The lavatory of claim 7, wherein the first and second retarders (50, 52A, 52B) are as claimed in claim 2, wherein the lid (10) comprises a first link portion (14A). ) rotatably driving the shaft (120A) of the first retarder and a second connecting portion (14B) rotatably mounted on the shaft (120B) of the second retarder and wherein the bezel (30) comprises a third connecting portion (34B) rotating the shaft (120B) of the second retarding device and a fourth connecting portion (34A) mounted at least partially free to rotate on the shaft (120A) of the first retarding device; compaction. 9. A lavatory according to claim 7 or 8, further comprising a compressed air supply system in the chamber (64A) of the first retarder (52A) and / or in the chamber (52B). the second retarder (64B).