• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Cylindrical diaphragm assembly of reduced diameter for hydraulic shock absorbers with sealing at both ends, used in self-closing furniture, which at its outer end seals the cylindrical body of the shock absorber (8) and at its inner end performs the sealing of the shock absorber shaft (9), said cylindrical diaphragm assembly (1) being on its outer side a fluid compensation chamber (13) and on the other inner side an aerial chamber (14) and consisting of an insertable elastic hood (2) whose inner end (5) has an annular decrease in diameter, generating a flat support area (6) and ending in a single-joint frusto-conical extension (7) in contact with the axis of the shock absorber (9), and an inner tubular centering male (3) provided at its internal end with a frusto-conical head (10) with a flat wall for external support and fixing (11) of said insertable elastic hood (2); and that said inner tubular centering male (3) has longitudinal fins (12) terminating said inner tubular centralizing male (3) in a protrusion of closing plug (15) that with the external end (16) of the insertable elastic hood (2) generates a simple joint with the cylindrical body of the shock absorber (8). (Machine-translation by Google Translate, not legally binding)
    公开号:ES2768474A1
    申请号:ES201831265
    申请日:2018-12-21
    公开日:2020-06-22
    发明作者:Iribarren Luis Maria Rioja
    申请人:Industrias Auxiliares SA Indaux;
    IPC主号:
    专利说明:

    [0002] Small diameter cylindrical diaphragm assembly for hydraulic shock absorbers with sealing at both ends, used in self-closing furniture.
    [0004] FIELD OF THE INVENTION
    [0006] This invention concerns a small diameter cylindrical diaphragm assembly for hydraulic shock absorbers with sealing at both ends, used in furniture self-closures. Of those used in shock absorbers to seal both the liquid passage in the external sealing end of the cylindrical body of the shock absorber, and to seal the liquid passage in the internal sealing end of the shock absorber shaft, and that these shock absorbers also contain axle volume compensators, due to the volume occupied by the axle inside the shock absorber body.
    [0007] It is important to consider that the reduced dimensions of these shock absorbers make the adoption of more complicated configurations critical.
    [0009] STATE OF THE PREVIOUS TECHNIQUE
    [0011] At present and with reference to the state of the art, the use of diaphragms is known, which in turn act of sealing at the outer end of contact with the cylinder of the damper and sealing at the inner end of contact with the axis of the damper. . The gaskets used at the ends prevent fluid from leaving the internal chamber of the shock absorber cylinder, both at the end of the body and the shaft, and incorporating different systems to compensate for the volume of liquid displaced due to the volume of the shaft introduced into the shock absorber body, which influences the capacity of the cameras.
    [0013] There are a type of solutions for the compensation of the volume of the shaft immersed in the fluid containing the shock absorber, based on longitudinally movable sealing gaskets with the help of a spring that allow the chamber that stores the fluid to increase or decrease, compensating the volume variation due to the axis. These solutions imply that the sealing of the outer body stop being static, as usual, and become mobile. This implies that the sealing is more critical due to the consequent wear. Furthermore, the spring generates the undesirable residual pressure effect, which, as with sponges, tries to move the shaft outwards.
    [0015] Another solution adopted in shock absorbers more common in the automotive sector is the use of a diaphragm mounted at the ends of a bush mounted between the shaft and the cylindrical body of the shock absorber, said bush being at its internal end in the form of a cup and with the diaphragm acting as a seal at the ends of said bush. Said diaphragm is coupled to the cup-shaped end of the bushing so that it wraps said cup by folding back to produce the sealing of the cylinder axis producing a double lip seal. However, this solution causes that, in use, in this backward bend the diaphragm breaks or permanently deforms with the consequent reduction of the tightness and making the compensation of the shock absorber less effective. Furthermore, in the case of furniture self-locks in which the diameters of these shock absorbers have very small dimensions, this solution would not be feasible due to the difficulty in their manufacture and assembly for such small dimensions.
    [0017] Other solutions also employ bushings or tubular elements at the two ends of the bush, resulting in sealing with the damper cylinder at its outer end, but requiring an additional gasket or several additional elements for sealing with the damper shaft.
    [0019] Another common solution in automobiles is the use of two pistons between which is placed a tubular bushing that fixes a compensation diaphragm at both ends. However, this arrangement, despite setting a compensation distance, does not allow homogeneous deformation of the diaphragm and therefore requires trochoidal diaphragm designs with variation in radial thickness to decrease the stress supported by the diaphragm during the damping operation and thus avoid the formation of small radius folds that shorten its useful life, being the most complicated and expensive manufacturing. And since the elastic work of the perimeter of the diaphragm is assumed mostly by the valleys of said Trochoidal section, which are the segments of lesser thickness, therefore this solution only takes advantage of half of the elastic deformation capacity of the diaphragm.
    [0021] EXPLANATION OF THE INVENTION AND ADVANTAGES
    [0023] Against this state of the art, the present invention refers to a cylindrical diaphragm assembly of reduced diameter for hydraulic shock absorbers with sealing at both ends, used in self-closing furniture, which at its outer end performs the sealing of the cylindrical body of the shock absorber and at its inner end it seals the shock absorber shaft, said cylindrical diaphragm assembly being on its outer side a fluid compensation chamber and on the other inner side an aerial chamber, and which has an insertable elastic hood whose Inner end has an annular decrease in diameter, generating a flat support area and ending in a frusto-conical extension of a simple joint in contact with the axis of the shock absorber, and acting in conjunction with a central tubular inner male provided at its internal end with a head frusto-conical wall flat for external support and fixing of said insertable elastic hood and; and that said inner tubular centering male has longitudinal fins ending in a protrusion of a closing plug that with the external end of the insertable elastic hood generates a simple joint with the cylindrical body of the shock absorber.
    [0024] Thanks to this configuration, it is possible to compensate the volume of the shaft immersed in the fluid (generally oil) during the maneuver of introducing said shaft into the body of the shock absorber, using a simple joint seal with the shaft and also reducing the number of elements necessary to carry out this task. In addition, this solution allows the manufacture of diaphragm assemblies for smaller dimensions, necessary in furniture self-closing shock absorbers, which are very different from the already known solutions for the automotive and large machinery sector. Thus, for the automotive sector, the minimum standard for the internal diameter of the cylindrical body of the shock absorber is of the order of 25 millimeters, while for self-closing furniture, diameters of the order of 6 millimeters are common, and allow the use of fewer elements .
    [0025] With the use of an inner tubular centering male and an insertable elastic hood, the assembly of the assembly prior to its insertion in the cylinder of the shock absorber is facilitated, which due to its configuration only with the insertion of the elastic hood in the inner tubular centralizing male, remains Centering and fixing the cylindrical diaphragm assembly without the need for additional maneuvers for mounting or additional elements for sealing.
    [0026] With respect to the internal end, and due to its configuration with an annular decrease in diameter ending in a frusto-conical extension, a simple seal is generated in the interior area of contact with the shaft, enabling the operation of the elasticity of the diaphragm that eliminates generating edges critical areas of fatigue that may cause breaks or permanent deformation of the elastic element, as occurs in the case of joints with inward bending or double lip configurations.
    [0027] In addition, the flat-wall frustoconical head of the inner tubular centering male allows fixing at the internal end of the insertable elastic hood, thus preventing it from moving in compression during the movement of the shock absorber shaft, as can happen in other embodiments in which said internal end of the diaphragm is not fixed and produces displacements that reduce the tightness and therefore, the least effectiveness in damping. In addition, with the help of the longitudinal fins of the inner tubular centering male, assembly is facilitated by centering the diaphragm assembly and it is guaranteed that the insertable elastic hood has a controlled deformation and is as smooth and distributed as possible, without critical zones of extreme flexion that end up breaking due to fatigue and therefore causing oil leaks and ensuring balanced flexing of the insertable elastic hood.
    [0028] Another advantage of the configuration with longitudinal fins of the inner tubular centering male is that they facilitate a greater compensation surface, since said longitudinal fins force the internal annular surface of the insertable elastic hood to have a controlled deformation throughout its entire length. perimeter and therefore take advantage of all the deformation capacity in a controlled way, unlike other embodiments in which the trochoidal configuration of the section of the elastic element forces it to be deformed by the smaller section segments thickness thus reducing the elastic deformation capacity by half and it is more complicated in this way to control the compensation.
    [0030] Another feature of the invention is that the top of the longitudinal fins of the inner tubular centering male is rounded. This allows a smoother deformation if possible, avoiding critical edges that may cause the cylindrical diaphragm assembly to break or malfunction.
    [0032] Another peculiarity of the invention is that the longitudinal fins are peripherally symmetrical in distribution, uniformly compensating the elastic stresses to which the insertable elastic hood is subjected, deformable in use. Thanks to this configuration, the inner tubular centering male is more robust and resistant, improving the resistance and durability of the cylindrical diaphragm assembly and allowing a more controlled and distributed deformation of the insertable elastic hood for compensation without critical areas of fatigue.
    [0034] According to the invention, it is provided that in the tubular part of the external end of the inner tubular centering core there is at least one window for atmospheric communication with the exterior.
    [0036] Thanks to this configuration of the invention, a compensation of the volume of the shaft immersed in the internal fluid of the shock absorber is obtained, providing a zero antagonistic residual effort, due to the fact that the pressure increase by compression of the air inside the chamber is avoided. annular fluid compensation when the damper shaft is inserted.
    [0038] Another feature of the invention is that the outer annular surface of the insertable elastic hood is intended to incorporate longitudinal evacuation grooves of reduced depth.
    [0039] Thanks to this configuration, the mounting of the shock absorber is facilitated, evacuating the volume of air that is going to be occupied by the double compensating sealing gasket inside the cylindrical body of the shock absorber. This air will go out through the longitudinal strips of evacuation towards the outside, avoiding the creation of air pockets. The dampers used in elements of Furniture is characterized by being small, making it necessary to facilitate and simplify the assembly of its elements as much as possible.
    [0041] Likewise, it is provided in an alternative embodiment that the insertable elastic hood, on its inner annular surface, incorporates circularly symmetrical positioning ribs extending radially to the shock absorber axis and with its end close to the surface of the shock absorber axis.
    [0042] This configuration, with the existence of the positioning ribs emerging from the inner annular surface of the insertable elastic hood, replacing the longitudinal fins of the inner tubular centering male, guarantees the correct operation of the diaphragm assembly, avoiding the displacement of the internal end shaft sealing when said shock absorber shaft is immersed in the fluid that contains the shock absorber cylinder.
    [0043] Likewise, possible displacements of the internal end of the shaft seal are avoided due to the turbulent oil flows produced when the acceleration that is provided to said shock absorber shaft is excessively high and the elimination of fatigue points in the elastic activation of the the insertable elastic hood.
    [0045] DRAWINGS AND REFERENCES
    [0047] To better understand the nature of the invention, an industrial embodiment is shown in the accompanying drawings which is merely illustrative and not limiting.
    [0049] Figure 1 shows an exploded view of the cylindrical diaphragm assembly for shock absorbers (1) where the arrow indicates the direction of insertion in the assembly of the insertable elastic cap (2) in the inner tubular centering male (3). With section details of the internal end of both components where you can see their configuration.
    [0051] Figures 2 and 3 are longitudinal sectional views of the inner tubular centering male (3) and the insertable elastic hood (2) respectively. Where the arrow it also indicates the direction of insertion in the assembly of the cylindrical diaphragm assembly for shock absorbers (1).
    [0053] Figure 4 shows a section view of the cylindrical diaphragm assembly (1) already assembled.
    [0055] Figure 5 shows a scale comparison of the difference in size of the shock absorber (4) of the present invention with the minimum internal diameter of the cylindrical body of the shock absorber (8), compared to an automobile or large machinery shock absorber with its minimum inner diameter of the cylindrical body of the shock absorber (8).
    [0057] Figure 6a shows in section the cylindrical diaphragm assembly (1) mounted on the damper (4) and with the damper shaft (9) extended to the maximum, where the arrows indicate the air outlet from the air chamber (14) to the Exterior.
    [0059] Figure 6b shows a longitudinal sectional view of the damper (4) with the damper shaft (9) extended to the maximum.
    [0061] Figure 6c shows a cross-sectional view A-A indicated in Figure 6b, in which the configuration of the insertable elastic hood (2) with the maximum volume of air inside the air chamber (14) is observed.
    [0063] Figure 7a shows a section of the cylindrical diaphragm assembly (1) mounted on the damper (4) and with the damper shaft (9) inserted fully into the cylindrical body of the damper (8), and where the aerial camera is observed (14) with the smallest volume of air inside, due to the volume of fluid displaced.
    [0065] Figure 7b shows a longitudinal sectional view of the damper (4) with the damper shaft (9) fully inserted.
    [0066] Figure 7c shows a cross-sectional view B-B indicated in Figure 7b, in which the configuration of the insertable elastic hood (2) with the minimum volume of air inside the air chamber (14) is observed.
    [0068] Figure 8a shows an elevation view of the inner tubular centering male (3) and Figure 8b a cross-sectional view C-C of Figure 8a showing the configuration of the longitudinal fins (12).
    [0070] Figure 9a shows a longitudinal section view of the shock absorber (4) with the shock absorber shaft (9) extended to the maximum, in an alternative embodiment, with the insertable elastic hood (2) having positioning ribs (22), in the which is observed the aerial chamber (14) with the largest volume of air inside.
    [0072] Figure 9b shows in section the section AA indicated in Figure 9a, in which the configuration of the insertable elastic hood (2) is observed, for the execution with positioning ribs (22), with the maximum volume of air in the inside the air chamber (14).
    [0074] Figure 10a shows a longitudinal section view of the shock absorber (4) with the shock absorber shaft (9) inserted as far as possible into the cylindrical body of the shock absorber (8), which has positioning ribs (22), in which the air chamber (14) with the smallest volume of air inside, due to the volume of fluid displaced.
    [0076] Figure 10b shows in section the section BB indicated in Figure 10a, in which the configuration of the insertable elastic hood (2) is observed, for the execution with positioning ribs (22), with the minimum volume of air in the inside the air chamber (14).
    [0077] The following references are indicated in these figures:
    [0078] 1. - Cylindrical diaphragm assembly for reduced diameters
    [0079] 2. - Insertable elastic hood
    [0080] 3. - Centering tubular inner core
    [0081] 4. - Shock absorber
    [0082] 5. - Internal end of insertable elastic hood (2)
    [0083] 6. - Flat support area for the insertable elastic hood (2)
    [0084] 7. - Truncated cone-shaped single joint with elastic insertable hood (2)
    [0085] 8. - Cylindrical damper body (4)
    [0086] 9. - Shock absorber shaft
    [0087] 10. - Truncated cone head
    [0088] 11. - Flat outer support wall
    [0089] 12. - Longitudinal fins
    [0090] 13. - Fluid compensation chamber
    [0091] 14. - Aerial camera
    [0092] 15. - Prominence of closing plug
    [0093] 16. - External end of the insertable elastic hood (2)
    [0094] 17. - Longitudinal fin top (12)
    [0095] 18. - Atmospheric communication window with the outside
    [0096] 19. - Longitudinal striae for evacuation
    [0097] 20. - External annular surface of the insertable elastic hood (2)
    [0098] 21. - Inner annular surface of the insertable elastic hood (2)
    [0099] 22. - Positioning nerves
    [0100] 22a.- End of the positioning nerve (22)
    [0102] EXHIBITION OF A PREFERRED REALIZATION
    [0103] With reference to the drawings and references listed above, a preferred embodiment of the object of the invention is illustrated in the attached drawings, referring to a cylindrical diaphragm assembly of reduced diameter for hydraulic shock absorbers with sealing at both ends, used by in furniture self-closures, which at its outer end seals the cylindrical body of the shock absorber (8) and at its inner end performs the sealing of the shock absorber shaft (9), said cylindrical diaphragm assembly (1) being on its outer side a fluid compensation chamber (13) and on the other inner side an aerial chamber (14) characterized in that it has an insertable elastic hood (2) whose inner end (5) has an annular decrease in diameter, generating a flat area of support (6) and ending in a single-joint frusto-conical extension (7) in contact with the axis of the shock absorber (9), and acting in conjunction with an inner tubular centering male (3) provided at its internal end with a frusto-conical head (10) with a flat wall for external support and fixing (11) of said insertable elastic hood (2); and that said inner tubular centering male (3) has longitudinal fins (12) terminating said inner tubular centralizing male (3) in a protrusion of closing cap (15) that with the external end (16) of the insertable elastic hood ( 2) generates a simple joint with the cylindrical body of the shock absorber (8).
    [0104] Thus, as can be seen in Figure 1 and Figures 2 and 3, during assembly the insertable elastic cap (2) is inserted into the inner tubular centering male (3), said cylindrical diaphragm assembly (1) being fixed to in a simple way and without the need for additional elements to achieve the compensation of the fluid displaced by the shock absorber shaft (9), nor the need for additional elements to achieve sealing between both chambers (13 and 14).
    [0106] Once the diaphragm assembly is assembled (figure 4), it is inserted into the cylinder body of the shock absorber (4), with the axis of the shock absorber (9) remaining inside the cylindrical diaphragm assembly (1). Thus, said insertable elastic hood (2) that has an annular decrease in diameter, ends in a frusto-conical extension of a single joint (7), which allows manufacturing for reduced diameters that with other existing configurations would not be possible due to the difficulty in fabrication and assembly due to the use of inward pleats or double lip configurations. In this way, a simple sealing of the diaphragm assembly (1) with the damper shaft (9) is achieved, which prevents the entry of fluid into the air chamber (14) without the use of additional gaskets.
    [0108] In the damping process, in its initial state of rest, before the introduction of the shock absorber shaft (9), the cylindrical diaphragm assembly (1) would remain as shown in Figures 6a, 6b and 6c. After introducing the shock absorber shaft (9) into the cylindrical body of the shock absorber for actuating the piston, it is necessary to compensate the fluid displaced by said shock absorber shaft (9). Thus, thanks to the cylindrical diaphragm assembly (1) this volume is compensated by the air chamber (14), leaving said cylindrical diaphragm assembly (1) in its active form as can be seen in Figures 7a, 7b and 7c. In these figures we can see that at the internal end of the diaphragm assembly corresponding to the deepest area in the cylindrical body of the shock absorber (4), specifically at the internal end (5) of the insertable elastic hood (2), thanks to the configuration of flat outer support wall and fixing (11) of the inner tubular centering male (3), its position is fixed with the flat support area (6) of said insertable elastic hood (2). Thus, during compression, said insertable elastic hood (2) is prevented from shifting, resulting in poor compensation that results in ineffective cushioning.
    [0109] Thus, thanks to the inner tubular centering male (3), the insertable elastic hood (2) is fixed and centered within the cylindrical body of the shock absorber (4) and as can be seen in Figure 7c, said insertable elastic hood (2) is It adapts to the shape of the inner tubular centering male (3) which, together with the longitudinal fins (12), results in a uniform deformation of the insertable elastic hood (2), achieving controlled compensation and without generating critical areas of fatigue. Furthermore, said longitudinal fins (12) provide greater resistance to the cylindrical diaphragm assembly (1) and consequently provide greater durability and reliability.
    [0111] Additionally, to achieve a smoother deformation if possible and avoiding critical edges that may cause the diaphragm to rupture, as can be seen in Figures 6c and 7c, the top (17) of the longitudinal fins (12) is rounded.
    [0113] And so that this deformation of the insertable elastic hood (2) is uniform, it is provided that the distribution of the longitudinal fins (12) of the inner tubular centering male (3) is peripherally symmetrical.
    [0115] As can be seen in Figure 1, another characteristic of the cylindrical diaphragm assembly (1) is that there are windows (18) in the tubular part of the external end (closest to the closing plug) that allow the air contained in the interior of the aerial chamber (14) is evacuated through said atmospheric communication windows with the exterior (18) (figure 6a), so that despite the volume decrease of said air chamber (14), the pressure on the inner annular surface (21) of the insertable elastic hood (2) does not increase, avoiding antagonistic efforts that act against the maneuver of introduction of the shock absorber shaft (9) in the cylindrical damper body (8).
    [0117] In figure 9b, the longitudinal evacuation grooves (19) can also be seen, in the contour of the outer annular surface (20), which facilitate the mounting of the damper (4), evacuating the existing air in the cylindrical body of the damper (8) and avoiding the creation of air pockets in the fluid accommodation area.
    [0119] In an alternative embodiment, as can be seen in Figures 9b and 10b, which show the cross sections AA and BB indicated in Figures 9a and 10a respectively, the positioning ribs (22) emerging from the annular surface can be observed. interior (21) of the insertable elastic hood (2). These positioning ribs (22) guarantee the correct operation of the air chamber (2), balancing the quantity of fluid admitted between its outer annular surface (20) and the inner surface of the cylindrical body of the damper (8), and avoiding displacement of the internal end (5) of the insertable elastic hood (2) during the operation of the shock absorber (4).
    [0121] The essential nature of this invention is not altered by variations in materials, shape, size and arrangement of the component elements, described in a non-limiting manner, this being sufficient to proceed with its reproduction by an expert.
    权利要求:
    Claims (6)
    [1]
    1a.- Reduced diameter cylindrical diaphragm assembly for hydraulic shock absorbers with sealing at both ends, used in self-closing furniture, which at its outer end performs the sealing of the cylindrical body of the shock absorber (8) and at its inner end performs sealing the shock absorber shaft (9), said cylindrical diaphragm assembly (1) being on its outer side a fluid compensation chamber (13) and on the other inner side an aerial chamber (14) characterized in that it consists of a insertable elastic hood (2) whose inner end (5) has an annular decrease in diameter, generating a flat support area (6) and ending in a single-joint frusto-conical extension (7) in contact with the shock absorber shaft (9) , and an inner tubular centering male (3) provided at its internal end with a frusto-conical head (10) with a flat wall for external support and fixing (11) of said insertable elastic hood (2); and that said inner tubular centering male (3) has longitudinal fins (12) terminating said inner tubular centralizing male (3) in a protrusion of closing cap (15) that with the external end (16) of the insertable elastic hood ( 2) generates a simple joint with the cylindrical body of the shock absorber (8).
    [2]
    2a.- Cylindrical diaphragm assembly for reduced sealing diameters at its two ends, according to claim 1, characterized in that the top (17) of the longitudinal fins (12) of the inner tubular centering male (3) is rounded.
    [3]
    3 a.- Cylindrical diaphragm assembly for reduced sealing diameters at both ends, according to any of the preceding claims, characterized in that the longitudinal fins (12) are peripherally symmetrical in distribution.
    [4]
    4a.- Cylindrical diaphragm assembly for reduced sealing diameters at its two ends, according to any of the previous claims, characterized in that in the tubular part of the external end of the inner core tubular centering device (3) there is at least one window for atmospheric communication with the outside (18).
    [5]
    5a.- Cylindrical diaphragm assembly for reduced sealing diameters at both ends, according to any of the preceding claims, characterized in that the outer annular surface (20) of the insertable elastic hood (2) is intended to incorporate longitudinal grooves of shallow depth evacuation (19).
    [6]
    6a.- Cylindrical diaphragm assembly for reduced sealing diameters at its two ends, according to any of the preceding claims, characterized in that the insertable elastic hood (2) is provided on its inner annular surface (21), incorporating ribs circularly symmetric positioning (22) extending radially to the shock absorber axis (9) and with its end (22a) close to the surface of the shock absorber shaft (9).
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    同族专利:
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    WO2020128120A1|2020-06-25|
    US20210095736A1|2021-04-01|
    ES2768474B2|2020-10-26|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US3206185A|1962-10-16|1965-09-14|Eaton Mfg Co|Suspension system and apparatus for supporting a structure|
    US4122923A|1977-07-11|1978-10-31|Ace Controls, Inc.|Adjustable hydraulic shock absorber|
    JPS63251643A|1987-04-07|1988-10-19|Fuji Seiki Kk|Shock absorber of air return type|
    US20160096585A1|2014-10-03|2016-04-07|Showa Corporation|Diaphragm unit and suspension|
    CN108571557A|2018-05-30|2018-09-25|宁波麦维科技有限公司|Reciprocating damper|
    法律状态:
    2020-06-22| BA2A| Patent application published|Ref document number: 2768474 Country of ref document: ES Kind code of ref document: A1 Effective date: 20200622 |
    2020-10-26| FG2A| Definitive protection|Ref document number: 2768474 Country of ref document: ES Kind code of ref document: B2 Effective date: 20201026 |
    优先权:
    申请号 | 申请日 | 专利标题
    ES201831265A|ES2768474B2|2018-12-21|2018-12-21|Set of cylindrical diaphragm of reduced diameter for hydraulic shock absorbers with sealing at both ends, used in self-closing furniture|ES201831265A| ES2768474B2|2018-12-21|2018-12-21|Set of cylindrical diaphragm of reduced diameter for hydraulic shock absorbers with sealing at both ends, used in self-closing furniture|
    US16/765,399| US20210095736A1|2018-12-21|2019-10-11|Cylindrical diaphragm assembly with reduced diameter for hidraulic shock absorbers sealed at both ends, of the type employed in self-closing furniture|
    PCT/ES2019/070692| WO2020128120A1|2018-12-21|2019-10-11|Reduced-diameter cylindrical diaphragm assembly for hydraulic dampers with a seal at both ends, of the type used in self-closing mechanisms in furniture|
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