• 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:
    The invention proposes a rotatable hydraulic damper assembly, suitable for use in a pivoting case, comprising, a damper body (56), a rotor (60) disposed inside an internal cavity of the body absorber (56) which is rotatably supported within the cavity, each of the internal cavity of the damper body and the rotor (60) having at least one blade, the internal cavity further containing a hydraulic fluid , the assembly being able to be arranged along the pivot axis of the swivel case; and comprising at least one flow control valve (124), able to control the speed of opening of the pivoting trunk when connected thereto.
    公开号:FR3038356A1
    申请号:FR1656310
    申请日:2016-07-01
    公开日:2017-01-06
    发明作者:Terrance E Daul;Jeffrey T Kelly;John M Janak;Thimothy J Boerschig
    申请人:ITT Manufacturing Enterprises LLC;
    IPC主号:
    专利说明:

    "Rotary Hydraulic Damper Kit with Flow Control Valve for Swivel Storage Box"
    TECHNICAL FIELD OF THE INVENTION The invention generally relates to the field of damping systems and is more particularly related to a rotary hydraulic damper for use with a pivoting storage box, such as those commonly used in commercial aircraft.
    At least one rotatable hydraulic damper is mounted along the pivot axis of the pivoting storage bin so that the torque loads can be distributed, thereby enabling fabrication using materials of reduced cost. The rotary hydraulic damper may further be mounted on the storage bin so that the radial loads are not applied to the moving parts of the damper.
    According to one version, the rotary hydraulic damper may comprise at least one flow control valve which standardizes the opening speed of the trunk independently of the weight contained in the storage trunk, in which the damper may further comprise a mechanical stop integrated, as well as means for adjusting the open position of the storage trunk.
    STATE OF THE ART
    Storage chests, such as those installed on commercial aircraft, typically include a pivot assembly to the axis of rotation of the trunk tray.
    This assembly supports the load of the trunk and allows the trough to rotate around the axis of rotation relative to a fixed trunk box.
    In such assemblies, it is preferable to be able to effectively control the opening speed of the storage box.
    Typical trunk dampers are relatively expensive in terms of cost and manufacturing, relying on highly metallic and relatively complex assemblies having a splined central shaft which, in known manner, receives and supports both torque and loads. radials.
    In addition, these rotary boot dampers usually also use single nonvariable orifices, which means that the storage case opens unevenly depending on the weight contained inside the trunk. That is, the storage bin slowly opens when the trunk is empty compared to the opening when the trunk is full.
    There is a general need in this field to improve the manufacture of the aforementioned assemblies and also to reduce the overall complexity thereof in order to reduce the cost, while not sacrificing reliability.
    BRIEF SUMMARY OF THE INVENTION
    For this purpose the invention proposes a set of rotary hydraulic damper, adapted to be used in a pivoting trunk, said assembly comprising: - a damper body; a rotor disposed inside an internal cavity of said damper body, said rotor being rotatably supported within the cavity, each of the internal cavity of said damper body and said rotor having at least one blade, said internal cavity further containing a hydraulic fluid, said assembly being able to be arranged along the pivot axis of said pivotal box; and - at least one flow control valve, which can control the opening speed of said pivoting box when connected thereto.
    According to other features of the invention: at least one flow control valve is disposed in a central portion between chambers formed in said internal cavity, said central portion having at least two orifices for conducting the fluid between said chambers when said rotor is rotated within said internal cavity, said flow control valve having a valve member under load to vary the effective area of an outlet port when said box is opened and to create a constant flow rate between them; at least one flow control valve is adjustable from the outside; said at least one flow control valve is held under load by a spring to provide a substantially constant opening speed to said swivel case, and said valve acts as a free flow valve when closing said swivel case; said at least one flow control valve is disposed inside a manifold which is arranged at the center of the rotor, the manifold having a set of lateral openings aligned with the openings of said central portion of the damper body .
    In terms of benefits, a conventional hydraulic rotary damper uses a single orifice to provide the necessary damping force by means of the fluid.
    In these types of applications, the chest will open slowly when empty and much faster when the chest is fully loaded.
    By incorporating a flow control valve within the damper in accordance with the assembly described herein, the opening time of the storage bin can be effectively controlled and standardized regardless of the amount of load that the bin contains.
    This and other features and advantages will be apparent from the detailed description which follows, for the understanding of which reference will be made to the accompanying drawings.
    BRIEF DESCRIPTION OF THE FIGURES - FIG. 1 is a perspective view of a pivoting storage box according to the state of the art; FIG. 2 is a rear perspective view of a rotary hydraulic damper made according to one embodiment, by way of example; FIG. 3 is a front perspective view of the hydraulic damper of FIG. 2; - Figure 4 is an exploded view of the rotary hydraulic damper of Figures 2 and 3, and shown in rear perspective; - Figure 5 is an exploded view of the rotary hydraulic damper of Figures 2 to 4, and shown in front perspective; FIG. 6 is an exploded view of a mounting arrangement of the rotary hydraulic damper of FIGS. 2 to 5, including a mounting configuration for a pivotable trunk assembly, which representation is illustrated by adjacent front and rear perspective views; Figures 7 and 8 are perspective views of the mounting arrangement of the rotary hydraulic damper of Figure 6 showing an integral mechanical stop member; Figure 9 is an enlarged side elevational view of a manifold used in the hydraulic damper of Figures 2 to 8; FIG. 10 is a sectional side view of the rotary hydraulic damper of FIGS. 2 to 9 including an integrated flow control valve according to an exemplary embodiment; and FIG. 11 is a view on a larger scale of a portion of the flow control valve of FIG. 10, used in operation.
    DETAILED DESCRIPTION OF THE FIGURES
    The following is an exemplary embodiment of a rotating hydraulic damper assembly used in conjunction with a pivotal storage box, of the type commonly found on board commercial aircraft.
    It will be immediately apparent, however, that many other variations and modifications are possible that generally incorporate the inventive concepts described here.
    In addition, it will be immediately apparent that these concepts can also be applied in a similar way to other fields of application.
    In the description, certain terms such as distal, proximal, internal, external, lateral, inner and outer among others, are used to provide a suitable reference assembly in conjunction with the accompanying drawings.
    These terms are by no means limiting of the inventive concepts described here.
    In addition, the purpose of the accompanying drawings is to make the inventive concepts more immediately noticeable, but the drawings themselves and the figures are not necessarily made to scale and do not constitute a basis in this regard. As a background, a storage case according to the state of the art is shown in Figure 1, which the rotary hydraulic damper described here can be applied.
    The storage trunk 20 has a trunk tray 24 which is hingedly hinged to a pair of opposite side ends of a fixed trunk case 28. Other suitable swivel storage trunk assemblies having Different storage tanks are described by way of example in the patent application US-A1-2001 / 0253837, the content of which may be referred to by reference.
    The trunk box 28 is fixedly attached to the chassis of the aircraft, at each lateral end, so as to constitute trunk walls between which the side walls of the trunk tray 24 are respectively pivotally attached to the trunk. using a mounting arrangement to the respective parallel walls of the fixed housing, thereby providing the positioning of pivots for the storage trunk 20.
    After assembly, the interior of the trunk tray 24 and the trunk case 28 combine to define an environment 32 in which the trunk tray further includes an outer latch 31 to allow the storage trunk 20 to be selectively open or closed by a user.
    In use, the trunk tray 24 is released from a locked position (not shown in this figure) by the latch 31, and its pivoting is caused by means of a mounting arrangement attached to the stationary housing 28, to a position open, as shown, presenting the environment 32 either to place or to remove luggage (not shown).
    Additional details of storage chests are provided by way of example in the reference publication mentioned above.
    According to the embodiment given by way of example and with reference to FIGS. 2 and 3, a pair of rotary hydraulic dampers 40 are respectively attached to each end of a storage box, for example of the type illustrated in FIG. as an example in Figure 1.
    Each of the dampers 40 is disposed along a pivot axis of the storage box in a mounting arrangement between the storage bin 24 (Figure 1) and the fixed box trunk 28 (Figure 1).
    In the following description, only a rotary hydraulic damper 40 is described and shown here and to the extent that the other damper is globally a mirror image thereof in terms of its structure, operation, and mounting arrangement.
    Note however that, in an alternative embodiment, a single rotary hinge damper could be used instead of a pair of separate rotating hydraulic dampers arranged at each of the opposite lateral ends of the storage bin 20. L rotary hydraulic damper 40 according to this embodiment, illustrated assembled with FIGS. 2 and 3, is defined by a distal end 42 which can be attached to the fixed box of chest 28 (FIG. 1) using a mounting flange 46, and a opposite proximal end 48 which can be separately connected to the trunk pan 24 (Figure 1), using a set of circumferentially spaced keys 52, as will be described in more detail below.
    The relative positioning of the damper 40 according to this embodiment is based on a design of the storage box which comprises a pivoting pan 24 (FIG. 1), forming the inner member with respect to an outer casing 28 of the box (FIG. ).
    It is immediately apparent that the distal 42 and proximal ends 48 of the hydraulic rotary damper 40 may be reversed, for example, depending on the structure of the pivotal storage case, for mounting purposes.
    As illustrated in Figures 4 and 5, the rotary hydraulic damper 40 is essentially a two-part structure having a damper body 56 having an internal cavity which is sized to receive a rotor 60 which is rotatably mounted therein.
    The damper body 56 according to this embodiment has a mounting flange 46 at one end, or distal side thereof, wherein the mounting flange has a plurality of spaced apart slots 64 circumferentially disposed along an extension outer radial portion 68 thereof, as well as a central opening 72.
    A cylindrical sleeve section 76 with open end opens axially from a rear side of the mounting flange 46 and defines the internal cavity of the damper body 56, which is hollow except for a pair of blades 80 wedge-shaped and diametrically opposed, each tapering inwardly from the inside diameter of the sleeve portion 76 and toward the central opening 72 of the mounting flange 46.
    The outer surface 84 of the sleeve portion 76 of the damper body 56 is substantially cylindrical, with the exception of an abutment finger 88 made in the form of an axial extension of the outer radial portion 68 of the mounting flange 46. the outer radial portion extending radially outwardly from the outer diameter of the cylindrical sleeve section 76.
    Referring again to FIGS. 4 and 5, the rotor 60 according to this embodiment is sized to cooperate with the open-ended cylindrical sleeve portion 76 of the damper body 56. The proximal or rear end of the rotor 60 is defined by a circular plate 90 having the set of keys arranged circumferentially 52 and formed on it, and also having a central opening 94.
    Each of the keys 52 is substantially wedge-shaped and is disposed at an intermediate radius from the central opening 94. The end or forward side of the rotor 60 has a central axially extending core portion 98, as a pair of radially extending blades 102, the blades tapering outwardly from the central core portion 98 to an outer radius which is substantially equal to that of the rear circular plate 90.
    The rotor 60 is inserted into the end-end sleeve section 76 of the damper body 56 such that the core core portion 98 extends between the diametrically opposed blades 80 of the damper body 56.
    The blades 102 of the rotor 60 are fitted between the blades 80 of the damper body 56, thus defining inside a set of variable size hydraulic chambers.
    This set of chambers varies in number between two and four hydraulic chambers, depending on the position of the blades 102 of the rotor.
    It is immediately understood that the total number and shape of the blades 80, 102 used can be suitably configured as needed.
    The central core portion 98 further includes a corresponding number of small side openings, or orifices, defined therein, each being spaced radially and axially.
    According to this specific embodiment, two (2) pairs of apertures are defined, having a pair of first apertures, or orifices, 108 and a spaced pair of second apertures 11 2.
    Each of the defined orifices 108, 112 is configured in relation to a defined internal hydraulic chamber of the damper 40.
    In the drawings, only single apertures of each pair 108, 112 are shown in Figures 4 and 5.
    After assembly, a pair of seal members 118, 113, such as elastomeric rings, provide a sealing interface between the outer and inner inner flange surfaces of the rotor 60 and the damper body 56, such as this is shown more clearly, in the assembled state, in FIG.
    According to this embodiment, a manifold or drawer 116 is sized to be slidably fitted within the central core portion 98 of the assembled rotor 60.
    As shown in the figure, the collector 116 is defined by a substantially cylindrical body member having a plurality of grooves 120, 122 which receive sealing members 119, 121, FIGS. 4 and 5, and a set of openings. lateral members 123, 125 disposed within the adjacent grooves 129, 131, the openings being aligned with the openings 108, 110 of the damper 40 when the rotor is rotated within the damper body 56.
    A valve member 124 is axially disposed within the sub-chamber which is defined by the interior of the manifold with a load spring 128 operatively associated with the valve member, as will be further described.
    The manifold 116 is held in place by the retainer 130 which is mounted through the central opening 72 of the damper body 56 from the distal side. The retainer 130 includes a threaded distal portion 134 which is configured and dimensioned to cooperate with a threaded end 117 of the manifold 116, thereby retaining the components of the damper assembly described herein. The distal end of the damper body 56 described herein further includes a pair of small apertures 138 extending into the defined cavities and allowing the incorporation of fill plugs 140 to allow a suitable amount of hydraulic fluid (not shown ) to be added in the defined internal hydraulic chambers, after the assembly of the damper 40.
    Referring to Fig. 6, and in terms of mounting the hydraulic damper 40 to the swivel case, aligned openings (not shown) are provided both in the trunk tray 24, Fig. 1, and in the housing fixed boot 28, Figure 1, along the pivot axis.
    A pivoting mounting plate 150 is fixedly attached to the trunk tray 24, FIG.
    The mounting plate 150 according to this embodiment has a rear mounting flange 154 having a plurality of circumferentially spaced mounting holes 158 along an outer radial portion 162, and an axially extending open end receiving section 66. which is substantially of cylindrical configuration and defined by an inner diameter which is sized to match correspondingly with the outer diameter of the sleeve section 76 of the damper body 56.
    The mounting plate 150 further comprises a set of elements configured to cooperate with the keys 52 on the proximal side of the rotor 60.
    According to this embodiment, three (3) keys 155 are used, each of the keys being substantially wedge-shaped and arranged symmetrically about an intermediate radial distance from the center of the flange 154, and with a spacer 170 which is introduced into the receiving portion 156 thereof.
    In this embodiment, the spacer 170 and the associated keys 155 on the front side of the mounting plate 150 combine to form a key path set which cooperates with the keys 52 of the rotor 60. The spacer 170 is preferably elastomeric material so as to catch manufacturing tolerances and also to provide an alignment of manufacturing sets and reduce the noise or vibration effects of the storage trunk.
    The mounting flange 46 of the damper body 56 is fixedly attached to the trunk body 28, FIG. 1, using fasteners (not shown) attached through the mounting slots 64 formed on the outer radial portion 68 and the trunk case 28, Figure 1, respectively.
    When assembled, the damper body 56 extends through an opening (not shown) of the trunk fixed housing 28, FIG. 1, such that the outer diameter of the damper body is attached to the housing. inside the inner diameter of the opening.
    As the swivel trunk tray 24, Fig. 1, rotates, the engagement of the mounting plate with the keys 52 causes rotation of the rotor 60 with the trunk tray 24, Fig. 1, and within the damper body 56, while the damper body remains fixed mounted on the trunk case 28, Figure 1.
    Referring to Figures 7 and 8, the receiving section 162 of the pivoting mounting plate 54 further includes a slot 174 which is cut axially from an outer surface on a circumferential portion thereof.
    The slot function is to provide a mechanical stop to the trunk tray 24. That is, when the trunk tray 24 swiveling, Figure 1, is rotated in the opening direction, the mounting plate and the rotor attached thereto is rotated between the positions illustrated in FIGS. 7 and 8, until the stop finger 88 meets the end of the slot 174.
    Referring to Figures 9-11, the description here of the flow control valve (load compensation) will be made in connection with this exemplary embodiment.
    As noted above, the central core portion 98 of the rotary hydraulic damper 40 described herein includes a first set of holes 108 and a second adjacent set of holes 112, each spaced apart to provide high and low pressure regions. pressure in terms of displacement of the hydraulic fluid contained through the hydraulic chambers defined inside the damper.
    According to this embodiment, and when the trunk tray 24, FIG. 1, is open, the tray is pivoted about the pivot axis, thus causing rotation of the rotor 60 on the basis of key connections with the mounting plate 150 of the swivel case.
    The relative movement of the rotor blades 102 inside the damper 40 thus causes the hydraulic fluid contained under high pressure to move through the inlet holes 108 of the core section 98 towards the opposite regions, or lower chambers. pressure, of it and inside the sub-chamber defined by the interior of the collector 116.
    The inlet of the fluid into the sub-chamber is caused when the fluid flows through the holes 108 and through the holes 123 via the outer groove 129 along a first defined path of fluid flow. The interposed valve element 124 is loaded by the spring 128 arranged axially in opposition to the fluid moving opposite the inlet holes 123.
    As the fluid pushes against the force of the loaded spring 128 on the basis of a pressure gradient developed as the fluid flows through the intermediate orifice 126 into the valve member 124, the element valve 124 is moved toward the outlet ports 125, and partially interrupts the flow of fluid through the outlets 125, creating a substantially constant rate of fluid flow, regardless of the applied force due to the flow effect. spring compensation 128.
    Details of the theory of this particular valve are provided in US-B-7,967,16 to the complete contents of which reference may be made.
    Upon opening the trunk tray 24 and once the hydraulic fluid flows through the outlets 125, this fluid flows into the groove 131 of the manifold 116 and out through the holes 112 in the region low pressure created by the blades 102 of the rotor and the blades 80 of the stator.
    The foregoing description relates to the central axial positioning of the flow control valve as an exemplary embodiment.
    However, there are design variations that can be made easily.
    For example, separate flow control valves implementing the above principles could each be positioned relative to the rotor blades or the stator blades.
    In addition, modifications may be included as an option as to the spring loaded nature of the flow control valve described herein, and the accessibility to the manifold 116.
    For example, an adjustment member (not shown) may be added so that adjustments can be made to the preload of the spring 128 to change the rate of fluid flow through the valve, thereby changing the speed of flow. opening the trunk tray 24.
    In addition, adjustments to the system described herein can be made mechanically with respect to the fluid return path, for example, by allowing additional fluid to flow to make closing the trunk tray easier.
    When the trunk pan 24 is closed, the rotor 60 will rotate in the opposite direction causing the fluid to flow into the damper in the directly opposed position.
    Additional fluid flow can be created through the use of a controlled valve that opens when the trunk is closed.
    This additional flow of fluid allows the damper to offer less resistance to movement, thus making it easier to close the trunk tray 24.
    One embodiment of this valve is shown in FIG.
    As the fluid flows into the hole 112 and into the groove 131 of the manifold 116, the fluid can flow through the annular zone 132 and force the sealing member 121 away from the annular zone 132.
    Cylindrical sections 133, FIG. 9, cut in the wall of the collector 116, prevent the sealing element 121 from sealingly engaging the wall and thus allowing the fluid to flow under the sealing element 121. , through the cylindrical sections 133 in the groove 129, then out through the openings 128 formed in the damper and in the low pressure region created by the blades 102 of the rotor and the blades 1 80 of the stator.
    Additional details regarding various linear versions of the previous valve structure are available in the aforementioned US-B1-7,976.116 patent.
    Attaching the rotary hydraulic damper as described herein and along the pivot axis of the storage bin 20, FIG. 1, as well as spreading the torque loads away, eliminating the common traditional fluted shaft at most dampers, the main components of the damper can be conveniently made from light and less expensive materials, such as molded plastics.
    As a result, manufacturing costs are significantly reduced.
    In addition, the removal of a splined shaft in the center of the damper described here allows the inclusion of the load compensation valve, without particular impact on the bulk.
    This results in an additional feature included in the set.
    Although exemplary embodiments have been described herein, it is readily apparent that there are many variations and modifications that could be further employed in the developments of the inventive concepts described herein, and the claims which follow. .
    权利要求:
    Claims (5)
    [1" id="c-fr-0001]
    A rotatable hydraulic damper assembly (40), adapted for use in a pivotable trunk (20), said assembly comprising: - a damper body (56); a rotor (60) disposed inside an internal cavity of said damper body (56), said rotor being rotatably supported within the cavity, each of the internal cavity of said damper body and said rotor (60) having at least one blade (80, 102), said internal cavity further containing a hydraulic fluid, said assembly being positionable along the pivot axis of said pivotal case; and at least one flow control valve (124) capable of controlling the speed of opening of said pivotal box when connected to it.
    [2" id="c-fr-0002]
    Rotary hydraulic damper assembly according to claim 1, characterized in that said at least one flow control valve (124) is disposed in a central portion between chambers formed in said internal cavity, said central portion comprising at least two orifices for conducting fluid between said chambers as said rotor (60) is rotated within said internal cavity, said flow control valve having a valve member under load (128) to vary the effective area of an outlet port when said trunk (20) is open and to create a constant flow rate therebetween.
    [3" id="c-fr-0003]
    3. Rotary hydraulic damper assembly according to claim 1, characterized in that said at least one flow control valve (124) is adjustable from the outside.
    [4" id="c-fr-0004]
    The rotary hydraulic damper assembly of claim 1, characterized in that said at least one flow control valve (124) is held under load by a spring (128) to provide a substantially constant opening speed to said trunk pivoting member (20), and in that said valve acts as a free-flow valve when closing said pivotal box.
    [5" id="c-fr-0005]
    Rotary hydraulic damper assembly according to claim 2, characterized in that said at least one flow control valve (124) is disposed inside a manifold (116) which is disposed at the center of the rotor ( 60), the manifold (116) having a set of side openings (123, 125) aligned with the openings (108, 110) of said central portion of the damper body (56).
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    同族专利:
    公开号 | 公开日
    US9371674B2|2016-06-21|
    DE102013205373A8|2013-11-28|
    DE102013205373B4|2022-03-17|
    FR3038356B1|2019-11-29|
    FR2988454B1|2016-08-19|
    BR102013006845A2|2016-02-23|
    DE102013205373A1|2013-09-26|
    US20130247330A1|2013-09-26|
    FR2988454A1|2013-09-27|
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    USD784905S1|2013-02-12|2017-04-25|C&D Zodiac, Inc.|Storage bin for aircraft|
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    法律状态:
    2016-07-19| PLFP| Fee payment|Year of fee payment: 4 |
    2017-03-27| PLFP| Fee payment|Year of fee payment: 5 |
    2018-03-26| PLFP| Fee payment|Year of fee payment: 6 |
    2019-03-25| PLFP| Fee payment|Year of fee payment: 7 |
    2020-03-25| PLFP| Fee payment|Year of fee payment: 8 |
    2021-12-10| ST| Notification of lapse|Effective date: 20211105 |
    优先权:
    申请号 | 申请日 | 专利标题
    US201261615620P| true| 2012-03-26|2012-03-26|
    US13/796,002|US9371674B2|2012-03-26|2013-03-12|Rotary hydraulic damper for pivoting stowage bin|
    US13796002|2013-03-12|
    FR1352481A|FR2988454B1|2012-03-26|2013-03-20|"ROTARY HYDRAULIC SHOCK ABSORBER ASSEMBLY FOR A SWIVEL STORAGE BOX"|
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