法国专利FR3066087A1 ADJUSTABLE STIFFENER ELEMENT FOR SLEEP OR SEAT FURNITURE

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专利摘要:
The invention relates to the field of furniture for sleeping or sitting. In particular, the invention relates to a flexible element (10) with adjustable stiffness along a compression axis (Z), comprising a compression spring (50). In order to allow adjustment of the stiffness of the flexible element (10), the latter further comprises a mechanism (150) coupled to the compression spring (50) to be actuated, for a movement in a direction different to that of the compression axis (Z), by compression of the compression spring (50) along the compression axis (Z), and an adjusting device for selectively restricting and releasing the movement of the mechanism (150). The invention also relates to a supply (200) comprising a plurality of such flexible elements (10), as well as a method for adjusting the stiffness of this flexible element (10).
公开号:FR3066087A1
申请号:FR1754172
申请日:2017-05-12
公开日:2018-11-16
发明作者:Geraud Cailley；Pascal Lobry；Jacques Lobry
申请人:Tournadre Standard Gum SA；
IPC主号:

专利说明:

Invention background
The present disclosure relates to the field of furniture and more particularly a flexible element with adjustable stiffness for sleeping or seating furniture, a supply comprising a plurality of such flexible elements with adjustable stiffness and a method for adjusting the stiffness of a flexible element for bed or seat furniture.
In order to make a seat, back or sleeping surface adaptable to the preferences and anatomy of different users, supplies, such as mattresses or box springs, with flexible elements with adjustable stiffness have been previously disclosed, by example in EP 1 386 564 Al, EP 1 155 643 A2, WO 2008/015235, WO 96/27312, US 4,667,357 or DE 10 2008 050 108 Al. Typically, the stiffness of the elements is adjusted there with restrictions on their mechanical deformation . For this, however, the proposed mechanisms have significant complexity and / or bulk.
Subject and summary of the invention
The present disclosure aims to remedy these drawbacks by proposing a flexible element with adjustable stiffness along a compression axis, for seating or sleeping furniture, with a simple structure and a limited space requirement.
According to one aspect of this disclosure, this object can be achieved thanks to the fact that the flexible element, comprising a compression spring, also comprises a mechanism coupled to the compression spring to be actuated, for a movement in a direction different from that of the compression axis, by compression of the compression spring along the compression axis.
Thanks to these arrangements, it is possible to obtain a flexible element with stiffness that is easily adjustable by restricting or releasing the movement of the mechanism. Indeed, when the movement of the mechanism is restricted by the adjustment device, this stiffens the compression spring, while when this movement is no longer restricted, the mechanism no longer opposes the compression of the compression spring .
The mechanism may in particular comprise an elastic articulation connected in overhang, in a direction orthogonal to the compression axis, to the compression spring, with a torsion axis orthogonal to the compression axis, and an adjustment device for selectively restrict and release a rotation of the elastic joint around the axis of torsion. Such a mechanism can be easily integrated into the flexible element without large additional space around the spring.
The mechanism may also include a rod secured to the elastic articulation in rotation about the axis of torsion and in which the adjustment device comprises a stop movable between a first position restricting rotation of the rod around the axis of torsion and a second position releasing the rotation of the rod around the axis of torsion. The adjustment device can thus be implemented in a particularly simple manner.
The adjustment device may comprise a rotary part integral with the stop, the rotary part being able to rotate, between the first position and the second position, around the compression axis.
The rod can be elastically flexible. Thus, it can stiffen rather than block the elastic joint when the rotation of the rod is restricted in the first position of the stop of the adjustment device. Furthermore, the rod can be curved. Configured in this way, it can in particular at least partially bypass the compression spring, to be arranged therein compactly, without enlarging the imprint of the flexible element in a plane perpendicular to the compression axis and without interfering with compression. of the compression spring.
The compression spring can in particular be helical. In particular, such a helical compression spring can be configured as a rod wound in a helix around the compression axis. The compression according to the compression tax can then translate into a torsional stress of this helical rod around the propeller. Thus, this torsional stress can in particular contribute to the rotation of the elastic articulation and of the rod secured thereto around the axis of torsion. The flexible element may in particular comprise a plurality of coaxial compression springs. In particular, this plurality of coaxial compression springs can comprise several identical coaxial compression springs with a regular angular offset between them. It is thus possible to increase the lateral stability of the flexible element and reduce the risk of buckling under compression. Furthermore, the flexible element may comprise a plurality of mechanisms, each of which is coupled to a respective compression spring from among the plurality of compression springs to be actuated, for movement in a direction different from that of the compression axis, by compression, along the compression axis, of the respective compression spring, the adjustment device being able to selectively restrict and release the movement of the plurality of mechanisms simultaneously. In particular, each mechanism can comprise an elastic articulation, connected in overhang, in direction orthogonal to the compression axis, to the respective compression spring, with a respective torsion axis orthogonal to the compression axis. In this flexible element, the adjustment device can then be able to selectively restrict and release a rotation of each elastic articulation of the plurality of mechanisms relative to the respective axis of torsion.
In addition, each mechanism of the plurality of mechanisms may comprise a rod integral, in rotation about a respective axis of torsion, with the respective elastic joint. The adjustment device can then comprise a plurality of stops movable between a first position restricting rotation of the rods of the plurality of mechanisms around the respective torsion axes and a second position releasing rotation of the rods around the respective torsion axes. Thus, the adjustment device can act simultaneously on the stiffness of several compression springs.
In order to avoid the risk of collision or interference between the rods of the plurality of mechanisms and the springs of the plurality of springs, two rods of the plurality of mechanisms can be connected by a joint. This articulation can in particular comprise a flexible sleeve receiving respective ends of the two rods. The flexible sleeve can in particular be split in order to facilitate its bending.
The plurality of compression springs may in particular comprise compression springs arranged mechanically in parallel and / or in series. It can furthermore be at least partially injection molded. Injection molding can in particular make it possible to facilitate the production of flexible elements at least partially made of organic polymer material, in particular thermoplastic. However, other materials, for example metallic, as well as other production methods, such as for example additive manufacturing, can be used alternatively or in addition to organic polymer materials and molding or extrusion, respectively.
Another aspect of the present disclosure relates to a supply of seat, backrest or bed comprising a plurality of such flexible elements. This supply can in particular be a box spring or a mattress.
In such a supply, the adjacent flexible element adjustment devices among the plurality of flexible elements can be mechanically coupled for common actuation. In particular, the supply may comprise pivots mechanically coupling the adjuster devices of adjacent flexible elements among the plurality of flexible elements for common actuation.
Yet another aspect of the present disclosure relates to a method of adjusting stiffness, along a compression axis, of a flexible element. This flexible element comprises a compression spring aligned with the compression axis and a mechanism coupled to the compression spring to be actuated, for a movement in a direction different from that of the compression axis, by compression of the following compression spring Compression tax. The stiffness adjustment method comprises a step in which an adjustment device selectively restricts or releases the movement of the mechanism.
BRIEF DESCRIPTION OF THE DRAWINGS The invention will be better understood and its advantages will appear better on reading the detailed description which follows, of embodiments shown by way of nonlimiting examples. The description refers to the accompanying drawings in which: - Figure IA is a perspective view of a flexible element with adjustable stiffness, relaxed, with its adjustment device in the position of greatest stiffness; - Figure IB is a side view of the flexible element of Figure IA; - Figure IC is a sectional view of the flexible element of Figure IB along the plane IC-IC; - Figure 1D is a sectional view of the flexible element of Figure IC along the same plane, but with its adjustment device in the position of lower stiffness; - Figure 2A is a side view of the flexible element of Figure IA, relaxed, without its adjustment device; - Figure 2B is a side view of the flexible element of Figure IA, compressed, without its adjustment device; - Figure 3A is a perspective view of a supply comprising a plurality of flexible elements similar to that of Figure IA, in the position of greatest stiffness; - Figure 3B is a sectional view of the supply of Figure 3A along the plane IIIB-IIIB; - Figure 3C is a detail of Figure 3B; - Figure 4A is a perspective view of the supply of Figure 3A, in the lower stiffness position; - Figure 4B is a sectional view of the supply of Figure 4A along the plane IVB-IVB; - Figure 4C is a detail of Figure 4B; - Figure 5A is a perspective view of the supply of Figure 3A, in the intermediate position; - Figure 5B is a sectional view of the supply of Figure 5A along the plane VB-VB; - Figure 5C is a detail of Figure 5B; - Figure 6A is a perspective view of an alternative supply also comprising a plurality of flexible elements with adjustable stiffness, in the position of greatest stiffness; - Figure 6B is a perspective view of the supply of Figure 6A, cut away in the plane VIB-VIB; - Figure 6C is a perspective view of a supply of Figure 6A, cut away in the plane VIB-VIB, in the lower stiffness position; - Figures 7A, 7B and 7C are, respectively, a perspective view, a side view and a top view of an alternative flexible element with adjustable stiffness, relaxed, with its adjustment device in the position of greatest stiffness; - Figures 8A, 8B and 8C are, respectively, a perspective view, a side view and a top view of an alternative flexible element with adjustable stiffness, compressed, with its adjustment device in the lower stiffness position; and - Figure 9A, 9B and 9C illustrate the alternative flexible element of Figures 8A to 8C, compressed, with its adjustment device in the position of greatest stiffness.
Detailed description of the invention
A flexible element 10, intended for seat or bed furniture, and whose stiffness along a compression axis Z is adjustable is illustrated in FIGS. 1A to 1D. As illustrated more clearly in FIG. 2A, this flexible element 10 can comprise several elastic parts arranged in series along the compression axis Z. In particular, it can comprise a first elastic part 20 and a second elastic part 30 mechanically arranged in series along the compression axis Z and connected to each other by a connection 40 which can be located, as in the example illustrated, in the center of the flexible element 10.
Each of the two elastic parts 20, 30 can comprise at least two compression springs 50 mechanically arranged in parallel as in the example illustrated. In particular, these compression springs 50 can be, as in the example illustrated in FIG. 1A, helical springs formed by rods wound in a helix H around the compression axis Z. Furthermore, in each of the parts elastic 20, 30, the angular offset around the compression axis Z between the helices of the helical and coaxial compression springs 50 can be regular. Thus, in the example illustrated, the angular offset between the compression springs 50 of each elastic piece 20, 30 can be 360 ° / x, where x is the number of compression springs 50 in parallel in each elastic piece 20, 30. Thus, for a number x of compression springs 50 of, for example, two, the angular offset can be 180 °.
In the example illustrated, each elastic piece 20, 30 may further comprise a connector 60, 70 complementary, respectively, to the connector 70, 60 of the other elastic piece 30, 20 to form the connection 40, as well as a support platform 80, 90. The connectors 60, 70 and the support platforms 80, 90 can be arranged on opposite ends of the respective elastic parts 20, 30. Thus, when the elastic parts 20, 30 are assembled in series, by connecting their respective connectors 60, 70, to form the flexible element 10, as in the example illustrated, this flexible element 10 can extend from one to the other of the support platforms 80, 90, along the compression axis Z.
In each elastic piece 20, 30 of the example illustrated, one end of each compression spring 50 can be connected directly to the respective connector 60, 70, while the other end can be connected to the support platform 80, 90 to through an elastic joint 100. Each of these elastic joints 100 may in particular have a torsion axis Y substantially orthogonal to the compression axis Z and be connected to the respective compression spring 50 by a more rigid arm 110, oriented in a radial direction substantially orthogonal to the compression axis Z and to the respective torsion axis Y, so that the elastic joint 100 is cantilevered with the compression spring 50 in the direction orthogonal to the axis of compression Z. As in the example illustrated, each elastic articulation 100 can take the form of a torsion rod connecting the arm 110 to the support platform 80, 90. However, other forms are also possible.
In addition, each elastic piece 20, 30 of the illustrated example may also include other rods 120 secured to the arms 110. More specifically, each rod 120 may extend from a first end 121 secured to a respective arm 110 at a second end 122. Each second end 122 can be offset relative to the axis of torsion Y of the elastic joint 100 corresponding to the respective arm 110 in a plane orthogonal to this axis of torsion Y, so as to rotate around the torsion axis Y with the respective arm 110. In particular, between these first and second ends 121, 122, each rod 120 can be curved, and in particular follow a helix wider than those of the compression springs 50, so as to bypass them so that the first and the second end 121, 122 of each rod 120 are located on diametrically opposite sides of the springs 50, while also being mutually offset in a direction parallel to the compression axis Z. The rods 120 are moreover elastically flexible.
Thus, each elastic articulation 100 forms, with the corresponding arm 110 and rod 120, a mechanism 150 configured so that the compression of the respective compression spring 50 in the compression axis Z actuates a movement of the second end of the rod 120 in radial direction with respect to the compression axis Z, as illustrated in Figure 2B.
As in the example illustrated, the second end 122 of each rod 120 of one of the elastic parts 20, 30 can be connected by an articulation to the second end 122 of a rod 120 opposite to the other of the elastic parts 30 , 20. More specifically, the corresponding second ends 122 of each pair of opposite rods 120 can be received in opposite end pieces 131, 132 of a flexible sleeve 130 which can thus form such a joint. The flexible sleeves 130 can in particular be split perpendicular to their main axis, so as to increase their flexibility. Apart from the elastic parts 20, 30, the flexible element 10 can also comprise a device for adjusting the stiffness of the flexible element 10 in the compression axis Z. This adjustment device can in particular be configured as a rotary part 140, as illustrated in Figures IA to IC. This rotary part 140 can be retained by the connectors 60, 70 so as to be rotatable around the compression axis Z. As can be seen in particular in FIG. 1C, the rotary part 140 can comprise several openings 141 traversed by the sleeves flexible 130 in direction parallel to the compression axis Z. Each opening 141 may extend over a respective arc around the compression axis Z. More particularly, along this respective arc, each opening 141 may include a first section 142 and a second section 143, the first section 142 possibly being narrower than the second section 143 in the radial direction relative to the compression axis Z. More specifically, the outer edge of each opening 141 may be closer to the compression axis Z in the first section 142 than in the second section 143, and thus form a radial stop 145 to restrict a radial displacement of the m respective flexible sleeve 130, and therefore also second ends 122 of rods 120 fitted into this flexible sleeve 130, with respect to the compression axis Z. The rotary part 140 can thus rotate between a first position, in which the flexible sleeves 130 are received in the first sections 142 of the openings 141 and the stops 145 restrict the radial spacing of the flexible sleeves 130, and therefore of the second ends 122 of the rods 120 relative to the compression axis Z, as illustrated in FIGS. IC, and a second position in which the flexible sleeves 130 will be received in the second, wider sections 143, of the openings 141, thus freeing the flexible sleeves 130 is the second ends 122 of the rods 120, as illustrated in FIG. 1D, for allow them greater radial spacing relative to the compression axis Z, such as that illustrated in FIG. 2B.
The elastic parts 20, 30, the rotary part 140 and the flexible sleeves 130 can be made of organic polymer material, in particular thermoplastic material such as, for example, a polyamide, a polyoxymethylene, or a copolyester. However, other materials, for example metallic, can be used alternatively or in combination with such polymeric materials. The elastic parts 20, 30 and the rotary part 140 can in particular be molded, in particular by injection. The flexible sleeves 130 can in particular be cut from an extruded part. However, other production methods, such as, for example, additive manufacturing, can be used alternatively or in addition to molding or extrusion.
The operation of the flexible element 10 of the illustrated example can also be described with reference to Figures IA to 2B. When the rotary part 140 forming a stiffness adjustment device is in its second position, with the flexible sleeves 130 received in the second, wider sections 143, of the openings 141, and the flexible element 10 is subjected to a force of compression F along the compression axis Z, between the support platforms 80, 90, the compression springs 50 will be compressed and the arms 110 connecting them to the elastic joints 100 rotate around the axis of torsion Y, with the rods 120. By this rotation of the rods 120 around the axis of torsion Y, the second ends 122 of the rods 120 can deviate radially from the compression axis Z, without opposition to the width of the second sections 143 of the openings 141 of the rotating part 140, as illustrated in FIG. 2B. The flexible element 10 thus remains relatively flexible in compression.
If the rotary part 140 is however turned, around the compression axis Z, towards its first position, so that the flexible sleeves 130 are received in the first, narrower sections 142, of the openings 141, the stops 145 can restrict the radial spacing, relative to the compression axis Z, of the flexible sleeves 130 and therefore of the second ends 122 of the rods 120, thus restricting the rotation of the rods 120 around the axes of torsion Y of the respective elastic joints 100 when the flexible element 10 is subjected to a compression F along the compression axis Z. Even if the rods 120 can be elastically flexible, in order to allow their return to the relaxed starting position when the compression F ceases, their restriction by the stops 145 will also indirectly restrict the rotation of the arms 110 around the axis of torsion Y, thereby stiffening the elastic joints 100, or even the springs 50, since the twist around their respective helices can also be indirectly restricted as well. In this way, the flexible elements 10 can have a stiffness in the compression axis Z which is substantially greater when the rotary part 140 is in its first position than when the rotary part 140 is in its second position.
To form a supply of bedding such as a mattress or box spring, it is possible to group several flexible elements such as those described above. Thus, FIGS. 3A, 3B, 4A, 4B, 5A and 5B illustrate the core of a mattress 200 on a bed 300. The core of this mattress 200 can comprise a plurality of flexible elements 10, arranged as in the example illustrated in several rows and columns in a plane perpendicular to the compression axes Z. The support platforms 80, 90 of adjacent flexible elements 10 can be connected by flexible connections 210.
In order to allow simultaneous actuation of the rotating parts 140 of the set of flexible elements to rotate them simultaneously between their first and second positions, they can be mechanically coupled to each other. More specifically, as illustrated in detail in FIGS. 3C, 4C and 5C, each of the rotating parts 140 may for example comprise at least one flexible blade 220, arranged on the periphery of the rotating part 140, oriented in a plane perpendicular to the axis compression Z, and bent radially outward with respect to the compression axis Z.
Flexible blades 220 of rotating parts 140 of adjacent flexible elements 10 can be connected by pivots 230 with pivot axes parallel to the compression axes Z of the flexible elements 10. The distance between each pivot 230 and the compression axes Z of each of the two adjacent flexible elements 10 whose pivot 230 connects the rotating parts 140 may be greater than half the distance between the compression axes Z of the two adjacent flexible elements 10, so that, when the rotating parts 140 of the elements flexible 10 adjacent are in their first respective positions, as illustrated in Figure 3C, the pivot 230 is on one side of a flat plane P connecting the compression axes Z of the two adjacent flexible elements 10, when the rotating parts 140 of adjacent flexible elements 10 are in their respective second positions, as illustrated in FIG. 4C, the pivot 230 is on the other side of the plane P and that, to move the rotating parts 140 of the flexible elements 10 adjacent from their first positions to their respective second positions, the pivot 230 must pass through an intermediate position, in the plane P, in which the flexible blades 220 are elastically stressed, against their respective camber, towards the compression axes Z of their respective flexible elements 10, as illustrated in FIG. 5C.
Thus, the elasticity of the flexible blades 220 makes it possible to provide return forces towards, respectively, the first and second positions of the rotating parts 140 of the flexible elements 10 adjacent to each side of the intermediate position, to maintain these first and second positions of stably and avoid the involuntary passage from one to the other, and therefore an involuntary change in the stiffness of the flexible elements 10. The user can make a conscious effort, against the elasticity of the flexible blades 220, to pass through the intermediate position in order to moving the rotating parts 140 between their first and second positions.
An alternative embodiment is illustrated in FIGS. 6A to 6C. In this alternative example, the flexible elements 10 are similar to those of the first example, and similar components are therefore given the same reference numbers in the drawings. The rotating parts 140 in this second example can be simpler than those of the first example, and simply comprise radial arms 146 carrying the radial stops 145 at their respective ends but, as in the first example, each rotating part 140 can rotate between a first position in which these radial stops 145 restrict the radial spacing of the flexible sleeves 130, and therefore also of the second ends 122 of the rods 120 fitted in these flexible sleeves 130, relative to the compression axis Z, and a second position in which the rotating part 140 no longer restricts this radial spacing movement.
Furthermore, in this alternative embodiment, the pivots 230 may not connect the rotating parts 140 directly to adjacent rotating parts 140, but rather to control members 300, which can be arranged between the rows of flexible elements 10 and moved in a straight line between the first and second position. The flexible blades 220 can moreover, in this alternative example, be integrated into the control members 300, in such a way that these control members 300 pass through an intermediate position, between the first and second position, in which the flexible blades 220 are constrained elastically, against their respective camber.
However, the principle of elastic stress in the intermediate position to ensure the return to one or other of the first and second positions can even be applied without such flexible curved blades. In fact, the flexible elements 10 can have an elasticity in bending perpendicular to their compression axes Z, so as to allow an elastic lateral movement of the rotating parts 140 in their intermediate positions between the first and second positions. In this case, the elasticity of the flexible elements 10 perpendicular to their compression axes Z could provide the return forces towards the first and second positions on each side of the intermediate position.
Although the present invention has been described with reference to specific examples, it is obvious that various modifications and changes can be made to these examples without departing from the general scope of the invention as defined by the claims.
Thus, FIGS. 7A to 9C illustrate yet another example of flexible element 10, intended for bed bases rather than mattresses. In this example, the flexible element 10 is similar to those of the first two examples, and the like components are therefore given the same reference numerals in the drawings. This alternative flexible element 10 can comprise a single elastic part 20 and a rotating part 140. The elastic part 20 can comprise at least two compression springs 50 mechanically arranged in parallel as in the example illustrated. In particular, these compression springs 50 can be partially helical springs formed by rods wound in part following a helix H around the compression axis Z. As illustrated in the figures, the compression springs 50 can comprise bent segments 51 diverging from the helix H so as to minimize their bulk while limiting the risk of interference with other parts of the flexible element 10. The rotary part 140 may be similar to those of the second example and include radial arms 146 carrying receptacles 147 at their respective ends. These receptacles 147 can be configured to receive, in the first position of the rotating part 140, the second ends 122 of the rods 120, restricting their radial spacing relative to the compression axis Z when the compression springs 50 are compressed along the compression axis Z, as illustrated in FIGS. 9A to 9C. As in the previous examples, the rotary part 140 can however rotate between this first position and a second position in which the rotary part 140 no longer restricts this radial spacing movement.
In addition, individual features of the various examples and embodiments discussed can be combined in additional embodiments. Therefore, the description and the drawings should be considered in an illustrative rather than restrictive sense.

权利要求:
Claims (19)
[1" id="c-fr-0001]
1. Flexible element (10), for sleeping or seating furniture, with adjustable stiffness along a compression axis (Z) and comprising: a compression spring (50); a mechanism (150) coupled to the compression spring (50) for being actuated, for a movement in a direction different from that of the compression axis (Z), by compression of the compression spring (50) along the axis of compression (Z); and an adjustment device for selectively restricting and releasing movement of the mechanism (150).
[2" id="c-fr-0002]
2. flexible element (10) according to claim 1, in which the mechanism (150) comprises an elastic articulation (100) connected in overhang, in direction orthogonal to the compression axis (Z), to the spring of compression (50), with a torsion axis (Y) orthogonal to the compression axis (Z) and the adjustment device (140) is configured so as to selectively restrict and release a rotation of the elastic joint (100) with respect to the axis of torsion (Y).
[3" id="c-fr-0003]
3. flexible element (10) according to claim 2, wherein the mechanism (150) further comprises a rod (120) integral with the elastic joint (100) rotating around the axis of torsion (Y) and in which the adjusting device comprises a stop (145) movable between a first position restricting rotation of the rod (120) around the axis of torsion (Y) and a second position releasing rotation of the rod (120) around the torsion axis (Y).
[4" id="c-fr-0004]
4. flexible element (10) according to claim 3, wherein the adjustment device comprises a rotary part (140) integral with the stop (145), the rotary part (140) being able to rotate, between the first position and the second position, around the compression axis (Z).
[5" id="c-fr-0005]
5. flexible element (10) according to any one of claims 3 or 4, wherein the rod (120) is elastically flexible.
[6" id="c-fr-0006]
6. flexible element (10) according to any one of claims 3 to 5, wherein the rod (120) is curved.
[7" id="c-fr-0007]
7. Flexible element (10) according to any one of the preceding claims, in which the compression spring (50) is helical.
[8" id="c-fr-0008]
8. Flexible element (10) according to any one of the preceding claims, comprising a plurality of coaxial compression springs (50).
[9" id="c-fr-0009]
9. flexible element (10) according to claim 8, comprising a plurality of mechanisms (150) each of which is coupled to a respective compression spring (50) among the plurality of compression springs (50) coaxial to be actuated, for a movement in a direction different from that of the compression axis (Z), by compression, along the compression axis (Z), of the respective compression spring (50), the adjustment device being able to selectively restrict and release moving the plurality of mechanisms (150) simultaneously.
[10" id="c-fr-0010]
10. Flexible element (10) according to claim 9, in which each mechanism (150) of the plurality of mechanisms (150) comprises an elastic articulation (100) connected in overhang, in a direction orthogonal to the axis of compression (Z), to the respective compression spring (50), with a respective torsion axis (Y) orthogonal to the compression axis (Z), and in which the adjustment device is capable of selectively restricting and releasing a rotation of each elastic joint (100) of the plurality of mechanisms (150) relative to the respective axis of torsion (Y).
[11" id="c-fr-0011]
11. flexible element (10) according to claim 10, wherein each mechanism (150) of the plurality of mechanisms (150) further comprises a rod (120) integral, rotating around the respective axis of torsion (Y) , of the respective elastic joint (100), and in which the adjustment device comprises a plurality of stops (145) movable between a first position restricting rotation of the rods (120) of the plurality of mechanisms (150) around the axes torsional (Y) and a second position releasing the rotation of the rods (120) of the plurality of mechanisms (150) around the respective torsional axes (Y).
[12" id="c-fr-0012]
12. flexible element (10) according to claim 11, wherein two rods (120) of the plurality of mechanisms (150) are connected by a hinge.
[13" id="c-fr-0013]
13. flexible element (10) according to claim 12, wherein the joint comprises a flexible sleeve (130) receiving respective ends of the two rods (120).
[14" id="c-fr-0014]
14. flexible element (10) according to any one of claims 8 to 13, wherein the plurality of compression springs (50) comprises compression springs (50) mechanically arranged in parallel and / or in series.
[15" id="c-fr-0015]
15. Flexible element (10) according to any one of the preceding claims, molded at least partially by injection.
[16" id="c-fr-0016]
16. Assembly (200) for seat, backrest or bed comprising a plurality of flexible elements (10) according to any one of the preceding claims.
[17" id="c-fr-0017]
17. An assembly (200) according to claim 16, in which the flexible element adjustment devices (10) adjacent among the plurality of flexible elements (10) are mechanically coupled for common actuation.
[18" id="c-fr-0018]
18. An assembly (200) according to claim 17, further comprising pivots (230) mechanically coupling the adjuster devices of flexible elements (10) adjacent among the plurality of flexible elements (10) for common actuation.
[19" id="c-fr-0019]
19. A method of adjusting stiffness, along a compression axis (Z), of a flexible element (10), for sleeping or seating furniture, comprising a compression spring (50) and a mechanism (150) coupled to the compression spring (50) to be actuated, for a movement in a direction different from that of the compression axis (Z), by compression of the compression spring (50) along the compression axis (Z), comprising a step in which: an adjustment device selectively restricts or releases the movement of the mechanism (150).

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PL3400841T3|2021-01-25|

US10722042B2|2020-07-28|

EP3400841B1|2020-06-03|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

DE20318252U1|2003-11-24|2004-12-30|Froli Kunststoffwerk Heinrich Fromme Ohg|Sprung support for seat and seat back has spring elements with outer support flanges clipped onto guide rails on a base support layer for an adjustable support for the cover layers|

WO2008015235A1|2006-08-04|2008-02-07|Froli Kunststoffwerk Heinrich Fromme Ohg|Mounting element for an upholstery cover for seating and lying surfaces|

EP2526835A1|2011-05-23|2012-11-28|Tournadre SA Standard Gum|Suspension device for a bed base with adjustable stiffness|

EP2803297A1|2013-05-13|2014-11-19|Tournadre SA Standard Gum|Support device for a seat or bed base|

EP3087873A1|2015-04-29|2016-11-02|Bekina NV|Adjustable slat suspension device|

US2323286A|1941-07-23|1943-06-29|Ralph E Ward|Mold for helical springs|

US2842784A|1955-12-13|1958-07-15|Grund John|Adjustable mattress springs|

US3084926A|1957-07-10|1963-04-09|Jerome H Lemelson|Compression springs|

US2985895A|1958-04-24|1961-05-30|Bloom Abraham|Adjustable box springs|

US3608107A|1969-09-24|1971-09-28|Boris Kentor|Mattress spring with adjustable firmness|

US4667357A|1986-10-08|1987-05-26|Fortune Richard L|Sleep unit having adjustable firmness|

ES2124118B1|1995-03-08|1999-08-16|Martinez Rafael Martinez|IMPROVEMENTS IN SPRING DEVICES APPLICABLE TO MATTRESSES, SEATS AND THE LIKE.|

DE29915339U1|1999-09-01|2000-01-05|Hartmann Siegbert|Spring body|

DE10024530A1|2000-05-18|2001-11-22|Heidinger Florian|Support device|

DE20300248U1|2002-07-31|2003-09-11|Froli Kunststoffwerk Fromme H|Bed frame spring has adjustable upthrust unit with arms resting on supporting curved base plate|

US6684435B1|2002-10-24|2004-02-03|L&P Property Management Company|Method of manufacturing bedding or seating product having coaxial coil springs|

DE202005006399U1|2005-04-21|2006-08-24|Diemer & Dr. Jaspert GbR, |spring system|

US7805790B2|2008-01-18|2010-10-05|Sealy Technology Llc|Foam springs and innerspring combinations for mattresses|

US7636971B2|2008-01-18|2009-12-29|Sealy Technology Llc|Innerspring dampening inserts|

US7849546B2|2008-04-11|2010-12-14|Somnium, Inc.|Membrane spring array for a mattress and a method of assembly of a membrane spring array|

DE102008050108A1|2008-10-06|2010-04-08|Schwenk, Hans Ulrich, Dipl.-Ing.|Spring element for laying of mattresses in under-beds, has ring provided to alternatively change height position of arms in which plates lie during springing, and/or to alternatively change stiffness of arms supporting plates|

FR3066088B1|2017-05-12|2019-07-05|Tournadre Sa Standard Gum|STIFF ADJUSTER DEVICE|

FR3066087B1|2017-05-12|2019-07-05|Tournadre Sa Standard Gum|ADJUSTABLE STIFFENER ELEMENT FOR SLEEP OR SEAT FURNITURE|FR3066088B1|2017-05-12|2019-07-05|Tournadre Sa Standard Gum|STIFF ADJUSTER DEVICE|

FR3066087B1|2017-05-12|2019-07-05|Tournadre Sa Standard Gum|ADJUSTABLE STIFFENER ELEMENT FOR SLEEP OR SEAT FURNITURE|

FR3075908B1|2017-12-27|2020-09-25|Airbus Operations Sas|DAMPING SYSTEM INCLUDING A PRIMARY DAMPER AND A SECONDARY DAMPER DEVICE FOR DIFFERENT STIFFNESS, ASSOCIATED STRUCTURE AND AIRCRAFT|

FR3090307B1|2018-12-21|2021-03-12|Tournadre Sa Standard Gum|Flexible element with adjustable stiffness for sleeping and / or seat furniture|

FR3090306B1|2018-12-21|2021-03-12|Tournadre Sa Standard Gum|Flexible element with adjustable stiffness for sleeping and / or seat furniture|

FR3090305B1|2018-12-21|2021-03-12|Tournadre Sa Standard Gum|Flexible element with adjustable height|

法律状态:
2018-05-24| PLFP| Fee payment|Year of fee payment: 2 |

2018-11-16| PLSC| Search report ready|Effective date: 20181116 |

2019-05-20| PLFP| Fee payment|Year of fee payment: 3 |

2020-05-22| PLFP| Fee payment|Year of fee payment: 4 |

2021-05-25| PLFP| Fee payment|Year of fee payment: 5 |

优先权:

申请号 | 申请日 | 专利标题

FR1754172A|FR3066087B1|2017-05-12|2017-05-12|ADJUSTABLE STIFFENER ELEMENT FOR SLEEP OR SEAT FURNITURE|

FR1754172|2017-05-12|FR1754172A| FR3066087B1|2017-05-12|2017-05-12|ADJUSTABLE STIFFENER ELEMENT FOR SLEEP OR SEAT FURNITURE|

ES18171876T| ES2812348T3|2017-05-12|2018-05-11|Adjustable stiffness element for furniture to lie down sit|

EP18171876.8A| EP3400841B1|2017-05-12|2018-05-11|Element with adjustable stiffness for sleeping or seating furniture|

PL18171876T| PL3400841T3|2017-05-12|2018-05-11|Element with adjustable stiffness for sleeping or seating furniture|

US15/978,353| US10722042B2|2017-05-12|2018-05-14|Element of adjustable stiffness for beds or seats|

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