DEVICE FOR SYNCHRONIZING THE TILT OF THE BACKREST AND THE SEAT OF A CHAIR

Abstract

A device for synchronizing the tilt of the backrest and of the seat of a chair, of the type having a frame of the backrest, a frame of the seat and a support integral with the base of the chair, as well as a first crank, integral with the backrest frame, and hinged in the rear portion of the seat frame and the support, and at least one second crank hinged in the front portion of the seat frame and to the support. The first crank and the second crank (5) form, together with the seat frame, a four-bar linkage. An adjusting lever is constrained to the four-bar linkage and is further operatively connected to a movable fulcrum and elastic means.

Claims

1. A device for synchronizing the tilt of the backrest and of the seat of a chair, of the type comprising a frame of the backrest, a frame of the seat and a support integral with the base of said chair, as well as a first crank, integral with said backrest frame, and hinged in the rear portion of said seat frame and said support, and at least one second crank hinged in the front portion of said seat frame and to said support, said at least one first crank and said at least one second crank, with said seat frame, forming a four-bar linkage, characterized in that an adjusting lever is constrained to said four-bar linkage, said adjusting leverage being operatively connected to a movable fulcrum and being further constrained to elastic means.

2. The device according to claim 1, wherein said adjusting lever is hinged to a hinge constraining said second crank and said seat frame.

3. The device according to claim 2, wherein said hinge is supported by a supporting profile.

4. The device according to claim 1, wherein said fulcrum is movable at least between a first position, in which the distance between said movable fulcrum and said elastic means is maximum, and a second position, in which the distance between said movable fulcrum and said elastic means is minimum.

5. The device according to claim 1, wherein said fulcrum comprises an element sliding with respect to a respective housing, and a head for engaging said adjusting lever.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0018] Hereinafter, referring to the appended figures, an exemplary and non-limiting embodiment of the present invention will be described, wherein:

[0019] FIG. 1 is a schematic view of an embodiment of a device according to the present invention;

[0020] FIGS. 2 and 3 are detailed views of the components of a device according to the present invention, in two subsequent operation steps according to a first arrangement of the position of the movable fulcrum;

[0021] FIG. 4 is a detailed view of the device of FIGS. 2 and 3 in a second arrangement of the position of the movable fulcrum;

[0022] FIG. 5 is a perspective view of some components of the device of FIGS. 2-4.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT OF THE PRESENT INVENTION

[0023] Referring to the appended figures, a device 10 for synchronizing the tilt of a backrest and of the seat of a chair, comprises a backrest frame 1, a seat frame 4 and a support 2 integral with the base of the chair itself.

[0024] These elements are known from the Patent EP2375938 in the name of the Applicant and are not described in detail herein.

[0025] In the following description, for ease of description, when in the chair there is a pair of elements, where the elements of the pair are identical in shape to each other, and arranged parallel with each other, they are individually described. In particular, as shown in FIG. 5, the chair is provided with two four-bar linkages 3, 4, 5 arranged in parallel, having a respective adjusting lever 6. A single four-bar linkage is described below and, as evident, this description identically applies to the second four-bar linkage. Further, more (or less) identical four-bar linkages can be arranged in parallel in a chair.

[0026] Briefly, the backrest frame 1 is constrained to the backrest in a known way and is integral with a first crank 3 rotatably constrained to the support 2. In the shown embodiment, part of the backrest frame is made in one piece with the first crank 3, which is constrained to the support 2 by means of a hinge A.

[0027] The seat frame 4 is constrained in a known way to the seat and is rotatably constrained to the first crank 3.

[0028] In particular, in the embodiment shown, a hinge B constrains the seat frame 4 to the first crank 3.

[0029] A second crank 5 is hinged in the front portion of the seat frame 4 and the support 2. In particular, a hinge D rotatably constrains the second crank 5 to the support 2. The second crank 5 is further constrained to the seat frame 4 by means of a hinge C.

[0030] The two cranks 3, 5 and the seat frame 4 form a four-bar linkage, similarly to what described in the Patent EP2375938 in the name of the Applicant.

[0031] According to the invention, an adjusting lever 6 is constrained to the four-bar linkage 3, 4, 5.

[0032] The adjusting lever is preferably constrained to one of the shared constraints in the four-bar linkage 3, 4, 5.

[0033] Herein, shared constraints means constraints interposed between at least two elements of the four-bar linkage 3, 4, 5. Therefore, in the embodiment of the figures, the shared constraints are the hinges B and C.

[0034] In the present embodiment, the adjusting lever 6 is constrained to the hinge C, which constrains together the seat frame 4, the second crank 5 and the adjusting lever 6.

[0035] Also referring to FIG. 5, in the present embodiment the hinge C is made by a rod 9, acting as a pin, rotatably engaged within respective and preferably circular openings 11a, 11b, 11c of the seat frame 4, the second crank 5 and the lever 6, respectively.

[0036] Preferably, the opening 11b of the second crank 5 is provided with a bush, not shown, shaped such as to constrain the bar 9 such that the second crank 5 can rotate around the axis of the bar 9 itself.

[0037] In particular, in the embodiment shown herein, the hinge C is rotationally guided by the second crank 5 around the hinge D. The hinge C, and in particular the bar 9, can be further supported or guided by a supporting profile 2a integral with the support 2.

[0038] In more detail, the supporting profile 2a acts as a guiding support for the hinge C, in particular when this hinge C is in the rest position, as shown in FIG. 2. The shape of the supporting profile is selected according to structural requirements, and thus it can change with respect to what shown in figures.

[0039] The adjusting lever 6 is constrained to elastic means 8, which are in turn constrained to the support 2.

[0040] The elastic means 8 are of a type known in the art. In the shown embodiment they are made by means of a spring, but pneumatic or oleodynamic elastic means are also possible.

[0041] For sake of simplicity, in the shown embodiment, the elastic means are constrained to the support 2 by the hinge A. The hinge A is integral with the support 2, so the movement of the first crank 3 is not directly correlated to the elastic means 8 through the hinge A.

[0042] In particular, the elastic means 8 could be constrained to another point integral with the frame 2 of the chair.

[0043] On the contrary, the elastic means 8 are constrained to the adjusting lever 6, preferably by means of a hinge E, such that the elastic means 8 are directly operated by displacing the adjusting lever 6.

[0044] In other words, the displacement of the adjusting lever 6 results in a tensile/compression force of the elastic means 8. Thus, according to the shape of the elastic means 8, the elastic means 8 themselves can selectively help or hinder the movements of the adjusting lever 6.

[0045] The adjusting lever 6 rotates around a movable fulcrum 7. Movable fulcrum means an element acting as a pivot for the adjusting lever 6 and able to be firmly positioned in different positions. In particular, the fulcrum 7 is movable at least in an axial direction of the adjusting lever 6 and, generally, at least between a position in which the distance from the elastic means 8 is minimum, and a position in which the distance from the elastic means 8 is maximum.

[0046] As better illustrated below in explaining the operation of the device 10, the lever 6 is a first-class lever, in which the movable fulcrum 7 acts as a pivot, the user weight acts as the effort force and the elastic means 8 act as the resistance force.

[0047] By changing the position of the movable fulcrum 7, a twofold effect is obtained, whereby the ratio of the lever arms of the effort force and the resistant force changes, such as to accordingly change the lever advantage/disadvantage, as evident to a field technician.

[0048] Moreover, by changing the position of the movable fulcrum 7, the adjusting lever 6 is forced to a displacement for finding a new equilibrium state between the forces applied on it.

[0049] As mentioned, as a result of this operation, the elastic means 8 are operated so that their preload changes.

[0050] In the present embodiment the movable fulcrum 7 has a head 7A for engaging the adjusting lever 6 and a body 7B, being movable with respect to a respective housing 12.

[0051] In more detail, the housing 12 and the body 7b are threaded, and the housing 12 is rotatably constrained with respect to the support 2. The rotation of the housing 12 can be controlled through a knob 13. The rotation of the housing 12 causes, in turn, a relative rotation between the threads of the body 7b of the movable fulcrum and the thread of the housing 12 itself. As evident to the field technician, this results in a translatory movement of the body 7b with respect to the housing 12 and therefore a displacement of the movable fulcrum 7.

[0052] It is however evident that different kinematic systems can be used to control the displacement of the movable fulcrum, for example by directly engaging a knob thread with a thread of the body 7b.

[0053] Referring to the appended figures, the operation of the device 10 will be now introduced.

[0054] When a user rests on the chair mounting the device 10, the user weight directly acts on the seat and the backrest.

[0055] In particular, the weight of the user resting on the seat applies a downward force to the seat frame 4 and therefore, due to the arrangement of the four-bar linkage 3, 4, 5, causes the cranks 3, 5 to rotate, clockwise in the appended figures.

[0056] On the contrary, the weight of the back acting on the backrest causes the backrest frame 1, and accordingly also the first crank 3, to rotate in the opposite direction, i.e. counterclockwise in the appended figures. The constraints in the four-bar linkage 3, 4, 5 also act to raise the seat frame 4, and to rotate also the second crank 5 in the same direction, i.e. counterclockwise in figures.

[0057] In general, the user weight acting on the seat frame 4 and the back weight acting on the backrest frame 1 tend to rotate the four-bar linkage in opposite directions, resulting in an unbalance in the direction imposed by the backrest frame 1.

[0058] In other words, when a user leans on the backrest, the latter tilts, being braked by the user weight acting on the seat.

[0059] To balance the forces acting on the four-bar linkage 3, 4, 5, the elastic means 8 act to help the action of user weight on the backrest frame 1.

[0060] In the embodiment illustrated herein, being the hinge C in common between the second crank 5 and the adjusting lever 6, a rotation of the former causes, as a result, the displacement of the latter. In more detail, when the crank 5 rotates, clockwise in figures, due to the weight of the back indirectly acting on the backrest frame 1, the adjusting lever 6, in turn, rotates around the movable pivot 7 in the direction of the crank 5, and thus in counterclockwise direction in figures.

[0061] The rotation of the adjusting lever 6 causes the elastic means 8 to be operated. In the shown embodiment, the rotation of the adjusting lever 6, clockwise in figures, results in a tensile force of the elastic means 8 such that they increasingly counter this movement of the lever 6, which is directed counterclockwise in figures, as mentioned.

[0062] When the weight force of the user on the seat frame 4 and the force of the elastic means 8 balance the weight of the user back acting on the backrest frame 1, the backrest stops moving and the user is in a stable position on the chair.

[0063] As mentioned, in the absence of further elements, each user, clearly provided with only one weight to be applied on the seat and the backrest, can get only one equilibrium position.

[0064] Thanks to the displacement of the movable fulcrum 7, each single user can instead select several equilibrium positions on the chair, and particularly several backrest tilts that are equilibrium positions.

[0065] As anticipated, the displacement of the movable fulcrum 7 firstly changes the length of the lever arms, in particular the distance between the head 7A of the fulcrum 7 and the hinge C, that is the position in which the weight forces of the user act on the seat and the backrest, and the distance between the head 7A and the hinge E, that is the position in which resistance force of the elastic means 8 acts.

[0066] Secondly, the change of the movable fulcrum 7 causes the preload of the elastic means 8 to change.

[0067] Indeed, when the movable fulcrum 7 is brought as close as possible with respect to the elastic means, the preload of the elastic means 8 is different from the position of maximum distance between movable fulcrum 7 and elastic means 8. In particular, according to the configuration of the elastic means 8 and the four-bar linkage 3, 4, 5, these two positions will correspond to the positions of minimum and maximum preload of the elastic means 8.

[0068] In the shown embodiment, the position in which the elastic means 8 and the fulcrum 7 are closest, is corresponding to the condition in which the preload on the elastic means 8 is minimum, and vice versa.

[0069] Referring particularly to FIGS. 3 and 4, as can be noted, for two users of different weight there are two positions with the same backrest tilt.

[0070] In FIG. 3, the user kept the movable fulcrum 7 in the closest position with respect to the elastic means 8. As a result of the user resting on the seat and backrest, the cranks 3, 5 rotate from the position of FIG. 2, in this case counterclockwise, and the hinge C is raised, rotating about the hinge D, until it gets the position of FIG. 4, in which the force of the elastic means 8 is balanced by the user action on the seat frame 4 and the backrest frame 3.

[0071] On the other hand, in FIG. 5 it is shown the same equilibrium state of FIG. 4 but with a user of greater weight with respect to the condition of FIG. 4.

[0072] In particular, due to the user's greater weight, with the same position of the movable fulcrum 7, the equilibrium position of such a user will involve a greater tilt of the backrest frame 1 because, for balancing the weight of the user back a greater resistance .force of the elastic means 8 is needed which is provided by a greater rotation of the four-bar linkage 3, 4, 5.

[0073] However, this position may be uncomfortable for the user. By operating the knob 13 or a similar control means, the user can translate the movable fulcrum 7, in this case moving the movable fulcrum away from the elastic means 8.

[0074] Such a change involves a rotation, counterclockwise in figures, of the adjusting lever 6 and a tensile force of the elastic means 8. Thanks to this, the resistance force of the elastic means 8 increases and they can balance the operation of the user weight in response to a lesser rotation of the four-bar linkage 3, 4, 5.

[0075] During the displacement of the movable fulcrum 7, the adjusting lever 6 is rotated around the hinge C which therefore substantially stays still in its position. Accordingly, during the displacement of the fulcrum 7, the four-bar linkage and therefore the positions of the seat frame 4 and the backrest frame 1 do not change, such that this only results in the change of the preload of the elastic means 8.