EP3649893A1 - Adjusting the pivotal resistance of a component of seating furniture - Google Patents

Abstract

The invention relates to a device for adjusting the pivoting resistance of a pivotable component (5) of a piece of seating furniture, which seating has a spring mechanism (15) with a spring element (16) influencing the pivoting resistance of the pivotable component (5) and two more besides the pivotable component (5) Components (3, 4), wherein at least one component (4) of these two further components (3, 4) is also moved by pivoting the pivotable component (5), the spring element (16) with its one spring end (18) or with a functional element (19) cooperating with this spring end (18) at the same time on two of the three components (3, 4, 5).

Description

The invention relates to a device for adjusting the pivoting resistance of a pivotable component of a piece of seating furniture.

Numerous possibilities for setting the pivoting resistance of a pivotable component of a piece of seating furniture are known from the prior art. Disadvantages of these known solutions are, on the one hand, that a high expenditure of force is required to change the swivel resistance, and, on the other hand, that the swivel resistance once set changes during the swiveling of the component. Both are perceived as uncomfortable by a user of such seating.

An object of the present invention is to achieve a particularly comfortable adjustment of the pivoting resistance of a seating component in a piece of seating.

This object is achieved by a device for adjusting the pivoting resistance of a pivotable component of a piece of seating furniture according to claim 1 or by a mechanism for a seating furniture according to claim 4 or by a seating furniture according to claim 10. Advantageous embodiments of the invention are specified in the subclaims.

The invention is implemented by a device for adjusting the pivoting resistance of a pivotable component of a piece of seating furniture, which seating furniture has a Spring mechanism with a spring element influencing the pivoting resistance of the pivotable component and, in addition to the pivotable component, two further components, at least one of these two further components being moved by pivoting the pivotable component, the spring element moving with its one spring end or with one with this spring end cooperating functional element is supported simultaneously on two of the three components.

It is particularly advantageous if one of these two components used for support is the component which is also moved or which is pivotable.

It is very particularly advantageous if one of these one (co-moving or pivotable) component and / or the other component serving for support is provided for the purpose of supporting the spring end or the functional element, its position and / or position for adjusting the pivoting resistance of the pivotable component is changeable.

The invention is also implemented by a mechanism for a piece of seating furniture, in particular a synchronous mechanism for a correlated movement of the seat-backrest of a piece of seating furniture, in particular an office chair, with a base support that can be placed on a chair column, with a seat support and with a backrest support, the backrest support with the seat support is connected in such a way that a pivoting movement of the backrest support from a basic position into a pivoted position to the rear induces a movement of the seat support relative to the base support, a spring mechanism being provided, which spring mechanism is at least one of the Has pivoting resistance of the backrest influencing spring element, one end of which is operatively connected to at least one functional element, the at least one functional element being supported on a support device which has both a support element arranged on the seat support and a support element arranged on the base support, which is supports at least one functional element on both support elements simultaneously.

It is particularly advantageous if at least one of these support elements can be changed in position and / or position.

The invention is also implemented by a piece of seating, in particular an office chair, with a device or with a mechanism, as described above.

The invention uses the principle of the so-called "powerless adjustment" which is already known in principle in the field of chair mechanics. This means that the initial force for pivoting the pivotable component can be changed without changing the pretension of the spring element involved. This principle is implemented according to the invention in a particularly elegant manner, namely preferably with the aid of an adjustable, in particular position and / or position-changing support element, which can be adjusted, in particular when the pivotable component is in a non-pivoted state, without the spring element being compressed (static aspect of the invention), this supporting element providing one of two contact surfaces on which the spring element, either directly or via a with the spring element cooperating functional element, supported at the same time. At least one of these two contact surfaces moves by pivoting the pivotable component relative to the other contact surface in such a way that the two contact surfaces act simultaneously on the spring end or the functional element when pivoting the pivotable component in the manner of closing arms of a pair of scissors and thereby compress the spring element depending on the previously set position and / or position of the adjustable support element. Depending on the design of the support element, the nature of the pivoting movement of the component can be varied (dynamic aspect of the invention). For example, the pivoting behavior of the component can be influenced in a simple manner and individually set by the user according to his wishes. In particular, the relationship between spring force and spring travel can be set for the pivoting of the pivotable component by the design of the support surfaces of the support elements. More precisely, such different pivoting behavior can be achieved as can be achieved by using spring elements with a linear, progressive or degressive spring characteristic, without however having to replace the spring element used for this purpose.

With the solution according to the invention, a particularly comfortable adjustment of the pivoting resistance of a seating component is achieved in seating.

The advantages and configurations explained below in connection with the device for adjusting the swivel resistance also apply analogously to the mechanics of the seating furniture according to the invention and the seating furniture itself and vice versa.

Fig. 1

eine Bürostuhlmechanik in einer nicht verschwenkten Grundstellung (geringer Schwenkwiderstand der Rückenlehne, "weiche/leichte Einstellung"), Längsschnitt;

Fig. 2

eine Bürostuhlmechanik in einer maximal nach hinten verschwenkten Stellung (geringer Schwenkwiderstand der Rückenlehne, "weiche/leichte Einstellung"), Längsschnitt;

Fig. 3

eine Bürostuhlmechanik in einer nicht verschwenkten Grundstellung (hoher Schwenkwiderstand der Rückenlehne, "harte/schwere Einstellung"), Längsschnitt;

Fig. 4

eine Bürostuhlmechanik in einer maximal nach hinten verschwenkten Stellung(geringer Schwenkwiederstand der Rückenlehne, "harte/schwere Einstellung"), Längsschnitt;

Fig. 5

eine Detailansicht der Federelemente und der Verstellvorrichtung (perspektivisch).

An embodiment of the invention is explained below with reference to the drawings. Here show:

Fig. 1

an office chair mechanism in a non-swiveled basic position (low swivel resistance of the backrest, "soft / light adjustment"), longitudinal section;

Fig. 2

an office chair mechanism in a maximum swiveled back position (low swivel resistance of the backrest, "soft / light adjustment"), longitudinal section;

Fig. 3

an office chair mechanism in a non-swiveled basic position (high swivel resistance of the backrest, "hard / heavy setting"), longitudinal section;

Fig. 4

an office chair mechanism in a maximum swiveled back position (low pivoting resistance of the backrest, "hard / heavy adjustment"), longitudinal section;

Fig. 5

a detailed view of the spring elements and the adjusting device (in perspective).

The figures do not show the invention to scale, but only schematically and only with its essential components. The same reference numerals correspond to elements of the same or comparable function.

The figures show a synchronous mechanism 1 for a correlated seat-backrest movement of an office chair, with one on one Chair column 2 placeable base support 3, with a seat support 4 and with a backrest support 5, wherein the backrest support 5 is connected to the seat support 4 such that a pivoting movement of the backrest support 5, as indicated by arrow 6, from one to the Fig. 1 and 3rd shown non-pivoted basic position in one of the Fig. 2 and 4th shown, pivoted rearward position induces a movement of the seat support 4 relative to the base support 3. This movement of the seat support 4 has at least one translational movement component, as seen in the longitudinal direction 8 of the chair. In the example shown, the seat support 4 is carried along by the backrest support 5 during a swiveling movement to the rear, as indicated by arrow 7. For this purpose, the seat support 4, in the present case with its rear end 9 seen in the longitudinal direction 8 of the chair, is pivotably connected to the backrest support 5 about a transverse axis 11. In addition, the backrest support 5 is pivotally connected to the base support 3 about a further transverse axis 12 and the seat support 4, in the present case with its front end 13 seen in the longitudinal direction 8 of the chair, is connected to the base support 3 using a suitable connection, e.g. B. by means of a rotary / sliding joint 14. Connections are suitable which allow the desired relative movement of the seat support 4 to the base support 3 seen in the longitudinal direction 8 of the chair towards the rear.

Instead of articulated connections, alternative connections between the mechanical components 3, 4, 5 can also be provided. For example, selected mechanical components, for example the backrest support 5 and the base support 3 or the backrest support 5 and the seat support 4, can also be made in one piece and elastically connected to one another, as long as this allows the desired movements of the components with each other.

The mechanism 1 comprises a spring mechanism 15 which has at least one spring element 16 which influences the pivoting resistance of the backrest. In the example described here, two helical compression springs arranged between the seat support 4 and base support 3 inside the mechanism 1 are provided as spring elements 16, as in FIG Fig. 5 shown. The mode of operation is explained below using one of these spring elements 16 as an example. However, the entire mechanism 1 is constructed with mirror symmetry with respect to its central longitudinal plane, as far as the actual kinematics are concerned. In this respect, unless explicitly stated otherwise or shown in the figures, the following description is always based on construction elements of the actual swivel mechanism that are present in pairs on both sides.

The front spring end 18 of the at least one spring element 16, which is attacked by an adjusting device 17 that is explained in more detail and seen in the longitudinal direction 8 of the chair, is “free” in the sense that it is not articulated to a component 3, 4, 5 of the mechanism 1. Instead, the front spring end 18, as will be explained in more detail below, is supported by a functional element 19 attached to the spring element 16 on a support device serving as an abutment. The functional element 19 is clamped between the seat support 4 and the base support 3, that is, it is supported at the same time on the seat support 4 and the base support 3. For this purpose, both a first support element 21 (upper support element) assigned to the seat support 4 and a second support element 22 (lower support element) assigned to the base support 3 are provided together form the support device. Each support element 21, 22 has a support surface 23, 24.

The two support elements 21, 22 are preferably attached to their respective mechanical components 4, 3, i.e. either connected to them or designed as an integral part of them.

At least one of the support elements 21 is adjustable, namely, position and / or position changeable. The purpose of this adjustability of the at least one support element 21 is to change a property of the movement of the spring end 18 of the spring element 21, which movement, in the present case, is directed rearward in the longitudinal direction 8 of the chair. The purpose of the adjustability is in particular to adjust the extent of the change in position of the functional element 19 and thus the extent of the change in the pivoting resistance of the backrest when the backrest carrier 5 is pivoted into a pivoted position. An adjustable support element 21 is preferably designed as a part of this mechanical component that is movable relative to the base body 25 of the corresponding mechanical component 4 or, as in the present example, as a separate component that is movably connected to this mechanical component 4.

In the example described, the second support element 22 is a fixed, i.e. non-adjustable, integrated part of the base support 3 and thus designed to be stationary. The support surface 24 of this second support element 22 has a defined surface configuration, so that there is a specific rolling path with a predetermined gradient.

In the example, the first support element 21 can be changed in position and position with the base body 25 of the seat support 4 connected so that the support surface 23 of the first support element 21 can have different angles to the support surface 24 of the second support element 22. The support surface 23 of the first support element 21 also has a defined surface configuration, so that a specific rolling path with a predetermined gradient is obtained. The adjustability of the first support element 21 is discussed in more detail below.

As an alternative to the simple variant just described, in which only the upper support element 21 is designed to be adjustable, instead of the upper support element 21 or in addition to the upper support element 21, the lower support element 22 can also be designed to be adjustable. This results in further possibilities for influencing the pivoting movement of the pivotable mechanical component 5, for example through the use of support surfaces 23, 24 with mutually coordinated gradient profiles.

With its other end 26, seen in the longitudinal direction 8 of the chair, the spring element 16 is supported in a suitable manner on the base support 3.

The front end 18 of the spring element 16, which is of interest for the spring force adjustment and is directed forward and upward in the longitudinal direction 8 of the chair, is in operative connection with the functional element 19. In the example shown, a functional element 19 is attached to this end 18 of the spring element 16, which can act on the spring end 18 in the longitudinal direction 28 of the spring via a suitable coupling element 27, such as an eyelet or a hook. The coupling element 27 strikes, for example, the end windings of the spring element 16 or is screwed into the spring element 16.

In order to avoid friction and "locking" in the interaction of the functional element 19 with the support elements 21, 22, the functional element 19 comprises two bearings 31, 32, in particular nail bearings or ball bearings, which are movable independently of one another and are mounted on a common bearing axis 29. However, other suitable rolling bearings or plain bearings can also be used. The coupling element 27 connects the bearing axis 29 to the spring element 16, in the example illustrated here in that the eyelet or the hook of the coupling element 27 at least partially encompasses the bearing axis 29. The bearings 31, 32 are arranged side by side on the bearing axis 29, only separated from one another by the coupling element 27.

In the state of use, the first bearing 31 of the functional element 19 is supported on the support surface 23 of the upper support element 21 and the second bearing 32 of the functional element 19 on the support surface 24 of the lower support element 22, or the bearings 31, 32 roll simultaneously on the support surfaces 23 , 24 from when the components move towards one another, in particular when the seat support 4 carried by the backrest support 5 moves relative to the fixed base support 3.

The upper support element 21 is adjustable, more precisely designed to change its position. The adjustable support element 21 is preferably arranged on the seat support 3 in such a way that an adjustment (change in position and position) of the support element 21 does not cause any loading, in particular no change in position, of the functional element 19 interacting with the spring element 16.

While the support surface 23 of the upper support element 21 points in the direction of the surface of the outer surface of the bearing 31 of the functional element 19, that is to say is formed on the inside 33 of the support element 21, the outside 34 of the support element 21 is at least partially convex and lies there in a corresponding manner concave-shaped receiving shell 35 on the underside of the base body 25 of the seat support 4.

When the support element 21 and its associated change in position and location relative to the seat support 4 are adjusted, the support element 21 is guided in the receiving shell 35. The support element 21 slides in the receiving shell 35 and rotates about an axis of rotation 36 lying transversely to the longitudinal direction 8 of the chair.

The upper support element 21 is rotatable about its axis of rotation 36 in the seat support 4. For this purpose, bearing pins 37 are provided on the two lateral ends of the upper support element 21, which lie in corresponding bearing bushes (not shown), which are located on both sides of the seat support 4 are attached to the base body 25. The bearing axis 29 serving for the storage of the bearings 31, 32 of the functional element 19, however, is exposed, i.e. it is neither firmly connected to the seat support 4 nor to any other mechanical component, so that, placed between the support surfaces 23, 24 of the upper and lower support elements 21, 22, it can move when acted upon by them.

The spring mechanism 15 and the mechanical components 3, 4, 5 are coordinated with one another in such a way that the axis of rotation 36 of the upper support element 21 in the non-pivoted state, ie when the backrest is not pivoted, when the seat support 4 is also is still in its basic position, lies on the bearing axis 29 of the functional element 19. As a result, when the upper support element 21 is adjusted in this non-pivoted state, it is possible to roll the support surface 23 of the support element 21 around the lateral surface of the bearing 31 of the functional element 19 without the position of the bearing 31 changing. In other words, a "powerless adjustment" is possible, that is, an adjustment of the upper support element 21 without changing the pretension of the spring element 16.

A manually adjustable adjustment device 17 is preferably provided for adjusting the at least one support element, here for pivoting the upper support element 21 about its axis of rotation 36. Alternatively, the adjusting device 17 can also be designed to be driven by a motor.

In the example shown here, a lever arm 38 arranged at a distance from the axis of rotation 36 is provided as an integrated driver on the upper support element 21. The lever arm 38 is made in two parts. The two lever arm halves 39 are oriented in the same direction, but spaced apart from one another, on the outer side 34 of the upper support element 21 opposite the double bearing 31, 32.

A movement thread (spindle drive) of the adjusting device 17 is positioned between the lever arm halves 39, with a threaded spindle 41 and with a threaded nut 42 movably guided on the threaded spindle 41, the threaded nut 42 engaging in the lever arm halves 39 with pins 43 attached to it laterally. To accommodate the pins 43 of the threaded nut 42, recesses 44 are provided in each lever arm half 39 and are elongated holes and extend in the longitudinal direction of the lever arm. These recesses 44 ensure one rotational decoupling and thus the additional degree of freedom required to adjust the upper support element 21 by the spindle drive.

To adjust the upper support element 21, the rotational movement of the threaded spindle 41 arranged in the longitudinal direction 8 of the chair is transmitted via the threaded nut 42 with the aid of the lever arm 38 to the upper support element 21, so that the support element 21 pivots about its axis of rotation 36. The threaded spindle 41 is driven, for example, via a bevel gear or the like with the aid of a drive device (not shown in more detail) which, for example, can have a handwheel or the like as a handle.

The spindle drive is self-locking. In other words, the design of the threaded spindle 41 prevents the upper support element 21 from moving automatically.

All means for influencing the mode of action of the spring mechanism, in particular for adjusting the spring force, in particular the adjustable support element 21 and the adjusting device 17, are, as in the example here, preferably arranged exclusively in the seat support 4 or assigned to the seat support 4. As a result, the base support 3, which only provides the second support surface, can be made lighter and structurally simpler than in conventional mechanisms in which the spring force is adjusted in the base support or by means of components attached to the base support.

After the upper support element 21 has been transferred to a desired position, for example in a particularly "soft" or "light" setting, as in FIG Fig. 1 shown, or in a particularly "hard" or "difficult" setting, as in Fig. 3rd shown, or in any infinitely adjustable intermediate position between these two settings, the spring-loaded pivoting of the pivotable components, here the backrest support 5, can take place, the pivoting behavior set in each case being able to be observed, see Figures 2 and 4th .

By supporting the spring element 16 on the two support elements 21, 22, due to the relative movement of the seat support 4 to the base support 3 when the backrest support 5 is pivoted into a pivoted position, the functional element 19, as seen in the longitudinal direction 8 of the chair, moves backwards or backwards below. This causes an action on the at least one spring element 16 and thus a change in the pivoting resistance of the backrest.

The two bearings 31, 32 of the functional element 19 are clamped between the support surfaces 23, 24 of the upper and lower support elements 21, 22. The support surface 23 of the upper support element 21 forms a first point of engagement on the outer ring of the first bearing 31, while a second point of attack on the outer ring of the second bearing 32 is defined by its contact with the support surface 24 of the lower support element 22. When the backrest support 5 is pivoted, the bearings 31, 32 and thus the entire functional element 19 are pressed forward by the upper support element 21, which moves backwards with the seat support 4, on the support surface 24 of the lower support element 22 (“scissor principle”). The bearings 31, 32 and thus the points of attack of the bearings 31, 32 on the support surfaces 23, 24 are forced to move rearward in the longitudinal direction 8 of the chair. There is a change in the position and location of the support surface 23 of the upper support element 21 relative to the fixed support surface 24 of the lower support element 22.

In other words, the seat support 4, which is carried along by the backrest support 5 when the backrest support 5 is pivoted, moves downward to the rear. As a result of this movement of the seat support 4, the upper support element 21 is also carried or moved to the rear and acts on the spring element 16 via the functional element 19, so that the spring element 16 is compressed. The user leaning against the backrest feels a swivel resistance.

Upper and lower support elements 21, 22, more precisely their support surfaces 23, 24, form the "arms" of a pair of scissors. While there would be no adjustment of the functional element 19 or spring stroke of the spring element 16 in a parallel position of these two support surfaces 23, 24 with a movement of the seat support 4 and thus the upper support element 21 to the rear, can be achieved by a targeted adjustment of the upper support element 21, preferably "without power", achieve a defined angular position of the two support surfaces 23, 24 relative to one another (static aspect) and thus change the movement of the functional element 19 and thus the mode of operation of the spring element 16 (dynamic aspect).

In the "soft" or "light" setting, in which the support surfaces 23, 24 of the two support elements 21, 22 of the seat support 4 and base support 3 enclose a comparatively acute angle to one another ( Fig. 1 ), the spring element 16 is only a little when the seat support 4 moves backwards compressed ( Fig. 2 ). The functional element 19 performs only a small displacement, the spring stroke is small.

In the "hard" or "heavy" setting, in which the support surface 23 of the upper support element 21 is almost perpendicular to the spring longitudinal direction 28 ( Fig. 3 ), a movement of the seat support 4 backwards causes a large displacement of the functional element 19 and thus a lot of spring stroke ( Fig. 4 ). The spring element 16 is strongly compressed when the backrest is pivoted to the rear. Due to the position of the upper support element 21 relative to the functional element 19, the translational movement of the seat support 4 is transmitted almost 1: 1 to the spring element 16, that is to say converted into a compression of the spring element 16, so that a very direct drive results.

In connection with this, the path curve formed by the support surfaces 23, 24 can play a role on which the functional element 19 moves during a pivoting of the backrest.

The support surface 23 of the upper support element 21 is curved, in the present case both convex in sections and concave in sections. The support surface 24 of the lower support element 22 is flat and runs obliquely, namely sloping from front to back as seen in the longitudinal direction 8 of the chair. The design of the two support surfaces 23, 24, but in particular the design of the support surface 23 of the upper support element 21, results in a defined, non-linear trajectory of the functional element 19 when the backrest is pivoted to the rear. The pivoting resistance thus changes during the pivoting of the backrest. In particular, by designing the Support surfaces of the "sensed" sequence of mechanics are influenced by a user. For example, a slight progressiveness can be achieved in the swiveled state just before the backrest hits its maximum swivel. The selected curvature of the support surface 23 results in a particularly pleasant movement characteristic of the mechanism 1. Preferably, the curved support surface 23 is designed in such a way that the effort felt by a user is always constant when the backrest is pivoted.

With the curvature of the support surfaces, in particular the support surface 23 of the upper support element 21, the degree of deflection of the functional element 19 and thus the degree of deflection of the front spring end 18, the spring stroke, is influenced. It can thus be influenced whether the mechanism 1 behaves progressively, linearly or degressively.

The degree of deflection or the spring stroke is influenced by the closing angle of the scissor arms, more precisely by the angle of the support surfaces 23, 24 to one another. Both a linear and a non-linear relationship can arise between the pivoting angle of the backrest support 5 on the one hand and the pivoting force required for this pivoting on the other hand. This relationship is preferably linear, i.e. the effort required by the user to pivot the backrest is always the same regardless of the pivoting angle of the backrest.

The example described above uses a device for adjusting the pivoting resistance of a pivotable component of a piece of seating furniture. The pivotable component is preferably the backrest support 5 Chair mechanism 1 of an office chair, wherein the chair mechanism 1 is preferably a synchronous mechanism. The seating furniture has a spring mechanism 15. The spring mechanism 15 comprises a spring element 16 which influences the pivoting resistance of the pivotable component 5. In addition to the pivotable component 5, the seating furniture has two further components 3, 4. These two further components are preferably the base support 3 and the seat support 4 of the chair mechanism 1. At least one of these two further components, preferably the seat support 4, is adjusted by pivoting the pivotable component, here preferably by pivoting the backrest support 5 at the bottom, moved along. The spring element 16 is supported with its one spring end 18 or with a functional element 19 cooperating with this spring end 18 simultaneously on two of the three components, namely preferably on the base support 3 and the seat support 4. In an alternative embodiment, not shown in the figures the rear end 26 of the spring element 16 is also supported on the backrest support 5. One of these two components serving for support is the component which is also moved or which can be pivoted, that is to say preferably the seat support 4 or alternatively the backrest support 5. This one component (which is moved or pivotable), preferably the seat carrier 4 or alternatively that Backrest support 5, and / or the other component serving for support, preferably thus the base support 3, is assigned a support element 21 for the purpose of supporting the spring end 18 or the functional element 19, its position and / or position for adjusting the pivoting resistance of the pivotable component 5 is changeable.

All features shown in the description, the following claims and the drawing can be essential to the invention both individually and in any combination with one another.

Reference symbol list

1

mechanics

2nd

Chair column

3rd

Base carrier

4th

Seat support

5

Backrest support

6

Direction of the swivel movement

7

Direction of the subsequent movement

8th

Longitudinal direction of the chair

9

rear end of the seat support

10th

(free)

11

first transverse axis

12

second transverse axis

13

front seat support end

14

Swivel / sliding joint

15

Spring mechanism

16

Spring element

17th

Adjustment device

18th

front spring end

19th

Functional element

20th

(free)

21

first (upper) support element

22

second (lower) support element

23

first support surface

24th

second support surface

25th

Seat support base

26

rear spring end

27th

Coupling element

28

Spring longitudinal direction

29

Bearing axis

30th

(free)

31

first camp

32

second camp

33

Support element inside

34

Support element outside

35

Receptacle

36

Axis of rotation

37

Bearing journal

38

Lever arm

39

Lever arm half

40

(free)

41

Threaded spindle

42

Threaded nut

43

Cones

44

Long hole

Claims (10)

Device for adjusting the pivoting resistance of a pivotable component (5) of a piece of seating furniture, which seating has a spring mechanism (15) with a spring element (16) influencing the pivoting resistance of the pivotable component (5) and, in addition to the pivotable component (5), two further components (3, 4), at least one component (4) of these two further components (3, 4) being moved along by pivoting the pivotable component (5), the spring element (16) moving with its one spring end (18) or with one this spring end (18) cooperating functional element (19) is supported simultaneously on two of the three components (3, 4, 5). Apparatus according to claim 1, wherein one of these two components (3, 4, 5) serving for support is the moving component (4) or the pivotable component (5). Apparatus according to claim 2, characterized by a support element (21) associated with one of the components (4, 5) serving for support and / or the other component (3) serving for the purpose of supporting the spring end (18) or the functional element (19) ), the position and / or position of which can be changed to adjust the pivoting resistance of the pivotable component (5). Mechanics (1) for a piece of seating furniture, in particular synchronous mechanisms for a correlated movement of the seat backrest of a piece of seating furniture, in particular an office chair, with a base support (3) that can be placed on a chair column (2), with a seat support (4) and with a backrest support ( 5), the Backrest support (5) is connected to the seat support (4) in such a way that a pivoting movement of the backrest support (5) from a basic position into a pivoted-back position induces a movement of the seat support (4) relative to the base support (3), a spring mechanism (15) is provided, which spring mechanism (15) has at least one spring element (16) influencing the pivoting resistance of the backrest, one end (18) of which is operatively connected to at least one functional element (19), the at least one functional element (19) is supported on a support device which has both a support element (21) arranged on the seat support (4) and a support element (22) arranged on the base support (3), the at least one functional element (19) being located on both support elements (21, 22) supports at the same time. Mechanism according to claim 4, characterized in that at least one of these support elements (21) is adjustable, in particular position and / or position changeable. Apparatus according to claim 5, wherein by adjusting the at least one adjustable support element (21) an angle enclosed by the support surfaces (23, 24) of the two support elements (21, 22) can be changed, this change in the angle when the Backrest support (5) changes the movement of the functional element (19) and thus the mode of action of the spring element (16) as a function of this angle. Device according to one of claims 4 to 6, wherein the functional element (19) two independently movable, preferably comprises bearings (31, 32) mounted on a common bearing axis (29). Apparatus according to claim 7, wherein the one bearing (31) is supported on the one support element (21) and the other bearing (32) on the other support element (22). Mechanism according to claim 8, wherein the at least one adjustable support element (21) is rotatable about an axis of rotation (36) which is preferably transverse to the longitudinal direction of the chair (8), the position of the axis of rotation (36) during the adjustment of the support element (21) in the basic position of the backrest support (5) corresponds to the position of the bearing axis (29). Seating, in particular office chair, with a device according to one of claims 1 to 3 or with a mechanism (1) according to one of claims 4 to 9.

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