DE102019113582B4 - synchronous mechanism - Google Patents

Abstract

Synchronous mechanism (100) for a correlated seat-backrest movement of an office chair, with a base support (1) that can be placed on a chair column (10), a seat support (3) and a backrest support (4), the backrest support (4) being pivotable with the base support (1), thereby fixing the main axis of rotation (11) of the synchronous mechanism (100), with a coupling device (20), having a first coupling element (21) that is operatively connected to the backrest support (4) and a first coupling element (21) that is operatively connected to the base support (1st ) operatively connected second coupling element (22), the first coupling element (21) and the second coupling element (22) being articulated to one another at a connection point (16), and having a spring arrangement (19) for fixing the pivoting resistance of the backrest support (4 ), wherein the spring arrangement (19) has at least one spring element (30), the spring element (30) having a stationary end (27) and a free end (28), the free E End (28) at the connection point (16) of the coupling device (20) engages.

Description

The invention relates to a synchronous mechanism for a correlated seat-backrest movement of an office chair, with a base support that can be placed on a chair column, a seat support and a backrest support. In addition, the invention relates to seating furniture, in particular an office chair, with a synchronous mechanism.

The term "synchronous mechanism" is understood to mean assemblies in the seat substructure of an office chair, which ensure coupled kinematics that bring about a specific relative movement of the seat and backrest to one another. The seat of the office chair, which is usually provided with an upholstered seat, is mounted on the seat support. The backrest support, which extends backwards in the usual way from the actual synchronous mechanism, carries the backrest of the office chair on an extension arm running upwards.

Synchronous mechanisms of this type are not only often constructed in a comparatively complicated manner, consist of a large number of interacting components and/or are complex to assemble, but also often require a comparatively large amount of space. Installation space requires in particular a device for adjusting the pivoting resistance of the backrest.

One object of the present invention is to make possible a piece of seating furniture, in particular an office chair, that requires only a comparatively small amount of space for the use of a synchronous mechanism, in particular that is particularly flat, although the pivoting resistance of the backrest can be adjusted with the synchronous mechanism used. This object is achieved by a synchronous mechanism according to claim 1 or by a piece of seating furniture according to claim 10. Advantageous embodiments of the invention are specified in the dependent claims.

Accordingly, a synchronous mechanism for a correlated seat-backrest movement of an office chair is provided, with a base support that can be placed on a chair column, a seat support and a backrest support, the backrest support being pivotably connected to the base support, thereby defining the main axis of rotation of the synchronous mechanism, with a coupling device , having a first coupling element (tension coupling) that is operatively connected to the backrest support and a second coupling element (support coupling) that is operatively connected to the base support, the first coupling element and the second coupling element being connected to one another in an articulated manner at a connection point, and having a spring arrangement for fixing of the pivoting resistance of the backrest support, the spring arrangement having at least one spring element, the spring element having a stationary end and a free end, the free end of the spring element being at the connection point of the coupling device attacks, for example by the free end of the spring element is articulated to the connection point of the coupling device or is supported at the connection point.

Compared to other mechanisms, the present synchronizing mechanism is characterized in that it can be made particularly flat due to the special design of the coupling device, which will be explained in detail below, so that a corresponding assembly requires only very little space.

This applies even if (to determine the pivoting resistance and/or to prevent the backrest from tipping backwards in an uncontrolled manner, as well as to safely return the backrest from the pivoted position to the basic position as soon as the user no longer puts any weight on the backrest) a spring mechanism with one or more spring elements is provided, since the spring mechanism can be designed in such a way that the at least one spring element connects the coupling element to the base support without requiring further additional installation space beyond the housing volume of the base support that is provided anyway. This applies in particular when the spring element is connected to the coupling element on the one hand and to the front area of the base support and is therefore arranged lying comparatively flat inside the assembly.

The design of the coupling device with a tension and a support coupling and the special connection of the spring element to the coupling device also enables an advantageous spring force setting which also requires little installation space and does not conflict with a particularly flat design of the synchro-mechanism.

Due to the selected design, a pivoting movement of the backrest from a basic position to a rearwardly pivoted position only induces an immediate lowering movement of the rear region of the seat support seen in the longitudinal direction of the seat instead of the usual raising of the entire seat. As a result, the seat is carried synchronously in a defined relationship to the backrest and the seat surface is tilted. This results in the desired synchronous effect, in which the angle of the seat support changes to the backrest support. the so-called The so-called "shirt pull-off effect" is avoided and a particularly high level of seating comfort is achieved.

According to a preferred embodiment of the invention, the first coupling element is articulated on the backrest support at a distance from the connection point and, when the backrest support pivots, pulls the connection point of the two coupling elements forwards as seen in the longitudinal direction of the seat, thereby acting on the spring element acting as a compression spring.

According to a preferred embodiment of the invention, the second coupling element is supported with an adjustment end spaced from the connection point, preferably via a support element articulated to the second coupling element, in particular a sliding shoe or the like, on a support point of the base support.

According to a preferred embodiment of the invention, the adjustment mechanism for adjusting the spring force of the at least one spring element comprises a track element which is attached to the base support in a position-changing manner and which provides the support point.

According to a preferred embodiment of the invention, the coupling device is designed in such a way that by actuating the adjustment mechanism, the location of the support point and thus the connection point of the two coupling elements in the vertical direction and thus the pretension of the at least one spring element can be changed and/or that by actuating the adjustment mechanism the spring action direction on the one hand and the distance of the spring action direction from the main axis of rotation (more precisely the distance between the pivot point of the spring element at the connection point of the coupling elements and the main axis of rotation) and thus the effective lever arm influencing the pivoting resistance of the backrest support on the other hand can be changed.

According to a preferred embodiment of the invention, the track element is formed as a part of the base support, the position of which can be changed relative to the base support, for which purpose it is preferably a mobile construction element running in a guide of the base support.

According to a preferred embodiment of the invention, the track element interacts with the variable spring end of the at least one spring element, in that the support coupling articulated at the connection point is supported on the track element via a sliding shoe articulated to the adjustment end of the support coupling, forming the support point.

According to a preferred embodiment of the invention, the track element can be moved by the user manually or motor-driven movement of the track element into vertically different positions of the support point, which can be assigned to different spring forces. The use of a toothed rack which is operatively connected to the track element as the adjustment means is advantageous because the movement of the track element can be precisely defined by the use of a gearwheel to drive the toothed rack and thus ultimately the variable-position spring end.

According to preferred embodiments of the invention, a particularly suitable coupling geometry and a synchronous movement resulting therefrom is achieved in that, regardless of the pivoting position of the backrest support, the connection point of the two coupling elements seen in the longitudinal direction of the seat is both behind the point of articulation of the first coupling element on the backrest support and behind the stationary end of the spring element is arranged, and/or that in the non-pivoted basic position of the backrest support, the connection point of the two coupling elements, seen in the longitudinal direction of the seat, is arranged both behind the main axis of rotation and behind the adjustment end of the second coupling element, and/or that in the maximum rearwardly pivoted position of the Backrest support the connection point of the two coupling elements seen in the longitudinal direction of the seat is arranged both in front of the main axis of rotation and in front of the adjustment end of the second coupling element.

• 1 eine teilweise geschnittene Seitenansicht der Synchronmechanik in der Grundstellung („harte/schwere“ Einstellung),
• 2 eine teilweise geschnittene Seitenansicht der Synchronmechanik in einer maximal nach hinten verschwenkten Stellung („harte/schwere“ Einstellung),
• 3 eine teilweise geschnittene Seitenansicht der Synchronmechanik in der Grundstellung („weiche/leichte“ Einstellung),
• 4 eine teilweise geschnittene Seitenansicht der Synchronmechanik in einer maximal nach hinten verschwenkten Stellung („weiche/leichte“ Einstellung),
• 5 Einzelheiten einer Koppelanordnung.

These and other advantages of the invention are explained below in connection with the exemplary embodiments of the invention with reference to the drawings. Here show:

• 1 a partially sectioned side view of the synchronous mechanism in the basic position (“hard/heavy” setting),
• 2 a partially sectioned side view of the synchro-mechanism in a position pivoted to the rear as far as possible ("hard/heavy" setting),
• 3 a partially sectioned side view of the synchronous mechanism in the basic position (“soft/light” setting),
• 4 a partially sectioned side view of the synchronous mechanism in a position pivoted to the rear as far as possible ("soft/light" setting),
• 5 Details of a coupling arrangement.

None of the figures show the invention to scale, but only schematically and only with its essential components. The same reference symbols correspond to elements with the same or comparable function.

"Front" or "front" means that a component is arranged at the front in the seat longitudinal direction 14 or refers to a component extending in the direction of the front edge of the seat or pointing in this direction, while "rear" or "rear" means that a component is arranged at the rear in the seat longitudinal direction 14 or refers to a component extending in the direction of the backrest or the backrest support 4 or the rear edge of the seat or pointing in this direction. The information "top" and "bottom" refers to the intended use of the office chair or the office chair mechanism 100.

The synchronous mechanism 100 has a base support 1, which is attached to the upper end of a chair column 10 by means of a cone mount 2 (see 1 ) is set. In addition, the synchronizing mechanism 100 comprises an essentially frame-shaped seat support 3 and a backrest support 4 which is fork-shaped in plan view and whose cheeks 5 are arranged on both sides of the base support 1 .

The seat support 3 is provided for receiving or mounting a preferably upholstered seat (not shown). The assembly is done with the help of fasteners not shown in the usual way. A backrest, not shown in detail, is attached to the backrest support 4, the height of which is adjustable in modern office chairs. The backrest can also be connected in one piece to the backrest support 4 .

As far as the actual kinematics are concerned, the entire synchronizing mechanism 100 has a mirror-symmetrical structure with respect to its central longitudinal plane. In this respect, the following description is always based on construction elements of the actual pivoting mechanism that are present in pairs on both sides.

In the 1 and 3 the basic position of the synchronous mechanism 100 is shown, in which the seat support 3 assumes a substantially horizontal position. 2 and 4 show the synchro-mechanism 100 in a position of the backrest support 4 pivoted to the maximum rearward.

The backrest support 4, which can be swiveled in the swiveling direction 7, is directly articulated to the base support 1 with its cheek 5 extending in the direction of the front area 17 of the mechanism about a first transverse axis 11, with this transverse axis defining the main axis of rotation 11 of the synchronous mechanism 100. The main axis of rotation 11 is seen in the longitudinal direction 14 of the seat in front of the cone mount 2.

In the rear area 6 of the mechanism, seen in the longitudinal direction 14 of the seat, the backrest support 4 is connected to the rear area 25 of the seat support 3 with an upwardly extending driver 12 of the cheek 5 via a rotating/sliding joint 24 . The main axis of rotation 11 is therefore arranged in front of the transverse axis 13 formed by the rotating/sliding joint 24 as viewed in the longitudinal direction 14 of the seat. Pivoting the backrest support 4 out of the basic position into a rearwardly pivoted position is associated with a lowering movement of the rear area 25 of the seat support 3 .

In the front area 17 of the mechanism, the front area 18 of the base support 1 is directly articulated to the front area 8 of the seat support 3, forming a further transverse axis 15. The movement of the seat support 3 and the backrest support 4 relative to one another is essentially determined by the position of the three joint axes 11, 13, 15 relative to one another. In an exemplary embodiment that is not shown, a joint is used in the rear area 6 of the mechanism instead of the rotary/sliding joint to form a simple pivot point, while a rotary/sliding joint is used in the front area 17 of the mechanism instead of the simple joint. In this variant, the axis 13 defines a pure pivot point, while the axis 15 is designed to be movable.

The backrest support 4 is connected directly to the seat support 3 only once, namely via the transverse axis 13 . In addition, the base support 1 is connected directly to the seat support 3 only once, namely via the transverse axis 15 . There is only a single direct, immediate pivot connection of the backrest support 4 to the base support 1, namely via the main axis of rotation 11. The further connection of the backrest support 4 to the base support 1 takes place via the coupling device 20 according to the invention (tension coupling and support coupling) and the coupling device 20 acting spring arrangement 19.

The pivoting mechanism described ensures that the backrest support 4 with the backrest can be pivoted backwards and downwards about the main axis of rotation 11 in the pivoting direction 7 . At the same time, this pivoting movement of the backrest support 4 induces an immediate lowering movement of the rear region 25 of the seat support 3 backwards and downwards. the one before their area 8 of the seat support 3 is not raised. When the backrest support 4 pivots, the base support 1 remains stationary.

The coupling device 20 comprises a first coupling element (traction coupling) 21 that is operatively connected to the backrest support 4 and a second coupling element (support coupling) 22 that is operatively connected to the base support 1, the first coupling element 21 and the second coupling element 22 being articulated with one another at a connection point 16 are connected. The tension coupling 21 is articulated on the backrest support 4 at a distance from the connection point 16, forming an axis of rotation 39, and when the backrest support 4 moves in the pivoting direction 7, it pulls the connection point 16 of the two coupling elements 21, 22 forward as viewed in the longitudinal direction 14 of the seat, as a result of which it acting as a compression spring spring element 30 is applied. The support coupler 22 is supported with its adjustment end 23 spaced apart from the connection point 16 at a support point 9 on a slideway 26 of the base support 1 . In the example illustrated here, this takes place via a support element, in particular a sliding shoe 48 or the like, which is attached in an articulated manner to the adjustment end 23 of the support coupling 22 . Apart from the backrest support via the pivot point 39 on the one hand and the base support via the support point 9 and via the spring element 30 on the other hand, the coupling arrangement 20 is not connected to any other structural element of the mechanism, either directly or indirectly.

The spring element 30 has a spring arrangement 19 for fixing the pivoting resistance of the backrest support 4 . The spring element 30 embodied as a compression spring exerts a spring force counter to the downward pivoting movement 7 of the backrest support 4 . In this case, the spring element 30 is acted upon when the backrest support 4 pivots. Depending on the “hardness” of the spring element 30, the synchronous movement (seat and backrest) takes place against a greater or lesser spring resistance.

A spring assembly 19 is provided with a centrally located helical compression spring 30 (not shown in detail in all figures). The spring element 30 is supported on the one hand with its stationary end 27 on a front abutment 31 and on the other hand with its free, positionable end 28 on a rear abutment 37, each with the aid of spring plates 32, 34, the rear abutment 37 being supported by the articulated connection of the two coupling elements 21, 22 is formed at the connection point 16. The spring 30, which is only in 2 is symbolically indicated, engages in one another running guide rods or sleeves 33, which have the spring plates 32, 34 at their respective ends.

The spring element 30 is directly connected to the base support 1 with its one front spring end 27 seen in the longitudinal direction 14 of the seat, in that it is supported in an articulated manner with the spring plate 32 there in a suitable bearing 31 . With its other rear spring end 28, viewed in the longitudinal direction 14 of the seat, the spring element 30 with its spring plate 34 there is supported on the connection point 16 of the two coupling elements 21, 22 in such a way that a movement of the backrest support 4 from a basic position into a rearwardly pivoted position Actuation of this rear end of the spring 28 causes.

The tension coupling 21, supported and held by the support point 9 on the slideway 26 of the base support 1 at a forced distance by the support coupling 22, performs a pivoting movement 29 when the backrest support 4 moves in the pivoting direction 7 or a resulting movement of the seat support 3 articulated thereon out, see 5 , which is directed forward as viewed in the longitudinal direction 14 of the seat, so that the compression spring 30 clamped between the base support 1 and the coupling element 21 is acted upon from behind. When the backrest support 4 pivots, the spring element 30 is loaded on one side, namely at its rear spring end 28 . To form an effective lever arm 36, the rear end of the spring 28 is connected to the coupling device 20, namely the connection point 16, at a distance from the main axis of rotation 11, in that it is supported there.

In the exemplary embodiment described here, regardless of the pivoted position of the backrest support 4, the connection point 16 of the two coupling elements 21, 22, viewed in the longitudinal direction 14 of the seat, is both behind the pivot point 39 of the tension coupling 21 on the backrest support 4 and behind the stationary end 27 of the spring element 30 arranged. In addition, when the backrest support 4 is in the non-pivoted basic position, the connection point 16 of the two coupling elements 21, 22, seen in the longitudinal direction 14 of the seat, is arranged both behind the main axis of rotation 11 and behind the adjustment end 23 of the support coupling, more precisely the support point 9. In addition, when the backrest support 4 is in the maximum rearward pivoted position, the connection point 16 of the two coupling elements 21, 22, seen in the longitudinal direction 14 of the seat, is arranged both in front of the main axis of rotation 11 and in front of the adjustment end 23 of the support coupling 22, more precisely the support point 9.

The adjusting mechanism 40 includes means for adjusting the spring force of the spring element 30 by changing the position of the rear end 28 of the spring. To change the position of the rear end of the spring 28, the adjustment mechanism 40 includes a variable location attached to the base support 1, namely along the guide 42 in the adjustment direction 49, see 5 , Displaceable track element 41, which provides the support point 9 for the support coupling 22.

The coupling device 20 is designed in such a way that by actuating the adjustment mechanism 40, the location of the support point 9 and thus the location of the connection point 16 of the two coupling elements 21, 22 can be changed in height (in the vertical direction) and thus the pretension of the at least one spring element 30 . At the same time, by actuating the adjustment mechanism 40, the spring action direction (direction of the spring action line) 38 on the one hand and the distance between the pivot point 16 of the spring element 30 on the coupling device 20 on the one hand and the main axis of rotation 11 on the other hand can be changed. As a result, the effective lever arm 36 influencing the pivoting resistance of the backrest support 4 can also be determined directly.

The web element 41 is designed as a part of the base support 1 . The position of the web element 41 relative to the base support 1 can be changed. For this purpose, the track element 41 is designed as a mobile structural element that runs in a straight line guide 42 of the base support 1 that is inclined to the horizontal and that descends backwards as viewed in the longitudinal direction 14 of the seat. The track element 41 forms a sliding track 26 which runs obliquely to the horizontal in the direction of the support coupling 22 and on which the adjustment end 23 of the support coupling 22 is supported. Therefore, when the pivoting resistance is adjusted, the support coupling 22 (due to the movement of the track element 41 forwards in the “heavy setting” direction) is pressed downwards, as a result of which the vertical position of the rear spring end 28 changes.

In other words, the track element 41 interacts with the variable-position spring end 28 of the spring element 30 in that the support link 22, which is articulated at the connection point 16, is supported on the track element 41 via the sliding shoe 48, which is articulated to the adjustment end 23 of the support link 22, and forms the support point 9 . A toothed rack 43 is attached to the track element 41 and the adjustment mechanism 40 has a gear wheel 44 for adjusting the track element 41, the gear wheel 44 engaging in the toothed rack 43 for adjusting the track element 41. The gear wheel 44 is rotated, for example, by means of a manually operable handle (not shown), for example with a rotary handle or a hand wheel. Alternatively, the gear wheel 44 can also be driven via levers, Bowden cables, etc. An (electric) motor drive can also be provided instead of manual actuation. The movement of the web element 41 can also be effected without a rack and pinion mechanism by means of suitable alternative actuating means.

Instead of a straight slideway 26 provided by the track element 41, the slideway 26 can also have a non-linear curved shape and/or a different slope, whereby the adjustment characteristics of the pivoting resistance can be modified compared to the variant shown here.

In the in the 1 and 2 In the hardest setting shown, the web element 41 is in its foremost position. The support point 9 is therefore located at the rear end of the slideway 26 and is therefore particularly deep. The distance 35 between the line of action 38 of the spring 30 to the main axis of rotation 11 of the mechanism is greatest in this position, or to put it another way, the length of the effective lever arm 36 perpendicular to the line of action of the spring 38 is greatest. The spring 30 is most compressed due to the greater preload. The pivoting resistance is greatest in this position. The spring 30 already has the greatest hardness at the beginning of the pivoting process, without the backrest support 4 having to be pivoted for this purpose. The restoring torque acting on the mechanism in this setting when the backrest support 4 pivots is also maximum.

You get from the "hard" to the "soft" setting when the gear wheel 44 mounted on the base support 1 is rotated in the direction of actuation 47, see FIG 3 . The track element 41 is moved backwards as seen in the longitudinal direction 14 of the seat. The support point 9 is located at the front end of the slideway 26 and is therefore particularly high. The effective lever arm 36 is shorter, the spring deflection and thus the pivoting resistance is correspondingly lower.

All of the features presented in the description, the following claims and the drawings can be used individually. as well as in any combination with one another.

Reference List

1

base carrier

2

cone mount

3

seat carrier

4

backrest support

5

cheek

6

rear mechanics area

7

pan direction

8th

front area of the seat carrier

9

support point

10

chair column

11

Main axis of rotation, transverse axis

12

driver

13

Axis of the rotating/sliding joint

14

seat longitudinal direction

15

front transverse axis

16

connection point

17

front mechanics area

18

front area of the base carrier

19

spring assembly

20

coupling device

21

coupling

22

support paddock

23

end of adjustment

24

Swivel/slide joint

25

rear area of the seat carrier

26

slideway

27

front end of the spring

28

rear spring end

29

pivoting movement

30

Helical compression spring, spring element

31

front abutment

32

front spring plate

33

guide rod, guide sleeve

34

rear spring plate

35

Distance

36

lever arm

37

rear abutment

38

spring action line

39

Pivot point of the towing coupler

40

adjustment mechanism

41

track element

42

guide

43

rack

44

gear

45

(free)

46

(free)

47

operating direction

48

Support element, sliding shoe

49

adjustment direction

100

synchronous mechanism

Claims (10)

Synchronous mechanism (100) for a correlated seat-backrest movement of an office chair, with a base support (1) that can be placed on a chair column (10), a seat support (3) and a backrest support (4), the backrest support (4) being pivotable with the Base support (1) is connected, thereby defining the main axis of rotation (11) of the synchronous mechanism (100), with a coupling device (20), having a first coupling element (21) that is operatively connected to the backrest support (4) and a second coupling element (22) that is operatively connected to the base support (1), the first coupling element (21) and the second Coupling element (22) are connected to one another in an articulated manner at a connection point (16), and with a spring arrangement (19) for fixing the pivoting resistance of the backrest support (4), the spring arrangement (19) having at least one spring element (30), the spring element (30) having a stationary end (27) and a free end (28) having, wherein the free end (28) engages the connection point (16) of the coupling device (20). Synchronous mechanism (100) according to claim 1 , wherein the stationary end (27) of the spring element (30) engages on the base support (1). Synchronous mechanism (100) according to claim 1 or 2 , wherein the first coupling element (21) is articulated on the backrest support (4) at a distance from the connection point (16) and when the backrest support (4) pivots from a non-pivoted basic position to a rearwardly pivoted position viewed in the longitudinal direction (14) of the seat, the Connection point (16) of the two coupling elements (21, 22) viewed in the longitudinal direction (14) of the seat pulls forward. Synchronous mechanism (100) according to claim 3 , wherein the second coupling element (22) with a from the connection point (16) spaced adjustment end (23) on a support point (9) of the base support (1) is supported. Synchronous mechanism (100) according to claim 4 with an adjustment mechanism (40) for adjusting the spring force of the at least one spring element (30), the adjustment mechanism (40) having a track element (41) which is attached to the base support (1) so that it can be moved and on which the support point (9) is located. Synchronous mechanism (100) according to claim 5 , wherein by actuating the adjustment mechanism (40) the location of the support point (9) and thus the location of the connection point (16) of the two coupling elements (21, 22) in the vertical direction and thus a) the pretension of the at least one spring element (30) and /or b) the spring action direction (38) and the distance (35) of the spring action direction (38) from the main axis of rotation (11) can be changed. Synchronous mechanism (100) according to claim 5 or 6 , wherein a toothed rack (43) is attached to the track element (41) and the adjustment mechanism (40) has a gear wheel (44) for adjusting the track element (41). Synchronous mechanism (100) according to one of Claims 5 until 7 , wherein a) regardless of the pivoted position of the backrest support (4), the connection point (16) of the two coupling elements (21, 22) viewed in the longitudinal direction (14) of the seat is both behind the pivot point (39) of the first coupling element (21) on the backrest support (4 ) and behind the stationary end (27) of the spring element (30), b) in the non-pivoted basic position of the backrest support (4), the connection point (16) of the two coupling elements (21, 22) viewed in the longitudinal direction (14) of the seat both is arranged behind the main axis of rotation (11) and also behind the support point (9) of the second coupling element (22), c) when the backrest support (4) is in the maximum rearward pivoted position, the connection point (16) of the two coupling elements (21, 22) in Seen in the longitudinal direction (14) of the seat, it is arranged both in front of the main axis of rotation (11) and in front of the support point (9) of the second coupling element (22). Synchronous mechanism (100) according to one of Claims 1 until 8th , the backrest support (4) being connected to the seat support (3) in such a way that when the backrest support (4) pivots (7) from a basic position into a rearwardly pivoted position relative to the stationary base support (1), the seat support (3 ) is taken backwards. Seating furniture, in particular an office chair, with a synchronous mechanism (100) according to one of Claims 1 until 9 .

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