DE202015100510U1 - synchronous mechanism - Google Patents

Abstract

Synchronous mechanism (100) for a correlated seat-backrest movement of an office chair, with a base support (1), which can be placed on a chair column (10), a seat support (3) and a back support (4),
wherein the backrest support (4) is pivotally connected both to a first transverse axis (11) pivotally connected to the base support (1), and with the seat support (3) and
wherein the seat carrier (3) is articulated to the base support (1) via a coupling element (21),
wherein the coupling element (21) is pivotally connected both to a second transverse axis (19) pivotally connected to the base support (1), and with the seat support (3),
wherein a spring mechanism is provided for adjusting the pivoting resistance of the backrest, which spring mechanism has at least one spring element (30),
characterized in that
the at least one spring element (30) with its one spring end (27) connected to the backrest support (4) and with its other spring end (28) either with the seat support (3) or with the coupling element (21) is such that a movement of Backrest causes a movement of both spring ends (27, 28).

Description

The invention relates to a synchronous mechanism for a correlated seat-backrest movement of an office chair, with a placeable on a chair column base support, a seat support and a backrest support.

The term "synchronous mechanism" assemblies are understood in the seat base of an office chair, which provide for a coupled, a certain relative movement of the seat and backrest with each other bringing kinematics. On the seat support of the usually provided with a padded seat seat of the office chair is mounted. The backrest support, which extends in a conventional manner from the actual synchronizing mechanism to the rear, carries on an upwardly extending arm, the backrest of the office chair.

It is known to construct certain types of synchronous mechanisms such that the user of the office chair raises himself by a load on the backrest. In other words, the user works while pressing the synchronous mechanism by pushing back the back against his own, resting on the seat weight. The desired swivel resistance thus arises, as it were, automatically due to the weight of the user.

Such self-adjusting synchronous mechanisms are not only often comparatively complicated, consist of a large number of interacting components and / or are expensive to install, but often also require a relatively large amount of space.

An object of the present invention is to provide a structurally simple self-adjusting synchronous mechanism, which requires a small space. This object is achieved by a synchronous mechanism according to claim 1. Advantageous embodiments of the invention are specified in the subclaims.

Thereafter, a synchronous mechanism for a correlated seat-backrest movement of an office chair is provided, with a placeable on a chair column base support, a seat support and a backrest support, wherein the backrest support is pivotally connected both about a first transverse axis pivotally connected to the base support and the seat support and wherein the seat carrier is pivotally connected via a coupling element to the base support, wherein the coupling element is pivotally connected both to a second transverse axis pivotally connected to the base support and the seat support, wherein a spring mechanism is provided for adjusting the pivotal resistance of the backrest, which spring mechanism at least a spring element, wherein the at least one spring element is connected with its one spring end to the backrest support and with its other spring end either with the seat support or with the coupling element such that a movement of Rüc kenlehne causes a movement of both spring ends.

Because of the two-sided loading of the at least one spring element only a very short spring travel is required to achieve the desired spring action. As a result, very little space is required for the construction of the mechanism. The necessary construction elements can be accommodated in a comparatively small space, in particular by realizing a particularly low overall height of the mechanism.

The desired two-sided loading of the at least one spring element is preferably achieved in that the one spring end spaced from the first transverse axis with the backrest support and / or the other spring end with the seat support or, if it is connected to the coupling element, spaced therefrom with the second Transverse axis is connected. This serves to form a number of lever arms, with the help of which in a pivoting of the backrest carrier to the rear, as it is caused by a leaning of the user to the backrest, the two-sided application is caused.

Preferably, the at least one spring element is so connected to the corresponding structural elements of the mechanism that the two-sided application causes the distance between the two spring ends changed to one another. Preferably, the two-sided loading causes, depending on whether it is the at least one spring element is a compression spring or a tension spring, either a reduction or increase in the distance between the two spring ends to each other.

Preferably, the spring mechanism comprises means for adjusting the spring force of the at least one spring element such that the distance of a spring end to the first transverse axis and / or the distance of a spring end to the second transverse axis is variable. In this way, the effective lever arm determining the application of the spring ends and thus influencing the pivoting resistance of the backrest support can be lengthened or shortened. When adjusting the spring force, the position of the spring element in the mechanics, in particular their inclination is changed, as a result, the bias of the overall mechanism changes.

The adjustment of the spring force is preferably carried out such that no work against the spring force must be performed. For such a "powerless" spring force adjustment, the adjusting means are designed such that the variable-position spring end is movable on a circular path with a substantially constant radius about the other end of the spring. The bias of the spring element remains unchanged.

Preferably, the adjusting means comprise a cam drive, the cam roller cooperating with a cam carrier is connected to a variable position spring end of the at least one spring element and is movable by a manual or motorized by the user movement of the cam carrier in positions of different spring force. The use of a cam drive as adjusting means is advantageous because of the precisely defined by the predetermined curve slope movement curve of the spring end.

With the present invention, moreover, the number of coupling elements, in particular the number of seat support and backrest support connecting elements is reduced, thereby achieving a particularly simple structural design of the mechanism, without sacrificing the desired functionality of a synchronous mechanism. For this reason, the backrest support is pivotable both about a transverse axis and thus defining the main pivot axis of the mechanism defining the base support as well as the seat support preferably directly, i. directly and without the interposition of an additional component, hinged.

The connection of the three main components of the mechanism, base support, seat support and backrest support to each other is preferably carried out such that a pivoting movement of the backrest from a basic position both in a pivoted backward position an immediate lowering movement of the chair in the longitudinal direction rear portion of the seat support back down also induced an immediate lifting movement of seen in the chair longitudinal direction front portion of the seat support to the rear above.

Instead of the usual lifting of the entire seat so the rear portion of the seat is lowered at a pivoting of the backrest in its rearwardly pivoted position, while the front portion of the seat is raised. The lowering of the rear seating area takes place directly at each leaving the basic position, without about initially a lifting movement of the rear seating area takes place. The basic position is considered that position in which the backrest is not pivoted to the rear.

Characterized in that the seat support is lowered in its rear region and at the same time takes place a lifting of the front portion of the seat support, there is a synchronous entrainment of the seat in a defined relationship to the backrest and a tilting of the seat. This gives the desired synchronizing effect, in which the angle of the seat support to the backrest support changes.

The user's weight directly affects the swing resistance felt by the user. A light user must overcome a significantly lower swing resistance when pivoting than a heavy user. Subjectively, the same "perceived" resistance arises when pivoting the backrest for each user.

The special synchronous movement of the mechanism according to the invention is preferably achieved in a particularly simple manner in that a coupling element formed as an integral part of the backrest support is defined by the positions of the articulation points of the backrest support on the base support on the one hand and on the seat support on the other hand. In other words, no reciprocally freely pivotable coupling element is required between the backrest support and the seat support. Instead, the backrest support itself serves as a coupling element.

A particularly suitable coupling geometry and a resulting synchronous movement is achieved in a preferred embodiment of the invention in that the pivot point of the backrest support seen in the seat longitudinal direction in the seat longitudinal direction in each position of the backrest support behind the pivot point of the backrest support to the base support and the pivot point of the front coupling element the seat support seen in the seat longitudinal direction is in any position of the backrest support in front of the articulation point of the front coupling element to the base support. Preferably, this is supported by the fact that the front coupling element is connected to the seat support via a pure rotary joint and not about in combined rotary / sliding joint.

Compared to other self-adjusting mechanisms, the present synchronous mechanism is characterized in that it is particularly flat, so that a corresponding assembly requires very little space. In other words, with the invention in an elegant manner in a small space, a particularly high level of comfort without the so-called "shirt extraction effect" achieved without must be resorted to complex and expensive constructive solutions.

These and other advantages of the invention will be explained in connection with the embodiments of the invention with reference to the drawings. Hereby show:

1 a side view of the synchronous mechanism in the basic position ("hard" setting),

2 a partially sectioned side view of the synchronizing mechanism in the basic position ("hard" setting),

3 a side view of the synchronizing mechanism in a maximum rearwardly pivoted position ("hard" setting),

4 a side view of the synchronizing mechanism in the basic position ("soft" setting),

5 a partially sectioned side view of the synchronizing mechanism in the basic position ("soft" setting),

6 a side view of the synchronous mechanism in a maximum rearward pivoted position ("soft" setting).

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

First, the general structure and sequence of movements of the mechanics will be explained.

The synchronous mechanism 100 has a base carrier 1 on, by means of a cone recording 2 on the top of a chair column 10 (please refer 1 ) is set. In addition, the synchronous mechanism includes 100 a substantially frame-shaped seat support 3 and a fork-shaped in plan view backrest support 4 whose cheeks 5 on both sides of the base 1 are arranged.

The seat carrier 3 is intended for receiving or mounting a preferably padded seat (not shown). The assembly is done using not shown fasteners in the usual way. On the backrest support 4 a non-illustrated backrest is attached, which is height adjustable in modern office chairs. The backrest can be used with the backrest support 4 also be integrally connected.

The entire synchronous mechanism 100 is with respect to its central longitudinal plane, as regards the actual kinematics, constructed mirror-symmetrical. In that regard, in the following description is always based on both sides in pairs existing construction elements of the actual pivot mechanism.

In the 1 and 2 as well as the 4 and 5 is the basic position of the synchronous mechanism 100 shown in which the seat carrier 3 a substantially horizontal position occupies. 3 and 6 show the synchronous mechanism 100 in a maximum rearwardly pivoted position of the backrest support 4 ,

In the chair longitudinal direction 14 seen the rear area 6 the mechanics is the backrest support 4 on the one hand with the rear area 9 of the basic holder 1 and on the other hand with the rear area 25 of the seat wearer 3 immediately articulated connected.

The backrest carrier 4 is doing his part towards the front seating area 8th extending cheek 5 directly to the base carrier 1 hinged and thus to a fixed main pivot axis of the synchronous mechanism 100 defining the first (rear) transverse axis 11 in the swing direction 7 pivotable. With an upwardly extending driver 12 the cheek 5 is the backrest support 4 with the seat carrier 3 immediately articulated connected.

The by the articulation of the backrest support 4 at the base carrier 1 defined first joint axis 13 is in chair's longitudinal direction 14 seen in front of by the articulation of the backrest support 4 on the seat carrier 3 defined second hinge axis 15 arranged. Opposite the vertical on the main pivot axis of the synchronous mechanism 100 is the second hinge axis 15 Although only slightly offset to the rear. A zenith position immediately above the first hinge axis 13 but can not be achieved. Swinging out the backrest carrier 4 from the basic position in a pivoted backward position is therefore always with a lowering S of the rear area 25 of the seat wearer 3 connected.

In the basic position are both joint axes 13 . 15 in chair longitudinal direction 14 seen in front of the center of the cone 2 , In the maximum backward pivoted position is the second hinge axis 15 in chair longitudinal direction 14 seen behind the center of the cone shot 2 while the position of the first hinge axis 13 opposite the cone holder 2 is immutable.

Through the positions of the pivot points of the backrest support 4 at the base carrier 1 on the one hand and on the seat carrier 3 on the other hand, a rigid with the backrest support 4 connected, as an integral part of the backrest support 4 trained coupling element 16 defines how it is in 1 is shown symbolically with dotted line. The coupling element 16 constructively consists exclusively of a part of the cheek 5 , The arrangement of the coupling element 16 immediately above the cone holder 2 contributes to an advantageous movement of the synchronous mechanism 100 at.

In the front area 17 the mechanics is the front area 18 of the basic holder 1 with the front area 8th of the seat wearer 3 articulated. For this purpose, a coupling element 21 provided, on the one hand directly to the base support 1 namely, a second (front) transverse axis 19 pivotable, and on the other hand directly to the seat support 3 is articulated. The front transverse axis 19 is, as well as the rear transverse axis 11 stationary to the base carrier 1 and thus fixed, so is at a pivoting of the backrest support 4 not moving. The articulation point of the coupling element 21 at the base carrier 1 and thus the third hinge axis 22 located in Stuhllängsrichtung 14 seen behind the articulation point of the coupling element 21 on the seat carrier 3 and thus behind the fourth joint axis 23 ,

Even in a maximum backward pivoted position of the synchronous mechanism 100 changes the order of arrangement of the joint axes 13 . 15 . 22 . 23 Not. The rear coupling element 16 shows in Stuhllängsrichtung 14 seen from the first transverse axis 11 in each case obliquely upwards and to the rear and the front coupling element 21 shows in Stuhllängsrichtung 14 seen from the second transverse axis 19 in each case diagonally upwards and forwards. The joint axes run thereby 15 . 23 at the articulation points of the seat support 3 Seen in the vertical direction always above the joint axes 13 . 22 by the linkage to the base plate 1 To be defined. The coupling elements 16 . 21 are mutually V-shaped, with the imaginary extension lines of the coupling elements 16 . 21 below the base carrier 1 to cut. The relative movement of seat support 3 and backrest support 4 to each other by the position of the four total by the ends of the two coupling elements 16 . 21 extending, defined by the articulation points hinge axes 13 . 15 . 22 . 23 certainly.

By the described pivot mechanism ensures that the backrest support 4 with the backrest around the rear transverse axis serving as the main pivot axis 11 , here the first joint axis 13 , in swivel direction 7 can be pivoted. At the same time, the pivotal movement of the backrest to the rear induces an immediate lowering movement S of the rear area 25 of the seat wearer 3 back down and the front area 8th of the seat wearer 3 performs a lifting movement H backwards (see 1 ). In a pivoting of the backrest thus takes place at the same time a displacement of the seat support 3 to the rear, while the base carrier 1 with the pivot bearings 13 . 22 and their transverse axes 11 remains fixed in position.

The mechanic 100 has a spring mechanism for adjusting the pivoting resistance of the backrest. This comprises at least one spring element 30 , please refer 2 , The spring element 30 it exerts a spring force against the rearward pivoting movement 7 the backrest off. In this case, the spring element 30 when pivoting the backrest support 4 applied. Depending on the "hardness" of the spring element 30 Thus, the synchronous movement (seat and backrest) takes place against a more or less large spring resistance.

It is a spring arrangement with a centrally arranged helical compression spring 30 provided, which on the one hand on a front abutment 31 and on the other hand at a rear abutment 37 with the help of spring plates 32 . 34 supported (not shown in detail in all figures). The feather 30 that alone in detail 2 is shown, thereby embracing guide rods 33 , which at their respective ends the spring plates 32 . 34 exhibit.

When pivoting the backrest support 4 becomes the spring 30 loaded on both sides. More precisely, this is at least one spring element 30 with his one, in Stuhllängsrichtung 14 seen the rear end of the spring 27 directly with the backrest support 4 and with his other, in chair-lengthwise direction 14 seen front end of spring 28 either directly with the seat carrier 3 or directly with the coupling element 21 connected such that a movement of the backrest from a basic position in a pivoted rearward position simultaneous movement of both spring ends 27 . 28 causes.

The rear end of the spring 27 is to form a length-variable in the illustrated embodiment rear lever arm 35 spaced from the first transverse axis 11 with the backrest support 4 connected. Is it the spring element 30 around a compression spring, as shown in the figures, there is this connection point 40 below the first transverse axis 11 , That means the back end 27 of the spring element 30 at one over the pivot point 11 with the base carrier 2 outstretched arm 20 the cheek 5 is articulated. For this purpose, the is towards the front seat edge 8th extending cheek 5 diagonally forward and downwards over the pivot point 11 extended out, creating one with the backrest support 4 pivoting lever arm 35 is formed. The connection point 40 the feather 30 with the backrest support 4 then lies in Stuhllängsrichtung 14 Always seen below and in front of the rear transverse axis 11 ,

In the event that a tension spring would be used (not shown), the connection point would 40 above the first transverse axis 11 located between the two points of articulation 13 . 15 of the backrest wearer 4 to basic carriers 1 and seat carrier 3 ,

The front end of the spring 28 is to form a constant length in the illustrated embodiment, front lever arm 36 from the front transverse axis 19 positioned at a distance, namely either with the seat carrier 3 connected, in particular with the front area 8th of the seat wearer 3 , preferably at the point of articulation 23 of the coupling element 21 on the seat carrier 3 , or, as shown, with the coupling element 21 , Is it the spring element 30 around a compression spring, as shown in the figures, there is this connection point 42 above the second transverse axis 19 between the two points of articulation 22 . 23 of the coupling element 21 to basic carriers 1 and seat carrier 3 so that the connection point 42 the feather 30 with the coupling element 21 in chair longitudinal direction 14 Always seen above and in front of the front transverse axis 19 lies.

The coupling element 21 performs as a kind of link during a pivoting movement of the backrest or the seat hinged thereto to the backrest support 4 directed pivoting movement 29 from that with the pivoting movement 41 the lever arm 20 the backrest support cooperates, that between the backrest support 4 and the coupling element 21 clamped compression spring 30 is compressed at the same time from both sides.

In the event that a tension spring would be used (not shown), the connection point of the spring would have to with the coupling element 21 below and in chair longitudinal direction 14 seen behind the second transverse axis 19 for what, if necessary, the coupling element 21 down, over the pivot point 22 of the coupling element 21 at the base carrier 1 addition, would have to be extended.

The two spring ends 27 . 28 be at a pivoting of the backrest support 4 acted upon so that the distance between the two spring ends 27 . 28 changed each other. Is it used in the spring element used is a compression spring 30 , This is the distance between the two spring ends 27 . 28 reduced to each other. In the case of a tension spring (not shown), the application of both spring ends 27 . 28 to an increase in the distance between the two spring ends 27 . 28 ,

The position of the rear articulation point 40 of the spring element 30 on the backrest support 4 So defines the length of a lever arm 35 to the main pivot axis 11 the mechanics 100 , When pivoting the backrest support 4 becomes the arm 35 forward in the swing direction 41 pivoted, causing the rear end of the spring 27 is charged. At the same time changes in a pivoting of the backrest support 4 also the position of the front spring end 28 at the paddock 21 or on the seat support 3 is articulated. As this seat carrier 3 in addition to a tilting movement to the rear bottom and a horizontal displacement to the rear performs, the result is a two-sided loading of the compression spring 30 reached.

According to the invention, the spring ends 27 . 28 connected to components, more precisely hinged to components, resulting in a pivoting of the backrest support 4 pivot each other in such a way that the spring ends 27 . 28 move in opposite directions, but in any case move such that their movement to a change in the distance of the spring ends 27 . 28 contribute to each other, whereby a greater spring action can be achieved.

The feather 30 is preferably arranged and the connection of the spring 30 with the backrest support 4 Preferably carried out such that in the initial position, the line of action of the spring 30 substantially perpendicular to the lever arm 35 stands.

The change of the swing resistance will be described in more detail below.

The spring mechanism comprises means for adjusting the spring force of the at least one spring element 30 by the position of at least one of the two spring ends 27 . 28 and thus the distance between the two spring ends 27 . 28 is changed. Shown in the figures is an adjustment of the rear end of the spring 27 , This is the removal of the rear end of the spring 27 to the first transverse axis 11 changed. When adjusting the front end of the spring 28 (not shown) would be corresponding to the removal of the front end of the spring 28 to the second transverse axis 19 to be changed. Also possible is a preferably simultaneous adjustment of the position of both spring ends 27 . 28 to increase the adjustment effect at the same adjustment.

In order to achieve a "powerless" spring force adjustment, the adjustment means are designed such that to be adjusted, variable position spring end 27 on a circular path with a substantially constant radius around the other end of the spring 28 of the spring element 30 is movable. If no simultaneous adjustment of both spring ends 27 . 28 takes place, the other end of the spring remains 28 during this adjustment position immutable.

The change in the position of the spring end 27 . 28 takes place preferably by means of a cam drive 43 , The curve drive 43 has a manually and / or motor-operated, movable on the backrest support 4 mounted, in particular rotatably mounted, preferably eccentric cam carrier 44 on, with a serving as a scanning cam follower 45 interacts with the curve 46 the cam carrier 44 cooperates or is engaged. In a simple case where the cam carrier 44 is designed as a cam, running, as shown, the cam roller 45 one-sided on the curve 46 to which they pass through the at least one spring element 30 is pressed. The cam roller 45 is with the rear end of the spring 27 or at an adjustment of the front end of the spring 28 (not shown) connected to this. By a movement of the cam carrier 21 can the cam roller 45 and thus the spring end attached there 27 . 28 in positions relative to the first transverse axis 11 be moved, which have different spring forces. Here is the cam roller 45 in the illustrated embodiment of the invention with a sliding block 51 provided and lies in one in the backrest support 4 or in the coupling element 21 provided slot 47 or otherwise with the backrest support 4 or at an adjustment of the front end of the spring 28 (not shown) with the coupling element 21 connected. The slot 47 is curved, namely circular executed such that the cam roller 45 and thus the rear end of the spring 27 on a circular path with a substantially constant radius around the other end of the spring 28 is movable.

The variable position spring end 27 . 28 of the spring element 30 is with the relevant construction element (backrest support 4 or coupling element 21 ) connected by a bolt or other to scan the curve 46 suitable component on which the spring end 27 . 28 attached, for example, is suspended, in this construction element 4 . 21 is directly or indirectly managed or stored. This is the scanning component, so for example, the cam roller 45 , in particular in a curved guide groove, a guide slot or the like and is based on a defined, from its position on the curve 46 dependent, the spring force of the spring element 30 determining position of the construction element 4 . 21 it depends on this design element 4 . 21 assigned, fixed transverse axis 11 . 19 is spaced. In other words, a suitable component, for example in the form of a bolt, is used, on the one hand with an adjustable cam carrier 44 , For example, the cam, cooperate and as a cam roller 45 the curve 46 the cam 44 on the other hand, as a kind of sliding shoe 51 to act or interact with a shoe or the like, which is on a slide, for example in the form of a guide or a curved slot 47 , on the backrest support 4 (with an adjustability of the rear spring end 27 ) or on the coupling element 21 (with an adjustability of the front end of the spring 28 ) is supported.

On the course of the curve 46 defining edge of the cam 44 are the local course of the curve 46 determining hollows 48 . 49 provided, which at defined points of the curve 46 a sufficiently large self-locking, so a sufficient resistance against slipping of the cam roller 45 on the bend 46 , guarantee. This leaves the cam roller 45 in place, even if to achieve the shortest possible adjustment in the adjustment of the spring force of the spring element 30 a cam carrier 44 is used, which is a curve 46 with the steepest possible rise, so a steep curve angle has.

An advantage of the hollows 48 . 49 is that thereby a stepped adjustment of the spring force is possible, which is often considered advantageous from the user's point of view, since the adjustment of the spring end with a more or less strong engagement of the cam roller 45 in the respective trough 48 . 49 which provides the user with tactile feedback on a successful completion of the adjustment process. However, it is also a version with continuous smooth edge of the curve possible.

From the "hard" to the "soft" setting and back one arrives, if at the rear transverse axis 11 mounted eccentric cam 44 in the direction of actuation 50 is turned. In the in the 1 to 3 pictured hardest setting is the cam roller 45 in the backmost hollow 48 the curve 46 one. The effective lever arm 35 from the point of attack 40 the feather 30 to the main pivot axis 11 is the biggest. In this position, the pivot point must 40 the feather 30 at the same pivot angle of the backrest support 4 cover a larger distance. In other words, the spring travel is longer. Because of this, the spring will 30 more compressed. The swing resistance is harder. This shows the spring 30 already at the beginning of the pivoting process to the greatest hardness, without causing a pivoting of the backrest support 4 necessary is.

In the in 5 pictured softest setting is the cam roller 45 in the foremost hollow 49 the curve 46 one. The effective lever arm 35 is shorter, the spring travel and thus the swivel resistance correspondingly lower.

The rotation of the cam carrier 44 in the direction of actuation 50 For example, by means of a manually operable handle, for example with a rotary handle or a handwheel (not shown). This handle is on the backrest support 4 stored, wherein the axis of rotation of the handwheel with the rear transverse axis 11 matches. Alternatively, the cam carrier 44 also be driven by levers, Bowden cables, etc. Also, instead of a manual operation, a (electric) motor drive can be provided.

In an alternative embodiment of the invention (not shown) is the cam carrier 44 carried out such that the cam roller 45 on or in the curve 46 the cam carrier 44 is forcibly led. For this purpose, the cam carrier 44 preferably designed as a spiral curve guide groove for the cam roller 45 on. In this case, the adjustment can be made stepless in any case.

Depending on the space available, a large or small cam can be used 44 be used. Also, depending on the desired size, a curve 46 be used with a low or a steep grade. Likewise, by choosing the curve 46 , in particular by deciding whether a curve 46 is used with constant or variable pitch, the adjustment of the swing resistance can be adjusted.

The spring force adjustment described by changing the position of the rear end of the spring 27 can also be used for the front end of the spring 28 be used. In this case, in the coupling element 21 a suitable guide, for example a curved slot, for one with the front end of the spring 28 connected cam roller 45 intended.

Overall, thus resulting in a few components realizable and very little space required spring force adjustment.

All features set forth in the description, the appended claims and the drawings may be considered individually. as well as in any combination with each other essential to the invention.

LIST OF REFERENCE NUMBERS

LIST OF REFERENCE NUMBERS

1

base support

2

cone holder

3

seat support

4

Backrest support

5

cheek

6

rear mechanics area

7

pan direction

8th

front area of the seat support

9

rear area of the base carrier

10

chair column

11

Main pivot axis, first (rear) transverse axis

12

takeaway

13

first joint axis

14

Chair longitudinally

15

second hinge axis

16

rear coupling element

17

front mechanics area

18

front area of the base carrier

19

second (front) transverse axis

20

poor

21

coupling element

22

third joint axis

23

fourth joint axis

24

(free)

25

rear area of the seat support

26

(free)

27

rear end of spring

28

front end of spring

29

Pivoting movement of the coupling element

30

Helical compression spring, spring element

31

front abutment

32

front spring plate

33

guide rod

34

rear spring plate

35

rear lever arm

36

front lever arm

37

rear abutment

38

(free)

39

(free)

40

Connection / application point of the rear end of the spring

41

Pivoting movement of the rear lever arm

42

Connection / application point of the front end of the spring

43

cam drive

44

Cam carrier, cam disc

45

Cam follower, scanner

46

Curve

47

Long hole

48

rear hollow

49

front trough

50

operating direction

51

shoe

100

 synchronous mechanism

H

raising movement

S

lowering

Claims (10)

Synchronous mechanism ( 100 ) for a correlated seat-backrest movement of an office chair, with one on a chair column ( 10 ) placeable base carrier ( 1 ), a seat carrier ( 3 ) and a backrest support ( 4 ), wherein the backrest support ( 4 ) around both a first transverse axis ( 11 ) pivotable with the base carrier ( 1 ), as well as with the seat support ( 3 ) is hinged and wherein the seat support ( 3 ) via a coupling element ( 21 ) with the base carrier ( 1 ) is hingedly connected, wherein the coupling element ( 21 ) about both a second transverse axis ( 19 ) pivotable with the base carrier ( 1 ), as well as with the seat support ( 3 ) is pivotally connected, wherein a spring mechanism is provided for adjusting the pivoting resistance of the backrest, which spring mechanism at least one spring element ( 30 ), characterized in that the at least one spring element ( 30 ) with its one spring end ( 27 ) with the backrest support ( 4 ) and with its other spring end ( 28 ) either with the seat carrier ( 3 ) or with the coupling element ( 21 ) is connected such that a movement of the backrest, a movement of both spring ends ( 27 . 28 ). Synchronous mechanism ( 100 ) according to claim 1, wherein said one spring end ( 27 ) spaced from the first transverse axis ( 11 ) with the backrest support ( 4 ) connected is. Synchronous mechanism ( 100 ) according to claim 1 or 2, wherein the other spring end ( 28 ), when connected to the coupling element ( 21 ), with this spaced from the second transverse axis ( 19 ) connected is. Synchronous mechanism ( 100 ) according to one of claims 1 to 3, wherein the spring ends ( 27 . 28 ) of the at least one spring element ( 30 ) in such a way with the backrest support ( 4 ) on the one hand and with the seat support ( 3 ) or with the coupling element ( 21 ) are connected on the other hand, that a movement of the backrest, a change in the distance between the two spring ends ( 27 . 28 ) causes each other. Synchronous mechanism ( 100 ) according to claim 4, wherein the spring ends ( 27 . 28 ) of the at least one spring element ( 30 ) in such a way with the backrest support ( 4 ) on the one hand and with the seat support ( 3 ) or with the coupling element ( 21 ) are connected on the other hand, that a movement of the backrest, a reduction of the distance of the two spring ends ( 27 . 28 ) causes each other. Synchronous mechanism ( 100 ) according to claim 4, wherein the spring ends of the at least one spring element ( 30 ) in such a way with the backrest support ( 4 ) on the one hand and with the seat support ( 3 ) or with the coupling element ( 21 ) are connected on the other hand, that a movement of the backrest, an increase in the distance between the two spring ends ( 27 . 28 ) causes each other. Synchronous mechanism ( 100 ) according to one of claims 1 to 6, wherein the spring mechanism comprises means ( 43 ) for adjusting the spring force of the at least one spring element ( 30 ) such that the removal of at least one of the spring ends ( 27 ) of the at least one spring element ( 30 ) to the first transverse axis ( 11 ) and / or the removal of at least one of the spring ends ( 28 ) of the at least one spring element ( 30 ) to the second transverse axis ( 19 ) is changeable. Synchronous mechanism ( 100 ) according to claim 7, wherein the adjusting means ( 43 ) are formed such that the at least one variable position spring end ( 27 ) of the at least one spring element ( 30 ) on a circular path with a substantially constant radius around the other spring end ( 28 ) of this spring element ( 30 ) is movable. Synchronous mechanism ( 100 ) according to claim 7 or 8, wherein the adjustment means ( 43 ) have a cam drive, with a movably mounted cam carrier ( 44 ) and with a cam roller ( 45 ), with the curve ( 46 ) of the cam carrier ( 44 ), wherein the cam roller ( 45 ) with the at least one variable position spring end ( 27 ) of the at least one spring element ( 30 ) and by a movement of the cam follower ( 44 ) is movable in positions of different spring force. Synchronous mechanism ( 100 ) according to claim 9, wherein the cam roller ( 45 ) one-sided on the curve ( 46 ), to which they by the at least one spring element ( 30 ) is pressed.

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