EP2244605B1 - Mechanism for an office chair - Google Patents

Abstract

A mechanism for an office chair has a displaceable actuating element. The position of the element changes during a movement of the office chair mechanism, and the change in position thereof changes the movement characteristic of the office chair mechanism. The actuating element is operationally connected to a functional element. The position of the functional element changes in the event of a change in the position of the actuating element during a movement of the office chair mechanism. At least one property of the change in position of the actuating element changes in the event of a change in the position of the functional element.

Description

The invention relates to a mechanism for an office chair, with a movable actuator, the position of which changes during a movement of the office chair mechanism and the change in its position, the movement characteristic of the office chair mechanism is changed.

Moreover, the invention relates to a device for use in such office chair mechanism and a method for changing the movement characteristics of an office chair mechanism with a movable actuator, the position of which changes during movement of the office chair mechanism and its change in position, the movement characteristic of the office chair mechanism is changed.

Numerous techniques for changing the movement characteristics of office chair mechanics are known in the art. As a rule, this is a pivoting movement. Depending on the mechanism used, it may be, for example, a combined synchronous or asynchronous seat backrest movement. Other implementable by an office chair mechanics movements, for example, adjusting the seat angle regardless of the backrest tilt or adjusting the backrest tilt regardless of the seat angle.

For example, if the pivoting resistance of the backrest of an office chair to be changed, it is usually with the help of an actuating element, such as a handle or a crank handle, a setting between "hard" and "soft", depending on whether the user of the office chair is a heavy or light person.

A mechanism for an office chair is off DE4235691 A1 known.

A disadvantage of the known from the prior art solutions is that the changing of the movement characteristics of the office chair mechanism, in particular, for example, the pivotal resistance of the backrest, often associated with a relatively large amount of force.

An object of the present invention is therefore to provide a technique by means of which a particularly easy change of the movement characteristics of an office chair mechanism, in particular, for example, the pivotal resistance of the backrest of an office chair, is possible.

This object is achieved by a mechanism according to claim 1 or by a device according to claim 13 or a method according to claim 14.

Thereafter, it is envisaged to design the mechanism such that the actuating element is in operative connection with a functional element whose position changes during a change in position of the actuating element during a movement of the office chair mechanism, wherein changes in a change in position of the functional element at least one property of the change in position of the actuating element

In addition, it is intended to design the method such that when a change in position of the actuating element during a movement of the Office chair mechanism changes the position of a function element operatively connected to the actuating element, wherein changes in a change in position of the functional element at least one property of the change in position of the actuating element.

In other words, a core idea of the invention is to provide the actuating element with a positionally variable functional element whose positional change on the one hand depends on the change in position of the actuating element, and on the other hand has an influence on the change in position of the actuating element. The invention thus provides a self-adjusting, dynamic system for changing the movement characteristics of an office chair mechanism, in particular for changing the pivoting resistance of the backrest of an office chair, which differs from the systems known from the prior art in that the setting of Movement characteristic, in particular, for example, the pivoting resistance, not arbitrarily by the hand of the user, but always automatically and according to the structural specifications of the mechanics takes place. The advantage here is that a particularly easy change of the movement characteristics, in particular, for example, the pivoting resistance, is possible.

The invention can be used in numerous office chair mechanisms, regardless of whether it is a synchronous or asynchronous or another mechanical form.

Advantageous embodiments of the invention are specified in the subclaims.

In particular, the invention is applicable to a spring mechanism having at least one spring element, which is in operative connection with a backrest support of the office chair and determines the pivoting resistance of the backrest support during a pivoting from a starting position into a pivoting position. In this case, the spring mechanism on the actuating element, the position of which changes when pivoting the backrest support and the change in its position, the voltage of the at least one spring element is changed, wherein the actuating element is in operative connection with the functional element, its position in a change in position of the actuating element changed during a pivoting of the backrest support. As a result, a particularly simple change of the pivoting resistance of the backrest of an office chair is possible.

Moreover, it is particularly advantageous if the manner of changing the movement characteristic of the office chair is adjustable by the user. For this purpose, it is provided according to a preferred embodiment of the invention that at least one property of the change in position of the functional element by means of an adjusting device is adjustable.

The adjustable property of the change in position of the functional element is preferably the type and / or the possible extent, ie the extent of the change in position. Thus, for example, the manner of movement of the functional element, such as, among other things, the form of movement, such as rotation or translation, or the shape of the movement curve can be adjusted. The possible extent of the change in position can be determined by setting a lower limit and / or an upper limit and indicates a range of motion in which the functional element can move. It is advantageously not only the extent of the game room, so the width of the area, but also the location of the area adjustable. For the caused by the change in position of the functional element change in position of the actuating element applies accordingly.

The spring mechanism operatively connected to the backrest support of the office chair can be connected to the backrest support both directly or indirectly. In an indirect connection, the spring mechanism is preferably connected via the seat support as a coupling element with the backrest support. The concrete design is dependent on the structure of the office chair and the type of mechanics (synchronous mechanism, asynchronous mechanism).

Due to the change in position of the actuating element, for example, a translational or rotational movement of the actuating element, the voltage of the at least one spring element is changed according to the invention. In the spring mechanism, any types of spring members may be used for the purposes of the present invention. Because of their simplicity and robustness, coil springs in the form of torsion springs, helical compression springs or helical tension springs have proven to be particularly advantageous. If a leg spring is used, the actuating element is preferably designed as an integral part of the leg spring. In particular, a spring leg of the leg spring is used as an actuating element. If, by contrast, a helical compression spring is used, a lever arm acting on the helical spring via a coupling device is preferably used as the actuating element. at Use of a helical tension spring, the actuating element is preferably an integral part of the spring, in particular an end provided hook or a hanger.

As a particularly advantageous, an embodiment of the invention has been found, in which the functional element is a variable-position mounted and directly acted upon by the actuating element rolling or sliding body, preferably in the form of a cylindrical bolt. In such an embodiment, a dynamic automatic positioning of the functional element under the action of the actuating element during pivoting of the backrest support can be realized particularly easily.

The bearing required for the bearing of the functional element is preferably designed as part of the functional element. The bearing is preferably a rolling bearing, in particular in the form of a ball or needle bearing. Of course, however, other actuators and storage devices, such as plain bearings, are used.

The adjustment of the property of the change in position of the functional element takes place with the aid of an adjusting device, which preferably comprises a supporting and / or guideway for the functional element and an adjusting element for changing at least one property of the support and / or guideway. The support and / or guideway, which may be formed for example by the bearing surface of a bearing block, is preferably variable in their inclination. From this variable property of the support and / or guideway depends on the position of the end position, up to the Functional element is movable when pivoting the backrest support.

It is also particularly advantageous if the functional element and / or the adjusting device is designed such that the setting of at least one property of the change in position of the functional element takes place without having to work against the spring force of the at least one spring element. The adjustment takes place in other words "powerless". Depending on the design of the mechanism, it may also be necessary to not perform the spring force adjustment "completely powerless", especially if it can be a particularly simple structural design and at the same time only very small spring forces must be overcome.

With the help of the present invention, a change in the spring force can be achieved with little effort and little effort. A change of the mechanism from a "soft" to a "hard" position is possible, for example, with two or three turns of a handwheel, while not working against the force of the at least one spring element of the spring mechanism or only to a very small extent.

Fig. 1

eine perspektivische Darstellung einer Mechanik gemäß einer ersten Ausführungsform der Erfindung mit einer Schenkelfeder,

Fig. 2

eine Schnittdarstellung der Mechanik aus Fig. 1 mit "weicher" Einstellung des Schwenkwiderstandes in einer Ausgangsposition,

Fig. 3

eine Schnittdarstellung der Mechanik aus Fig. 1 mit "weicher" Einstellung des Schwenkwiderstandes in einer Schwenkposition,

Fig. 4

eine Schnittdarstellung der Mechanik aus Fig. 1 mit "harter" Einstellung des Schwenkwiderstandes in einer Ausgangsposition,

Fig. 5

eine Schnittdarstellung der Mechanik aus Fig. 1 mit "harter" Einstellung des Schwenkwiderstandes in einer Schwenkposition,

Fig. 6

eine perspektivische Darstellung einer Mechanik gemäß einer zweiten Ausführungsform der Erfindung mit einer Schraubendruckfeder,

Fig. 7

eine Schnittdarstellung der Mechanik aus Fig. 6 mit "weicher" Einstellung des Schwenkwiderstandes in einer Ausgangsposition,

Fig. 8

eine Schnittdarstellung der Mechanik aus Fig. 6 mit "weicher" Einstellung des Schwenkwiderstandes in einer Schwenkposition,

Fig. 9

eine Schnittdarstellung der Mechanik aus Fig. 6 mit "harter" Einstellung des Schwenkwiderstandes in einer Ausgangsposition,

Fig. 10

eine Schnittdarstellung der Mechanik aus Fig. 6 mit "harter" Einstellung des Schwenkwiderstandes in einer Schwenkposition,

Fig. 11

eine Schnittdarstellung einer Mechanik gemäß einer dritten Ausführungsform der Erfindung,

Fig. 12

eine Detaildarstellung der Mechanik aus Fig. 11 mit "weicher" Einstellung des Schwenkwiderstandes in einer Ausgangsposition,

Fig. 13

eine Detaildarstellung der Mechanik aus Fig. 11 mit "weicher" Einstellung des Schwenkwiderstandes in einer Schwenkposition,

Fig. 14

eine Detaildarstellung der Mechanik aus Fig. 11 mit "harter" Einstellung des Schwenkwiderstandes in einer Ausgangsposition,

Fig. 15

eine Detaildarstellung der Mechanik aus Fig. 11 mit "harter" Einstellung des Schwenkwiderstandes in einer Schwenkposition,

Fig. 16

eine perspektivische Darstellung von Lagerbolzen und Lagerblock als Teile aller drei dargestellten Ausführungsformen der Erfindung,

Fig. 17

eine Schnittdarstellung einer Mechanik gemäß einer vierten Ausführungsform der Erfindung in einer Ausgangsposition,

Fig. 18

eine Schnittdarstellung der Mechanik aus Fig. 17 mit "weicher" Einstellung des Schwenkwiderstandes in einer Schwenkposition,

Fig. 19

eine Schnittdarstellung der Mechanik aus Fig. 17 mit "harter" Einstellung des Schwenkwiderstandes in einer Schwenkposition.

Embodiments of the invention are explained below with reference to the drawings. Hereby show:

Fig. 1

a perspective view of a mechanism according to a first embodiment of the invention with a leg spring,

Fig. 2

a sectional view of the mechanics Fig. 1 with "soft" adjustment of the pivoting resistance in a starting position,

Fig. 3

a sectional view of the mechanics Fig. 1 with "soft" adjustment of the pivoting resistance in a pivoting position,

Fig. 4

a sectional view of the mechanics Fig. 1 with "hard" setting of the pivoting resistance in a starting position,

Fig. 5

a sectional view of the mechanics Fig. 1 with "hard" adjustment of the pivoting resistance in a pivoting position,

Fig. 6

a perspective view of a mechanism according to a second embodiment of the invention with a helical compression spring,

Fig. 7

a sectional view of the mechanics Fig. 6 with "soft" adjustment of the pivoting resistance in a starting position,

Fig. 8

a sectional view of the mechanics Fig. 6 with "soft" adjustment of the pivoting resistance in a pivoting position,

Fig. 9

a sectional view of the mechanics Fig. 6 with "hard" setting of the pivoting resistance in a starting position,

Fig. 10

a sectional view of the mechanics Fig. 6 with "hard" adjustment of the pivoting resistance in a pivoting position,

Fig. 11

a sectional view of a mechanism according to a third embodiment of the invention,

Fig. 12

a detailed view of the mechanics Fig. 11 with "soft" adjustment of the pivoting resistance in a starting position,

Fig. 13

a detailed view of the mechanics Fig. 11 with "soft" adjustment of the pivoting resistance in a pivoting position,

Fig. 14

a detailed view of the mechanics Fig. 11 with "hard" setting of the pivoting resistance in a starting position,

Fig. 15

a detailed view of the mechanics Fig. 11 with "hard" adjustment of the pivoting resistance in a pivoting position,

Fig. 16

a perspective view of bearing pin and bearing block as parts of all three illustrated embodiments of the invention,

Fig. 17

a sectional view of a mechanism according to a fourth embodiment of the invention in a starting position,

Fig. 18

a sectional view of the mechanics Fig. 17 with "soft" adjustment of the pivoting resistance in a pivoting position,

Fig. 19

a sectional view of the mechanics Fig. 17 with "hard" setting of the swivel resistance in a swivel position.

All figures show the invention only schematically and with its essential components. The same reference numerals correspond to elements of the same or comparable function.

In the FIGS. 1 to 5 a first embodiment of the invention is illustrated. The figures show parts of a pivot mechanism 1 for an office chair, with only the structural elements required for the understanding of the present invention are shown.

The pivoting mechanism 1 comprises a base support 2 with a cone seat 3 for the upper end of a chair column, a seat support 4 and a backrest support. 5

In this case, the front end 6 of the base support 2 is connected to the front end 7 of the substantially horizontally arranged seat support 4 via a rotary joint 8, whereby the main pivot axis 9 of the mechanism 1 is formed, which extends transversely to the chair longitudinal direction 11. The rear end 12 of the seat support 4 is also pivotally connected to the backrest support 5 at bearing points 13. Just as the seat support 4 can be provided with a seat, so the backrest support 5 can be provided with a backrest, wherein neither the type of seat, nor the nature of the Backrest for the invention plays a role. The backrest support 5 is also articulated at its front end 14 to the base support 2.

The backrest support 5, when leaning a user against the backrest of his in the Figures 2 and 4 shown starting position are transferred to a pivot position, as exemplified in the Figures 3 and 5 is shown. To set the restoring force of the backrest support 5, a spring mechanism 15 is provided, whose operation will be explained in detail below.

The spring mechanism 15 comprises two leg springs 16, which are arranged cantilevered between the base support 2 and seat support 4 and are supported with their forwardly directed upper and lower spring legs 17, 18 respectively on the underside 19 of the seat support 4 and on a movably arranged bearing pin 22. In the starting position, the spring legs 17, 18 run almost parallel to one another and to the seat support 4.

In a pivoting of the backrest support 5 in the pivoting direction 23 backwards down the coupled to the backrest support 5 seat support 4 also pivots in the same manner, which together with the seat support 4, the two torsion springs 16 are moved through the at the bottom of the 19th the seat support 4 arranged bearing prisms 24 acted upon and pressed down. As a result, the spring center defined by the position of the spring axis 25 shifts.

In Fig. 2 is the bearing pin 22 in the starting position between the lower spring legs 18 and the bearing surfaces 26 of a bearing block 32. The bearing surfaces 26 are concave. The bearing pin 22 has at its two ends bearings 27 in the form of ball bearings. The position of the rolling bearing 27 corresponds to the position of the bearing surfaces 26 of the bearing block 32. The bearing block 32 preferably has lateral guide flanks (not shown), which serve for the lateral guidance of the bearing pin 22 on the bearing block 32 and thus ensure that the rolling bearings 27 of the bearing pin 22 always rest completely on the bearing surfaces 26. The bearing pin 22 is thus clamped between the straight bottom sides 28 of the lower spring legs 18 on the one hand and the concave bearing surfaces 26 of the bearing block 32 on the other. In this case, formed on the lower spring legs 18 abutment of the leg springs 16 form two first points of attack 29 on the bearing pin 22, while two second points of attack 31 are defined on the bearing pin 22 by its points of contact on the bearing surfaces 26 of the bearing block 32.

Upon pivoting of the backrest support 5, the bearing pin 22 provided with the roller bearings 22 is pushed forward by the moving lower spring legs 18 on the bearing surfaces 26 of the bearing block 32 ("scissor-type"). The bearing pin 22 and thus the points 29 of the bearing pin 22 on the lower sides 28 of the lower spring legs 18 and the points 31 of the bearing pin 22 on the bearing surfaces 26 move forcibly forward. At the same time, the lower spring legs 18 are pressed by the bearing pin 22 upwards. The bearing pin 22 seeks an equilibrium position. In this end position he stops, cf. Fig. 3 , Since the predetermined by the bearing surfaces 26 track of the bearing pin 22 comparatively flat is, the position of the lower spring legs 18 in the pivot position is flat. The shape and inclination of the bearing surfaces 26 is selected so that upon pivoting of the backrest support 5 by a load on the backrest, ie at a tension of the torsion springs 16, the bearing pin 22 is not pushed out of the bearing block 32 forward.

In the initial state, the inclination of the bearing block 32 can now be changed with the aid of an adjusting wedge 34. For this purpose, a Verstellkeil 34 is pushed under the front end 33 of the bearing block 32, which is guided in a recess 35 of the base support 2 slidably. The bearing block 32, which is connected at its rear end 36 at a pivot point 37 to the base support 2, slides on a rising in the direction of the front chair end functional surface 30 of Verstellkeils 34 and is tilted about a pivot axis 38 in the pivoting direction 39 such that the Bearing surfaces 26 describe a relation to the starting position steeper path, cf. Fig. 4 ,

From the front "soft" position of Verstellkeils 34 in the starting position, which has a minimum possible resistance of the torsion springs 16 against pivoting of the backrest support 5 result, see. Fig. 2 , a displacement of the adjusting wedge 34 in a rear "hard" position, in which the torsion springs 16 show the greatest possible resistance to the pivoting of the backrest support 5, see. Fig. 4 ,

When adjusting the bearing block position only 16 must be worked in a comparatively small extent against the spring force of the torsion springs. If the bearing block 32 is mounted centrally, as in another embodiment of Mechanics 1 would be conceivable, so the inclination of the bearing block 32 could be adjusted without the spring force of the torsion springs 16 would have to be worked. In the present example, however, the adjustment follows almost "force-free", By adjusting the bearing surfaces 26 takes place in other words, almost no change in the spring preload. The adjustment is thus also almost independent of whether the person using the office chair is light or heavy.

Due to the resulting steeper path of the bearing surfaces 26, the path of the bearing pin 22 is shortened forward in a pivoting of the backrest support 5. The balance occurs earlier. Opposite the in Fig. 3 shown pivot position, the distance between the first point 29 and the free end 41 of the lower spring leg 18 is greater, see. Fig. 5 , In other words, the bearing pin 22 can no longer dodge the lower spring leg 18 to the same extent as was previously the case, as it prevents the now steeper track from doing so. As a result, the position of the lower spring leg 18 is comparatively steep. The angular movement of the lower spring leg 18 toward the upper spring leg 17 is in other words larger, which has an increased spring force and thus an increased swing resistance result.

The adjusting wedge 34 is moved in the chair longitudinal direction 11 by means of an adjusting device which essentially comprises a threaded rod 42 mounted in the base support 2 with handwheel 43, on which an axially displaceable wedge nut 44 is arranged. Verstellkeil 34 and wedge nut 44 are connected to each other via a positive guide 45, which in the embodiment shown here in the manner of a Dovetail guide is executed. The inclination of the corresponding contact surfaces 46 of adjusting wedge 34 and wedge nut 44 lead to a deflection of the linear movement of the wedge nut 44 in the transverse direction by 90 degrees to a linear movement of the adjusting wedge 34 in chair longitudinal direction eleventh

The manner in which the adjusting wedge 34 is moved may differ from the embodiment shown here. Thus, in particular, other transmission and transmission means can be used. The spindle drive shown with a comparatively coarse thread, however, is particularly advantageous, since it is not only very robust and thus less susceptible to error, but at the same time also very few revolutions of the handwheel 43 are required to achieve a noticeable change in the pivoting resistance.

Upon pivoting of the backrest support 5, starting from a starting position of the bearing pin 22, the distance of the first point of application 29 to the spring axis 25 changes continuously until the bearing pin 22 has reached its end position determined by the inclination of the bearing surfaces 26. In other words, the spring tension of the torsion springs 16 changes with the pivoting and the pivoting of the backrest support 5. So that a heavy person feels an increased ground resistance, the bias of the torsion springs 16 is increased, namely by the pivot point 37 of the bearing block 32 is arranged off-center ,

An actuation of the handwheel 43 thus results in a change of the clearance, within which a movement of the bearing pin 22 is possible. In known from the prior art solutions is instead only one Construction element, which is provided at the location of the bearing pin 22, moved in position and then fixed. When swiveling, however, the position of this construction element does not change. In contrast, moves in the present invention, the bearing pin 22 during and by the movement of the backrest support 5. At the same time, the scope of the movement of the bearing pin 22 and thus the margin of movement of the lower spring legs 18 is adjustable.

In other words, by changing frame parameters, the margin is defined in which the lower spring legs 18 can move to change the tension of the leg springs 16. In a "light" setting the margin of the bearing pin 22 is increased, resulting in a relatively small change in position of the lower spring legs 18 results, while in a "heavy" setting the scope of the bearing pin 22 is reduced. The spring mechanism 15 is allowed at a "heavy" setting to change the position of the lower spring legs 18 stronger.

In the FIGS. 6 to 10 another embodiment of the invention is illustrated in which instead of two leg springs 16, a spring mechanism with two helical compression springs 48 is used.

In Fig. 6 only the spring mechanism and the adjusting mechanism is shown. However, the arrangement of these constructive elements substantially corresponds to that in the FIGS. 1 to 5 shown arrangement. Kinematically, the two embodiments correspond largely.

Part of the spring mechanism is in this case a centrally disposed lever arm 49, which serves as an actuating element in the context of the invention and a suitable connecting element, here in the form of a hexagonal shaft 51, rotatably connected to two retaining legs 52, 53 is connected. The lever arm 49 has in the seat longitudinal direction 11 forward. Its bottom 28 extends in the starting position substantially horizontally. In contrast to the embodiment described above, in which two actuators come in the form of the two lower spring legs 18 used, the actuator is not an integral part of the spring elements, but acts via a coupling device on the springs of the spring mechanism, which is described below.

The one holding leg 52 is connected via a hinge 59 with a spring plate 54 which defines the movable end 55 of the compression spring 48 and on which the compression spring 48 is supported. The opposite fixed end 56 of the compression spring 48 is articulated at the connection point 8 of the base support 2 and seat support 4 and thus coupled to the main pivot axis 9 of the mechanism 1. In the compression spring 48 a trained as a hollow cylinder guide means 61 is used with a guided therein guide rod 58 in parallel, which prevents kink protection that the compression spring 48 kinks when upsetting. The guide device 61 forms a spring plate 57 at the fixed end 56 of the compression spring 48. The guide rod 58 is connected to the spring plate 54 at the movable end 55 of the compression spring 48. However, the compression spring 48 does not necessarily have on the main pivot axis. 9 be attached. Alternatively, the fixed end 56 may also be fixed solely to the base support 2 or the seat support 4.

The other holding leg 53 is - which for reasons of clarity in Fig. 6 is not shown - also connected via a rotary joint with the spring plate of a second compression spring, which is completely identical in type and arrangement with the compression spring 48 and lying symmetrically on the other side of the lever arm 49 is also part of the spring mechanism 15. Of course, it is possible both in this, as well as in the embodiment described above, to use only a single spring element.

The hexagonal shaft 51 of the spring mechanism 15 is rotatably supported at pivot points 60 on the seat support 4. In a pivoting of the also connected to the seat support 4 and hinged to the base support 2 backrest support 5 from a starting position, see. Fig. 6 , in a swivel position, cf. Fig. 7 , in pivoting direction 23 back down this movement is followed by the hexagonal shaft 51. The structural design is chosen such that in this case the attached to the retaining legs 52, 53 rear spring plate 54 due to the coupling on the holding legs 52, 53 in chair longitudinal direction 11 move forward, whereby the two compression springs 48 are tensioned. At the same time the lever arm 49 presses on the bearing pin 22, which moves due to the action of the lever arm 49 from its initial position in the defined by the inclination of the bearing surfaces 26 end position. At the same time resting on the bearing pin 22 lever arm 49 is pressed by the bearing pin 22 upwards ("scissors").

Unlike in the first embodiment, the lateral guide flanks 50 of the bearing block 32 are shown here, which serve for the lateral guidance of the bearing pin 22 on the bearing block 32.

After a change in the inclination of the bearing surfaces 26, cf. Fig. 8 , the result is the same as in the previous embodiment. Due to the steeper track of the bearing pin 22 comes to a standstill earlier, cf. Fig. 9 , The position of the lever arm 49 is then comparatively steep. This is reflected in an increased spring force of the compression spring 48 and thus an increased swing resistance.

In the FIGS. 11 to 15 a third embodiment of the invention is illustrated. The figures show parts of a swivel mechanism 1 for an office chair. The actual backrest is indicated by broken lines. The backrest support 5 is connected via a link 62 to the rear end 12 of the seat support 4. The front backrest support end 14 is pivotally connected to the base support 2, which is connected at its front end 6 to the front seat support end 7 via a pivot joint 8. On the seat support 2, a bearing block 32 is attached verschenkbar, wherein in Fig. 11 the connection of bearing block 32 and seat support 2 is not shown. The pivot axis 38 of the bearing block extends through a pivot point at the rear (upper) end 37 of the bearing block 32. The type of adjustment of the bearing block 32 may vary and is not shown here in detail. Due to the adjustment, however, a pivoting of the front bearing block end 33 forward take place, which leads to a "hard" setting of the mechanism, as described in more detail below.

There is provided a spring mechanism 15 for adjusting the adjusting force of the backrest with at least one spring element in the form of a helical tension spring 63. By way of example, it is assumed in the following that only a single helical tension spring 63 is used. But it can also be used two or more springs. The helical tension spring 63 is mounted with its rear end of the spring 64, which is formed as Einhängöse or open hook, centrally on a running between the two arms of the backrest support 5 transverse pin 65 which can be regarded as part of the backrest support 5. Thus, the spring 63 is connected directly to the backrest support 5 without an additional coupling element. The front spring end 66, which is also designed as Einhängöse or open hook, is connected to a bearing pin 22. The front end of the spring 66 serves as an actuator in the context of the invention. The bearing pin has - as in the embodiments described above - at its two ends bearings 27 in the form of ball bearings and rests with these on the bearing surfaces 26 of the bearing block 32, see. Fig. 16 ,

In the in Fig. 12 illustrated initial position, which is characterized by a substantially horizontal position of the coil spring 63, is the bolt 22 on the bearing surface 26 in the region of the rear (upper) Lagerblockendes 37. When pivoting the backrest support 5 back down in the pivoting direction 23 changes the Position of the front spring end 66. This change in position is associated with an expansion of the spring 66 and thus a change in the pivoting resistance, cf. FIG. 13 , At the same time, the pin 22 is carried along by the spring end 66, so that it moves on the bearing surface 26 to the front (bottom) in the direction of the front (lower) Lagerblockendes 33.

In the in the FIGS. 12 and 13 shown position of the bearing block 32, the defined by the concave bearing surface 26 rolling curve from the vertical starting comparatively flat. The bolt 22 can swerve comparatively strongly when pivoting the spring 63, with the result that the spring 63 is stretched only comparatively little. In this "soft" setting, it is therefore comparatively easy for the user to pivot the backrest of the office chair to the rear. The swivel resistance is low.

Now, the position of the bearing block 32 is changed such that the defined by the bearing surface 26 rolling curve is relatively steep with respect to the vertical, see. FIGS. 14 and 15 Thus, the pivoting of the backrest support 5 causes a comparatively weak (short) deflection of the bolt 22, with the result that the spring 63 is stretched more than before. In this "hard" setting, it is therefore harder for the user to pivot the backrest of the office chair to the rear. The swing resistance is high. The pivot angle of the backrest support 5 is here, as in the embodiments described above, always the same, regardless of the position of the bearing block 32. The mechanism is constructed so that the actuator always moves the same.

In Fig. 16 the device provided for use in the office chair mechanism 1 is shown in detail. It comprises the positionally variable functional element 22 in the form of a rolling and / or sliding body with two bearings 27 for rotational support of the functional element 22 and a bearing and / or guide track for the bearings 27, formed by two concave bearing surfaces 26 of the bearing block 32nd

In the 17 to 19 a fourth embodiment of the invention is illustrated. The figures show parts of a swivel mechanism 1 for an office chair. The backrest support 5 is connected via a common link 67 both with the rear end 12 of the seat support 4, and with the rear end 68 of the base support 2 pivotally connected. The base support 2 is pivotally connected at its front end 6 to the front seat support end 7 via a second link 69.

On a construction element 70 of the seat support 2, a bearing block 32 is verschenkbar attached. The pivot axis 38 of the bearing block 32 passes through a pivot point at the front (upper) end 33 of the bearing block 32. The inclination of the straight bearing surface 26 of the bearing block 32 in this case can be varied by means of an adjusting element (not shown). As a result, a pivoting of the rear bearing block end 37 upwards in the direction of the seat support 4, which leads to a "hard" setting of the mechanism, as described in more detail below. The bearing surface 26 may instead of just but also be concave or convex as in the embodiments described above.

It is a spring mechanism 15 for adjusting the adjusting force of the backrest with at least one Spring element provided in the form of a coil spring 63. By way of example, it is assumed in the following that only a single helical tension spring 63 is used. But it can also be used two or more parallel springs. The helical tension spring 63 is mounted with its front end of the spring 66, which is designed as Einhängöse or open hook on a running between structural elements 71 of the base support 2 transverse pin 65. The rear spring end 64, which is also designed as Einhängöse or open hook, is connected to a bearing pin 22. The rear spring end 64 serves as an actuating element in the context of the invention. The bearing pin 22 has - as in the embodiments described above - at its two ends bearings 27 in the form of ball bearings and rests with these on the bearing surface 26 of the bearing block 32.

The bearing pin 22 is pivotally connected to a coupling element 72. For this purpose, the bearing pin 22 is mounted in the one end of the coupling element 72. The opposite end of the coupling element 72 is pivotally connected to the seat support 4 at a pivot point 73. In a pivoting of the backrest support 5 in the pivoting direction 23 backwards down the coupled to the backrest support 5 seat support 4 also pivots in the same manner. This results in a movement of the articulation point 73 of the coupling element 72 on the seat support 4, which also changes the position of the bearing pin 22 and thus the position of the coil spring 63 via the coupling element 72. The seat support 4 thus serves together with the coupling element 72 for the indirect coupling of the spring mechanism 15 to the backrest support fifth

The inclination of the bearing surface 26 is set in the starting position, ie when the backrest is not pivoted. In the best possible "soft" setting, the rear end 37 of the bearing block 32 bears against the base support 2. The angle of the bearing surface 26 to the horizontal is about 60 °, cf. Fig. 18 , In the "hardest" setting, the bearing surface 26 is almost horizontal. The angle of the straight bearing surface 26 to the horizontal in this case is about 10 °, cf. Fig. 19 , Since the bearing pin 22 is in the starting position near the rotation and bearing point 38 of the bearing block 26, see. Fig. 17 , the adjustment of the inclination and thus the adjustment of the spring force setting is almost powerless. The spring 63 is biased only minimally.

At the in Fig. 17 When pivoting the backrest support 5 back down in the pivoting direction 23, the position of the rear end of the spring 64 changes. This change in position is with an extension of the spring 63 and thus a change in the Pivoting resistance connected. At the same time, the pin 22 is taken along by the coupling element 72, so that it moves on the bearing surface 26 to the rear in the direction of the rear bearing block end 37.

At the in Fig. 18 shown pivot position is defined by the bearing surface 26 rolling curve of the vertical starting comparatively flat. When the spring 63 is pivoted, the bolt 22 can deflect comparatively strongly downwards, with the result that the spring 63 is stretched only comparatively little. In this "soft" setting, it is for the user comparatively easy to pivot the back of the office chair to the rear. The swivel resistance is low.

Now, the position of the bearing block 32 is changed such that the defined by the bearing surface 26 rolling curve is relatively steep with respect to the vertical, see. Fig. 19 Thus, the pivoting of the backrest support 5 causes a stronger displacement of the bolt 22 towards the backrest support 5 and thus a greater elongation of the spring 63. In this "hard" setting, it is therefore harder for the user to pivot the backrest of the office chair to the rear. The swing resistance is high. The pivot angle of the backrest support 5 is here, as in the embodiments described above, always the same, regardless of the position of the bearing block 32nd

The design of the construction elements 70, 71 and the arrangement of the pivot points 38, 65 are also variable in the embodiment described above for setting the desired pivoting characteristic, as the shape of the cam track 26 for the bearing pin 22 and the length and arrangement of the coupling element 72nd

Individual aspects of the present invention will be explained again in detail below.

First, it is assumed that the bolt 22 would not be provided with bearings 27, but would rest directly on a track. If the path on which the bolt 22 moves, then no curved path, but a straight line and would be an on this bolt 22 rolling actuator always move parallel to the web, then no evasive forces would act on the pin 22. However, it does the actuator in an office chair mechanics always an angular movement. Therefore, a curved path is provided, which prevents an undesired pushing away of the bolt 22 from the web by their defined pitch.

If now the actuating element rest on such an unsupported pin 22, it would initially always perform a rolling motion at an angular movement of the actuating element. In case of an excessive increase of the cam track 26, however, the bolt 22 would be prevented from rolling. The rolling motion of the pin 22 would slip, which would result in undesirable wear on pin 22 and track. Therefore, it is provided to provide the bolt 22 with bearings 27 in which the bolt 22 is freely rotatable and thus receives an additional rotational degree of freedom. A transition to sliding friction in the above-described case is thereby effectively prevented.

The movement of the functional element under the action of the actuating element will be described again below with reference to the in the Fig. 2 and 3 described example. Presses the actuator in the form of the lower spring leg 18 of the leg spring 16 at a pivoting of the backrest support 5 at the support point 29 on the functional element in the form of the bolt 22, this is accompanied by a change in angle of the spring leg 18. By this change in position of the spring leg 18, there is an imbalance of forces, by which the position of the bolt 22 is changed on the web. The bolt 22 deviates from the obliquely fitting spring leg 18 until, by the curve geometry of the web again an equilibrium of forces arises. The bolt 22 arrives at the latest then, when the spring leg 18 is parallel to the respective tangent through the contact point 31 of the bolt 22 to the web (bearing surface 26). The steeper the track, the sooner this equilibrium of forces is achieved and the less the pin 22 deviates. The lower the escape path of the bolt 22, the steeper turns - with the same pivoting of the backrest support 5 - the spring leg 18. This has the consequence that the spring 16 is a more taut. In other words, by a change in position, in particular a pivoting, of the bearing block 32 and thus a change in the curved path, the spring force behavior of the mechanism 1 or another feature of the movement characteristic can be adjusted.

The bearing block 32 can, however, in principle - depending on the application - be permanently installed, i. not swiveling or tilting. In such a case, however, the adjustability of the at least one property of the change in position of the bolt 22 would no longer exist. However, even in this case, the wear of the mechanism 1 due to the spring-biased without sliding friction spring mechanism 15 would be reduced.

The position of the bearing of the bearing block 32, so the position of the pivot axis 38 may vary. The more distant the bearing point from the axis of the bolt 22, the more bias can be achieved when adjusting the spring mechanism 15. The closer the pivot axis 38 moves to the position of the bolt 22, the less bias voltage can be generated by the spring mechanism 15.

The web may in the simplest case have the shape of a circular arc section. Variations (initially flat, later steeper etc.) are possible and have a different dynamic spring behavior. Depending on the customer's requirements, the mechanics can show degressive, linear or progressive behavior. In other words, not only by adjusting the inclination of the bearing block 32 is it possible to change the movement characteristic of the mechanism. Also by the change of the concavity of the bearing surface 26, so the shape of the curved path, this is possible. The curved path can also be a straight line, cf. that in the 17 to 19 illustrated embodiment.

All in the description, the following claims and the drawings illustrated features may be essential to the invention both individually and in any combination.

LIST OF REFERENCE NUMBERS

1

swivel mechanism

2

base support

3

cone holder

4

seat support

5

Backrest support

6

front end base

7

front seat carrier end

8th

swivel

9

Main pivot axis

10

(free)

11

Chair longitudinally

12

Rear seat carrier end

13

bearing point

14

front backrest end

15

spring mechanism

16

Leg spring

17

upper spring leg

18

lower spring leg

19

bottom

20

(free)

21

(free)

22

bearing bolt

23

pan direction

24

bearing prism

25

spring axis

26

storage area

27

roller bearing

28

Spring leg base

29

First attack point

30

functional surface

31

second point of attack

32

bearing block

33

front end of warehouse block

34

adjusting wedge

35

recess

36

pivot point

37

rear end of storage block

38

swivel axis

39

pan direction

40

(free)

41

free end

42

threaded rod

43

handwheel

44

spline nut

45

dovetail guide

46

contact area

47

(free)

48

compression spring

49

lever arm

50

guide flanks

51

Hexagonal shaft

52

holding leg

53

holding leg

54

spring plate

55

movable spring end

56

solid spring end

57

spring plate

58

guide rod

59

Swivel of the holding leg

60

Fulcrum of the hexagonal shaft

61

guide means

62

handlebars

63

mainspring

64

rear end of spring

65

cross bolt

66

front end of spring

67

handlebars

68

rear base station end

69

handlebars

70

design element

71

design element

72

coupling element

73

pivot point

Claims (15)

1. Mechanism (1) for an office chair, having a displaceable actuating element (18, 49, 66, 64), the position whereof changes during a movement of the office chair mechanism (1), and the change in position thereof changing the movement characteristic of the office chair mechanism (1), the actuating element (18, 49, 66, 64) being operationally connected to a functional element (22), the position thereof changing in the event of a change in the position of the actuating element (18, 49, 66, 64) during a movement of the office chair mechanism (1), wherein at least one property of the change in position of the actuating element (18, 49, 66, 64) changes in the event of a change in the position of the functional element (22), the at least one property of the change in position of the functional element (22) being adjustable with the help of an adjustment device (26, 32, 34, 44, 43), wherein the adjustment device comprises a supporting track and/or a guide track (26) for the functional element (22) as well as an adjustment element (34, 44, 43) for changing at least one property of the supporting track and/or the guide track (26), and wherein the changeable property of the supporting track and/or the guide track (26) is its inclination.
2. Mechanism (1) according to Claim 1, characterized in that it comprises a spring mechanism (15) exhibiting at least one spring element (16, 48, 63), which mechanism is operationally connected to a backrest support (5) of the office chair and determines the resistance to pivoting of the backrest support (5) in the event of its pivoting from an initial position into a pivoted position, the spring mechanism (15) exhibiting the actuating element (18, 49, 66, 64), the position thereof changing in the event of the pivoting of the backrest support (5), and the change in the position thereof changing the tension of the at least one spring element (16, 48, 63), the actuating element (18, 49, 66, 64) being operationally connected to the functional element (22), the position thereof changing in the event of a change in the position of the actuating element (18, 49, 66, 64) during pivoting of the backrest support (5).
3. Mechanism (1) according to Claim1 1 or 2, characterized in that a property of the change in position of the actuating element (18, 49, 66, 64) or the functional element (22) is the nature of the change in position.
4. Mechanism (1) according to one of Claims 1 to 3, characterized in that a property of the change in position of the actuating element (18, 49, 66, 64) or the functional element (22) is the possible extent of the change in position.
5. Mechanism (1) according to one of Claims 2 to 4, characterized in that the spring mechanism (15) is connected to the backrest support (5) via the seat support (4) as a coupling element.
6. Mechanism (1) according to one of Claims 2 to 4, characterized in that the spring mechanism (15) is directly connected to the backrest support (5).
7. Mechanism (1) according to one of Claims 2 to 6, characterized in that the at least one spring element is a helical spring in the form of a leg spring (16), and in that the actuating element is an integral component part of the leg spring (16), in particular a spring leg (18).
8. Mechanism (1) according to one of Claims 2 to 6, characterized in that the at least one spring element is a helical spring in the form of a helical compression spring (48), and in that the actuating element is a lever arm (49) acting on the helical spring (48) via a coupling device (51, 52, 53).
9. Mechanism (1) according to one of Claims 2 to 8, characterized in that the at least one spring element is a helical spring in the form of a helical tension spring (63), and in that the actuating element (66, 64) is an integral component part of the helical tension spring (63), in particular a hook provided on the end or an eye.
10. Mechanism (1) according to one of Claims 1 to 9, characterized in that the functional element (22) is a rolling element or a sliding element mounted in a position-adjustable fashion and acted upon directly by the actuating element (18, 49, 66, 64), preferably in the form of a cylindrical pin.
11. Mechanism (1) according to one of Claims 1 to 10, characterized in that the functional element (22), in the event of pivoting of the backrest support (5), is capable of being displaced as far as an end position, which depends on the changeable property of the supporting track and/or the guide track (26, 27).
12. Mechanism (1) according to one of Claims 2 to 11, characterized in that the functional element (22) and/or the adjustment device (26, 32, 34, 44, 43) is/are configured in such a way that the setting of the at least one property of the change in position of the functional element (22) takes place without having to work against the spring force of the at least one spring element (16, 48, 63) for this purpose.
13. Device for use in the mechanism (1) of an office chair having a position-adjustable functional element (22) in the form of a rolling element or a sliding element, having at least one bearing (27) for the rotational bearing of the functional element (22) and having a supporting track and/or a guide track for the bearing (27), formed by at least one bearing surface (26) of a bearing block (32), the inclination of said bearing surface (26) being adjustable by means of an adjustment element (34, 44, 43), the functional element (22) being capable of connection to a displaceable actuating element (18, 49, 66, 64), the position thereof changing during movement of the office chair mechanism (1), and the change in position thereof changing the movement characteristic of the office chair mechanism (1), and the change in position thereof changing the movement characteristic of the office chair mechanism (1), the position of the functional element (22) changing in the event of a change in position of the actuating element (18, 49, 66, 64) during a movement of the office chair mechanism (1), wherein at least one property of the change in position of the actuating element (18, 49, 66, 64) changes in the event of a change in the position of the functional element (22).
14. Method for changing the movement characteristic of the mechanism (1) of an office chair having a displaceable actuating element (18, 49, 66, 64), the position thereof changing during movement of the office chair mechanism (1), and the change in position thereof changing the movement characteristic of the office chair mechanism (1), wherein the actuating element (18, 49, 66, 64) is operationally connected to a functional element (22), the position thereof changing in the event of a change in the position of the actuating element (18, 49, 66, 64) during a movement of the office chair mechanism (1), wherein at least one property of the change in position of the actuating element (18, 49, 66, 64) changes in the event of a change in the position of the functional element (22), wherein the at least one property of the change in position of the functional element (22) is adjustable with the help of an adjustment device (26, 32, 34, 44, 43), wherein the adjustment device comprises a supporting track and/or a guide track (26) for the functional element (22) as well as an adjustment element (34, 44, 43) for changing at least one property of the supporting track and/or the guide track (26), and wherein the changeable property of the supporting track and/or the guide track (26) is its inclination.
15. Method according to Claim 14, characterized in that the mechanism (1) serves to change the tension of at least one spring element (16, 48, 63) of a spring mechanism (15) that is operationally connected to a backrest support (5) and determines the resistance to pivoting of the backrest support (5) in the event of its pivoting from an initial position into a pivoted position, the spring mechanism (15) exhibiting the actuating element (18, 49, 66, 64), the position thereof changing in the event of the pivoting of the backrest support (5), whereby the change in the position thereof changes the tension of the at least one spring element (16, 48, 63), the position of the functional element (22) that is operationally connected to the actuating element (18, 49, 66, 64) changing in the event of a change in the position of the actuating element (18, 49, 66, 64) during pivoting of the backrest support (5).

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