CN112384106A

CN112384106A - Chair (Ref. TM. chair)

Info

Publication number: CN112384106A
Application number: CN201980044670.4A
Authority: CN
Inventors: T·米歇尔森
Original assignee: Konich And Neulat Ag
Current assignee: Konich And Neulat Ag
Priority date: 2018-07-02
Filing date: 2019-06-28
Publication date: 2021-02-19
Anticipated expiration: 2039-06-28
Also published as: EP3817628A1; CN112384106B; DE102018115925A1; EP3817628B1; PL3817628T3; WO2020007411A1; EP3817628C0

Abstract

The invention relates to a chair comprising a chair base body (1) on which a seat and a backrest connected to the seat by means of a synchronization mechanism are mounted so as to be movable, wherein a spring (4) is provided which presses the seat into an initial position of the chair, and a support (5) is mounted so as to be rotatable on the chair base body (1), wherein the support (5) is designed to interact on the one hand with a connecting element (7) connected to the front edge of the seat and on the other hand with the end of the spring (4). According to the invention, the connecting element (7) interacting with the bearing (5) is designed to be guided in a longitudinal guide (8) and is arranged in the uppermost position of the longitudinal guide (8) in the initial position of the seat.

Description

Chair (Ref. TM. chair)

Technical Field

The present invention relates to a chair according to the preamble of claim 1.

Background

A chair of the type mentioned at the outset is known from DE 102007059985B 3. The chair comprises a chair base body on which a seat and a backrest connected to the seat by means of a synchronization mechanism are movably supported, wherein a spring is provided which presses the seat into an initial position of the chair, and a support which is rotatably supported on the chair base body, wherein the support is designed to interact on the one hand with a connecting element connected to a front edge of the seat and on the other hand with an end of the spring. The spring is also designed to be able to be positioned in different positions on the support to adjust the acting spring force. In this solution, the front edge of the seat and the support are also arranged on a front seat guide, which is itself mounted on the chair base in a pivotable manner.

Disclosure of Invention

The object of the invention is to improve a chair of the type mentioned at the outset. In particular, a chair should be provided in which, unlike the prior art described above, the front edge of the chair is not raised when the backrest is loaded.

This object is achieved by a chair of the type mentioned at the outset with the features specified in the characterizing part of claim 1.

According to the invention, it is thus provided that the connecting element interacting with the abutment is designed to be guided in a longitudinal guide and, in the initial position of the seat, is arranged in the uppermost position of the longitudinal guide.

In other words, the solution according to the invention is thus characterized in that the adjustability of the spring force, which is achieved by the longitudinal guide and at the same time by the rotatably mounted support, does not lift the seat front edge under load of the chair. It is also specified here that the longitudinal guide optionally extends completely horizontally in the upright position of the chair (the connecting element then being located in the uppermost position of the longitudinal guide in each position) or that the longitudinal guide in the initial position is configured so as to be inclined gently downwards from the uppermost position with respect to the horizontal, so that the seat front edge is maximally lowered under load of the chair, but is never raised.

In addition, it is particularly preferably provided that, as is also explained in more detail below, the bearing has a toothing on the longitudinal guide side and, between the longitudinal guide and the toothing for transmitting force between the spring and the seat, an intermediate connecting element, also referred to as a force transmission element, is arranged which is likewise engaged on the toothing side and is mounted so as to be pivotable relative to the longitudinal guide.

Further advantageous developments emerge from the dependent claims.

Drawings

The following drawings, which are based on preferred embodiments, illustrate in detail a chair according to the invention, comprising advantageous further solutions according to the dependent claims.

In the drawings:

fig. 1 shows a section perspective view of a synchronization mechanism with a "soft" actively controlled spring in an unloaded position;

fig. 2 shows a section perspective view of the synchronization mechanism according to fig. 1 with a "soft" spring adjusted in the loaded position;

fig. 3 shows a perspective view of the synchronization mechanism according to fig. 1 with a "hard" spring adjusted in the unloaded position;

fig. 4 shows a section perspective view of the synchronization mechanism according to fig. 1 with a "hard" spring adjusted in the loaded position;

fig. 5 shows a chair according to the invention, in which the synchronizing mechanism shown in fig. 1 to 4 is located below the seat or seat surface;

fig. 6 shows a section perspective view of the synchronization mechanism according to fig. 3 in the unloaded position with a spring adjusted in a "hard" manner;

fig. 7 shows a part of the synchronization mechanism according to fig. 1 in a side view with a "soft" actively adjusting spring in the unloaded position;

fig. 8 shows a part of the synchronization mechanism according to fig. 1 with a "soft" actively adjusting spring in the loaded position in a side view;

fig. 9 shows the support according to fig. 1, in particular with an adjusting element (schematic) and an adjusting wheel, as a perspective exploded view;

fig. 10 shows a perspective view of a part of the synchronization mechanism according to fig. 1, in particular the carrier, with a spring that is adjusted in a "soft" manner in an unloaded position (in which the spring force can be adjusted);

fig. 11 shows a part of the synchronization mechanism according to fig. 1, in particular an adjusting lever with a pin and a rotary shaft with a curved guide, in a position of the load, in a perspective and sectional view;

fig. 12 shows a part of the synchronization mechanism according to fig. 1, in particular an adjusting lever with a pin and a rotary shaft with a curved guide, in a perspective and sectional view in an unloaded position;

fig. 13 shows, in perspective and in cross section, a part of the synchronization mechanism, in particular the locking mechanism, according to fig. 1 when the chair is unloaded and thus in the open position; and

fig. 14 shows a part of the synchronization mechanism according to fig. 2, in particular the locking mechanism, in perspective and in a sectional view, when the chair is loaded and thus in the locked position.

Detailed Description

The chair shown in fig. 1 to 14 comprises a chair base 1, which is initially mounted in a known manner, preferably with legs 20, on which a seat 2 and a backrest 3 connected to the seat 2 via a synchronizing mechanism are mounted so as to be movable, wherein a spring 4 is provided which presses the seat 2 into the initial position of the chair, and a support 5 is mounted so as to be pivotable on the chair base 1, wherein the support 5 is designed to interact on the one hand with a connecting element 7 connected to the front edge of the seat 2 and on the other hand with the ends of the spring 4.

As can be seen from the figures, two seat carriers 10 connected to one another by a connecting element 7 are particularly preferably provided, wherein the chair base body 1 is arranged between the two seat carriers 10 and the connecting element 7 is mounted on the chair base body 1 in a displaceable manner.

Furthermore, it is preferably provided that a backrest carrier 9 which can be pivoted about a horizontal axis is supported on the chair base body 1.

The backrest carrier 9 and the two seat carriers 10 are preferably connected to one another here by two swivel joints 11 with a horizontal axis, which are movable independently of the chair base 1.

Furthermore, it is preferably provided that the connecting element 7, which is operatively connected to the seat 2 via the seat carrier 10, is designed to be operatively connected to the support 5 for the spring 4.

It is important for the chair in this case that the connecting element 7 interacting with the support 5 is configured to be guided in the longitudinal guide 8 and, in the initial position of the seat, is arranged in the uppermost position of the longitudinal guide 8. As already mentioned above, this condition makes it possible to provide a chair in which the front edge is not actually lowered even under load.

More specifically, it is seen that it is particularly preferably provided that the longitudinal guides 8 for the connecting elements 7 are designed to be inclined downward when the chair is in use, as viewed from the front edge of the seat 2 in the direction of the backrest 3.

As can be seen from the figures, it is furthermore provided that the support 5 has a bearing surface 5.1 on which the ends of the spring 4 can be positioned in different positions in order to adjust the acting spring force. In this case, it is furthermore particularly preferably provided that an adjusting element 6 which transmits only tensile forces is provided for fixing the position of the end of the spring 4 on the bearing surface 5.1.

More specifically, it is particularly preferably provided that the adjusting element 6 is optionally designed as a chain (see fig. 1 to 14) or as a cable (not otherwise shown).

For guiding the adjusting element 6, a groove 16 is particularly preferably provided in the support 5 (see fig. 9 in particular for this purpose). The groove is formed to be wider than the adjusting element 6, so that it is supported in the groove 16 so as to be laterally displaceable.

Furthermore, it is particularly preferred to provide an adjusting wheel 17 for adjusting the adjusting element 6 on the support 5, said adjusting wheel having a rotation axis which extends horizontally when the chair is in use. In this case, it is also particularly preferably provided that the adjusting wheel 17 is arranged on a rotary shaft 22 which is rotatably mounted on the support 5, if necessary.

In addition, it is particularly preferably provided for the longitudinal guide 8 to be formed so as to be inclined downward at an angle of approximately 10 ° relative to the horizontal in the upright position of the chair, starting from the front edge of the seat 2, toward the backrest 3. Furthermore, it is preferably provided that the longitudinal guide 8 is of semicircular design at its two ends which are adapted to the cylindrical rod-shaped connecting element 7.

With regard to the spring 4 mentioned at the beginning, it is particularly preferably optionally embodied as a compression spring and/or a telescopic guide 14 is arranged in the interior of said spring, it being furthermore particularly preferably provided that one end of the spring 4 is embodied as a connection to the bearing 5 and the other end of the spring 4 is connected to a rotary bearing 12 provided on the chair base 1. More specifically, it is seen that the spring 4 is here configured to be rotatably supported about a horizontal axis about a rotary support 12.

As can also be seen from the figures, it is particularly preferred for a predetermined prestress to arrange a second spring 18, preferably likewise embodied as a compression spring, between the connecting element 7 and the chair base 1, in the interior of which a telescopic guide 19 is preferably likewise arranged. It is thereby advantageously achieved in the end that the adjustable spring 4 and thus also the support 5 are dimensioned to be smaller. However, this results in particular in a basic stress which, despite the seat load, keeps the chair in the front position, so that the spring force can be varied, specifically without locking the adjustment (see locking wheel and locking element).

As can also be seen from the figures, it is particularly preferably provided that the longitudinal axes of the spring 4 and of the second spring 18 (along which compensation of the spring is effected) lie in planes which are parallel to one another.

It is more particularly seen that the swivel bearing 15 is particularly preferably arranged on the chair base 1 for the purpose of fixing the aforementioned support 5 (see in particular fig. 10 for this purpose). Furthermore, the swivel bearing 15 is arranged at the end of the support 5 facing away from the seat, which swivel bearing preferably has a horizontal axis of rotation in the upright position of the chair.

It is furthermore preferably provided that the rotary bearing 15 is configured to be arranged on one end of the support 5 and the connecting element 7 is configured to be fitted on the other end of the support 5.

Furthermore, it is particularly preferably provided that the aforementioned bearing surface 5.1 of the support 5, which is preferably divided into two elongated partial surfaces by the aforementioned groove 16, is concavely curved in the direction of the spring 4. Furthermore, it is preferably provided that the spring 4 is designed to rest on the bearing surface 5.1 at its end on the bearing side by means of a slide 13 that can be moved relative to the bearing surface 5.1. For this purpose, it is also particularly preferably provided that the slide 13, which is preferably designed in a fixed connection with the adjusting element 6, is designed to be convexly curved on the support side in a manner adapted to the bearing surface 5.1.

It follows from the drawing that the rotation of the support 5 about its rotary bearing 15 causes the compression of the spring 4. It is furthermore particularly preferably provided that, in a predetermined movement of the connecting element 7, the position of the spring 4 close to the rotary bearing 15 of the bearing 5 results in a smaller compression of the spring 4 than the position of the spring 4 remote from the rotary bearing 15.

In addition, it is particularly preferably provided that the bearing surface 5.1, viewed in both adjustment directions of the spring 4, is provided with a stop for the spring 4 or the carriage 13, respectively.

In order to transmit the force from the seat 2 and acting on the spring 4, a force transmission device 21 is furthermore arranged between the connecting element 7 and the support 5. As is apparent in particular from fig. 7 and 8 and the following description, the force transmission device serves to transmit forces from the connecting element 7 to the bearing 5, always parallel to the longitudinal guide 8 and thus practically without losses, by means of the further-described toothing of the force transmission device 21.

More specifically, it is provided that the carrier 5 has a first toothing 5.2 with preferably at least three teeth on the force transmission device side, the force transmission device 21 has a second toothing 21.1 with preferably at least four teeth on the carrier side, and the two toothings 5.2, 21.1 are each formed to be convexly curved toward one another and at least partially mesh with one another.

Furthermore, it is particularly preferably provided that the support 5 is embodied in an arcuate, in particular circular-arc-shaped manner and that the toothing 5.2 on the force transmission device side is arranged on the convex outer side and the bearing surface 5.1 for the spring 4 is arranged on the concave inner side of the support 5.

As can also be seen from the figures, it is furthermore preferably provided that the force transmission device 21 is mounted on the connecting element 7 so as to be rotatable about an axis which is oriented horizontally in the upright position of the chair. It is also more particularly seen that it is particularly preferably provided here that the force transmission means 21 has a cylindrical, in particular so-called rod through-hole, which surrounds the connecting element 7.

Furthermore, it is preferably provided that the force transmission means 21 is formed by two parts each having a second tooth 21.1, between which a free space 6 for the adjusting element is present.

As is shown with reference to the figures, it is furthermore particularly preferably provided that the movement of the connecting element 7 is designed to cause a movement and a rotation of the force transmission device 21. Furthermore, it is provided that the displacement and rotation of the force transmission means 21 are designed to cause the rotation of the carrier 5 about its rotary bearing 15.

Furthermore, it is particularly preferably provided that the adjusting element 6, which is preferably closed on itself, is designed to be guided around the bearing 5 or that it is also preferably designed to surround an adjusting wheel 17, which will be described below.

As can be seen from the figures, the adjusting wheel 17 is particularly preferably designed as a sprocket wheel (see also https:// de. wikipedia. org/w/index. pt. tile. Kettenrad & oldid. 177726929 for this purpose). Alternatively (not shown in addition), it is provided that the adjusting element 6 is designed as a cable, in particular a wire cable, and that the adjusting wheel 17 has a guide groove which cooperates with the cable and makes it impossible for the cable to slip (furthermore, for example, a cylinder or the like can be arranged on the cable, said cylinder preventing slipping on the adjusting wheel 17). In both solutions, it is preferably provided that the adjusting wheel 17 has an axis of rotation which extends parallel to the rotary bearing 15 of the carrier 5.

For actuating the adjusting wheel 17, an adjusting mechanism is furthermore particularly preferably provided, to which in particular the above-mentioned rotary shaft 22 belongs.

It is furthermore preferably provided for the rotational axis to be mounted on a support 5 so as to be movable between two axial positions.

Furthermore, a spring element 23 is particularly preferably provided here for moving the rotational shaft 22 into the first axial position. Furthermore, it is particularly preferred to provide a first locking element 22.1 on the rotational shaft 22, which is designed to interact in a first axial position with a second locking element 5.3 provided on the bearing 5. In this case, the two locking elements 22.1, 5.3 are particularly preferably each designed as crown gear teeth (see also https:// de. wikipedia. org/w/index. ptile. picttile. kronerad & oldid. 174349785 for this purpose). As can be seen in particular from fig. 9 and 10, it is particularly preferably provided that the crown gear toothing is designed as a sawtooth toothing, to be precise that any movement of the carriage 13 on the bearing surface 5.1 in the direction of the pivot bearing 15 is reliably prevented.

Furthermore, an adjusting lever 24 is preferably provided, which is operatively connected to the rotational shaft 22. Furthermore, an adjusting mechanism is preferably provided for the axial displacement of the rotary shaft 22 into the second axial position. The adjusting mechanism is preferably formed here by a pin 24.1 arranged on the adjusting lever 24 and a cam guide 22.2 arranged on the rotary shaft 22 and interacting with the pin 24.1. Further, the rotation shaft 22 preferably has a through hole through which a portion of the adjustment lever 24 passes. Furthermore, the adjusting lever 24 is preferably mounted on the bearing 5 in a rotatable, but axially immovable manner.

As can be seen from the drawing, a rotational movement of the adjusting lever 24 is thereby achieved, the bolt 24.1 moving along the wall of the curved guide 22.2. This in turn leads to the described axial displacement of the rotary shaft 22 and thus to the two locking elements 22.1, 5.3 being released from one another, which in turn leads to the adjustment wheel 17 being able to be rotated and thus to the adjustment of the slide 13.

Since the displacement of the carriage 13 on the support 5 becomes increasingly difficult with increasing compression of the spring 4, it is furthermore particularly preferred to provide a locking mechanism which prevents the rotation of the rotation shaft 22 under load of the chair. The locking mechanism is particularly preferably formed here by a locking wheel 26 connected in a rotationally fixed, but preferably axially displaceable manner to the rotary shaft 22 and a locking element 27 which is mounted in a displaceable manner on the support 5, is spring-loaded and interacts with the locking wheel 26 (if the locking element 27 is of sufficiently wide design as in the exemplary embodiment shown, it can be dispensed with here that the locking wheel 26 is designed to be mounted in an axially displaceable manner on the rotary shaft 22). It is also preferably provided here that the locking element 27 is configured to interact with the chair base 1 when the chair is unloaded and the locking wheel 26 is released and the locking wheel 26 is locked when the chair is loaded. As can be seen in particular from fig. 13 and 14, it is particularly preferably provided that the locking wheel 26 has a toothed toothing, which in turn reliably prevents any movement of the carriage 13 on the bearing surface 5.1 in the direction of the pivot bearing 15.

Since the adjusting wheel 17 is preferably designed to be fixedly connected to the rotational shaft 22, it is furthermore preferably provided that the adjusting element 6 is designed to be mounted so as to be displaceable parallel to the rotational axis of the bearing 5, at least in the region of the adjusting wheel 17.

Finally, guide elements 28, preferably in the form of screws, which act on the adjusting element 6 from the outside, are preferably provided on both sides of the adjusting wheel 17, in each case, in order to ensure a good guidance of the adjusting element 6.

List of reference numerals

1 chair base

2 chair seat

3 back support

4 spring

5 support

5.1 bearing surface

5.2 first tooth System

5.3 Secondary latching elements

6 adjusting element

7 connecting element

8 longitudinal guide device

9 backrest carrier

10 chair seat carrier

11 rotating joint

12 rotating support

13 sliding seat

14 telescopic guide device

15 swivel bearing

16 grooves

17 regulating wheel

18 second spring

19 telescopic guide device

20 chair leg

21 force transmission device

21.1 second tooth

22 rotating shaft

22.1 first latching element

22.2 Curve guide device

23 spring element

24 adjusting rod

24.1 suppository

25 guide element

26 locking wheel

27 locking element

28 guide element

Claims

1. Chair comprising a chair base body (1) on which a seat (2) and a backrest (3) connected to the seat (2) by means of a synchronization mechanism are movably supported, wherein a spring (4) is provided which presses the seat (2) into the initial position of the chair, and a support (5) is rotatably supported on the chair base body (1), wherein the support (5) is designed to interact on the one hand with a connecting element (7) connected to the front edge of the seat (2) and on the other hand with the ends of the spring (4),

it is characterized in that the preparation method is characterized in that,

the connecting element (7) interacting with the bearing (5) is designed to be guided in a longitudinal guide (8) and to be arranged in the uppermost position of the longitudinal guide (8) in the initial position of the seat.

2. Chair according to claim 1, characterized in that the longitudinal guide (8) for the connecting element (7) is configured in the upright position of the chair obliquely downwards, viewed in the direction of the backrest (3) from the front edge of the seat (2).

3. Chair according to claim 1 or 2, characterized in that two seat carriers (10) are provided which are connected to one another by the connecting element (7), wherein the chair base body (1) is arranged between the two seat carriers (10) and the connecting element (7) is movably supported on the chair base body (1).

4. A chair according to any of claims 1-3, characterized in that a backrest carrier (9) which can be swung about a horizontal axis is supported on the chair base (1).

5. Chair according to claim 3 or 4, characterized in that the backrest carrier (9) and the two seat carriers (10) are connected to each other by two swivel joints (11) with a horizontal axis, which are movable independently of the chair base (1).

6. Chair according to any of claims 1 to 5, characterized in that the connecting element (7) operatively connected to the seat (2) by the seat carrier (10) is configured to be operatively connected to a seat (5) for the spring (4).

7. Chair according to claim 6, wherein a swivel bearing (15) is provided for fixing the support (5) on the chair base (1), characterized in that the swivel bearing (15) is configured to be arranged on one end of the support (5) and the connecting element (7) is configured to be fitted on the other end of the support (5).

8. Chair according to claim 6 or 7, characterized in that a force transmission means (21) is arranged between the connecting element (7) and the seat (5).

9. Chair according to claim 8, characterized in that the support (5) has a first toothing (5.2) on the force transmission side, the force transmission means (21) has a second toothing (21.1) on the support side, and the two toothings (5.2, 21.1) are each configured to be convexly curved towards one another and to mesh with one another.

10. Chair according to claim 8 or 9, characterized in that the support (5) is configured arcuately and that the toothing (5.2) on the force transmission side is arranged on the convex outer side of the support and the bearing surface (5.1) for the spring (4) is arranged on the concave inner side of the support (5).