EP0635227B1 - Chair, particularly office chair - Google Patents

Abstract

A chair, particularly office chair, has as so-called sychronizing mechanism a front seat carrier part (6), fixed in relation to a chair column, and a rear seat carrier part (7) which is pivotable with respect to said front seat carrier part about a pivot shaft (8) and carries a backrest. A seat is supported on the two seat carrier parts (6, 7). Articulated on the rear seat carrier part (7) at a distance from the pivot shaft (8) is a locking lever (62) of a locking device (61), which locking lever has a stop face (64). The latter comes into engagement under gravity with a locking face (65) fixed relative to the front seat carrier part (6). To release this locking arrangement, the locking lever (62) is lifted by means of an actuating arm (67) of the locking arrangement. <IMAGE>

Description

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

Such a chair known from DE-C-27 33 322 (corresponding to US Pat. No. 4,200,332) has a so-called synchronous mechanism in which the backrest and seat are pivoted simultaneously in a certain predetermined ratio. The energy accumulator serves to enable an adjustment or pivoting of the backrest, which is done by the user pressing against the backrest. Here, the rear area of the seat is also lowered or raised when the backrest swings forward. In order to freeze the backrest and the seat in one position, a length-adjustable gas spring is provided, which can be fixed in any length setting. The effort for this is great. In addition, the seat and the backrest have a fixed position to each other for each pivot position of the synchronous mechanism. This does not meet the needs of users with different body shapes and different postures when using the chair.

From DE-U-9 006 925 an office chair is known in which an adjusting screw is provided between a front seat support part and a rear backrest part, by means of which the inclination of the backrest relative to the seat can be adjusted. This means that the seat inclination in relation to the backrest can also be adjusted.

The invention has for its object to design a chair of the generic type so that an adaptation to different body shapes and working postures of the user is possible with a simple structure.

This object is achieved by the features in the characterizing part of claim 1.

The measures according to the invention make it possible for the basic inclination of the seat surface to be changed, i.e. the basic setting of the inclination of the seat relative to the backrest can be changed. The position of the front area of the seat is not changed, but the seat is raised or lowered in its rear area.

For this purpose, the subclaims give advantageous and partly inventive configurations. In particular, it is stated in the subclaims that the seat recliner can be used as a kit for retrofitting the chair and that the chair retains its synchronous mechanism even without this recliner.

Fig. 1

einen Stuhl in perspektivischer Gesamtdarstellung,

Fig. 2

eine Teildraufsicht auf einen Sitzträger des Stuhles nach Fig. 1,

Fig. 3

einen Bedienungshebel für den Stuhl in perspektivischer Darstellung,

Fig. 4

einen vertikalen Teilschnitt durch den Stuhl gemaß der Schnittlinie IV-IV in Fig. 2,

Fig. 5

einen vertikalen Teilschnitt durch den Stuhl gemaß der Schnittlinie V-V in Fig. 2,

Fig. 6

einen vertikalen Teilschnitt durch den Sitz des Stuhles, wobei eine Sitzneigungs-Verstelleinrichtung gezeigt wird,

Fig. 7

einen vertikalen Teil-Querschnitt durch den Stuhl gemäß der Schnittlinie VII-VII in Fig. 6 und

Fig. 8

eine Teil-Draufsicht auf die Sitzneigungs-Verstelleinrichtung entsprechend einem Sichtpfeil VIII in Fig. 7.

An embodiment of the invention is explained below with reference to the drawing. It shows

Fig. 1

an overall perspective view of a chair,

Fig. 2

2 shows a partial top view of a seat support of the chair according to FIG. 1,

Fig. 3

an operating lever for the chair in a perspective view,

Fig. 4

a vertical partial section through the chair along the section line IV-IV in Fig. 2,

Fig. 5

a vertical partial section through the chair along the section line VV in Fig. 2,

Fig. 6

a partial vertical section through the seat of the chair, a seat inclination adjustment device being shown,

Fig. 7

a vertical partial cross section through the chair along the section line VII-VII in Fig. 6 and

Fig. 8

FIG. 7 shows a partial top view of the seat inclination adjustment device in accordance with an arrow VIII in FIG. 7.

1 shows an office chair which has a chair frame 1. This is provided with a base frame 2, which is supported by rollers 3 against the floor. On the base 2, a height-adjustable chair column 4 is attached, at the upper end of which a seat support 5 is attached. The seat support 5 is configured in two parts; it has a front seat support part 6, which is fastened on the chair column 4, and a rear seat support part 7, which is articulated above the chair column 4 by means of a pivot axis 8 on the front seat support part 6. In the front area of the front seat support part 6, a support tube 9 is fastened, which runs parallel to the pivot axis 8. A seat 10 is supported on this support tube 9 shortly behind its front edge 11. The seat 10 is supported in its rear area on a support axis 12 which is mounted in the rear seat support part 7. A seat inclination adjustment device 13 can also be arranged on the rear seat support part 7.

In one piece with the rear seat support part 7 is formed a backrest support 14 which projects from this and on which a backrest 15 is attached. In order to be able to adjust their height relative to the seat 10, a backrest height adjustment device 16 is provided.

The described design of the seat support 5 with the arrangement of the seat 10 and the backrest 15 forms a so-called synchronous mechanism. In order to be able to change the forces to be overcome when adjusting or rocking, a force changing device 17 is provided. Armrests 18 are attached to the front edge 11 of the seat 10, specifically on the outer ends of the support tube 9, of which only one can be seen in the side view of FIG. 1.

As can be seen in FIG. 2, with the front seat support part 6 two bearing bushes 19, 19 'aligned with one another are integrally formed, in which two support tube sections 20, 20' forming the support tube 9 are mounted in alignment with one another and in each case by means of a screw 21 rotatably and in the direction of the Axis 22 of the support tube 9 are held immovably. The support tube sections 20, 20 'only protrude outward beyond the bearing bushes 19, 19'. Between the bearing bushes 19, 19 '- and consequently between the support tube sections 20, 20' - there is a largely open space 23.

In Fig. 2 below is also indicated that the armrest 18 is provided at its lower end with a short holding sleeve 24 which is attached to the end of the support tube section 20 '. A holding pin 25, which is connected to the holding sleeve 24 and engages in the supporting tube section 20 ', is formed in the holding sleeve 24. A screw, not shown in the drawing, is provided to fix the holding sleeve 24 in the direction of the axis 22. To prevent the armrest 18 from rotating relative to the axis 22, positioning projections (not shown in the drawing) are formed in the holding sleeve 24, which engage in recesses 26 formed at the end of the respective support tube section 20.

In each support tube section 20, 20 ', an actuating shaft is pivotally mounted about the axis 22, which projects into the open space 23 at one end. An actuating shaft 27 for a chair height adjustment is mounted in the support tube section 20 shown above in FIG. 2, while an actuation shaft 28 for the actuation of a synchronous mechanism is mounted in the support tube section 20 'shown in FIG. 2 below. Each actuating shaft 27, 28 has at least one driving pin 29 running radially to the axis 22, which extends outwards through an elongated hole 30 in the respective support tube section 20 or 20 '. The respective elongated hole 30 extends over a part of the circumference of the respective support tube section 20, 20 ′, the maximum pivoting angle of the actuating shaft 27 or 28 also being caused by the circumferential extent of the respective elongated hole 30 the axis 22 is set. Only a driving pin 29 and an elongated hole 30 are shown in FIG. 2.

The actuation shafts 27, 28 are each pivoted by means of an operating lever 31 which has a push-in sleeve 32 and an actuating handle 33 attached to it. Before the armrest 18 is mounted on the support tube 19, the tubular plug-in sleeve 32 is pushed onto the corresponding support tube section 20 or 20 ', with recesses 34 formed on the inside of the plug-in sleeve 32 coming into engagement with the driving pin 29. The configuration of the operating lever 31 can be seen in FIG. 3. The actuating handle 33 protrudes - on the axis 22 - on one side via the push-in sleeve 32, as can be seen in FIGS. 2 and 3. Since recesses 34 are formed at both ends of the push-in sleeve 32, the push-in sleeve 32 can be plugged onto the support tube section 20 'in such a way that the operating lever 31 projects outwards in the direction of the armrest 18, as shown in FIG. 2 below if - what Fig. 2 can be removed above - no armrest 18 is to be provided, then the operating lever 31 can be plugged onto the support tube section 20 such that the actuating handle 33 projects in the direction of the adjacent bearing bush 19. In this case, the front end of the respective support tube section 20 having the recesses 26 only has to be closed with a cover cap. As can be seen from FIG. 2 below, an area of the respective support tube section 19 or 20 forming a bearing section 35 is left free between the respective bearing bush 19 'and the adjacent push-in sleeve 32. The seat 10 is pivotally supported on these storage areas, as will be shown further below.

For height adjustment of the seat support 5 with seat 10 and backrest 15, the chair column 4 has a generally known length-adjustable gas spring 36 which is held in a clamping manner in the form of a cone-shaped clamping device 37 of the front seat support part 6. A valve actuation pin 38 protrudes upward from the gas spring 36, and when it is inserted into the gas spring 36, an existing valve is opened, making length adjustments of the gas spring 36 possible. Such Gas springs are generally known in practice and are shown and described, for example, in DE 18 12 282 C2 (corresponding to US Pat. No. 3,656,593). To actuate this pin 38, a two-armed valve actuation lever is provided, which is pivotably supported against the pivot axis 8, as can be seen in FIG. 4. A lever arm 40 of the lever 39 bears against the valve actuation pin 38, while the other lever arm 41 ends in the region of the open space 23. There is a valve actuating arm 42 attached to the actuating shaft 27 for seat height adjustment, specifically to its section projecting into the open space 23, which projects approximately radially to the axis 22 from the actuating shaft 27. It engages with its free end under the adjacent free end of the lever arm 41, so that when the actuating shaft is pivoted in such a way that the free end 43 is pivoted upward, the lever arm 40 of the lever 39 is pivoted downward and the valve actuating pin 38 pushes into the gas spring 36. In Fig. 4 this pivoting takes place counterclockwise. When the user releases the actuating handle 33, the pin 38 is reset by the gas pressure in the gas spring 36, as a result of which the lever 39 and thus the actuating shaft 27 are then reset in their initial position.

As already indicated above, the seat 10 is snapped elastically onto the support tube sections 20, 20 'by means of latching sections 44 which partially encompass the bearing sections 35. Since the seat 10 together with the latching sections 44 is made in one piece from hard elastic plastic, this is readily possible. The latching sections 44 are shown in particular in FIG. 6. In its rear area, the seat 10 is supported on the support axis 12 which is mounted in approximately horizontally extending elongated holes 45 in the rear seat support part 7 and which extends parallel to the axis 22 and to the pivot axis 8. The seat 10 is snapped onto this support axis 12 by means of latching openings 46 which are formed in webs 47 of the seat 10 which extend downward from the seat 10. If the seat 10 is pivoted about the pivot axis 8 about the axis 22 of the front bearing sections 35 when the rear seat support part 7 is pivoted, ie is raised or lowered in its rear region, then the elongated hole 45 in the rear seat support part 7 enables such pivoting occurring substantially horizontal relative movements between the seat 10 and the rear seat support part 7 by the support axis 12 executing these movements in the elongated holes 45. When the rear seat support part 7 is pivoted about the pivot axis 8, on the one hand the backrest 15 is pivoted in accordance with the pivoting movements of the rear seat support part 7. On the other hand, the seat 10 is pivoted about the stationary axis 22 due to the essentially vertical pivoting movements of the support axis 12 mounted in the rear seat support part 7. 1, 4, 6, the geometric ratios of the horizontal spacing ratios of the axis 22 to the pivot axis 8, to the support axis 12 and to the backrest 15 result in that when the rear seat support part 7 is pivoted, the backrest 15 by the 3- to 4- times the angular amount compared to the seat 10 is pivoted.

The previously described pivoting of the synchronous mechanism is counteracted by a force accumulator 48, which in the exemplary embodiment shown is a prestressed helical compression spring 49. This helical compression spring 49 is supported via a pivotable abutment 50 against the front seat support part 6 below the actuating shaft 28 in the open space 23. With its other end, the compression spring 49 is supported against a slide shoe 51 of the force changing device 17. The sliding shoe 51 in turn bears against a sliding surface 52 which is formed on a lever arm 53 of the rear seat support part 7. This lever arm 53 is formed in one piece with the rear seat support part and extends essentially downwards from the pivot axis 8. Geometrically, the rear seat support part is designed as an angle lever. The pivotable abutment 50 is provided with a rod 54 passing through the compression spring 49, on which the slide shoe 51 can also be displaced in the direction of the compression spring 49. The force changing device 17 acts on the end of the rod 54 opposite the abutment 50. It has an adjusting screw 55 articulated on the rod 54, which engages in an adjusting nut 56 which is designed as part of a turning handle 57 and is mounted in a lower wall 58 of the front seat support part 6 so as to be rotatable but non-displaceably in the direction of the adjusting screw 55 is. When the handle 57 rotates with the adjusting nut 56, the adjusting screw 55 is therefore pivoted with the rod 54 about the pivot joint 59, via which the pivotable abutment 50 is supported in the front seat support part 6. The sliding block 51 is shifted on the sliding surface 52 of the lever arm 53, whereby the distance between the axis 60 of the energy accumulator 48 and the pivot axis 8 is changed. Since the sliding surface 52 lies at least approximately on a circular arc section, the center point of which is formed by the swivel joint 59, the distance b between the swivel joint 59 and the intersection of the axis 60 with the sliding surface 52 is not or only slightly changed when the rotary handle 57 is rotated that the bias of the helical compression spring 49 does not change with such adjustments.

The force acting on the lever arm 53 by the compression spring 49 is therefore not changed; it is only by changing the distance a between the axis 60 and the pivot axis 8 that the effective lever arm, i.e. Overall, the torque acting from the compression spring 49 on the rear seat support part 7 and thus on the seat 10 and the backrest 15 changes. This torque is smaller the smaller the distance a is and vice versa. This means that the adjustment forces to be applied to the rotary handle 57 can also be kept constant over the entire adjustment path of the slide shoe 51, since the frictional forces between the slide shoe 51 and the sliding surface 52 practically do not change.

In order to be able to switch off the described pivoting of the seat 10 and the backrest 15 against the force of the compression spring 49, a locking device 61 is provided. This locking device 61, shown essentially in FIGS. 2 and 5, has a locking lever 62 which is attached to the lever arm 53 of the rear seat support part 7 by means of a pivot connection 63 and can be pivoted about an axis parallel to the pivot axis 8. The swivel connection 63 is located in the lower region of the lever arm 53, and is therefore at a clear distance from the swivel axis 8. The locking lever 62 is on its underside with an approximately perpendicular to its longitudinal direction provided stop surface 64, which is associated with a fixed locking surface 65. This locking surface 65 is formed in the front seat support part 6, specifically in the area of the lower wall 58 thereof. The locking surface 65 faces the pivot connection 63, whereas the stop surface 64 faces the locking surface 65. Contrary to the pivot connection 63, the locking lever 62 has a fork-shaped end 66, under which a locking actuating arm 67 engages, which is T-shaped and is fixedly connected to the actuating shaft 28. A crossbar 67a of the actuating arm 67 therefore engages under the fork-shaped end 66. The actuating arm 67 protrudes radially from the section of the actuating shaft 27 located in the open space 23 in relation to the axis 22. Due to the pivoting of this actuating shaft 28 already described for the actuating shaft 27, the locking actuating arm 67 is pivoted between a position shown in solid lines in FIG. 5 and a position shown in broken lines there. In the position shown in solid lines in FIG. 5, the locking actuating arm 67 lifts the locking lever 62 to such an extent that its stop surface 64 disengages from the locking surface 65. If the user of the chair now presses the backrest 15 back against the force of the compression spring 49, the fork-shaped end 66 of the locking lever 62 on the T-shaped actuating arm 67 can be displaced in the direction of the actuating shaft 27. So it is possible to rock freely with the synchronous mechanism. If, on the other hand, the actuating shaft 28 is pivoted into the position shown in broken lines in FIG. 5 by means of the operating lever 31, then the transverse web 67a of the T-shaped actuating arm 67 disengages from the fork-shaped end 66, so that the latter is connected to the locking surface 65 via one Guide pin 68 can fall. This pivoting down of the locking lever 62 is only possible if the rear seat support part 7 is pivoted by the force of the compression coil spring 49 with a corresponding relief of the backrest 15 and the seat 10 into a position in which the backrest 15 and its front end position the seat 10 assumes its upper end position. In these positions, the distance of the pivot connection 63 from the locking surface 65 is so large that the locking lever 62 can fall into a lower locking position shown in phantom in FIG. 5. Locking the rear seat support part 7 with respect to the front seat support part 6 and thus fixing the backrest 15 and the seat 10 in one position is therefore only possible in this position. If the unlocked locking lever 62 is moved essentially in its longitudinal direction by pivoting the rear seat support part 7, then its underside 69 slides over a support surface 70 of the front seat support part 6 formed between the locking surface 65 and the guide pin 68.

Deviating from the support of the seat 10 via the support axis 12, which is essentially fixed relative to the rear seat support part 7, the basic setting of the seat inclination can also be changed via an alternatively possible seat inclination adjusting device 13, which is shown essentially in FIGS. 6 to 8. Here, a continuous rod-shaped support axis 12 is not provided, but the support axis 12 'is formed by two pins 71, 71', which are held clamped in bearing parts 72 on the underside of the seat 10, so that they can also be retrofitted or, if necessary, again without destruction the seat 10 can be pulled out. They are - as can be seen in FIGS. 7 and 8 - on both sides of the rear seat support part 7, so that they can pivot past the webs 47 thereof.

A rocker 73 designed in the manner of a double-armed lever is pivotably mounted on the seat support part 7 about a pivot axis 74. The pivot axis 74 is inserted into openings 47a in the webs 47 of the rear seat support part 7. It also penetrates web-like bearing cheeks 73a which are formed on the underside of the rocker 73 facing the rear seat support part 7. The pivot axis 74 can be held clamped in the webs 47 or the web-like bearing cheeks 73a. The rocker 73 has two fork-shaped lever arms 75, 75 'which are also located on both sides of the rear seat support part 7 and each overlap a pin 71 or 71', so that when the rocker 73 is pivoted about the pivot axis 74 parallel to the pivot axis 8, the pins 71, 71 'in the height can be changed. Thus, in an otherwise fixed position from the rear seat support part 7 to the front seat support part 6, i.e. without simultaneous adjustment of the position of the backrest 15, the seat 10 is pivoted about the axis 22, so that its rear region 76 has a higher or lower position relative to the rear seat support part 7 occupies. These swiveling of the rocker 73 are realized in a similar manner to the swiveling of the compression spring 49 of the force changing device 17.

On the plate-shaped lever arm 77 of the rocker 73 opposite the fork-shaped lever arms 75, 75 ', an adjusting screw 78 is articulated which engages in an adjusting nut 79. This is firmly connected to a rotary handle 80 which, together with the adjusting nut 79, is rotatably but immovably mounted in the direction of the adjusting screw 78 in an opening 81 in a wall 82 of the rear seat support part 7. The adjusting screw 78 has at its end opposite the adjusting nut 79 a transverse web 83 which engages in elongated holes 84 of abutment webs 85 of the lever arm 77. When the rotary handle 80 rotates, the adjusting screw 78 is screwed into or unscrewed from the adjusting nut 79, which results in corresponding rocking of the rocker 73 about the pivot axis 74, the lowest basic setting of the seat 10 which can be achieved hereby being shown in solid lines in FIG. 6, while the highest possible basic setting is shown in phantom in FIG. 6.

When mounting the seat inclination adjustment device 13, which is possible as an additional equipment, if necessary subsequently, the adjusting nut 79 is pushed from above through the opening 81 in the wall 82 and the rotary handle 80 is set against it from below; both parts are then connected with a screw 86. In addition, the pins 71, 71 'are inserted or pressed into the bearing parts 72. The rocker 73 is connected to the rear seat support part 7 by inserting the pivot axis 74. In addition, the support axis 12 is pulled out of the elongated holes 45. The pins 71, 71 'are then inserted into the fork-shaped lever arms 75, 75'. Then the seat 10 is connected to the front support tube 9 in that the latching sections 44 are elastically snapped onto the support tube sections 20, 20 ', on which they can be pivoted about the axis 22. The disassembly takes place accordingly.

Claims (9)

1. A chair, in particular an office chair, comprising

   - a pedestal (2)

   - a chair column (4) projecting upwards from the pedestal (2)

   - a seat support (5) supported on the chair column (4) and having a front seat support member (6) joined to the chair column (4) and a rear seat support member (7) joined to the front seat support member (6) by way of a pivot axle (8)

   - a seat (10) pivotably supported on the seat support members (6, 7)

   - a back-rest (15) secured to the rear seat support member (7)

   - an energy storing device (48), of which one end is positioned on the front seat support member (6) and of which the other end is positioned on the rear seat support member (7) at a distance (a) from the pivot axle (8), and

   - a blocking mechanism (61) for arresting the rear seat support member (7) in relation to the front seat support member (6),

   characterized in that
   the seat (10) is supported in relation to the rear seat support member (7) by a supporting axle (12') which is adjustable in height referred to the rear seat support member (7) by means of a seat pitch adjuster (13), the seat pitch adjuster (13) having a double-armed lever (73), which is supported on the rear seat support member (7) pivotably about a pivot axle (74) and of which one side (75, 75') is coupled with the supporting axle (12') and to the other lever arm (77) of which a pivoting device (78, 79) is coupled which is joined to the rear seat support member (7).
2. A chair according to claim 1, characterized in that the double-armed lever is a balance (73).
3. A chair according to claim 1, characterized in that the one side of the double-armed lever (balance 73) is formed by at least one forked lever arm (75, 75') accommodating the supporting axle (12').
4. A chair according to claim 1, characterized in that the pivoting device has an adjusting nut (79) and an adjusting screw (78) engaging with the latter, one of which is supported on the rear seat support member (7) rotatably but non-displaceably in its longitudinal direction and of which the other engages with the other lever arm (77) of the double-armed lever (73).
5. A chair according to claim 4, characterized in that the adjusting nut (79) is positioned on the rear seat support member (7).
6. A chair according to claim 3, characterized in that the double-armed lever (73) has two forked lever arms (75, 75'), which are situated on either side of the rear seat support member (7) and with each of which a supporting axle (12') secured to the seat (10) engages.
7. A chair according to one of claims 1 to 6, characterized in that the seat pitch adjuster (13) is releasably mounted on the rear seat support member (7) and in that the seat (10) is alternatively supported in relation to the rear seat support member (7) by way of a supporting axle (12) positioned in the latter.
8. A chair according to claim 7, characterized in that the supporting axle (12) located in the rear seat support member (7) is located in at least one oblong hole (45) in the rear seat support member (7).
9. A chair according to claim 8, characterized in that the seat (10) is joined to the supporting axle (12) by means of a locking assembly (46).

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