EP1459655A1 - Seating device for dynamic sitting - Google Patents

Abstract

A seat (1) comprises a seat element (3) which by means of a fiber-composite spring element (4) is joined to the support structure (2) so that it is movable, in particular, in all directions relative to the support structure. The spring element is firmly joined to the seat element and the support structure. Independent claims are also included for the following: (a) A building set with different fiber-composite spring elements for the proposed seat (b) An application of fiber-composite spring elements for construction of the proposed seat.

Description

The invention relates to a seat device for dynamic sitting according to the preamble of claim 1. The invention further relates to the use of a spring element made of fiber composite material for a seat device.

It is known that sitting every day at work can be dangerous to health. The trigger for complaints and illnesses is not necessarily the sitting itself, but incorrect sitting. Poor posture and misconduct when sitting are common among office workers. Damage to the spine and an under or overstraining of the surrounding and supporting muscles are the result. Permanent one-sided stress on the spine and intervertebral discs can lead from harmless cases such as irritation with attacks of pain to a herniated disc with extreme pain. Furthermore, muscle tension and hardening can occur, which results in a restriction of the ability to move. In addition to adjusting the position of the workplace to suit the body size of the office worker, occupational physicians therefore require dynamic or flexible sitting, which promotes frequent changing of the sitting position. This is one-sided Counteracts strain on muscles and intervertebral discs and also activates the circulation.
There are therefore known seating devices, such as office swivel chairs, which enable dynamic sitting, for example by the seat surface being tiltable forward and backward in order to support an optimal sitting position. From the document DE 197 42 052 A1 a seat device is known which has a torsion pivoting and tilting bearing consisting of a plurality of rubber buffers, which is firmly connected to a seat plate, so that the seat is flexibly movably supported on all sides. This torsion and tilting bearing requires a relatively large installation height, so that this is unsuitable for a chair made according to the Euro standard for office swivel chairs with a lower seat height of 40 cm at + 12 cm stroke by means of gas pressure spring. The rubber buffers used in the torsion and tilting bearings also have a relatively short lifespan and require a stroke limitation.

It is therefore an object of the present invention to form a seating device which enables comfortable, dynamic sitting, in particular in an office swivel chair or a visitor chair.

This object is achieved with a seat device having the features of claim 1. Subclaims 2 to 13 relate to further, advantageously designed seat devices. The object is further achieved by a kit for a seat device having the features of claim 14.

The object is achieved in particular with a seat device for dynamic sitting comprising a seat position and a seat, wherein the seat is connected to the seat frame via a spring element made of fiber composite material such that the seat is movably mounted, in particular movably, on all sides. The seat device advantageously has a plurality of spring elements.

There are a number of design options for a seat device. The term seating device used here can be, for example, an office swivel chair with casters, a conference chair with four legs, a children's chair, a children's swivel chair, a sofa, a seat like this used in a stadium, or for example a car seat like this in a car applied, act. All these seat devices according to the invention have in common that the seat surface or the seat plate is movably mounted with respect to the seat frame or the substructure.

• dass es kostengünstig herstellbar ist,
• dass es ermüdungsfrei beansprucht wird, sodass dieses Federelement während einer sehr langen Zeit verwendet werden kann,
• dass es wartungsfrei ist,
• dass es geräuschfrei betätigbar ist,
• dass es kein Metall aufweist,
• dass es rezyklierbar ist,
• und dass es auch eine progressive Federcharakteristik aufweisen kann.

In einer vorteilhaften Ausgestaltung ist das Federelement streifenförmig ausgestaltet und weist bevorzugt einen geradlinigen oder geschweiften Verlauf auf. In weiteren vorteilhaften Ausgestaltungen weist das Federelement einen S-, Z- oder C-förmigen Verlauf auf. Ein derartig ausgestaltetes Federelement weist eine sehr geringe Bauhöhe auf, sodass die Verbindung zwischen dem Sitzgestell und dem Sitz eine sehr geringe Bauhöhe erfordert. Bevorzugt verlaufen die im Federelement eingebetteten Glasfasern ausschliesslich in der streifenförmigen bzw. länglichen Ausdehnungsrichtung des Federelementes.In an advantageous embodiment, the spring element consists of a fiber composite material, in particular of glass fibers embedded in a matrix, a thermoset or a thermoplastic being used as the matrix, for example polypropylene, polyamide or PEEK. The glass fibers are preferably arranged in the matrix as directional continuous glass fibers. This spring element made of fiber composite material has the advantages

• that it is inexpensive to manufacture,
• that it is stressed without fatigue, so that this spring element can be used for a very long time,
• that it is maintenance free
• that it can be operated without noise,
• that it has no metal,
• that it is recyclable
• and that it can also have a progressive spring characteristic.

In an advantageous embodiment, the spring element is designed in the form of a strip and preferably has a straight or curved shape. In further advantageous embodiments, the spring element has an S, Z or C-shaped course. A spring element designed in this way has a very low overall height, so that the connection between the seat frame and the seat requires a very low overall height. The glass fibers embedded in the spring element preferably run exclusively in the strip-shaped or elongated direction of expansion of the spring element.

The seat device according to the invention for dynamic sitting comprising the spring element mentioned can be designed in a large number of different embodiments and different areas of application, for example as an office chair, as a seat device in an automobile, or as a seat device in public transport such as an airplane, a bus or a railroad car. The seating device according to the invention can, for example, also be designed for the home, for example as a sofa or as a kitchen chair.

The seating device according to the invention can also include further subcomponents such as armrests or backrests, which are connected to the seat frame, the seat or, for example, a chair leg via spring elements made of fiber composite material, so that these subcomponents are also arranged to be movable and thereby promote dynamic sitting or movement while sitting.

Advantageously, spring elements with different force-displacement spring characteristics can be provided as a kit for a seat device, so that the resilient properties of the seat device can be freely selected by installing correspondingly hard or soft springs. These springs can be replaced at any time by springs with a different force-displacement spring characteristic, so that a seat device can be individually adjusted and changed at any time to ensure seating comfort that is adapted to the person concerned.

Fig. 1a

eine Frontansicht einer Sitzvorrichtung;

Fig. 1b

eine Seitenansicht einer Sitzvorrichtung;

Fig. 1c

eine Draufsicht auf das Sitzgestellt der Sitzvorrichtung gemäss Fig. 1a und 1b;

Fig. 2a

ein erstes Ausführungsbeispiel eines Federelementes;

Fig. 2b

ein zweites Ausführungsbeispiel eines Federelementes;

Fig. 2c

ein drittes Ausführungsbeispiel eines Federelementes;

Fig. 2d

ein viertes Ausführungsbeispiel eines Federelementes;

Fig. 2e

ein fünftes Ausführungsbeispiel eines Federelementes;

Fig. 2f

ein sechstes Ausführungsbeispiel eines Federelementes;

Fig. 2g

eine Draufsicht der Federelemente gemäss Fig. 2a - 2d;

Fig. 2h

ein siebtes Ausführungsbeispiel eines Federelementes;

Fig. 2i

eine Draufsicht auf des Federelement gemäss Fig. 2h;

Fig. 2k

eine Draufsicht auf ein weiteres Federelement;

Fig. 21

eine Draufsicht auf ein weiteres Federelement;

Fig. 2m

eine Seitenansicht auf ein weiteres Federelement;

Fig. 3

eine Seitenansicht eine Sitzschale mit Sitzpolster;

Fig. 4

eine Seitenansicht einer weiteren Sitzschale;

Fig. 5

eine Teilansicht eines Schnitts durch eine Sitzvorrichtung mit Federelement mit progressiver Federcharakteristik;

Fig. 6

eine Teilansicht einer weiteren Anordnung mit progressiver Federcharakteristik;

Fig. 7

eine Teilansicht eines Schnitts durch eine weitere Sitzvorrichtung mit Federelement;

Fig. 8a,8b

Teilansichten eines Schnitts durch eine weitere Sitzvorrichtung mit Federelement;

Fig. 9

eine Seitenansicht eines Bürodrehstuhls;

Fig. 10a, 10b

eine Frontansicht sowie eine Seitenansicht eines Konferenzstuhls;

Fig. 11a, 11b, 11c

weitere Ausführungsbeispiele von Sitzvorrichtungen.

The seating device according to the invention is described in detail below using exemplary embodiments. Show it:

Fig. 1a

a front view of a seat device;

Fig. 1b

a side view of a seat device;

Fig. 1c

a plan view of the seat of the seat device according to FIGS. 1a and 1b;

Fig. 2a

a first embodiment of a spring element;

Fig. 2b

a second embodiment of a spring element;

Fig. 2c

a third embodiment of a spring element;

Fig. 2d

a fourth embodiment of a spring element;

Fig. 2e

a fifth embodiment of a spring element;

Fig. 2f

a sixth embodiment of a spring element;

Fig. 2g

a plan view of the spring elements according to Figures 2a - 2d;

Fig. 2h

a seventh embodiment of a spring element;

Fig. 2i

a plan view of the spring element according to FIG. 2h;

Fig. 2k

a plan view of another spring element;

Fig. 21

a plan view of another spring element;

Fig. 2m

a side view of another spring element;

Fig. 3

a side view of a seat shell with seat cushion;

Fig. 4

a side view of another seat shell;

Fig. 5

a partial view of a section through a seat device with spring element with progressive spring characteristic;

Fig. 6

a partial view of a further arrangement with a progressive spring characteristic;

Fig. 7

a partial view of a section through a further seat device with spring element;

8a, 8b

Partial views of a section through a further seat device with spring element;

Fig. 9

a side view of an office swivel chair;

10a, 10b

a front view and a side view of a conference chair;

11a, 11b, 11c

further embodiments of seat devices.

The front view shown in FIG. 1a shows a seat device 1 comprising a seat frame 2 with chair legs 2a and chair frame 2b and a seat 3, the seat 3 being connected to the seat frame 2 by means of spring elements 4 arranged in a distributed manner. As shown in FIG. 1b with a side view, the spring elements 4 have a curved course, the spring elements 4 being attached with their end sections to the seat frame 2 or to the seat 3, so that the seat 3 has at least one mobility shown in the direction of the arrow F having. Figure 1c shows a plan view of the seat device 1 with the seat 3 removed, so that only the seat frames 2 and the spring elements 4 are shown. The seat frame 2 has two narrow, strip-shaped spring elements on the left 4, each spring element 4 having two fastening sections 4a, 4b with fastening means 6 (not shown in detail) for fastening it in the end region. On the right, a single, long spring element 4 is shown, which extends almost over the entire length of the chair frame 2b. For example, four narrow, strip-shaped spring elements 4, which jointly carry the seat 3, could also be arranged on the seating furniture 2. For example, only two long spring elements 4, which together carry the seat 3, could also be arranged on the seat frame 2.

The spring elements 4 consist of a composite material, preferably of polypropylene and glass fibers. These spring elements 4 have the advantages that a very low overall height is required for the resilient connection of seat frame 2 and seat 3. In addition, the spring elements 4 are fatigue-free and can therefore be used maintenance-free for an extremely long period of time.

The spring elements 4 can be arranged in a wide variety of ways in order to bring about a resilient connection between the seat frame 2 and the seat 3, and to thereby enable dynamic or movable sitting. A person sitting on the seat 3 can change the inclination of the seat 3 with respect to the seat frame 2 or the floor 6 by a corresponding weight shift.

FIGS. 2a to 2e each show, in a side view, differently running spring elements 4, all of which have the strip-shaped course shown in FIG. 2g in plan view. The spring element 4 can be straight, for example run (Figure 2a), run slightly curved (Figure 2b), run slightly or strongly S-shaped (Figure 2c, 2d) or Z-shape (Figure 2e). As shown in FIG. 2f, the spring element 4 can also run in a C-shape, the spring element 4 being connectable to the seat 2 via the fastening section 4a and to the seat 3 via the fastening section 4b. In a particularly advantageous embodiment, the glass fibers of the spring element 4 are designed as directional continuous glass fibers, which extend in the direction of the elongated strip-shaped course shown in FIG. 2g. The strip-shaped spring elements 4 shown in FIGS. 2a to 2f preferably have a thickness between 1 and 5 mm. FIG. 2h shows a further exemplary embodiment of a spring element 4, which has a fastening section 4a and two fastening sections 4b. FIG. 2i shows a top view of the spring element 4 shown in FIG. 2h. The spring element 4 shown in FIG. 2h could also be circular, as shown in the top view according to FIG Attachment points 4b. As shown in FIG. 21, the spring element 4 can also be designed in the shape of a cross, with fastening points 4a, 4b. The strip-shaped spring element 4 could, as shown in FIG. 2m, also be L-shaped or semicircular, with fastening points 4a, 4b.

The spring elements 4 shown in FIGS. 2a to 2m have, in the side view shown, an overall height of preferably between 0 mm and 25 mm, and in particular an overall height between 0 mm and 5 mm. The spring elements 4 according to the invention therefore require an extremely low installation height. The earlier However, the spring elements 4 mentioned can also be made higher, and for example have a height of up to 25 mm.

FIG. 3 shows a side view of a seat shell 3a, as is used for office swivel chairs. At the bottom of the seat shell 3a, spring elements 4 can be fastened, which in turn can be fastened to the seat frame 2 of an office swivel chair. A seat cushion 3b is arranged in the seat shell 3a.

FIG. 4 shows a further seat shell 3a made of plastic, the spring elements 4 forming part of the seat shell 3a or being cast directly into the seat shell 3a, so that the fastening sections denoted by 4b can be connected to the seat frame 2.

FIG. 5 shows a section through a seat device 1, the seat frame 2 and seat 3 of which are connected to one another via a spring element 4 with V-shaped spring sections 4c and fastening means 6. This arrangement has a progressive spring characteristic in that an increasingly stronger spring force counteracts the seat 3 moved downward. The force-travel characteristic of the spring element 4 can also be actively influenced, for example with the schematically illustrated spring travel limiting means 8, which can be moved back and forth in the direction 9, which can rest against the spring section 4c, which shortens the spring-effective leg length and thus a progressively increasing one Force-displacement characteristic results.

FIG. 6 shows a further side view of a seat device 1. In contrast to the arrangement shown in FIG. 5, this is The spring element 4 is designed to run essentially semicircular, the end sections 4d of which are held in u-shaped, metallic fastening means 6a and fastened to the seat 3 and the seat frame 2 by means of the screw 6. The seat 3 is shown in an unloaded position 10a and a loaded position 10b. With increasing load, a longer spring section 4c rests against the seat frame 2 or seat 3, which results in an increasingly progressive force-displacement characteristic of the spring element 4.

FIG. 7 shows a further section through a seat device 1 with seat frame 2 and seat 3, which are connected to one another via two spring elements 4. The seat frame 2 has a hole in the center through which the two spring elements 4 fastened at the bottom of the seat frame 2 run to the seat 3. This arrangement of the spring elements 4 enables a very long spring travel, since the legs of the spring elements 4 can partially escape through the hole during the compression. It can prove to be advantageous to restrict the mutual mobility between seat frame 2 and seat 3. In the illustrated embodiment, spring travel limiting means 7 configured as rubber buffers are arranged on the seat frame 2 and on the seat 3. The seat 3 is movably mounted on all sides with respect to the seat frame 2.

FIGS. 8a and 8b show a simple arrangement for changing the spring characteristic of the spring arrangement comprising the spring element 4. The spring element 4 can be fastened to the position shown in FIG. 8a, as a result of which a longer partial section of the spring element 4 rests on the seat frame 2, which the force-displacement characteristic of the entire spring arrangement is increased. However, the spring element 4 can also be fastened to the position shown in FIG. 8b, which influences the force-displacement characteristic in such a way that the entire spring arrangement has a lower spring hardness.

FIG. 9 shows the side view of an office swivel chair 1, which comprises a seat frame 2 with a chair leg 2a, chair plate 2c, inclination adjustment device 2d, height-adjustable rod 2e, pivot bearing 2f, holding device 2g and rollers 2h. In addition, the office swivel chair 1 comprises a backrest 5 and a backrest holding device 5a. The office swivel chair 1 can also comprise an armrest 5b, which is connected to the seat frame 2 via a support 5c. In the exemplary embodiment shown, the armrest 5b is also connected to the carrier 5c via a spring element 4, so that the armrest 5b, similar to the seat 3, is connected to the seat frame 2 in a springy and / or tiltable manner. In addition, the backrest 5 could be connected to the backrest holding device 5a via spring elements 4. The inclination adjustment device 2d allows the inclination of the chair plate 2c to be adjusted with respect to the rod 2e or the chair leg 2a. The spring elements 4 and thus the seat shells 3a shown in FIGS. 3 and 4 can be fastened on the chair plate 2c, so that the seat 3, comprising the seat shell 3a and the seat cushion 3b, is tilted relative to the chair plate 2c. This flexibility enables dynamic sitting.

As shown in FIG. 9, the seat device 1 can be designed as an office swivel chair. However, the seat device 1 can be in a variety of different seat or chair variants be configured, for example as the seat of a car or an aircraft. All these seat and chair variants have in common that the seat is movably mounted with respect to the seat frame with the aid of springs made of fiber composite material in order to enable dynamic sitting.

FIGS. 10a and 10b schematically show a so-called visitor or conference chair, which usually has four legs 2a, in a side view and in a front view. This seat device 1 comprises a seat frame 2 with four chair legs 2a, a chair frame 2b and two chair back supports 2i. The seat 3 is connected to the seat frame 2 via spring elements 4. The backrest 5 is connected to the chair back supports 2i via spring elements 4, so that both the seat 3 and the backrest 5 are connected to the seat frame 2 in a resilient manner. For example, one of the spring elements 4 shown in FIGS. 2a to 2m can be used as spring elements 4. However, the spring elements 4 can also be designed in a large number of other geometric shapes. The seat 3 or the backrest 5 can be moved in a maximum of 6 dimensions, namely in three straight translational directions and in three axes of rotation. Such mobility in six dimensions is said to be movable on all sides. Depending on the design of the spring elements 4 used and, if applicable, of additionally used guide elements, the seat device 1 can also be movable in less than six dimensions. For example, the seat 3 could only be movably supported in three dimensions, in the linear direction A and in two directions of rotation G and F. The backrest 5 could, for example only in FIG linear direction B with respect to the seat frame 2 be movably mounted. However, the spring elements 4 can, for example, also be designed such that the seat 3 and / or the backrest 5 have additional mobility in the direction C. The mobility in the direction C can be, for example, only a few millimeters, depending on the spring element 4 selected, but, if necessary, could also be up to one centimeter or more. If necessary, guide elements could also be arranged which prevent or limit the mobility of the seat 3 and / or the backrest 5 with respect to the seat frame 2 in certain dimensions. For example, FIG. 7 shows limiting means 7 which limit the maximum translatory and / or rotational movement path of the seat 3 with respect to the seat frame 2.

The spring element 4 consists of a fiber composite material, of glass fibers embedded in a matrix, a thermoset or a thermoplastic being used as the matrix, for example polypropylene, polyamide or PEEK. The fiber composite material could also comprise natural fibers or consist of natural fibers which are embedded in a matrix. The fibers can be arranged in the fiber composite material such that the spring element 4 has isotropic or anisotropic properties.

The spring elements 4 according to the invention can be designed with different spring hardness or different elastic modulus. For example, it may prove to be advantageous to include a plurality of spring elements 4 with different force-displacement spring characteristics or different spring hardness when a office swivel chair is delivered, so that the user can meet his needs, in particular the can adjust his body weight adapted spring elements 4 in the office swivel chair. Thus, a user can individually adjust the spring properties of the office swivel chair when it is being assembled and, if necessary, can also change it again at a later time by replacing the spring elements 4. This property of the seating device according to the invention has the advantage that the spring properties of the office swivel chair can be optimally adjusted once and that these spring properties no longer change during subsequent use due to the spring properties of the fiber composite material. An unconscious adjustment of the spring properties, as is often the case with known office swivel chairs, is therefore ruled out. The spring elements made of fiber composite materials have the advantage that the force-displacement spring characteristics can be varied within a wide range by simply varying the number, arrangement and / or type of fibers and / or the matrix. In particular, geometrically identical spring elements can also be formed which, owing to the different structure and arrangement of fibers and matrix, have a different force-displacement spring characteristic. Thus, for example, a set of geometrically identical spring elements can be provided for an office swivel chair, the spring elements, however, having different force-displacement spring characteristics. Thanks to the geometrically identical design, the spring elements can be freely mounted on the office swivel chair, so that the spring properties of the office swivel chair with regard to dynamic sitting can be adjusted in a variety of ways. For example, four spring elements with the same force-displacement spring characteristic can be installed. However, it exists at will also the possibility to mount spring elements with different force-displacement spring characteristics on the same office swivel chair.

FIG. 11a shows a further exemplary embodiment of a seat device 1, the seat 3 and the seat frame 2 being connected via a C-shaped or U-shaped spring element 4, the spring element 4 being arranged on that side of the seat 3 on which the knees are in each case are located. As shown, the spring element 4 protrudes in the direction B over the seat 3 and the seat frame 2. The seat frame 2 comprises a chair plate 2c, a height-adjustable rod 2e and chair legs 2a (not shown) with rollers 2h. In an advantageous embodiment, a further spring element 4 is arranged between the seat 3 and the backrest 5, so that the backrest 5 is arranged springs with respect to the seat 3. The seat device 1 could also be designed without a backrest 5.

FIG. 11b schematically shows a side view of the chair 1 shown in FIG. 11a. In an advantageous embodiment, at least the seat 3, the spring element 4 and part of the seat frame 2, preferably the chair plate 2c, are formed from a single part and from plastic. This part is produced, for example, as an injection molded part, 4 fibers being arranged in the area of the spring element and embedded in the plastic matrix such that the spring element 4 is formed. The chair plate 2c and the seat 3 are preferably designed such that they are stiff and therefore not or hardly flexible. In a further advantageous embodiment, the single part also comprises the spring element 4 arranged between the seat 3 and the backrest 5 and the backrest 5, the latter spring element 4 also being formed with the aid of fibers arranged correspondingly in the plastic. So the whole is in Figure 11b shown seat device 1, with the exception of the rod 2e, made of plastic, and is preferably designed as a single part, that is, all sub-components, with the exception of the rod 2e, form a single or one-piece plastic part. This seat device 1 can be configured in such a way that the chair plate 2c is connected to rollers 2h via a metal rod 2e, for example. As shown in FIG. 11c, this seating device 1 can also have a fixed seating frame 2, which can be made of metal or plastic. The seat device 1 shown in FIG. 11c could also be formed from one piece and from plastic, the springs 4 correspondingly having fibers arranged in the plastic or in the matrix. The seat 3 could also be designed as a seat shell 3a, on which a seat cushion 3b still rests.
The spring 4 could also be connected to the seat 3 and / or the seat frames 2 and / or the backrest 5 with a detachable connection, for example a screw connection, a connection such as that shown in FIG. 5 or 6. In the seat devices 1 shown in FIGS. 11a to 11c, the seat 3 has properties which are resilient in particular in the direction A. An advantage of these seat devices 1 can be seen in the fact that they can be designed to be very light and elegant, and the seat 3 has pleasantly resilient properties. The spring properties could be determined, for example, by a spring 4 selected with corresponding spring properties. Of course, it is also possible to provide an arrangement as shown in FIG. 5 for the adjustable limitation of the spring travel in order to set the spring characteristic of the spring 4. There is also the possibility, particularly in the seat 3 and / or the backrest 5, of installing additional springs, in the plastic on the appropriate fibers are arranged in a suitable location, and the thickness of the plastic is selected accordingly, so that a desired local spring property results. The seat 3 and / or the backrest 5 can, for example, have surfaces with different local spring properties in order to increase the seating comfort or to improve the ergonomic properties of the seat device 1.

Claims (18)

Seat device (1) for dynamic sitting, comprising a seat frame (2) and a seat (3), characterized in that the seat (3) is connected to the seat frame (2) via a spring element (4) made of fiber composite material such that the seat (3) is movable with respect to the seat frame (2), in particular movably mounted on all sides, and that the spring element (4) is firmly connected both to the seat (3) and to the seat frame (2). Seat device according to claim 1, characterized in that the fiber composite material comprises glass fibers, and in particular consists of glass fibers and a matrix of thermoset or thermoplastic. Seat device according to claim 1, characterized in that the fiber composite material comprises natural fibers, and in particular consists of natural fibers and a matrix of thermoset or thermoplastic. Seat device according to one of the preceding claims, characterized in that the fibers are arranged in a directed manner, running parallel in the fiber composite material. Seat device according to one of claims 1 to 4, characterized in that the spring element (4) has a progressive displacement-force characteristic. Seat device according to one of the preceding claims, characterized in that the spring element (4) is designed in the form of a strip. Seat device according to one of the preceding claims, characterized in that the spring element (4) is rectilinear or curved, or is S, Z or C-shaped. Seat device according to one of the preceding claims, characterized in that the spring element (4) has a thickness between 1 and 5 mm. Seat device according to one of the preceding claims, characterized in that a displaceable spring travel limiting means (8) is arranged to act on the spring element (4) in such a way that the force-travel characteristic can be influenced. Seat device according to one of the preceding claims, characterized in that the seat (3) is a seat shell (3a) and a seat cushion (3b), the seat shell (3a) being connected to the seat frame (2) via the spring element (4). Seat device according to claim 10, characterized in that the spring element (4) forms part of the seat shell (3a) and in particular is cast with the seat shell (3a). Seat device according to one of the preceding claims, characterized in that the spring element (4) has a height between 0 mm and 25 mm. Seat device according to one of the preceding claims, characterized in that an additional partial component of the seat device (1) such as an armrest (5b) or a backrest (5) via a spring element (4) made of fiber composite material with the seat frame (2) and / or the seat (3) is connected. Seat device according to one of the preceding claims, characterized in that the seat (3) and the seat frame (2) are connected via a C- or U-shaped spring element (4), the spring element (4) on that side of the seat (3 ) is arranged, on which the knees are located. Seat device according to claim 14, characterized in that the spring element (4) extends above the seat (3) and the seat frame (2). Seat device according to claim 14 or 15, characterized in that the seat (3), the spring element (4) and at least part of the seat frame (2) are formed from one part and from plastic. Kit for a seat device according to one of the preceding claims, comprising a plurality of spring elements (4) with different force-displacement spring characteristics. Use of a spring element (4) made of fiber composite material for a seat device (1) according to one of claims 1 to 16.

Images