WO2010066409A1

WO2010066409A1 - Seat apparatus with a moving seat surface

Info

Publication number: WO2010066409A1
Application number: PCT/EP2009/008786
Authority: WO
Inventors: Daniel Baumgartner
Original assignee: Eth Zurich
Priority date: 2008-12-09
Filing date: 2009-12-09
Publication date: 2010-06-17
Also published as: EP2381816A1; EP2381816B1

Abstract

An apparatus (30) for dynamic seating has a moving seat surface (21). This seat surface has at least one rotation axis (25) in the region of the thoracolumbar spine. The rotation axis (25) is linked to a bearing support device (22) and is at least a horizontal rotation axis (25) which is in the median plane, which is predetermined by the seat surface (21), of a user who is sitting on the apparatus.

Description

Seating device with movable seat

Technical field of the invention

The invention relates to a seat device for dynamic sitting with a movable seat according to the preamble of claim 1.

Technical background of the invention

From the prior art chairs with moving, tilting to the side seats are known. Corresponding examples are shown on the market and in FIGS. 1 to 3. These are, for example, schematic representations, which include the "Pending Chair" of bio-med GmbH, the Schwipp of Schwipp Sitzmöbel, the Swooper by Aeris, and HSB and Ergo Topp of the HSB Büroservice Gruppe.An option is also a translatory one Component in the movement through a two-armed chair, depending on the body movement, as shown in Fig. 2. The pivot points are located respectively below the seats of the chairs.

Some movable chair designs have integrated the axis of rotation directly at the level of the seat, as shown in FIG. This solution causes tilting and tilting of the pelvis and the spine, which is compensated with the upper body by an opposite inclined position to maintain the balance. Relative to the work table results in a lateral displacement and additional immersion of the upper body, which adversely affects the work process. To reach a deflected position, it is necessary to shift body mass to the side in order to initialize the dynamics of the chair. Fig. 5 shows the spine conditions in a lateral translational movement of the seat and Fig. 6 shows an adjustment of the spine of a user at a pivot point below the seat.

In this context, scientific studies have been made with seating devices with actively moving seating surfaces. The positive influence on parameters such as sitting comfort and back pain / pain perception was examined in comparison to a control group. In a clinical study, the influence of an actively controlled seating principle was examined, where a rotational movement of the seat around a vertical axis took place. In addition, the length of the spine was measured before and after application of the active stool. It was by an electric motor certain range of motion in and a certain frequency (0.8 ° rotation, 5 times per minute) given so longitudinal spinal structures are moved through. In this context, the term "Continuous Passive Motion" CPM has been defined.

It could be shown that there was no tendency to increase pain in persons with back injury, but it did not lead to a significant improvement. On the other hand, it was possible to show an extension of the spine, which occurred in comparison with static sitting after the use of a movable chair.

This result was explained by the fact that increased movement of the vascular system caused increased internal disc pressure due to movement. (It is known that with higher fluid flow in the avascular disc, the exchange of proteins is higher and the proportion of water increases as a result of diffusion (Kraemer, J., D. Kolditz, et al. (1985) Spine 10 (1): 69-71.) Instead of a length reduction of 0.75mm in static sitting, the average length of the column (8 subjects) was 0.5 mm (van Dieen, JH, MP de Looze, et al. (2001). "Effects of dynamic office chairs on trunk kinematics, trunk extensor EMG and spinal shrinkage." Ergonomics 44 (7): 739-50.)

Van Deursen has shown reduced height loss of the spine on movement in three studies in 1999 and 2000, possibly suggesting better protein supply (van Deursen, DL, RH Goossens, et al., 2000) and Ergon 31 (1): 95-8.), and a slight reduction in back pain when using an active mobile chair (van Deursen, DL, M. Lengsfeld, et (2000). "Mechanical effects of continuous passive motion on the lumbar spine in seating." J Biomech 33 (6): 695-9.) and the mechanical effects of a rotational, tilting seat on the spine function and posture (Lord spine lordosis) (van Deursen, LL, J. Patijn, et al., 1999). "Sitting and low back pain: the positive effect of rotary dynamic stimuli during prolonged sitting." Eur Spine J 8 (3): 187-93.). Van Deursen applies a rotational movement around the longitudinal vertical axis of the spinal column, causing the spine to twist in its longitudinal direction. Overall, taking a long static sitting position has emerged as a risk factor for subsequent degenerative spine postural damage. (Balague, F., Troussier, et al., (1999) "Non-specific low back pain in children and adolescents: risk factors." Eur Spine J 8 (6): 429-38.)

An interesting finding resulted from the investigation of the 5th Biga report from the year 2008 of the Institute for Occupational Safety of the German Social Accident Insurance. The "ergonomic study of special office chairs" came to the conclusion that the dynamic principles of the chairs are not used at all and are not applied during the work process on the office table, suggesting that dynamic principles are not consciously activated, possibly due to disruption in work.

Another study is: Lengsfeld, M., I.R. Konig, et al. (2007). "Passive rotary dynamic sitting at the workplace by office workers with lumbar pain: a randomized multicenter study." Spine J 7 (5): 531-40; discussion 540.]

From DE 1 099 142 an armchair with a molded seat shell is known in which this comprises a round seat shell, which is arranged in a concentric bearing shell. Here are stored between the seat and the bearing shell balls that rest on springs. Sense of this arrangement is the consequences of the seat recess in the person's movements of the sitter; that is, the mobility of the seat recess of the chair should allow the occupant or better lying down to change a position without moving against the fabric of the seat. The document refers to a chair without the possibility of occupying an upright sitting position therein, and contains no information on the dimensions of the curvature of the seat pan.

A similar even more sparse disclosure takes the expert in DE 203 03 472, in which a seat is inserted into a frame with a circular opening for receiving the seat.

DE 89 14 349 Ul is a representative of the prior art, in which a seat is also rotatable about a transverse axis, but also indicates more adjustment options for other axes, but it should be noted that these axes are to be arranged below the seat , From DE 42 395 48 Al a chair with a tiltable about a transverse to the seat transverse axis seating surface is known, said axis is arranged above the seat in height and in the region of the pelvis, at the level of the vertebra Os sacrum.

From EP 1 090 568 B1, a chair with a seat surface mounted about a laterally pivotable axle is known, in which the instantaneous center MZ is shown at the level of the upper back with the associated projection track. With regard to the spine, the pivotable axis is located in the region of the thoracic vertebra Th3 to Th6.

Summary of the invention

Existing office chairs allow for mobility in flexion and extension (lateral plane motion), however lateral tilt of the seat (which induces lateral flexion on the spine) is not released. Due to the static position and low level of activity on the office chair for a long time, a reduced diffusion rate in the intervertebral disc is evident. The discs are depleted of nutrients and there is a risk of accelerated degeneration.

For this reason, efforts are being made to revolutionize static sitting through mobile, dynamic sitting. However, previous solutions do not allow easy lateral deflection of the seat with respect to the frontal view of the seated person. The invention shows a simple construction which allows such a deflection.

Dynamic sitting counteracts this circumstance. The lateral trunk musculature becomes more dynamic, this induces a higher vascularization in the surrounding tissue. In addition, the novel seat concept is designed so that the rotation of the chair is at the height of the spine. The mechanical center of rotation of the chair thus coincides with the physiological center of rotation. The consequence of this is that the freed-up degree of freedom follows a pelvic movement and the calm upper body does not affect the work process (in office chairs) or the vehicle guidance (in the case of motor vehicle drivers). The movement releases and loads the buttocks in an alternating manner, so that the pressure points are relieved. In contrast to the prior art, the device according to the invention applied a movement with a lateral deflection or lateral inclination of the spine, which is also called lateral flexion in the literature.

The dynamic sitting device has a movable seat. This has at least one axis of rotation in the region of the thoraco-lumbar spine. The axis of rotation is connected to a supporting support device and is at least a horizontal axis of rotation which is in the median plane of a seated user on the device.

Brief description of the drawings

The invention will now be described with reference to drawings, with which a

Embodiment of the invention will be explained. Show it:

Figures 1 to 3 are a graphic representation of prior art chairs with movable side-tipping seating surfaces; 4 to 6 are graphs showing the position of centers of rotation in chairs of the

Prior art; Fig. 7 is a schematic representation of a chair according to a first

Embodiment of the invention; Fig. 8 is a schematic representation of a chair according to a second

Embodiment of the invention; Fig. 9 is a schematic representation of a chair according to a third

Embodiment of the invention; Fig. 10 is a schematic representation of a chair according to a fourth

Embodiment of the invention; Figures 11 & 12 are schematic representations of a chair with modifications based on the fourth embodiment of the invention; 13 shows a schematic illustration of the mounting of a seat surface on ball bearings according to a fifth embodiment; 14 shows a schematic illustration of the mounting of a seat surface on rolling cylinders according to a sixth embodiment; 15A to 15C is a schematic representation of the storage of a seat with

Shells according to Fig. 14; Fig. 16 is a schematic representation of a chair according to a seventh

Exemplary embodiment of the invention; Fig. 17 is a schematic representation of a chair according to a eighth

Exemplary embodiment of the invention; and FIG. 18 is a schematic representation of a chair according to a ninth

Embodiment of the invention.

Detailed description of an embodiment of the invention

Figures 1 to 3 show a graphic representation of three prior art chairs with movable side-facing seats. These are common that they include a lateral tilt. The axis of rotation is indicated in each case by the reference numeral 25.

Figs. 4 to 6 are graphs showing the position of centers of rotation in chairs of the prior art.

The seat has received the reference numeral 1. The illustrated spine 2 of a user of the chair shown is bent in the left representation relative to the median axis 3. There is the center of rotation, represented by the circle around the point 4 at the height of the seat 1. In the middle of a lateral displaceability of the seat 1 of the chair is shown, resulting in a lateral S-shape of the spine posture 2 to the upper body in to keep the existing median axis 3.

Finally, a center of rotation 4 is shown below the seat 1 on the right, resulting in a straight spine 2 with an inclined orientation in the direction of the new median axis 3 of the user's body.

The invention is based on a modified so-called mobilized seat principle. FIGS. 7 to 10 show four embodiments of chairs 10, 20, 30 and 40 according to the invention. The chairs shown have a spider base 11 with castors, but can also have a base without castors as in chair 30. It is clear that the foot shape of the chair is immaterial to the function described below. The chair shown in Fig. 7 has an S-shaped bent chair leg 12, so that the center of the seat 21 is above the center of the foot 11. The attachment of the seat 1 on the chair leg 12 will be explained below.

The chair 10 of FIG. 7 does not use a backrest. The seat 1 consists of a horizontally illustrated plate 21 which is integrally formed with a polygonal, in the upper part triangular transition piece 23 which is aligned substantially perpendicular to the plate 21 and thus parallel to the longitudinal axis of the chair (26 in Fig. 10) , This transition piece 23 comprises a bearing 24, whose axis 25 is aligned parallel to the plate 21 and via a corresponding bearing pin (not shown) is connected to the chair leg 12. Thus, the anterio-posterior axis of rotation 25 is aligned above the seat formed by the plate 21, namely, the arrangement is provided at the level of the area of the thoraco-lumbar spine of a user.

In Fig. 8, the backrest 5 is fixedly mounted on the axis 25 on the chair leg 12, so that only the seat 1 is rotatably attached to the seat surface 21 and the transition piece 23 about this horizontal axis 25 of the chair 20. The back of the user leaning against the backrest 5 receives a support in the upper area above the axis of rotation 25, so that it does not rub against the backrest 5 even when the seat surface 1 is moving. Advantageously, then the backrest 5 is not as long as shown in Fig. 8, but shorter, so that no back contact with the back 5 in the rotating region of the spine below the axis of rotation 25 can occur. The axis of rotation 25 is a sagittal axis and therefore runs horizontally from front to back in relation to a user intended for sitting on the chair and lies in the sagittal plane.

The new, inventive position of the center of rotation is primarily the pelvis and the lumbar spine 2 of a user sitting on the chair rotate, the upper body remains stable during work and the work process is not disturbed by the movement. To move the center of rotation of the seat upwards (Figure 7), it is necessary to support the seat surface on a lower fixed surface.

The invention therefore involves a movable seat 21 of a dynamic sitting concept such that movement of the seat 21 is spatially defined Rotational movement that is in line with the center of rotation in the area of the thoraco-lumbar spine.

The movable seat 21 is designed so that a person sitting on it can induce the spatial movement by a muscular contraction, without the self-weight from the going through the center of gravity vertical axis of the upper body to trigger the movement must be moved decentrally and the center of gravity of Upper body remains in the longitudinal axis of the spine.

The inventive chair design requires the activation of the lateral spinal muscles, so that a rotation of the seat is triggered. These new kinematic conditions are achieved by changing the position of the center of rotation of the seat. In comparison with existing movable chairs, the center of rotation 25 of a chair design 30 according to the invention is located, for example in the third exemplary embodiment of FIG. 9, in which the chair leg is simply oriented straight vertically above the seat 21, approximately at the level of the intervertebral discs L3 to ThIO, advantageously in the range Ll to L3 or L2-L3. This results in a more stable position, especially in a deflected state of the seat 21. To reach the normal sitting position again, no muscular force must be expended, the initial position is automatically after relaxation again. In other words, the suspension of the seat 21 is arranged by the transition piece 23 or the strut 33 at a distance from the axis of rotation, that this distance means for a user that the intervertebral discs L2-L3 are equal to the axis of rotation. This advantageously means a distance between 20 and 30 centimeters above the seat 21, in particular above the center of the seat, if this is flat.

Fig. 10 shows a fourth embodiment of the invention, wherein in the chair 40, the backrest 5 is inserted into the chair leg 12 in a manner known to those skilled, but above the center of rotation 25. Thus, the seat 21 can pivot freely about the axis 25 while the back of the user above the axis of rotation 25 finds a fixed support in the backrest 5. Here there is no backrest portion below the axis of rotation 25th In particular, the foot 11 is configured symmetrically with respect to a vertical longitudinal axis 26 of the chair. In some embodiments, the supporting support 12 has an S-shaped chair leg which begins in the symmetrical leg and then pivots out of the axis to receive the pivot 24 in another section parallel to the vertical longitudinal axis 26. In this case, the axis of rotation 25 and the longitudinal axis 26 intersect at a point that lies in the median plane of a person using the chair and in the frontal plane of this person with respect to the upper body (ie without extremities beyond the pelvic area). By this L-shape of seat 21 and a triangular connection with the pivot bearing 24, either as a solid surface 23 or in the form of triangular converging on the pivot bearing struts (not shown), creates a chair easy to manufacture.

Advantageously, either different models with different distances for different sized people or the transition piece 23 is adjustable in its length. A corresponding exemplary embodiment is shown in FIG. 11 with the chair 50. It is essential that said distance of an arrangement of the axis of rotation (or of the pivot point according to further exemplary embodiments presented below) is in the region of the thoraco-lumbar spine of a user. In this case, the transition piece 23 consists of two separate sections 35 provided with a rib toothing: the section mounted in FIG. 24 can have a fixed hole or threaded hole, while the opposite section 35 connected to the seat surface 21 has a sequence of superimposed holes, then that by a locking pin 36 or a corresponding screw in the corresponding hole of the portion 35 of the seat, the two sections are connectable. Thus, then the distance of the seat 21 to the axis 25 on the distance from the seat to the area of the spine L3 to ThIO or L2 / L3 of the user adjustable. Other embodiments are possible, such as a telescopic extension, for example, with bayonet lock. It should be noted that this extension can be used and combined not only in the exemplary embodiment of FIG. 12 but also with all other exemplary embodiments. Therefore, the same or similar features are denoted by the same reference numerals in all figures.

Thus, an embodiment is shown in FIG. 11, which is realized by suspending an L-shaped seat surface 21, 23 at the level of the belly button of a user by means of a rotary bearing 24. The user is advantageously symmetrical to Longitudinal axis 26 of the chair on the seat. The location of the fulcrum on the vertical surface 23 of the L-profile can be varied so that the height of the fulcrum of the spine is also adjusted. Decisive is the vertical distance between bearing 25 and seat 21, which induces the center of rotation at a corresponding height of the spine. This pivot bearing 25 can thus be adapted to the individual sizes of the respective user and to his needs.

Fig. 12 shows another feature which can be applied or combined individually with the other features of the various embodiments. Due to the bearing 24 on the axis 25, a load on the seat 21 user generates a torque which loads this camp. For this purpose, an opening may be provided in the chair leg 12, in which a wheel 37 is rotatable about a vertical axis 39 through corresponding bearings 38. The wheel 37 is dimensioned so that it is supported on the back of the transition piece 23. Thus, the main load of the moment is transmitted via the wheel 37 in the chair leg and not only charged the bearing 24. Instead of a wheel may also be provided a ball which is held with a smaller diameter than the ball having cover in said cavity. Finally, for example, three such wheels may be provided in the then wider designed chair leg 12, wherein the axes 39 of the other two wheels are oriented so that they are viewed from the front of the chair inclined, a plane parallel to the main plane of the transition piece 23 and span the axes intersect in the axis of rotation 25.

13 shows a schematic representation of the mounting of a seat surface 21 on three ball bearings 34. On the ball bearings 34 rests a correspondingly curved bottom 43 of the seat pan 21. The curvature of the seat is such that it corresponds to a spherical shell having a ball center, the is at a distance from the seat 21, so that said ball center is, for example, in the region of the intervertebral discs L2-L3 of a user of the seat. The difference from the embodiment of FIG. 11 is the fact that the seat surface does not rotate about a horizontal axis of rotation arranged in the said distance, but about a pivot point arranged at said distance. If the user executes only a sideways movement, the movement of Ausführungsbeispicls according to Fig. 11. But there are also movements perpendicular to this possible, ie a rotation about a horizontal axis which is aligned perpendicular to the axis 25. Due to the ball bearing these movements of the seat are freely superimposed. FIG. 14 shows, together with FIGS. 15A to 15C, a further embodiment of a seat 21 of the invention, the solution consisting of the mounting of two adjoining curved shells 41, 42. The upper shell is the seat pan 41, the lower shell the bearing shell 42. The shells are shown in cross-section, so that they are a shell of cylindrical surfaces. The intermediate bearing consists of bearing rollers 45, thereby allowing the displacement of the upper shell 41 relative to the lower 42. The mutually moving convex outer surfaces of the shells may represent segments of a cylinder, cone or a ball, wherein the movement in a cylindrical surface (as shown here) is predetermined in one direction; when using a sphere, they can be combined in two main directions. Advantageously, there are two bearing rollers 45, although three or more bearing rollers would be possible if they were somewhat resilient, which would cause a friction effect in the inclination and the provision of the shell 41.

Fig. 15A shows the seat 21 in a rest position, in Figs. 15B and 15C in a left and right, respectively, deflected position. The cylindrical rolling bodies 45 are inserted in principle loosely between the shells 41 and 42. On the upper side 53 of the lower shell, in each case the free ends of two bands 46 with respect to the rolling bodies 45 are fastened on both sides of the center of the seat surface. The bands 46 are then tangential to the lateral surface of the respective rolling body 45 and led to this around. The opposite free ends of the bands 46 are fixed on the underside 43 of the seat 41 relative to the other free ends. Centered with respect to the longitudinal direction of the rolling body 45, the two free ends of a further tension band 48 are arranged on the underside 43 of the seat shell, which is guided in the opposite direction with respect to the other bands 46 around the rolling body 45 around. By the choice of flexible stretchable bands 46 and 48 and a suitable choice of attachment points and tape length, the rolling bodies 45 can be kept under tension. This results in the rolling between the upper and lower part of the chair during stabilization of the rollers on a predetermined path between the concave inner side of the lower part and the convex outer side of the movable part. In the cross-section of FIG. 15, the band 48 is not shown as a continuous band, which may then not be attached to the bottom 43 of the seat 21, but is attached only at the two free ends on the top 53 of the lower shell 42. The band 48 is shown in FIG. 15 as two central bands to show that by the rolling of the cylinder 45, the bands 46 and 48 be moved against each other so that they roll up or down the length with respect to their free ends and thus a low-friction movement of the seat is realized on the cylinders.

If the at least one further band 48 of the two rolling bodies 45 is a one-piece continuous band, its free ends are fastened either only to the underside 43 of the seat shell 41 or to the upper side 53 of the bearing shell 42 and otherwise in one piece to the upper side 53 or the underside 43 led. In an arrangement with respect to the upper side 53, the band generally does not run directly against it due to the curvature of the bearing shell 42, but is stretched between the two rolling bodies 45. The adjustment of a bias of the bands 46, 48 simplifies the functionality of the low-friction tilting movement of the seat 21.

A further embodiment can be realized in that a movable upper part is arranged relative to the fixed chair lower part, wherein the position of the upper movable and lower fixed part is defined by rolling bodies. Preferably, the movable upper part may take on the shape of spherical cutouts, cylinders or cones on its convex underside, so that the superiore position of the center of rotation results from the radii of these shapes.

On the lower shell are said rolling bodies. These rolling elements can be two cylinders. It may also be that these rolling elements are slightly conical truncated cones, which are oriented opposite. That is, the thicker end portion of one rolling body opposes the thinner end portion of the other rolling body. In other words, the cylinders 45 of FIGS. 14 and 15 may also be other bodies of revolution enabling a rolling behavior.

The rolling elements between the upper and lower part are designed so that they roll when moving the movable upper seat relative to the lower fixed part of the chair without resistance. To ensure that the rolling elements slide smoothly between the upper and lower parts of the chair during rolling on its predetermined path between the concave inner side of the lower part and the convex outer side of the upper moving part, they are fixed by straps or ropes. In the solutions according to the invention, the mobility through the movable seat can be controlled and, depending on the intensity, can be controlled by the user himself through his muscular work. Unlike existing designs, body mass must be used. An alternating relief of the left and right side of the gluteus maximus animates to relaxed back and pelvic structures and contributes to an alternating shift of weight in the buttocks.

16 and 17 show a schematic representation of the mounting of a seat surface 21 according to two further embodiments of chairs 70 and 80. This embodiment of the seat shells 21 use the same rotation principle. In Fig. 16, the lower bearing shell 42 is a straight horizontal surface, whereas the lower surface 43 of the upper seat shell 41 is round. The cylindrical bearings 45 in between allow the rolling motion of the seat pan. Here, the actual seat 21 is flat and flat. The rolling movement is realized as shown in FIGS. 14 and 15 with bands 46 and 48. In contrast, according to FIG. 17, the lower sliding surface 42, in particular its upper side 53, is round, and the upper shell 41 is straight, in which case wheels or cylinders 45 are fastened to the seat shell 41 via bearings. The reference numeral 25 in each case the axis of rotation is marked.

Finally, FIG. 18 shows a schematic perspective view of a chair 90 according to a further exemplary embodiment of the invention. In this case, a centrally arranged and horizontally extending fork 91 is fixed to the support means 12, which is branched into two arms 92. On each of the two arms 92, two ball bearings 93 are arranged in a longitudinal distance of the arms. In this ball bearing 93, the curved at least on the bottom 43 seat 21 is placed, which is shown here transparent. The curvature of the seat 21 is such that a lateral movement of the seat 21 is possible, whereby by the curvature in the support surface, a pivoting about a horizontal axis is achieved, which is arranged in a range between 20 and 40 centimeters above the seat 21. For a user, this corresponds to a lateral tilt about a horizontal axis at the level of the vertebrae L3 to ThIO. Here it is essential that the seat has the corresponding curvature; a direct adjustability is given only by replacing the seat shell 41, namely against a seat shell with a different curvature 43 of its underside. In order to integrate this embodiment in a chair, a correspondingly curved slot can be provided in the back of the seat surface 21, through which the horizontally extending arms 92 pushed. The seat 21 may be closed at the bottom by a likewise correspondingly curved shell.

The positions of the upper movable and lower fixed parts are defined relative to one another via the said rolling bodies 45 such that sliding friction-free, unresisting rolling of the two parts takes place relative to one another by means of the rolling bodies.

The advantage of selecting the axis of rotation 25 in the region of the spinal column sections L3 to ThIO or advantageously L2 to ThI l or L3 to L2 or in the range between Thl2 to Ll is that the lateral inclination or lateral bending of the spine, which in the vertebrae from Sl up into which L-vertebrae is large, first in the area L2 / L3 falls sharply. Thus, when the axis of rotation is arranged in this region, a large range of motion ROM (for ranks of motion) remains in the combination of flexion / extension with axial rotation, which surprisingly has a positive effect on tension in the area of the thoraco-lumbar spine. At higher pivot point (as in the prior art in the field of vertebra Th3 to Th6), this positive effect is lost. Essential here is the effect on the living human, a comparative study for humans and calves with respect to in vitro experiments is in "Bicomechanical Comparison of Caif and Human Spines" by Hans-Joachim Wilke et al., In Journal of Orthopedic Reseaerch 14: 500-503 to find.

As advantages over the prior art, it should be pointed out that the position of the center of rotation at the level of the spinal column, more precisely at vertebra Thio to L3, in particular between L1 and L3 and also between L2-L3, has some specific biomechanically improved properties compared with the prior art Technique result:

- The rotation of the seat is controlled by muscular contraction and not with displacement of body weight as in previous principles. For this purpose, the lateral trunk musculature is activated, in particular M. obliquus ext./int. abdominus, and M. transversus abdominus.

- The upper body with the entire shoulder area is at rest when the movement of the seat is performed. The shoulder girdle remains at the same height - the arms and the head are thus not mobilized. There is thus virtually no relative movement between the shoulders / arms and work table instead; the work process remains undisturbed. - The deflected seat automatically returns to its original state without the user having to exert any force and is therefore self-stabilizing.

- The physiological center of rotation of the upper body is in accordance with the technical axis of rotation of the chair, and therefore congruent with each other. There is a movement that the spine performs under everyday movements, unless it is restricted by a mechanism such as a chair.

As potential users can be mentioned:

- Sitting office workers

The office work is clearly a risk factor, because of the static position early on to get back pain. For that reason, preventative measures are necessary and counteract increased mobility while sitting an accelerated degeneration.

- AlIg. Industrial worker with a quiet working position

Examples of this are people who have to take a quiet job. Analysis of samples (laboratory), as well as eg. Assembly of small components (watchmakers).

- Car driver

Long journeys by car can have a negative impact on the spine. The static position in the car seat results in pressure points on the muscles. The muscles are also inactive for a long time and not moved. Even a slight movement results in a relaxation of the dorsal structures.

- Public transport users

Long distance users (car trips, flights, trains) often use long-lasting static seating positions. The circumstance of reduced blood circulation combined with a reduced fluid intake increases the risk of thrombosis.

Furthermore, such a chair can also be used for patients in the field of regenerative medicine.

- Patients with cerebral palsy

Patients with partial paralysis of the spinal column often suffer from decubitus - an occurrence of pressure sores due to prolonged sitting. With the help of the rotation of the chair, a rearrangement of the body weight can take place, which relieves damaged areas.

- Spastic Paraplegics with incomplete paraplegia often exhibit spontaneous, twitching

Movements - so-called spasms on. It has been shown that such spasms can be better controlled with rhythmic therapy. The chair can be a kind

Therapy form, as it also harmonious regular movements can be performed.

- Patients with scoliosis

Around 80% of the population is at least affected by a slight scoliosis. heavier

Cases with severe curvatures of the spine in the frontal plane require therapeutic treatment. A dynamically controlled variable chair

Adjustment of the rotation center is able to apply the appropriate kinematic conditions during therapy.

Bezugszeichenhste

1 seat

2 spine of a user

3 median level

4 turning center

5 backrest

10 chair (first embodiment)

11 spider foot

12 S-shaped chair leg

13 Extension of the chair leg

20 chair (second embodiment)

21 seat surface plate

22 chair leg

23 transition piece

24 bearings

25 axis of rotation

26 longitudinal axis of the chair

30 chair (third embodiment)

33 Transition brace

34 ball bearings

35 rib teeth

36 locking pin Wheel Wheel Bearing Wheel Rotary Axis Chair (Fourth Embodiment) Seat Seating Cup Bottom of Seating Cup Bearing Tape Band Seating Area of a Chair (Fifth Embodiment) Top of Bearing Seat of a Chair (Sixth Embodiment) Chair (Seventh Embodiment) Chair (Eighth Embodiment) Chair (Ninth Embodiment) Fork arm ball bearing

Claims

claims

A device (10) for dynamic sitting comprising a supporting support means (1 1, 12) to which a movable seat surface (21) is connected, wherein the connection of the seat surface (21) with the support means (1 1, 12) for a Rotation of the seat (21) is designed at least about a horizontal axis of rotation (25). which lies in the predetermined median plane of a user sitting on the device, characterized in that the axis of rotation (25) above the seating surface is in the area of the thoraco-lumbar spine.

2. Apparatus according to claim 1, wherein the axis of rotation (25) in the height of the vertebrae L3 to ThIO, more preferably in the height of the vertebrae L2 to ThI 1 or in the height of the vertebrae L3 to L2 or in the amount of vertebra Th 12 to Ll is provided, in particular in a vertical distance between 20 and 30 centimeters above the seat surface (21) is arranged.

3. Apparatus according to claim 1 or 2, characterized in that the spine is supported by a stable, non-moving part, in particular a backrest (5) of the device.

4. Device according to one of claims 1 to 3, characterized in that the movable seat surface (21) and the stable part of the chair (supporting support means) (1 1, 12) by a located at the level of the thoraco-lumbar spine pivot bearing ( 24) are connected.

5. Device according to one of claims I to 4, characterized in that the movable seat surface (21) in the lateral cross section has an L-shaped design, wherein the horizontal part is used as a seat surface (21), and the frontal, in particular vertical surface (23) includes a bearing to the stationary part (12).

6. Device according to one of claims 1 to 5, characterized in that a Höheneinstellbarkeitseinrichtung (35, 36) for adjusting the distance of the pivot bearing (24) to the seat surface (21) is provided in the relative height position, so the height of the center of rotation (25) is displaceable relative to the trunk of a respective user and adaptable to the individual needs of the user.

7. Apparatus according to claim 1, characterized in that a relative to the lower stable chair part (11; 42) movable seat roof part (21; 41) is arranged, wherein its position by a rolling body (34, 45) between the stable lower part (42) and movable upper part (41) is defined.

8. Apparatus according to claim 7, characterized in that the convex underside (43) of the seat surface part (21, 41) can be described with sections of spherical surfaces, cylinder surfaces or conical sections, so that the superiore position of the center of rotation (25) from the radii of these forms results.

9. Apparatus according to claim 8, characterized in that the underside of the seat is selectively mounted on individual rolling bearings (34, 45), wherein at least three roller bearings (34, 45) are fixed on the lower part of the chair to a stable position of To receive seat (21).

10. Device according to one of claims 7 to 9, characterized in that the two mounted shells (41, 42) represent each other cutouts or segments of a hollow sphere, hollow cylinder or hollow cone.

1 1. Apparatus according to claim 7, characterized in that the supporting rolling bodies (45) are held underneath on the inclined by its concave lower part by looping ropes / cords / straps in position.

12. Apparatus according to claim 10, characterized in that this rolling body during rolling between the upper and lower part of the chair by both sides tensile forces of the loops (in roll direction) stable on its predetermined path between the concave inner side of the lower part and the convex outer side of the upper movable part slides.

13. Device according to one of the preceding claims, characterized in that for two rolling bodies (45) are provided, between the seat shell (41) and bearing shell (42) are arranged, wherein at least one band (46) per rolling body (45) is provided. the free ends of which are fastened to the underside (43) of the seat shell (41) and to the top side (53) of the bearing shell (42) and are guided around the roller body (45) in abutment therewith, the attachment being opposite the other rolling body on the body the side facing away from the other rolling body on the side facing, and that at least one further band (48) per rolling body (45) is provided, whose free ends on the underside (43) of the seat shell (41) and on the Attached to the upper side (53) of the bearing shell (42) and around the rolling body (45) are guided around this, wherein the attachment relative to the other rolling body on the facing side and the leadership is opposite to the other rolling body on the opposite side.

14. Apparatus according to claim 13, characterized in that the at least one further band (48) of the two rolling bodies (45) is an integral continuous band whose free ends either on the underside (43) of the seat shell (41) or on the Upper side (53) of the bearing shell (42) are fastened and are otherwise guided in one piece on the upper side (53) or the underside,