The present invention relates to an active-dynamic chair in accordance with claim 1. The invention relates in particular to an active-dynamic seat device with a seat part for rocking and moving from a home position into a deflected position, it also being possible to perform forms of movement consisting of a combination and/or superposition of elliptical movements and rocking movements. Upon rocking and moving the seat out of its home position, the relative change in inclination of the seat part is influenced by the specific configuration of a three-dimensional linkage system.
Moving or active-dynamic chairs differ from static chairs in that the chair user who is sitting on the chair can while so doing perform movements of the trunk and the body together with the seat part, which is not possible with static chairs.
Human physiology prefers dynamic movements to static resting even when sitting. Chairs which bear the weight of the legs at the same time should not only permit dynamic movement, but also offer the seat user ergonomic support.
Seating furniture in most cases is equipped with correspondingly shaped seat surfaces and rests in a position which is anatomically as beneficial as possible, so that the body, in particular the back, is supported. Such seating furniture is frequently perceived as comfortable, but has the crucial disadvantage that the body sits merely passively, i.e. the back muscles are scarcely engaged and the intervertebral discs are subject to permanent compression. If these seat devices are used for a relatively long time, this may result in degeneration of the back muscles and wear on the intervertebral discs. Damage to the health and pain in the back and hip regions are frequent consequences of static or passive sitting.
For this reason, active-dynamic seat devices have been developed which allow what is called active dynamic sitting, in which the back muscles and the intervertebral discs are always slightly active. This active-dynamic sitting posture is achieved in practically all cases in that the actual seat of the seat device is held in an unstable position and can be rocked to and fro from a home position into a laterally deflected position by the seat user.
An active-dynamic pendulum chair of this type is known for example from DE 42 44 657 02. Therein, a generic seat device is described which consists of a foot part, an intermediate piece connected to the foot part, and a seat part which is rigidly connected to the intermediate piece, the intermediate piece being held in an opening in the foot part so as to be tiltable in every lateral direction by means of an elastically deformable connecting element, and in the unloaded state being returned into its neutral position (home position).
EP 0 808 116 B1 describes a self-aligning bearing which is arranged between the column and the foot part. The self-aligning bearing is formed as a rubber-metal swing connector and consists of a substantially tubular upper part, the upper end of which serves as a spline connection, a lower part which is fastened fixedly to an arm of the foot part, and a resilient material arranged between the upper part and the lower part. The self-aligning bearing allows the seat part to rock to and fro.
For example, U.S. Pat. No. 5,921,926 discloses an active-dynamic pendulum chair which is likewise based on the principle of an inverted pendulum. Such chairs have a defined path of movement and a structural restoring mechanism which at the same time have a protective device in order to prevent the chair from tipping over. However, the seat upon a rocking movement tilts backwards from the horizontal position into an inclined position pointing away from the centre of the body.
Such pendulum chairs make it possible for the seat to rock to and fro from the non-deflected starting position into various deflected positions, as a result of which the seat surface tilts from its horizontal position into an inclined position. The tilt angle in such case depends on the direction of the deflection and the degree of the deflection. For example, the seat in the case of a pendulum chair in which the horizontally attached seat is connected fixedly to a pendulum column which is movable to and fro inclines with increasing deflection of the column from its horizontal position into a distinct inclined position.
With the pendulum chairs known from the prior art, the degree of inclination of the seat follows exclusively dependent on the angle of deflection upon the rocking movement. In the home position, the seat as a rule does not exhibit any inclination; rather, the (idealised) seat surface is oriented parallel to the base surface. If the seat is now deflected out of its home position into any inclined position whatsoever, the seat surface inclines accordingly, since the seat is connected rigidly to the pendulum support. The greater the angle of the rocking movement, the greater the inclination of the seat surface. In such case, the seat inclines upon rocking to and fro from its home position into its deflected position, so that that region of the seat which in each case is located further to the outside relative to the home position upon rocking is lowered relative to the region located further to the inside. Thus the seat user, for example in the case of rocking movements backwards, ends up in a supine position, which is not pleasant for every seat user. In the event of excessive rocking movements, it might also happen that the seat user loses his balance. Depending on the different requirements of chair users, there is accordingly a need for pendulum chairs with a different, preferably settable, change in inclination. In particular, there are seat users who prefer a precisely opposite change in inclination when rocking outwards.
With the pendulum chairs known from the prior art, further merely rocking movements about a self-aligning bearing which is close to the ground can be performed.
Upon dynamic movements of a seated person, it is however desirable for him further to move his entire body including his trunk, similarly to a movement with a “hula hoop”, and in so doing to be able to perform both rocking movements “as such” and “lateral” deflections (i.e. horizontal translational movements) with the pelvis, in order to compensate for the transfers of weight of the upper regions such as arms and head and set them moving.
Departing from the prior art, it is therefore an object of the present invention to overcome the aforesaid disadvantages and to provide an active-dynamic chair with which the seat user can perform many different, safe movements of the seat part in the entire movement space. Advantageously, in so doing horizontal translational movements of the seat region by the chair user should also be made possible, and the change in the seat inclination should take place according to the ergonomic requirements of the seat user.
Further co-ordinate objects are:
a) Controllable horizontal rocking, translational and/or rotational movements of the pelvis of a seat user should be possible, upon which the seat is guided into a defined inclined position during the movements;
b) The chair should ensure an ergonomic sequence of movement;
c) The chair should have a restoring mechanism or a spring mechanism for returning to its initial position (home position);
d) The seat inclination in the home position should be able to be adapted individually.
This object is achieved by the measures described in the co-ordinate independent claims. Advantageous configurations of the invention are described in the respective dependent claims.
Further, the complete contents of the German patent application having the number DE 10 2013 102 034.8 are jointly incorporated by reference in the present application.
The basic concept of the present invention lies in the suitable attachment and arrangement of a three-dimensional (yielding) linkage system, preferably formed from three-dimensional four-bar linkage corners.
Therein, a three-dimensional linkage system consisting of at least three legs with foot parts at their lower ends is provided, wherein the legs in each case at their upper ends are mounted movably on the seat part on connecting articulations which are on the seat-part side, such that rocking and circular movements (and preferably also torsional movements) of the seat part can be performed with respect to its non-deflected home position.
In a preferred embodiment, at least three four-bar linkages are formed, with one four-bar linkage in each case being formed from in each case two directly adjacent legs, the seat part and the base surface, and the “coupler length” thereof being defined by the distance between the legs on the seat part, and the frame length thereof being defined by the distance between the legs on the base surface. The realisation of the linkage systems can accordingly be described equivalently in accordance with the principle of four-bar linkages. Thus the realisation of the three-dimensional linkage system can take place either by means of a plurality of movable chair legs, in particular pendulum chair legs (“legs” for short below) on the seat part. The legs in this embodiment are connected movably to the seat part at their (upper) connecting ends, not rigidly, but by means of a movable (preferably resilient) connecting articulation, so that three-dimensional rocking and circular movements and preferably also torsional movements of the leg connected thereto in each case relative to the seat part are possible. Preferably, three or four legs are connected to the seat part of the chair in each case with identical or similar connecting articulations. However, more than four legs may also be used.
In one alternative embodiment of the invention, the three-dimensional (yielding) linkage system may also be realised by means of flexible, elastically deformable legs which are fastened to rigid fastening elements on the seat part.
According to the invention, therefore, in its most general form an active-dynamic chair is provided which comprises the following: a seat part and a three-dimensional linkage system consisting of at least three legs with foot parts at their lower ends, wherein the legs in each case at their upper ends are mounted movably on the seat part on connecting articulations which are on the seat-part side, such that rocking and circular movements of the seat part can be performed with respect to its non-deflected home position.
In such a configuration, the positions of the connecting articulations span a common seat-part plane, by means of which the relative inclination of the seat part can be defined. In a preferred configuration of the invention, the legs are arranged symmetrically and the relative inclination of the seat part extends in a plane parallel to the base surface (on which the chair stands). In the non-deflected home position of the seat, the relative inclination of the seat surface is defined by the two polar angles (θ1, θ2), which are offset by the azimuth angle of 90°, of the normal to the seat-part plane which is as previously explained. Insofar as the seat-part plane is oriented parallel to the base surface, both angles are equal to 0°.
In one advantageous embodiment, the active-dynamic chair is configured such that each of the connecting articulations is formed as an articulation which permits rocking and circular movements of the leg which is connected thereto. Put another way, movements by a polar angle θ at different azimuth angles Φ with respect to the seat-part plane can be performed. It is particularly advantageous to form the articulations as resilient articulations, in order thus to obtain great mobility in various (three-dimensional) directions of deflection. It is even more preferable to provide an articulation with an elastically deformable articulation body which as a result of the elasticity provides an integrated restoring mechanism. In this way, the legs are coupled together mechanically via the common seat part. Two pairs of legs in each case can then be regarded as a four-bar linkage by the coupling to the seat surface, with the feet of the legs in such case bearing at defined points on the ground.
It is preferred if each of the connecting articulations is formed as an articulation of this type which permits a rocking and circular movement of the leg which is connected to the respective connecting articulation relative to the seat-part plane, and preferably such that the seat part can be deflected into a large number of different positions which can be described by a family of movement curves.
In a preferred embodiment of the invention, the inclination of the seat-part plane of the seat part changes upon movements of the seat part out of the home position into a deflected position such that that region of the seat which when performing movements is located further to the outside in each case is raised or lowered relative to the region located further to the inside.
Due to a desired pre-setting of the inclination of the seat surface of the seat part relative to the inclination of the seat-part plane, therefore, the change in inclination of the seat surface can be set by forming the leg length of the legs and their relative orientation accordingly.
A sequence of movement with a seat-part plane which is “raised up” towards the back upon deflection can be realised in that for example the legs are not oriented mutually parallel, but the foot points of two legs are further apart from each other compared with the upper connection points at the articulations. In this way, a four-bar linkage is formed from in each case two legs with the seat part and the base surface, the coupler (seat part) of which is shorter than the frame (base surface) thereof. It is preferred in this case, in the case of legs which are adjacent in each case, for the distance between their upper connecting ends in the seat-part plane to be less than the distance, close to the ground, between the respective leg ends between their foot parts. The foot parts may also be connected on a common footplate or a common ring element by means of connecting articulations, the degrees of freedom of movement of which are configured identically to the connecting articulations on the seat part. A form in which the inclination of the legs on the footplate and/or on the seat part is changeable is particularly preferable. This can be achieved by providing articulations which are adjustable in position. The foot parts may, in an alternative configuration, also stand directly on the base surface, where they are optionally additionally equipped with a slip-resistant end piece (for preventing shifting) or the like.
Alternatively, a sequence of movement in which the inclination of the seat-part plane does not change upon movement of the seat part, but rather the seat-part plane remains oriented parallel to the base surface and is merely lowered, can also be achieved by a parallel, preferably vertical, orientation of legs of equal length. In the case of legs of equal length, a symmetrical four-bar linkage is formed from in each case two legs with the seat part and the base surface. A four-bar linkage known from kinematics as a rule consists of a coupler, a frame and two connecting members. That means, transferred to the three-dimensional four-bar linkages in accordance with the present invention, that the seat part of the chair can be regarded as the “coupler” and the base surface as the “frame”, while the legs are to be regarded as connecting members.
In a preferred configuration of the invention, the linkage system is further equipped with a sprung restoring mechanism, so that the deflected seat part is returned automatically into its home position.
Advantageously, the restoring mechanism is integrated in the connecting articulations. It is therefore particularly advantageous to form the articulations as resilient (elastically deformable) articulations which upon deflection generate a restoring force if the chair leg is guided out of its home position into a deflected position. For example, the articulations may be formed as resilient rubber articulations which are elastically deformed upon movement of the legs and thus generate a restoring force. Alternatively, the “yielding” linkage system can also be realised by means of resilient legs.
There are further possible ways of advantageously configuring and developing the teaching of the present invention. For this, reference is made on one hand to the claims dependent upon the independent claims, and to the explanations of preferred embodiments of the invention set out below. Generally preferred configurations and developments will also be explained in conjunction with the explanation of the preferred embodiments of the invention with reference to the drawings. In the drawings:
a, 4b show views of a simplified model of two chair legs of a chair according to the invention in different positions;
c shows views of a simplified model of two chair legs of a chair in different positions in which the seat surface is inclined outwards;
d-4f show views of a simplified model of two chair legs of a chair according to the invention in different positions;
a shows a plurality of views and positions of an embodiment of a chair according to the invention with three legs similarly to
a-8c show a plurality of alternative embodiments of a chair according to the invention;
a-9b show two further alternative embodiments of a chair according to the invention;
A person 40 may, inter alia, perform the movements illustrated in
In
Upon a movement towards the rear (backwards) in the direction of the arrow R, as also shown in the lower right-hand view of
In the home position of the chair (the middle figure in each case in
a shows a model of a four-bar linkage 20 of a chair 1 according to the invention. The distance D2 (defined as in
If the chair 1 is deflected out of the home position into the supine position shown in the right-hand figure of
Alternatively, also different leg lengths can be used, since the leg ends with the articulations 5 are moved along different circular paths and the inclination of the seat part like-wise changes as a result.
Upon a movement of the seat part 2 in the opposite direction V forwards (upper left-hand figure of
b shows a model of a four-bar linkage 20 of a chair 1 in which the inclination of the seat part 2 remains constant. This results from the vertical symmetrical position of the legs and the identical upper and lower distance between the legs 3. This achieves displacement of the seat part 2 upon which the seat-part plane E, upon a movement into a position as illustrated on the left and on the right in
d to 4f depict further forms of movement of chair models similarly to the embodiments of
It can be seen that, in the positions of the legs 3 which are shown with a greater lower distance in the foot region at the foot parts 4, the seat inclination (as described in greater detail above) is inclined towards the centre. In this case, the seat-part plane E is raised in the outer region 2a, while the inner region 2i is lowered, as a result of which the seat part 2 tilts towards the centre.
However, the inclination of the seat-part plane E of the chair 1 of
In the figures of
In
c shows a special embodiment in which a sprung oscillating arm 11 bears the seat part 2, and on the lower end (close to the ground) thereof three vertically oriented legs 3 extend upwards in the direction of the seat part 2 and are connected there to a further spring arm 11 with a footrest 8. Each spring arm 11 forms a holding plate with connecting articulations 5, on which articulations the legs 3 are mounted in articulated manner.
In a further preferred embodiment, the connecting articulations 5 are provided on the seat part 2 and/or the footplate 8 so as to be settable, preferably radially displaceable or changeable in position.
In this way, the chair user can set the desired seat inclination and change in inclination individually.
Combinations of the embodiments previously mentioned and of individual features are also covered and are intended to be able to be claimed individually, as are alternative embodiments which are not explicitly mentioned. Thus for example instead of the rails 30 individual receiving positions can be provided on the foot part 8 and/or on the seat part 2 in order to be able to effect defined settings. Advantageously, these are lockable, adjustable in inclination and individually settable. Further, provision may be made for the legs 3 in their inclination relative to each other to be settable and lockable in inclination in a plane radially to the centre by an adjustment mechanism. It is particularly advantageous if the adjustment mechanism has a stop, preferably in a direction towards the front and towards the rear, or towards the inside and towards the outside.
Number | Date | Country | Kind |
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10 2012 110 032.2 | Oct 2012 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/061888 | 6/10/2013 | WO | 00 |
Number | Date | Country | |
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61658121 | Jun 2012 | US |