The invention relates to an apparatus in accordance with the precharacterizing clause of claim 1.
Apparatuses for balance training and/or fine motor skills training have at least one movable platform which can be moved in at least two dimensions in a rocking manner. Apparatuses are known with damping elements for damping movements of the movable platform, which damping elements are configured, for example, as plastic-encapsulated steel cables which fasten the platform in a hanging manner and have a damping effect on account of material properties of the plastic encapsulation. The known damping elements can be set merely very roughly and a dynamic change or adaptation of damping properties during operation of the apparatus is not possible.
It is the objective of the invention, in particular, to provide an apparatus of the generic type with improved properties with regard to adaptability of a damping action. According to the invention, the objective is achieved by way of the features of patent claim 1, whereas advantageous refinements and developments of the invention can be gathered from the subclaims.
The invention proceeds from an apparatus, in particular an apparatus for balance training and/or fine motor skills training, having at least one movable platform which can be moved in an oscillating manner in at least two dimensions, and having at least one counterforce unit which is provided to oppose a force for producing a deflection of the movable platform with a resistance. A “movable platform which can be moved in an oscillating manner in at least two dimensions” is to be understood to mean, in particular, a platform, preferably a flat platform, which is mounted in such a way, for example by means of suspension on a framework, that it can be deflected within a predefined deflection region at least along two directions in one plane which run perpendicularly with respect to one another, preferably a plane parallel with respect to a floor, on which the apparatus is set up, and which has a restoring means of the deflection to a rest position. In particular, in addition to the deflection in two directions in the plane, the movable platform can also be tilted in a direction perpendicular with respect to the plane or the movable platform can be deflected three-dimensionally by a rolling and tilting angle without a translational movement. The platform has a standing surface, on which a person stands who deflects the platform on account of his/her own movements and/or counteracts a deflection of the platform as a result of an external stimulus. The standing surface is preferably of flat configuration, but the standing surface can in principle also be configured to be curved or in other basic shapes which are different from a flat surface, for example hemispherical. The apparatus is provided, in particular, for use for training in order to reinforce the sense of balance or for a therapy for disruptions of the sense of balance. A “counterforce unit which opposes a force for deflection of the movable platform with a resistance” is to be understood to mean, in particular, a unit which is provided to oppose a force which leads to a deflection of the platform with a counterforce and thus to oppose a deflection of the platform with a defined resistance. To this end, the counterforce unit comprises, in particular, elastic elements which generate a restoring force, such as spring elements.
It is proposed that the apparatus has at least one force transmission interruption unit which, in at least one operating state, interrupts a force flow between the movable platform and the counterforce unit. A “force transmission interruption unit” is to be understood to mean, in particular, a unit which is provided to interrupt a force flow between the movable platform and the counterforce unit in at least one operating state, by the force flow being converted in the force transmission interruption unit in the at least one operating state into an action of force on the force transmission interruption unit, for example into stressing of a previously slack cable element or into an at least largely resistance-free extension of a piston as far as a stop. In particular, an operating mode of the apparatus can be realized by way of the force transmission interruption unit, in which operating mode a deflection of the movable platform from the rest position takes place substantially free of a counterforce within a provided initial region and, when the provided initial region is exceeded, the deflection of the movable platform is opposed by a counterforce by way of the counterforce unit, “Substantially free of a counterforce” is to be understood to mean, in particular, that an active counterforce provided for deflection of the movable platform is at most ten percent, preferably at most five percent and particularly preferably at most one percent of a counterforce by way of the counterforce unit. An operating mode can be achieved, in particular, in which no counterforce is generated in a part region of a deflection and a counterforce is generated in further part regions, in order to generate a high training effect by way of a high variability of the counterforce.
Furthermore, it is proposed that the counterforce unit has at least one central connecting element which runs at least partially along a zero axis of a rest position of the at least one platform for connecting the at least one platform to the at least one counterforce unit and for transmitting an at least two-dimensional movement of the at least one platform. A “zero axis of a rest position of the platform” is to be understood to mean, in particular, an axis which lies perpendicularly on a plane of the at least one platform and runs through a geometric center of the at least one platform in a rest position of the at least one platform. A “connecting element” is to be understood to mean, in particular, an element which is provided to transmit a deflection of the at least one platform from the rest position to at least one further element. The connecting element is preferably configured as a flexurally slack element. A “central connecting element” is to be understood to mean, in particular, that the connecting element is arranged at least in a region close to the zero axis of the rest position of the platform, is preferably fastened to a center point of a surface of the platform, and that the connecting element converts deflections of equal magnitude of the platform in directions which are opposite one another into an identical deflection. In particular, damping of movements of the platform can take place via the central connecting element by way of damping of a movement of the central connecting element. “Damping of movements” is to be understood to mean, in particular, that the movements are opposed by a counterforce, in particular a restoring force, with the result that a deflection of the platform which is achieved by an acting, deflecting force is smaller than a deflection as a result of the acting, deflecting force which can act in a manner which is free from damping. In particular, the central connecting element is provided to transmit the at least two-dimensional movement to the counterforce unit in a one-dimensional manner. In particular, a reduction in a number of required counterforce elements to generate a provided for deflections of the platform can be achieved.
Furthermore, it is proposed that the at least one force transmission interruption unit comprises at least one connecting element which, in the at least one operating state, is mounted at least partially in a stress-relieved state. The connecting element of the force transmission interruption unit is preferably formed by a cable element. A “stress-relieved state” is to be understood to mean, in particular, a state, in which the connecting element is tautened in the case of an action of force by way of a tensile force, for example by a cable element which lies in loops and/or lies slackly on a floor being stressed into a straight state and/or being raised up, or by a piston being extended as far as a stop. In the operating state, in particular, the connecting element which is mounted in the stress-relieved state is first of all tautened by way of a deflection of the platform, and the force flow is guided to the counterforce unit only after complete tautening. In particular, a counterforce unit can be achieved in a structurally simple manner.
Furthermore, it is proposed that the at least one central connecting element transmits the at least two-dimensional movement of the at least one platform to the at least one counterforce unit in a one-dimensional manner. In particular, a reduction in a required number of counterforce elements of the counterforce unit can be achieved.
Furthermore, it is proposed that the at least one counterforce unit has at least one movement conversion unit which converts a rotational component of the at least two-dimensional movement of the at least one platform into a rotational movement of the at least one central connecting element about an axis of its own. In particular, an amount of a translational deflection of the platform from the rest position remains as a deflection of the central connecting element. In particular, the rotational component of the movement of the platform is converted into a rotational component of a movement of the at least one central connecting element in a part region of the central connecting element, which part region is arranged between the at least one movable platform and the at least one movement conversion unit, and said rotational component of the movement of the central connecting element is converted into a rotational movement of the central connecting element about the axis of its own. In particular, the at least two-dimensional movement of the platform is therefore converted into a one-dimensional movement of the central connecting element. A “movement conversion unit” is to be understood to mean, in particular, a unit which is provided for converting a movement in a rotational or translational direction into a movement in another rotational or translational direction. The movement conversion unit is preferably provided to reduce a dimensionality of a movement, by, for example, a two-dimensional movement with a rotational component being converted into a purely translational movement in one dimension. The movement conversion unit preferably comprises an element, about which the central connecting element can rotate, in order to convert the rotational component of the movement into a rotation about the axis of the central connecting element. In particular, a reduction in a number of required damping elements can be achieved, by only a translational deflection of the platform from the rest position still having to be opposed with a resistance.
Furthermore, it is proposed that the at least one movement conversion unit has at least one sleeve or at least one bore with a rounded opening. In particular, the sleeve or bore with a rounded opening is provided to convert a rotational component of a movement of the central connecting element into a rotation about the axis of its own of the central connecting element, by the central connecting element rotating about a contact point with the sleeve or bore at the rounded opening. In alternative refinements, in principle, the opening can be formed by a sharp-edged opening instead of a rounded opening. In particular, a structurally simple movement conversion unit can be achieved.
The at least one central connecting element is preferably formed at least partially by a cable element. A “cable element” is to be understood to mean, in particular, a flexurally slack elongate element which consists of natural or artificial fibers or of metallic wires, the fibers or wires being twisted, which element is provided for a transmission of tensile forces. In particular, the cable element is formed from a steel cable comprising steel wires. In particular, a cable element can have a coating, a sleeve or an encapsulation made from an identical or different material than a material of the fibers or wires. In principle, the central connecting element can be formed at least partially by a chain element. In particular, a central connecting element which can be produced simply and is inexpensive can be achieved.
Furthermore, it is proposed that the at least one counterforce unit has at least one spring element. A “spring element” is intended to mean, in particular, a macroscopic element which, in a normal operating state, can be changed elastically in at least one length by at least 10%, in particular by at least 20%, preferably by at least 30% and particularly advantageously by at least 50%, and which generates in particular a counterforce which counteracts the change and is dependent on a change in the length and is preferably proportional to the change. A “length” of an element is to be understood to mean, in particular, a maximum spacing of two points of a perpendicular projection of the element onto a plane. A “macroscopic element” is to be understood to mean, in particular, an element having an extent of at least 1 mm, in particular of at least 5 mm, preferably of at least 10 mm and particularly preferably of at least 50 mm. In particular, the spring element is connected to the central connecting element and opposes a deflection of the central connecting element with resistance which is dependent on a prestress, with the result that deflections in one direction are opposed by a resistance. The spring element can be configured as a linearly elastically deformable element or as a torsion spring element. A force/path behavior of the spring element can in principle be configured to be linear or nonlinear. In principle, instead of or in addition to a spring element, the counterforce unit can comprise an additional damping element which can be arranged in series with or parallel to the spring element in the counterforce unit. It is also conceivable in principle to use a number of groups of spring elements and additional damping elements which are arranged parallel to one another, the number of groups being connected in parallel and/or series to one another. The additional damping element can be formed by an element having internal damping properties, for example a rubber cable or a braided rubber cable with a non-linear load characteristic. The additional damping element can be of integrated configuration with the spring element. In particular, a counterforce unit which is configured in a structurally simple manner can be achieved.
The apparatus preferably comprises proposed at least one untwisting unit with respect to a connection of the central connecting element and the spring element, which makes rotation of the central connecting element about the axis of its own possible. An “untwisting unit” is to be understood to mean, in particular, a unit which is fastened at one end to an element, in particular the central connecting element, and makes a rotation of the element about the axis of its own within the element possible, the rotation of the element being converted into an internal rotation of the untwisting unit. In particular, a structurally simple connection of the central connecting element and the spring element can be achieved.
Furthermore, at least one setting unit which is provided for setting a counterforce strength is proposed. A “setting unit” is to be understood to mean, in particular, a unit which acts on the counterforce unit in a manner which is manual or is controlled in an electronic way, and changes a counterforce strength of the counterforce unit and therefore the possible movement radius of the platform in the case of a given deflection force. The setting unit is preferably provided to change the counterforce strength during operation of the apparatus. In particular, an apparatus which can be adapted in a flexible manner to different conditions can be achieved.
Furthermore, it is proposed that the at least one setting unit has at least one actuator, preferably at least one electric actuator. An “electric actuator” is to be understood to mean, in particular, a mechatronic component which is provided to convert electric signals into a movement, in particular into a linear or rotational movement. In particular, the electric actuator is provided to set a prestress of the spring element. In particular, the actuator is provided for infinitely variable setting of the prestress. In particular, an infinitely variable setting unit which can be realized inexpensively and can be actuated simply can be achieved.
As an alternative, the at least one counterforce unit can have at least one directly adjustable damping element. A “directly adjustable damping element” is to be understood to mean, in particular, a damping element, the counterforce strength of which can be set by means of a direct electric actuation, in particular without previous actuation of an actuator for adapting a prestressing force, or by application of an external electric and/or magnetic field. In alternative refinements, instead of or in addition to a directly adjustable damping element and/or spring element, the counterforce unit can also have an eddy current brake or a friction brake. In particular, infinitely variable and rapid setting of a counterforce strength can be achieved in a structurally simple manner. In particular, the directly adjustable damping element can be formed by an electrorheological damper and/or a magnetorheological damper. An “electrorheological damper” is to be understood to mean, in particular, a damper having an electrorheological liquid. An “electrorheological liquid” is to be understood to mean, in particular, a liquid in which electrically polarizable particles are suspended and which liquid has a viscosity which can be changed by application of an electric field as a result of the formation of dipoles in the particles. A “magnetorheological damper” is to be understood to mean, in particular, a damper having a magnetorheological liquid. A “magnetorheological liquid” is to be understood to mean, in particular, a liquid in which magnetic polarizable particles are suspended and which liquid has a viscosity which can be changed by application of a magnetic field. In particular, a structurally simple and directly adjustable damping element can be achieved.
Furthermore, it is proposed that the at least one setting unit has at least one control unit. A “control unit” is to be understood to mean, in particular, a unit which has at least one computing unit and at least one memory unit and which is provided to execute at least one program which is stored in the memory unit and preferably to perform setting of the counterforce strength depending on the stored program and/or on a movement of the platform. In particular, the control unit can be provided to set the counterforce strength depending on measured values of at least one sensor for measuring a deflection of the platform, deflection speed or deflection acceleration. The sensor can be formed, for example, by a camera, an induction sensor or a further sensor for positional measurement which appears to be suitable to a person skilled in the art. In particular, an apparatus which can be adapted in a flexible manner can be achieved. In particular, an apparatus can be achieved which can be adapted readily and rapidly to different requirement options and which, in particular, can be combined with further external devices, for example a videogame console.
In addition, the at least one control unit can be provided for executing a training program, in which a slow reduction in the counterforce strength of the counterforce unit as a result of an increase of a deflection amplitude of the platform is superimposed with a rapid increase in the counterforce strength. A “slow reduction” and a. “rapid increase” in the counterforce strength is to be understood to mean, in particular, that the reduction in the counterforce strength takes place slowly in comparison with the increase in the counterforce strength. An “increase of a deflection amplitude” is to be understood to mean, in particular, that an amplitude of deflections of the platform from the rest position increases on account of a diminishing of the counterforce strength, of an interruption of the force flow by the force transmission interruption unit which leads to a movement of the platform occurring largely free of a counterforce, and/or on account of movements of a person on the platform, for example compensating movements of the person in the case of an external stimulus. An increase of the deflection amplitude of the platform is preferably determined by the computing unit of the control unit. In particular, the rapid increase in the counterforce strength serves to avoid an excessively large increase of the deflection amplitude of the platform. In particular, the slow reduction of the counterforce strength is provided during the training program to challenge the person again and again during the training program as a result of a gradual increase in a deflection amplitude during an identical movement of the person on the platform, and therefore to achieve a high training effect. In particular, stability and motor capabilities of a person who passes through the training program can be determined and trained simply and reliably by way of a slow reduction of the counterforce strength and an increase, associated therewith, of a deflection of the platform, which deflection is brought about by movements of the person. In particular, a training program with a high stability which is adapted in a person-specific manner can be achieved. Furthermore, the central connecting element can be provided for damping the movement of the platform by means of external friction. “External friction” is to be understood to mean, in particular, a friction of the central connecting element with a further component of the apparatus, which component is different than the central connecting element. In particular, the central connecting element is provided to be in frictional contact with a surface of the sleeve or bore with a rounded opening in accordance with the Euler-Eytelwein formula and to convert kinetic energy into heat energy in a dissipative manner. In particular, additional damping of movements of the movable platform can be achieved.
Furthermore, it is proposed that the at least one counterforce unit has at least one element with a non-linear force characteristic. An “element with a non-linear force characteristic” is to be understood to mean, in particular, an element which experiences a non-linear extension under tensile stress, for example a rubber cable or a spring element with a non-linear force-extension characteristic curve. In particular, a high variability of the counterforce which is generated by the counterforce unit can be achieved.
The apparatus according to the invention is provided, in particular, to be used with respect to balance training and/or with respect to therapy. In therapy, the apparatus according to the invention can be used, for example, for muscle training. In particular, a use of the apparatus according the invention in cooperation with a games console is proposed. The apparatus according to the invention preferably comprises a control unit which is connected to the games console and can be configured either such that it is integrated into the games console or is separate from the latter. In particular, the control unit which is connected to the games console is formed by the control unit of the setting unit.
Furthermore, a use of the apparatus according to the invention under conditions of reduced gravity for balance training and or fine motor skills training and/or for therapy is proposed. “Conditions of reduced gravity” are to be understood to mean, in particular, conditions, in which a gravitational effect of at most 0.9 g, advantageously at most 1*10−3 g, preferably at most 1*10−6 g and particularly preferably at most 1*10−8 g is active. The gravitational effect can be generated by gravity and/or artificially by way of an acceleration. “g” denotes the value of the gravitational acceleration on Earth of 9.81 m/s2. In particular, a use of the apparatus according to the invention in cooperation with a games console under conditions of reduced gravity is proposed. In particular, a training possibility under conditions of reduced gravity which can be adapted simply to personal requirements can be provided.
In particular, a use of the apparatus according to the invention for a training program can be provided, in which a rapid increase of the counterforce strength by way of an increase of a deflection amplitude of the platform is superimposed on a slow reduction of the counterforce strength of the counterforce unit. In particular, a training program with a high stability which is adapted in a person-specific manner can be achieved.
The apparatus according to the invention is not to be restricted here to the above-described application and embodiment. In particular, the apparatus according to the invention can have a number of individual elements, components and units which differs from a number of said individual elements, components and units mentioned herein with respect to fulfilling a method of operation which is described herein.
Further advantages result from the following description of the drawings. The drawings show two exemplary embodiments of the invention. The drawings, the description and the claims contain numerous features in combination. A person skilled in the art will expediently also consider the features individually and combine them to form appropriate further combinations.
In the Drawings:
The apparatus 10a has a counterforce unit 20a (
The central connecting element 22a transmits the at least two-dimensional movement of the platform 12a in a one-dimensional manner to the counterforce unit 20a. The counterforce unit 20a has a movement conversion unit 24a which converts a rotational component of the at least two-dimensional movement of the platform 12a into a rotational movement of the central connecting element 22a about an axis of its own. The movement conversion unit 24a has a bore 26a in a body with a rounded opening. In an alternative refinement, instead of a bore 26a in a body, the movement conversion unit 24a can have a sleeve with a rounded opening. In principle, it is likewise conceivable that the bore 26a or the sleeve has a sharp-edged opening. The central connecting element 22a is guided through the bore 26a, said central connecting element 22a bearing against the opening. During a deflection of the platform 12a from the rest position, the translational component of the deflection and therefore the movement of the platform 12a is converted into a translational movement of the central connecting element 22a, whereas a rotational component of the movement is converted into a rotation of a part region of the central connecting element 22a between the bore 26a and the platform 12a about the bore 26a of the movement conversion unit 24a and, during multiple rotation, about the bore 26a into a rotation of the central connecting element 22a about the axis of its own. The rotational component of the movement of the platform 12a is therefore filtered out and only an amount of the deflection from the rest position remains which is opposed by a resistance by way of the counterforce unit 20a. In principle, it is conceivable to provide different resistance strengths for in each case one of the two movement directions 48a, 50a of the platform 12a and, instead of the central connecting element 22a, to provide different elements for the connection to separate counterforce elements.
The counterforce unit 20a has a spring element 32a which is connected to the central connecting element 22a and opposes a translational movement of the central connecting element 22a by way of a resistance on account of a restoring force, with the result that a deflection of the platform 12a is opposed by a resistance via the central connecting element 22a. An additional damping element 58a of the counterforce unit 20a is arranged in series with the spring element 32a. The counterforce unit 20a has an element with a non-linear force characteristic, which element is formed by the additional damping element 58a. The additional damping element 58a is configured as a braided rubber cable with a non-linear force characteristic. In alternative refinements of the counterforce unit 20a, the additional damping element 58a of the counterforce unit 20a can be arranged parallel to the spring element 32a. Furthermore, the central connecting element. 22a is provided for damping of the movement of the platform 12a by means of external friction, since the central connecting element 22a comes into frictional contact during a translational movement with the surface of the bore 26a in accordance with the Euler-Eytelwein formula and, during said external friction, kinetic energy of the central connecting element 22a and therefore of the platform 12a is dissipated, as a result of which the movement of the platform 12a is damped. In particular, the external friction of the central connecting element 22a with the surface of the bore 26a is provided for damping a reverberation of the platform 12a during deflection and for damping movements as a result of a person climbing on. In the exemplary embodiment which is shown, both the central connecting element 22a and the surface of the rounded opening of the bore 26a are manufactured from steel, but in principle both the central connecting element 22a and the surface of the rounded opening of the bore 26a can be manufactured from other materials. On a path between the bore 26a and the spring element 32a, the central connecting element 22a is deflected by means of a deflection roller 54a. The apparatus 10a has an untwisting unit 56a which is formed by a turbulence bearing for a connection of the central connecting element 22a and the spring element 32a, which turbulence bearing makes a rotation of the central connecting element 22a about the axis of its own possible, with the result that an action of force on the spring element. 32a as a result of the rotation of the connecting element 22a about the axis of its own is avoided and the spring element 32a is loaded merely with an action of force as a result of the amount of the deflection of the platform 12a from the rest position. The untwisting unit 56a which is formed by the turbulence bearing is connected via a sleeve element 28a to the spring element 32a. It conceivable in alternative refinements that, in addition to or instead of the spring element 32a, the counterforce unit 20a has, for example, an eddy current brake or a friction brake for damping.
A setting unit 34a is provided for setting a counterforce strength of the counterforce unit 20a. The setting unit 34a has an electric actuator 36a which sets a prestressing force on the spring element 32a. The counterforce strength of the counterforce unit 20a is set via a setting of the prestressing force of the spring element 32a by way of the actuator 36a, since firstly a deflection of the central connecting element 22a by the platform 12a is opposed by a higher counterforce by way of an increased, prestressing force and secondly a change in a frictional force with the surface of the bore 26a in accordance with the Euler-Eytelwein formula is achieved on account of a changed force on the central connecting element 22a. The force transmission interruption unit 60a comprises a connecting element 62a which, in the at least one operating state, in which the force transmission interruption unit 60a interrupts the force flow, is mounted at least partially in a stress-relieved state. The connecting element 62a is configured as a cable element which, in the stress-relieved state, lies loosely in loops on a floor and is first of all tautened in the case of an action of force on the central connecting element 22a. The spring element 32a is extended and generates a counterforce only after complete mechanical tautening of the connecting element 62a is achieved. Tautening of the connecting element 62a takes place in a substantially force-free manner, with the result that no counterforce is exerted on the platform 12a. The connecting element 62a is arranged between the actuator 36a and the spring element 32a and can be stressed and relieved by way of the actuator 36a, it being possible for the spring element 32a to be prestressed by the actuator 36a only after complete stressing of the connecting element 62a. The setting unit 34a has a control unit 40a which is integrated into the setting unit 34a and which comprises a computing unit and a memory unit with programs which are stored therein. The control unit 40a is provided for actuating the actuator 36a for adapting the damping. In particular, different counterforce strengths can be set for adapting the apparatus 10a to different requirements of users of the apparatus 10a, for example to different degrees of balance impairment of different persons who carry out balance training during therapy. A setting of the counterforce strength can take place in an infinitely variable manner on account of the electric actuator 36a. In its memory unit, the control unit 40a has, in particular, various training programs stored with different degrees of difficulty which are realized via different counterforce strengths, the degree of difficulty changing during the course of the training program being carried out in some training programs. In particular, a setting and adaptation of the counterforce strengths can be carried out during use of the apparatus 10a by means of the setting unit 34a via the control unit 40a and the electric actuator 36a, as a result of which it is made possible to realize training programs with different counterforce strengths and therefore degrees of difficulty without an interruption of the training program for adapting the counterforce strength. The control unit 40a is provided for carrying out a training program, in which a slow reduction in the counterforce strength of the counterforce unit 20a as a result of an increase in a deflection amplitude of the platform 12a is superimposed with a rapid increase in the counterforce strength. The rapid increase in the counterforce strengths serves to avoid an excessively large increase in the deflection amplitude of the platform 12a, whereas, as a result of the slow reduction in the counterforce strength during the course of the training program as a result of a gradual increase in a deflection amplitude during an identical movement of a person on the platform 12a, the person is challenged again and again in the course of the training program and a high training effect is therefore achieved. In particular, the training program comprises an initial phase with a high counterforce strength, in which initial phase movements of the person on the platform 12a lead only to a small deflection of the platform 12a. After the initial phase, a transition into an actual training phase takes place by way of the slow reduction in the counterforce strength of the counterforce unit 20a, in which actual training phase, on account of the reduction of the counterforce strength of the counterforce unit 20a, a resulting increase in the deflection amplitude of the platform 12a is actuated by way of the control unit 40a to produce a rapid increase in the counterforce strength and is superimposed on the slow reduction in the counterforce strength, which results in rapidly changing training conditions, by way of which a high training effect is achieved.
Furthermore, in cooperation with the games console 44a, it is possible by means of the control unit 40a to simulate different situations for training games on the games console 44a by way of different counterforce strengths, for example in order to train astronauts. In alternative refinements, the control unit 40a can be integrated into the games console 44a, with the result that an actuation of the setting unit 34a can take place by way of the games console 44a. Furthermore, alternative refinements are conceivable, in which an adaptation of the counterforce strength is performed by hand on the spring element 32a. The control unit 40a is provided to set the counterforce strength depending on measured values of at least one sensor 42a for measuring deflection of the platform 12a. The sensor 42a is formed by a camera, via which the control unit 40a achieves the movement of the platform 12a using a detection of markings on an underside of a platform 12a. In alternative refinements, the sensor 42a can be formed for positional measurements of the platform 12a by other sensors 42a which appear to be suitable to a person skilled in the art.
An alternative apparatus 10b for balance training with a movable platform 12b which can be moved in an oscillating manner in at least two dimensions, with a counterforce unit 20b which opposes a force provided for deflection of the movable platform. 12h with a resistance, and with a force transmission interruption unit 60b which interrupts a force flow between the movable platform 12b and the counterforce unit 20b in at least one operating state, is configured substantially analogously with respect to the preceding exemplary embodiment (
Number | Date | Country | Kind |
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13160478.7 | Mar 2013 | EP | regional |