This application is a §371 application of PCT/EP2013/065366, filed Jul. 19, 2013. The entire disclosure of the foregoing application is incorporated by reference herein.
In general, the present invention relates to systems, devices and methods for exercising the limbs, in particular for exercising lower limbs. In some aspects, the present invention relates to powered orthoses and to the rehabilitation by aid of said orthoses. The present invention relates to devices comprising articulated systems and/or an articulated lambda-framework for exercising. The present invention further relates to orthopedic systems devices equipped with motors and captors, to motorized devices for training the lower limbs of a subject, and to methods for controlling or driving the orthoses, systems, devices and methods of the invention.
Robotics applied to rehabilitation requires specific manipulators: Powered Orthoses. They are orthopedic devices equipped with motors and captors that enable locomotor assistance. Powered orthoses must be capable of reproducing physiological articular trajectories and taking over or simulating the segmentary charges of a movement, mainly walking. One needs to obtain rather high dynamic performances with the help of small activators enabling mechanical integration bearable for its subject.
Previously developed, powered orthoses for re-education of the lower limbs are generally serial, exoskeleton-based structures, such as the MOTIONMAKER™. These devices are based on an exoskeleton fixed along the lower limbs of an individual, wherein a series of actuating motors cause movement of the exoskeleton and of the limbs attached thereto. An example of a serial, hip-knee-ankle exoskeleton-based device is disclosed in EP 1 387 712. These devices have several disadvantages. They are generally not capable of rapid movement and the motors have limited strengths, because motor size is limited as the motors are fixed on the moving exoskeleton. A further disadvantage is that for small persons, such as children, a separate, smaller device is necessary, as adjustment to anatomical particulars is only possible within relatively narrow limits. Furthermore, such devices take a lot of space, even when they are not used. Finally, it would be advantageous to provide devices suitable for re-education not only of patients suffering from paralysis, such as paraplegia and tetraplegia, but also for training healthy people and/or only partially paralyzed patients, retaining some musculoskeletal function in the lower limbs.
In the thesis no. 3783 of Carl Schmitt (2007) entitled “Orthèses fonctionnelles à cinématique parallèle et sérielle pour la rééducation des membres inférieures” (2007) at the École Polytechnique Fédérale de Lausanne, parallel powered orthoses having a λ-structure are proposed. The publication of M. Bouri et al. entitled “A new concept of parallel robot for rehabilitation and fitness: The Lambda” of the Proceedings of the 2009 IEEE International Conference on Robotics and Biomimetics, Dec. 19-23, 2009 discloses a λ-robot for rehabilitation and fitness. However, these prior art devices suffer from several disadvantages: they are relatively noisy; they are too big, heavy and are built from too many parts. The prior art devices generally use a spring for compensating gravity.
The present invention addresses the problems depicted above and seeks to provide improved devices for rehabilitation and/or for exercising lower limbs.
The present invention seeks to provide a device suitable for re-educating and/or training the lower limbs of a person, in particular a person having an impairment of the central nervous system, such as a patient suffering from tetraplegia, paraplegia and/or hemiplegia. The invention seeks in particular to provide a device that can be used to train the limbs of a large population of subjects suffering from various conditions, for geriatric subjects and also a device that can be used for wellness purposes by healthy subjects.
In an aspect, the present invention concerns a motorized device and/or a robot for training the lower limbs of a subject, the device comprising a pair of articulated systems and/or orthoses, intended to form an interface with said subject, wherein each of said articulated systems comprises a base, a foot support assembly and a framework for said foot support assembly.
In an aspect, the present invention concerns a device for re-educating and/or training the lower limbs of a person, in particular a person having an impairment of the central nervous system, wherein the device comprises a pair of articulated systems and/or orthoses, each orthose comprising a lambda-framework structure for positioning and/or moving a foot support assembly.
In an aspect, the present invention concerns a device for re-educating and/or training the lower limbs of a person, in particular a person having an impairment of the central nervous system, wherein the device comprises a pair of articulated systems (ASs).
In an aspect, the present invention concerns a motorized device for training the lower limbs of a subject, the device comprising a pair of articulated systems (ASs), intended to form an interface with said subject, wherein each of said articulated systems comprises a foot support assembly comprising a Tool Operation Center (TOC) pivotally fixed on an articulated lambda framework (ALF), wherein: said ALF is pivotally connected to at least two carts, a first cart guided on a first rail track section and a second cart guided on a second rail track section; wherein said device comprises a first driving screw and a second driving screw for driving said first and second carts, respectively, and wherein said first and second driving screws are independently driven by a first motor and a second motor, respectively; wherein a position of said TOC within a plane is determined by positions of said sliding carts on their respective rail track sections; wherein the device further comprises a transmission assembly, for transmitting a rotational movement driven by a third motor to said TOC; and, wherein said third motor is fixed on said first sliding cart.
In an aspect, the present invention provides a motorized device for training the lower limbs of a subject, the device comprising a pair of articulated systems, intended to form an interface with said subject, wherein each of said articulated systems comprises a base, a foot support assembly and a framework for said foot support assembly, wherein: said framework comprises two longitudinal, articulated subassemblies, a main subassembly and a supporting subassembly, wherein, at one extremity, said main subassembly is pivotally connected to a first cart articulation, and with the other extremity it is connected to said foot support assembly, wherein said supporting subassembly is pivotally connected at one extremity to a second cart articulation and with the other extremity to said main subassembly; said base comprises a support or carrier structure on which two rail track sections, a first rail track section and a second rail track section are fixed, wherein a first cart is guided on said first rail track section and a second cart is guided on said second rail track section; said base further comprises a first driving screw and a second driving screw, wherein said first driving screw is arranged to drive said first cart and said second driving screw is arranged to drive said second cart; a first motor is arranged to rotate said first driving screw and a second motor is arranged to rotate said second driving screw, wherein rotation of said first and second driving screws results in linear movement of said first and second cart, respectively; a third motor is fixed on said first cart, adapted to act on a transmission assembly, wherein said transmission assembly is adapted to transmit a rotational movement of said third motor to a foot contact assembly, wherein said foot contact assembly is pivotally connected with said foot support assembly.
In an aspect, the invention further relates to a carrying system for carrying the device of the invention, and/or a carrying system comprising the device of the invention.
In an aspect, the invention relates to methods of running the device of the invention. The invention also relates to methods of training and/or exercising using the device of the invention.
Further aspects and preferred embodiments of the invention are defined herein below and in the appended claims. Further features and advantages of the invention will become apparent to the skilled person from the description of the preferred embodiments given below.
Hereinafter, preferred embodiments of the device and system of the invention are described with reference to the drawings.
The present invention provides a motorized system, device and/or a robot for training the lower limbs of a subject. In preferred embodiments, the device comprises a motorized mechanical device and a control system for operating the device.
For the purpose of the present specification, the expression “comprise”, “comprising” or its various grammatical forms is intended to mean “include, amongst other”. It is not intended to mean “consists only of”.
In
As can be seen in
According an embodiment of the invention, the AS of the invention comprises a parallel architecture and/or geometry. For example, the device of the invention comprises a parallel robotic architecture. According to a preferred embodiment, the device of the invention comprises a parallel and serial (hybrid) architecture and/or geometry. For example, the device comprises a hybrid robotic architecture. Accordingly, the device of the invention comprises preferably a parallel or hybrid manipulator.
Instead of first and second ASs, one could also refer to left and right articulated systems 900, 9. Said first and second ASs are preferably substantially identical or symmetrical with respect to a plane extending vertically (in
According to an embodiment, said first and second ASs are identical. According to an embodiment, said first and second ASs comprise identical structural components. According to an embodiment, said first and second ASs function essentially in the same way.
Hereinafter, only the right or first AS 9 will be described in more detail, as the second or left AS 900 is basically constructed as a mirror image of the first AS 9. The structures described herein with respect to the first AS 9 are also present in the second AS 900, and what is said herein below with respect to the first AS 9 also applies, independently, to the second AS 900. Regarding the reference numerals, it is noted that each structural element of the second AS corresponds to the reference numeral of the left AS+900. For example, the food support assemblies of the first and second ASs have reference numerals 4 and 904, respectively. For easier understanding, the reference numerals of the second AS are not consequently shown in the figures and are not separately described herein below.
As can be seen in
Each base 2 preferably comprises a support and/or carrier structure 10 on which structural elements are fixed, such as rails, motors, cable hangers, screw fixations and drives or gear boxes from the motors to the drive screw are fixed, for example. The support structure 10 preferably provides a surface for fixing the AS 9. The support structure 10 may comprise profiles made from a rigid material, such as a metal, preferably selected from aluminum or steal, for example. Preferably, the support structure provides or comprises a surface extending in a plane on which the AS can be fixed.
Each base 2 further preferably comprises two rail tracks or two rail track sections. In the embodiment shown in the figures, each rail track comprises a pair of rails. In particular, the right base 2 comprises a first rail track comprising a first pair of rails 11, 12, and a second rail track comprising a second pair of rails 13, 14. In
Said first rail track is preferably arranged in the same direction as the second rail track. Said first pair of rails 11, 12 is preferably oriented in the same direction as the second pair of rails 13, 14. According to an embodiment, said first and second pairs or rails are in the same plane.
According to an embodiment, said first and second pair of rails of AS 9 are coaxial and/or collinear. More specifically, a first rail 11 of said first pair of rails is collinear with a first rail 13 of said second pair of rails, and/or a second rail 12 of said first pair of rails is collinear with a second rail 14 of said second pair of rails. Preferably, one pair of rails is provided behind and/or as a prolongation of the first pair of rails.
In the figures, an AS comprising two pairs of collinear rails 11, 12 and 13, 14 is shown. The term “collinear” for the purpose of the present specification, means that a rail (e.g. rail 14) of the second pair of rails is the linear prolongation of a rail (here: rail 12) of the first pair of rails.
The term “coaxial” for the purpose of the present specification, means that a common axis of the first rail track section or first pair of rails together is the same as the axis of the second rail track section and or second pair of rails. The “axis” of a pair of rails extends at an equal distance between the two rails. As a consequence, the two driving screws 31 and 32 of the two coaxial pairs of rails are preferably coaxial, too.
It is noted that the invention encompasses various alternative constructions of the two rail tracks or rail track sections. For example, the invention encompasses that the two rail track sections are constructed as one single pair of rails, with the two sliding carts 21 and 22 being positioned on different sections of a single pair of rails. For example, collinear rails 12 and 14 may be formed by one single, continuous rail, and collinear rails 11 and 13 may be formed by another single, continuous rail. In this embodiment, the first sliding cart 21 can be said to be moved on a first rail track section 11/12, and the second sliding cart 22 is moved on a second rail track section 13/14.
According to another embodiment, there are two separate rail tracks and/or two pairs of rails, but they are not necessarily collinear. For example, while the first and second pairs of rails are preferably parallel, each pair of rail may comprise a different rail-to-rail distances. For example, the distance between rails 11 and 12 may be different from the distance between rails 13 and 14. For example, the distance between the rails 11 and 12 may be larger or smaller than the distance between rails 13 and 14. Since the distance between the rails may have an impact on the stability, the variation of the distance can be used as a possibility to adjust and/or optimize the stability of the ALF with respect to other constraints, such as spatial considerations, for example.
According to another embodiment, the two rail tracks and/or the two pairs of rails 11, 12 and 13, 14 extend in parallel, laterally displaced one section with respect to the other.
According to another embodiment, the two rail tracks and/or the two pairs of rails 11, 12 and 13, 14 are displaced with respect to the plane in which they are situated. For example, one of the two rail tracks may be elevated with respect to the other rail track. For example, one rail track may be closer to the base and the other more distanced or elevated with respect to the base plane.
According to a still further embodiment, the two rail tracks and/or the two pairs of rails 11, 12 and 13, 14, respectively, do not even extend in parallel, but extend at an angle with respect to each other. In this embodiment, the two rail tracks resemble the two edges of an obtuse triangle, for example.
The constructional and/or architectural variations depicted above are just examples. Such variations may help increase the stability of the ASs and or of the entire device of the invention, for example, during operation.
On each rail track or rail track section, a sliding cart is provided, arranged to move on the rail track. A first car 21 is provided on the first rail track 11, 12, and a second cart 22 is provided on a second rail track 13, 14. Said first and second sliding cars are preferably arranged to move, independently, in the same two opposing directions on their respective rail tracks.
The first and second sliding carts 21, 22 are preferably driven independently by a first driving screw 31 and a second driving screw 32. In
According to an embodiment, said first and second driving screws 31, 32, comprise at least a multiple thread screw. Preferably, the first and second driving screws comprise at least a triple—more preferably at least a quadruple thread screw. Preferably, said driving screw comprises a multiple outer thread screw. The expression “multiple thread screw”, for example “quadruple thread screw” encompasses in particular multiple-start threads, such as quadruple-start screws.
In particular, a first motor 41 is arranged to rotate said first driving screw 31 and a second motor 42 is arranged to rotate said second driving screw 32, wherein rotation of said first and second driving screws results in linear movement of said first and second cart, respectively. In the embodiment shown in
The device of the invention comprises a framework 3 comprising two subassemblies, a first or main subassembly 5, and a second or supporting subassembly 6. Preferably, said main and support subassemblies 5, 6 are each longitudinal. Preferably, said main subassembly 5 is longer and larger than said support subassembly 6. The support subassembly 6 comprises two extremities wherein at one of said two extremities said support assembly is pivotally connected to said main subassembly 5, and at said other or second extremity it is connected to said second sliding cart 22. Instead of main subassembly 5, the expression “main longitudinal assembly”, “main longitudinal structure” or simply “main beam” may be used for the purpose of this specification. Instead of support subassembly 6, the expression “support longitudinal assembly”, “support longitudinal structure” or simply “support beam” may be used for the purpose of this specification.
The subassemblies 5 and 6 are pivotally connected to each other at a pivotal connection 51. With respect to the main subassembly 6, the pivotal connection 51 may be located closer to the center than to one of the extremities of the main subassembly, as shown in
When viewed from lateral, as shown in
At their extremities, the main and support subassemblies 5 and 6, respectively, are pivotally connected to the first and second sliding carts 21, 22. In
For the purpose of the present specification, the term “proximal” generally means closer to the base 2 of the device of the invention, and “distal” generally means further away from the base. The foot support assembly 4 is thus provided at the distal end of the main framework assembly 5. In this specification, these terms are thus generally used with reference to the device as such and not with respect to the subject using the device. When seen with respect to the user/subject, the most proximal part of the device of the invention would be the foot support assembly 4. In this situation, the expressions “proximal” and “distal” will be used specifically with respect to or with reference to the subject.
It is noted that the foot contact assembly 4, and more specifically the foot contact plate 52 of assembly 4 forms the Tool Operation Center (TOC), which is the place where the function of the device of the invention is achieved or fulfilled and/or, which is the place of the interface between the subject and the device of the invention for the purpose of exercising.
Therefore, for the purpose of this specification, the expression “TOC” refers to the foot support assembly 4 and more specifically to the foot contact plate 52.
The present invention encompasses different λ-type or λ-derived geometries, as illustrated in
The AS 3 in the middle of
It is noted that the expression “geometric length” refers to geometrically or physically relevant lengths, in particular lengths between articulations. These lengths are relevant with respect to the calculation and computation of the movements of the AS and also for the adjustment of the AS to the parameters of a subject using the device of an invention, as described elsewhere in this specification. In
In the AS 3′ shown on the left side on
In embodiment that can be seen as a variation of the embodiment shown on the left side of
Finally, the exemplary AS 3″ shown on the right side in
As becomes clear from
The device of the invention comprises a foot assembly or foot support assembly 4, which comprises in particular a foot contact plate 52. The foot contact plate 52 comprises a surface or contact area for placing and/or fixing the foot or sole as described elsewhere in more detail. The foot contact plate 52 preferably represents the TOC as described elsewhere in this specification. The foot contact assembly 4 is pivotally connected to a distal extremity 44 of the main framework subassembly 5, and is thus capable of pivoting. The distal extremity 44 is actually an assembly for pivotally holding the foot contact assembly 4. The foot contact assembly 4 resembles and/or functions in a similar manner as a pedal or treadle, and may also be referred to as pedal in this specification. In the operating device, the pivoting of the foot contact assembly 4 allows determining the movement and/or rotation of the ankle articulation of a subject.
For operating the device of the invention, in particular for the purpose of training the limbs of a subject, the foot contact assembly 4 is moved in a vertical plane and/or rotated so as to design a specific trajectory defined by of a training exercise. To this end, motors are provided. A first motor 41 is provided to drive said first cart 21. A second motor 42 is provided to drive said second driving cart 22. A third motor 43 is provided to rotate and or pivot the foot contact assembly 4. The third motor 43 is preferably fixed on said first cart 21. Rotation of the motor axle of the third motor is preferably transmitted by way of a transmission assembly 20 to said foot contact assembly 4, as will be described in more detail elsewhere in this specification.
The support framework assembly 6 is connected via ball bearings to the two axles 67, 103. In
In
At one extremity, a short shaft or pin 76 of the driving screw 31 extends axially beyond the ball bearing in the holder piece 69. On the pin 76, the pulley 77 of the first driving screw fixed in a rotationally fixed manner with respect to the driving screw 31, as can be seen in
An identical and/or analogous construction (motor, gearshift, motor-pulley, belt, screw-pulley, etc.) is used to propel the second driving screw 32 (
In
The second pair of rails 13, 14, the second cart 22 and the second driving screw 32 are constructed, arranged, and mounted independently as described for the first pair of rails shown in
In the embodiment shown, the hole 89 of the chassis does not contain an inner threading itself. However, inner threading holding pieces 15, 16, a first inner threading holding piece 15 and a second inner threading holding piece 16, are fixed in the cart 21, in particular on the chassis 81 (
It is noted that the second nut 16 (or second inner threading holding piece) is rigidly fixed on the chassis 81, by way of screws 97, 97′, 97″ and 97′″. These screws 97 extend through bores in the flange 92 of the second nut and are anchored in the body of the chassis 81. The flange 92 has a roughly rectangular contour, with straight top and bottom borders, as can be seen in
The play between the outer threading of the driving screw 31 and the inner threadings of the nuts 15 and 16 can be adjusted as described herein below. It is noted that the first nut 15 (or first inner threading holding piece) is fixed in a different manner to the chassis 81/cart 21 than the second nut. First nut 15 is fixed once the driving screw 31 is already inserted through bore 89 and threadedly engaged with the second nut 16. In other words, when mounting the device of the invention, the first nut 15 is inserted and blocked only once the second nut is already rigidly fixed to the chassis 81. The first nut 15 is then rotated on the screw 31 until it abuts against abutment surface 95 of the chassis 81. Further rotation leads to a certain axial traction on the screw, as the axial movement of the first nut 15 is blocked in this direction by the abutment surface 95 of the chassis. This traction can be conducted by turning the first nut 15 until the play between the drive screw 31 on the one side and, on the other side, the inner threading of nuts 15 and 16 considered together (as a whole) is zero or close to zero. It is noted that by further turning nut 15 once it already abuts against abutment surface 95 cannot lead to further insertion of the nut into the bore, as the nut is blocked in this direction. Further turning leads, however, to a rotation of the inner threading of the nut 15, and this rotation will at some point be counteracted by the outer threading of the driving screw 31, resulting in the traction mentioned.
Once the play is adjusted as desired by rotation of the first nut 15, the latter is blocked rotationally by a blocking device 18. In the embodiment shown, the blocking device 18 is a flask or clamp 18, which is fixed on the chassis 81 so that it presses or clamps the flange 91 of the first nut 15 onto the chassis 81, and more particular onto the abutment surface 95 of the chassis 81. The clamp 18 comprises a central bore, through which the drive screw 31 extends (
The clamp 18 comprises at least one cut-out or opening 99, giving access to the flange 91. In
Of course, the present invention encompasses further ways of blocking the inner threading holding piece 15 at a rotationally desired and/or adjusted position, in order to adjust play. In particular, the invention encompasses the adjustment of the rotational position of the inner threading holding piece 15 while being in an axially determined or fixed position, in order to adjust the play/tolerance/clearance. Furthermore, the invention encompasses in general a mechanism and/or adjustment device for adjusting the rotational position of the inner threading holding piece when fixed on the chassis 81 of the cart 21. The invention encompasses the use of a separate and/or specific tool for adjusting the inner threading holding piece during maintenance, for example.
The actual position of a sliding cart could also be determined, for example, using an optic linear encoder instead of the magnetic encoder 61 and an optic ruler instead of the magnetic strip 102. As a further alternative, the actual position of the cart could be determined using a draw wire sensor, for example, in which one part of the sensor is fixed at an extremity of the rails and the other part on the cart. Therefore, there are several possibilities of sensors or encoders for determining the actual position of the cart on their respective rails, and the cited possibilities just represent exemplary embodiments.
The main framework subassembly 5 comprises a connection subassembly 50, longitudinal subassembly 30 and a foot support carrying subassembly 44.
The transmission subassembly 20 can be considered as part of all subassemblies 50, 30, and 44 of the main framework subassembly 5, and even of the sliding cart 22. On the other hand, the transmission assembly 20 can also be considered as an own or separate subassembly 20 that is carried by or in contact with all these subassemblies 50, 30 and 44 and/or the cart 21. The transmission 20 assembly transmits the rotational movement of the third motor 43 to the foot contact assembly 4.
The connection subassembly 50 contains the axle 85, which is part of the first cart articulation 7 by which the main subassembly 5 is pivotally connected to the first cart 21. The axle 85 is rotationally harbored between two lateral plates 105, 105′ of the connection subassembly 50. These plates are rigidly fixed to the one (proximal) extremity of the longitudinal subassembly 30, the latter providing the longitudinal support and carrier function for the foot support subassembly 4. At the other (distal) extremity, the longitudinal subassembly 30 is connected to the foot support subassembly 4, the latter comprising and carrying the foot contact plate 52. In
In the embodiment shown in the figures, the carrying structure 79 of the longitudinal subassembly 30 is a H-beam. Of course, any longitudinal support or carrying structure 79 could be used in the alternative, such as profiles other than H profiles, such as I, L, U, T profiles, for example, or a combination comprising several longitudinal structures. The carrying structure of the longitudinal subassembly 30 can also be selected from flat bars, such as boards, or from hollow prisms, for example.
The longitudinal subassembly 30 comprises a bearing assembly 51, which, in the assembled device, holds the axle 103 by which the support subassembly 6 is pivotally connected to the main framework subassembly 6. The bearing assembly 51 preferably comprises at least two ball bearings, of which ball bearing 109 can be seen in
In the embodiment shown, the transmission assembly 20 comprises a plurality of pairs of co-rotational belt pulleys 23, 23′; 24, 24′; 25, 25′; 26, 26′ and pulley 47 and a plurality of driving belts 27, 28, 29, 33, 34 acting on and interlinked with said belt pulleys. The rotational movement from said third motor 43 is transmitted via and/or by aid of said transmission system to a rotation axis of said foot contact assembly 4. In particular, an axle propelled by the third motor propels a motor pulley 104 (
Rotation of the motor pulley 104, propelled by the motor 43 via reducer 87 is transmitted via/by way of the motor belt or first belt 27 to the pulley 23, which is part of the first pair of pulleys 23, 23′ of the transmission assembly 20. In the embodiment shown, the first pair of belt pulleys 23, 23′ are coaxial with the axle 85 of the first cart articulation 7. In the embodiment shown, the first pair of belt pulleys 23, 23′ are fixed on the axle 85 and rotationally blocked with axle 85. Axle 85 is guided in a pair of ball bearings, a ball bearing being fixed in each of the mount plates 84, 84′, respectively, of the first sliding cart 21. One such ball bearing of axle 85 can be seen in
The two belt pulleys 23, 23′ forming the first pair of belt pulleys are connected so as to be rotationally fixed with respect to each other (
The transmission assembly 20 transmits the rotational movement of motor 43 to the foot contact assembly 4. The power efficiency η of the transmission assembly is P2/P1, with P1 being the power produced by motor 43 and P2 the power yield at the end of the transmission assembly 20 and/or by foot contact assembly 4. The belt- and pulley based transmission system is advantageous as η is close to 1 or only slightly smaller than 1. For example, η is 0.6-0.99, preferably 0.8-0.99, most preferably 0.9-0.99.
A transmission unit of the transmission assembly 20 is formed by two pulleys connected by a belt. According to an embodiment, the transmission assembly 20 comprises two or more, preferably three or more, more preferably four or more transmission units. In the embodiment shown in the figures, the transmission assembly 20 comprises five (5) transmission units.
When considered in the direction from the motor 43 to the foot contact plate 4, the first transmission unit comprises motor pulley 104, pulley 23 and belt 27. A further transmission unit comprises or is formed by pulleys 23′ and 24 and belt 28. The third transmission unit comprises or is formed by pulley 24′ and 25 and belt 29. The fourth transmission unit comprises or is formed by pulleys 25′ and 26 and belt 33. The fifth transmission unit comprises or is formed by pulleys 26′ and 47 and belt 34.
A transmission unit may work as an amplifier and/or as a reducer of the moment (M), if the two pulleys in a transmission unit have different radii. The transmission assembly 20 of the device of the invention comprises one or more reducers or reducing units, which reduce the moment considered in the direction from the foot contact assembly 4 (see also TOC specified elsewhere) to the motor 43. In the direction motor 43→foot contact assembly/TOC 4, the moment is increased.
As the skilled person will understand, in a transmission unit comprising two pulleys (pulley 1: usually the smaller of a pair of pulley, which is fixed to the motor axle, and pulley 2: bigger than pulley 1) and a belt, the tangential speed vtg, which is the linear speed of the belt, the tangential force Ftg and the power P remain constant (yield close). On the other hand, the angular speed ω and the moment M are dependent on the radius r of the pulley in accordance with the equations vtg=ω*r and M=Ftg*r. r1 and r2 being the radii of the pulleys 1 and 2 respectively, with vtg=ω1*r1=ω2*r2, ω1 and ω2 are the two angular speeds of the pulleys and the moments are M1=Ftg*r1 and M2=Ftg*r2. The power of the unit is P=M1*ω1=M2*ω2 (yield close). Small i represents the ratio of r2/r1 (or ω1/ω2), so that ω1=i*ω2 and M1=M2/i.
If r1 is smaller than r2, i is >1 and the angular speed ω1 is higher than ω2 and M1 is smaller than M2. On the other hand, if r2 >r1, ω1 is smaller than ω2 and M1 is larger than M2. In summary, in the case of the transmission in the direction from a larger pulley to a smaller one via a transmission belt, angular speed amplifies but the moment is reduced. The expression “reducer” and “amplifier” refer to the changes of the moment. If i>1, the belt- and pulley system works as a reducer having regard to the motor. Moment is reduced in a pulley with small radius compared to the pulley with a comparatively larger radius, if the two pulleys are connected via a belt, because i>1.
In the transmission system 20 of the embodiment shown in the figures, the transmission units goes from large wheels to small wheels when seen in the direction from foot contact assembly 4 (or TOC) to the motor 43, as can be seen in
The transmission assembly 20 of the device of preferably comprises a plurality of reducers and/or amplifiers connected in series. In particular, the transmission assembly 20 comprises a one or more reducers connected in series from the foot contact assembly 4 (and/or the TOC) to the motor 43. Each reducer/amplifier being characterized by its value i (i1, i2, i3, i4, in), the overall reduction and/or amplification of the moment is the product of all i. According to an embodiment, n (the number of reducers/amplifiers in series) is an integer of 1 to 20, preferably 2 to 10, more preferably 3 to 8 and most preferably 4-6.
According to an embodiment, said transmission assembly 20 comprises a plurality of pairs of co-rotational (and/or rotationally fixed) belt pulleys 23, 23′; 24, 24′; 25, 25′; 26, 26′, each pair of belt pulleys being coaxial.
As one can see from
In the embodiment shown, and in the direction from the motor to the foot support assembly 4, rotation is transmitted, within a pair of pulleys from a larger to a small pulley (for example, from pulley 24 to pulley 24′). Within a pair of coaxial pulleys, such as 24 and 24′, for example, the angular speed ω and the moment M remain constant, but tangential speed vtg and tangential force Ftg become dependent on the radius. By analogy to the formulae provided above, when passing from a smaller to a larger pulley (r1<r2) within a pair of coaxial and rotationally fixed pulleys, ω remains constant. Vtg2 is higher than vtg1 and Ftg2 is smaller than Ftg1. In this manner, each pair of pulleys 26′, 26; 25′, 25; 24, 24′; and 23′, 23 result in an increase of tangential speed and a reduction of tangential force in the direction TOC 4 to motor 43.
The power P remains roughly constant, in accordance with high η, within a transmission unit e.g. 24, 28, 23′, within a pair of coaxial and rotationally fixed pulleys, such as 24′ and 24, and also within the entire transmission assembly 20.
In
During operation of the device, the foot contact assembly 4 rotates only within a defined angular frame. For example, the foot contact assembly 4 does not conduct any complete rotation, but pivots generally within an angular span of 270° or less, preferably 180° or less, for example 150° or less. Preferably, the moment accompanying rotation of the foot contact assembly 4 is increased compared to the moment of the motor pulley 104.
According to an embodiment, the carrying structure 79 of the longitudinal subassembly 30 comprises a flat, longitudinal structural element, which is oriented so that the flat part is vertical. In the embodiment shown in the figures, the carrying structure 79 is a H-beam, and the vertically oriented, flat structural element is the web 35 of the H-beam. The belt pulleys of the transmission assembly 20 are preferably oriented so that their axis of rotation is perpendicular to the vertically oriented, flat, longitudinal structural element 35. Preferably, the axis of rotation of the belt pulleys are horizontal. As can be seen in
According to an embodiment of the invention, said main subassembly 5 comprises an H-beam 30, connected at one extremity in a rotational manner to said first cart 21 and at the other extremity in a rigid manner to said foot support carrying assembly 44, wherein said H-beam comprises a web 35 oriented in a vertical plane, wherein said web comprises a first side 48 and a second side 49, said first and second sides being opposing sides of said web, wherein an axis and/or axle 38, 39 of a pair of said co-rotational belt pulleys 24, 24′; 25, 25′ is perpendicular to said vertical plane and extends across said web, wherein two belt pulleys of a pair of belt pulleys are arranged each on one of the two opposing sides of said web. Said vertical plane is in particular a plane in which pivoting of the main subassembly 5 is free to or capable of occurring.
In the case of the pair of belt pulleys 26, 26′ that is most distal to the base 2, one belt pulley 26 is fixed close to the flat, longitudinal structural element 35, the other being fixed next to one of the two lateral plates 53, 54 of the food support carrying assembly 44. A last, fifth and/or most distal driving belt 34 transmits rotation of pulley 26′ of the fourth pair of pulleys 26, 26′ to the belt pulley of foot support assembly 4 (the foot support pulley) 47. The foot support pulley 47, which is part of the foot support assembly 4, is connected in a rotationally fixed manner to the foot contact carrying assembly 44. The latter pivotally harbors the foot support assembly 4. In particular, foot support pulley 47 is coaxial with the axis of rotation of the foot contact assembly 4.
In accordance with an embodiment, said food support assembly 4 comprises a foot pulley 47 propelled by a belt 34 of said transmission assembly 20, wherein an axis of said foot pulley is co-axial with a pivoting axis of said foot support assembly 4.
The foot contact (or foot support) assembly 4 comprises a substantially flat piece or plate 52 having some lateral border or rim 128 where the heel of the subject is to be placed or blocked (
In accordance with an embodiment of the invention, the foot support assembly 4 comprises a force/torque sensor 60 arranged to measure the force and/or torque applied by a foot put on said foot support assembly 4 and/or on a foot contact plate 52.
The sensor 60 is placed centrally on the support bar 108. The support structure 108 is connected to a ball bearing on each of its two lateral sides. The two ball bearings harbor each an axle 55, 56 connected to the first and second lateral carrier plates 53, 54, respectively. In this way, the foot contact assembly 4, comprising the support bar 108 with the sensor force/torque sensor 60 and the foot contact plate 52 rigidly fixed on the sensor, is pivotally carried on the foot support carrying assembly 44. In summary, a pivoting movement of the foot contact assembly 4 within the angular span defined above is driven by the third motor 43 and transmitted by transmission assembly 20 to said foot contact assembly. The articulation allowing pivoting movement and/or rotation of the foot contact assembly 4 is also referred to herein as foot support articulation 19.
In accordance with an embodiment, said longitudinal framework subassembly 5 comprises, preferably at its distal end, a first lateral carrier plate 53 and a second lateral carrier plate 54, wherein a pivoting axle 55 is born in a first bearing of said foot contact assembly 4, and/or wherein said axle 55 connects a foot pulley 47 propelled by a belt 34 of said transmission assembly 20 to said foot contact assembly 4 in a co-rotationally fixed manner. Preferably, a second pivoting axle 56 is born in a second bearing of said longitudinal framework subassembly and/or in said second lateral plate 54. Preferably, said first and second pivoting axles 55, 56 are co-axial.
In the embodiment shown, the transmission assembly 20 is based on a system comprising several belt pulleys and belts, in particular transmission units as described above, for transmitting the rotation from the third motor to the foot contact assembly 4. Of course, the rotational movement can be transmitted in other ways, for example by cables, gears, clutches or chains acting on the foot contact assembly 4. It is also possible to use a linear actuator and crankshaft unit for rotating the foot contact assembly, for example. An advantage of using a transmission based on belt pulleys and belts is the good yield and low loss.
It is also noted that the pulleys used in the transmission assembly 20 preferably comprises or consists of one or more cogwheels, as can be seen in
The steel-frame 111 comprises a plurality of steel profiles 122, 122′, 123, 123′ extending at and forming the edges of the cabinet 120. In the embodiment shown, there are four vertical steel profiles 122, 122′, 123, 123′, forming the four vertical edges of the cabinet 120. There are also horizontal steel profiles 124, 124′, 125 for connecting the vertical steel profiles. In the figures, not all the profiles and/or support bars of the steel frame 111 are visible, but can be deducted from the sides of the figures that are shown and from the apparent symmetric construction.
The carrying system 110 comprises a plurality of lateral supports or legs 117, 118, 119, 121, for further stabilizing the device, in particular the cabinet 120 of the invention and/or for preventing the device from falling down and/or tilting. The lateral supports are described at the example of the lateral support or support assembly 117, which is shown on the right in
The carrier system or verticalizer 110 allows the positioning of the device of the invention at any position in a locality, for example in a room, such as rehabilitation or exercising hall or center. The device can also be conveniently displaced by aid of the verticalizer, which would not be the case if one just fixes the ASs 9, 900 or the supports 10, 910 comprising the ASs to a wall, for example.
For example, the drivers 211-213 for driving the motors 41-43 of the right AS 9 can be seen. The three drivers for the motors of the left AS 900 are next to drivers 211-213 (not referenced). Below the drivers, one can see the intermediate I/O unit (e.g. EtherCAT) 207, 1107, described elsewhere in more detail. The cabinet 120 further comprises the power supply units, such as 24V power supplier 214, and an electrical breaker or circuit breaker 214′. In the embodiment shown, the cabinet 120 comprises the voltage transformer 216, which transforms power received from an external power supply to the voltage required by the drives 211 to 213 of the device of the invention. The computer and/or data processing unit 200 can also be seen inside the cabinet 120.
In
For example, the cabinet containing the electronic components may be fixed on a rigid, permanent support, such as a wall, pillar, floor or ceiling, for example. If the cabinet is fixed on its backside to a wall, for example, the device access to the components inside the cabinet is preferably allowed and/or enabled. Instead of a back-door 116, 116′, one or more lateral and/or front doors may be provided for accessing the electronic components in the cabinet. It is noted that the front side is the side on which the device of the invention is fixed, in particular where the ASs are fixed. The ASs may thus be fixed on a front door of the cabinet, for example.
The invention thus encompasses that the cabinet is not free-standing and/or not movable or only movable after unfixing from the permanent support.
In another embodiment, the cabinet 120 may be placed next to the ASs, for example as a separate assembly and/or unit. In this manner, the depth of the entire system is reduced and access of the cabinet is kept free when the ASs are fixed on a wall, for example.
The device of the invention is controlled by a data processing assembly. The data processing assembly comprises a central data processing unit 200, in particular a computer 200 shown on the left side of
Reference numerals 214 and 215 in
In
On the main λ-framework subassembly 5, one can see the sequence of belt/pulley-based reducers, which have been described in more detail with respect to transmission assembly 20 (
The device of the invention comprises motors 41, 42, and 43 for propelling the driving carts 21, 22 and for propelling the rotational movement of the foot support assembly and/or TOC 4. The three motors provide the three degrees of freedom covered by the AS of the invention. The device has preferably at least three degrees of freedom, which encompass a first and second degree of freedom provided by the first and second driving carts 21, 22, which allow the positioning and/or movement of the foot contact assembly and/or TOC 4 within a vertical plane (two axis of space) by using the λ-framework. The third degree of freedom is the ability of rotation of the foot contact assembly and/or TOC 4 on an (horizontal) axis that is perpendicular to said vertical plane of said first and second degree of freedom. As the skilled person will understand, the position of said first and second driving carts directly determines the position of the foot contact assembly and/or TOC 4 in said vertical plane of the first and second degree of freedom. Therefore, for the purpose of the discussion of redundancy features, data concerning the position of the first and second driving carts is equivalent to and/or can be mathematically converted into data concerning the position of the foot contact assembly and/or TOC 4 in said vertical plane.
In general terms, each motor is driven and/or controlled by the data processing assembly. More specifically, each motor 41, 42, and 43 is preferably driven by its own motor driver 211, 212 and 213. The motor drivers may be considered as being part of the data processing assembly. The motor drivers are preferably connected with the computer 200, for example. In particular, the first motor 41 is driven by the first motor driver 211, the second motor 42 is driven by the second motor driver 212 and the third motor is driven by the third motor driver 213. The drivers provide their respective motor with current and voltage required to achieve a required motor action so as to produce a movement of the TOC as desired or targeted.
Furthermore, each motor is connected to a shaft encoder and/or decoder. The first motor 41 is connected to the first shaft encoder and/or decoder 71, the second motor 42 is connected to the second shaft encoder and/or decoder 72 and the third motor 43 to the third shaft encoder and/or decoder 106.
In accordance with an embodiment, the device of the invention comprises motor shaft encoders 71, 72, 106 for determining the rotations and/or, more specifically, the angle covered by the rotation of the respective motor axle, for example. The signals of encoders 71, 72, 106 can be translated to a position of the respective cart 21, 22 driven by the motor 41, 42 on the rails, and/or to an angular position of the foot support assembly 4, driven by the third motor 43. For example, the start or original position of the motor may be related to a start position or a zero position, and, when operating, the position of the motor can be determined as the sum of rotations with respect to the start position. From this information, the position of the cart propelled by the respective motor can be determined. Rotation in the two (opposing) senses may then be treated with different algebraic signs (+/−), so that the position 0 always corresponds to the start position. The start or original position corresponds to a determined position of the cart driven by the motor on the respective rail track. Motor speed may be expressed in terms of number of rotations per time unit.
Preferably, the communication between the computer 200 and each motor 41, 42, 43 and shaft encoder 71, 72, 106 is managed by the respective motor driver 211, 212 and 213. The motor drivers receive information from the respective shaft encoder 71, 72, 106. The information may be selected from information related to the position of the motor (and thus of the driving cart), the speed of the motor, the acceleration, and the couples/moments.
In an embodiment, the motor drivers 211, 212 and 213 manage electrical characteristics to drive the motors. In particular each driver manages motor current intensity of the respective motor. The motor current is in direct relationship with the moment (and/or torque) that should apply. The motor current intensity is related to the force or strength applied by the subject to the foot contact assembly 4 (TOC). Regarding the rotational movement of the foot contact plate 52 and/or the foot contact assembly 4, the current intensity is related to the moment caused by the subject's action on said foot contact plate 52 and/or the foot contact assembly 4 through the transmission chain 20 discussed elsewhere in this specification.
The motor drivers 211, 212 and 213 are preferably arranged to send data and/or information from the respective shaft encoder 71, 72, 106 and/or from the respective motors 41, 42, 43 to the computer 200.
For moving the TOC in accordance with a particular exercise, the computer 200, the motor drivers 211, 212 and 213, the motors 41, 42, and 43 and their respective decoders 71, 72, 106 work together in a synchronized manner, preferably in real time. The driving of the movement of the TOC may also be referred to as movement control or exercise control of the device of the invention. In particular, the computer is programmed to have information regarding a specific trajectory to be executed by the TOC. A given trajectory is part of an exercise, such as the exemplary exercises specified elsewhere in this specification. The computer 200 mathematically transforms the trajectory to data concerning the angular position, speed and/or acceleration of each of the motors and sends this data to the drivers 211, 212 and 213, which transform the instructions to power to be provided to the motors. In turn, the drivers 211, 212 and 213 receive information from the motors and/or in particular from the shaft encoder 71, 72, 106 and send this information to the computer 200, which can thus monitor the trajectories actually performed. The computer 200 assesses if a position of a motor 41, 42, 43 as determined by the respective shaft encoder 71, 72, 106 corresponds to a “target position” of the TOC, for example a target position within the trajectory of the TOC. The computer 200 may adapt information sent to the driver in order to achieve the target position, for example to correct the position of the TOC if its position as measured by the encoders 71, 72, 106 is different from the target position. Also termination program can be triggered if the difference between the target position and the measured position exceeds a threshold value.
Of course, the control of the movement of the TOC involves real time and closed loop procedures and/or programs running on the computer 200 as well as in the motor drivers 211, 212 and 213.
In an embodiment of the invention, information of the motor drivers, in particular information about the current consumed by the motors is used to determine the force applied by the subject to the TOC 4. The current consumed by any motor can be retrieved from the respective motor driver 211, 212 and 213, and this information can be used to determine the force applied on TOC, optionally taking further available information into account. Further information and/or parameters concern the device (e.g. current consumption flow in absence of a subject) and/or the subject doing the exercise. The data processing unit preferably compares the data about current obtained from motor drivers and force/torque sensor to data concerning force on the TOC obtained in another way, as disclosed elsewhere in this specification, for example from the force sensor 60.
The force and/or torque sensor 60 is preferably provided at the TOC, in particular below the foot contact plate 52. The sensor 60 is present in a preferred embodiment of this invention, preferably it is an important element of the device of the invention, because it is the sensor that is closest to the interface with the subject (closest to the TOC). The sensor 60 preferably produces signals concerning the force and torque exerted by the foot of the subject placed on the foot contact plate 52 (
According to a preferred embodiment, the device of the invention comprises one or a plurality of sensors for measuring the force and torque exerted on the foot contact plate 52 by a subject and/or user of the device of the invention.
According to an embodiment, the device of the invention comprises one or a plurality of sensors for measuring the force on the three axes (Fx, Fy, Fz) of space.
According to an embodiment, the device of the invention comprises one or a plurality of sensors for measuring the torque on the three axes (Mx, My, Mz) of space.
Most preferably, the device of the invention comprises one or a plurality of sensors for measuring each force and torque on three axes of space. Preferably, a single six-axis force and torque sensor is used. However, the invention encompasses the use of several sensors for measuring force and torque with respect to all directions. For example, the invention may comprise two sensors 60, one being capable of measuring force on three axes (Fx, Fy, Fz) and the other being capable of measuring torque on three axes (Mx, My, Mz). Alternatively, reference numeral 60 may refer to a plurality of sensors, each sensor measuring force and torque on one axis only (Fx, Mx; Fy, My, and/or Fz, Mz). By combining three such sensors, each sensor measuring force and torque on one of the three special axes, signals with respect to all six axes (three force axes and three torque axes) are produced.
Although measurement of force and torque in all directions (six-axes) is preferred, the invention also encompasses a sensor 60 that measures only force or only torque. Furthermore, the invention encompasses one or more sensors 60 measuring force and torque on only one or only two axes of space (e.g. Fx, Mx and Fy and My), for example.
In accordance with the above said, for the purpose of this specification reference to “the sensor 60” includes specifically also the plural form (“the sensors”) in case there are several sensors as specified above, for example.
In accordance with an embodiment, the sensor 60 is suitable to produce a signal that allows the computer 200 to assess if the foot of a subject is placed on the foot contact plate 52. If no force and/or torque whatsoever is measured by the sensor 60, this means that no subject is positioned on the device and the TOC will not execute an exercise and/or will not produce any TOC movement. On the other hand, if the force and/or torque measured by the sensor 60 exceed a determined threshold value, this can be interpreted by the computer 200 as information that a subject is in contact with the TOC and that an exercise program can be run. The data produced by sensor 60 may thus function as a switch required for running an exercise on the device of the invention.
In accordance with an embodiment, the information produced by the force and/or torque sensor 60 is used together with information concerning the current produced by the motors in order to determine the force or moment on the foot contact assembly. In an embodiment, the information concerning the force and/or torque as determined by sensor 60 is suitable to be used by the computer 200 for determining the power required to achieve a given trajectory. In accordance with this embodiment, the information of the force and/or torque exerted by the subject on the sensor 60 may be transformed to instructions with respect to motor power that is sent to the motors 41, 42, and 43 via drivers 211, 212 and 213, respectively. It is noted, that the data from the force sensor 60 can in particular be used to determine the extent by which the action of the motors are assisted or counteracted by the subject. A given movement is associated with much more power if counteracted actively by the subject. In some exercises, the subject may accompany and/or support the movement driven by the motors, so that the power used by the motors is reduced for a given movement or distance.
In accordance with an embodiment, the information concerning the force and/or torque as determined by sensor 60 is used in safety monitoring procedures, which are more generally discussed elsewhere in this specification. In particular, if a force and/or torque as determined by sensor 60 exceeds a specific (second) threshold value, a safety termination or stopping procedure is rapidly started, for warranting the safety of the subject. The computer 200 can assess whether the data produced by sensor 60 indicates potential damage to the motors, due to overheating, for example. Motor damage or failure could in particular result in a risk for the subject using the device of the invention. The purpose of the force sensor 60, preferably associated with parameters related to the TOC strength on a specific trajectory given by motor speed and position, is mainly to ensure subject security, by braking the AS in case of accident or human failure.
As can be seen in
In particular, the computer 200 runs one or a plurality of monitoring programs adapted to check one or more redundancy features or signals in real time and in a closed loop procedure. The safety system and/or the monitoring programs ensure that the ASs is/are correctly positioned during operation.
According to an embodiment, the device of the invention comprises one or more linear encoders which produce a signal corresponding to the actual position of the driving carts on the longitudinal axis along the rails. In
According to an embodiment, the device of the invention comprises an angle sensor 59, which produces a signal that indicates the angle of the foot contact assembly 4, for example with respect to a reference of the longitudinal main subassembly 5.
According to an embodiment, the device of the invention comprises an angle sensor 63 is situated close to the pivotal connection 51 of the main subassembly 6 with the support subassembly 5. The angle sensor 63 measures the angle between those two subassemblies.
The signal produced by any one or both of the angle sensor 59 and/or angle sensor 63 may be sent, independently to the intermediate device 207 and/or directly to the data processing unit 200, for example.
In accordance with the safety and/or monitoring system of the device of the invention, the data processing unit 200 of the invention is programmed to compare redundant data related to a position of said first and/or second carts and/or to a position of the Tool Operating Center (TOC) of the device, and to start one or more selected from a correction or termination program in case the data processing unit detects a determined inconsistency between the redundant data.
For the purpose of the present invention, the expressions “redundant data” and/or “redundant information” refer to data and/or information concerning a parameter of the device that is determined at least two times independently. Data may be determined more than two times, in particular n-times, with n being 1, 2, 3 or 4, or more, resulting in n-times redundant data. 1-time redundant data means that information concerning a parameter is obtained independently at least two times. The parameter may be any parameter that may be considered to be relevant for the controlled and safe operation of the device. Typically, the parameter is related or corresponds to the position of one or both driving carts, 21, 22, the angular position, the force and/or torque of the foot contact assembly 4, the angle between the main and support beams 5 and 6, just to mention a few examples. The fact of obtaining and using redundant data provides the “redundancy features” of the device of invention.
A “termination program”, “exit program” or “emergency program” is a stop, braking and/or any type of program which results in the immediate abort of an exercise and brakes the motors of the devices of the invention. The purpose of braking the device is to prevent damage to the subject using the device of the invention. It is noted, in this regard, that the motors 41, 42, 43 are all independently equipped with brakes. The brakes are activated in accordance with the emergency and/or termination program. The brakes are preferably automatically activated in case of any type of anomaly, including a power cut, for example. In this way, the ASs is blocked at a specific position by the brakes and is prevented from falling down under the effect of gravity or from conducting any uncontrolled movement in general.
The expression “determined inconsistency” refers to the fact that the data processing unit assesses or is programmed to assess whether any inconsistency between redundant data is sufficiently relevant for requiring the start of a specific program. The relevance of an inconsistency may be assessed by comparison with a predetermined threshold value. In general, a specific program for correcting the position or for terminating the operation of the device is started only if the threshold value is reached or exceeded.
A “correction program” is a program that aims at obtaining and/or restoring consistency between the redundant data. Accordingly, a correction program generally sends instructions to any one or more motors of the device to speed up or slow down, as applicable.
Preferably, in the real time system and/or program, there is a “monitoring block” that checks every time unit at the millisecond range that the principal sensor values are matching with the values of the redundant sensors. If the difference of these values exceeded the maximum of the tolerance and/or threshold value, the system stops and insures the security of the subject. In normal operation, this should not happen. Preferably, the control and/or monitoring systems and/or programs of the invention function in real time.
For example, information received from the sensors is received and interpreted in real time. In other words, inconsistencies or deviations from threshold parameters are detected in the range of seconds, preferably within less than a second, less than 0.1 seconds, more preferably less than 0.01 second, even more preferably within less than 10 milliseconds, in particular within 1 milliseconds.
According to an embodiment, the device of the invention comprises a plurality of sensors 59, 60, 61, 62, 63 sending information to a data processing unit 200 to provide a monitoring of the device of the invention.
The linear encoders 61 and 62 provide information with respect the position of the first and second carts 21, 22, respectively on their respective rails tracks. Information with respect to the position of said first and second carts is also provided by the first and second shaft encoders 71, 72, respectively. The information produced by linear encoders 61, 62 and shaft encoders 71, 72 is thus redundant. The data processing unit 200 preferably runs a program, which compares the data from linear encoder 61 with the redundant data received from shaft encoder 71 and/or the data from linear encoder 62 with the redundant data received from shaft encoder 72. Of course, it is not relevant which data is considered to be redundant, as the data of shaft encoder 71 is redundant with the data of linear encoder 61 and vice versa.
If the data processing unit 200 detects any determined inconsistency and/or deviation when comparing the redundant data received, a correction or termination program is preferably triggered.
Preferably, the data processing unit 200 receives redundant information regarding the position of first and second carts 21 and 22 in real time and/or within a very short time delay following sending the instructions to the first and second motors 41 and 42. In this manner, regarding the security, the real time monitoring system of the invention is provided.
The angle sensor 63, measuring angle γ in
In particular, as can be seen from
Accordingly, the angle sensor 63 produces information related to the differential position of the driving carts 21 and 22, and thereby provides further redundant information concerning the position of the driving carts. The data processing unit 200 further compares the data of angle sensor 63 with the data received from either liner encoders 61 and 62 and/or with data received from shaft encoders 71 and 72. Again, redundant data are compared in real time in a monitoring control system and the emergency program is activated upon detection of inconsistencies between redundant data.
A further redundancy feature concerns the position of the foot contact assembly 4. The angle φ (
Angle φ can also be retrieved or determined from data produced by the encoder 106, which can also include or comprise a shaft or rotary encoder 106. The shaft encoder 106 thus provides information, which can be translated to a parameter, such as the angle, which can then be compared with the other data concerning the same parameter.
In an embodiment, the device of the invention comprises a data processing unit 200, which is programmed to compare redundant data related to an angular position of said foot contact assembly 4 and/or of said Tool Operating Center (TOC) 4 of the device, and to start a correction or a termination program in case the data processing unit 200 detects a determined inconsistency between the redundant data.
The data processing unit 200 compares data received from angle sensor 59 with data from the shaft encoder 106, preferably within a very short time delay (e.g. in real time) following sending the instructions to the third motors 43, more preferably in real-time, thereby providing said a monitoring. In case of inconsistency, a correction or termination procedure is triggered, as described elsewhere in this specification. As the data processing unit 200 sends instructions to the third motor driver 43, the data of sensor 59 and/or of encoder 106 can be compared to the instructions sent previously to the motor.
A further redundancy feature concerns the current intensity of the motors 41, 42 and 43 and the information produced by the force and/or torque sensor 60, measuring the load, in particular the force and/or torque applied on the foot contact assembly and/or TOC 4. The force and/or torque measured by sensor 60 is thus redundant with the current intensity of the motors.
In an embodiment, the data processing unit 200 compares data received from the force and/or torque sensor 60 with data concerning the current intensity of the motors. As described elsewhere in this specification, the information concerning the current intensity is part of the data that the motor drivers 211, 212 and 213 to the computer 200.
When comparing redundant information and/or data, the data processing unit 200 checks if there are inconsistencies between comparable parameters and if these inconsistencies reach or exceed a specific threshold value. If the threshold value is reached, the termination computer procedure is run.
In the embodiment, the device of the invention comprises electronic stoppers 208, 209 and 208′, 209′. An electronic stopper is preferably provided at the extremity and/or end of each rail track section 11/12 and 13/14, respectively. For example, at the two extremities of rail track section 11/12, electronic stoppers 208 and 209 are provided, respectively. The electronic stoppers/encoders of the second pair of rails 13, 14 and the second drive screw 32 are indicated with reference numerals 208′ and 209′. The electronic stoppers may be fixed on the support structure 68 for the rails (
In the embodiment shown in
In another, alternative embodiment, the data produced by the electronic stoppers is transmitted to the motor drivers, such as to 211, 212 and/or 213. The drivers may directly brake the motors down following receipt of a signal from any one or more of the electronic stoppers, indicating the presence of a cart at the end point of a rail track. According to a still other embodiment, the data produced by the electronic stoppers is transmitted directly to the computer 200.
In
As has been described above with reference to
For using the device of the invention, the feet of a subject are attached to the left and right foot contact areas 904, 4. Depending on the orientation of the ASs 9, 900, the subject takes place in a seat in front of the device, on a bed or in any applicable position (
Stabilization of the legs or articulations of the subject is conducted by way of external splints possibly comprising articulations. Since the device of the invention lacks an exoskeleton for stabilizing the limbs of the subject, such external stabilizers (exoskeleton, splints, etc) are preferably used for stabilizing or guiding the movement of the lower limbs during exercising. This applies in particular to subjects that cannot control their lower limbs, such as para- or tetraplegic patients, for example.
Detailed information regarding the subject has to be available to the computer before any exercise can be started. This detailed information comprises detailed biometric data of the subject, such as the positions or distances between the articulations, in particular between the hip, knee and ankle articulations. Biometric data concerning the size, weight, age, sex of the subject is collected, as well as any information regarding a possible handicap, such as paralysis, or also regarding constraints with respect to the degrees of freedom of the movement of the subject. This information determines the extent or distances run by the ASs once an exercise starts.
The device of the invention is destined to different types of users and/or subjects. For the purpose of this specification, the term “subject” is used for an individual that can use or that uses the device of the invention. The device of the invention can be operated as a wellness device for healthy subjects and/or elderly subjects, for example. The device of the invention can be used for wellness purposes in general.
According to an embodiment, the device of the invention is suitable to re-educate or train the lower limbs of subjects having an impairment of the central nervous system, such as a subject suffering from tetraplegia, paraplegia or hemiplegia, subjects suffering from muscular atrophy, geriatric subjects, subjects suffering from traumatic injuries of the lower limbs, multiple trauma patients, subjects that have undergone surgery, for example of the hips or lower limbs, in particular subjects having undergone surgery to receive a prosthesis, subjects having received a prosthesis, such as an artificial limb or joint, such as an artificial hip or knee, for example.
The device of the invention is suitable to re-educate subjects suffering from bone fracture, injuries of the ligaments (torn or overstretched), and/or subjects suffering from multiple trauma.
The device is thus not limited to being used by subjects that are totally or partially paralyzed (e.g. patient suffering from paraplegia), but also subjects that are not suffering from paraplegia. For example, the device can be used for training patients that need exercising of the lower limbs for any reason, including non-medical reasons.
The device of the invention can be run in different modes. In a first mode the subject is passive, and the movements are substantially controlled by the device. In this case, the movements, including movement speed, of the ASs are entirely determined by the device and/or the computer. The muscles of the subject to not contribute to the movement of the ASs in this mode, or, in other words, the ASs have to be moved against resistance due to gravity of the device itself and due to the limbs of the subject fixed on the device. The exercises in this mode will be run by paraplegic or tetraplegia patients, for example. In another mode, the motors only guide the movement, but muscular efforts by the subject are required to make the ASs move. The motors may provide a controlled resistance to the movement of the ASs. In this type of mode, the patient trains his/her muscles actively, by own activity. This type of exercise is suitable, of course, for patients that are still able to control, even a little and/or not totally, the movement of their lower limbs.
As the skilled person will understand, the ASs of the invention are constructed to allow any type of movement and/or exercise within the sagittal plane in which the ASs are situated. The device has three degrees of freedom, of which two concern the position in an sagittal (vertical) plane, and the third the angular position of the foot contact assembly 4.
Circular movements as well as linear movements and movements comprising a combination of linear or curved parts can be conducted. Just to mention a few examples, a typical exercise is “cycling”. In this exercise, the foot contact area 4 is moved by the λ-framework so as to conduct circular movements, and the left and right ASs are offset by 180° degrees (half a circle), as is the case with the pedals of a bicycle. Of course, the pedal 4 also performs a defined, regular angular movement in addition to the circular, so as to take the ankle movement of the subject into account.
Another type of exercise is the “press-leg” or the leg part of the rowing movement. In this exercise, the pedal 4 is moved back and forth by λ-framework along a straight line. Of course, the pedal 4 also performs a defined, regular angular movement in addition to the linear, straight line-movement, so as to take the ankle movement of the subject into account. In this exercise, both ASs 9, 900 will move substantially synchronously, unless the anatomy of the subject requires an offset movement, for example, or an independent, non-synchronous movement.
Besides these two types of exemplary exercises, the device of the invention can be programmed to conduct a nearly indefinite number of movements and exercising in which the two ASs conduct any determined movement, synchronously or independently.
The control system of the device of the invention comprises memories for stocking the data associated with a subject, such as the biometric date set out above. Furthermore, the control system of the invention is preferably capable of storing data produced during an exercise. These data include the length, numbers of repetition of the exercise. Furthermore, regarding a specific exercise, all data are stored immediately in the memory of the device. This includes data received from the sensors recoded during the exercise. The exercise can be analysed in real time (in the course of the exercise) or after the exercise by a medically trained person and/or an assistant. Forces exerted by the subject during the exercises and torques measured by force and/or torque sensor 60 are recorded and can be analysed. In this manner, it is also possible to detect spasms that occurred during an exercise and to check in what position/movement such spasms occurred, for example. In this way, the exercise can be adapted to the needs and capacities of the subject and/or patient using the device.
The present invention encompasses serious games for the purpose of training and/or exercising. In accordance with an embodiment, the device of the invention preferably comprises at least one output unit producing serious games and/or a virtual or extended environment or reality for the subject. For example, serious games and/or the virtual reality can be a visual or optical games and/or reality, displayed on a screen and/or on head-mounted displays in the form of glasses or a helmet, for example. The serious game and/or virtual reality may comprise or essentially consist of an audible game and/or reality. According to an embodiment, the serious game and/or virtual reality is an audio-visual game and/or reality. In accordance with an embodiment, the serious game and/or virtual reality is related to a specific exercise. For example, in case of a cycling exercise, the virtual reality may comprise a visual reality of cycling, for example in a cycling tour and/or on a track. The bicycle and/or parts thereof may be part of the virtual reality produced by a computer program and/or the computer 200. As another example, in case of a rowing exercise, the virtual reality may exhibit a water body, and/or a rowing boat and/or parts thereof. The serious games and/or virtual reality may simulate a competitive environment, with competing bicycles and/or rowing boats as applicable, for example. Preferably, the serious game and/or virtual reality is adapted to, related to, tuned with or timed with a specific type of exercises. In this regard, characteristics of an exercise are related to events taking place in the serious game and/or the virtual reality. Or, the other way round, the serious game and/or virtual reality is tuned with characteristics of the exercise. For example, in the cycling environment, if there is an ascending slope, the ASs and/or TOCs conduct the cycling movement more slowly, the latter being an example of a characteristic of the exercise as programmed. On the other hand, when there is a decreasing slope, the ASs and/or TOCs move more rapidly and the background of the virtual passes by more quickly. The virtual reality may produce obstacles, associated with and/or corresponding to changes in the regular movement of the ASs at the same time. The obstacle is thus a characteristic of the virtual reality, related to the characteristic of the irregular movement of the ASs, as determined by the program running the motor drivers. Of course, one can envisage different games that can accompany the various exercises that can be conducted by the device of the invention. The games are preferably run by a computer and/or data processing machine 200 and produce a virtual reality related to a given exercise. Of course, it is much more entertaining and/or motivating to exercise in the environment of a virtual reality. The present invention allows thus combining useful or even necessary training with a playful and/or funny environment, in particular with a virtual environment. This combination is preferably controlled by the computer or control system 200.
In accordance with an embodiment, said control system 200 comprises an output unit for producing serious game and/or a virtual reality, wherein said output unit is arranged to exhibit the serious game and/or virtual reality to a subject of the device during an exercise, wherein said serious game and/or virtual reality is related to, tuned with and/or timed with characteristics of the exercise. Preferably, the serious game and/or virtual reality is related to, tuned with and/or timed with movements of the ASs and/or TOCs.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/065366 | 7/19/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/007349 | 1/22/2015 | WO | A |
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Number | Date | Country | |
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20160158086 A1 | Jun 2016 | US |