FR2972340A1 - Sensor device for use in rehabilitation apparatus for exercising shoulders of body of e.g. sportsman in gym, has sleeve including sensors, each comprising strain gauge to measure force exerted on handle of apparatus - Google Patents

Abstract

The device has a sleeve (30) to surround a handle (16) of a rehabilitation apparatus, where the sleeve includes sensors (32, 34) secured to an inner surface of the sleeve in contact with the handle. Each sensor includes a strain gauge to measure force exerted on the handle and to communicate the measurement results to a data acquisition card. Each sensor includes a bending zone (48) between fixing areas (50, 52), where the bending zone rests on the handle, and the fixing areas are fixed to the sleeve.

Description

The present invention relates to rehabilitation and weight training devices intended to be used in gym or at home such as devices equipped with apparatus for exercising the upper limbs and whose bearing surface is a movable tray and concerns in particular a sensor device for a rehabilitation device. There are devices with a vibrating plate such as that described in WO 2008/129162 which generate vertical unidirectional vibrations. When an individual is positioned on the vibrating plate in operation, his body undergoes a slight imbalance immediately triggering the myotatic reflex (reflex muscle contractions) which allows the rebalancing. This 1.5 type of work requiring both the perception of movement within the body and triggering muscular adaptation actions is called proprioception work. It is very effective in the preparation of sportsmen and in rehabilitation because it makes it possible to work the capacity of the muscle not used in exercises where muscular work "reflex" does not intervene. The disadvantage of such vibrating plate devices is that they do not work the upper body and especially the arms and shoulders. There are, however, apparatus for exercising the upper body. Most of these devices have a more or less sophisticated structure consisting of bars or tubes. The patient then exerts a special effort with the hand on one or the other of these bars, depending on the exercise requested. The simple visual or tactile appreciation of the effort is both imprecise and subjective. It can be very useful for the practitioner to know precisely at that moment the forces exerted by his patient. The knowledge of these efforts makes it possible to highlight the points of strength and weakness, the imbalances, and above all to quantify the progress made by the patient. This is particularly true for example in the case of shoulder rehabilitation where the patient must involve specific muscle groups. It is useful in this case to measure the forces produced by each arm in the three directions. It is difficult to directly measure the forces on the structure of the device. Indeed, the useful efforts to know are the linear components at the level of the hand. But the sensors used in existing devices measure the reactions on the structure, and these reactions depend on the moments, that is to say, the force exerted by the hand and its position on the structure. Since it is not possible to measure forces in all three directions with a single sensor, some device manufacturers have circumvented the problem by positioning sensors at various points in the structure. They thus obtain a partial measure, but are strongly limited by economic and mechanical constraints. Therefore, the object of the invention is to overcome the aforementioned drawbacks by providing a sensor device for measuring the forces in a plane directly at the hand in an apparatus of rehabilitation of the upper body. The object of the invention is therefore a sensor device in an upper body rehabilitation device comprising at least one handle intended to be grasped by a user and on which efforts are exerted by the user during an exercise. rehabilitation. This device comprises a sleeve adapted to surround the tube of the handle and comprising at least one sensor fixed on its inner surface in permanent contact with the tube of the handle, the sensor comprising at least one strain gauge to measure the forces exerted on the tube of the handle by the hand of the user and communicate the results of the measurement to a data acquisition card or electronic conditioning circuit and a display or other means of reading a voltage. According to an important characteristic of the invention, each sensor comprises a zone of flexion between two fixing zones, the bending zone being supported on the tube of the handle by two points of support, and the fixing zones being fixed to said sleeve. so as to communicate to the bending zone the forces exerted by the user on the tube via the sleeve. The objects, objects and features of the invention will appear more clearly on reading the following description with reference to the drawings, in which: FIG. 1 represents a rehabilitation apparatus comprising a sensor device according to the invention, FIG. represents a cross-sectional view of the device according to the invention comprising a sleeve provided with four sensors and surrounding the tube of the handle; Fig. 3 is a longitudinal sectional view of the sleeve shown in Fig. 2; Fig. 4 is a longitudinal sectional view of the bending region of the sensor; and Figure 5 shows a sensor device according to the invention in two parts and can be installed at any point on the handle. The sensor device according to the invention can advantageously be integrated into any apparatus for reeducation of the upper part of the body of the type of the apparatus shown in FIG. 1. A device 10 for the rehabilitation of the upper part of the body comprises a rigid plate 20 mounted on a vertical axis 12 attached to a foot 11 placed on the ground. The axis 12 is in the direction of the vertical axis. The rigid plate 20 can be mounted on the axis 12 by a sliding connection for sliding vertically along the foot 12 and thus adjust to the size of the user. Quick fastening means or controlled means such as an electric jack can immobilize the vibrating device along the axis 12. The vertical axis 12 can be equipped with a hinge 22 allowing a rotation of the portion located above the joint in a vertical plane schematized by the plane of the sheet in the front view of Figure 1. Two arms 13 and 14 are fixed rigidly on the rigid plate 20. Note that the two arms 13 and 14 may be either hollow tubes or bars and therefore solid tubes, hereinafter referred to as tubes. They each comprise a hinge 23 and 24 allowing them to bend in the horizontal plane. Each articulation 23 and 24 has a return means (not shown) which tends to maintain the unfolded articulation. The arms 13 and 14 of the apparatus at rest are unfolded so that for each arm, the portion located before the articulation is aligned with the portion after the joint. The two arms 13 or 14 respectively have a handle 16 or 17 slidably fixed along the arms. A quick fastening means makes it possible to immobilize or release the handle on the arm and thus adjust its position on the arm according to the morphology and the span of the user of each user. Note that the device could have only one arm 13 or 14.

On the other hand, the rigid plate 20 can pivot about an axis aligned on the horizontal axis perpendicular to the plane of the sheet, which allows to adjust its position, depending on the desired exercise, at a maximum angle of 90 ° to the horizontal position, ie a total angle of 180 °. The pivot connection which allows this rotation is placed between the sliding connection along the axis 12 and the vibrating device. This link can be blocked or left free. The rotational movement obtained with this pivot connection is in a vertical plane (Y, Z) schematized by the plane of the sheet in the front view of Figure 1. Note that the rigid plate could be a vibrating device comprising a vibrating plate covered with a cover 21. In this case, the vibrations induced by the vibrating plate are transmitted to the handles 16 and 17 and therefore to the user via the arms 13 and 14. A sensor device according to the invention. The invention is normally attached to each of the handles 16 and 17 of the rehabilitation apparatus 10, although only one sensor device could be attached to one of the handles 16 or 17. Thus, with reference to FIG. of sensors is shown in section is fixed on the handle 16. It comprises a sleeve 30 which surrounds the tube of the handle 16. The sleeve 30 has four sensors 32, 34, 36 and 38 fixed on its inner face and about 90 ° the each other's that the sensors 32 and 36 are in the same plane and the sensors 34 and 38 are in the same plane also but perpendicular to the other plane. As will be seen below, each sensor bears on the tube of the handle 16.

Because of the position of the sensors at 90 ° to one another, two opposite sensors are stressed by forces exerted by the user's hand in a plane and the two other opposing sensors are stressed by forces exerted on them. a perpendicular plane. As has been mentioned with reference to FIG. 1, the handle of the user-operated rehabilitation apparatus can take, due to the different articulations of the apparatus and the possible rotation of the vibrating device about an axis. horizontal, a horizontal position, a vertical position or an intermediate position. Therefore, in a certain type of rehabilitation, the handle 16 shown in Figure 2 being in a horizontal position, the user's hand that surrounds the handle can exert efforts in a vertical plane, a vertical force F1 down which urges the sensor 32 and a vertical force F2 upwards which solicits the sensor 36. Similarly, the hand can exert forces in a horizontal plane, a horizontal force F3 towards the front which solicits the sensor 34 and a force rearward F4 that solicits the sensor 38. Assuming that the handle is in the vertical position, the user's hand can then exert, in addition to horizontal forces F3 forward and F4 backwards, horizontal forces Fl to the left side and F2 to the right side. Note that it is not essential that each sensor device has four sensors. It depends on the type of rehabilitation to be performed. We can consider a sensor device having only one, two or three sensors without departing from the scope of the invention. Figure 3 shows the longitudinal section of the tube of the handle 16 at the location of the sensors 32 and 36. As seen in the figure, each sensor is attached to the sleeve 30 by four screws. Thus, the sensor 32 is fixed by the screws 40, 42, 44 and 46 on the sleeve 30. The sensor 32 comprises three zones in the extension of one another and therefore integral: a central zone or flexion zone 48 located between the screws 42 and 44 and without contact with the sleeve, and two attachment zones 50 and 52 on either side of the central zone 48 without contact with the tube of the handle. The fixing zone 50 is located between the screws 40 and 42 and the fixing zone 52 is located between the screws 44 and 46. The flexion zone 48 illustrated in FIG. 4 comprises two small zones 60 and 62 which serve as points of contact. It should be noted that the sensor has no other point of contact with the tube of the handle. When a force is produced by the user, the thrust exerted by the hand of the user on the tube is transmitted to the bearing points 60 and 62 via the attachment zones 50 and 52. Bending zone 48 undergoes a bending moment that induces tensile and compressive stresses in the zone. In order to measure the stresses induced in the bending zone 48, resistive strain gages, also called strain gages, are placed in this zone. If only one strain gauge is installed, it is in the middle of the flexion zone 48. But, as is well known, it is preferable to install four strain gauges in the middle of the bending zone between the points. 60 and 62 in a Wheatstone bridge arrangement (not shown) powered by a constant voltage generator between two opposite points of the bridge. A voltmeter is connected between the other two opposite points of the bridge and makes it possible to measure any voltage variation which is proportional to the relative resistance variations of the strain gauges which constitute the branches of the bridge and therefore of the stresses induced in the bending zone. The connection between the strain gauges and the voltmeter located at another place of the apparatus can be made by wires running along the tubes of the apparatus. In order to keep the traceability of the exercise performed which is essential during medical treatments, the voltage variation measuring signal is recorded in a data acquisition card or transmitted to an electronic conditioning circuit and a display or any other means of reading a voltage. It should be noted that the conditioning electronics of the strain gauges can be integrated in the sleeve 30. In this case, it is advisable to also integrate a wireless transmission means for transmitting to measurement results to the acquisition card. an autonomous battery-type power thus allowing a great comfort of use autonomy of the sensor. The sleeve 30 having the four sensors 38 must have a length at least equal to the hand to provide a good grip of the data and battery distance, and a total

32, 34, 36 and width of the handle to the user, about 10 cm. The sleeve can be permanently installed on the handle tube 16 or installed anywhere on the handle. In this case, it is possible to provide a sleeve in two articulated parts illustrated in FIG. 5. A first largest part 70 comprising the sensors 32, 36 and 38 is connected to a mobile part 72 comprising the sensor 34 by a hinge 74. When the user wants to install the sensor device on the handle, he grasps the portion 70 of the sleeve while inserting his index finger in the strap 76 attached to the portion 72 of the sleeve. By producing a slight effort, it engages the tube of the handle 16 in the portion 70 of the sleeve. It then suffices to close the portion 72 of the sleeve on the tube of the handle 16 with his index finger to get the contact of the four sensors with the tube. Note that one can provide a clipping member of the portion 72 on the portion 70 so that the sensors remain in contact with the tube. Note that the sensor device according to the invention can be used on a rehabilitation device having a vibrating plate of the type described in the international patent application WO 2008/129162 and on which the user is standing .

Claims (10)

REVENDICATIONS1. Sensor device in a device (10) for the rehabilitation of the upper part of the body comprising at least one handle (16) intended to be grasped by a user and on which efforts are exerted by the user during a reeducation exercise said device characterized in that it comprises a sleeve (30) adapted to surround the tube of the handle, said sleeve comprising at least one sensor (32, 34, 36, 38) fixed on its inner surface in permanent contact with said tube of the handle, said sensor comprising at least one strain gauge for measuring the forces exerted on said tube and communicating the results of the measurement to a data acquisition card. 2. Device according to claim 1, wherein said at least one sensor (32, 34, 36, 38) comprises a bending zone (48) between two attachment zones (50, 52), said bending zone being in abutment. on said handle tube (16) by two bearing points (60, 62), and said attachment regions being fixed to said sleeve (30) so as to communicate the forces exerted by the user on said tube by the intermediate said sleeve to said bending zone. 3. Device according to claim 1, wherein said attachment zones (50, 52) are fixed to said sleeve (30) by screws (40, 42 and 44, 46) and are not in contact with said handle tube (16) while said bending zone (48) is integral with said fixing areas without being in contact with said sleeve. 4. Device according to claim 2 or 3, wherein said at least one sensor (32, 34, 36, 38) comprises four stress gauges located in the center of said bending zone (48) between said support points (60, 62), said gages being arranged in Wheatstone bridge powered by a constant voltage generator between two opposite points of said bridge. 5. Device according to claim 4, wherein a 40 voltmeter is connected between the two other opposite points of the bridge and makes it possible to measure any voltage variation which is proportional to the relative resistance variations of said strain gauges constituting the branches of said Wheatstone bridge. . 45 The apparatus of claim 5, wherein said voltmeter is integrated in said sleeve and said device comprises wireless transmission means and an autonomous power supply for remotely transmitting the measurement results to said data acquisition card. 7. Device according to one of claims 1 to 6, comprising four sensors (32, 34, 36 and 38) fixed on the inner surface of said sleeve (30) at about 90 ° to each other so that two opposed sensors are biased by forces exerted by the hand of the user in a plane and that the other two opposite sensors are solicited by forces exerted in a perpendicular plane. 60 8.The device of claim 7, wherein said sleeve (30) is composed of two articulated parts, a first portion (70) having three of the sensors (32, 36 and 38) to a movable portion (72) having the fourth sensor 65 (34) connected to the first portion by a hinge (74) so that the user can install the sensor device at any point of the handle by gripping said first portion of the sleeve while inserting its index finger into a strap (76) attached to said movable portion (72) 70 producing a slight force, then engaging the handle tube (16) in said first portion and finally closing said movable portion on the handle tube with the aid of its index to get the four sensors to touch the tube. 75 9. Rehabilitation apparatus of the upper body comprising at least one sensor device according to one of the preceding claims. 80 10. upper body rehabilitation apparatus according to claim 9, comprising at least one vibrating device such as a vibrating plate.