JP2019097584A - Motion training device - Google Patents

Abstract

To provide a method of controlling optimally a drive motor in a motion training device for training in a state of engaging an upper extremity or lower extremity of a user to an operation part which linearly moves in an inclination direction by the drive motor.SOLUTION: A motion training device comprises: a first actuator part 21 having a first drive motor for linearly moving an operation part 3 in a cross direction along a first guide part 23; a second actuator part 22 having a second drive motor for linearly moving the first actuator part in a lateral direction along a second guide part 33; a control part; a force sensor for detecting force which the operation part receives from the upper or lower extremity of a user; and an inclination sensor 77 for detecting inclination of a device body 2. The control part controls the first drive motor and second drive motor according to force components in the cross and lateral directions of force of the user detected by the force sensor, based on the inclination of the device body 2 detected by the inclination sensor.SELECTED DRAWING: Figure 2

Description

  The present invention relates particularly to an exercise training device for improving the user's exercise function.

  Conventionally, in order to improve a person's motor function, various exercise training according to the motor function is performed. For example, in order to improve the motor function of the upper and lower limbs of the user, wiping motion training in which the shoulders and elbows are flexed and extended by wiping the desktop, and for strengthening the upper limbs and improving the range of motion of joints. Sanding motion training is widely practiced by sliding the hand up and down on a sloped board. And various training devices have been developed and proposed to support these exercises.

  For example, the upper and lower left and right and up and down directions by the linear drive device including the reversible rotation motor provided at the guide member and the crossing portion for the upper limb suspension supporting device suspended from the crossing portion of the two guide members An upper limb function recovery training support device that has been made movable is proposed (see, for example, Patent Document 1). The motion of the upper limb of the user supported by the upper limb suspension support device is detected by the sensor device, and the difference between the motion trajectory and the target trajectory is processed by the computer and fed back to the image display device. Can visually recognize the training status.

  Also, there is known a training device that reciprocates a base member to which the user's lower limbs or upper limbs are fixed by the reciprocating mechanism part of the device body, and performs flexion and extension of the crotch, knees, feet or shoulders, elbows, hands. (See, for example, Patent Document 2). The device body can be used not only in the horizontal position but also in the inclined position and the vertical position by standing and fixing the arms attached to both longitudinal side surfaces. The reciprocation mechanism unit is a rodless type that slides a slide table for fixing the base member to a feed screw that is rotationally driven by a motor and guides the screw axially, or slides axially in the cylinder tube by air pressure. The structure integrally attached to the piston of the cylinder is employed.

Unexamined-Japanese-Patent No. 2000-271180 JP 2002-119555 A

  Normal sanding training is performed by the user manually sliding the sanding block up and down on the slope of the sanding board. At this time, the inclination angle of the sanding board and the weight of the sanding block are set in accordance with the load applied to the user.

  The conventional device described in Patent Document 2 can be used for sanding operation training by tilting the device body with respect to the floor surface. However, the base member that the user slides up and down at that time is heavier than the sanding block used for normal sanding operation training, and the load received by the user from the sanding block is dependent on the degree of inclination of the device body. It changes greatly. Further, in the reciprocating mechanism, the torque of the motor for driving the base member fluctuates depending on the magnitude of the applied current, and the driving force of the piston of the rodless cylinder varies depending on the supplied air pressure.

  As a result, an excessive or small load or an unexpected load fluctuation may occur during training, which may cause the user to feel uncomfortable or the training may not be performed sufficiently effectively. Furthermore, the load to be given to the user may differ depending on the user and / or the purpose, conditions, etc. of the training, and it is not easy to adjust only by the degree of inclination.

  Therefore, the present invention has been made in view of the problems of the prior art described above, and its object is to use an electric motor to support training for improving the motor function of the upper and / or lower limbs of the user. In the exercise training apparatus which causes the user's upper or lower limbs to be engaged with the operation unit which can be driven to move linearly in the tilt direction, the purpose, conditions, etc. of the user or the training are adjusted according to the degree of tilt. Another object of the present invention is to control the electric motor so that the operation of the operation unit can be adjusted so that the load given to the user is always optimized.

The exercise training device of the present invention is made to achieve the above object,
An exercise training device for improving a person's motor function,
Device frame,
An operation unit capable of moving the position within the device frame;
A first guide portion for linearly moving the operation portion along the first direction; and a first drive motor for driving the operation portion along the first guide portion or applying a load to the movement thereof. A first actuator unit,
A control unit for controlling the drive or load of the first drive motor;
The operating unit is moved by the user's upper or lower leg against the driving force of the first drive motor along the first guide unit, or when moving the upper or lower arm of the user by the first driving motor driving force. A force sensor for detecting a force that the operation unit receives from the upper or lower limbs of the user,
An inclination detection unit for detecting an inclination of the first actuator unit along the first direction;
The force sensor is provided at or near the operation unit to detect a force component of at least a first direction of the force received from the upper or lower limbs of the user.
The control unit controls the first drive motor in response to the force component of the user's force in the first direction detected by the force sensor based on the inclination of the first actuator detected by the inclination detection unit. It is characterized by

  According to the exercise training device of the present invention, the control unit controls the first drive motor in response to the force component of the user's force detected by the force sensor in the first direction, and the inclination detection unit detects the first The drive or load of the first drive motor can be adjusted based on the tilt state of the actuator unit, for example, the direction and angle of the tilt. Therefore, exercise training of the upper or lower limb can be performed with an optimum load without giving discomfort to the user regardless of the user or the purpose or condition of the training.

BRIEF DESCRIPTION OF THE DRAWINGS The perspective view which shows 1st Embodiment of the exercise training apparatus of this invention. FIG. 2 is a perspective view showing an apparatus main body of the first embodiment. Sectional drawing of the apparatus main body in the III-III line of FIG. Sectional drawing of the apparatus main body in the IV-IV line of FIG. The disassembled perspective view of the actuator mechanism of the apparatus main body. The elements on larger scale of the 1st actuator part in FIG. The elements on larger scale of the 2nd actuator part in FIG. The top view of the actuator mechanism which shows the home position of an operation part. The top view of the actuator mechanism which shows the movement range of the operation part. FIG. 2 is a block diagram of a control unit of the first embodiment. FIG. 7 is a diagram showing basic control of the output of the drive motor in the first embodiment. The perspective view which shows the apparatus main body of 2nd Embodiment of this invention. The side sectional view of the main part of a device showing support leg structure of a 2nd embodiment. Sectional drawing of a support leg structure. The block diagram of the control part of 2nd Embodiment. Explanatory drawing which shows the use condition of 2nd Embodiment notionally. Explanatory drawing of output control of the drive motor in 2nd Embodiment. The block diagram of the control part of the exercise training apparatus of 3rd Embodiment of this invention. FIG. 16 is a view showing the moving direction of the operation unit in the first operation mode of the third embodiment. The figure which shows the moving direction of the operation part in the 2nd operation mode of 3rd Embodiment.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. The exercise training apparatus 1 of the first embodiment shown in FIG. 1 is used particularly for exercise training performed for the purpose of improving the exercise function of the user U. Similar components are denoted by like reference numerals throughout the attached drawings and the present specification.

  The exercise training apparatus 1 is composed of a rectangular box-shaped apparatus main body 2 having a relatively low height as a whole, and is used by being mounted on a horizontal installation surface. As shown in FIG. 1, the exercise training apparatus 1 has an operation unit 3 projecting from the upper surface of the apparatus main body 2, and the periphery of the operation unit is substantially entirely covered by upper surface covers 4 a to 4 d. In FIG. 1, the user U is located on the front side of the exercise training device 1 and, for example, in order to perform wiping operation training, the right arm UL is extended forward and the operation unit 3 is gripped with the right hand HR. In the present specification, the front side of the user U in the exercise training apparatus 1 of FIG. 1 is referred to as the front side, and the back side is referred to as the rear side.

  FIG. 2 shows the apparatus main body 2 in a state in which the top covers 4a to 4d, the front cover 5, the rear cover 6, and the left and right side covers 7 and 8 are removed from the exercise training apparatus 1 of FIG. In FIG. 2, the front side or the front side in the drawing is the front side of the apparatus main body 2, and the back side or the rear side is the rear side.

  The upper surface covers 4a to 4d are disposed in the front-rear direction and the left-right direction of the operation unit 3, respectively, and are composed of sheets of a bellows structure that can expand and contract in the plane of the upper surface cover according to the movement of the operation unit 3. In another embodiment, the upper surface cover is formed of a relatively flexible sheet made of, for example, resin or cloth, and a roll mechanism (not shown) disposed inside the front, rear, left, and right side edges of the device body 2 It can be stored in a freely retractable manner by a spring structure biased in the winding direction. Roll mechanisms of this type have been widely used in screens for covering windows of vehicles and buildings. In addition to the bellows structure and the roll mechanism, the upper surface cover may have various conventional known structures.

  As shown in FIG. 2, the device body 2 has a frame structure including an outer frame 11 having a substantially rectangular frame shape. On the left and right outer side surfaces of the outer frame 11, horizontal bar-like handle portions 12 are respectively fixed in order to lift and carry the exercise training device 1 by hand.

  On the inside of the outer frame 11, as shown in FIGS. 2 to 4, three front and rear fixed frames 13a to 13c extending in the front and rear direction are arranged in parallel separated in the left and right direction, and both ends thereof are respectively outside It is fixed near the lower end of the inner wall of the frame 11. On the front and rear fixed frames 13a to 13c, two left and right fixed frames 14a and 14b extending in the left and right direction in the outer frame 11 at right angles to them are separately disposed in parallel in the front and rear direction. Each is fixed near the lower end of the inner wall of the outer frame 11.

  In the present embodiment, the left and right fixed frames 14a and 14b are placed on the front and rear fixed frames 13a to 13c and fixed integrally with set screws. In another embodiment, the left and right fixed frames 14a and 14b and the front and rear fixed frames 13a to 13c may not be integrally coupled, and may be separated in the vertical direction. In addition, on the lower surface of the outer frame 11, more specifically, the lower surfaces of the front and rear fixed frames 13a to 13c and the lower surface of the right side of the outer frame 11, a plurality of shorts for placing the exercise training device 1 on the installation surface. Legs 15 are provided in a protruding manner.

  On the front and rear inner walls of the outer frame 11, step surfaces 16a and 16b with a constant width extend inward over substantially the entire length in the left-right direction at heights slightly lower than the upper end thereof. There is. Further, the upper end of each of the front and rear inner walls of the outer frame 11 is bent inward at a right angle to form bent plate portions 17a and 17b having a constant width over substantially the entire length in the left-right direction. A low clearance is defined between the step surfaces 16a and 16b. The left and right sides of the upper surface covers 4a and 4b are inserted over substantially the entire length in the front-rear direction, and when the operation unit 3 moves in the left-right direction as described later, the upper surface covers It serves as a guide for expanding and contracting the bellows.

  The device body 2 includes an actuator mechanism 20 for moving the operation unit 3 in the front and rear direction and the left and right direction on a predetermined plane in the outer frame 11. The predetermined plane is a horizontal plane parallel to the installation plane in the present embodiment. The actuator mechanism 20 is provided on the front and rear fixed frames 13a to 13c and the left and right fixed frames 14a and 14b inside the outer frame 11, as shown in FIG. The actuator mechanism 20 includes a first actuator unit 21 for linearly reciprocating the operation unit 3 in the front-rear direction, and a second actuator unit 22 for linearly reciprocating the operation unit 3 in the left-right direction orthogonal thereto. Each of the first and second actuator units 21 and 22 is a so-called linear motion actuator that converts the rotational motion of the drive unit into the linear motion of the driven unit.

  The first actuator portion 21 includes a first guide portion 23 for linearly guiding the operation portion 3 in the front-rear direction, and a first drive portion 24 for driving the operation portion along the first guide portion 23. Have. The first drive portion 24 is provided integrally with the first guide portion at one end portion of the first guide portion 23 (in the present embodiment, the rear end portion as shown in FIGS. 2 and 4).

  In the present embodiment, as shown in FIG. 5, the first guide portion 23 has a rectangular channel shaped first guide frame 25 opened upward, and a rod shaped feed screw 26 extending longitudinally in the inside. , And a slider block 27. The longitudinal upper surface of the first guide frame 25 provides a slide rail for guiding the slider block 27 in the longitudinal direction. The slider block 27 has a nut portion which is engaged with the thread groove of the feed screw 26 through a plurality of steel balls, and is combined with the feed screw to constitute a known ball screw structure.

  As shown in FIGS. 4 and 5, the first drive unit 24 includes a first drive motor 30 capable of rotating in forward and reverse directions, and a reduction gear interposed between the rotation shaft of the first drive motor and the feed screw 26. It consists of a gear 31. A sensor such as a known rotary encoder is attached to the first drive motor 30 in order to detect and control its rotation direction and rotation amount. The reduction gear 31 is a gear train that decelerates the rotation of the first drive motor 30 and transmits it to the feed screw 26. The gear ratio of the reduction gear 31 is set so as to generate a torque sufficient to transmit the driving force of the first drive motor 30 to the user's upper or lower limbs via the operation unit 3.

  The gear ratio of the reduction gear 31 is preferably set relatively high so that the first drive motor 30 does not easily rotate due to the reverse input from the feed screw 26 when the power is shut off. In another embodiment, a braking means such as an electromagnetic brake may be provided to stop and hold the rotation when the power to the first drive motor 30 is shut off.

  The second actuator unit 22 includes a second guide unit 33 for linearly guiding the first actuator unit 21 in the left-right direction, and a second guide unit 33 for driving the first actuator unit along the second guide unit 33. And a drive unit 34. The second drive portion 34 is provided integrally with the second guide portion at one end of the second guide portion 33 (in the present embodiment, the end on the right side in FIGS. 2 and 3).

  Similar to the first guide portion 23, the second guide portion 33 has a rectangular channel-shaped second guide frame 35 opened upward, a rod-shaped feed screw 36 extending longitudinally in the inside, and a slider block And 37. The longitudinal upper surface of the second guide frame 35 provides a slide rail for guiding the slider block 37 in the longitudinal direction. The slider block 37 has a nut portion engaged with the thread groove of the feed screw 36 through a plurality of steel balls, and is combined with the feed screw to constitute a known ball screw structure.

  As shown in FIGS. 3 and 5, the second drive unit 34 includes a second drive motor 38 capable of rotating in forward and reverse directions, and a reduction gear interposed between the rotation shaft of the second drive motor and the feed screw 36. It consists of gears 39. A sensor such as a known rotary encoder is attached to the second drive motor 38 in order to detect and control the rotation direction and the amount of rotation. The reduction gear 39 comprises a gear train for decelerating the rotation of the second drive motor 38 and transmitting it to the feed screw 36. The gear ratio of the reduction gear 39 is set to generate sufficient torque to transmit the driving force of the second drive motor 38 to the upper or lower limbs of the user via the first actuator unit 21 and the operation unit 3. Be done.

  The gear ratio of the reduction gear 39 is preferably set relatively high so that the second drive motor 38 does not easily rotate due to the reverse input from the feed screw 36 when the power is shut off. In another embodiment, a braking means, such as an electromagnetic brake, may be provided to stop and hold the rotation when the second drive motor 38 is de-energized.

  As shown in FIGS. 2 to 4, the first actuator portion 21 is integrally provided with a movable frame 41 that extends the inside of the outer frame 11 in the front-rear direction over substantially the entire length. The movable frame 41 includes a pair of movable frame members 41a and 41b extending in the longitudinal direction of the first guide portion 23, as shown in FIG. The movable frame members 41a and 41b are fixed to both sides in the longitudinal direction of the first guide frame 25 with set screws or the like, with the L-shaped inner side facing the first guide portion 23 side. Thus, between the first guide portion 23 and the movable frame members 41a and 41b, horizontal surfaces 42a and 42b having a constant width extending laterally from the side surface of the first guide frame 25 and a grooved space having a rectangular cross section Sa and Sb are defined.

  The upper ends of the movable frame members 41a and 41b fixed to the first guide frame 25 are bent at a right angle toward the first guide frame side along the entire length in the longitudinal direction, and a bending plate portion with a constant narrow width 43a and 43b are formed. The L-shaped vertical inner surface of the movable frame members 41a and 41b has a fixed narrow protruding plate portion 44a extending perpendicularly from the inner surface to the first guide frame 25 at a height position slightly lower than the upper end thereof. , 44b are integrally formed over substantially the entire length except for both end portions in the longitudinal direction. Thus, a gap with a low height between the bent plate portions 43a and 43b and the protruding plate portions 44a and 44b extends over substantially the entire length except for both end portions in the longitudinal direction inside the upper end of the movable frame members 41a and 41b. Is defined. The front and rear sides of the upper surface covers 4c and 4d are inserted over substantially the entire length in the left-right direction, and when the operation unit 3 moves in the front-rear direction as described later, this upper surface cover It serves as a guide for expanding and contracting the bellows.

  As shown in FIG. 2 and FIG. 4, the lower ends of the movable frame members 41 a and 41 b in the longitudinal direction are cut away from the projecting plate portions 44 a and 44 b, and the remaining portions are the projecting portions 45 a, It forms 45b. When the actuator mechanism 20 is mounted in the outer frame 11, each of the protrusions 45a and 45b is located between the bent plate portions 17a and 17b of the front and rear inner walls of the outer frame and the step surfaces 16a and 16b, respectively. It is inserted into the defined space with a margin between it and its inner surface.

  As shown in FIG. 5, the operation unit 3 comprises a relatively short vertical operation rod 48 and a handle member 49 provided at the upper end thereof. The handle member 49 of this embodiment is formed in a relatively thick small circular disc shape so that it can be grasped with one hand for training the exercise function of the upper limb UL of the user U. The handle member 49 is pivotally mounted about the operating rod 48 so that the user can turn it with a hand. In another embodiment, the handle member 49 can be fixed so as not to rotate relative to the operating rod 48.

  The handle member 49 is removably attached to the operating rod 48. Thereby, the handle member 49 may be replaced with various engagement members suitable for engaging the upper or lower limbs of the user in accordance with the purpose of use of the exercise training device 1, the condition of the user, etc. it can. For example, if the user's hand can not grip the handle member 49 well, a belted engagement member can be used to secure the hand (or upper limbs). Thus, the force is transmitted from the user's hand (or upper limb) to the operation rod 48 to move the operation unit 3 or the force is received from the operation unit 3 via the operation rod 48 and the hand (or upper limb) Can move. When training the user's lower extremity, the handle member 49 may be replaced by a table on which the user's foot is placed or a belt-shaped engaging member for fixing the foot.

  The operation unit 3 has a force sensor 51 provided integrally with the operation rod 48. The force sensor 51 operates on the operating rod 48 from the handle member 49 in either an automatic operation in which the user moves the operating unit 3 by himself or in an inactive operation in which the upper or lower leg is moved by the force of the operating unit 3. Detect the force. In the present embodiment, a commercially available six-axis force sensor using a strain gate is employed as the force sensor 51.

  In general, a six-axis force sensor detects forces (Fx, Fy, Fz) in three orthogonal x, y, z directions and moments (Mx, My, Mz) around three x, y, z axes. Can. In this embodiment, the six-axis force sensor is oriented such that the x-axis and y-axis thereof coincide with the front-rear direction and the left-right direction of the actuator mechanism, respectively.

  Usually, a commercially available force sensor includes a fixed side base and a detection unit for receiving an external force to be detected. In the present embodiment, as shown in FIG. 5, the force sensor 51 includes a substantially short cylindrical base and a detection unit provided on the upper surface thereof. At the center of the upper surface of the detection portion of the force sensor 51, an operation rod 48 is integrally fixed vertically upward. The base portion of the force sensor 51 is integrally fixed on the slider block 27 of the first actuator unit 21 via the mounting plate 52.

  Thereby, the force sensor 51 is a force component in the front-rear direction that the operating rod 48 receives directly from the upper or lower limbs of the user when the upper or lower limbs of the user move the operation unit 3 or are moved by the operation unit. The force component can be divided into force components in the left and right direction and force components in the vertical direction orthogonal to them, and can be detected as moments acting around axes in the front-rear direction, the left-right direction, and the vertical direction.

  In actual use of the exercise training apparatus 1, the force components in the front-rear direction, the left-right direction and the vertical direction detected by the force sensor 51 are the first and / or second drive of the first and / or second actuator parts 21 and 22 The difference between the rotational force of the motors 30, 38 and the force that the user exerts on the operation unit 3 is detected as the reaction force that the operation unit 3 receives from the upper or lower limbs of the user. For example, in the training of passive movement, the force of the user is a load or rotational drag acting on the first and / or second drive motors 30, 38 as a resistance to the movement of the operation unit 3. In the training of the automatic operation, the rotational force of the first and / or second drive motors 30, 38 acts as a resistance, ie, exerts a load on the user against the movement of the operation unit 3 by the force of the user.

  Conventionally, capacitance sensors and optical sensors are widely used as force sensors other than those using strain gates. Any type of force sensor can be employed as the force sensor 51 of the present invention. In another embodiment, a user can attach a sensor device such as a strain gauge directly to the operating rod 48 or the connecting portion between the operating rod and the mounting plate 52 without using a commercially available force sensor, and the user can The force exerted can also be detected.

  The mounting plate 52 which constitutes a part of the operation unit 3 is a rectangular plate member, and as shown in FIG. 6, in the width direction orthogonal to the longitudinal direction of the movable frame 41, it is slightly smaller than the inner width of the movable frame Have dimensions. Both sides of the mounting plate 52 along the longitudinal direction of the movable frame 41 are cut at a right angle on the lower surface side, and the side portion 53a, which is thinner than the height of the gap between the bent plates 43a and 43b and the protruding plates 44a and 44b 53b is formed.

  The mounting plate 52 crosses the groove-shaped spaces Sa and Sb defined between the first guide portion 23 and the movable frame members 41a and 41b, and the side portions 53a and 53b are bent plate portions 43a and 43b and a projecting plate The slider block 27 is attached to the slider block 27 so as to be inserted into the gap between the portions 44a and 44b with a margin. Thus, when the operation plate 3 is moved in the front-rear direction, the mounting plate 52 travels along the longitudinal direction immediately above the first guide frame 25 and the groove spaces Sa and Sb.

  The first actuator portion 21 is mounted on the second actuator portion 22 via the connecting member 53, as shown in FIG. The connecting member 53 is a rectangular plate member, and is coupled to the lower surface of the first guide frame 25 to integrally fix the first guide portion 23 on the slider block 37 of the second actuator portion 22. Thus, when the operation unit 3 is moved in the left-right direction, the first actuator unit 21 travels immediately above the second guide frame 35 along the longitudinal direction.

  The first actuator unit 21 has a pair of limit sensors 55 a and 55 b in order to limit the movement range of the operation unit 3 in the front-rear direction. As shown in FIG. 2, the limit sensors 55a and 55b are provided on the horizontal surface 42b between the first guide portion 23 and one of the movable frame members 41b (right side in the figure) from the front and rear of the outer frame 11 respectively. It is placed in the front position.

  The limit sensors 55a, 55b of the present embodiment have a known structure in which the arm lever is spring-biased so as to be able to swing in the horizontal direction. On the lower surface of the mounting plate 52, an operation block 56 for operating the arm levers of the limit sensors 55a and 55b is integrally protruded. As a result, when the operation unit 3 moves in the front-rear direction and reaches its limit position, the operation block 56 rotates the arm lever to turn on the limit sensors 55a and 55b.

  The first actuator unit 21 further includes a home position sensor 57 for stopping / maintaining the operation unit 3 at the home position in the front-rear direction. As shown in FIG. 2, the home position sensor 57 is disposed slightly on the horizontal surface 42b between the movable frame member 41b and the one on the front side (the front side in the figure) of the limit sensor 55a.

  The home position sensor 57 of the present embodiment is a transmission type photo sensor having a light emitting portion and a light receiving portion disposed opposite to each other with a small gap, and is turned off when light passes from the light emitting portion to the light receiving portion. When the light receiving unit is shielded from light, the light receiving unit is turned on. When the operation unit 3 is moved in the front-rear direction, a plate-like sensor flag member 58 which protrudes vertically downward passes through a gap between the light emitting unit of the home position sensor 57 and the light receiving unit. It is attached to get.

  Similarly, the second actuator unit 22 has a pair of limit sensors 61a and 61b in order to limit the movement range of the first actuator unit 21 in the left-right direction. As shown in FIG. 2, the limit sensors 61 a and 61 b are disposed on the far side of the left and right fixed frame 14 a at positions before the left and right sides of the outer frame 11.

  The limit sensors 61a and 61b of the present embodiment also have a known structure in which the arm lever is spring-biased to be able to swing in the horizontal direction. As shown in FIG. 7, on the lower surface of one (left side in FIG. 2) of the movable frame member 41a, an operating block 62 for operating the arm levers of the limit sensors 61a and 61b is integrated via the mounting plate 63. It is provided in the As a result, when the operation unit 3 moves in the lateral direction together with the first actuator unit 21 and reaches its limit position, the operation block 62 rotates the arm lever to turn on the limit sensors 61a and 61b.

  The second actuator unit 22 further includes a home position sensor 64 for stopping / maintaining the operation unit 3 at the home position in the left-right direction. As shown in FIG. 2, the home position sensor 64 is disposed on the back side of the left and right fixed frame 14a slightly closer to the center than one of the limit sensors 61b (right side in the figure).

  The home position sensor 64 of the present embodiment is a transmission type photosensor having a light emitting portion and a light receiving portion similarly disposed opposite to each other with a small gap, and is turned off, for example, when light passes from the light emitting portion to the light receiving portion. In the state, when the light receiving unit is shielded from light, it is turned on. On the lower surface of the movable frame member 41a, when the plate-like sensor flag member 65 protruding vertically downward moves the operation unit 3 in the left and right direction, a gap between the light emitting unit and the light receiving unit of the home position sensor 64 Are attached by a mounting plate 63 so that they can pass through.

  FIG. 8 shows a state in which the operation unit 3 is disposed at the home position. As shown in the figure, the home position of the operation unit 3 is set to the front side in the front-rear direction and the right side in the left-right direction with respect to the upper surface center position of the exercise training device 1. Thus, when the user U is positioned in front of the exercise training device 1 as shown in FIG. 1, the user U can touch the handle member 49 of the operation unit 3 as soon as the right hand is extended. However, in the present invention, the home position of the operation unit 3 is not limited to the position shown in FIG.

  FIG. 9 shows the movable range in the front-rear direction and the left-right direction of the operation unit 3 in the actuator mechanism 20. As shown in the figure, the movement range of the operation unit 3 in the front-rear direction is directly determined by the first guide frame 25. The movement range of the operation unit 3 in the left-right direction is determined by the second guide frame 35 via the first actuator unit 21.

  The exercise training apparatus 1 further includes a control unit 70 for controlling the first and second actuator units 21 and 22. As shown in FIG. 10, the control unit 70 includes a drive control unit 71, a signal control unit 72, a display control unit 73, a memory 74, and a control CPU 75 for controlling and managing them.

  The drive control unit 71 is connected to the first and second drive motors 30 and 38 and controls the drive of them. The signal control unit 72 is connected to the force sensor 51, the limit sensors 55a, 55b, 61a, 61b, and the home position sensors 57, 64, and receives signals output from the sensors. The display control unit 73 is connected to the monitor device 76 and controls the display of the monitor device. The memory 74 stores, in addition to the program for operating the exercise training apparatus 1, data related to training such as personal data of the user and training history.

  In the exercise training apparatus 1 of the present invention, the basic concept for controlling the output of the first and second drive motors 30, 38 of the first and second actuator units 21, 22 when training the user. Are described below. In order to simplify the description, it is assumed that the second actuator unit 22 is stopped and only the first actuator unit 21 is used.

  FIG. 11 shows the variation of the force of the user detected by the force sensor 51 and the variation of the output of the first drive motor 30 controlled by the control unit 70 according to the force of the user along the time axis. It shows. In the figure, the user's force received by the operation unit 3 and the rotational force of the first drive motor 30 are shown in place of the output (kW) of the first drive motor. The vertical axis in the figure indicates that the upward (+) is a force pushing the operation unit 3 forward, and the downward (-) is a force drawing the near side.

  As shown in FIG. 11, when the force sensor 51 detects the force of the output value 5 at time t1, the output signal is inputted to the signal control unit 72 of the control unit 70, and the control CPU 75 controls the first drive motor at time t2. The drive control unit 71 is controlled such that 30 generates a rotational force of the same output value 5. When the input signal from the force sensor 51 becomes 0 at time t3, the control CPU 75 controls the drive control unit 71 so that the output of the first drive motor 30 becomes 0 at time t4.

  According to the present invention, since the force sensor 51 is substantially provided in the operation unit 3, the detected user's force can be directly output to the control unit 70 as it is. Therefore, it is possible to shorten the time delay from time t1 at which the force sensor 51 outputs a signal to time t2 at which it is reflected to the first drive motor 30 to such an extent that the user can not feel it. Furthermore, since the output signal from the force sensor 51 does not need to be amplified or converted in the control unit 70, the first drive motor 30 is optimally driven to output a rotational force according to the user's force. can do.

  The exercise training device 1 can be used in a state where the device body 2 is inclined in the front-rear direction or in the left-right direction, for example, in order to conduct sanding operation training. To that end, the device body 2 can be equipped with a tilt sensor 77 for detecting its tilt state, ie the tilt direction and the tilt angle. In this case, the exercise training device 1 is installed on a separate support structure whose tilt angle can be adjusted. The output signal of the inclination sensor 77 is input to the control unit 70, and in order to control the output of the first and / or second drive motors 30, 38 in accordance with the inclination direction and the inclination angle of the apparatus body 2. used.

  As the tilt sensor 77, for example, a conventionally known gyro sensor can be used, but the present invention is not limited to this. For example, if the exercise training device 1 is to be supported on a separate support structure by tilting it, the support structure can be equipped with a tilt sensor. In this case, an encoder of an electric motor for tilting the support structure or a motor drive pulse counter may be used as a tilt sensor, or a sensor or scale for specifying the tilt may be provided in a hinge portion for tilting the installation surface of the support structure. it can.

  12 and 13 show a second embodiment of the present invention suitable for use with the device body 2 inclined in the front-rear direction. In particular, FIG. 12 shows a state in which the rear side of the device body 2 is highly inclined from the rear side.

  The exercise training apparatus 81 according to the second embodiment has a telescopic support leg mechanism 82 in place of the legs 15 according to the first embodiment, and the device body 2 to detect the inclined state, that is, the inclination direction and the inclination angle. The second embodiment differs from the first embodiment in that a tilt sensor of Since it is the same as the exercise training apparatus 1 of 1st Embodiment except those points, detailed description is abbreviate | omitted.

  The support leg mechanism 82 has four support legs 83 a to 83 d attached to the lower surface of the apparatus body 2. Each support leg 83a-83d has an outer lower leg portion 84a-84d and an inner upper leg portion 85a-85d which are rectangular in cross section. Inner upper leg portions 85a to 85d are formed so that the outer dimensions thereof are somewhat smaller than the inner dimensions of outer lower leg portions 84a to 84d, and are insertably inserted in and removed from the upper end opening of the outer lower leg portion. .

  The front upper inner leg portions 85a and 85b are rotatably coupled in the front-rear direction with the upper ends thereof separated in the left-right direction to the lower surfaces of the left-right fixed frame 14b on the front side. The upper ends of the rear upper inner leg portions 85c, 85d are pivotably connected to the lower surfaces of the rear left and right fixed frames 14a so as to be separated in the left-right direction. At the lower end of the outer lower leg portions 84a to 84d, a flat base plate is provided in order to stably install the exercise training device 81 on the installation surface.

  In the upper inner leg portions 85a to 85d, a plurality of positioning holes 86a to 86d, which horizontally penetrate the opposite left and right side surfaces, are formed at substantially equal intervals in a row in the vertical direction. Positioning pins 87a to 87d are respectively inserted into the positioning holes 86a to 86d of the desired height so as to penetrate the left and right side surfaces in the horizontal direction. In the positioning pins 87a to 87d, portions of the inner upper leg portions 85a to 85d which protrude outward from the left and right sides engage with the upper ends of the outer lower leg portions 84a to 84d. Thereby, each support leg 83a-83d is set to a desired height.

  In the exercise training device 81 according to the second embodiment, a tilt sensor for detecting the tilt state of the device body 2 can be provided on the support leg mechanism 82. FIG. 14 illustrates the tilt sensor 88 mounted on one of the rear support legs 83c. The inclination sensor 88 comprises a rack 89 vertically provided on the inner surface of the inner upper leg portion 85c, a pinion 90 engaged with the rack 89 and fixed thereto in the outer lower leg portion 84c, and a sensor device provided on the pinion (Not shown). As this sensor device, for example, a variable resistor such as a rotary volume can be used, and by the amount of rotation of the pinion 90, the length of the inner upper leg portion 85c raised from the lowermost position, that is, the height of the support leg 83c It can be detected.

  In another embodiment, the inclination sensor 77 of the first embodiment shown in FIG. 1 can be used as the inclination sensor for detecting the inclination state of the device body 2. In that case, the structure of the support leg mechanism 82 can be simplified, and the tilt state of the device body 2 can be detected with higher accuracy.

  FIG. 15 shows a configuration of a control unit 91 for controlling the first and second actuator units 21 and 22 in the exercise training apparatus 81 of the second embodiment. As shown in the figure, in the control unit 91, the signal control unit 72 is also connected to the inclination sensor 88, and the drive control unit 71 corresponds to the inclination state of the device body detected by the inclination sensor. , And controls the driving of the first and second drive motors 30, 38.

  FIG. 16 conceptually illustrates a state in which the user U performs training using the exercise training device 81. As shown in the figure, in the operation unit 3, an engagement member 94 provided with left and right handle portions 94 a instead of the circular disk shaped handle member 49 of the first embodiment is attached to the operation rod 48. There is. The second drive motor 38 is locked in the second actuator unit 22 so that the operation unit 3 can not be moved in the left-right direction. The user U can hold the handle portion 94 a with both hands and move the operation portion 3 only along the first guide portion 23 in the front-rear direction.

  In this case, it is preferable in view of the nature of movement that the engaging member 94 be fixed so as not to pivot about the operating rod 48. However, it is also possible to pivotally attach the engagement member 94 to the operation rod 48 depending on the state of the upper limb (or lower limb) of the user, the exercise function and the like. In yet another embodiment, the mounting structure of the operating rod 48 and / or the engaging member 94 can be used so that one engaging member 94 can be used to be turned or non-rotatably switched with respect to the operating rod 48. It can also be configured.

  Control of the output of the first drive motor 30 in the second embodiment will be described with reference to FIG. FIG. 17 shows the force acting on the operation unit 3 when the apparatus main body 2 is inclined at a certain angle θ in the front-rear direction. Here, the operation unit 3 is in a free state in which no force of the user acts. In the figure, m is the mass of the operation unit, g is the gravitational acceleration, and μ is the coefficient of friction between the operation unit 3 and the first actuator unit 21. In the drawing, the direction of action of the force on the inclined surface is positive (+) upward in the direction in which the user pushes up the operation unit 3 and negative (−) downward in the direction in which the operation unit 3 is lowered.

  In this case, the force F (+) required to move the operation unit 3 upward along the inclined surface is F (+) = mg · sin θ + μm · cos θ. Conversely, the force F (−) required to move the operation unit 3 downward along the inclined surface is F (−) = − mg · sin θ + μm · cos θ.

  When the apparatus body 2 is installed horizontally (θ = 0 °), the force required to move the operation unit 3 in the front-rear direction is only the frictional force μmg generated between the operation unit 3 and the first actuator unit 21. is there. On the other hand, when the apparatus main body 2 is inclined (θ ≠ 0 °), a part of the weight mg of the operation unit 3 acts in the + direction or the − direction with a size (sin θ times) corresponding to the inclination angle θ. . The size thereof is 1/2 of the weight mg of the operation unit 3 when, for example, θ = 30 °. Usually, the frictional force μmg between the operation unit 3 and the first actuator unit 21 is very small compared to the weight mg of the operation unit 3.

  Therefore, when moving the operation unit 3 upward along the inclined surface, the output is controlled to increase the rotational force of the first drive motor 30 by about sin θ times the weight mg of the operation unit 3. When the operation unit 3 is moved downward along the inclined surface, the output is controlled to decrease the rotational force of the first drive motor 30 by about sin θ times the weight mg of the operation unit 3.

  According to the exercise training device 81 of the present embodiment, the control unit 91 controls the first drive motor 30 to adjust the driving force of the operation unit 3 according to the degree of inclination of the device body detected by the inclination sensor. be able to. Therefore, exercise training of the upper or lower limb can be performed with an optimum load on the user without giving discomfort to the user regardless of the user or the purpose or condition of the training.

  According to the third embodiment of the present invention, the function of the first actuator unit 21 or the second actuator unit 22 can be selectively stopped. The first and second actuator units 21 and 22 in the function stop state stop the first and second guide units 23 and 33 at predetermined positions set in advance, for example, at the home position or the central position of the device body 2. The first and second drive motors are locked non-rotatably. In addition, since the exercise training apparatus of 3rd Embodiment uses the apparatus main body 2 of 1st or 2nd embodiment, the detailed description is abbreviate | omitted.

  FIG. 18 shows the configuration of the control unit 101 of the exercise training device of the third embodiment. The control unit 101 is different from the control unit 91 of the second embodiment in that the control unit 101 further includes an actuator unit switching control unit 102. The other configuration is the same as that of the control unit 91, so detailed description will be omitted.

  The actuator unit switching control unit 102 selectively deactivates the first actuator unit 21 or the second actuator unit 22 based on a command from the control CPU 75 or recovers the function that has been deactivated. The deactivation of the actuator unit is performed, for example, by turning off the power to the actuator unit. When the first and second drive motors 30, 38 are provided with a brake means such as an electromagnetic brake circuit, the brake means is operated to lock the rotation of the drive motor of the actuator unit which has stopped its function. By this, the operation unit 3 can be moved only in the first or second actuator unit 21 or 22 which has not stopped functioning.

  In the exercise training apparatus according to the third embodiment, the user or his / her supporter operates only the first actuator unit 21 to stop the function of the second actuator unit 22, and only the second actuator unit 22. It can be provided with input means for selecting which of the second operation modes to be operated to cause the first actuator section 21 to stop functioning, or can be used by being connected to such external input means. In this case, the input unit is connected to the control unit 101, and the control CPU 75 controls the actuator unit switching control unit 102 in response to the input from the input unit. When there is no input from the input means, the control unit 101 controls the first and second actuator units 21 and 22 in a standard operation mode in which both of them can operate.

  FIG. 19 shows the moving direction of the operation unit 3 in the first operation mode. In this case, the first actuator portion 21 is disposed along the front-rear direction as in the first and second embodiments. By tilting the device body 2 in the front-rear direction in this arrangement, it is possible to perform sanding operation training. At this time, a part of the weight of the operation unit 3 acts on the operation unit 3 as a load in the + direction or the − direction in FIG. The force that acts on the operation unit 3 in this case is the same as that described in the second embodiment with reference to FIG.

  FIG. 20 shows the moving direction of the operation unit 3 in the second operation mode. In this case, the second actuator unit 22 is disposed along the front-rear direction. By tilting the device body 2 in the front-rear direction in this arrangement, sanding operation training can be performed similarly. In this case, a part of the weight of the operation unit and the first actuator unit 21 acts on the operation unit 3 in accordance with the inclination angle of the apparatus main body 2.

  Therefore, when moving the operation unit 3 upward along the inclined surface in the second operation mode, the rotational force of the first drive motor 30 is set by about sin θ times the weight of the operation unit 3 and the weight of the first actuator unit 21. Control its output to increase. Conversely, when the operating unit 3 is moved downward along the inclined surface, the rotational force of the second drive motor 38 is reduced by about sin θ times the weight of the operating unit 3 and the weight of the first actuator unit 21. , Control its output.

  In the first operation mode, the load applied to the first drive motor 30 is small, so the output may be relatively low. On the other hand, in the second operation mode, since the load applied to the second drive motor 38 is larger than that in the first operation mode, the output also increases. As described above, in the present embodiment, the output of the drive motor necessary for it also increases or decreases according to the load applied to the user, so it is necessary to be aware of this point when in use.

  According to the third embodiment, the control unit 101 controls the actuator switching control unit 102 to selectively stop the function of the first actuator unit 21 or the second actuator unit 22, thereby a single device. Training can be selectively performed according to the conditions, such as the load acting on the user.

  In another embodiment, the actuator switching control unit 102 can be interlocked with the inclination of the device body 2. The control unit 101 can determine the tilt direction of the device body 2 based on the input from the tilt sensor. For example, the control unit 101 causes the second actuator unit 22 to stop functioning when the device body 2 is tilted in the front-rear direction, or the first actuator portion when the device body 2 is tilted in the left-right direction. The actuator switching control unit 102 is controlled to stop the function 21.

  In yet another embodiment, the first and / or second actuators 21 and 22 may be provided with a mechanical lock mechanism to move the first guide 23 with respect to the second guide 33 and The movement of the operation unit 3 can be locked. In this case, a sensor is provided in the first and second actuator units 21 and 22 or the mechanical lock mechanism, and when the first and second actuator units 21 and 22 are in a locked state, this is detected to control the control unit 101. Output.

  Although the present invention has been described above in connection with the preferred embodiments, the present invention is not limited to the above embodiments, and various changes or modifications may be made within the technical scope thereof. Needless to say. For example, the first guide portion 23 of the first actuator portion 21 and the second guide portion 33 of the second actuator portion 22 can be arranged to intersect at an angle other than a right angle. In addition, if it is only necessary to control the first and second drive motors 30 and 38 to detect force components in the longitudinal and lateral directions or force components in the longitudinal and lateral directions and moments around the vertical axis, the force sensor 51 Is a three-axis force sensor that detects forces (Fx, Fy) in two orthogonal axial directions x and y and a moment Mz about the z-axis orthogonal to them in place of the six-axis force sensor in the above embodiment Can be used.

1, 81 exercise training device 2 device body 3 operation unit 11 outer frame 20 actuator mechanism 21 first actuator unit 22 second actuator unit 23 first guide unit 24 first drive unit 25 first guide frame 26, 36 feed screw 27, 37 Slider block 30 First drive motor 33 Second guide portion 34 Second drive portion 35 Second guide frame 38 Second drive motor 41 Movable frame 48 Operating rod 49 Handle member 51 Force sensor 52 Mounting plate 53 Connecting members 70, 91, 101 Control Unit 71 Drive Control Unit 72 Signal Control Unit 73 Display Control Unit 74 Memory 75 Control CPU
77, 88 tilt sensor 82 support leg mechanisms 83a to 83d support leg 94 engagement member 102 actuator switching control unit

Claims (8)

An exercise training device for improving a person's motor function,
Device frame,
An operation unit capable of moving a position within the device frame;
A first guide portion for moving the operation portion linearly along a first direction, and a first drive for driving the operation portion along the first guide portion or applying a load to the movement thereof A first actuator unit having a motor;
A control unit for controlling the drive or load of the first drive motor;
The operation unit is moved along the first guide unit by the user's upper or lower limb against the driving force of the first drive motor, or the upper or lower limbs of the user by the first driving motor driving force A force sensor for detecting a force that the operation unit receives from the upper or lower limbs of the user when moving the
An inclination detection unit for detecting an inclination of the first actuator unit along the first direction;
The force sensor is provided at or near the operation unit to detect a force component of at least the first direction of the force received from the upper or lower limbs of the user.
The control unit corresponds to the force component of the first direction of the user's force detected by the force sensor based on the inclination of the first actuator unit detected by the inclination detection unit. An exercise training apparatus characterized by controlling a first drive motor. A second guide portion for linearly guiding the first actuator portion along a second direction intersecting the first direction; and the first operation guide portion along the second guide portion And a second actuator unit having a second drive motor for driving.
The force sensor is configured such that the operation portion is along the first guide portion and / or the second guide portion and against the driving force of the first drive motor and / or the second drive motor, the upper or lower limbs of the user When the user moves the upper or lower limbs of the user by the first drive motor and / or the second drive motor, at least the force received by the operation unit from the user's upper or lower limb Detect force components in the 1 direction and the second direction,
The control unit corresponds to force components of the first and second directions of the user's force detected by the force sensor based on the inclination of the first actuator unit detected by the inclination detection unit. The exercise training apparatus according to claim 1, wherein the first drive motor and / or the second drive motor are controlled.   The exercise training device according to claim 2, wherein the first direction and the second direction are orthogonal to each other.   The exercise training device according to any one of claims 1 to 3, further comprising an inclination support mechanism for inclining the first actuator unit along the first direction.   The exercise training device according to claim 4, wherein the tilt support mechanism is a support leg structure provided on the device frame.   The exercise training apparatus according to claim 4 or 5, wherein the tilt detection unit is provided in the tilt support mechanism.   The force sensor is a three-axis force sensor for detecting a force in the directions of x and y axes orthogonal to each other and a moment around the z axis orthogonal to the x and y axes. The exercise training device according to any one of 6.   The force sensor according to any one of claims 1 to 6, wherein the force sensor is a six-axis force sensor that detects forces in the x, y, and z directions orthogonal to one another and moments about the x, y, and z axes. The exercise training device according to any one of the above.

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