JP2011217825A - Own weight compensating type walk assist device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an own weight compensating type walk assist device capable of effectively assisting walking action by compensating the own weight of a walker or a walking robot or others without needing a driving source.SOLUTION: The own weight compensating type walk assist device has a pair of leg parts 3A, 3B which are laterally symmetrically constituted, an upper body holding frame 2 connecting between the upper ends of the leg parts, a free leg own weight compensating mechanism arranged in each of the leg parts and compensating weight load acting to the leg part becoming a free leg, and an upper body own weight compensating mechanism arranged in each of the leg parts and compensating the weight load of the upper body acting on the leg part becoming the support leg, and carries out the assist of the walking action by operating the free leg own weight compensating mechanisms corresponding to the right and left leg parts and the upper body own weight compensating mechanism along with the walking action.

Description

  The present invention assists the walking movement of persons who are difficult to walk on their own due to injury, illness, old age, etc., or reduces the load on the walking robot and the motor that performs the leg bending and stretching movement of the power assist suit More particularly, the present invention relates to a self-compensated leg walking assist device for assisting a walking motion and a leg bending / extension motion by compensating the weight of a pedestrian or a robot.

  Conventionally, for example, as described in Patent Literature 1, a walking robot provided with means for assisting walking motion and reducing energy required for walking motion, or as described in Patent Literature 2, Proposals have been made for lower limb power amplifying devices that are used for assisting the walking of persons and the like, as well as for assisting movement at the site of heavy labor.

  In the walking robot described in Patent Document 1, the air circuit unit assists the walking of the walking robot by controlling the movement of the control air in a predetermined closed space in conjunction with the walking motion. It has.

  The air circuit unit is associated with a change in relative position that is performed via each joint portion of each link member that constitutes the leg when the leg moves from the standing leg state to the swing leg state during walking of the walking robot. A part of the energy of the walking is recovered to the walking energy recovery unit via the control air, and the walking energy recovered by the walking energy recovery unit is released when the leg shifts from the free leg state to the standing state. This assists the transition of the leg to the standing state.

  Further, the lower limb power amplifying device described in Patent Document 2 is connected to a base member connected to a saddle and to the base member so as to be swingable in the front-rear and left-right directions along the legs of the occupant. It has a pair of extended leg units, and the rider rides in a standing state across the saddle, and puts his left and right feet on the pedals respectively connected to the lower parts of these leg units to operate the lower limbs Thus, the force used for the movement of the human lower limb is assisted by the driving of the actuator.

JP 2009-274142 A JP 2008-253539 A

  What is described in Patent Document 1 described above is an electromagnetic valve for switching the flow of control air in order to switch the collection and release of walking energy in accordance with the timing of the walking operation, and a control device for switching and controlling the electromagnetic valve. In addition, in the process of walking from the standing state to the free leg state, the knee is rapidly bent and stretched using the flow resistance when the control air passes through the throttle valve of the air circuit unit. Because of this, there is a problem in that the walking energy that can be recovered is lost, and the energy that can be used when the knee is extended after the free leg state is reduced.

In addition, what is described in Patent Document 2 described above is that a plurality of actuators for driving these leg units and left and right pedals are operated in order to operate the left and right leg units in accordance with the movement of the human lower limbs. Incorporates a pressure sensor unit for detecting the movement of the passenger's foot, and a control device for controlling the actuator by the output signal of these pressure sensor units, resulting in a complicated structure and high manufacturing cost. There was a problem.
In addition, in order to operate these actuators and control units, it is necessary to mount a rechargeable battery or the like, and there is a problem that the use in places where the power source cannot be secured easily such as outdoors is restricted.

  Therefore, the present invention eliminates the problems in the prior art as described above, and can efficiently assist the walking motion by compensating for the weight of a pedestrian, a walking robot, etc. without requiring a drive source. An object is to provide a self-weight-compensated leg walking assist device.

  The self-weight-compensated walking assist device of the present invention provided for the above purpose includes a pair of symmetrically configured legs, a body holding frame that connects the upper ends of these legs, and each leg. A free leg self-weight compensation mechanism that compensates for a gravitational load acting on a leg that is a free leg, and an upper body that acts on a leg that is a support leg. It is equipped with a body weight compensation mechanism that compensates for gravity load, and assists walking motion by alternately operating the free leg weight compensation mechanism and the body weight compensation mechanism corresponding to the left and right legs together with the walking motion. .

Here, the free leg means the leg on the side where the upper body weight is not loaded during walking and can be separated from the floor surface, and the support leg means the leg on the side supporting the weight of the upper body. ing. Further, when standing on the floor with both feet, the left and right legs are the supporting legs.
In the following description, the floor surface includes an indoor floor surface and an outdoor road surface that can be walked by the self-compensation type walking assist device of the present invention.

  In the self-weight-compensated walking assist device of the present invention, each of the left and right leg portions has a pair of upper leg links pivotally mounted on the upper body holding frame, respectively, and lower ends of these upper leg links. A guide frame pivotally attached to the guide frame, a slider attached to the guide frame so as to be slidable by a predetermined distance in the front-rear direction, and a pair of lower leg links each having an upper end pivotally attached to the slider. The lower legs of the lower leg links are each composed of a foot portion pivotally attached to the lower end link.

  The upper body holding frame, the pair of upper leg links, and the guide frame form an upper parallel link mechanism that allows the guide frame to translate in a vertical plane including the front-rear direction with respect to the upper body holding frame. The slider, the pair of lower leg links, and the foot form a lower parallel link mechanism that allows the foot to translate in a vertical plane including the front-rear direction with respect to the slider.

  Each of the free leg weight compensation mechanisms is incorporated in a free leg weight compensation spring, an upper master cylinder unit having a piston rod that receives an urging force of the free leg weight compensation spring, and an upper parallel link mechanism. The upper working cylinder unit is connected to the unit through a conduit having an opening / closing valve that is opened only during the swinging leg, and transmits the biasing force of the free leg self-weight compensation spring to the upper parallel link mechanism.

  Each of the upper body weight compensation mechanisms is slidable along the upper body weight compensation spring, a lower master cylinder unit having a piston rod provided with an engaging portion at the tip, and a piston rod of the lower master cylinder unit. A spring force transmitting body that receives an urging force of an upper body weight compensation spring and transmits the urging force of the upper body weight compensation spring to the piston rod when contacted with the engaging portion; The lower working cylinder unit is incorporated into the lower parallel link mechanism, is connected to the lower master cylinder unit via a pipe line, and transmits the urging force of the upper body weight compensation spring to the lower parallel link mechanism.

  In addition, the lower master cylinder units of the upper body weight compensation mechanism corresponding to the respective leg portions are provided in parallel with the piston rods facing the same side, and the spring force transmission bodies corresponding to the respective piston rods are Both are configured to slide together or in synchronization.

  In the self-weight compensation type walking assist device of the present invention, the upper body holding frame is provided with a saddle over which the occupant straddles, and the neutral position is responsive to the movement of the occupant tilting the upper body to the left or right side. The tilting response member that opens the open / close valve of the free leg self-weight compensation mechanism of the leg on the side opposite to the tilted side when tilted by a predetermined angle from the left to the right side, and the guide frame of the leg on the opposite side are the upper body When positioned above the lower limit position with respect to the holding frame, the return valve is prevented from returning to the neutral position in conjunction with the upper parallel link mechanism including the guide frame, and the on-off valve is held open. It is desirable to provide an interlock mechanism.

  According to the self-weight-compensated walking assist device according to the first aspect of the present invention, it is possible to efficiently assist the walking motion by compensating the self-weight of a pedestrian, a walking robot, etc. without using a drive source. When attached to a walking robot or power assist suit, the load and energy consumption of the walking actuator can be significantly reduced.

  In addition, according to the self-compensation type walking assist device according to the second aspect of the present invention, it can be used effectively for walking assistance of a pedestrian, and the passenger performs a natural walking motion in a standing posture straddling the saddle. It becomes possible.

  Also, during walking motion, the upper body weight compensation mechanism operates on the support leg side to compensate for the upper body weight, while on the free leg side, the leg weight is compensated by the free leg weight compensation mechanism, These compensation powers can be switched alternately left and right, so even if the muscle strength of the legs is weak and it is difficult to walk on its own due to injuries, illness, or elderly age, both hands are free without riding in a wheelchair etc. It is possible to walk easily in a state where it can be used, and work involving leg bending and stretching operations at a fixed position can be easily performed without burdening the knees and waist.

1 is a front view showing an embodiment of a self-weight-compensated walking assist device according to the present invention. 1 is a side view showing an embodiment of a self-weight-compensated walking assist device according to the present invention. It is the side view which simplified and showed the structure of 3 A of left leg parts in one Embodiment of the self-weight-compensation type walk assist apparatus which concerns on this invention. 1 is a schematic structural diagram of a free leg self-weight compensation mechanism in one embodiment of a self-compensation type walking assist device according to the present invention. It is a figure explaining the geometric relationship between the piston rod and upper leg link of the action | operation cylinder unit in FIG. 1 is a schematic structural diagram of a body weight compensation mechanism in an embodiment of a weight compensation type walking assist device according to the present invention. 1 is a schematic structural diagram of an on-off valve control mechanism in one embodiment of a self-weight-compensated walking assist device according to the present invention. FIG. 8 is a partial perspective view schematically showing a relationship between a fixed guide and a gate plate in the on-off valve control mechanism shown in FIG. 7. In the on-off valve control mechanism shown in FIG. 7, it is a figure which shows the state by which the on-off valve by the side of the left leg was opened by the tilting of the inclination response member to the right. In the on-off valve control mechanism shown in FIG. 7, it is a figure which shows the state by which the inclination response member is hold | maintained in the inclination position by the raising of the gate board by the side of a right leg. It is explanatory drawing of the both-legs bending-extension operation | movement in the fixed position by the self-weight compensation type | mold walk assistance apparatus which concerns on this invention. It is explanatory drawing of the walk operation | movement by the self-weight compensation type walk assist apparatus which concerns on this invention.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a front view showing a schematic structure in one embodiment of a self-weight-compensated walking assist device (hereinafter simply referred to as a walking assist device) according to the present invention, and FIG. 2 is a side view thereof. The walking assist device 1 shown is for assisting the walking motion by compensating the pedestrian's own weight and the like.

  The walking assist device 1 has a left-right symmetric structure in which a pair of legs 3A, 3B are connected to the left and right sides of the upper body holding frame 2. In the following description, the front of the passenger M who rides on the walking assist device 1 is the front side, the rear is the rear side, the left leg side of the passenger M is the left side, and the right leg side is the right side.

  The rider M mounts the left and right feet on the foot portions 4A and 4B at the lower ends of the leg portions 3A and 3B, and fixes them by appropriate means, and is attached to the front center of the upper body holding frame 2. Ride the walking assist device 1 in a standing posture across 5. In the present embodiment, a fixing belt 6 for fixing the waist of the passenger M to the saddle 5 is attached to the upper portion of the saddle 5.

  FIG. 3 is a side view showing a simplified structure of the left leg 3A, and the right leg 3B has the same structure as the leg 3A except that it has a bilaterally symmetric structure. Hereinafter, the leg 3A will be described.

  As shown in the figure, the leg portion 3A is pivotally attached to the side portion of the upper body holding frame 2 with support shafts 7 and 8 provided with their upper ends spaced apart in the vertical direction. It has a pair of upper leg links 9 and 10 of the same length.

  The lower ends of the upper leg links 9 and 10 are pivotally supported on the guide frame 13 by the support shafts 11 and 12 that are spaced apart in the vertical direction with an equal distance between the support shafts 7 and 8. The upper parallel link mechanism 14 that can be swung in a vertical plane parallel to the front-rear direction is formed by the upper body holding frame 2, the pair of upper leg links 9, 10 and the guide frame 13. .

  The guide frame 13 is configured in a substantially L shape from a vertical portion 13A to which the support shafts 11 and 12 are attached, and a horizontal portion 13B extending continuously rearward from the lower end of the vertical portion 13A. A slider 15 is guided and supported on the lower surface of the horizontal portion 13B so as to be slidable by a predetermined distance in the front-rear direction.

  The upper ends of a pair of lower leg links 18 and 19 having the same length are pivotally attached to the slider 15 by supporting shafts 16 and 17 which are spaced apart in the front-rear direction. The lower legs of the lower leg links 18 and 19 are pivotally attached to the upper portion of the foot portion 4A by the support shafts 20 and 21 spaced apart in the front-rear direction with the same inter-axis distance as the support shafts 16 and 17. The slider 15, the lower leg links 18, 19 and the foot 4A form a lower parallel link mechanism 22 that can swing in a vertical plane parallel to the front-rear direction.

  Further, between the upper leg link 10 and the upper body holding frame 2 is connected an upper working cylinder unit 23 that constitutes a part of a free leg self-weight compensation mechanism described later. The upper working cylinder unit 23 has a piston rod 23A whose tip is pivotally supported by a support shaft 24 at an intermediate position in the longitudinal direction of the upper leg link 10 and a position that is a predetermined distance away vertically above the support shaft 8. Thus, the cylinder body 23B is pivotally attached to the vicinity of the rod side end portion by the support shaft 25.

  FIG. 4 is a schematic structural diagram of the free leg self-weight compensation mechanism. In the walking assist device 1 of this embodiment, the free leg self-weight compensation mechanism is provided symmetrically with respect to the left and right leg portions 3A and 3B. However, since the structures of both are basically the same, the structure will be described on the left leg 3A side.

  The free leg self-weight compensation mechanism includes an upper working cylinder unit 23, an upper master cylinder unit 26, a pipe line 27 connecting them, an on-off valve 28 provided in the middle of the pipe line 27, and a compression coil. The upper master cylinder unit 26, the on-off valve 28, and the free leg self-weight compensation spring 29 are mounted on the body holding frame 2.

  As shown in the figure, the support shaft 25 that rotatably connects the cylinder body 23B to the upper body holding frame 2 is the support shaft 8 that connects the upper leg link 10 and the upper body holding frame 2. They are spaced vertically above the center distance h.

  Further, the support shaft 24 that rotatably connects the tip of the piston rod 23A protruding outward from the cylinder body 23B and the upper leg link 10 is centered in the longitudinal direction of the upper leg link 10 from the support shaft 8. They are spaced apart by a distance p.

  In the cylinder body 23B of the upper working cylinder unit 23, a piston 23C fixed to one end of the piston rod 23A is slidably fitted. Ports P1 and P2 are provided in the vicinity of the rod-side end and the head-side end of the cylinder body 23B to communicate the inside and the outside of the cylinder body 23B.

  On the other hand, the upper master cylinder unit 26 has the same structure as the upper working cylinder unit 23, but a spring receiving portion 26B having an enlarged outer diameter is formed at the tip of the piston rod 26A. The aforementioned free leg self-weight compensation spring 29 is incorporated in a compressed state by a predetermined amount between the end face on the rod side and the spring receiving portion 26B.

  Further, ports P1 and P2 similar to the cylinder body 23B of the upper working cylinder unit 23 are provided in the vicinity of the rod side end and the head side end of the cylinder body 26C, respectively. Are connected by a flexible conduit 27.

  Further, the head side ports P2 of the cylinder main body 23B of the upper working cylinder unit 23 and the cylinder main body 26C of the upper master cylinder unit 26 are both open to the atmosphere.

  The cylinder body 23B and the cylinder body 26C have a head side cylinder chamber defined by pistons 23C and 26D, respectively, and the inside of the pipe line 27 communicating between these cylinder chambers is incompressible like oil. Working fluid is enclosed.

  When the on-off valve 28 provided in the middle of the pipe line 27 is closed as shown in the figure, the upper working cylinder unit 23 is connected to the pipe line 27 side through the port P1 of the cylinder body 23B. Since the entrance and exit of the working fluid is blocked, the piston rod 23A does not move, and therefore the rotation of the upper leg link 10 around the support shaft 8 is locked.

  On the other hand, when the on-off valve 28 is opened, when the upper leg link 10 is rotated around the support shaft 8, the piston rod 23 </ b> A of the upper working cylinder unit 23 expands and contracts, and the movement of the working fluid passes through the pipe line 27. To the piston rod 26A of the upper master cylinder unit 26.

That is, the piston rod 23A of the upper working cylinder unit 23 side by a length [delta] L ₁ elongation (contraction), the piston rod 26A of the upper master cylinder unit 26 side, the length [delta] L ₂ in conjunction with this contraction (elongation) To do.

Here, S ₁ the pressure receiving area of the piston 23C of the upper working cylinder unit _23, when the pressure receiving area of the piston 26D of the upper master cylinder unit 26 and S _2, as the working fluid in the oil in the case of incompressible fluid Since the volume of the working fluid flowing out (or flowing in) on the upper working cylinder unit 23 side is equal to the volume flowing in (or flowing out) on the upper master cylinder unit 26 side, the following relationship is established.
δL ₁ S ₁ = δL ₂ S ₂ (1)

If the spring constant of the free leg self-weight compensation spring 29 is K, the force F (the free leg self-weight compensation spring 29 acts on the piston rod 26A of the upper master cylinder unit 26 when it is compressed by δL ₂ from its natural length. The pulling force is as follows:
F = KδL ₂ (2)

Further, if the force transmitted from the upper master cylinder unit 26 side to the piston rod 23A of the upper working cylinder unit 23 through the working fluid flowing through the pipe line 27 is f,
f = (S ₁ / S ₂ ) F (3)

Applying equations (1) and (2) to equation (3)
f = (S ₁ / S ₂ ) KδL ₂ = (S ₁ / S ₂ ) ² KδL ₁ (4)
Here, if k = (S ₁ / S ₂ ) ² K, it can be expressed as f = kδL _1. Therefore, the upper working cylinder unit 23 apparently has a function equivalent to the spring having the spring constant k. .

On the other hand, as shown in FIG. 4, when the center-to-center distance between the support shaft 24 and the support shaft 25 is Ls, the free leg self-weight compensation spring 29 has its natural length (length under no load). It is assembled to the piston rod 26A in a state in which _{(S 1} / S 2) is Ls by compression.

As a result, a pulling force of (S ₁ / S ₂ ) ² KLs acts on the piston rod 23A of the upper working cylinder unit 23, and this rotates the upper leg link 10 around the support shaft 8 in the clockwise direction in FIG. A compensation torque to be moved is generated.

  Here, a free leg state in which the upper body holding frame 2 is supported only by the opposite leg 3B (see FIG. 1) and the left foot 4A is separated from the ground is considered. In this state, it is assumed that the total weight W of the left leg 3 </ b> A including the weight of the upper leg link 10 is concentrated on the virtual point of action G on the upper leg link 10.

  FIG. 5 is a schematic diagram in which the geometric relationship among the body holding frame 2, the upper leg link 10, and the piston rod 23A is simplified. In FIG. 5, the point O is the center position of the support shaft 8, a The point represents the center position of the support shaft 25, and the point b represents the center position of the support shaft 24.

  Θ represents an angle at which the upper leg link 10 is inclined downward from the horizontal direction (direction indicated by X in the drawing), and φ represents an inclination angle of the piston rod 23A with respect to the vertical direction (direction indicated by Y in the drawing). Yes.

When the total weight W of the left leg 3A acting on the action point G exerts on the upper leg link 10 the load torque around the point O, τw and the distance between the point O and the action point G is L,
τw = WLcosθ (5)

On the other hand, when the tensile force acting on the piston rod 23A is to τs compensation torque O point around on the upper leg link 10, by replacing the Ls and [delta] L ₁ in formula (4),
τs = (S ₁ / S ₂ ) ² KLshsinφ (6)

Here, as is apparent from the geometric relationship of FIG.
Lssinφ = pcosθ (7)
Therefore, if sin φ is eliminated from the equations (7) and (6),
τs = (S ₁ / S ₂ ) ² Kphcos θ (8)

Here, the directions of the compensation torque τs and the load torque τw are opposite to each other, and if the spring constant K of the free leg self-weight compensation spring 29 is selected as follows, the leg 3A is applied regardless of the angle θ of the upper leg link 10. It is possible to compensate for the load due to the acting gravity.
K = (S ₂ / S ₁ ) ² WL / ph (9)
The free leg self-weight compensation spring 29 actually used is selected to be slightly smaller than the spring constant K, and adjusted so that the compensation torque τs is slightly lower than the load torque τw.

  When the walking assist device 1 performs a walking motion, the free leg self-weight compensation mechanism described above has a role of reducing the burden of the operation of lifting these leg portions 3A and 3B by opening the open / close valve 28 on the free leg side. Fulfill.

  In the present embodiment, as shown in FIG. 3, the tip of the piston rod 23A of the upper working cylinder unit 23 is rotatably connected to the middle position in the longitudinal direction of the upper leg link 10 by a support shaft 24. Although the cylinder body 23B is rotatably connected to the upper body holding frame 2 by the support shaft 25, the connection position of the upper working cylinder unit 23 is not limited to this, and the expression (8) described above is used. As shown in FIG. 5, if the compensation torque generated by the upper working cylinder unit 23 satisfies a geometrical relationship that changes in proportion to the cosine of the inclination angle of the upper leg links 9, 10, the spring constant K is appropriately set. By selecting, it is possible to compensate for the weight of the free leg.

  Further, as shown in FIG. 3, between the lower leg link 19 which is a component of the lower parallel link mechanism 22 and a bracket 15A provided on the lower surface of the slider 15, a body weight compensation described later is performed. A lower working cylinder unit 30 constituting a part of the mechanism is connected.

  The lower working cylinder unit 30 has a piston rod 30A whose tip is pivotally supported by a support shaft 31 at a midway position in the longitudinal direction of the lower leg link 19, and a position that is separated by a predetermined distance vertically below the support shaft 17. It is composed of a cylinder body 30B pivotally mounted in the vicinity of the rod side end by a support shaft 31A.

  FIG. 6 is a schematic structural diagram of the upper body weight compensation mechanism, and includes a lower working cylinder unit 30, a lower master cylinder unit 32, a pipe line 33 connecting them, an upper body weight compensation spring 34, and An upper body weight compensation mechanism is configured for each of the left leg side and the right leg side by a spring force transmission body 35 interposed between the piston rod 32A of the lower master cylinder unit 32 and the upper body weight compensation spring 34. ing.

  As is clear from the figure, the lower working cylinder unit 30, the lower master cylinder unit 32, and the pipe line 33 connecting them are used in two sets having the same structure for the left leg and the right leg. The upper body self-weight compensation spring 34 and the spring force transmission body 35 are used as a pair for both left and right.

  The lower master cylinder unit 32 is mounted in parallel in a rectangular holding frame 36 attached to the above-described upper body holding frame 2 with the head side end portions of the left and right cylinder bodies 32B being fixed. .

  Further, between these cylinder bodies 32B, guide rods 37 are fixed at both ends between two sides facing the top and bottom of the holding frame 36, and the guide rods 37 are arranged at the center of the aforementioned spring force transmission body. The spring force transmitting body 35 is guided and supported so as to be slidable in the axial direction through a guide hole 35A formed in the portion.

  The spring force transmission body 35 is formed with a pair of piston rod receiving holes 35B at positions symmetrical with respect to the guide hole 35A. The piston rod 32A of the pair of left and right lower master cylinder units 32 penetrates through the piston rod receiving holes 35B so as to be slidable in the axial direction.

  At the tip of these piston rods 32A, an engaging portion 32C having an enlarged outer diameter that engages with the peripheral portion of the piston rod receiving hole 35B on the upper surface of the spring force transmitting body 35 is provided.

  Further, the upper body weight compensation spring 34 is held between the holding frame 36 and the spring force transmission body 35 so as to be extendable and retractable by the guide rod 37, and always urges the spring force transmission body 35 upward. is doing.

  On the other hand, a piston 30C fixed to one end of the piston rod 30A is slidably fitted into the cylinder main body 30B of the left and right lower working cylinder units 30. Ports P1 and P2 are provided in the vicinity of the rod side end of the cylinder body 30B and in the vicinity of the head side end, respectively, for communicating the inside and outside of the cylinder body 30B.

  Further, ports P1 and P2 similar to the cylinder body 30B of the lower working cylinder unit 30 are provided in the vicinity of the rod side end and the head side end of the cylinder body 32B of the lower master cylinder unit 32, respectively. The rod side ports P1 are connected to each of the leg side and the right leg side by a pipe line 33.

  On the other hand, the head side ports P2 of the cylinder main body 30B of the lower working cylinder unit 30 and the cylinder main body 32B of the lower master cylinder unit 32 are both open to the atmosphere.

  Further, the cylinder body 30B and the cylinder body 32B have a head side cylinder chamber defined by the pistons 30C and 32D, respectively, and the inside of the pipe line 33 communicating between these cylinder chambers is not compressed with oil or the like. The working fluid is filled.

  As shown in FIG. 6, the upper body weight compensation mechanism configured as described above is such that the lower leg links 18 and 19 on the left leg side and the right leg side are inclined at the same angle on the left and right sides, so In a state where the piston rod 30A of the cylinder unit 30 protrudes the same length, the engaging portions 32C provided at the tips of the piston rods 32A of the left and right master cylinder units 32 are at the same height, and both are springs. The force transmission body 35 is engaged.

  In this state, the urging force of the upper body weight compensation spring 34 is evenly distributed and transmitted to the left and right piston rods 32 </ b> A via the spring force transmitting body 35, and the left and right lower portions are respectively connected via the pipe line 33. 6 is transmitted as a compensation force in the direction of contraction to the piston rod 30A of the working cylinder unit 30, and a compensation torque is generated to cause the left and right leg links 19 to rotate counterclockwise in FIG. .

  The description of the compensation torque is omitted here, but by selecting the spring constant of the upper body weight compensation spring 34, the same as in the case of the free leg weight compensation mechanism described above, the leg links 18, 19 Regardless of the inclination angle, it is possible to compensate for the upper body weight of the walking assist device 1 including a passenger acting above the foot portions 4A and 4B.

In practice, the spring constant of the upper body weight compensation spring 34 is selected so that the compensation torque is slightly lower than the load torque acting clockwise around the center of the support shaft 21.
Further, in the present embodiment, as shown in FIG. 3, the tip of the piston rod 30A of the lower working cylinder unit 30 is rotatably connected to the middle position in the longitudinal direction of the lower leg link 19 by a support shaft 31, The main body 30B is rotatably connected to a bracket 15A provided on the lower surface of the slider 15 by a support shaft 31A. However, the connection position of the lower working cylinder unit 30 is not limited to this, and the upper working cylinder is not limited thereto. 23, it is only necessary to satisfy a geometrical relationship such that the compensation torque generated by the lower working cylinder unit 30 changes in proportion to the cosine of the inclination angle of the lower leg links 18 and 19.

  Here, as shown in FIG. 1, when the occupant M who has evenly placed his / her weight on the left and right foot portions 4A and 4B moves his / her weight to the right leg support body 4B side, the lower working cylinder unit 30 on the right side. The piston rod 30A is pulled in the extending direction because the load is greater than the compensation force.

  As a result, the force with which the piston rod 32A of the lower master cylinder unit 32 on the right side connected by the pipe line 33 is pulled in the contraction direction increases, while the load on the piston rod 30A of the lower working cylinder unit 30 on the left side decreases. Therefore, the force by which the piston rod 32A of the left lower master cylinder unit 32 is pulled in the contraction direction is reduced.

  Since the piston rod 32A of each of the left and right lower master cylinder units 32 does not transmit the urging force from the upper body weight compensation spring 34 when the engaging portion 32C is separated relative to the spring force transmitting body 35. When the balance of loads acting on the piston rods 32A of the left and right lower master cylinder units 32 is lost due to the weight shift to the right, only the piston rods 32A of the right lower master cylinder unit 32 are connected via the spring force transmission body 35. All of the urging force of the upper body weight compensation spring 34 is transmitted.

  As a result, by moving the weight to the right leg side, all the compensation force by the upper body weight self-weight compensation spring 34 can be applied to the right leg side. Similarly, when the weight is moved to the left leg side, all the compensation force can be applied to the left leg side.

  In the present embodiment, one upper body weight compensation spring 34 is used. However, the present invention is not limited to this. For example, the piston rods 30A of the left and right lower master cylinder units 32 are respectively You may wear them one by one.

  Further, in the present embodiment, a single spring force transmission body 35 is used, but one spring force transmission body is provided for each of the left and right piston rods 30A, and these are provided as links or the like. They may be connected by an interlocking member so that the left and right spring force transmission bodies slide in synchronization.

  Next, FIG. 7 is a schematic structural diagram of an on-off valve control mechanism for performing on-off control of the above-described on-off valve 28. The on-off valve control mechanism 38 is rotatable with respect to the above-described body holding frame 2. And a pivot shaft 39 which is supported by the shaft and faces in the front-rear direction.

  A plate cam 40 having a symmetrical left and right profile is fixed to the rotating shaft 39, and a pair of the on-off valves 28 described above are arranged on both the left and right sides of the plate cam 40. Further, the turning shaft 39 is given a turning behavior that always returns to the neutral position by a return spring 41 connected to the plate cam 40.

  The on-off valves 28 arranged on the left and right sides of the plate cam 40 are incorporated in the pipe line 27 connected to the upper working cylinder unit 23 described with reference to FIG. Those arranged are on the left leg side, and those arranged on the right side correspond to those on the right leg side, respectively.

  When the plate cam 40 rotates by a predetermined angle clockwise from the neutral position, the roller follower 28A provided on the left on-off valve 28 (for the left leg) in the same figure is pressed to open the on-off valve 28, while counterclockwise. When rotated by a predetermined angle, the right on-off valve 28 (for the right leg) is similarly opened.

  Further, the lower end of a rod-shaped tilting response member 42 that is vertically oriented at the neutral position is fixed to the rotary shaft 39, and a short circle is positioned at a midpoint in the longitudinal direction of the tilting response member 42. A columnar engagement pin 43 is provided projecting rearward.

  Although detailed illustration is omitted, the tilting response member 42 moves when the occupant M tilts the upper body to the left or right with respect to the upper body holding frame 2 of the walking assist device 1 shown in FIG. It can be tilted by.

  On the other hand, above the pivot shaft 39, a predetermined position in the vertical direction between the pair of fixed guides 44 and the fixed guides 44 is provided at positions symmetrical to the vertical plane including the central axis of the pivot shaft 39. A gate plate 45 is provided that is slidably guided and supported by a distance of.

  As shown in FIG. 8, the pair of left and right fixed guides 44 and the gate plate 45 are substantially U-shaped and overlap each other when the gate plate 45 is lowered to the lower limit position. Notches a and b are provided.

  Further, as shown in FIG. 7, the left and right gate plates 45 are urged by a pulling spring 46 so as to be always lowered to the lower limit position. As shown in FIG. 8, the overlapping cutouts a and b are provided in the tilting response member 42 when the tilting response member 42 tilts in the left or right direction around the rotation shaft 39. These positions and sizes are set so that the engaging pin 43 can pass.

  When the left and right gate plates 45 are at the lower limit position, as shown in FIG. 9, the tilting response member 42 tilts to the right, and the engagement pin 43 passes through the notch a of the right gate plate 45 to the outside. Then, the plate cam 40 opens the left on-off valve 28, and when the tilting responsive member 42 tilts to the left and the engaging pin 43 passes through the notch a of the right gate plate 45 to the outside, the right on-off valve 28 To open.

  A wire 48 is connected to the upper end portion of each gate plate 45 via a connecting tool 47. Although the detailed description and illustration are omitted, the gate plate 45 on the right side in FIG. 7 is interlocked with the upper parallel link mechanism 14 on the left leg side shown in FIG. Is interlocked with an upper parallel link mechanism on the right leg side (not shown because it has the same structure as the left leg side).

  That is, when the guide frame 13 descends to the lower limit position relative to the body holding frame 2 that is a link element of the upper parallel link mechanism 14 on both the left leg side and the right leg side, the gate plate 45 has moved to the lower limit position where the pair of fixed guides 44 guiding this and the notches a and b communicate with each other.

  When the guide frame 13 is lifted upward from the lower limit position, the gate plate 45 is lifted upward against the urging force of the pulling spring 46 via the wire 48, and a pair of notches a on the gate plate 45 and the pair of notches a. The position of the notch b of the fixed guide 44 is shifted in the vertical direction to close the opening.

  Therefore, as shown in FIG. 10, when the left guide frame 13 is lifted relative to the upper body frame 2 when the engagement pin 43 is moved to the outside of the right gate plate 45, The gate plate 45 is raised and the opening is closed, so that the return movement of the engagement pin 43 is prevented. Therefore, the tilt responding member 42 is held in a state tilted to the right.

  This state is released when the notches a and b are overlapped by returning the left guide frame 13 to the lower limit position, and the tilting response member 42 can be rotated back to the neutral position. In addition, about the case where the inclination response member 42 inclines to the left, since the operation | movement of right and left is only switched, description is abbreviate | omitted.

  The fixed guide 44, the gate plate 45, the wire 48, the tension spring 46, etc. described above constitute an interlock mechanism in the present invention. This interlock mechanism is not limited to the configuration described above, and interlocks with the upper parallel link mechanism 14 including the guide frame 13 when the guide frame 13 is positioned above the lower limit position with respect to the upper body holding frame 2. Thus, it is only necessary to prevent the inclination responsive member 42 from returning to the neutral position and to keep the on-off valve 28 open.

  In the present embodiment, the on / off control of the on / off valve 28 is mechanically performed, but instead of this, an electromagnetic on / off valve is used, and the upper body of the occupant is tilted or the upper body is held. You may electrically perform by detecting the vertical position of the guide frame 13 with respect to the frame 2 with position detection means, such as a limit switch.

Next, the operation of the self-weight-compensated leg walking assist device of the present invention will be described.
A) Case where both feet are grounded and bending / extending operation is performed. FIG. 11 is an explanatory view of the bending / extending operation of both legs at the fixed position of the walking assist device 1 described above, and FIG. The (triggered) state and (b) show a state in which the lower leg links 18 and 19 are bent (tilted).

  Although the passenger is not shown in the figure, the rider is standing upright with both feet on the feet 4A and 4B across the saddle 5 as described above with reference to FIGS. Boarding.

  At the time of the bending / extending operation, the upper body of the occupant is not inclined to the left or right side with respect to the upper body holding frame 2, so that the tilting response member 42 shown in FIG. 7 is in the neutral position, and therefore FIG. The on-off valve 18 shown in FIG.

  In this state, the working fluid is blocked from entering and leaving the left and right upper working cylinder units 23, and the piston rods 23A cannot be expanded or contracted. Therefore, the upper parallel link mechanism 14 including the upper leg links 9 and 10 Both legs are fixed, and the bending and stretching operation is performed only by the movement of the lower parallel link mechanism 22 including the lower leg links 18 and 19.

  In the state where the center of gravity of the walking assist device 1 including the occupant is in the center, as shown in FIG. 6, the compensation force of the body weight compensation spring 34 incorporated in the body weight compensation mechanism is on the left and right sides. Because the piston rod 30A of the lower working cylinder unit 30 acts equally, the left and right lower leg links 18, 19 follow the movement of the occupant when the occupant bends and stretches both legs at the same time in a fixed position. In addition, the body weight compensation mechanism can easily perform the bending and stretching operation.

  During bending and stretching movements, as shown in FIGS. 11A and 11B, the left and right sliders 15 slide back and forth within the movable range with respect to the respective guide frames 13, and the upper ends of the lower leg links 18 and 19 are moved. Absorbs back and forth movement.

B) When performing walking motion Next, FIG. 12 is an explanatory diagram of walking motion by the self-weight-compensated walking assist device 1, and in FIG. .

  FIG. 12 (a) is a side view showing a state where both legs are aligned with each other, as in FIG. 11 (a), and the legs 4A, 4B are in a position where they overlap each other. . In this state, as described above, the flow of the working fluid to the left and right upper working cylinder units 23 is blocked.

  At this time, the upper leg links 9 and 10 are fixed at the lower limit position at the same angle with respect to the upper body holding frame 2 on both the left and right sides. On the other hand, the weights of the lower leg links 18 and 19 are equally compensated for their weights by the upper body weight compensation mechanism at the same left and right angles. Further, each slider 15 is located at an intermediate position in the movable range in the front-rear direction relative to the left and right guide frames 13.

  Next, when the occupant moves the center of gravity of the body to the right leg side, as described above, all of the compensation force of the upper body compensation spring 34 shown in FIG. 6 is transmitted to the lower working cylinder unit 30 on the right leg side. At this stage, no change in the stroke occurs in the piston rod 30A of the left and right lower working cylinder units 30.

  Further, when the passenger tilts the upper body to the right, as shown in FIG. 9 described above, the tilt responding member 42 tilts to the right and the left on-off valve 28 is opened. As a result, the left upper leg links 9 and 10 can be rotated upward with respect to the upper body holding frame 2 in a state where a compensation force is applied from the piston rod 23A of the upper working cylinder unit 23 on the left leg side. Become.

  Next, when the passenger raises the left leg, the left upper leg links 9 and 10 are rotated upward from the lower limit position, and the left leg side foot portion 4A is moved to the floor surface as shown in FIG. Get away from. At this time, since the free leg self-weight compensation mechanism exhibits a compensation force weaker than the leg weight as described above, the upper leg links 9 and 10 are not lifted unless the rider intentionally exerts a force to lift the leg. Absent.

  In conjunction with the upward rotation of the upper leg links 9 and 10 on the left leg side, the right gate plate 45 is pulled up via the wire 48 as shown in FIG. 10, and the engagement pin 43 is connected to the right gate plate. Engage with the outer surface of 45. As a result, the tilting response member 42 is restrained to be tilted to the right, and unless the left leg side upper leg links 9 and 10 are lowered to the lower limit position, the left leg side on-off valve 28 is in an open state. Is retained.

  Next, as shown in FIG. 10 (c), the occupant slides the slider 15 supported by the guide frame 13 on the left leg side forward by stepping his / her left leg forward, and the lower leg link The entire lower parallel link mechanism 22 on the left leg side including 18 and 19 is moved forward, and the right leg is bent to tilt the right lower leg links 18 and 19 whose upper body weight is compensated backward.

  At this time, the upper leg links 9 and 10 in the upper parallel link mechanism 14 on the right side are restrained from rotating because the right on-off valve 28 is closed. Therefore, if the rider bends the right leg, the lower leg link Only 18 and 19 follow and bend.

  Further, as shown in FIG. 10 (d), the passenger lands the left foot portion 4A forward. At this time, since the compensating force of the upper body weight compensation mechanism does not act on the left lower leg links 18 and 19 until the same angle as the right lower leg links 18 and 19 is inclined, the upper leg links 9 and 10 on the left leg side are It turns downward to the lower limit position.

  Then, as shown in FIG. 9, the right gate plate 45 is lowered and the notch a overlaps with the notch b of the fixed guide 44 adjacent to both sides, so that an opening through which the engagement pin 43 can pass is formed. When the occupant returns the tilt of the upper body and rotates the tilt response member 42 to the neutral position shown in FIG. 7, the left on-off valve 28 is closed and the upper leg links 9 and 10 on the left leg are lowered. Fixed at the limit position.

  Further, when the occupant moves his / her weight to the center of both legs, the upper body weight compensation mechanism enters the state shown in FIG. 6 and applies equal compensation force to the lower leg links 18 and 19 on both the left and right sides. Thereafter, the passenger stretches both knees to cause the lower leg links 18 and 19 on both the left and right sides as shown in FIG. The walking motion can be repeated by alternately performing the procedure described above on the left leg side and the right leg side.

  Since the walking assist device 1 in the above-described embodiment is intended to assist a pedestrian, a saddle or a fixing belt is provided on the upper body holding frame 2, but the walking assist device of the present invention is limited to this. Instead of attaching the upper body holding frame to the body of the leg walking robot or power assist suit, and connecting the legs of the leg walking robot or power assist suit to the left and right feet, the robot or power assist It can be configured as a walking assist device for a suit.

  The self-weight-compensated leg walking assist device of the present invention can be used to reduce the load and energy consumption of a walking actuator by being attached to or integrated with a robot that performs leg walking or a power assist suit. It can be used as a walking assist device for persons who have difficulty in walking on their own due to weak legs due to injury, illness, or elderly age.

DESCRIPTION OF SYMBOLS 1 Walking assist apparatus 2 Upper body holding frame 3A, 3B Leg part 4A, 4B Foot part 5 Saddle 6 Fixed belt 7, 8 Support shaft 9, 10 Upper leg link 11, 12 Support shaft 13 Guide frame 13A Vertical part 13B Horizontal part 14 Upper parallel link mechanism 15 Slider 15A Bracket 16, 17 Support shaft 18, 19 Lower leg link 20, 21 Support shaft 22 Lower parallel link mechanism 23 Upper operation cylinder unit 23A Piston rod 23B Cylinder body 23C Piston 24, 25 Support shaft 26 Upper master cylinder Unit 26A Piston rod 26B Spring receiving part 26C Cylinder body 26D Piston 27 Pipe line 28 Open / close valve 28A Roller follower 28A Operation part 29 Free leg self-weight compensation spring 30 Lower operating cylinder unit 30A Piston rod 30B Cylinder body 30C Pi Ton 31, 31A Support shaft 32 Lower master cylinder unit 32A Piston rod 32B Cylinder body 32C Engagement section 32D Piston 33 Pipe 34 Upper body weight compensation spring 35 Spring force transmission body 35A Guide hole 35B Piston rod receiving hole 36 Holding frame 37 Guide Rod 38 Opening / closing valve control mechanism 39 Rotating shaft 40 Plate cam 41 Return spring 42 Inclination responding member 43 Engagement pin 44 Fixed guide 45 Gate plate 46 Pull spring 47 Connector 48 Wire

Claims (2)

A pair of legs configured symmetrically, an upper body holding frame that connects the upper ends of these legs, and a gravity load that is provided for each leg and acts on the legs that are free legs. A free leg self-weight compensation mechanism that compensates, and a body self-weight compensation mechanism that is provided for each leg and compensates for the gravitational load of the upper body acting on the leg serving as a support leg. A self-compensation type walking assist device that assists walking motion by alternately operating a corresponding free leg weight compensation mechanism and upper body weight compensation mechanism together with a walking motion,
Each leg has a pair of upper leg links whose upper ends are pivotally attached to the upper body holding frame, and guide frames whose lower ends of these upper leg links are pivotally attached, respectively. A slider attached to the guide frame so as to be slidable by a predetermined distance in the front-rear direction, a pair of lower leg links pivotally mounted on the upper ends of the sliders, and lower ends of the lower leg links, respectively. Consists of pivoted feet,
The upper body holding frame, the pair of upper leg links, and the guide frame form an upper parallel link mechanism that allows the guide frame to translate in a vertical plane including the front-rear direction with respect to the upper body holding frame.
The slider, the pair of lower leg links, and the foot part form a lower parallel link mechanism in which the foot part can translate in a vertical plane including the front-rear direction with respect to the slider.
Each free leg self-weight compensation mechanism includes a free leg self-weight compensation spring, an upper master cylinder unit having a piston rod that receives an urging force of the free leg self-weight compensation spring, and an upper parallel link mechanism. And an upper working cylinder unit that transmits an urging force of the free leg weight compensation spring to the upper parallel link mechanism.
Each upper body weight compensation mechanism is provided so as to be slidable along the upper body weight compensation spring, a lower master cylinder unit having a piston rod provided with an engaging portion at the tip, and a piston rod of the lower master cylinder unit. And a spring force transmission body that receives the biasing force of the upper body weight compensation spring and transmits the biasing force of the upper body weight compensation spring to the piston rod when it comes into contact with the engagement portion,
Built into the lower parallel link mechanism, connected to the lower master cylinder unit via a conduit, and composed of a lower working cylinder unit that transmits the urging force of the upper body weight compensation spring to the lower parallel link mechanism,
The lower master cylinder units of the upper body weight compensation mechanism corresponding to the respective legs are provided in parallel with the piston rods facing the same side, and the spring force transmission bodies corresponding to the respective piston rods are integrated with each other. Alternatively, a self-compensation type walking assist device configured to slide in synchronization.   A saddle straddling the passenger is attached to the upper body holding frame, and when the upper body tilts from the neutral position to the left or right by a predetermined angle in response to the horizontal tilt of the passenger's upper body In addition, a tilting response member that opens the open / close valve of the free leg self-weight compensation mechanism of the leg portion on the opposite side to the tilt side, and the guide frame of the opposite leg portion are positioned above the lower limit position with respect to the body holding frame. And an interlock mechanism that holds the on-off valve in an open state by preventing the return to the neutral position of the inclined response member in conjunction with the upper parallel link mechanism including the guide frame. The self-weight-compensated walking assist device according to claim 1.

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