JP6722811B2 - Assistance robot - Google Patents

Description

The present invention relates to a assistance robot that assists a person being assisted in standing up.

The assistance robots described in Patent Documents 1 to 4 are known. This kind of assistance robot assists the movement from the sitting posture to the standing posture. These assistance robots move to the standing posture while holding a part of the upper half of the body of the person being assisted in the sitting posture.

Japanese Unexamined Patent Publication No. 09-066082 JP 2012-030077 A JP, 2008-067849, A JP 2012-217686A

By the way, in order to assist the standing motion in a more stable state, it is required to perform the standing motion according to the seated posture of the person being assisted and the physique of the person being assisted.

It is an object of the present invention to provide a assistance robot capable of performing a standing motion according to the seated posture of the person being assisted and the physique of the person being assisted. Another object of the present invention is to provide an assisting robot capable of performing the above-mentioned standing motion with a simple configuration.

The assistance robot according to the present invention includes a base, a holding base that is movable at least up and down with respect to the base, a holding unit that is provided on the holding base, and holds a part of the body of the person being assisted, An actuator that performs an operation of the holding unit with respect to a base, a storage unit that stores in advance an operation locus of the actuator for moving the holding unit from a sitting posture to a standing posture, and the physique of the person being seated And a vertical movement operating section for inputting a change in the vertical position of the holding section in the sitting posture so as to match at least one of the seating height and the actuator, and the holding section from the sitting posture. A control unit for moving the holding unit to the upright posture, the control unit moving the vertical position of the holding unit based on an input operation to the vertical movement operation unit, and the holding unit after the movement. The operation locus of the actuator for moving to the standing posture is corrected according to the vertical position of the.

By performing an input operation on the person being assisted or an assistant on the vertical movement operation part, the vertical position of the holding part in the sitting posture can be changed to match at least one of the physical size and the sitting height of the person being seated. Becomes Then, the operation locus of the actuator for moving the holding unit to the upright posture is corrected according to the vertical position of the holding unit after the movement. That is, the start position of the operation of the holding unit that moves to the standing posture can be freely determined according to the physique and the sitting height of the person being assisted. In particular, since the start position is freely determined to be an arbitrary vertical position by the person being assisted or an input operation by the person being assisted, the operability of the assistance robot is improved, and the standing movement of the person being assisted is stably performed.

FIG. 7 is a diagram of the assistance robot according to the embodiment of the present invention, as viewed from the right side. It is the figure seen from the right side of the outline of the internal structure of the assistance robot in the extended state shown in FIG. It is the figure which looked at from the back of the outline of the internal structure of the assistance robot in the extended state shown in FIG. It is the figure seen from the upper part around the holding part shown in FIG. It is the figure seen from the upper part around the holding part of the state where the elbow rest pad of the holding part shown in Drawing 4A was moved. It is sectional drawing which shows the detection apparatus among the holding parts shown in FIG. It is a functional block diagram regarding the control apparatus shown in FIG. It is the figure which looked at the situation that the assistance robot is supporting the seated person from the right side. It is the figure which looked at the state that the assistance robot is supporting the person being assisted standing up from the right side. It is a figure which shows the stand-up operation of a assistance robot. 7 is a flowchart showing processing by the first control unit shown in FIG. 6. 7 is a flowchart showing processing by the correction unit shown in FIG. 6. 7 is a flowchart showing processing by the second control unit shown in FIG. 6. It is a figure which shows the other standing up movement of a support robot. It is a figure which shows the other standing up movement of a support robot. It is the figure seen from the right side of the assistance robot which attached other holding parts. It is the figure seen from the upper part around the other holding part shown in FIG. It is the figure seen from the upper part around a holding part in the state where the space of the right and left side holding parts of the other holding part shown in Drawing 14 was changed. It is the figure seen from the right side of the assistance robot which attached the holding part using a cam mechanism. It is the figure seen from the upper part of the components of the cam mechanism shown in FIG. FIG. 17 is a partial cross-sectional view of a part of the assistance robot of FIG. 16 viewed from the right side. It is the figure seen from the right side of some assistance robots in the state where the holding part was moved. It is a fragmentary sectional view of the figure seen from the right side of a part of assistance robot of FIG. It is the figure seen from the right side of a part of assistance robot in the state where a part of cam groove is used.

(1. Configuration of assistance robot)
Hereinafter, an embodiment of the assistance robot according to the present invention will be described. The assistance robot 10 supports a part of the body of the person M1 to be assisted (for example, the upper half of the body) to assist standing and sitting. As shown in FIGS. 1 to 3, the assistance robot 10 includes a base portion 11, an actuator 12, a holding portion 13, a handle (grasping portion) 14, an operating device 15, a storage device (storage portion) 16, and a control device 17. Hereinafter, the structure of the assistance robot 10 (a configuration excluding the storage device 16 and the control device 17) will be described with reference to FIGS. 1 to 5. Further, in the following description, front, rear, left and right are front, rear, left and right when the traveling direction of the assistance robot 10 is the front.

The base 11 includes a base 21, a base cover 22, and a boarding plate 23. The base 21 is formed in a substantially U-shape in a plan view that opens rearward (leftward in FIG. 1). Specifically, the base 21 is a connecting frame 21c that connects the left and right frames 21a and 21b and one end of the left and right frames 21a and 21b (in this embodiment, the front end (rightward in FIGS. 1 and 2)). Equipped with. The left and right frames 21a and 21b are arranged with a space necessary for the person being assisted M1 to enter.

Left and right rear wheels 21d and 21e are provided at the rear ends of the left and right frames 21a and 21b, respectively. The left and right rear wheels 21d and 21e may be driven by motors. Left and right front wheels 21h and 21i are provided at the front end portions of the left and right frames 21a and 21b, respectively. The left and right front wheels 21h and 21i can rotate according to the traveling direction of the assistance robot 10.

As shown in FIG. 1, the base cover 22 is a cover that covers the base 21 from above. Similar to the base 21, the base cover 22 is formed in a substantially U-shape in a plan view that opens rearward. The boarding plate 23 is provided in the U-shaped opening of the base 21, as shown in FIGS. 2 and 3. The assistance robot 10 functions as a towing vehicle when the person M1 to be assisted gets on the boarding plate 23. Further, the boarding plate 23 can be set upright as shown by the chain double-dashed line in FIG. In this case, the assistance robot 10 functions as a walker.

The actuator 12 (30) includes a slide portion 31 and a tilting portion 32, as shown in FIGS. 2 and 3. The slide portion 31 moves the holding portion 13 up and down with respect to the base 21. The tilting unit 32 tilts the holding unit 13 with respect to the base 21.

The slide portion 31 (40) includes left and right slide portions 41 and 42. As shown in FIG. 3, the left slide portion 41 includes a slide base portion 41a, a first slide portion 41b and a second slide portion 41c. The base of the left slide portion 41 is attached to the left frame 21 a of the base 21. That is, the slide base 41a is attached to the base 21 inclining to the front side at a predetermined angle (for example, 80 degrees). The first slide portion 41b slides in the longitudinal direction (axial movement direction) with respect to the slide base portion 41a, and is configured to be substantially accommodated in the slide base portion 41a when contracted. The second slide portion 41c slides in the longitudinal direction (axial movement direction) with respect to the first slide portion 41b, and is configured to be substantially accommodated in the first slide portion 41b when contracted. ..

An arm portion 43 (holding base portion) extending rearward is attached to the upper end of the second slide portion 41c. In the present embodiment, the arm portion 43 is orthogonal to the longitudinal direction of the left slide portion 41. The holding portion 13 is rotatably attached to the tip of the arm portion 43.

Further, the slide portion 31 includes a drive motor 45 (vertical movement actuator, first actuator) that slides the first and second slide portions 41b and 41c. The output of the drive motor 45 is configured to be transmitted to the second belt 48 via the speed change mechanism 46 and the first belt 47. The second belt 48 is mounted on the pulley 48a and the pulley 48b. The pulley 48a is rotatably attached to the lower end of the slide base 41a. The pulley 48b is rotatably attached to the upper end of the slide base 41a. The lower end of the first slide portion 41b is fixed to the second belt 48.

The third belt 49 is mounted on the pulley 49a and the pulley 49b. The pulley 49a is rotatably attached to the lower end of the first slide portion 41b. The pulley 49b is rotatably attached to the upper end of the first slide portion 41b. The lower end portion 41c1 of the second slide portion 41c is fixed to one side of the third belt 49. The upper end 41a1 of the slide base 41a is fixed to the other side of the third belt 49.

The left slide portion 41 includes a slide cover 41d (shown in FIG. 1) that covers the first slide portion 41b and the second slide portion 41c. The slide cover 41d is formed in a tubular shape. The slide cover 41d may be configured by one tubular body, or may be configured by a two-stage slide type in which two tubular bodies slide.

As shown in FIGS. 2 and 3, the right slide portion 42 includes a slide base portion 42a, a first slide portion 42b, and a second slide portion 42c, like the left slide portion 41. The base of the right slide portion 42 is attached to the right frame 21b of the base 21. An arm portion 44 (holding base portion) extending rearward is attached to the upper end of the second slide portion 42c. The holding portion 13 is rotatably attached to the tip of the arm portion 44.

Further, the output of the drive motor 45 is transmitted to the second belt 52 via the speed change mechanism 46 and the first belt 51. The second belt 52 is mounted on the pulleys 52a and 52b. The pulley 52a is rotatably attached to the lower end of the slide base 42a. The pulley 52b is rotatably attached to the upper end of the slide base 42a. The lower end of the first slide portion 42b is fixed to the second belt 52.

The third belt 53 is mounted on the pulley 53a and the pulley 53b. The pulley 53a is rotatably attached to the lower end of the first slide portion 42b. The pulley 53b is rotatably attached to the upper end portion of the first slide portion 42b. The lower end portion 42c1 of the second slide portion 42c is fixed to one side of the third belt 53. The upper end 42a1 of the slide base 42a is fixed to the other side of the third belt 53.

The right slide portion 42 includes a slide cover 42d (shown in FIG. 1) that covers the first slide portion 42b and the second slide portion 42c. The slide cover 42d is configured similarly to the slide cover 41d.

When the drive motor 45 is driven in the forward direction, the second belt 48 is rotated, and the first slide portion 41b extends along the axial movement direction with respect to the slide base portion 41a. At the same time, the third belt 49 is rotated with the rise of the first slide portion 41b, and the second slide portion 41c extends in the axial direction with respect to the first slide portion 41b. The extension operation of the left slide portion 41 is the same as that of the right slide portion 42.

On the other hand, when the drive motor 45 is driven in the opposite direction, the second belt 48 is rotated in the opposite direction to that when it is stretched, and the first slide portion 41b contracts with respect to the slide base portion 41a along the axial movement direction. At the same time, as the first slide portion 41b is lowered, the third belt 49 is rotated in the opposite direction to that when it is extended, and the second slide portion 41c contracts with respect to the first slide portion 41b along the axial movement direction. The contraction operation of the left slide portion 41 is the same for the right slide portion 42. As a result, the arm portions 43, 44 and the holding portion 13 are moved up and down with respect to the base 21. The slide portion 31 may use a ball screw or the like instead of the structure using a belt.

The tilting portion 32 includes left and right tilting portions 32a and 32b. The left tilting portion 32a includes a drive motor 32a1 (tilt actuator), a conversion mechanism 32a2, and an output rod 32a3. The conversion mechanism 32a2 incorporates, for example, a ball screw, converts the rotational output of the drive motor 32a1 into a linear motion, and outputs the linear motion to the output rod 32a3. The output rod 32a3 moves back and forth in the axial direction with respect to the conversion mechanism 32a2. The drive motor 32a1 and the conversion mechanism 32a2 are attached to the lower end portion of the second slide portion 41c. The left tilting portion 32a is tiltably attached to the second slide portion 41c and the arm portion 43. The output end of the output rod 32a3 is tiltably attached to the front end of the holding unit 13.

The right tilting portion 32b includes a drive motor 32b1 (tilt actuator), a conversion mechanism 32b2, and an output rod 32b3, like the left tilting portion 32a. The drive motor 32b1 and the conversion mechanism 32b2 are attached to the lower end portion of the second slide portion 42c. The right tilting part 32b is tiltably attached to the second slide part 42c and the arm part 44. The output end of the output rod 32b3 is tiltably attached to the front end of the holding unit 13.

When the drive motor 32a1 is driven in the forward direction, the output rod 32a3 advances (extends) in the output direction. At the same time, when the drive motor 32b1 is driven in the forward direction, the output rod 32b3 advances (expands) in the output direction. As a result, the holding portion 13 rotates (is tilted backward) in the counterclockwise direction (in FIGS. 1 and 2) around the rotation axis A1. On the other hand, when the drive motor 32a1 is driven in the opposite direction, the output rod 32a3 retracts (contracts). At the same time, when the drive motor 32b1 is driven in the forward direction, the output rod 32b3 retracts (contracts). As a result, the holding portion 13 rotates (is tilted forward) in the clockwise direction (in FIGS. 1 and 2) around the rotation axis A1. As a result, the holding portion 13 is tilted with respect to the base 21 and the arm portions 43 and 44.

The holding portion 13 is at least vertically movable and tiltable with respect to the base 21. Further, the holding portion 13 is tiltable with respect to the arm portions 43 and 44. Further, the holding portion 13 is an attachment that can be attached to and detached from (replaceable with) the arm portions 43 and 44. That is, the holding portion 13 is formed according to the physique of the person being assisted M1. The holding unit 13 suitable for the person M1 to be assisted who uses the assistance robot 10 is attached to the arm units 43 and 44.

The rear end portion of the holding portion 13 is rotatably attached around the rotation axis A1 of the arm portions 43 and 44. The front end portion of the holding portion 13 is adjusted to a predetermined angle with respect to the horizontal plane by the tilting portion 32, and is supported at that position. The holding unit 13 holds a part of the body (for example, the upper half of the body) of the person being assisted M1 and assists standing, sitting and walking (moving).

The holding unit 13 is a member that supports the upper body of the person being assisted M1 when facing the person being assisted M1 in the standing motion and the sitting motion of the person being assisted, for example. As shown in FIG. 4A, the holding portion 13 is formed in a substantially U-shape in a plan view that opens rearward (downward in FIG. 4A). The holding portion 13 is configured in a state where two plate members 61 and 62 (holding portion main body and attachment main body) formed in a substantially U shape in plan view are stacked. As shown in FIG. 5, a detection device 63 that detects the weight distribution received from the person being assisted M1 is provided between the plate member 61 and the plate member 62.

The detection device 63 includes a plurality of pressure sensors 63a. In the present embodiment, the pressure sensors 63a are arranged at the four corners of the holder 13. Two pressure sensors 63a are provided on the left and right along the front-rear direction (left-right direction in FIG. 5) of the person being assisted M1. The pressure sensor 63a provided in the front direction of the person being assisted M1 is the front side pressure sensor 63af. The pressure sensor 63a provided in the rearward direction of the person being assisted M1 is the rear side pressure sensor 63ar. The pressure sensor 63a detects a strain amount of a strain-generating body that changes according to a change in load as a voltage change, or when pressure is applied to a silicon chip, the gauge resistance changes according to the deflection and is converted into an electric signal. For example, a semiconductor pressure sensor. The detection device 63 may be composed of a planar pressure sensor.

As shown in FIG. 4A, a pair of elbow rest pads 64, 64 (elbow rests) are provided at the rear end of the upper surface of the holding portion 13. A pair of handles 14, 14 (grasping portions) are provided at the front end of the upper surface of the holding portion 13. The handles 14 and 14 are adapted to be gripped by the left and right hands of the person being assisted M1.

As shown in FIG. 4B, each of the left and right elbow rest pads 64, 64 is provided on the plate member 61 (holding portion main body) so that the distance between the left and right sides of the person being assisted M1 is variable. Further, each of the left and right elbow rest pads 64, 64 is provided so that the front-rear spacing with the handles 14, 14 is variable. For example, the elbow rest pads 64, 64 may be detachable from the plate member 61, or a mechanism that is guided so as to be movable in the front-rear direction and the left-right direction may be adopted.

The positions of the left and right elbow rest pads 64, 64 are appropriately adjusted according to the physique of the person being assisted M1. Thereby, the person being assisted M1 maintains a comfortable posture, and the posture of the person being assisted M1 is easily stabilized when the person being assisted M1 moves from the sitting posture to the standing posture.

A body detection switch 66 (body detector) is provided in the center of the holding portion 13 in the front-rear direction and the center of the left-right direction. The body detection switch 66 projects upward from the upper surface of the plate member 61 and detects contact with the body of the person being assisted M1.

An operating device 15 is provided at the front end of the upper surface of the holding portion 13. The operation device 15 includes a display unit 15a that displays an image and an operation unit 15b that receives an input operation from a user (assistant or person being assisted M1). The display unit 15a is composed of a liquid crystal display, and displays an operation mode selection screen of the assistance robot 10 and the like. The operation unit 15b is provided with a cursor key for moving the cursor up, down, left and right, a cancel key for canceling the input, a decision key for deciding the selected content, and the like, and is configured so that a user's instruction can be keyed in.

The operation device 15 includes at least the function of the vertical movement operation unit 15c that allows the person being assisted M1 or the assistant to change the vertical position of the holding unit 13, and the function of the height acquisition unit 15d that acquires the height of the person being assisted M1. , And the function of the standing up start switch 15e. The vertical movement operation unit 15c, the height acquisition unit 15d, and the standing up start switch 15e may cause the display unit 15a to display the performance status of the function. The operation device 15 has a display function of the display unit 15a and an input function of the operation unit 15b, and may be configured by a touch panel that operates the device by pressing the display on the screen.

As shown in FIG. 1, a cover 65 is attached to the lower surface of the holding portion 13 so as to face downward. The cover 65 is formed in a plate shape and a fan shape, and closes the gap between the holding portion 13 and the arm portion 43 (or the arm portion 44).

(2. Description of storage device and control device)
The storage device 16 and the control device 17 will be described with reference to FIGS. 6 to 13. The storage device 16 (storage unit) moves the holding unit 13 from the reference sitting posture to the reference standing posture when the virtual person being assisted M1 corresponding to a predetermined standard physique stands up from the sitting state. The operation loci of the drive motor 45 as the vertical movement actuator and the drive motors 32a1 and 32b1 as the tilt actuators are stored.

As shown in FIG. 7A, the reference sitting posture of the holding unit 13 refers to a state in which the virtual support recipient M1 is seated on a seating portion having a predetermined height and the forearm of the support recipient M1 is supported. This is the posture of the holding unit 13 of FIG. As shown in FIG. 7B, the reference standing posture is the posture of the holding unit 13 that supports the forearm of the person being assisted M1 while the virtual person being assisted M1 is standing.

When the assistance robot 10 operates according to the movement loci of the actuators 45, 32a1, 32b1 stored in the storage device 16, the movement locus Tas1 of the shoulder of the person being assisted M1 is indicated by the broken line in FIG. That is, the person being assisted M1 stands up while leaning forward.

The control device 17 controls the drive motor 45 as a vertical actuator and the drive motors 32a1 and 32b1 as a tilt actuator based on various information. The control device 17 includes a first control unit 17a, a correction unit 17b, and a second control unit 17c.

As shown in FIG. 9, the first control unit 17a determines the operation input to the vertical movement operation unit 15c by the person being assisted M1 or the assistant (S11). The first control unit 17a controls the drive motor 45 as a vertical movement actuator according to the vertical movement operation when an operation is input to the vertical movement operation unit 15c (S12).

Specifically, when the person being assisted M1 is in a seated state and the person being assisted M1 or the person performing an operation to move the vertical movement operation unit 15c upward, the first control unit 17a causes the drive motor 45 to operate. It is controlled to move the holding unit 13 upward. On the other hand, when the person being assisted M1 is in a seated state and the person being assisted M1 or the person making an operation to move the up/down operation section 15c downward, the first controller 17a controls the drive motor 45. , The holding unit 13 is moved downward.

That is, the first control unit 17a moves the holder 13 so that the height of the holder 13 matches the height of the forearm of the person M1 when the person M1 is seated. The height of the forearm of the person being assisted M1 in the sitting state varies depending on the height of the seated portion and the physique of the person being assisted M1. Therefore, the person being assisted M1 or the person who is being assisted operates the vertical movement operation unit 15c, so that the height of the holding unit 13 easily matches the height of the forearm of the person being assisted M1.

The correction unit 17b corrects the reference motion locus stored in the storage device 16 based on the vertical position of the holding unit 13 moved by the first control unit 17a and the height of the person being assisted M1. As shown in FIG. 10, the correction unit 17b acquires the vertical position of the holding unit 13 in the state operated by the first control unit 17a (S21). Next, the correction unit 17b acquires the height of the person being assisted M1 acquired by the height acquisition unit 15d (S22), and acquires the motion trajectory stored in the storage device 16 (S23).

The correction unit 17d corrects the motion locus stored in the storage device 16 based on the acquired information. For example, as shown in FIG. 12, the person being assisted M1 is seated in a high sitting portion, and the height of the person being assisted M1 is stored in the storage device 16 and the person being assisted M1 having a standard physique is stored. In the same case, the movement locus Tas2 of the shoulder of the person being assisted M1 by the corrected movement locus of the actuator becomes the movement locus shown by the solid line. Here, the broken line in FIG. 12 is the movement trajectory Tas1 of the shoulder of the person being assisted M1 stored in the storage device 16.

Further, when the person being assisted M1 is smaller than the person being assisted with a standard physique M1, the movement trajectory Tas3 of the shoulder of the person being assisted M1 by the corrected movement trajectory of the actuator is shown in FIG. The movement locus is shown by the solid line. The broken line in FIG. 13 is the motion trajectory Tas1 of the shoulder of the person being assisted M1 stored in the storage device 16.

The second control unit 17e controls the drive motor 45 as a vertical movement actuator and the drive motors 32a1 and 32b1 as tilt actuators based on the motion locus of the actuator corrected by the correction unit 17d.

As shown in FIG. 11, the second controller 17e determines whether or not the standing up start switch 15e is ON (S31). If the standing up start switch 15e is ON, the second controller 17e determines whether the body detection switch 66 is ON (S32). The state in which the body detection switch 66 is ON is a state in which the person being assisted M1 is leaning against the body detection switch 66. The second control unit 17e repeats the process from S31 again if any of the above determinations is not satisfied. In other words, the second control unit 17e performs the standing-up operation when the body detection switch 66 is ON, and thus can realize the stable standing-up operation of the person being assisted M1.

When the standing up start switch 15e and the body detection switch 66 are ON, the second control unit 17e acquires the motion locus of the actuator corrected by the correction unit 17d (S33). Subsequently, the second control unit 17e acquires each load detected by the pressure sensor 63a (S34), and performs stand-up control according to the corrected operation trajectory and load of the actuator. For example, when the person being assisted M1 leans significantly forward, the second control unit 17e controls the person M1 to lean forward. In addition, when the person being assisted M1 is greatly tilted backward, the second control unit 17e performs control so as to regulate the backward tilt of the person being assisted M1. The second control unit 17e repeats the processing of S34 and S35 until reaching the standing position, and ends the processing when reaching the standing position (S36).

As described above, when the person being assisted M1 or the person who is being assisted operates the vertical movement operation unit 15c, the position of the holding unit 13 can be moved to any position when the person being assisted M1 is seated. The operation locus of the actuator for moving the holding unit 13 to the predetermined upright posture is corrected according to the vertical position of the moved holding unit 13. That is, the start position for moving to the standing posture is freely determined according to the sitting height of the person being assisted M1 and the physique of the person being assisted M1. Particularly, since the start position is freely determined to be an arbitrary position by the operation of the person being assisted M1 or the person being assisted, the operability is improved and the standing motion is stably performed. The physique here refers to the length of the body of the person being assisted M1, the size of the buttocks, the length of the upper arm, and the like. Further, the motion locus of the actuator is corrected according to the height of the person being assisted M1. Therefore, the assistance robot 10 can perform an appropriate standing motion according to the physique of the person being assisted M1.

Further, the elbow rest pads 64, 64 are variably provided in the left-right space of the person being assisted M1, and are also variably provided in the front-rear space with the handles 14, 14. That is, the holding unit 13 corresponds to the physique of the person being assisted M1. Therefore, the assistance robot 10 can more reliably and stably perform the standing motion of the person M1 to be assisted.

(3. Attachment)
The holding portion 13 is an attachment that can be attached to and detached from the arm portions 43 and 44, as described above. The holding portion 13 having the elbow rest pads 64, 64 and the handles 14, 14 can be replaced according to the person being assisted M1.

In addition to the holding portion 13 having the above structure, the holding portion 113 shown in FIGS. 14 to 15B can be applied. The holding unit 113 is of a type that is sandwiched between the left and right sides of the person being assisted M1. The holding portion 113 is an attachment that can be attached to and detached from the arm portions 43 and 44.

The holding unit 113 includes a holding unit body 166 on the upper surface of the plate member 61. The holding portion main body 166 includes a center fixing portion 166a fixed to the center of the plate member 61 and left and right side holding portions 166b and 166c. The left and right arm holding portions 166b and 166c are slidable with respect to the center fixing portion 166a. That is, the shape of the holding portion main body 166 is appropriately changed according to the physique of the person being assisted M1.

In this way, the holding portions 13 and 113 are attachments that can be attached to and detached from the arm portions 43 and 44, so that the support person M1 can be in accordance with the physique of the person being assisted M1 and the medical condition of the person being assisted M1. Appropriate holding parts 13, 113 are applied. As a result, a stable standing motion is performed. The physique here is the physique of the person being assisted M1 such as a large or small person.

(4. Cam mechanism)
In the above, the holding portions 13 and 113 rotate about the rotation axis A1 with respect to the arm portions 43 and 44. Here, when the assistance robot 10 performs a standing motion with respect to the person to be assisted M1 from a seated state, it is desired that the assistance robot 10 rise while tilting the person to be assisted M1 forward. The assistance robot 10 having the above configuration can raise the person being assisted M1 while leaning forward. Hereinafter, the assistance robot 200 that can perform a larger forward tilting motion by using the cam mechanism will be described.

As shown in FIGS. 16 to 18, the assisting robot 200 includes arm portions 243 and 244 (holding base portions) extending forward from the upper ends of the second slide portions 41c and 42c. The arm portions 243 and 244 are connected by the connecting portion 245 at the front end sides of the arm portions 243 and 244. Further, each of the arm portions 243 and 244 is provided with two cam pins 243a, 243a, 244a and 244a that project to the outside on the left and right.

The holding portion 213 includes cam plates 266 and 267 fixed to the left and right of the lower surface of the plate member 62. The rear ends of the cam plates 266 and 267 are connected by the connecting portion 268. Cam grooves 266a and 267a are formed in the cam plates 266 and 267. The cam grooves 266a and 267a are linearly formed on the front side and arcuate on the rear side. Cam pins 243a and 244a are movably inserted into the cam grooves 266a and 267a along the cam grooves 266a and 267a. That is, the holding portion 213 is connected to the arm portions 243 and 244 by the cam mechanism so as to be movable back and forth and tiltable.

Further, the assistance robot 200 includes a linear motion actuator 232 (second actuator). One end of the linear motion actuator 232 is tiltably provided on the connecting portion 245, and the other end of the linear motion actuator 232 is tiltably provided on the connecting portion 268.

The linear actuator 232 is controlled by the second controller 17e. When the linear motion actuator 232 contracts from the state where the linear motion actuator 232 extends as shown in FIGS. 16 and 18, the holding portion 213 becomes as shown in FIGS. 19 and 20. That is, when the linear motion actuator 232 contracts, the holding portion 213 moves to the front side by the linear portions of the cam grooves 266a and 267a. Further, the arcuate portions of the cam grooves 266a and 267a cause the holding portion 213 to tilt forward. Therefore, the one linear actuator 232 causes the holding portions 213 to move back and forth and tilt with respect to the arm portions 243 and 244. The above-described operation of the holding unit 213 is possible with a simple configuration.

When the person being assisted M1 has a small physique, the second control unit 17e does not use the entire range of the cam grooves 266a and 267a, but a part of the cam grooves 266a and 267a, as shown in FIG. Can also be used. That is, the correction unit 17b corrects the operation locus of the actuator 232 so that the operation ranges of the cam grooves 266a and 267a differ according to the physique of the person being assisted M1. As a result, proper back-and-forth movement and tilting according to the physique of the person being assisted M1 are realized.

10, 200: Assistance robot, 13, 113, 213: Holding unit, 14: Handle (grasping unit), 15c: Vertical movement operating unit, 15d: Height acquisition unit, 15e: Standing start switch, 16: Storage device (storage unit ), 17: control device, 17a: first control unit, 17b: correction unit, 17c: second control unit, 17d: correction unit, 17e: second control unit, 21: base, 31: slide unit, 32: Tilt unit, 32a1, 32b1: Drive motor (actuator), 43, 44, 243, 244: Arm part (holding base), 45: Drive motor (first actuator), 61, 62: Plate member (attachment body) , 64: Elbow rest pad (elbow rest part), 66: Body detection switch, 232: Direct acting actuator (second actuator), M1: Assistee

Claims (5)

A base,
A holding base that can move at least vertically with respect to the base;
A holding portion which is provided on the holding base and holds a part of the body of the person being assisted,
An actuator that operates the holding unit with respect to the base,
A storage unit that stores in advance a motion trajectory of the actuator for moving the holding unit from the sitting posture to the standing posture,
A vertical movement operation unit for inputting a change in the vertical position in the sitting posture of the holding unit so as to match at least one of the physique and the sitting height of the person being seated,
A control unit that controls the actuator and moves the holding unit from the sitting posture to the standing posture;
Equipped with
The control unit is
The vertical position of the holding unit is moved based on an input operation to the vertical movement operation unit, and the vertical position of the holding unit after the movement is moved to the upright posture according to the vertical position. An assisting robot that corrects the movement locus of the actuator. The assistance robot according to claim 1, wherein the holding unit includes an attachment body whose shape can be changed according to the physique of the person being assisted. The assistance robot according to claim 1, wherein the holding unit sandwiches the left and right sides of the person being assisted. The holding portion is
Left and right elbow rests,
Left and right grips gripped by the person being assisted,
The assistance robot according to claim 1, further comprising: The assistance robot according to any one of claims 1 to 4, wherein the holding unit is detachably attached to the holding base.

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