WO2016103497A1 - Assistance robot - Google Patents

Abstract

Provided is an assistance robot such that a person to be assisted thereby can be prevented from feeling discomfort during vertical movement of a lifting member thereof. The assistance robot (1) comprises: a base (10); a holding part (50) which holds a portion of the body of the person being assisted (M1) and moves vertically relative to the base (10); actuators (70, 80) which drive the vertical movements of the holding part (50) relative to the base (10); detectors (110, 210) which are provided in the holding part (50) and detect contact or proximity of the holding part (50) to an object; and a control device (120) which stops the holding part (50) from being moved vertically to the object side by the actuators (70, 80) if the detectors (110, 210) have detected contact or proximity of the holding part (50) to the object while the actuators (70, 80) are vertically moving the holding part (50).

Description

Assistance robot

The present invention relates to an assistance robot that assists the standing person in standing up.

Patent Document 1 describes an apparatus that assists a person being assisted in standing up. In the apparatus, the support member that supports the person being assisted moves up and down. The support member is provided with two operation handles for the person being assisted to operate the ascending operation and the descending operation. When the person being assisted grips the support member and grips one of the operation handles, the support member rises, and when the other handle is gripped, the support member descends.

JP-A-9-66082

When the user in the sitting position lowers the support member, the support member may be lowered too much and the support member may press the leg of the person being assisted. The person being assisted may feel uncomfortable due to the pressing force of the support member.

An object of the present invention is to provide an assistance robot capable of preventing the person being assisted from feeling uncomfortable when the elevating part moves up and down.

The assistance robot includes a base, a holding part that holds a part of the body of the person being assisted, and moves up and down relative to the base, an actuator that drives the lifting and lowering operation of the holding part relative to the base, A detector provided in the holding unit that detects contact or approach to the object by the holding unit, and contact or approach to the object by the detector while the actuator is moving up and down the holding unit. And a control device that stops the movement of the holding unit toward the object by the actuator.

When the part of the person being assisted comes into contact with the holding part or approaches the holding part, the movement of the holding part to the object side stops, so that the person being assisted can be prevented from being pressed by the holding part. As a result, the person being assisted can be prevented from feeling uncomfortable.

It is the figure which looked at the assistance robot 1 of 1st embodiment from the traveling direction right side. The right side of the figure is the front in the direction of travel. It is a top view of the assistance robot 1 of FIG. The right side of the figure is the front in the direction of travel. It is the figure which looked at the assistance robot 1 from the back of the advancing direction. It is the figure which looked at the assistance robot 1 from the front of the advancing direction. It is the figure which looked at the assistance robot 1 of the state which raised the holding part in the assistance robot 1 of FIG. 1 from the advancing direction right side. It is the figure which showed the internal structure of the assistance robot 1 of FIG. 1, and looked at the assistance robot 1 from the right side of the advancing direction. It is the figure seen from the left side of the assistance robot 1 of FIG. 6, ie, the figure which looked at the assistance robot 1 from the back in the advancing direction. FIG. 8 is a sectional view taken along the line 8-8 in FIG. It is an enlarged view of the raising / lowering part 40, the holding | maintenance part 50, and the back-and-forth movement actuators 90 and 100 in the upper part of FIG. It is an enlarged view of the detector 110 of the assistance robot 1 of FIG. 1, Comprising: It is a longitudinal cross-sectional view of the left-right direction. It is a block diagram of the control apparatus 120 of the assistance robot 1. FIG. It is the figure which looked at the assistance robot 1 when the person being assisted M1 is in a sitting posture from the right side in the traveling direction. It is the figure which looked at the assistance robot 1 when the care receiver M1 is in the standing posture from the right side in the traveling direction. It is a flowchart which shows the automatic stop process of the calculating part 121 of the control apparatus 120 of FIG. It is a figure which shows the state of the detector 110 when the sensor 131 of the 1st detector 111 is ON. It is a figure which shows the state of the detector 110 after the sensor 131 of the 1st detector 111 turns ON. It is a figure which shows the state of the detector 110 of another aspect when the sensor 131 of the 1st detector 111 turns ON. It is a flowchart which shows the process after the automatic stop of the calculating part 121 of the control apparatus 120 of FIG. It is a flowchart which shows the automatic stop process of the calculating part 121 of the control apparatus 120 of the assistance robot 1 of 2nd embodiment. It is an enlarged view of the detector 210 of the assistance robot 1 of 3rd embodiment, Comprising: It is a longitudinal cross-sectional view of the left-right direction.

<First embodiment>
(1. Overall configuration of assistance robot 1)
The overall configuration of the assistance robot 1 according to the first embodiment will be described with reference to FIGS. The assistance robot 1 supports a part of the body (for example, the upper body) of the person being assisted M1 (shown in FIGS. 12 and 13) to assist the standing operation and the sitting operation. As shown in FIGS. 1 to 5, the assistance robot 1 includes a base 10, elevating arms 20 and 30, an elevating unit 40, a holding unit 50, elevating actuators 70 and 80, longitudinal actuators 90 and 100, a detector 110, A control device 120 is provided. In the following description, front, rear, left and right are front, rear, left and right when the traveling direction of the assisting robot 1 is forward.

The base 10 is a part installed on the ground. As shown in FIG. 2, the base 10 is formed in a U shape that opens rearward in a plan view. The base 10 includes four wheels 15-18 and can move forward and backward.

The elevating arms 20 and 30 are provided on the left and right sides of the upper surface of the base 10 and are provided so as to be extendable upward. As shown in FIGS. 1 and 5, the elevating arms 20 and 30 extend and contract linearly in a direction in which the upper end is inclined forward with respect to the lower end. The elevating unit 40 is provided at the upper ends of the elevating arms 20 and 30. As the elevating arms 20 and 30 expand and contract in the vertical direction, the elevating unit 40 moves up and down with respect to the base 10. That is, as shown in FIGS. 1 and 5, the elevating unit 40 moves linearly in the direction of moving forward as it rises with respect to the base 10.

The holding part 50 is located above the elevating part 40 and is supported by the elevating part 40. The holding unit 50 moves back and forth with respect to the lifting unit 40 and tilts. The holding unit 50 holds a part of the body of the person being assisted M1. The holding | maintenance part 50 is provided with the attachment 60 replaceable according to the care receiver M1.

The attachment 60 includes a main body 61 that can be attached to and detached from a main body frame 51 (described later) of the holding unit 50, a torso pad 62 that supports a torso that is a part of the body of the person being assisted M1, and left and right grips that the person being assisted by Grips 63a and 63b, left and right elbow placement parts 64a and 64b for placing the elbow part of the person being assisted M1, armpit holding parts 65a and 65b for holding both sides of the person to be assisted M1 on the left and right sides of the body bud 62, And the operation part 66 in which raising / lowering operation is performed by the care receiver M1 or a caregiver is provided.

The elevating actuators 70 and 80 drive the elevating operation of the elevating unit 40 with respect to the base 10. Each of the lift actuators 70 and 80 drives expansion / contraction of the corresponding lift arms 20 and 30. That is, by driving the elevating actuators 70 and 80, the elevating unit 40 performs the operation from the state shown in FIG. 1 to the ascending position and the advancing position shown in FIG. 5 and vice versa. The lift actuators 70 and 80 are provided across the base 10 and the lift arms 20 and 30.

The back-and-forth actuators 90 and 100 drive the holding unit 50 to move back and forth and tilt with respect to the elevating unit 40. That is, by driving the longitudinal actuators 90 and 100, the holding unit 50 performs the operation from the state shown in FIG. 1 to the forward position and the forward inclined state shown in FIG. Do. The longitudinal actuators 90 and 100 are provided across the elevating unit 40 and the holding unit 50.

The detector 110 is provided in the holding unit 50 and detects contact or approach of the object by the holding unit 50. Specifically, the detector 110 is provided on the lower surface of the holding unit 50 and detects contact or approach to an object existing below the holding unit 50. In particular, the detector 110 is used for the purpose of detecting whether or not the leg of the person being assisted M1 is in contact with or close to the holding unit 50. The detector 110 is provided only behind the holding unit 50 in the traveling direction and over the entire length in the width direction. The detector 110 includes a first detector 111 disposed at the center, and second and third detectors 112 and 113 disposed on the left and right, respectively. Each of the first, second, and third detectors 111, 112, and 113 detects contact or approach to an object.

The control device 120 controls the elevating actuators 70 and 80 and the forward / backward moving actuators 90 and 100 according to the operation by the person being assisted M1. Furthermore, the control device 120 controls the lift actuators 70 and 80 and the longitudinal actuators 90 and 100 based on the detection result of the detector 110.

(2. Internal structure of assistance robot 1)
As shown in FIGS. 1 to 5, the assistance robot 1 includes a cover 11 of the base 10, covers 25 and 35 of the lifting arms 20 and 30, a cover 45 of the lifting and lowering unit 40, and an attachment 60 of the holding unit 50. . Therefore, the internal structure of the assistance robot 1 from which these are removed will be described with reference to FIGS.

The base 10 includes left and right frames 12 and 13 and a connecting frame 14 that connects the front end portions of the left and right frames 12 and 13. The left and right frames 12 and 13 are arranged at an interval necessary for the care recipient M1 to enter. Left and right rear wheels 15 and 16 are provided at the rear ends of the left and right frames 12 and 13, respectively. Left and right front wheels 17 and 18 are provided at the front end portions of the left and right frames 12 and 13, respectively. The left and right front wheels 17 and 18 turn according to the traveling direction of the assistance robot 1. Here, in the present embodiment, the left and right rear wheels 15 and 16 and the left and right front wheels 17 and 18 are wheels having no driving force, but may be driven by a motor or the like.

The elevating arms 20 and 30 include first arm portions 21 and 31, second arm portions 22 and 32, and third arm portions 23 and 33. The 1st arm parts 21 and 31, the 2nd arm parts 22 and 32, and the 3rd arm parts 23 and 33 are formed in the shape of a straight long. The first arm portions 21 and 31 are fixed to the left and right frames 12 and 13 of the base 10. The first arm portions 21 and 31 are fixed to the base 10 by being tilted forward at a predetermined angle (for example, 80 degrees).

The second arm portions 22 and 32 slide in the longitudinal direction with respect to the first arm portions 21 and 31. When the second arm portions 22 and 32 contract, most of the second arm portions 22 and 32 are accommodated in the first arm portions 21 and 31.
The third arm parts 23 and 33 slide in the longitudinal direction with respect to the second arm parts 22 and 32. The elevating part 40 is fixed to the upper ends of the third arm parts 23 and 33. When the third arm portions 23 and 33 contract, most of the third arm portions 23 and 33 are accommodated in the second arm portions 22 and 32.

Therefore, when the second arm portions 22 and 32 and the third arm portions 23 and 33 contract, most of the third arm portions 23 and 33 are moved to the first arm portions 21 and 31 and the third arm portions 23 and 33 as shown in FIG. The second arm portions 22 and 32 are accommodated. At this time, the raising / lowering part 40 is located in the lowest position. On the other hand, when the second arm portions 22 and 32 and the third arm portions 23 and 33 are extended, the third arm portions 23 and 33 are moved to the first arm portions 21 and 31 as shown in FIGS. It is located in the position away from the 1st arm parts 21 and 31 without overlapping in the up-and-down direction. At this time, the elevating part 40 is located at the uppermost position.

The elevating actuators 70 and 80 include rotational drive sources 71 and 81, first elevating mechanisms 72 and 82, and second elevating mechanisms 73 and 83. The rotational drive sources 71 and 81 include a motor that outputs rotational driving force. As appropriate, the rotational drive sources 71 and 81 may include a speed reduction mechanism.

The first elevating mechanisms 72 and 82 are connected to the rotation drive sources 71 and 81 and are mechanisms for elevating and lowering the second arm portions 22 and 32 with respect to the first arm portions 21 and 31. The first elevating mechanisms 72 and 82 are screw mechanisms. Note that a belt mechanism can be applied to the first elevating mechanisms 72 and 82. The first elevating mechanisms 72 and 82 include screw shafts 72a and 82a that are rotationally driven by rotational drive sources 71 and 81, and nut members 72b and 82b. In the present embodiment, the screw shafts 72 a and 82 a are fixed to the first arm portions 21 and 31, and the nut members 72 b and 82 b are fixed to the second arm portions 22 and 32. That is, when the screw shafts 72a and 82a are rotated by the rotational drive sources 71 and 81, the nut members 72b and 82b are moved up and down. In this way, the second arm portions 22 and 32 are moved up and down with respect to the first arm portions 21 and 31.

The second elevating mechanisms 73 and 83 are mechanisms for elevating and lowering the third arm parts 23 and 33 with respect to the second arm parts 22 and 32. The second elevating mechanisms 73 and 83 are belt mechanisms. Note that a screw mechanism can be applied to the second elevating mechanisms 73 and 83. The second elevating mechanisms 73 and 83 include lower pulleys 73a and 83a and upper pulleys 73b and 83b that are rotatably provided at both ends of the second arm portions 22 and 32 in the longitudinal direction.

Furthermore, the second elevating mechanisms 73 and 83 include belts 73c and 83c suspended from the lower pulleys 73a and 83a and the upper pulleys 73b and 83b. One of the belts 73c and 83c is fixed to the upper end connecting members 21a and 31a of the first arm portions 21 and 31, and the other of the belts 73c and 83c is fixed to the lower end connecting members 23a and 33a of the third arm portions 23 and 33. . That is, when the second arm portions 22 and 32 are lifted with respect to the first arm portions 21 and 31, the belts 73c and 83c are rotated in conjunction with the lifting operation. The third arm parts 23 and 33 are raised with respect to the second arm parts 22 and 32 in conjunction with the rotation operation. The operation of lowering the second arm portions 22 and 32 and the third arm portions 23 and 33 is an operation obtained by reversing the above operation.

As shown in FIG. 9, the elevating part 40 includes a base 41 fixed to the upper ends of the third arm parts 23, 33, a swing support part 42 fixed to the base 41, and a guided member 43. The holding part 50 includes a main body frame 51, a swing support part 52 fixed to the main body frame 51, and an arcuate guide path 53. The guide path 53 holds the guided member 43 so as to be sandwiched from above and below by the guided member 43. That is, the guide path 53 moves the guided member 43 along the guide path 53 in an arc shape. As the guided member 43 moves in an arc along the guide path 53, the main body frame 51 of the holding unit 50 moves back and forth with respect to the elevating unit 40 and tilts.

The back-and- forth actuators 90 and 100 drive the holding unit 50 to move back and forth and tilt with respect to the elevating unit 40. As shown in FIG. 9, the longitudinal actuators 90 and 100 include a supported member 91, a rotation drive source 92, a screw shaft 93, and a nut member 94. The supported member 91 is swingably supported by the swing support portion 52 of the holding portion 50. The rotational drive source 92 is a motor, for example, and is fixed to the supported member 91. The screw shaft 93 is connected to the output shaft of the rotational drive source 92 and is rotationally driven by the rotational drive source 92. The nut member 94 is swingably supported by the swing support portion 42 of the elevating unit 40. The nut member 94 engages with the screw shaft 93 and moves along the screw shaft 93 as the screw shaft 93 rotates.

That is, the rotational drive source 92 rotates the screw shaft 93 by the rotational drive, and further moves the nut member 94 in the front-rear direction as the screw shaft 93 rotates. As the rotational drive source 92 rotates, the distance between the supported member 91 that supports one end of the screw shaft 93 and the nut member 94 changes. At this time, as described above, the guided member 43 moves in an arc shape along the guide path 53, whereby the posture of the holding unit 50 with respect to the lifting unit 40 is determined.

(3. Internal structure of detector 110)
The internal structure of the detector 110 will be described with reference to FIG. The detector 110 includes a first detector 111, a second detector 112, and a third detector 113.
The first detector 111 is arranged at the center in the left-right direction of the traveling direction. The first detector 111 includes a plurality of sensors 131, a guide 132, and a contact moving body 133. The plurality of sensors 131 are provided only on the lower surface of the main body frame 51 (shown in FIG. 9) of the holding unit 50 only behind the holding unit 50 in the traveling direction. The plurality of sensors 131 are arranged at equal intervals in the left-right direction of the traveling direction. The plurality of sensors 131 are contact-type sensors, and detect a pressing load from below. The plurality of sensors 131 may be non-contact sensors.

The guide 132 is provided on both outer sides of the plurality of sensors 131 in the left-right direction, and extends downward from the lower surface of the main body frame 51 of the holding unit 50. The contact moving body 133 is supported by the guide 132 so as to be movable in the vertical direction, and has a wider width than the detection width of the plurality of sensors 131. In particular, the contact moving body 133 is locked against the guide 132 so as not to fall downward. However, the contact moving body 133 is allowed to move upward along the guide 132.

The contact moving body 133 includes a restraining plate 133a and an elastic material 133b. The restraint plate 133a is formed of, for example, metal or resin. In a basic state where no external force is applied, the restraint plate 133a is positioned at a distance from the plurality of sensors 131. However, when the restraint plate 133a receives an external force from below to above, the restraint plate 133a can contact any of the plurality of sensors 131. That is, the restraining plate 133a is a member that contacts the plurality of sensors 131 and applies a pressing load. The elastic material 133b is attached to the lower surface of the restraining plate 133a over the entire length. The elastic material 133b is formed of foamed resin or highly flexible rubber.

The second detector 112 and the third detector 113 differ from the first detector 111 in that the number of sensors 131 is one and the size in the left-right width direction is small. It is comprised substantially the same as the vessel 111. In the drawing, the components of the second detector 112 and the third detector 113 are denoted by the same reference numerals as the components of the first detector 111.

(4. Configuration of control device 120 and operation of assistance robot 1)
The configuration of the control device 120 and the operation of the assistance robot 1 will be described with reference to FIGS. The control device 120 includes a calculation unit 121 such as a CPU and a storage unit 122 such as an HDD or a Flash SSD. Although not shown, the control device 120 includes an interface for communicating with the operation unit 66, the lifting actuators 70 and 80, and the longitudinal actuators 90 and 100 as external devices.

The calculation unit 121 acquires operation information from the operation unit 66 when the operation unit 66 is operated by the person being assisted M1. The operation information is an ascending operation, a descending operation, and a stopping operation for the holding unit 50. Further, the calculation unit 121 acquires the current state information of each actuator 70, 80, 90, 100, for example, the rotation increment value of the motor. Then, the calculation unit 121 determines whether the lift actuators 70 and 80 and the forward / backward movement actuators are based on the acquired operation information, the current state of each actuator 70, 80, 90, 100, and information stored in the storage unit 122. 90 and 100 are synchronously controlled. Here, the storage unit 122 stores the relationship between the operation information, the current state of each actuator 70, 80, 90, 100 and the command value for each actuator 70, 80, 90, 100.

When the person being assisted M1 is in the sitting position, immediately after the person assisted by M1 is held by the body pad 62 of the attachment 60 of the holding part 50, as shown in FIG. 90 and 100 are driven, and the holding part 50 is moved back and forth and tilted. Thereafter, the calculation unit 121 drives the elevating actuators 70 and 80 while driving the longitudinal actuators 90 and 100. That is, as shown in FIG. 13, the holding unit 50 moves up and down while moving back and forth. The rising height of the holding part 50 can be set according to the height of the person being assisted M1. Similarly, when the person being assisted M1 shifts from the standing posture to the sitting posture, the raising / lowering operation by the raising / lowering actuators 70, 80 and the forward / backward movement and tilting by the longitudinal actuators 90, 100 are coordinated. Done.

Further, the arithmetic unit 121 of the control device 120 automatically stops the actuators 70, 80, 90, 100 when the detector 110 detects that an object has contacted or approached the holding unit 50. Specifically, as shown in FIG. 14, the control device 120 determines whether the elevating actuators 70 and 80 are in the process of lowering the holding unit 50 (S <b> 1). If the lifting / lowering actuators 70 and 80 are in the middle of the lowering operation of the holding unit 50 (S1: Yes), the control device 120 determines whether any of the plurality of sensors 131 is turned on by applying a load from the restraint plate 133a. Is determined (S2). In other words, the control device 120 determines whether or not it is detected that any object has contacted or approached the holding unit 50.

Here, a state where the control device 120 detects that an object has contacted or approached the holding unit 50 will be described with reference to FIG. The person being assisted M1 is assumed to be in a sitting posture sitting on a seat (not shown). In this case, the leg part L of the person being assisted M1 exists below the holding part 50. That is, the leg part L of the person being assisted M1 is located between the holding part 50 and the seat part. Furthermore, it is assumed that the person being assisted M1 operates the operation unit 66 of the assistance robot 1 to lower the holding unit 50.

Normally, the person being assisted M1 consciously stops the lowering operation of the holding unit 50 before the detector 110 comes into contact with its leg. However, the person being assisted M1 may temporarily forget to consciously stop the lowering operation of the holding unit 50 and continue the lowering operation unconsciously. In such a case, the leg part L of the person being assisted M1 comes into contact with the elastic member 133b of the first detector 111, for example. Of course, the leg portion L of the person being assisted M1 may contact the elastic member 133b of the second detector 112 or the elastic member 133b of the third detector 113.

When the holding unit 50 further continues to descend, the leg L of the person being assisted M1 is sandwiched between the holding unit 50 and the seat. Then, the leg portion L of the person being assisted M1 moves the elastic member 133b of the first detector 111 together with the restraint plate 133a, and the restraint plate 133a applies a pressing load to any of the plurality of sensors 131. . Then, any of the plurality of sensors 131 detects that any object has contacted or approached the holding unit 50.

Thus, when any of the plurality of sensors 131 is turned on (S2: Yes), the control device 120 automatically stops the lowering operation of the actuators 70 and 80 (S3). Here, since the longitudinal actuators 90 and 100 are synchronized with the lifting actuators 70 and 80, when the lifting actuators 70 and 80 are automatically stopped, the longitudinal actuators 90 and 100 are also automatically stopped. In this way, the control device 120 automatically stops the movement of the holding unit 50 toward the leg L of the person being assisted, so that the leg L of the person being assisted by the holding part 50 and the seat is Further, it is prevented from being pinched with a strong force.

If the lowering operation is not in progress in S1 of the above process (S1: No), the control device 120 performs the return process as it is. That is, when the lifting actuators 70 and 80 are in the middle of raising the holding unit 50, the raising operation of the holding unit 50 by the lifting actuators 70 and 80 is continued. Further, when none of the plurality of sensors 131 is turned on in S2 of the above process (S2: No), the control device 120 performs a return process. That is, unless any of the plurality of sensors 131 is turned on, the control device 120 does not perform the automatic stop process in S3.

Here, a state after the lowering operation of the holding unit 50 is automatically stopped will be described with reference to FIG. As described above, when the plurality of sensors 131 are turned on, the control device 120 automatically stops the lifting / lowering operation of the holding unit 50. At this time, the leg part L of the person being assisted M1 is already sandwiched between the holding part 50 and the seat part. Since the elastic material 133b is provided on the lowermost surface of the detector 110, the elastic material 133b becomes a contact surface with the leg portion L of the person being assisted M1. On the other hand, since the restraining plate 133a is in contact with the sensor 131, the restraining plate 133a cannot move relative to a portion (support surface) where the restraining plate 133a and the elastic material 133b are supported, that is, the lower surface of the main body frame 51 of the holding unit 50.

Since the elastic material 133b is elastically deformable, even if the restraint plate 133a cannot move, the contact surface of the elastic material 133b with the leg L can be moved. That is, as shown in FIG. 16, when the person being assisted M1 moves the leg L upward, the contact surface of the elastic member 133b is deformed into a concave shape. Thus, the contact surface of the elastic member 133b is moved to the main body frame 51 side (support surface side) of the holding unit 50 by the elastic force of the elastic member 133b itself when a load is applied by the leg portion L of the person being assisted M1. Is allowed to move. And the control force with respect to the leg part L by the elastic material 133b becomes small. Although the person being assisted M1 is sandwiched between the legs L, the person M1 has some degree of freedom of movement of the legs L.

In the above, the restraint plate 133a and the elastic member 133b of the first detector 111 are raised in a horizontal state, and any one of the plurality of sensors 131 is turned on. In addition to this, as shown in FIG. 17, for example, when the right leg L of the person being assisted M1 comes into contact with the elastic member 133b of the first detector 111, the restraint plate 133a and the elastic member 133b are inclined. In this state, any one of the plurality of sensors 131 is turned on. In this case, the same operation as described above is performed.

Next, processing of the control device 120 after the descent operation is automatically stopped will be described with reference to FIG. The control apparatus 120 determines whether the raising / lowering operation | movement of the holding | maintenance part 50 is stopping automatically (S11). If the automatic stop is in progress (S11: Yes), the control device 120 determines whether or not the operation unit 66 has been lifted or lowered by the person being assisted M1 or the assistant, in particular whether or not the lowering operation has been performed. Determine (S12).

When the descending operation is performed on the operation unit 66 by the attendant M1 or the assistant (S12: Yes), the control device 120 prohibits the descending operation by the lifting actuators 70 and 80 (S13). . That is, even if the lowering operation is performed by the operation unit 66, the elevating actuators 70 and 80 do not perform the lowering operation of the holding unit 50. Therefore, the holding | maintenance part 50 continues being located as it is in the position which stopped automatically. Then, the control device 120 performs a return process.

When the ascending operation is performed in the operation unit 66 by the person being assisted M1 or the assistant during the automatic stop of the holding unit 50 (S12: No), the control device 120 is controlled by the lifting actuators 70 and 80. The ascending operation is performed (S14). And the control apparatus 120 performs a return process. Even when the automatic stop is not being performed in S11 (S11: No), the control device 120 performs a return process.

As described above, when the elevating actuators 70 and 80 are once automatically stopped, the elevating actuators 70 and 80 are maintained in the stopped state even if the lowering operation is performed by the operation unit 66. If the raising operation is performed by the operation unit 66, thereafter, the holding unit 50 performs the lifting operation by the lifting actuators 70 and 80 in accordance with the lifting operation by the operation unit 66.

<Second embodiment>
The automatic stop process by the calculating part 121 of the control apparatus 120 in the assistance robot 1 of 2nd embodiment is demonstrated with reference to FIG. The calculation unit 121 of the control device 120 determines whether or not the elevating actuators 70 and 80 are performing the lowering operation of the holding unit 50 (S21). If the lowering operation of the holding unit 50 is not in progress (S21: No), the control device 120 performs the return process as it is.

If the elevating actuators 70 and 80 are in the middle of the lowering operation of the holding unit 50 (S21: Yes), the control device 120 determines whether any of the plurality of sensors 131 is turned on by applying a load from the restraint plate 133a. Is determined (S22). Even when none of the plurality of sensors 131 is ON (S22: No), the control device 120 performs a return process.

When any of the plurality of sensors 131 is turned on (S22: Yes), the control device 120 automatically stops the lowering operation of the holding unit 50 by the lifting actuators 70 and 80, and the holding unit 50 by the lifting actuators 70 and 80. Is increased by a predetermined amount (S23). That is, the holding unit 50 moves by a predetermined amount in a direction away from the leg portion L of the person being assisted M1. The predetermined amount may be an amount such that the person being assisted M1 feels that the leg L is not sandwiched. Subsequently, the control device 120 automatically stops the operation of the elevating actuators 70 and 80 (S24). Thus, the holding part 50 is automatically stopped at a position slightly away from the leg part L of the person being assisted M1, so that the leg part L of the person being assisted is sandwiched between the holding part 50 and the seat part. Is prevented.

<Third embodiment>
The detector 210 of the assistance robot 1 of 3rd embodiment is demonstrated with reference to FIG. The detector 210 includes a first detector 211, a second detector 212, and a third detector 213, similarly to the detector 110 of the first embodiment.

Each detector 211, 212, 213 includes a non-contact proximity sensor 231, a guide 232, an elastic body 233, and a contact moving body 234. The guide 232 and the contact moving body 234 are the same as in the first embodiment. The contact moving body 234 includes a restraining plate 234a and an elastic material 234b.

The non-contact proximity sensor 231 is disposed at the same position as the sensor 131 in the first embodiment. However, the non-contact type proximity sensor 231 is provided on the main body frame 51 of the holding unit 50, and is turned on when the distance from the restraining plate 234a constituting the contact moving body 234 becomes a predetermined value or less. That is, after the non-contact proximity sensor 231 is turned on, the restraint plate 234a can be moved to the holding unit 50 side. The elastic body 233 is provided on the outer peripheral side of the guide 232 and urges the restraining plate 234a downward with respect to the main body frame 51 of the holding unit 50. The elastic body 233 is, for example, a coil spring, a disc spring, or rubber.

In the present embodiment, the processing of the control device 120 is the same as in the first embodiment or the second embodiment. However, the detector 210 of this embodiment is different from the above-described embodiment in the following points by including the elastic body 233.

When the operation of the holding unit 50 automatically stops, the non-contact proximity sensor 231 and the restraining plate 234a are separated. Therefore, the restraining plate 234a can move to the main body frame 51 side of the holding unit 50. However, since the elastic body 233 is interposed between the main body frame 51 of the holding unit 50 and the restraint plate 234a, the restraint plate 234a is supported in a state having an elastic force.

That is, in addition to the elastic force of the elastic member 234b, the elastic force of the elastic body 233 acts, so that the contact surface of the elastic member 133b with the leg L can be moved upward. The restriction force on the leg L by the elastic material 234b is further reduced. Although the person being assisted M1 is sandwiched between the legs L, the person being assisted M1 has a sufficient degree of freedom of movement of the legs L.

<Summary>
The assistance robot 1 according to the first, second, and third embodiments includes a base 10, a holding unit 50 that holds a part of the body of the person being assisted M <b> 1, and moves up and down with respect to the base 10, and the base 10. Actuators 70 and 80 for driving the raising and lowering operation of the holding unit 50 with respect to the detector, detectors 110 and 210 provided in the holding unit 50 for detecting contact or approach to an object by the holding unit 50, and the actuators 70 and 80 The controller 120 that stops the movement of the holding unit 50 toward the object by the actuators 70 and 80 when the detectors 110 and 210 detect contact or approach to the object while the unit 50 is moving up and down. With.

When a part of the body of the person being assisted M1 comes into contact with the holding part 50 or approaches the holding part 50, the movement to the object side of the holding part 50 stops, so that the person being assisted M1 is pressed by the holding part 50 Can be prevented. As a result, the person being assisted M1 can be prevented from feeling uncomfortable. In the assistance robot 1 of the first and second embodiments, when the detector 110 is turned on, a part of the body of the person being assisted M1 is not in direct contact with the holding unit 50, but indirectly held. It will be in the state which is contacting the part 50. FIG. That is, in the assistance robot 1 of the first and second embodiments, the detector 110 detects that the holding unit 50 has contacted the leg L of the person being assisted M1. On the other hand, in the assistance robot 1 of the third embodiment, the detector 210 detects that the holding unit 50 has approached the leg L of the person being assisted M1 in a non-contact manner.

In the assistance robot 1 according to the first, second, and third embodiments, the detectors 110 and 210 are provided on the lower surface of the holding unit 50, and contact or approach an object that exists below the holding unit 50. The controller 120 detects and holds the actuators 70 and 80 when the detectors 110 and 210 detect contact or approach to the object while the holding units 50 are being lowered. The descending operation of the unit 50 is stopped. Thereby, it can prevent reliably that the leg part L of the care receiver M1 is pinched by the holding | maintenance part 50. FIG.

Moreover, the assistance robot 1 of 1st, 2nd, 3rd embodiment is provided with the operation part 66 by which the raising / lowering operation of the holding | maintenance part 50 is performed by the person M1 or the assistance person, and the control apparatus 120 is the detector 110, In the state where the lowering operation is stopped by the detection by 210, if the lowering operation is performed at the operation unit 66 by the person being assisted M1 or the assistant, the lowering operation of the holding unit 50 by the actuators 70 and 80 is not performed. When the raising operation is performed in the portion 66, the raising operation of the holding portion 50 by the actuators 70 and 80 is performed. As described above, after the suspension is stopped, only the ascending operation of the holding unit 50 is allowed, so that the person being assisted M1 can be prevented from being pressed by the holding unit 50.

In the assistance robot 1 according to the first, second, and third embodiments, the control device 120 causes the detectors 110 and 210 to move the object to the object while the actuators 70 and 80 are moving up the holding unit 50. Even when the contact or approach is detected, the ascending operation of the holding unit 50 by the actuators 70 and 80 is continued. During the raising operation of the holding unit 50, the leg portion L of the person being assisted M <b> 1 is not sandwiched between the holding units 50. Therefore, even if the detectors 110 and 210 are turned on, the holding unit 50 can be moved to a desired upper position at an early stage by continuing the ascending operation of the holding unit 50.

Moreover, in the assistance robot 1 of 1st, 2nd, 3rd embodiment, the detectors 110 and 210 are the sensors 131 and 231 provided in the holding | maintenance part 50, and the guide provided in the holding | maintenance part 50 and extended in an up-down direction. 132, 232 and guides 132, 232 are movably supported in the vertical direction, have a width wider than the detection width of the sensors 131, 231 and are held by the sensors 131, 231 by contact or approach to the sensors 131, 231. Contact moving bodies 133 and 233 for detecting contact or approach to an object by the unit 50. By the sensors 131 and 231 having a narrow detection width, the detection range of contact or approach to the object by the holding unit 50 can be set wide.

Moreover, in the assistance robot 1 of 1st, 2nd, 3rd embodiment, after detecting the contact or approach to the object by the holding | maintenance part 50, the detectors 110 and 210 move to the holding | maintenance part 50 side by an object. Is acceptable. Even after the leg L of the person being assisted M1 is in contact with the detectors 110 and 210, the person being assisted M1 can move the leg L upward. Therefore, the person being assisted M1 can be prevented from feeling uncomfortable.

Moreover, in the assistance robot 1 of 1st, 2nd, 3rd embodiment, the detectors 110 and 210 give elastic force to the contact surface with an object on the basis of the support surface by the holding | maintenance part 50, and a contact surface is After the detectors 110 and 210 detect the contact or approach of the object by the holding unit 50, the detectors 110 and 210 are allowed to move toward the support surface side by the elastic force. Since the contact surface is given an elastic force to the support surface, the flexibility for the person being assisted M1 is improved.

Further, in the assistance robot 1 of the first embodiment, when the detector 110 detects contact or approach to an object, the control device 120 does not move the holding unit 50 up and down by the actuators 70 and 80. The raising / lowering operation of the holding part 50 by 70 and 80 is stopped. That is, the holding unit 50 stops immediately. For the person being assisted M1, the operation of the holding unit 50 becomes very easy to understand.

In the assistance robot 1 of the second embodiment, the control device 120 moves the holding unit 50 away from the object by the actuators 70 and 80 when the detectors 110 and 210 detect contact or approach to the object. After the movement, the lifting and lowering operation of the holding unit 50 by the actuators 70 and 80 is stopped. When the person being assisted M1 contacts or approaches the holding unit 50, the person being assisted M1 has the degree of freedom of movement of the leg L.

Further, in the assistance robot 1 of the first, second, and third embodiments, the detectors 110 and 210 are provided only in the rearward direction of the holding unit 50 and over the entire length in the width direction. While minimizing the number of sensors 131 and 231, uncomfortable feeling when the leg portion L of the person being assisted M1 is pinched is reliably suppressed.

In the above embodiment, the lifting and lowering of the holding unit 50 is performed by the lifting actuators 70 and 80 that move linearly in the vertical direction. In addition to this, although different from the configuration of the above embodiment, if the lifting arms 20 and 30 swing with respect to the base 10, the lifting arms 20 and 30 swing and hold. The part 50 will move up and down. That is, the raising and lowering of the holding unit 50 is performed by the swinging actuator. And the automatic stop process by the control apparatus 120 in the said embodiment and the process after an automatic stop are applicable also in the said structure. That is, when the holding unit 50 is lowered due to the swinging of the lifting arms 20 and 30, the swinging of the lifting arms 20 and 30 is detected when the detectors 110 and 210 detect contact or approach to the object by the holding unit 50. Will automatically stop.

1: assistance robot, 10: base, 20, 30: lifting arm, 40: lifting part, 50: holding part, 51: body frame, 60: attachment, 70, 80: lifting actuator, 90, 100: longitudinal actuator 110, 210: detector, 111, 211: first detector, 112, 212: second detector, 113, 213: third detector, 120: control device, 131, 231: sensor, 132, 232: Guide, 133, 234: contact moving body, 133a, 234a: restraint plate, 133b, 234b: elastic material, 233: elastic body, L: leg (object), M1: caregiver

Claims (10)

1. The base,
   A holding unit that holds a part of the body of the person being assisted and moves up and down with respect to the base;
   An actuator for driving up and down movement of the holding unit with respect to the base;
   A detector provided in the holding unit for detecting contact or approach to an object by the holding unit;
   Control that stops the movement of the holding unit to the object side by the actuator when the detector detects contact or approach to the object while the actuator is moving up and down the holding unit Equipment,
   An assisting robot.
2. The detector is provided on a lower surface of the holding unit, detects contact or approach to the object existing below the holding unit,
   The control device stops the lowering operation of the holding unit by the actuator when the detector detects contact or approach to the object while the actuator is performing the lowering operation of the holding unit. The assistance robot according to claim 1.
3. The control device raises the holding portion by the actuator even when the detector detects contact or approach to the object while the actuator is raising the holding portion. The assistance robot according to claim 2 which continues.
4. The assisting robot includes an operation unit in which the lifting / lowering operation of the holding unit is performed by the person being assisted or an assistant,
   In the state where the lowering operation is stopped by the detection by the detector, the control device is configured such that when the lowering operation is performed on the operation unit by the person being assisted or the assistant, 4. The assistance robot according to claim 2, wherein when the raising operation is performed by the operation unit without performing the lowering operation, the raising operation of the holding unit by the actuator is performed.
5. The detector is
   A sensor provided in the holding unit;
   A guide provided in the holding portion and extending in the vertical direction;
   The guide is supported so as to be movable in the vertical direction, has a lateral width wider than the detection width of the sensor, and detects contact or approach of the object by the holding unit by the sensor by contact or approach of the sensor. A contact moving body;
   The assistance robot according to any one of claims 1 to 4, further comprising:
6. The assisting robot according to any one of claims 1 to 5, wherein the detector allows the object to move toward the holding unit after detecting contact or approach of the object with the holding unit. .
7. The detector gives an elastic force to the contact surface with the object on the basis of the support surface by the holding unit,
   The assistance robot according to claim 6, wherein the contact surface is allowed to move toward the support surface by the elastic force after the detector detects contact or approach of the object by the holding unit.
8. The said control apparatus stops the raising / lowering operation | movement of the said holding part by the said actuator, without raising / lowering the said holding part by the said actuator, when the contact or approach to the said object is detected by the said detector. The assistance robot according to any one of 1-7.
9. The controller, when detecting contact or approach to the object by the detector, moves the holding unit in a direction away from the object by the actuator, and then moves the holding unit up and down by the actuator. The assistance robot according to any one of claims 1 to 7, which stops.
10. The assisting robot according to any one of claims 1 to 9, wherein the detector is provided only behind the holding unit in the traveling direction and over the entire length in the width direction.

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