JP5206393B2 - Transfer support device and control method of transfer support device - Google Patents

Description

  The present invention relates to a transfer support device and a control method for the transfer support device. For example, the present invention relates to a transfer support device that supports a transfer operation when a person who has difficulty in walking independently moves from a bed to a wheelchair or moves from a wheelchair to a toilet seat or the like, and a control method thereof.

  It is not easy for a cared person who is difficult to walk independently to perform a transfer operation such as moving from a bed to a wheelchair alone. Usually, caregiver's help is required, but the help of the transfer operation has a great physical burden for the caregiver and also a great mental burden for the care recipient. In recent years, a device for supporting a transfer operation of a person who has difficulty walking independently has been developed.

For example, Patent Document 1 discloses a transfer support apparatus in which a support column is tiltably erected on a turntable and a receiving plate (holding tool) is provided at the end of the support column. When a care receiver performs a transfer operation using the transfer support apparatus, first, the support plate is tilted to bring the receiving plate toward the care receiver's body. Then, the cared person gets on the holding tool or clings to hold the body on the receiving plate so that the weight can be deposited. When the column is raised in this state, the cared person's body is lifted. After moving to the transfer destination, tilting the support post completes the transfer operation.
JP 2006-305092 JP

However, the cared person's body shape varies from person to person, and further, the cared person often has a unique disease.
In such a case, if the receiving plate is moved in the same orbit to all the care recipients, the care recipient is stressed and distressed, and in the worst case, the life threatens. An accident may occur.

A series of processes for transferring a cared person will be described.
First, the receiving plate is moved to a position and an angle at which the cared person can hold, and the cared person is grasped by this. Then, the arm is turned up so as to lift the cared person. Then, the cared person's body is lifted.
Here, most of the weight is applied to the receiving plate, and excessive stress is applied to the chest that is in contact with the receiving plate during the transfer operation.
This is fine as long as there is no disease in the chest, but it is extremely dangerous to compress the chest of a cared person who has a chest disease or who has a cardiac pacemaker implanted.

Here, when operating the transfer assist device, it is also conceivable that the care recipient or the caregiver operates while manually adjusting the trajectory of the receiving plate and the arm.
However, there are several times a day when the toilet seat is moved several times a day, and there is often no room to finely adjust the trajectory of the backing plate and arm in a scene where a quick transfer operation is required. . It is unavoidable that accidents that impact the affected area will occur if there are too many scenes to be operated in a hurry.

  An object of the present invention is to provide a transfer support apparatus and a control method thereof that can support a transfer operation quickly and safely.

The transfer support apparatus of the present invention is
A transfer support device that supports a transfer operation of a care recipient,
A movable carriage section;
An arm part capable of horizontal rotation and tilting and having a base end attached to the carriage part;
A body holder attached to the tip of the arm part and provided so as to be tiltable so that the angle formed with respect to the vertical direction can be changed ;
A plurality of drive means for driving the carriage unit and the arm unit;
An input device for inputting personal data for each care recipient;
A control unit for driving and controlling the driving means,
The body holder has a chest support portion that contacts the cared person's chest and supports the cared person's torso during transfer support,
The controller is
A personal data storage unit for storing personal data for each care recipient input by the input device;
A safe trajectory control unit that controls the driving means so that the trajectory of the arm unit and the body holding tool during transfer support is within a safe trajectory that can ensure the safety of the care recipient based on the personal data. ,
The personal data of the care recipient includes information on the disease site and its symptoms,
The safe trajectory controller is
In providing transfer support for caregivers with diseases in the abdomen or chest,
First, lower the tip of the arm so that the cared person can be held by the body holder,
Next, when the tip of the arm part is raised to lift the cared person, control is performed so that the angle formed by the surface of the chest support part contacting the cared person with respect to the vertical direction does not exceed a predetermined limit. However , the carriage unit is advanced .

  According to such a configuration, control is automatically performed in a trajectory that can ensure the safety of the cared person in the entire series of transfer operations. Each cared person has a different body type, disease symptoms, etc., but based on the input personal data of the cared person, a safe trajectory is obtained for each cared person, and individual responses can be made. In this way, the trajectory of the arm unit and body supporter is automatically controlled within the safe trajectory, so that caregivers and other operators can smoothly support caregiver movement without any special fine adjustments. can do. Since fine adjustment or the like is not necessary, the transfer operation can be performed quickly and safely even when rushing to a toilet or the like.

Here, to control the trajectory of the arm part and the body holding tool so as to be within a safe trajectory means that an operation lever operation error occurs when a caregiver or the like is operating the transfer assist device using the operation lever. If the track of the arm unit and the holder deviates from the safe track, etc., the safe track control unit will stop the operation of the transfer support device, or the arm unit and the track of the holder will automatically fit in the safe track. It is possible to modify the operation.
Or you may drive an arm part and a holder automatically along the safe track | orbit which the safe track | truck control part calculated | required.

In the present invention, the personal data of the caregiver, disease site and the information of the symptoms and Nde free, safe trajectory is determined so as to reduce as much as possible the external force applied to the disease site.
For example, a safe trajectory is required so as not to compress the affected area and to reduce the pain caused by bending and stretching.

In the present invention, it is preferable that the personal data of the cared person includes information related to the body shape of the cared person.
In such a configuration, based on the cared person's body shape data, the body holding tool can be prevented from colliding with the cared person's body, or the body holding tool can be at an angle along the cared person's body. A safe orbit is required.

In the present invention, the personal data of the cared person includes information on past operation data when the transfer support device has been used in the past, and the past operation data feels a part and a fear of pain during a transfer operation. It is preferable to include information on other factors.
In such a configuration, when a pain has occurred in the past, a safe trajectory is set so as to reduce the pain. In addition, when fear of operation speed or operation sound occurs, a limit is set for the operation speed or the like.

In the present invention, the input device preferably includes a display panel that displays input items, and a keyboard or touch panel sensor that inputs personal data for each input item.
According to such a configuration, the cared person, the caregiver, the doctor, or the like can input the personal data of the cared person into the transfer support apparatus using the input device.

In the present invention, the personal data is stored in an IC tag, barcode or mobile phone carried by a care recipient, and the input device can read information on the IC tag, barcode or mobile phone. preferable.
In such a configuration, before providing care support, the input device of the transfer support device reads information such as an IC tag, a barcode, and a mobile phone, and executes safety control according to personal data.
According to such a configuration, it is not necessary to input personal data of the care recipient every time care support is provided, so that quick care support can be performed.

DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of the present invention will be illustrated and described with reference to reference numerals attached to respective elements in the drawings.
A first embodiment according to the present invention will be described.
FIG. 1 is a side view of a transfer support apparatus according to the first embodiment of the present invention.
The transfer support apparatus 10 includes a carriage unit 1, a robot arm unit 2 connected to the carriage unit 1, and a holder 3 attached to the robot arm unit 2.

The carriage unit 1 is attached to the rear side of the carriage body 11, the handle part 12 for pushing and moving the carriage part 1, the pair of left and right front auxiliary wheels 13 attached to the front side of the carriage body 11, and the carriage body 11. The pair of left and right rear auxiliary wheels 14 and a pair of left and right drive wheels 15 that are attached to a substantially central portion of the carriage main body 11 and drive the carriage part 1 are provided.
A pair of left and right sixth motors 16 for driving each drive wheel 15 are connected to the pair of left and right drive wheels 15, respectively.

The robot arm unit 2 is an articulated arm, and includes a first arm unit 21, a second arm unit 22, and a third arm unit 23.
The first arm portion 21 is connected to the base portion 11a of the carriage main body 11 via the first joint portion 51 so as to be able to rotate around the yaw axis and the pitch axis.
The second arm portion 22 is connected to the first arm portion 21 via the second joint portion 52 so as to be able to rotate around the pitch axis.
One end of the third arm portion 23 is connected to the second arm portion 22 via the third joint portion so as to be rotatable around the pitch axis. (In Fig. 1, the third joint is not shown because it is not visible on the back of the third arm)
An attachment portion 24 for attaching the holder 3 is connected to the other end of the third arm portion 23 via a fourth joint portion so that rotation around the roll axis is possible. (In Figure 1, the fourth joint is not shown because it is built in the third arm and cannot be seen.)
The attachment portion 24 has a well-known attachment structure (for example, a fastening structure using a bolt and a nut, a fitting structure) in which the holder 3 can be attached / detached.

Here, the yaw axis is a rotation axis of the first arm unit 21 and is a vertical axis.
The pitch axis is a rotation axis when the first arm portion 21, the second arm portion 22, and the third arm portion 23 are rotated in the vertical direction.
The roll axis is a rotation axis when the attachment portion 24 and the holder 3 are rotated with respect to the third arm portion 23, and corresponds to the axis of the third arm portion 23.

The base portion 11a of the carriage body 11 is provided with a first motor (driving means) 61 that rotationally drives the first arm portion 21 around the yaw axis.
The first joint portion 51 is provided with a second motor (drive means) 62 that rotationally drives the first arm portion 21 around the pitch axis.
The second joint portion 52 is provided with a third motor (driving means) 63 that rotationally drives the second arm portion 22 around the pitch axis.
The third joint portion is provided with a fourth motor (driving means) 64 that rotationally drives the third arm portion 23 around the pitch axis.
The fourth joint portion is provided with a fifth motor (driving means) 65 that rotationally drives the attachment portion 24 and the holder 3 around the roll axis.

The first to sixth motors 61, 62, 63, 64, 65 are connected to the control unit 17 via the drive circuit 18 and are driven to rotate by a control signal from the control unit 17. Further, in the base portion 11a and each joint portion (51, 52), rotation sensors 71, 72, 73, such as potentiometers for detecting the rotational drive amount of the first to fifth motors 61, 62, 63, 64, 65, 74 and 75 are provided, respectively.
The rotation sensors 71, 72, 73, 74, 75 are connected to the control unit 17 and output the detected rotational drive amount to the control unit 17.

FIG. 2 is a perspective view of the holder.
The holder 3 is attached to the attachment part 24 of the robot arm part 2.
The holder 3 includes a torso support portion 31 that holds the to-be-cared person's torso and a lower-limb support portion 32 that supports the lower-limb part of the to-be-cared person.

The lower limb support part 32 is formed in a substantially inverted T shape and is connected to the lower part of the trunk support part 31.
The torso support portion 31 and the lower limb support portion 32 are integrally formed, but may be formed separately.

  The torso support portion 31 includes a chest support portion 31a that contacts the chest of the care recipient, a pair of side support portions 31b that support the side surfaces of the chest, and a head support portion 31c that supports the jaws of the head. ing.

  The pair of side surface support portions 31b are formed so as to face each other, and extend from both side edges of the chest support portion 31a in a substantially vertical direction. The head support portion 31c is formed in a convex shape on the upper portion of the chest support portion 31a. Note that the chest support part 31a, the side support part 31b, and the head support part 31c are integrally formed, but may be formed separately.

FIG. 3 is a block diagram showing a system configuration of the transfer support apparatus.
The carriage unit 1 is provided with a control unit 17 that controls the rotational drive of the first to sixth motors 61, 62, 63, 64, 65, and 16.
The control unit 17 includes a CPU (Central Processing Unit) 17a that performs control processing, arithmetic processing, and the like, a ROM (Read Only Memory) 17b that stores control programs, arithmetic programs, and the like executed by the CPU 17a, processing data, and the like Is composed mainly of a microcomputer having a RAM (Random Access Memory) 17c, and further includes a personal data storage unit 130 and a safe trajectory control unit 120.

The attachment part 24 of the robot arm part 2 is provided with an operation part 25 for a caregiver to operate the transfer support device 10, and the operation part 25 is connected to the attachment part 24 of the robot arm part 2 via a force sensor 25c. It is connected.
The force sensor 25c detects an operation according to the magnitude, direction, moment, etc. of the operation force applied to the operation unit 25 and outputs an operation signal to the control unit 17.

An input device 110 for inputting personal data of the care recipient is connected to the control unit 17.
An example of the input device 110 is an input support system that includes a keyboard, a mouse, and a display panel. This display panel may be a touch panel. In addition to a keyboard and a mouse, a digital pen may be used as the input device 110.

FIGS. 4 to 6 are diagrams for explaining examples of personal data of a care receiver input using the input device 110. FIG.
FIG. 4 is an example of an input screen.
The data to be input includes (A) body type, (B) special matters such as disease, and (C) past operation data as personal data under the individual name and gender.
Items relating to body type (A) include weight and detailed size items.
The subordinate items of the detailed size items are (1) papillary chest thickness, (2) abdominal thickness, (3) sitting armpit height, (4) sitting thigh thickness, (5) knee height, (6) trochanter High, (7) Anterior axillary height.
The corresponding part of each item is as shown in FIG.
As an input method, input may be accepted by clicking and selecting each item, etc., and the size of each part is selected by selecting on the image showing the body as shown in FIG. 5 with a touch pen etc. You may enter.

  It should be noted that the detailed size items are not limited to those exemplified above, and may be appropriately set as necessary.

As a special note (B) such as a disease, a disease or a disorder possessed by each part of the body is input.
FIG. 6 is a diagram illustrating an example of subordinate items of a special note such as a disease.
There are body parts such as the chest, abdomen, waist, and legs as sub-items of special items such as diseases, and symptoms are input for each part.
For example, in the case of the waist, it is possible to input detailed symptoms such as pain when pressed, pain when bent, and pain when stretched.
These input methods may be selected and checked from preset items, and the diseased part and symptom can be input by selecting on the image showing the body as shown in FIG. 5 with a touch pen or the like. It may be like this.

  In addition, as past operation data (C), information such as the part that felt pain or pressure when using the transfer support device in the past, the presence or absence of fear of motion speed or motion sound, etc. are accepted .

  The personal data input by the input device 110 is stored in the personal data storage unit 130 for each care recipient.

Based on the data input to the personal data storage unit 130, the safe trajectory control unit 120 obtains a safe trajectory for the care recipient who supports the transfer, and within the safe trajectory in which the arm unit 2 and the holder 3 are allowed. The sixth motors 61 to 65 are controlled from the first motor to operate.
The control operation by the safe trajectory control unit 120 will be described later using a specific example.

(Operation example 1)
FIG. 7 shows an operation example 1.
The operation example 1 is an operation example when there is a disease in at least one of the chest and abdomen of the care recipient and it is necessary to avoid pressure on the diseased part.
First, FIG. 7A shows a case where a transfer support operation is performed regardless of personal data.
In FIG. 7A, first, the tip of the arm portion 2 is lowered so that the care recipient is held by the holder 3. The cared person is held by the holder 3 that came in front of the chest. Then, the arm portion 2 is rotated upward so that the care receiver is placed on the holder 3. Although the cared person's body can be lifted by this, since the entire weight is applied to the cared person's chest and abdomen, great pressure is applied to the chest and abdomen.

Next, FIG. 7B shows a case where the trajectory of the arm unit 2 and the holder 3 is controlled within the safe trajectory when personal data indicating that there is a disease in at least one of the chest and abdomen is input. Is the action.
Input of personal data is performed by the input device 110, and personal data of the care recipient is stored in the personal data storage unit 130.
This personal data input method is similar to the method described in FIG. 6, and in this operation example 1, information such as “painful when pressed” or “dangerous when pressed” is input to the chest or abdomen. It shall be.
Based on such personal data, the safe trajectory control unit 120 obtains a safe trajectory for the cared person and executes drive control of the arm unit 2 and the holder 3.
Here, the limit is set to the angle formed by the holder 3 with respect to the vertical direction so that the angle of the holder 3 does not become too large. This prevents the holder 3 from compressing the chest or abdomen.

That is, as shown in FIG. 7 (B), first, the tip of the arm portion 2 is lowered so that the cared person is held by the holder 3, so that the cared person is held by the holder 3. Then, the arm part 2 is raised so as to lift the cared person, but the angle of the holder 3 is prevented from becoming too large in the process of raising the arm part 2.
Specifically, while observing the detection value of the rotation angle by the rotation sensor 75, the fourth arm (drive means) 64 that drives the third arm portion 23 to rotate around the pitch axis is driven, and the angle of the holder 3 is a safe trajectory. To fit within.
Note that if the holder 3 is simply rotated so that the angle of the holder 3 does not increase, the holder 3 rotates in the direction of pushing the chest, and therefore the carriage 1 of the transfer assist device 10 is advanced.
This prevents the holder 3 from pressing the cared person's chest.

In this way, when assisting a cared person having a disease in the chest or abdomen, the angle of the holder 10 is prevented from becoming too large in the entire process of the transfer operation.
This prevents large pressure from being applied to the diseased part (chest or abdomen) of the care recipient during the transfer operation.
Since the transfer support device 10 automatically operates so as to avoid pressure on the cared person by the safety control of the safe trajectory control unit 120, the cared person does not need to make special fine adjustments. Can be smoothly supported. Since fine adjustment or the like is not necessary, the transfer operation can be performed quickly and safely even when rushing to a toilet or the like.

(Operation example 2)
FIG. 8 shows an operation example 2.
The operation example 2 is an operation example when there is a disease in the arm and lower back of the care recipient and it is necessary to avoid stress on the diseased part.
First, FIG. 8A shows a case where a transfer support operation is performed regardless of personal data.
In FIG. 8 (A), first, the tip of the arm part 2 is lowered so that the cared person is held by the holder 3. The cared person is held by the holder 3 that came in front of the chest. Then, the arm part 2 is rotated so as to lift the cared person, and the vertical position of the holder 3 is maintained so that the cared person can be held by the holder.
Thus, the cared person's body can be lifted, but the cared person must support most of his / her own weight with his / her arm in the process of the transfer operation, and a large pressure is applied to the arm.
In addition, since only the upper body is lifted, the lumbar region is stretched. If the cared person has a disease that hurts when the waist is stretched, the cared person is in pain.

Next, FIG. 8 (B) is an operation when the trajectory of the arm unit 2 and the holder 3 is controlled within the safe trajectory when personal data indicating that there is a disease in the arm and lower back is input. .
Input of personal data is performed by the input device 110, and personal data of the care recipient is stored in the personal data storage unit 130.
This personal data input method is similar to the method described in FIG. 6, and in this operation example 2, the information that "It hurts when pressed" is input to the arm, and "It hurts when stretched" to the waist. Is input.
Based on such personal data, the safe trajectory control unit 120 obtains a safe trajectory for the cared person and executes drive control of the arm unit 2 and the holder 3.
Here, the holding tool maintains an angle of a certain level or more with respect to the vertical line so that a load is not applied to the arm part and the waist part does not extend.

That is, as shown in FIG. 8 (B), first, the tip of the arm part 2 is lowered so that the cared person is held by the holder 3, and the holder 3 is substantially vertical in front of the cared person's chest. To be. Then, the arm part 2 is rotated upward so as to lift the cared person, but in the process of raising the arm part 2, the angle of the holder 3 is set to a certain angle or more with respect to the vertical line.
Specifically, while observing the detection value of the rotation angle by the rotation sensor 75, the fourth motor (drive means) 64 that drives the third arm portion 23 to rotate about the pitch axis is driven, and the angle of the holder is within the safe trajectory. To fit in. Then, the cared person's body comes to rest on the holder 3, and no great force is applied to the arm part, and the waist part can be kept bent.

(Operation example 3)
FIG. 9 shows operation example 3.
The operation example 3 is an operation example when there is a disease in the lower part of the cared person and it is necessary to avoid stress on the diseased part.
First, FIG. 9A shows a case where a transfer support operation is performed regardless of personal data.
In FIG. 9 (A), first, the tip of the arm part 2 is lowered so that the cared person is held by the holder 3.
The cared person is held by the holder 3 that came in front of the chest. Then, the arm portion 2 is rotated upward so that the care receiver is placed on the holder 3. As a result, the cared person's body can be placed on the holder 3 and lifted, but the cared person's waist is bent greatly. If the cared person has a disease that hurts when the waist is bent, the cared person is in pain.

Next, FIG. 9 (B) is an operation when the trajectory of the arm unit 2 and the holder 3 is controlled within the safe trajectory when personal data indicating that there is a disease in the arm and lower back is input. .
Input of personal data is performed by the input device 110, and personal data of the care recipient is stored in the personal data storage unit 130.
This personal data input method is similar to the method described with reference to FIG. 6, and in this operation example 2, it is assumed that the information “It hurts when bent” is input to the waist.
Based on such personal data, the safe trajectory control unit 120 obtains a safe trajectory for the cared person and executes drive control of the arm unit 2 and the holder 3.
Here, the holder 3 is kept at an angle within a predetermined value with respect to the vertical line so that the waist does not bend too much.

That is, as shown in FIG. 9 (B), first, the tip of the arm part 2 is lowered so that the cared person can be held by the holder so that the holder comes in front of the breast of the cared person. Then, the arm part 2 is raised so as to lift the cared person, but the angle of the holder 3 is prevented from becoming too large in the process of raising the arm part 2.
Specifically, while observing the detection value of the rotation angle by the rotation sensor 75, the fourth arm (drive means) 64 that drives the third arm portion 23 to rotate around the pitch axis is driven, and the angle of the holder 3 is a safe trajectory. To fit within. Then, since the waist of the cared person can be kept stretched without bending, the cared person can smoothly perform the transfer operation without feeling pain.

(Operation example 4)
FIG. 10 shows an operation example 4.
The operation example 4 is an operation example when there is a disease in the leg of the care recipient and it is necessary to avoid stress on the diseased part.
First, FIG. 10A shows a case where a transfer support operation is performed regardless of personal data.
In FIG. 10A, first, the tip of the arm portion 2 is lowered so that the care recipient is held by the holder 3.
The cared person is held by the holder 3 that came in front of the chest. Then, the arm portion 2 is rotated upward so that the care receiver is placed on the holder 3. As a result, the cared person's body can be placed on the holder 3 and lifted. However, when moving the holder 3 in front of the cared person's chest, if the holder 3 is lowered too much due to an operational error, etc., the holder will come into contact with the cared person's leg part, or the leg part will be strengthened. There is a danger of pressing.

Next, FIG. 10B shows an operation when the trajectories of the arm unit 2 and the holder 3 are controlled within the safe trajectory when personal data indicating that there is a disease in the leg is input.
Input of personal data is performed by the input device 110, and personal data of the care recipient is stored in the personal data storage unit 130.
This personal data input method is similar to the method described with reference to FIG. 6, and in this operation example 4, it is assumed that information that “pauses when pressed” is input to the leg.
Based on such personal data, the safe trajectory control unit 120 obtains a safe trajectory for the cared person and executes drive control of the arm unit 2 and the holder 3.
Here, the holder is not lowered too much in front of the care recipient so that the holder does not fall too much in front of the care recipient and does not press the leg.

That is, as shown in FIG. 10 (B), first, the tip of the arm is lowered so that the cared person is held by the holder 3, so that the holder 3 comes in front of the breast of the cared person.
At this time, the lower limit positions of the arm part 2 and the holding tool 3 are limited so that the holding tool 3 does not fall too much.
Specifically, while observing the detected value of the rotation angle by the rotation sensor 74, the third motor (driving means) 63 that drives the second arm portion 22 to rotate about the pitch axis is driven, and the lower end of the holder 3 is the safety track. To fit within.
As a result, it is possible to prevent the care receiver's leg from being squeezed accidentally by the holder 3 when the care receiver is placed on the holder 3. Then, the arm part 2 is raised so as to lift the cared person to support the transfer operation of the cared person.

Note that the safe trajectory of the operation example 4 may be set so that the lower limit position of the holder 3 is always above a predetermined height.
However, in some cases, it is preferable that the holder 3 is sufficiently lowered so that it can be easily lowered when the user moves onto the holder 3 and then gets off to the next destination.
Therefore, it is preferable that the lower limit position of the holder 3 as a safety track is set so that the lower limit is activated only when the holder 3 is moved in front of the cared person's chest when the holder 3 is transferred.
In this way, a smooth transfer operation can be performed while ensuring safety in the process of a series of transfer operations.

(Operation example 5)
FIG. 11 shows an operation example 5.
The operation example 5 is an operation example in the case where the nipple position chest thickness diameter and the abdominal thickness diameter of the care recipient are significantly different.
First, FIG. 11A shows a case where a transfer support operation is performed regardless of personal data.
In FIG. 11 (A), first, the tip of the arm is lowered so that the cared person can be held by the holder.
At this time, if the holder is brought in front of the cared person's chest so as to match the position of the chest, the holder collides with the cared person's abdomen, which is dangerous.
Also, if the holder is brought in front of the cared person so as to match the position of the abdomen, the gap between the holder and the chest is excessively open, and it is difficult for the cared person to be caught by the holder.

Next, FIG. 11 (B) shows the operation when the trajectory of the arm unit 2 and the holder 3 is controlled within the safe trajectory when personal data regarding the nipple position chest thickness and abdominal thickness is input. is there.
Input of personal data is performed by the input device 110, and personal data of the care recipient is stored in the personal data storage unit 130.
This personal data input method is a method similar to the method described in FIG. 6, and in this operation example 5, as the body type item (A), the nipple position chest thickness diameter (1) and the abdominal thickness diameter (2) The detailed size including and is entered.
Based on such personal data, the safe trajectory control unit 120 obtains a safe trajectory for the cared person and executes drive control of the arm unit 2 and the holder 3.
Here, it is made for the holder 3 not to contact the abdomen while approaching the chest in front of the cared person's chest.
Specifically, as shown in FIG. 11 (B), the angle of the holder 3 is inclined from the vertical so as to extend from the chest to the abdomen.
As a result, the cared person can safely grasp the holder without feeling a pressure on the abdomen.

(Operation example 6)
FIG. 12 shows an operation example 6.
The operation example 6 is an operation example when the care receiver's thigh is at a position higher than the average.
First, FIG. 12A shows a case where a transfer support operation is performed regardless of personal data.
In FIG. 10 (A), first, the tip of the arm is lowered so that the cared person can be held by the holder.
The cared person is caught in the holder that came in front of the chest. At this time, if the holder is moved in front of the chest as is normally done, the holder will collide with the thigh.

Next, FIG. 12 (B) shows an operation when the trajectory of the arm unit 2 and the holder 3 is controlled within the safe trajectory when personal data regarding the sitting thigh thickness is input.
Input of personal data is performed by the input device 110, and personal data of the care recipient is stored in the personal data storage unit 130.
This personal data input method is similar to the method described in FIG. 6, and in this operation example 6, a detailed size including the sitting thigh thickness (4) is input as the body type item (A). ing.
Based on such personal data, the safe trajectory control unit 120 obtains a safe trajectory for the cared person and executes drive control of the arm unit 2 and the holder 3.
Here, based on the seated thigh thickness, the holder is prevented from falling too low in front of the cared person's chest so that the holder does not contact the thigh. This prevents the holder from damaging the foot by colliding with the cared person's thigh.

  Note that the operation example 6 can also be applied when the height of the cared person is high and the leg length, specifically, the knee height (5) is longer than the average. That is, based on the knee height, the holder is prevented from falling too low in front of the cared person's chest, and the holder is prevented from coming into contact with the legs.

(Operation example 7)
FIG. 13 shows an operation example 7.
The operation example 7 is an operation example in the case where the height of the holder 3 is adjusted to the height of the care receiver's sitting axilla so that the care receiver can be safely held by the holder.
When the tip of the arm is lowered so that the cared person can be held by the holder 3, if the height of the holder 3 does not match the body of the cared person, it is held for the cared person who originally needs transfer support. It is difficult to move to ingredient 3, and there is a risk of an accident. Therefore, since the detailed size including the sitting position axillary height is input as the body type item (A), the safety trajectory control unit 120 has the upper end of the holder 3 being cared for when the holder 3 is approached to the cared person. Adjust to fit the person's axilla height. Thereby, the cared person can be securely held by the holder without any difficulty.

(Operation example 8)
FIG. 14 shows an operation example 8.
The operation example 8 is an operation example in the case of transferring while ensuring safety in accordance with the cared person's body shape.
When a care recipient is safely transferred to a transfer support device, it is important to prevent the care recipient from wobbling or falling back.
At this time, if the cared person's body is placed on the holder after the cared person's center of gravity is moved onto the cared person's foot, a stable transfer operation is achieved.

Detailed data including knee height, trochanter height, and axillary height are input as body data items of personal data.
The safe trajectory control unit 120 creates a link model of the care recipient based on the knee height, trochanter height, and axillary height data.
The link model has a structure in which links of knees, thighs, and torso are connected by ankles, knees, and waist joints.
Using this model, the center of gravity of the cared person is obtained, and a safe trajectory for supporting the body of the cared person is obtained so that the center of gravity trajectory becomes a stable trajectory.
A specific example of the safety trajectory is as follows. First, the center of gravity of the cared person is moved in the direction of the foot while pulling the cared person's body forward and downward. Then, when the center of gravity comes on the foot, the cared person's body is lifted and placed on the holder.
The safe trajectory control unit 120 calculates the safe trajectory as described above, and controls the angle of the holder and the drive of the arm so as to enter the safe trajectory.
As a result, the care recipient can be safely transferred and the load acting on the knee extension muscles can be reduced.

(Operation example 9)
The operation example 9 includes safe trajectory control based on the weight of the care recipient.
When the cared person's weight is heavy, if the contact area between the holder and the cared person is small, there is a problem that a large pressure is generated in a narrow range and the cared person's body is strongly pressed. Therefore, when the cared person's weight is large, for example, the angle of the holder is controlled in a range along the cared person's body based on the nipple position chest thickness diameter and the abdominal thickness diameter.
As a result, the body pressure of the cared person can be dispersed so that the cared person's body is not strongly compressed.

(Operation example 10)
As an operation example 10, control based on operation data can be cited.
Input of personal data is performed by the input device 110, and personal data of the care recipient is stored in the personal data storage unit.
The personal data input method is similar to the method described with reference to FIG. 6. In this operation example 10, pain and fear felt in the past are registered as past operation data.
When pain occurs in a certain part, as described in the above operation example, a safe trajectory corresponding to the part where pain occurs is obtained, and drive control of the arm and the holding tool is executed.

Moreover, when there is a fear in the past operation data, the following measures are taken as an example.
That is, when the operation speed is too high and there is a feeling of fear or when the operation sound is feared, a limit is set on the maximum rotation speed and the maximum rotation acceleration of the arm drive.
If you feel a sense of fear that the position of the holder will rise too high during a series of transfer support operations, set a height limit within the range where care work is possible.
In the case of a fear of the tilt angle of the holder being too large or too small during a series of transfer support operations, a limit is set to the angle of the holder within a range where care work is possible.

(Modification 1)
In the above description, the case where the input of the personal data is performed through the input device has been described. However, as a means for registering the personal data in the transfer support device 10, the following modification is given as an example.
An IC tag (RFID: Radio frequency identification) or barcode that records personal data of the cared person is attached to the name tag or bracelet of the cared person.
Alternatively, personal data of the care recipient may be stored in a mobile phone or a PDA (personal digital assistant). Then, a transmission / reception function is provided in the input device of the transfer support device so that transmission / reception with the IC tag is possible.
Alternatively, a bar code reader is provided as an input device for the transfer support device.
In such a configuration, before providing care support, the input device of the transfer support device reads information such as an IC tag, a barcode, and a mobile phone, and executes safety control according to personal data.
According to such a configuration, since it is not necessary to input personal data of the care recipient every time care support is provided, quick care can be performed.

  It goes without saying that personal data of a plurality of care recipients may be registered in the personal data storage unit 130 of the transfer support device 10 and information on the care recipients may be read out during a care operation.

  Further, the personal data may be data on a safe trajectory for each cared person obtained by another computer or the like, not the body shape or the disease.

  In addition, this invention is not limited to the said embodiment, The deformation | transformation in the range which can achieve the objective of this invention, improvement, etc. are included in this invention.

The side view of a transfer assistance apparatus. It is a perspective view of a holder. The block diagram which shows the system configuration | structure of a transfer assistance apparatus. The figure which shows the example of the input screen of personal data. The figure for demonstrating the site | part of a body type item. The figure which shows the example of the low-order item of special mention matters, such as a disease. The figure which shows the operation example 1. The figure which shows the operation example 2. The figure which shows the operation example 3. The figure which shows the operation example 4. The figure which shows the operation example 5. The figure which shows the operation example 6. The figure which shows the operation example 7. The figure which shows the operation example 8.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Carriage part, 2 ... Robot arm part, 3 ... Holder, 10 ... Transfer support device, 11 ... Carriage body, 11a ... Base part, 12 ... Handle part, 13 ... Front auxiliary wheel, 14 ... Back auxiliary wheel, 15 ... driving wheel, 16 ... sixth motor, 17 ... control unit, 18 ... drive circuit, 21 ... first arm unit, 22 ... second arm unit, 23 ... third arm unit, 24 ... mounting unit, 25 ... operation unit , 25c ... Force sensor, 25 ... Operation part, 31 ... Torso support part, 31a ... Chest support part, 31b ... Side support part, 31c ... Head support part, 32 ... Lower limb support part, 61 ~ 65 ... Motor, 71 ~ 79 ... Rotation sensor, 110 ... Input device, 120 ... Safe trajectory control unit, 130 ... Personal data storage unit.

Claims (5)

A transfer support device that supports a transfer operation of a care recipient,
A movable carriage section;
An arm part capable of horizontal rotation and tilting and having a base end attached to the carriage part;
A body holder attached to the tip of the arm part and provided so as to be tiltable so that the angle formed with respect to the vertical direction can be changed ;
A plurality of drive means for driving the carriage unit and the arm unit;
An input device for inputting personal data for each care recipient;
A control unit for driving and controlling the driving means,
The body holder has a chest support portion that contacts the cared person's chest and supports the cared person's torso during transfer support,
The controller is
A personal data storage unit for storing personal data for each care recipient input by the input device;
A safe trajectory control unit that controls the driving means so that the trajectory of the arm unit and the body holding tool during transfer support is within a safe trajectory that can ensure the safety of the care recipient based on the personal data. ,
The personal data of the care recipient includes information on the disease site and its symptoms,
The safe trajectory controller is
In providing transfer support for caregivers with diseases in the abdomen or chest,
First, lower the tip of the arm so that the cared person can be held by the body holder,
Next, when the tip of the arm part is raised to lift the cared person, control is performed so that the angle formed by the surface of the chest support part contacting the cared person with respect to the vertical direction does not exceed a predetermined limit. While moving the cart part forward
A transfer support apparatus characterized by that. In the transfer assistance apparatus of Claim 1,
The transfer support apparatus characterized in that the personal data of the cared person includes information on the body shape of the cared person. In the transfer assistance apparatus of Claim 1 or Claim 2 ,
The personal data of the care recipient includes information on past operation data when using the transfer support device in the past,
The past operation data includes information on a part that felt pain and a factor that felt fear during a transfer operation. In the transfer assistance apparatus in any one of Claims 1-3 ,
The input device is:
A transfer support apparatus comprising: a display panel that displays input items; and a keyboard or touch panel sensor that inputs personal data for each input item. In the transfer assistance apparatus in any one of Claims 1-4 ,
The personal data is stored in an IC tag, barcode or mobile phone carried by the care recipient,
The transfer support device, wherein the input device reads information of the IC tag, barcode or mobile phone.

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