JP3701582B2 - Exo Skeleton Device, Exo Skeleton Cyborg Device, and Exo Skeleton Cyborg System - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an exo skeleton device (exoskeleton device), an exo skeleton cyborg (organic human body with exoskeleton) device and an exo skeleton cyborg system, and in particular, an arm, hand, leg, foot, neck, head, etc. The present invention relates to an exo skeleton device, an exo skeleton cyborg device, and an exo skeleton cyborg system that substitute or assist kinematic and biological body functions for human skeletons and joints. Generally, the skeleton includes an endoskeleton (endo skeleton) and an exoskeleton (exo skeleton, exotic skeleton) such as oyster shells, shrimp and crab cuticles and claws. The exoskeleton in the present embodiment includes a part having each internal skeleton of a human body such as an arm, a leg, and a head or a part having each internal skeleton that simulates a human body such as a prosthetic hand and a prosthetic leg. And operate in conjunction with each other. The configuration including these end skeletons and exo skeletons is referred to herein as an exo skeleton cyborg device. The term cyborg is used to refer to an exoskeleton device on which organisms (human beings) are attached.
[0002]
The present invention is applicable to public works such as heavy labor work, construction work, dangerous work such as maintenance in nuclear power plants, industrial fields that require work in poor environments, rehabilitation, remote work, medical welfare field, disaster relief, etc. .
[0003]
[Prior art]
In recent years, a number of private companies provide care services to care for people whose physical abilities have declined due to various causes such as accidents, aging, and illness. This care service is performed by, for example, a caregiver, but care for an elderly person who has difficulty walking is very hard work.
Further, a predetermined action is performed by remote control while the person is at the current location. So-called tele-distance technology and telemotion technology are being studied.
[0004]
[Problems to be solved by the invention]
However, for people whose physical ability has declined due to various causes such as accidents, old age, and illness, for example, standing up from the bed, moving the floor for excretion or bathing, moving around the stairs etc., moving cars, etc. It is difficult to fully carry out the transfer to the company, the manual work after moving to the company, etc., and it is assumed that a power assist that compensates for this lowered or lost physical ability is required. In the present specification, movement refers to acting in the same coordinate system, transfer refers to shifting to another coordinate system, and transfer refers to turning to a new coordinate system.
[0005]
Conventionally, a smooth and efficient method for transmitting a human movement to a remote human model has not been sufficiently developed.
In view of the above points, the present invention is able to substitute kinematic and biological body functions for hands, feet, etc., and is applicable to a comprehensive welfare robot and the like. The object is to provide a skeleton cyborg and its system. Another object of the present invention is to smoothly and efficiently transmit human movements to a similar remote robot. Another object of the present invention is to enable each part to perform operations such as boost, high speed, and precision. Furthermore, the present invention provides power assistance for standing up from the bed, moving the floor for excretion and bathing, moving around the space for avoiding stairs, etc., transferring to automobiles, etc., and manual work after moving to the company. The purpose is to do.
[0006]
[Means for Solving the Problems]
According to the first solution of the present invention,
An exoskeleton device having an exoskeleton structure for enclosing a portion having an endoskeleton,
A first turning pair that moves around the transverse bending axis at the exoskeleton joint position;
A second turning pair that moves about a longitudinal bending axis at an exoskeleton joint position orthogonal to the first turning pair;
A third counter-even moving around the endoskeleton axis;
A sliding pair having an elastic function in a sliding direction with respect to the movement by the first or second turning pair;
A frame on which the first to third turning pairs and the sliding pair are disposed;
A holding part for holding the frame in a portion having an internal skeleton;
A coupling portion for coupling to an adjacent frame;
A holding drive unit that adjusts the mounting of the holding unit to a site having an endoskeleton;
First to third driving units that respectively rotate and drive the first to third turning pairs;
First to third displacement sensors for detecting a rotation angle of the first to third turning pairs, and first to third forces for detecting lateral bending, vertical bending, and twisting direction of the endoskeleton axis with respect to the frame. A third force sensor;
The angle signal of each pair is input from the first to third displacement sensors, the force signal of each direction is input from the first to third force sensors, and a predetermined target value is set according to the angle signal and the force signal. A processing unit for outputting a driving signal for driving the first to third driving units and the holding driving unit;
There is provided an exoskeleton device comprising:
[0007]
According to the second solution of the present invention,
A plurality of the exo skeleton devices are arranged corresponding to the shoulder, elbow and wrist, respectively, and the plurality of exo skeleton devices are connected by a coupling means, and a portion including an endoskeleton corresponding to the arm portion is provided. An exo-skeleton cyborg device for holding arms to be worn,
A central processing unit for controlling the processing unit of each exo skeleton device,
By the central processing unit,
The first exoskeleton device of the shoulder has at least three turning pairs and two sliding pairs,
The second exoskeleton device of the elbow has at least one turning pair and one sliding pair,
The third exoskeleton device of the forearm has at least one turning pair functioning,
In the wrist, the fourth exoskeleton device has state detection and drive control for each of the left and right arms with at least 7 degrees of freedom so that at least two turning pairs and one sliding pair can function.
An exo skeleton cyborg device is provided.
[0008]
According to the third solution of the present invention,
A plurality of the exo skeleton devices are arranged corresponding to the joint portions of the thumb part and each of the other finger parts, and the plurality of exo skeleton devices are connected by a coupling means, and an endoskeleton corresponding to a hand part is formed. An exoskeleton cyborg device for hand-holding for a part to be included,
A back holding part for holding the exoskeleton device of the hand part;
A central processing unit for controlling the processing unit of each exo skeleton unit;
With the central processing unit,
At least three exo skeleton devices on the thumb of the hand have at least five turning pairs and two sliding pairs,
At least three exoskeleton devices on each other finger of the hand function to function at least four swivel pairs and three slip pairs, respectively,
State detection and drive control of left and right hand parts with at least 21 degrees of freedom
An exoskeleton cyborg device for holding a hand is provided.
[0009]
According to the fourth solution of the present invention,
A portion including a plurality of the exo skeleton devices corresponding to the hip joint portion, the leg portion, and the foot portion, the plurality of exo skeleton devices being connected by a coupling means, and including an endoskeleton corresponding to the leg foot portion. Is an exoskeleton cyborg device for holding legs and feet for wearing,
A central processing unit for controlling the processing unit of each exo skeleton device,
With the central processing unit,
The first exoskeleton device of the hip joint functions at least three turning pairs and two sliding pairs,
The second exoskeleton device of the knee functions at least one turning pair and one sliding pair,
The third exoskeleton device of the lower leg functions as at least one swivel pair,
The fourth exoskeleton device of the foot is characterized in that state detection and drive control of the left and right leg feet are performed with at least 7 degrees of freedom so that at least two swivel pairs and one sliding pair are functioning. An exoskeleton cyborg device for holding the leg and foot is provided.
[0010]
According to the fifth solution of the present invention,
The exo skeleton device,
An arm-hand holding device for attaching a part including an endoskeleton corresponding to the arm-hand portion, each of the left and right arms having a link of at least 7 degrees of freedom and a hand portion of at least 21 degrees of freedom;
A leg-foot holding device for attaching a part including an internal skeleton corresponding to a leg-foot part, wherein the left and right leg-foot parts have links of at least seven degrees of freedom;
As a head holding device for mounting a part including an internal skeleton corresponding to the head of the neck including a link having at least 3 degrees of freedom in the neck and at least 4 degrees of freedom in the lower jaw,
Configure at least one for each of 77 links,
An endoskeleton corresponding to a body part for holding the crotch movable frame, the side movable frame, the shoulder movable frame, and each holding device, and holding the arm-hand holding device, the leg foot holding device, and the head and head holding device. A body holding device for wearing a part including,
A support for connecting the arm-hand holding device, the leg-foot holding device, and the head-and-head holding device to the body holding device, respectively;
A central processing unit for inputting angle signals and force signals from the arm-hand holding device, the leg-and-foot holding device, and the head-and-head holding device, and driving each of the holding devices;
An exo-skeleton cyborg device comprising:
[0011]
According to the sixth solution of the present invention,
First and second exoskeleton cyborg devices as described above;
The angle signal detected by the displacement sensor of the first exoskeleton cyborg device and the force signal detected by the force sensor are converted into predetermined vector quantized data and output, and the transmitted vector quantized data And first and second communication interfaces for transmitting and receiving signals to and from the respective central processing units of the first and second exoskeleton cyborg devices,
A communication line connecting the first and second communication interfaces;
With
Vector quantized data representing the operation or position of the first exo skeleton cyborg device is transmitted to the second exo skeleton cyborg device, and the second exo skeleton cyborg device transmits the transmitted vector quantum. An exo skeleton cyborg system is provided, wherein the exo skeleton cyborg system receives the control data and executes operation or position control corresponding to the operation or position of the first exo skeleton cyborg device.
[0012]
The exoskeleton cyborg of the present invention is, for example, as a power assist by pose control of skeletal body functions, for example, the entire body skeleton (torso, arms, hands, legs, feet, neck, head, etc.); ) And part of the skeletal body function can be subjected to power assist by pose control.
The exoskeleton cyborg of the present invention is, for example, an exoskeleton communication human function control system, and includes a body holding device, excretion processing device, modular exoskeleton power assist device (up to about 77 degrees of freedom exoskeleton). Type manipulator), flexible wire drive device with driver (wire drive motor), opposed two-wheel oscillating four-axis independent suspension omnidirectional mobile trolley, lifting retractable hoist, three-point support six-degree-of-freedom transfer wheelchair, An aerial track carriage (cable car) or a communication control device (computer, communication device) can be provided as necessary.
[0013]
As one of the features of the present invention, for example, the holding and driving of the modular type exoskeleton type power assist device includes a pair of pairs around the skeleton central axis, a pair of pairs around two axes orthogonal to the exoskeleton position, and a spring. The exoskeleton device with a maximum of 3 degrees of freedom obtained by the combination of a sliding pair connected by a force-variable spring can be easily attached to and detached from a portion having a skeleton (inner skeleton) that requires driving. It is driven by a flexible wire motor drive device with a driver. However, it is also possible to drive directly with a drive device without using a flexible wire.
[0014]
Another feature of the present invention is that, for example, when the arm, hand, leg, foot, neck, head, etc. are damaged as an alternative to kinematic body function, the entire artificial body (torso, arm, hand, leg) , Feet, neck, head, etc .; up to about 77 degrees of freedom) and parts thereof can be substituted for kinematic body functions using artificial organs including artificial skeletons, exoskeletons and soft materials.
[0015]
As another feature of the present invention, for example, an artificial arm, hand, leg, foot or the like can be attached to the body holding device as the exoskeleton device. As for the complicated operation data for the exoskeleton device, the pose data of the exoskeleton is stored in advance, and computer control (pause) with control signals such as finger (joystick, push button), myoelectric potential, voice, eye contact, etc. By driving as an agent, an exoskeleton cyborg can be constructed.
[0016]
As another feature of the present invention, for example, a torso of a person who lies on a bed is held by a body holding device using an exo skeleton device, and further, an opposed two-wheel swinging four-axis independent suspension omnidirectional mobile carriage is provided. By lifting up with a lifting retractable hoist, it is possible to easily move the toilet to the toilet seat position and perform walking training. In addition, by mounting a modular exo-skeleton power assist device on the arms, hands, legs, feet, neck, and head, a power assist function is provided for manual operations such as grabbing objects and writing characters. be able to.
[0017]
As another feature of the present invention, for example, a pose of a person wearing a body holding device can be transferred to a car or a bath tub by operating a three-point support 6-degree-of-freedom transfer wheelchair, A person wearing the body holding device can be moved by an aerial track carriage (cable car). Furthermore, for complex motion data, the pose data of the exo skeleton device is stored in advance and restored using control signals such as finger (joystick, push button), myoelectric potential, voice, eye contact, etc. Power assist is performed by agent).
[0018]
As another feature of the present invention, for example, as an alternative to biological body function, various artificial body organs (anus, bladder, etc.) are held in the body holding device, and the biological body function is substituted. Can do. In this case, for example, for excrement disposal, an artificial excretory device that guides or treats excrement directly or indirectly from the bladder or rectum is attached to the crotch supporter of the body holding device. This artificial excretory device includes a urine absorbing material portion and a stool adhering material portion. Using a soft tube from the bladder, rectum, genitals, or anus, the excrement is guided to the excreta. In addition, the excrement is discarded to the outside if a certain amount is accumulated in the excretory device.
[0019]
As another feature of the present invention, for example, for transmission / preservation / enlargement / reduction of body motion, a human body, an exoskeleton device, and an artificial body substantially similar to the human body are connected to each other by a communication device. The transmission, storage, enlargement, and reduction of operations can be performed.
[0020]
For example, a detector such as a potentiometer is attached to all or a part of about 77 degrees of freedom of the exoskeleton device along the entire human body, and the data is collected by a computer or the like. By transmitting to the exoskeleton device along the artificial body and driving the exoskeleton device with a flexible wire motor drive device with a driver, the body motion can be transmitted, stored, enlarged, reduced, etc. it can. However, it is also possible to drive directly with a drive device without using a flexible wire.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a schematic configuration diagram of an exoskeleton device.
The exoskeleton (exoskeleton) device 100 is, for example, a module type exoskeleton, and includes a rotating pair 1 to 3, a sliding pair 4, a force sensor 5-1 to 3, a displacement sensor 6-1 to 3, and a driving device. 7-1 to 3, holding unit driving device 8-1, holding unit 8-2, module coupling unit 9, end skeleton (endoskeleton) unit 10, joints 12 and 14, frames 15 and 16, interface (I / F) 20, a processing device 30 and an input unit 40. In addition, the bearings required for each driving unit are omitted as appropriate. The exo skeleton device 100 is used, for example, by connecting the end skeleton unit 10 as a usage pattern.
[0022]
A turning pair 1 is a turning pair around a horizontal bending axis. The turning pair 2 is a turning pair around the longitudinal bending axis. Turning pair 3 is a turning pair around the skeleton axis. Moreover, these turning pairs 1-3 are driven using a worm gear etc., for example. The sliding pair 4 is a sliding pair that also functions as an auxiliary drive device, and is auxiliary driven by, for example, a spring, a gear, hydraulic pressure, air pressure, or the like. The force sensors 5-1 to 5 are, for example, strain sensors. The displacement sensors 6-1 to 6-3 appropriately include, for example, a potentiometer, an encoder, a visual sensor, and the like. The driving devices 7-1 to 3 include, for example, a flexible wire, a motor, a driver, and the like as appropriate. The holding unit driving device 8-1 drives the holding unit 8-2 around its drive shaft, and appropriately includes, for example, a flexible wire, a motor, a driver, and the like. The holding unit 8-2 holds the exoskeleton device 100 in the end skeleton unit 10. The module coupling unit 9 is for coupling the frames 16 of other adjacent exoskeleton devices. The frames 15 and 16 are for connecting the even-number holding devices and the like to form an exoskeleton.
[0023]
The end skeleton unit 10 is a skeleton included in the exoskeleton device 100, and corresponds to each part such as a human arm and a leg, for example. End skeleton part 10 is a part having each internal skeleton of the human body, a part having each internal skeleton simulating the human body, or a part having the internal skeleton of the human body in part and the internal skeleton simulating the human body in the other part Etc. Further, the end skeleton portion 10 is connected with three degrees of freedom by, for example, a pair 3 around the central axis of the end skeleton portion 10, a pair 1 around the horizontal bending axis, and a pair 2 around the vertical bending axis. Is done. Further, the joint 12 is a joint with 0 to 1 degree of freedom, and is a pair of turns around the end skeleton 10 axis. The joint 14 is a joint having 1 to 2 degrees of freedom, and is a pair that couples the end skeleton part 10 by a pair of pairs around a horizontal bending axis and a pair of turns around a vertical bending axis.
[0024]
The interface (I / F) 20 includes a sensor information input unit and an amplification unit that tune input data and output data, and is connected to a sensor, an amplifier, a bridge, a driver, a motor, a flexible wire, and the like. The interface (I / F) 20 detects data from the force sensors 5-1 to 3 and the displacement sensors 6-1 to 3 and transmits the data to the processing device 30, while driving according to instructions from the processing device 30. The devices 7-1 to 3 and the holding unit driving device 8-1 are driven. The processing device 30 includes a vector quantized data input / output device and executes various processes. The input unit 40 inputs a predetermined target value and the like for the measurement values and the like by the displacement sensors 6-1 to 3 and the force sensors 5-1 to 3.
[0025]
FIG. 2 is a flowchart of the modular exoskeleton device according to the present invention. Here, as an example, a case where power assist is performed by a module-type exoskeleton device will be described. Here, the module type exo skeleton device performs power assist for moving to the target value for the end skeleton unit 10 by determining the target value with the displacement sensor including the visual sensor.
[0026]
When the exo skeleton device is applied to a module type exo skeleton type power assist device, the module type exo skeleton type power assist device can be held and driven by, A skeleton with a maximum of 3 degrees of freedom, made up of a combination of a rotating pair 1 and 2 around two axes orthogonal to each other at the skeletal position and a sliding pair 4 connected by a spring with a variable spring force, to the skeleton required to be driven It is held as detachable and is driven by a flexible wire motor drive device with a driver. However, it is also possible to drive directly with a drive device without using a flexible wire.
[0027]
First, in the module type exoskeleton device, for example, a predetermined target value is input to the sensor values of the displacement sensors 6-1 to -3 by a user or the like (S101). Note that an allowable value such as the maximum value or the minimum value of the force sensors 5-1 to 3 may be input in advance, and power assist may be performed within the range. The module-type exoskeleton apparatus is configured to include the force sensor 5 and the displacement sensor 5 generated by the movement of the actual end skeleton unit 10 (for example, an arm, a leg, etc.) by the human body or the like with respect to the target value input in step S101. The value is measured (S103). Next, in the module type exoskeleton device, the measurement value is input to the processing device 30 via the interface (I / F) 20. The processing device 30 calculates the control amounts of the drive devices 7-1 to 3 and the holding unit drive device 8-1 (S105), and the control amount calculated in step S105 by the amplification unit of the interface (I / F) 20 Amplification processing is performed to a predetermined value corresponding to (S107).
[0028]
Next, the module type exoskeleton device outputs the control amount amplified in step S107 to the driving devices 7-1 to 3-3 and the holding unit driving device 8-1 (S109). The module type exoskeleton device measures the amount driven by the drive devices 7-1 to 3 in step S109 by the displacement sensors 6-1 to 3 and force sensors 5-1 to 3, and in advance in step S101. It compares with the set target value (S111). The module type exoskeleton apparatus determines whether or not the difference between the measured values of the displacement sensors 6-1 to 3 and force sensors 5-1 to 3 measured in step S111 and the target value is within an allowable range ( S113). If the difference between the measured value and the target value is outside the allowable range, the process returns to step S103 again. On the other hand, if the difference between the measured value and the target value is within the allowable range, the module-type exoskeleton device has the above-described power assists of the predetermined pairs 1-3, the sliding pair 4, the holding unit driving device 8- It is determined whether or not it has been executed for 1 etc., and if it has been executed for a predetermined portion, the power assist process is terminated (S115). Note that the module type exoskeleton device returns to step S101 again when the power assist process is not completed for the predetermined part in step S115, and each of the displacement sensors 6-1 to 3 or the force sensor 5 again. Target values for -1 to 3 are input and set by a user or the like.
[0029]
FIG. 3 is a schematic configuration diagram of the endoskeleton link mechanism of the exoskeleton cyborg device. It should be noted that the arm from the shoulder to the fingertip, and the leg leg from the crotch to the toe.
The end skeleton unit 10 includes, for example, 57 links (LINKs) based on the body. The degree of freedom of the end skeleton 10 is, for example, a total of 77 of the left arm 7 + left hand 21, right arm 7 + right hand 21, left foot 7, right foot 7, neck 3 + mandible 4. The left arm hand end skeleton 210 includes, for example, LINKs 11 to 31. The skeleton 220 of the right arm hand includes, for example, LINKs 32 to 52. The right leg foot end skeleton 230 includes, for example, LINKs 6 to 10. Further, the left leg foot end skeleton 210 includes, for example, LINK1 to LINK5. The head end skeleton 250 includes LINKs 53 and 54, for example. The lower jaw end skeleton 260 includes, for example, LINK55-57. Corresponding to each such link, an exoskeleton device is provided. Each exo skeleton device is coupled by a coupling means such as an appropriate frame.
[0030]
FIG. 4 shows a configuration diagram of a holding device for an exoskeleton type seven-degree-of-freedom arm. In this figure, an exo-skeleton cyborg device for holding an arm for mounting a portion including an endoskeleton corresponding to the arm portion is shown. The exo-skeleton device as described above includes a shoulder portion, an elbow portion, and an elbow skeleton device. A plurality of exoskeleton devices are arranged corresponding to the degrees of freedom of the wrist, and the plurality of exoskeleton devices are connected by a coupling means. The arm has 3 degrees of freedom on the shoulder (1), (2), (3), 1 degree of freedom on the elbow (4), 1 degree of freedom on the forearm (5), and 2 degrees of freedom on the wrist (6) There are 7 pairs of swivel pairs, 2 (8) (9) on the shoulder, 1 (10) on the elbow, and 1 (11) on the wrist. Exoskeletons are deployed on the shoulder, upper arm, forearm, and back of the hand. Since the arm is an exoskeleton, the slip pair corresponds to the change in the inter-link distance due to the bending of the human arm. If this is included, the degree of freedom becomes 11 degrees, but in actual mounting, the mechanism becomes 7 degrees of freedom.
[0031]
With a central processing unit for controlling the processing unit of each exo skeleton unit, the first exo skeleton unit of the shoulder functions at least three swivel pairs and two sliding pairs, and a second elbow skeleton unit. The exo skeleton device functions at least two turning pairs and one sliding pair, and the third exo skeleton device on the forearm functions at least one turning pair and the fourth exo skeleton on the wrist. The device is state-detected and drive-controlled with at least 7 degrees of freedom for each of the left and right arms so that at least one swivel pair and one slip pair function.
[0032]
FIG. 5 shows a configuration diagram of a holding device for an exoskeleton type 21-degree-of-freedom hand. In the hand, an exoskeleton is provided at each finger joint using the back part as a support member.
In this figure, an exoskeleton cyborg device for holding a hand for mounting a part including an endoskeleton corresponding to the hand part is shown, and the exoskeleton apparatus as described above includes a thumb part and each other part. A plurality of finger joints are arranged corresponding to the joint portions, and the exoskeleton devices are connected by a coupling means.
[0033]
This exo skeleton cyborg device includes a back holding portion for holding the exo skeleton device in a hand portion, and a central processing portion for controlling a processing portion of each exo skeleton device. By means of the central processing unit, at least three exo skeleton devices of the thumb part of the hand function at least five turning pairs and two sliding pairs, and at least three exo skeleton devices of each other finger of the hand Each of the left and right hands is controlled in state detection and drive control with at least 21 degrees of freedom so that at least four turning pairs and three sliding pairs can function.
[0034]
FIG. 6 is a configuration diagram of a body holding device serving as a base of an exoskeleton cyborg.
The body holding device 300 is a base of the body when the exo skeleton cyborg is combined. For example, the crotch movable frame 305, the side movable frame 310, the base frame 320, the lock mechanism 330, the head movable frame 340, and a lifting tool. An open / close handle (yoke) 350, a shoulder movable frame 360, and a left leg uniting device 370, a right leg uniting device 372, a left arm hand uniting device 374, a right arm hand uniting device 376, and a head uniting device 378 are provided. Here, the uniting means a state in which a body is mounted in a space formed in the body holding device 300. The crotch movable frame 305 corresponds to the position of the crotch in the body, and is a movable frame for assisting crotch driving. The side movable frame 310 corresponds to a side position in the body, and is a movable frame for assisting side driving. The head movable frame 340 corresponds to the position of the head in the body and is a movable frame for assisting in driving the head. The shoulder movable frame 360 corresponds to the position of the shoulder in the body, and is a movable frame for assisting in driving the shoulder. In addition, the suspension / opening / closing handle (yoke) 350 may be formed by changing the crotch movable frame 305, the side movable frame 310, the shoulder movable frame 360, and the head movable frame 340 from an open state to a closed state. These movable frames can be mounted and locked by the lock mechanism 330 so that the above-mentioned members are fixed.
[0035]
The left leg foot uniting device 370, the right leg foot uniting device 372, the left arm hand uniting device 374, the right arm hand uniting device 376, and the head uniting unit 378 are respectively the body holding device 300, the left leg foot, the right leg foot, and the left arm. It is for uniting the hand, the right arm hand, and the head holding device. Each of the plurality of members described above corresponds to a body part. Note that an excretion processing device may be provided in the crotch movable frame 505 of the body holding device 300.
[0036]
FIG. 7 is a schematic configuration diagram of the exoskeleton cyborg device 500.
An exo skeleton cyborg device 500 simulating a human includes, for example, a body holding device 300, a uniting device 510-1 to 5, an interface (I / F) 20-1 to 5, a processing unit 30-1 to 5, and a hand holding Devices (left and right) 520, 530, leg and foot holding devices 540, 550, head holding device 560, and central device (vector quantized data input / output device) 795. The central processing unit 795 includes a command unit that can be activated in the same manner as a human being using a visual sensor or the like. Each holding device includes an end skeleton corresponding to an arm, a leg, a neck, or the like.
[0037]
Further, the exoskeleton cyborg device 500 is activated by combining the leg support devices 540 and 550 with the body support device 300 and pressing the input unit (operation console) of the central device 795. The holding devices 520 and 530 and the head holding device 560 are combined to operate.
[0038]
FIG. 8 is a schematic configuration diagram of a three-point support type coalescing device.
The three-point support type uniting device 600 connects the body holding device 300, the head and head holding device 560, the arm-and-hand holding devices 520 and 530, and the leg holding devices 540 and 550, and supports them. The three-point support type uniting device 600 is supported at three points, and includes, for example, a uniting bearing 610, a presser 620, a fixing shaft 630, and a hitting unit 640. The union bearing 610 is disposed on the female side of the three-point support union device 600, and a presser 620 is placed on the end of the union bearing 610. (Refer to the female unit side in the figure) The fixing shaft 630 is, for example, arranged on the male side of the three-point support type uniting device 600 and is formed by cutting half of both sides of the cylindrical rod. The tool 640 is arranged on the male side of the support uniting device 600 (see the uniting device male side in the figure). At the time of coalescence, the hitting tool 640 is attached to the side surface of the coalescence bearing 610, and the pressing tool 620 is attached to the end of the coalescence bearing 610 via the fixing shaft 630 (see the time of coalescence in the figure). Further, as shown in the figure, the support uniting device 600 includes a gap for changing the three-point support.
[0039]
FIG. 9 is a schematic configuration diagram of a hoist device that is a cockpit and storage device of the exoskeleton cyborg device.
The hoist device (cockpit and storage device) 400 is, for example, a lifting retractable hoist with an omnidirectional moving carriage that lifts and unites the body holding device 300 to become a cockpit, and an operation control unit for operating and controlling the hoist device 490. The hoist device 400 is for storing, for example, the body holding device 300, the arm-and-hand holding devices 520 and 530, the leg and foot holding devices 540 and 550, and the head and head holding device 560. A frame 420, motor drive devices 430 and 440, an exoskeleton storage device 450, a hoist arm 460, and a ball screw 470 are provided.
[0040]
Here, operation | movement of the body holding apparatus 300 and the hoist apparatus 400 is demonstrated roughly.
When the exo skeleton cyborg device is not used, the hoist device 400 includes the body, right arm hand, left arm hand, right leg foot, left leg foot, and neck head exo skeleton device (holding device) and processing device (vector quantization). In the case of using the data input / output device), on the other hand, each exo skeleton device is coupled to the body holding device 300 holding the trunk, and the connector of the processing device is also coupled to complete the combination. . Specifically, in the body holding device 300, the right arm hand, the left arm hand, the right leg foot, the left leg foot, and the head of the neck skeleton device (holding device) are united with each uniting device 370-374.
[0041]
The hoist device 400 is, for example, a state in which the body holding device 300 that holds the trunk and the hoist arm 460 are combined, and the hoist arm 460 is lifted and lowered at the input unit (operation console) provided in the processing device. By operating the position / posture angle of the direction moving carriage 410 and the command units for rotation and the like provided in the body holding device 300, the user can stand up from the body bed, go to the body bed, for example. Can be supine. In addition, when used by a healthy person, the body holding device 300 that holds the torso can be easily attached and detached even in a basic state.
[0042]
As described above, according to the hoist device 400, the hoist arm 460 and the body holding device 300 for holding the trunk are united, and the hoist arm 460 is lifted and lowered by the console of the operation processing unit 490. In the sequence of pressing the position / posture angle of the direction moving carriage 410 and the rotation command of the body holding device 300, the hoist arm 460 can be put on the hoist arm 460, and the body holding device 300 can be mounted.
[0043]
Here, the operation principle of the hoisting and retracting hoist arm 460 included in the hoist device 400 will be described.
First, the case where the user who mounted | worn the body holding apparatus 300 to the hoist arm 460 is fixed is demonstrated. In particular, the operation when a human enters the exoskeleton cyborg device 500 as an endoskeleton (during power assist) will be described.
[0044]
First, the hoist 400 corresponding to the cockpit and storage device includes, for example, six exoskeleton devices (holding devices 300, 520, and 530) of the body, the right arm hand, the left arm hand, the right leg foot, the left leg foot, and the neck. 540, 550, 560) and a processing device (vector quantized data input / output device). For this reason, the exoskeleton cyborg device includes, for example, eight elements.
[0045]
Here, based on a state where the hoist device 400 and the exoskeleton cyborg device 500 (in this case, corresponding to the body holding device 300) that holds the trunk are combined, for example, the operation of raising the trunk from the bed is as follows: This is when the fuselage enters the exoskeleton cyborg device 500. Further, the action of the body to lie on the bed is when the body comes out of the exoskeleton cyborg device 500 (body holding device). In addition, when a healthy person uses, it will use in and out of the exoskeleton cyborg device 500 which holds a trunk in a basic state.
[0046]
In a state where the hoist device 400 and the exoskeleton cyborg device 500 holding the body are combined, five exoskeletons (right arm hand, left arm hand, right leg foot, left leg foot, After combining the head holding devices as necessary, the signal line connector of the processing device is connected to complete the combination. After the combination is completed, the command from the input unit (operation console) of the processing device is completed. By pressing the part, the exoskeleton cyborg device 500 is operated. Thus, coalescence means here that both the signal system and the mechanism system are coupled.
[0047]
For example, the exoskeleton cyborg device 500 may be operated while being combined with the hoist device 400 or may be operated away from the hoist device 400 (racewalking). In this walking-type walking, each arm and neck exoskeleton device is used depending on the situation. In addition, since the walk type walking in the exoskeleton cyborg device 500 is stable like an automobile, for example, the stabilization control for preventing the fall like a bipedal robot is not necessary.
[0048]
Next, regarding the exoskeleton cyborg device 500, a case where an endoskeleton simulating a human body such as a prosthetic hand and a prosthetic leg is used as an end skeleton will be described. The connection between an actual body and a prosthetic hand and a prosthetic leg is a modular end skeleton ( Endoskeleton). For example, modular end skeletons are coupled with each other, such as a pair around a horizontal bending axis, a pair even around a vertical bending axis, and a pair even around a skeleton center axis. It is expected to be handled in the same way as
[0049]
FIG. 10 is a front view of the exoskeleton cyborg device.
The exoskeleton cyborg device includes, for example, omnidirectional moving wheels 710 and 715, interfaces (I / F) 720 and 730 including a leg and foot holding device sensor and an amplifying device, leg and foot holding devices 732 and 734, and a body holding device. Includes leg and foot holding device combining devices 736 and 738, body holding device 300, arm and hand holding devices 752 and 754, body holding device and arm and hand holding device combining devices 760 and 762, arm and hand holding device sensors and amplifying devices. Interface (I / F) 764, 766, head holding device 770, mandibular holding device 780, interface (I / F) 790 including head holding device sensor and amplification device, and vector quantized data input / output device Including a processing device 795.
[0050]
By combining the body holding device 300 and the arm holding device 760, 762, the left arm hand and the right arm hand can be independently combined with the body holding device 300, and the arm holding device interface (I / F) 764, 766 Are connected to the arm holding devices 752 and 754, respectively. Also, since the left leg foot and the right leg foot can be independently combined with the body holding device 300 by the uniting devices 736 and 738 of the body holding device and the leg foot holding device, the interface (I / F) of the leg foot holding device can be obtained. ) 720 and 730 are connected and attached to the leg and foot holding devices 732 and 734, respectively. In addition, omnidirectional movement can be performed by attaching four wheels on the left and right of the most advanced link of the leg. Further, a central processing unit 795 is attached to the head of the neck. In the figure, a rectangle indicates a driver.
[0051]
Here, a description will be given of the operations associated with supine, standing, and movement in the exoskeleton cyborg device. In supine, for example, the hoist device 400 stores leg feet, arms, and head-holding devices other than the body holding device 300. The hoist arm 460 is lowered onto the bed using only the body holding device 300, and the body is placed on the bed. In standing, for example, the body holding device 300 holds the body that is supine on the bed and lifts and pulls it in. Further, the body holding device 300 is provided with leg-leg, arm-hand, and head-and-head holding devices and a processing device 795. Combine. In the movement, for example, the hoist device 400 is separated and moved. As a result, the exoskeleton cyborg device can perform supine, standing and moving.
[0052]
Further, the opposed two-wheel oscillating four-axis independent suspension omnidirectional moving wheels 710 and 715 on which the exo skeleton cyborg device is mounted are driven by, for example, driving the opposed two-wheels with a motor. Are swinging so that they always come into contact with each other, and further, this group is suspended independently using springs using four axes. In addition, this cart steers the four axes by the pause control method, but considers the interference caused by the fact that the center of rotation of the four axes does not coincide with each other at the time of steering, and steers until this interference falls within a practical allowable range. Wait for the progress.
[0053]
Further, the state of uniting in the exoskeleton cyborg device will be described. At this time, the exoskeleton cyborg device operates away from the hoist device 400 corresponding to the cockpit and storage device. The left arm hand, the right leg foot, the left leg foot, and the head and neck skeleton device (holding device) and the central processing unit 795 are fully equipped. The operation here is the same as the above-described flowchart (see FIG. 2).
[0054]
FIG. 11 is an explanatory diagram showing an example of power assist at the time of a competitive walking.
In power assist at the time of a race walk, for example, the leg foot holding device (right foot) 734 is braked by the processing device, the leg foot holding device (left foot) 732 is released, the body is brought forward, and both legs are When fully open, brake the left leg foot wheel. As a result, the exoskeleton cyborg device effectively processes the data from the force and displacement sensor during the walk-type walking, for example, walking with repeated knee extension, knee folding, knee extension, pulling, knee folding, knee extension. In addition, the power during walking can be assisted. Here, since the body holding device 300 exchanges the position energy and the kinetic energy at the location indicated by the broken line in the figure, the performance can be further improved by using an auxiliary driving device such as a spring. .
[0055]
In addition, the power assist operation process at the time of the race-walking in the exoskeleton cyborg device corresponds to the flowchart shown in FIG. 2. For example, the “tilt forward” operation here is “displacement sensor” in step S 101. Corresponding to “target value input for value 6”, “brake, brake release, knee folding, knee extension, pulling” operations correspond to “output to drive device 7” in step S109.
[0056]
FIG. 12 is an explanatory diagram regarding signal transmission of the interface (I / F) 20 and the processing device 30.
The interface (I / F) 20 and the processing device 30 are for performing signal transmission in a unified manner, for example, and a plurality of matrix sections in the figure indicate vector standardization. Here, the processing device (vector quantized data input / output device) treats all data including image data in a unified manner by vector quantization. For this reason, the scalar quantity is once expanded to a vector and then quantized. Specifically, the LINK angle, force, and image data (image density) are all quantized. In this quantization, it is assumed that the correspondence relationship between the pixel (or memory) 810, a vector 820 of about 4 × 4, the quantized scalar quantity 830, and the code book 840 when restoring the vector as necessary is constant. To do. The position can be expressed by, for example, x, y, z, coordinates, and the posture can be expressed by a rotation angle roll, pitch, and yaw angle around each x, y, z axis. When a 4 × 4 transformation matrix is used, an exoskeleton cyborg device (manipulator) expressed as a linear chain of link elements can be controlled to a target position and target posture by the DH method (Deravit Harterbag method) or the like. (Robot dynamics and control, Taku Arimoto, Asakura Shobo Reference)
[0057]
Further, the interface (I / F) 20 performs tuning so that Expression (1) is established by the sensor and amplification.
M = {(P−Ps) (Me−Ms) / (Pe−Ps)} + Ms (1)
However, M: output data, Ms: minimum output value command value, Me: maximum output value command value, P: input data, Ps: minimum input value command value, Pe: maximum input value command value.
[0058]
FIG. 13 is an explanatory diagram of data transfer in the exoskeleton cyborg device according to the present invention. Normally, the legs, arms, neck and head and body holding device are separated and stored in the hoist, but these are used together with the body holding device if necessary. The
[0059]
In the data transfer between the exoskeleton cyborg devices, for example, a treatment device 800 including a vector quantized data input / output device, an interface (I / F) 900, an exoskeleton cyborg device 500, and a hoist device 400 are involved. In addition, the data of the exoskeleton cyborg device can be stored, enlarged, and reduced in operation in an environment where the data can be transferred via a communication line. One exo skeleton cyborg device may be worn by a human and the other may be worn by a robot / human body model having an internal skeleton, or both may be a human or a robot / human body model.
[0060]
Here, as the transmission / storage / enlargement / reduction of the body motion by the exoskeleton cyborg device, for example, a separate robot is operated by using only data transmission, data is repeatedly stored, It is possible to output powerful force by expanding the size, and to perform micro work by reducing the data.
[0061]
【The invention's effect】
According to the present invention, as described above, an exoskeleton device that can substitute for kinematic and biological body functions for arms and legs, legs, and the like, and can be applied to a comprehensive welfare robot, etc. An exoskeleton cyborg device and system thereof can be provided. Further, according to the present invention, it is possible to smoothly and efficiently transmit a human movement to a similar remote robot. In addition, according to the present invention, each part can perform operations such as boost, high speed, and precision. Furthermore, according to the present invention, power assist for standing up from the bed, moving the floor for excretion and bathing, moving around the space for avoiding stairs, etc., transferring to automobiles, manual work after moving to the company, etc. It can be performed.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of an exoskeleton device.
FIG. 2 is a flowchart of a modular type exoskeleton device according to the present invention.
FIG. 3 is a schematic configuration diagram of an end skeleton unit 10 of the exoskeleton cyborg device.
FIG. 4 is a configuration diagram of an exoskeleton type 7-degree-of-freedom arm.
FIG. 5 is a schematic configuration diagram of an exoskeleton-type 21-degree-of-freedom hand.
FIG. 6 is a schematic configuration diagram of a body holding device serving as a base of the exoskeleton cyborg device.
7 is a schematic configuration diagram of an exoskeleton cyborg device 500. FIG.
FIG. 8 is a schematic configuration diagram of a three-point support type coalescing device.
FIG. 9 is a schematic configuration diagram of a hoist device.
FIG. 10 is a front view of the exoskeleton cyborg device.
FIG. 11 is an explanatory diagram showing an example of power assist at the time of competitive walking.
12 is an explanatory diagram of signal transmission of the interface (I / F) and the processing device 30. FIG.
FIG. 13 is an explanatory diagram of data transfer in the exoskeleton cyborg system according to the present invention.
[Explanation of symbols]
1-3
4 Sliding kinematic pairs
5-1-3 Force sensor
6-1-3 Displacement sensor
7-1-3 Drive unit
8-1 Holding unit drive
8-2 Holding part
9 Module connection
10 End skeleton
12, 14 joints
20 interface (I / F)
30 processing equipment
100 Exoskeleton device

Claims (13)

An exoskeleton device having an exoskeleton structure for enclosing a portion having an endoskeleton,
A first turning pair that moves around the transverse bending axis at the exoskeleton joint position;
A second turning pair that moves about a longitudinal bending axis at an exoskeleton joint position orthogonal to the first turning pair;
A third counter-even moving around the endoskeleton axis;
A sliding pair having an elastic function in a sliding direction with respect to the movement by the first or second turning pair;
A frame on which the first to third turning pairs and the sliding pair are disposed;
A holding part for holding the frame in a portion having an internal skeleton;
A coupling portion for coupling to an adjacent frame;
A holding unit driving device that adjusts the mounting of the holding unit to a site having an endoskeleton;
First to third driving devices that respectively rotate and drive the first to third turning pairs;
First to third displacement sensors for detecting a rotation angle of the first to third turning pairs, and first to third forces for detecting lateral bending, vertical bending, and twisting direction of the endoskeleton axis with respect to the frame. A third force sensor;
The angle signal of each pair is input from the first to third displacement sensors, the force signal of each direction is input from the first to third force sensors, and a predetermined target value is set according to the angle signal and the force signal. An exoskeleton device comprising a processing device that outputs a driving signal for driving the first to third driving units and the holding unit driving device. An input unit for inputting a target value for a predetermined state;
An amplifying circuit for converting the drive signal from the processing device into output data within a range of the minimum and maximum output signals to be supplied to the first to third drive devices according to the minimum and maximum drive signals; In addition to outputting the output signal, the detection signals from the first to third displacement sensor units and the first to third force sensor units are converted into detection data within a predetermined range and output to the processing device. And an interface to
The processor is
Detecting the rotation angle of each pair detected by the first to third displacement sensors via the interface;
Compare the angle signal corresponding to the detected angle and the target value set by the input unit,
The first to third driving via the interface so that the angle signals from the first to third displacement sensors become the target value within the range of a predetermined load of the first to third force sensors. The exoskeleton apparatus according to claim 1, wherein the apparatus is driven. The exoskeleton apparatus according to claim 2, wherein the exoskeleton apparatus includes human parts and performs a power assist operation by a central processing unit. 4. The exoskeleton apparatus according to claim 1, wherein the drive signal, the angle signal, the force signal, and the position and orientation information of each link are expressed by unified vector quantization data. . The holding unit includes a part having an internal skeleton of the human body, a part having an internal skeleton that simulates the human body, or a part having the internal skeleton of the human body in part and the internal skeleton that simulates the human body in the other part. An exoskeleton device according to any one of claims 1 to 4, characterized in that it can be made. A plurality of the exoskeleton devices according to any one of claims 1 to 5 are arranged corresponding to a shoulder portion, an elbow portion, and a wrist portion, and the plurality of exoskeleton devices are connected by a coupling means. , An exo-skeleton cyborg device for holding an arm for wearing a part including an endoskeleton corresponding to the arm part,
A central processing unit for controlling the processing unit of each exo skeleton device,
With the central processing unit,
The first exoskeleton device of the shoulder has at least three turning pairs and two sliding pairs,
The second exoskeleton device of the elbow has at least one turning pair and one sliding pair,
The third exoskeleton device of the forearm has at least one turning pair functioning,
The third exoskeleton device of the wrist part is characterized in that the right and left arms are state-detected and driven and controlled with at least 7 degrees of freedom so that at least two swivel pairs and one sliding pair can function. Exo skeleton cyborg device to do. A plurality of the exoskeleton devices according to any one of claims 1 to 5 are arranged corresponding to the joint portions of the thumb portion and other finger portions, respectively, and the plurality of exoskeleton devices are coupling means. Is an exo-skeleton cyborg device for holding a hand for attaching a part including an endoskeleton corresponding to a hand part,
A back holding part for holding the exoskeleton device of the hand part;
A central processing unit for controlling the processing unit of each exo skeleton device,
By the central processing unit,
At least three exo skeleton devices on the thumb of the hand have at least five turning pairs and two sliding pairs,
At least three exoskeleton devices on each other finger of the hand function to function at least four swivel pairs and three slip pairs, respectively,
An exo-skeleton cyborg device for holding a hand, wherein the right and left hands are state-detected and driven and controlled with at least 21 degrees of freedom. A plurality of the exo skeleton devices according to any one of claims 1 to 4 are arranged corresponding to a hip joint portion, a leg portion, and a foot portion, and the plurality of exo skeleton devices are connected by a coupling means. , An exoskeleton cyborg device for holding a leg foot for mounting a part including an endoskeleton corresponding to a leg foot part,
A central processing unit for controlling the processing unit of each exo skeleton device,
By the central processing unit,
The first exoskeleton device of the hip joint functions at least three turning pairs and two sliding pairs,
The second exoskeleton device of the knee functions at least one turning pair and one sliding pair,
The third exoskeleton device of the lower leg functions as at least one swivel pair,
The fourth exoskeleton device of the foot is characterized in that state detection and drive control of the left and right leg feet are performed with at least 7 degrees of freedom so that at least two swivel pairs and one sliding pair are functioning. An exoskeleton cyborg device for holding leg feet. The exoskeleton device according to any one of claims 1 to 4,
An arm-hand holding device for attaching a part including an endoskeleton corresponding to the arm-hand portion, each of the left and right arms having a link of at least 7 degrees of freedom and a hand portion of at least 21 degrees of freedom;
A leg-foot holding device for attaching a part including an internal skeleton corresponding to a leg-foot part, wherein the left and right leg-foot parts have links of at least seven degrees of freedom;
As a head holding device for mounting a part including an internal skeleton corresponding to the head of the neck including a link having at least 3 degrees of freedom in the neck and at least 4 degrees of freedom in the lower jaw,
Configure at least one for each of 77 links,
An endoskeleton corresponding to a body part for holding the crotch movable frame, the side movable frame, the shoulder movable frame, and each holding device, and holding the arm-hand holding device, the leg foot holding device, and the head and head holding device. A body holding device for wearing a part including,
A support for connecting the arm-hand holding device, the leg-foot holding device, and the head-and-head holding device to the body holding device, respectively;
An exoskeleton cyborg device comprising a central processing unit for inputting angle signals and force signals from the arm-hand holding device, the leg-foot holding device, and the head-and-head holding device and driving each of the holding devices. As the arm hand holding device,
The exoskeleton cyborg device for holding an arm according to claim 6;
The exoskeleton cyborg device for holding a hand according to claim 7,
10. The exoskeleton cyborg device according to claim 9, wherein the exoskeleton cyborg device for holding a leg foot according to claim 8 is used as the leg foot holding device. A storage device for storing the body holding device, the arm-and-hand holding device, the leg and foot holding device, and the head holding device;
The exoskeleton cyborg device according to claim 9 or 10, further comprising a hoist controlled by an operation unit for moving the body holding device in the vertical direction and in all directions. A first and second exoskeleton cyborg device according to any of claims 6 to 11,
The angle signal detected by the displacement sensor of the first exoskeleton cyborg device and the force signal detected by the force sensor are converted into predetermined vector quantized data and output, and the transmitted vector quantized data And first and second communication interfaces for transmitting and receiving signals to and from each central processing unit of the first and second exoskeleton cyborg devices,
A communication line connecting between the first and second communication interfaces;
Vector quantized data representing the operation or position of the first exo skeleton cyborg device is transmitted to the second exo skeleton cyborg device, and the second exo skeleton cyborg device transmits the transmitted vector quantum. The exoskeleton cyborg system is characterized in that the control data or the position control corresponding to the operation or position of the first exoskeleton cyborg device is executed. For the first exoskeleton cyborg device, the second exoskeleton cyborg device performs movement or position control of any of body motion transmission, storage, enlargement or reduction, high speed or low speed movement. The exoskeleton cyborg system according to claim 12.

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