JP2007097636A - Muscular strength assisting apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a very safe muscular strength assisting apparatus which has an operation to apply the force besides the lifting up motion, assists the muscular force of the knees and the thighs and the muscular force of the supporting arms, for example, at the time of the standing up motion from a chair, and becomes the assist exceeding a movable range of the user's joint in the case of the assist of the muscular force by a rotating machine. <P>SOLUTION: The muscular force assisting apparatus is equipped with an exoskeleton to surround the user's human body, a clothing section to make the exoskeleton be attached to the user's human body, an actuator to make the exoskeleton act, a primary drive to make the actuator act and a device to control the primary drive, and is an outfit which can be compactly attached to the whole body so that the assist of the muscular force of the whole body can be executed by disposing the actuators over the entire body. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a muscle force assisting device, and assists muscle strength with respect to human movement.

  In recent years, it has become an aging society, and in the field of nursing care and welfare, it is necessary to assist muscles in both caregivers and care recipients. In addition, a lot of work for lifting heavy objects is seen in labor and daily work.

  In the following Patent Document 1, a device that assists a caregiver's muscular strength in a care work such as cuddling a cared person who cannot perform basic operations necessary for daily life is disclosed.

  The muscle force assisting device disclosed in Patent Document 1 is worn by a user by fixing the muscle strength assisting device to both arms, torso, and both legs with bands or the like, and assists the user's muscle strength by a pneumatic actuator and a link mechanism. .

  However, since the muscular strength assisting device of Patent Document 1 is large, it is difficult to guess that the user can easily wear it. In particular, the link mechanism and pneumatic actuator that assist the muscle strength of the back and abdominal muscles during work involving forward bending exercises are greatly extended to the rear of the user. It is done.

  Further, since it is necessary to supply compressed air to the pneumatic actuator from an external compressor, the user is likely to be restricted in the action range and the use range by the air piping.

In addition, the muscle force assisting device disclosed in the following Patent Document 2 proposed to solve the above problem is that a user carries a back like a rucksack, fixes a shoulder portion and a hip joint portion, and expands / contracts the distance between both ends. Actuators are provided on the back portion in the vertical direction, and the distance from the shoulder portion to the back side to the hip joint portion is expanded and contracted to assist the muscle strength of the operation involving forward bending.
JP 2000-51289 A JP 2005-000339 A

  However, the conventional muscle strength assist device reduces the burden on the waist, but has a problem that the strain on the knee that supports them all increases, and the muscle strength such as arms and shoulders is not assisted. Yes. In addition to the lifting operation, there is a work to apply force. For example, it is necessary to assist the muscular strength of the knees and thighs and assist the muscular strength of the supporting arm when standing up from the chair. Further, in the assistance of the muscular strength, the assistance by the rotating machine is not likely to be assistance beyond the range of motion of the user's joint, and thus there is a problem that safety is poor.

  In order to solve the above problems, the muscle force assisting apparatus of the present invention operates an exoskeleton surrounding a user's human body, a garment part for mounting the exoskeleton on the user's human body, an actuator for operating the exoskeleton, and the actuator. Since it is a muscular strength assisting device that includes a drive source and a device that controls the drive source, it is a brace that can be worn compactly throughout the body. It becomes possible to assist.

  The muscle force assisting device according to claim 2, wherein the exoskeleton is composed of an upper limb, a lower limb, and a trunk, and transmits a weight of the upper limb and the trunk and a reaction during actuator operation to the lower limb, It has the effect of not burdening.

  The muscle force assisting device according to claim 3 is a mechanism in which the exoskeleton contacts the ground, so that the user's weight and the reaction at the time of actuator operation are released to the ground, so that the user is not burdened. It has the action.

The muscle force assisting device according to claim 4, wherein the spine structure of the exoskeleton is connected to a plurality of spine joints so as to move freely, and operates in the same manner as a human spine, so that the user can bend forward and backward. Has the effect of assisting bending, lateral bending and lateral rotation,
The muscle strength assisting device according to claim 5, wherein the rib part of the exoskeleton extends from the user's back to the shoulder and reaches the chest, and tension is applied to the inside of the rib part from the back to the chest. When the user wears it, the rib portion does not directly touch the user, and the weight is dispersed to reduce the burden on the user. In addition, the garment for attaching the exoskeleton to the user is provided with an abdominal band, which acts to disperse the weight of the exoskeleton and increase the user's abdominal pressure, making it easy to exert force.

  The muscle force assisting device according to claim 6 is pivotally connected to the backbone structure of the exoskeleton by a joint symmetrically, and is opened to the left and right so that the user can put both arms through when wearing. It has the effect of facilitating and easy mounting.

  The muscle strength assisting device according to claim 7, wherein the lumbar portion of the exoskeleton is slidably coupled to the spine structure by a joint, and a base portion disposed so as to surround a user's waist and the base portion. It consists of two waist plates attached to the left and right with joints, and has the action of attaching and fixing to the user through clothes in the previous term, and the action of connecting the trunk and the lower limbs freely. Have.

  The muscle force assisting device according to claim 8, wherein the thigh portion of the exoskeleton is rotatably connected to the waist plate by a waist joint, and rotates around the waist plate. It has the action of transmitting a force that assists the flexion and extension of the user's thigh.

  The muscle strength assisting device according to claim 9, wherein the thigh of the exoskeleton is connected to the crus by two or more pivotable knee joints that are interlocked to form a double joint, By performing the same movement as that of the knee joint, there is an effect of transmitting a force that assists the muscle strength of knee extension and flexion without imposing a burden on the user's joint.

  The muscle force assisting device according to claim 10, wherein the foot portion of the exoskeleton is connected to the lower leg portion and an ankle joint so as to be swingable and rotatable, and the foot portion rotates. By this, it has the effect | action which transmits the force which assists the muscular strength of an ankle dorsiflexion and a plantar flexion, without impairing the freedom degree of a user's ankle joint.

  The muscle force assisting device according to claim 11, wherein the shoulder portion of the exoskeleton is slidably connected to the rib portion by one or a plurality of joints, thereby connecting the upper limb to the trunk. By doing so, it has the effect of transmitting its own weight and reaction during actuator operation to the lower limbs and not burdening the user.

  The muscle force assisting device according to claim 12, wherein the upper arm portion of the exoskeleton is rotatably connected to the shoulder portion by a shoulder joint, and rotates around the shoulder portion, thereby allowing the user's shoulder to rotate. It has the effect of transmitting a force that assists the muscle strength of the forward and backward tilt of the joint.

  The muscle strength assisting device according to claim 13, wherein the upper arm portion of the exoskeleton is connected to the forearm portion by two or more pivotable elbow joints to form a double joint, and a human elbow By performing the same movement as the joint, it has an effect of transmitting a force that assists the muscle strength of elbow extension and flexion without imposing a burden on the user's joint.

  The muscle force assisting device according to claim 14, wherein the wrist portion of the exoskeleton is rotatably connected to the forearm portion by a joint, and the wrist portion rotates to rotate the wrist. It has the effect of operating without interfering with inward and outward movement.

  The muscle force assisting device according to claim 15, wherein the hand portion of the exoskeleton is connected by two or a plurality of rotatable wrist joints interlocking with the wrist portion to form a double joint, and the wrist joint of a human body By performing the same movement as the above, there is an action of transmitting a force assisting the dorsiflexion of the hand and the muscle strength of the palm curve without imposing a burden on the user's joint.

  The muscle force assisting device according to claim 16 is a pneumatic rubber artificial muscle that expands in a radial direction when the actuator applies air pressure and contracts in an axial direction to obtain an output, and the drive source is an air pressure source, The control device operates the pneumatic rubber artificial muscle by controlling the air pressure flowing into the pneumatic rubber artificial muscle from the pneumatic source. Since the pneumatic rubber artificial muscle does not rotate the joint beyond the contraction limit, it has an effect of realizing a muscle force assisting device that has less burden on the user's joint and ensures safety.

  The muscle force assisting device according to claim 17, wherein two pairs of pneumatic rubber artificial muscles that antagonize are arranged on the shoulder joint of the exoskeleton that is rotatably arranged on the shoulder and the upper arm. Thus, it has an effect of assisting the muscular strength of the user's upper and lower limbs.

  The muscle force assisting device according to claim 18 is used by arranging two pairs of pneumatic rubber artificial muscles that antagonize at a double joint of the elbow joint of the upper arm portion and the forearm portion of the exoskeleton. It has the effect of assisting the elbow joint's flexion and extension muscle strength.

  The muscle force assisting device according to claim 19 is used by arranging two pairs of pneumatic rubber artificial muscles to antagonize at a double joint of the wrist part of the exoskeleton and the wrist joint of the hand part. It has the effect of assisting the palmar and dorsiflexion muscle strength of the hand of the person.

  The muscle force assisting device according to claim 20, wherein the two pairs of pneumatic rubber artificial muscles that antagonize are arranged on the waist joint of the exoskeleton and the waist joint that is rotatably arranged on the thigh. By this, it has the effect | action which assists a bending | flexion and extension of a user's thigh.

  The muscle force assisting device according to claim 21, wherein the two pairs of pneumatic rubber artificial muscles to be antagonized are arranged in a double joint of the knee joint of the thigh and the crus of the exoskeleton. It has the effect of assisting the user's knee joint flexion and extension muscle strength.

  23. The muscle force assisting device according to claim 22, wherein two sets of pneumatic rubber artificial muscles that antagonize are arranged on the ankle joint that is rotatably arranged on the lower leg and the foot of the exoskeleton. By this, it has the effect | action which assists the user's ankle dorsiflexion and muscular strength of a plantar flexion.

  The muscle strength assisting device according to claim 23, wherein three sets of the pneumatic rubber artificial muscles are arranged on the front surface, the back surface, and the upper portion from the shoulder portion to the rib portion of the exoskeleton, thereby allowing the shoulder of the user to It has the effect of assisting the muscular strength of joint pronation, pronation and elevation.

  The muscle strength assisting device according to claim 24, wherein two sets of the pneumatic rubber artificial muscles are arranged on the front surface and the back surface from the rib portion to the waist portion of the exoskeleton, so that the user can bend forward and backward. It has the effect of assisting muscle strength.

  26. The muscle strength assisting device according to claim 25, wherein two sets of the pneumatic rubber artificial muscles are arranged on the left and right side surfaces from the rib part to the waist part of the exoskeleton, respectively. It has the effect of assisting the muscle strength of the convolution.

  According to a twenty-sixth aspect of the present invention, the muscle force assisting device has a function of detecting a user's motion intention and performing a tracking operation by mounting a sensor for detecting a movement of a human body on the clothes or the exoskeleton.

  The present invention can assist the muscle strength of the whole body.

  Embodiments of the present invention will be described below with reference to the drawings.

(Embodiment 1)
As shown in FIG. 1, the muscle force assisting device of the present invention is arranged so as to surround the user's human body, and the user's trunk is covered with clothes (Fig. (Not shown). FIG. 2 shows only the exoskeleton. The upper limb and the lower limb are attached to the user by the upper arm 3, the forearm 4, the hand 5, and the bands (not shown) provided on the thigh 6, the crus 7, and the foot 8, respectively. The Each joint assists in bending and extending movements by contraction of the pneumatic artificial rubber muscles arranged in each. An air source for driving the pneumatic rubber artificial muscle and a control unit for operating the pneumatic rubber artificial muscle are housed in the backpack 9. Each joint is described in detail below.

  A description will be given of muscle strength assistance for the upper limb of the user with reference to FIG. A sensor 201 provided in the upper arm 3 and mounted in the band 101 for wearing on the user's upper arm detects the movement of the muscle due to the bending of the elbow of the user, and information is transmitted to the control unit built in the backpack 9. And by driving the pneumatic rubber artificial muscle 301 based on the signal output from the control unit, the elbow joint group 10 connecting the upper arm 3 and the forearm 4 is rotated, and the forearm 4 is By pulling up, it helps the muscle strength to bend the user's elbow. Further, when the user's bent arm is extended, the sensor 202 built in the band 101 detects the movement of the muscle, transmits information to the control unit, and based on the signal output from the control unit, By driving a pneumatic rubber artificial muscle 302 arranged to antagonize the artificial rubber muscle 301 via the elbow joint group 10, the muscle strength for bending the user's elbow is assisted. Similarly, for the wrist, sensors 203 and 204 built in a band 102 for attaching the wrist joint group 11 that connects the forearm portion 4 and the hand portion 5 to the forearm portion 4 of the user are provided by the user. By detecting the movement of the muscle, transmitting information to the control unit, and operating the pneumatic rubber artificial muscles 303 and 304 based on the signal output from the control unit, the muscle strength of palm flexion and dorsiflexion of the wrist To assist.

  Next, assistance for muscle strength of the user's lower limbs will be described with reference to FIG. Sensors 205 and 206 provided in the thigh 6 and installed in the band 103 for wearing on the user's thigh, and built in the band 104 provided in the thigh 6 and attached to the user's thigh. Sensors 207 and 208 detect the movement of the user's thigh muscles, transmit information to the control unit, and operate the pneumatic rubber artificial muscles 305 and 306 based on the signal output from the control unit, By rotating the waist joint 13 connecting the waist plate 12 and the thigh 6 to assist the user's thigh flexion and extension muscle strength, and operating the pneumatic rubber artificial muscles 307 and 308, the thigh 6 The knee joint joint group 14 that connects the leg 7 and the lower leg 7 is rotated to assist the user's knee strength in flexing and extending the knee joint. Similarly for the ankle, the sensors 209 and 210 provided in the band 105 for wearing on the user's lower leg that are provided on the lower leg part 7 and for attaching to the user's lower leg provided on the lower leg part 7. Sensors 211 and 212 built in the band 106 detect the movement of the user's lower leg muscles, transmit information to the control unit, and based on the signal output from the control unit, the pneumatic rubber artificial muscle 309 , 310 is operated to rotate the ankle joint 15 that connects the lower leg 7 and the foot 8, thereby assisting the user's ankle dorsiflexion and plantar flexion muscle strength.

  Next, assistance for the muscle strength of the user's shoulder will be described with reference to FIG. The movement of the upper limb of the user is detected by the sensor 213 incorporated in the band 101 and the sensor 214 incorporated in the band 102, information is transmitted to the control unit, and the air pressure is generated based on the signal output from the control unit. The artificial rubber muscles 311 and 312 are operated, and the shoulder joint 17 connecting the shoulder 16 and the upper arm 3 is rotated to assist the forward and backward muscle strength of the user's shoulder, and the artificial rubber muscle 313 To assist the muscular strength of the shoulder pronation, or to activate the rubber artificial muscle 314 to assist the muscle elevation of the shoulder, or to activate the rubber artificial muscle 315, and the muscular strength outside the shoulder To assist.

  Next, assistance for muscle strength of the user's trunk will be described with reference to FIG. Sensors 215, 216, 217, and 218, which are provided in the waist 2 and are installed in the abdominal band 18 for wearing on the user's abdomen, detect the movement of the user's trunk, transmit information to the control unit, and control By operating the pneumatic rubber artificial muscle 316 based on the signal output from the section, the user's forward bending muscle strength is assisted, and the pneumatic rubber artificial muscle 317 is operated to By assisting the bending muscle strength and operating the pneumatic rubber artificial muscles 318 and 319, assisting the user's leftward bending strength and operating the pneumatic rubber artificial muscles 320 and 321, By assisting the user's lateral flexion muscle strength in the right direction and operating the pneumatic rubber artificial muscles 318 and 320, the user's left side muscle strength is assisted in the pneumatic rubber artificial muscle. 319, 3 By allowed to operate one, to assist the strength of the lateral rotation in the right direction of the user.

  The embodiment of the operation using the present invention has been described above. Although the actuator for operating the exoskeleton has been described using the pneumatic rubber artificial muscle, the same effect can be obtained by using other actuators such as a motor and a gear. In addition, for the sake of simplicity, separate operations and sensor detection have been described for each part, but individually or individually using a plurality of sensors, or operating a plurality of pneumatic rubber artificial muscles, Similar or more effects can be obtained. Further, although the whole body has been described, it is also possible to separate each part and operate by each to assist muscle strength.

  Since the muscle force assisting device according to the present invention is a device that is attached to a human body and assists the muscle strength of the whole body, it can be used for lifting heavy objects. It can also be applied to industrial uses such as transportation in factories and moving companies. In addition, if a soft pneumatic rubber artificial muscle is used, it can be applied to the medical and nursing fields such as holding a patient. Furthermore, by applying the actuator as a load as well as an assist, it can be applied to sports fields such as exercising and training and rehabilitation fields.

(A) Front side perspective view in which the user wears the muscular strength assisting device in Embodiment 1 of the present invention (b) Rear side perspective view in which the user has worn the muscular strength assisting device in Embodiment 1 of the present invention (A) Perspective view of the front side of the exoskeleton of the muscle force assisting apparatus in Embodiment 1 of the present invention (b) Perspective view of the back side of the exoskeleton of the muscle strength assisting apparatus in Embodiment 1 of the present invention The perspective view of the upper limb of the muscular strength assistance apparatus in Embodiment 1 of this invention The perspective view of the leg of the muscle force auxiliary device in Embodiment 1 of the present invention The perspective view of the shoulder of the muscular strength assistance apparatus in Embodiment 1 of this invention The perspective view of the trunk of the muscular strength assisting device in Embodiment 1 of the present invention

Explanation of symbols

1 rib part 2 waist part 3 upper arm part 4 forearm part 5 hand part 6 thigh part 7 lower leg part 8 foot part 9 backpack 10 elbow joint group 11 wrist joint group 12 waist plate 13 waist joint 14 knee joint group 15 ankle joint 16 Shoulder 17 Shoulder joint 18 Abdominal band 19 Spine structure 101, 102, 103, 104, 105, 106 Bands for wearing 201, 202, 203, 204 Sensors 205, 206, 207, 208 Thigh muscles detecting movement of upper limb muscles Sensors 209, 210, 211, 212 Sensors that detect the movement of the lower leg muscles 213, 214 Sensors that detect the position of the upper limbs 215, 216, 217, 218 Sensors that detect the movement of the trunk muscles 301 ~ 321 Pneumatic rubber artificial muscle

Claims (27)

An exoskeleton that surrounds the human body of the user, a garment that attaches the exoskeleton to the human body of the user, a plurality of actuators that operate the exoskeleton, a drive source that operates the actuator, and a device that controls the drive source Equipped with muscle strength assist device. The exoskeleton has a backbone structure including a spine structure, a rib part, and a waist part, an upper limb comprising a shoulder part, an upper arm part, a forearm part, a wrist part, and a hand part, a thigh part, and a lower leg part The muscular strength assisting device according to claim 1, further comprising a lower limb having a foot. The muscle force assisting device according to claim 1, wherein the foot portion of the exoskeleton is in contact with the ground. The muscle strength assisting device according to any one of claims 1 to 3, wherein the spine structure of the exoskeleton operates in the same manner as a human spine by connecting a plurality of spine joints in a freely swingable manner. The muscle strength assisting device according to any one of claims 1 to 4, wherein the rib portion of the exoskeleton extends from the back of the user to the shoulder and reaches the chest. The muscle strength assisting device according to any one of claims 1 to 5, wherein the rib part of the exoskeleton is connected to the spine structure in a bilaterally symmetrical manner by a joint so as to be pivotable and open left and right. . The lumbar part of the exoskeleton is slidably connected to the spine structure by a joint, and is slidably attached to the left and right sides of the base and the base disposed so as to surround the user's waist. The muscle strength assisting device according to any one of claims 1 to 6, comprising two waist plates. The thigh of the exoskeleton is rotatably connected to the waist plate by a waist joint, and rotates around the waist plate. Muscle strength assist device. The thigh part of the exoskeleton is connected to the lower leg part by two or more interlocking rotatable knee joints to form a double joint, and behaves like a human knee joint. The muscular strength assisting device according to any one of claims 1 to 8, wherein 10. The foot part of the exoskeleton is connected to the lower leg part and an ankle joint so as to be swingable and rotatable, and the foot part rotates. The muscular strength assistance apparatus in any one. The muscle strength assisting device according to any one of claims 1 to 10, wherein the shoulder portion of the exoskeleton is slidably connected to the rib portion by one or a plurality of joints. The muscle strength assist according to any one of claims 1 to 11, wherein the upper arm portion of the exoskeleton is rotatably connected to the shoulder portion by a shoulder joint, and rotates around the shoulder portion. apparatus. The upper arm part of the exoskeleton is connected to the forearm part by two or more interlocking rotatable elbow joints to form a double joint, and moves similar to a human elbow joint. The muscular strength assisting device according to any one of claims 1 to 12. The muscle strength assisting device according to any one of claims 1 to 13, wherein the wrist portion of the exoskeleton is rotatably connected to the forearm portion by a joint, and the wrist portion rotates. The hand part of the exoskeleton is connected by two or more rotatable wrist joints interlocking with the wrist part to form a double joint, and moves in the same manner as a wrist joint of a human body. The muscular strength assisting device according to any one of claims 1 to 14. When the air pressure is applied, the actuator is a pneumatic rubber artificial muscle that expands in the radial direction and contracts in the axial direction to obtain an output, the drive source is the air pressure source, and the control device receives the air pressure from the air pressure source. The muscle force assisting device according to claim 1, wherein the air pressure flowing into the artificial rubber artificial muscle is controlled. Two sets of pneumatic rubber artificial muscles that antagonize are arranged on the shoulder joint of the exoskeleton so that the shoulder part and the upper arm part are rotatably arranged, and the user's upper limb is tilted forward and rearward. The muscle force assisting device according to any one of claims 1 to 16, wherein the device assists in tilting. Two pairs of pneumatic rubber artificial muscles that antagonize are arranged in the double joint of the upper arm part of the exoskeleton and the elbow joint of the forearm part to assist the bending and extension of the user's elbow joint The muscular strength assisting device according to any one of claims 1 to 17, wherein Two pairs of pneumatic rubber artificial muscles that antagonize are arranged in the double joint of the wrist part of the exoskeleton and the wrist joint of the hand part to assist the user's hand palm flexion and dorsiflexion The muscular strength assisting device according to claim 1, wherein the muscular strength assisting device is provided. Two sets of pneumatic rubber artificial muscles that antagonize are arranged on the waist joint of the exoskeleton on the waist plate and the thigh, which are rotatably arranged, so that the user's thigh can be bent and extended. The muscular strength assisting device according to claim 1, wherein the muscular strength assisting device is assisted. Two pairs of pneumatic rubber artificial muscles that antagonize are arranged in the double joint of the knee joint of the thigh and the crus of the exoskeleton to flex and extend the knee joint of the user The muscular strength assisting device according to any one of claims 1 to 20, wherein the muscular strength assisting device is assisted. Two sets of pneumatic rubber artificial muscles that antagonize are arranged in the ankle joint that is rotatably arranged between the crus and the foot of the exoskeleton, and the dorsiflexion of the user's ankle, and The muscular strength assisting device according to any one of claims 1 to 21, wherein the muscular strength assisting device assists in buckling. Three sets of the pneumatic rubber artificial muscles are arranged on the front, back and top of the exoskeleton from the shoulders to the ribs to assist the pronation, supination and elevation of the user's shoulder joints. The muscular strength assisting device according to any one of claims 1 to 22, wherein the muscular strength assisting device is provided. From the rib part of the exoskeleton to the waist part, two sets of the pneumatic rubber artificial muscles are arranged on the front and back surfaces to assist the user's forward bending and backward bending. 24. The muscle strength assisting device according to any one of 23. 2. The pneumatic rubber artificial muscles are arranged in two sets on the left and right side surfaces from the rib part to the waist part of the exoskeleton, respectively, to assist a user's lateral bending and lateral rotation. The muscular strength assisting device according to any one of 1 to 24. The muscle force assisting device according to any one of claims 1 to 25, wherein a sensor for detecting a movement of a human body is mounted on the clothes or the exoskeleton. The sensor is a position sensor, force sensor, torque sensor, gravity sensor, gravity acceleration sensor, velocity sensor, acceleration sensor, angle sensor, angular velocity sensor, voice sensor, myoelectric potential sensor, displacement sensor, pressure sensor, strain gauge, flow sensor 27. A temperature sensor, a humidity sensor, an electrostatic sensor, an infrared sensor, a photoelectric sensor, a vibration sensor, an impact sensor, a current sensor, a voltage sensor, a magnetic sensor, an ultrasonic sensor, or an electroencephalogram sensor. The muscular strength assisting device according to 1.