JP2021045803A - Assist device - Google Patents

Abstract

To provide an assist device which is light-weight, achieves good wearing feel, and can generate an assist force having a proper strength according to a posture etc. of a user.SOLUTION: An assist device 10 includes: a first attachment 11 attached to at least one of a shoulder and a chest of a user; second attachments 12 respectively attached to left and right leg parts of the user; a belt body 13 which is provided along the back surface side of the user while spanning the first attachment 11 and the second attachments; an actuator 14 which is provided at the first attachment 11 and enables a part of the belt body 13 to be taken up or fed; a control unit 15 which executes action control of the actuator 14; and a sensor 38 which is provided at the first attachment 11 and outputs a signal according to a posture of the user. The control unit 15 executes operation control of the actuator 14 to provide an assist force to the user by using the output of the sensor 38.SELECTED DRAWING: Figure 1

Description

The invention of the present disclosure relates to an assist device.

Various assist devices have been proposed that are attached to the body of a user (person) and assist the user's work. According to the assist device, the user can perform the work with a small force (small load) even when lifting a heavy object, for example. Such an assist device is disclosed in, for example, Patent Document 1.

JP-A-2018-199205

The assist device disclosed in Patent Document 1 has a frame made of metal or the like to be attached to a user. The output of the actuator mounted on the frame is transmitted to the upper body and lower body of the user through the link mechanism. This assists, for example, the action of lifting a heavy object.

The movements that the user needs assistance include, in addition to the movements that place a heavy load such as lifting a heavy object, the movements that assist (assist) the activities of daily living for a person such as a sick person or an elderly person. When the user performs work with a heavy load, a high-output assist device as disclosed in Patent Document 1 is effective.

However, when the user assists a person such as a sick person or an elderly person, the high-power assist device may have excessive performance. Further, in the high output assist device, a rigid body member such as a link mechanism and a frame made of metal or the like is often used, and the structure is heavy in order to obtain high output. Therefore, the weight of the assist device becomes heavy, and the movement of the user is restricted by the rigid body member.

Therefore, the inventor of the present invention has already proposed an assist device that is lightweight and has a good fit (for example, Japanese Patent Application No. 2019-043462). The assist device covers the first wearer worn on the shoulder of the user, the second wearer worn on the left and right legs of the user, and the first and second wearers. It is provided with a belt body provided along the back side of the machine and an actuator. The actuator is provided on the first attachment and enables the winding and feeding of a part of the belt body.

When the actuator winds up a part of the belt body, tension acts on the belt body. This tension acts as an assist force on the user. As a result, the burden is reduced when the user provides assistance to a person as described above, for example.

In the assist device provided with the belt body as described above, it is preferable that the assist force acting on the user is not always constant, but for example, the assist force having a strength corresponding to the posture of the user is applied.
Therefore, an object of the present disclosure is to provide an assist device that is lightweight, has a good fit, and can generate an assist force having an appropriate strength according to the posture of the user and the like. ..

The assist device of the present disclosure includes a first wearer worn on at least one of the user's shoulder and chest, a second wearer worn on each of the left and right legs or the waist of the user, and the first wearer. A belt body provided along the back side of the user across the first wearer and the second wearer, and a part of the belt body provided on the first wearer or the second wearer. It includes an actuator that enables delivery, a control unit that executes operation control of the actuator, and a sensor provided on the first attachment or the second attachment that outputs a signal according to the posture of the user. The control unit uses the output of the sensor to control the operation of the actuator in order to apply an assist force to the user.

According to the assist device having the above configuration, when the actuator winds up the belt body, tension acts on the belt body, and the tension creates an assist force to assist the user's work, which puts a burden on the user's body. It will be reduced. The belt body is lightweight and can follow the movement of the user even if the posture is changed. Therefore, an assist device having a good fit can be obtained.

It is desirable that the assist device generate an assist force according to the posture of the user. Therefore, according to the assist device having the above configuration, a signal corresponding to the posture of the user is output from the sensor. By controlling the operation of the actuator in order to apply the assist force to the user by using the output of the sensor, it is possible to generate the assist force according to the posture of the user.

Further, preferably, the control unit includes a posture estimation unit that estimates a posture parameter indicating the posture of the user, and a determination unit that obtains a physical quantity for operating the actuator based on the estimated posture parameter. The posture estimation unit has, based on the output of the sensor, using the processing result of either the first estimation process defined below or the second estimation process defined below, and the posture estimation unit. Estimate the parameters.
The first estimation process: the estimation process performed based on the amount of movement of the actuator when the belt body is wound or sent out by changing the posture of the user. The second estimation process: the estimation process performed based on the output of the sensor.

In this case, a physical quantity for operating the actuator is obtained based on the posture parameter indicating the posture of the user. This makes it possible for the actuator to generate an assist force according to the posture of the user.
Depending on the state or operation of the user, an error may occur when estimating the posture parameter based on the output of the sensor. Therefore, according to the configuration, when it is appropriate for the attitude parameter to be estimated by the sensor, the second estimation process is performed, and when it is not suitable, the first estimation process based on the movement amount of the actuator is performed. It is said.

As described above, the result of one of the first estimation process and the second estimation process is used to estimate the attitude parameter. Therefore, the estimated posture parameters may differ greatly between the previous time and this time. As a result, the physical quantity for operating the actuator may change significantly, which may give the user a sense of discomfort. Therefore, the posture estimation unit repeatedly executes the estimation of the posture parameter, and when the change amount of the posture parameter exceeds the threshold value, a new posture parameter is newly estimated based on the posture parameter estimated in the past and the change amount. It is preferable to obtain the posture parameters.

In this case, even if the parameters estimated by the posture estimation unit are significantly different between the previous time and this time, a new posture parameter is obtained based on the posture parameters estimated in the past and the amount of change in the posture parameters. .. Therefore, it is possible to prevent a large change in the physical quantity for operating the actuator.

According to the assist device of the present disclosure, it is lightweight and comfortable to wear, and it is possible to generate an assist force having an appropriate strength according to the posture of the user and the like.

It is a rear view which shows an example of an assist device. It is a rear view of the assist device attached to the user's body. It is a side view of the assist device attached to the user's body. It is explanatory drawing which shows the state which the user which attached the assist device is leaning forward. It is explanatory drawing of a control box and a belt body. It is a block diagram which shows the control structure which the assist device has. It is explanatory drawing when the user wearing an assist device changes a posture. It is explanatory drawing of correspondence information. It is explanatory drawing of conversion information. It is explanatory drawing of the drive pulley around which a belt body (the first belt) is wound. It is a block diagram explaining the process performed by a control unit. It is explanatory drawing which shows two postures of a user. It is a side view which shows the assist device of another form.

[Overall configuration of assist device 10]
FIG. 1 is a rear view showing an example of the assist device. FIG. 2 is a rear view of the assist device attached to the user's body. FIG. 3 is a side view of the assist device attached to the user's body. FIG. 4 is an explanatory view showing a state in which the user equipped with the assist device is in a forward leaning posture (forward bending posture). The assist device 10 shown in FIG. 1 includes one first attachment device 11 attached to the left and right shoulder BSs which are a part of the user's body, and the left and right which are other parts of the user's body. It is provided with two second attachments 12 to be attached to the leg BL of the above. The first attachment 11 may be attached to at least one of the user's shoulder BS and chest BB, and may be in a form other than the one shown in the figure. In the present disclosure, the second attachment 12 is attached to the knee BN in the leg BL. The second attachment 12 may also have a form other than the illustrated form.

In the assist device 10 of the present disclosure, the left and right are the left and right for a user in an upright posture wearing the assist device 10, the front and back are the front and back for the user, and the top and bottom are the top and bottom for the user. is there. The top is the user's head side, and the bottom is the user's foot side.

The assist device 10 includes a belt body 13, an actuator 14, a control unit 15, a battery 37, and a sensor 38, in addition to the first attachment 11 and the left and right second attachments 12.

The first attachment 11 is attached to the shoulder BS of the user. On the other hand, the second attachment 12 is attached to the left knee BN of the user. The other second attachment 12 is attached to the user's right knee BN. The second fitting 12 on the left side and the second fitting 12 on the right side are symmetrical, but have the same configuration. The first attachment 11 and the two second attachments 12 are attached to two places separated by sandwiching the lumbar BW, which is a joint of the user, that is, the shoulder BS and the leg BL.

The first fitting 11 is made of a flexible cloth or the like. The first attachment 11 has a back body portion 21 that is attached to the back of the user, and a shoulder belt 22 and an axillary belt 23 that are connected to the back body portion 21. The shoulder belt 22 and the axillary belt 23 bring the back body 21 on the back of the user. The axillary belt 23 connects the back body portion 21 and the shoulder belt 22, and the length thereof can be adjusted. By adjusting the length of the axillary belt 23, the back body portion 21 is in close contact with the user's back. The first attachment 11 is immovably attached to the shoulder BS in the front-back, left-right, and up-down directions. The first fitting 11 may include, for example, a hard member as a portion to be hung on the shoulder BS.

The second fitting 12 is made of a flexible cloth or the like. The second attachment 12 has a knee body portion 24 that is attached to the rear surface side of the user's knee portion BN, and a knee belt 25 that extends from the knee body portion 24. The knee belt 25 orbits the knee BN at each of the vertical positions of the knee BN, and the tip end side thereof is fixed to the knee body 24. The wrapping length of the knee belt 25 with respect to the knee BN can be adjusted by a locking member such as a belt and a buckle or a hook-and-loop fastener. By this adjustment, the knee body portion 24 is in close contact with the rear surface side of the knee portion BN. The second fitting 12 is immovably mounted in the front-back, left-right, and up-down directions with respect to the knee BN.

The belt body 13 is provided along the back side of the user so as to connect the first wearing tool 11 and the second wearing tool 12. The belt body 13 comprises a first belt 16 provided on the upper body side, a second belt 17 provided on the lower body side, and a connecting member 18 connecting the first belt 16 and the second belt 17. Have. Each of the first belt 16 and the second belt 17 is long and flexible. The connecting member 18 is made of metal and is formed of a rectangular annular body called a "flat can".

Each of the first belt 16 and the second belt 17 is a strip-shaped member made of cloth or leather, and can be curved along the shape of the body. Each of the first belt 16 and the second belt 17 may be a string-shaped belt (a member such as a wire). Each of the first belt 16 and the second belt 17 of the present disclosure is a non-stretchable member, that is, has a property of being difficult to expand and contract in the longitudinal direction or a property of not expanding and contracting.

The assist device 10 of the present disclosure includes a control box 30. The control box 30 is provided on the back body 21 of the first attachment 11. FIG. 5 is an explanatory view of the control box 30 and the belt body 13. The control box 30 has a plate-shaped base 31 and a cover 32 that covers the base 31. In order to explain the internal structure of the control box 30, the cover 32 is shown by an alternate long and short dash line (dashed line) in FIG. The base 31 may be the back body portion 21 of the first attachment 11.

An actuator 14, a control unit 15, a battery 37, a sensor 38, and the like are provided in a space formed between the base 31 and the cover 32. An opening (notch) 32a is formed in the cover 32, and the first belt 16 passes through the opening 32a.

The actuator 14 is provided in the control box 30. That is, the actuator 14 is provided on the first attachment 11. The actuator 14 enables the winding and feeding of a part of the belt body 13. Therefore, the actuator 14 has a motor 33, a speed reducer unit 34, and a drive pulley 35. The motor 33 is a brushless DC motor. The motor 33 can rotate at a predetermined torque and a predetermined rotation speed based on the drive signal output from the control unit 15. The motor 33 can rotate forward and reverse based on the drive signal output from the control unit 15.

Rotational parameters such as the rotation angle, rotation speed, or rotation speed of the motor 33 are detected by the rotation detector 36 attached to the motor 33. The rotation detector 36 of the present disclosure is a rotary encoder, but may be a Hall sensor or a resolver. The detection result of the rotation detector 36 is input to the control unit 15. The control unit 15 controls the operation of the motor 33 based on the detection result, so that the assist device 10 can generate an appropriate assist force.

The speed reducer unit 34 is composed of a plurality of gears and decelerates the rotation speed of the motor 33 to rotate the output shaft 34a of the speed reducer unit 34. A drive pulley 35 is connected to the output shaft 34a, and these rotate integrally. One end 16a side of the first belt 16 is attached to the drive pulley 35. When the drive pulley 35 rotates in one direction due to the forward rotation of the motor 33, the first belt 16 is wound around the drive pulley 35. When the drive pulley 35 rotates in the other direction due to the reverse rotation of the motor 33, the first belt 16 is sent out from the drive pulley 35.

As described above, the actuator 14 has a drive pulley 35 capable of winding the belt body 13 and a motor 33 for causing the drive pulley 35 to wind the belt body 13. The first belt 16 is wound and sent out by the actuator 14.

The control unit 15 is composed of a control unit including a microcomputer. The control unit 15 controls the operation of the actuator 14 (motor 33), which will be described later. An acceleration sensor is provided as the sensor 38. The signal of the sensor 38 is input to the control unit 15. The control unit 15 can estimate the posture of the user based on the signal from the sensor 38. The battery 37 supplies electric power to the control unit 15, the motor 33, the rotation detector 36, and the sensor 38. The sensor 38 may be provided outside the control box 30.

[About belt body 13]
As described above, the belt body 13 has a first belt 16, a second belt 17, and a connecting member 18. One end 16a side of the first belt 16 is wound and fixed to the drive pulley 35. The other end 16b side of the first belt 16 is fixed to the connecting member 18. When the first belt 16 is wound around the drive pulley 35, the connecting member 18 is pulled up. When the connecting member 18 is forcibly pulled down, the first belt 16 is unwound (pulled out) from the drive pulley 35. There is a correlation between the winding amount or unwinding amount (pulling amount) of the first belt 16 in the drive pulley 35 and the rotation amount of the output shaft of the motor 33. The rotation detector 36 detects parameters related to the rotation of the motor 33 accompanying the winding or unwinding of the belt body 13.

As described above, the connecting member 18 is formed of a rectangular annular body. The shaft portion 27a on one side (upper side) of the annular body is the first mounting portion 27, and the end portion 16b of the first belt 16 is attached to the first mounting portion 27. In the present disclosure, the first belt 16 is not removable with respect to the first attachment portion 27, but it may be removable by a buckle or the like.

The other side (lower side) of the rectangular annular body constituting the connecting member 18 is the second attachment portion 28 for attaching the second belt 17. As described above, the connecting member 18 has a first attachment portion 27 for attaching the first belt 16 and a second attachment portion 28 for attaching the second belt 17.

The second attachment portion 28 supports the second belt 17 in a folded state in the middle (intermediate portion 17c). The second mounting portion 28 of the present disclosure has a shaft portion 28a integrated with the first mounting portion 27, and a rotary pulley 29 rotatably supported by the shaft portion 28a. The second belt 17 is hung on the rotary pulley 29 in a folded state on the way. Due to this configuration, the second belt 17 is not fixed to the second mounting portion 28, and the second belt 17 is in a folded state, but moves in both directions in the longitudinal direction (arrow X direction in FIG. 5). A configuration that supports it freely can be obtained.

In FIG. 2, the second belt 17 is attached to the second fitting 12. Specifically, the second belt 17 is composed of a single strip-shaped member. One end 17a side of the second belt 17 is attached to the second attachment 12 on the left. The other end 17d side of the second belt 17 is attached to the second fitting 12 on the right. As described above, the intermediate portion 17c of the second belt 17 is hung on the connecting member 18.

According to the configuration of the second belt 17 as described above, the second belt 17 includes the left second belt portion 19 from the connecting member 18 to the left second fitting 12 and the second right from the connecting member 18. It has a right second belt portion 20 up to the fitting 12. As described above (see FIG. 5), since the second belt 17 is hung on the second mounting portion 28 (rotary pulley 29) and is not fixed, the length of the left second belt portion 19 and the right second belt portion 19 are used. The length of the belt portion 20 can be freely changed. However, the total of the length of the left second belt portion 19 and the length of the right second belt portion 20 is constant. With this configuration, for example, walking of the user is not restricted by the second belt 17, and the user can walk comfortably.

The second belt 17 further has a connecting member 39 that connects the left second belt portion 19 and the right second belt portion 20. The connecting member 39 is left second at an intermediate position between the folded-back portion (middle portion 17c) of the second belt 17 and the fixing portion (one end portion 17a, other end portion 17d) between the two second attachments 12. The belt portion 19 and the right second belt portion 20 are connected. The folded portion is a portion of the connecting member 18 where the second belt 17 is folded. The fixing portion is a portion in which the second belt 17 is fixed to each of the two second attachments 12.

For example, when the user changes his / her posture from the upright posture to the forward bending posture as shown in FIG. 4, according to the connecting member 39, the left and right second belt portions 19 and the right second belt portion 20 are left and right. It is possible to prevent the interval between the above from being widened. That is, it is possible to prevent the left second belt portion 19 and the right second belt portion 20 from being along the back side of the user's leg BL.

[About the sensor 38 and the control unit 15]
In FIG. 5, as described above, the sensor 38 is composed of an acceleration sensor. The control unit 15 can execute various arithmetic processes. The control unit 15 calculates and processes the signal from the sensor 38, so that the user's motion and posture can be detected. The sensor 38 has a configuration that outputs a signal according to the posture of the user, and functions as a posture detector for detecting the posture of the user. For example, it is possible to detect whether the posture of the user's upper body is in a forward leaning posture or an upright posture, or to detect that the user is in a crouched state.

Further, there is a correlation between the winding amount and the feeding amount of the belt body 13 by the drive pulley 35 by the motor 33 and the posture of the user. Therefore, the control unit 15 can estimate the posture of the user based on the rotation angle of the motor 33 detected by the rotation detector 36.

The control unit 15 processes signals from one or both of the sensor 38 and the rotation detector 36. A drive signal is output to the actuator 14 (motor 33) as a result of the processing, that is, according to the posture of the user. Based on the drive signal, the actuator 14 (motor 33) operates to wind and feed the belt body 13, and to temporarily stop the belt body 13. The operation control of the actuator 14 (motor 33) performed by using the signals from the sensor 38 and the rotation detector 36 will be described later.

With the assist device 10 attached to the user, the motor 33 is constantly operating in the direction of winding the belt body 13 with a weaker force than when the assist force is generated under the control of the control unit 15. (Torque is generated), and a weak tension is generated in the belt body 13. As a result, the belt body 13 does not loosen.

When the user changes his / her posture, for example, when he / she changes from an upright posture to a forward leaning posture, tension is generated in the belt body 13 due to the change in the posture. Therefore, in this case, when the posture change is started so as to be in the forward leaning posture, the motor 33 is forcibly rotated by the tension of the belt body 13 regardless of the power of the actuator 14 (the motor 33 idles). The belt body 13 is unwound. Alternatively, when the posture change is started so as to be in the forward leaning posture, the actuator 14 operates, that is, the motor 33 is rotationally driven to send out the belt body 13.

On the contrary, when the user changes from the forward leaning posture to the upright posture, the belt body 13 tries to loosen due to the change in the posture. Therefore, in this case, when the posture change is started so as to be in the upright posture, the actuator 14 operates in order to maintain the tension acting on the belt body 13, that is, the motor 33 is rotationally driven to drive the belt body 13. Take up.

In this way, the belt body 13 is wound or sent out by changing the posture of the user. In this winding or feeding, the motor 33 actively or passively rotates about a predetermined rotation angle. The rotation angle at this time is detected by the rotation detector 36. In this way, the rotation detector 36 detects the amount of movement of the actuator 14 (motor 33) when the belt body 13 is wound or sent out by changing the posture of the user.
Then, as will be described later, the control unit 15 acquires the operating amount (rotation angle of the motor 33) of the actuator 14 when winding or sending out the belt body 13 due to the change in the posture of the user, and is based on the operating amount. Therefore, a posture parameter indicating the posture of the user can be obtained, and the operation of the actuator 14 can be controlled based on the posture parameter in order to apply an assist force to the user.

FIG. 6 is a block diagram showing a control configuration included in the assist device 10. The control unit 15 is composed of a control unit including a microcomputer, and includes an arithmetic processing unit (CPU) 15a and a storage device (storage unit) 15b such as a memory. The arithmetic processing unit 15a executes various arithmetic processes based on various programs and various parameters stored in the storage device 15b. The control unit 15 of the present disclosure includes a posture estimation unit 42a, a determination unit 42b, and a determination unit 42c as functional units realized by arithmetic processing by the arithmetic processing unit 15a. The control unit 15 further includes a drive circuit (motor driver) 15c that controls the operation of the motor 33. The motor 33 executes a predetermined operation by cooperating with each of the above-mentioned functional units and the drive circuit 15c. The functional unit included in the control unit 15 will be described later.

[About the assist force by the assist device 10]
FIG. 7 is an explanatory diagram when a user wearing the assist device 10 changes his / her posture. The assist device 10 can apply an assist force to the user in response to this change in posture.

When the first belt 16 is wound around the drive pulley 35 by the motor 33 of the actuator 14, the connecting member 18 pulls the second belt 17 toward the actuator 14, that is, upward. Both ends 17a and 17d of the second belt 17 are attached to the left and right second attachments 12. The second fitting 12 is fixed to the knee BN. Therefore, when the first belt 16 is wound around the drive pulley 35, tension acts on the first belt 16 and the second belt 17. This tension acts as an assisting force (auxiliary force) for the user.

A case where the user changes from an upright posture to a forward leaning posture will be described. When the posture change is started so as to be in the forward leaning posture, the actuator 14 sends out the belt body 13. Alternatively, the belt body 13 is unwound regardless of the power of the actuator 14. As a result, the user can easily lean forward. When the forward tilt angle of the user's upper body with respect to the vertical line becomes θL and the user stops at the forward tilt angle θL, the feeding (unwinding) of the belt body 13 is stopped. The start and end of the posture change can be detected by the rotation detector 36 or the sensor 38.

When the user starts the posture change from the forward leaning posture to the upright posture, the actuator 14 winds up the belt body 13. As a result, tension is generated in the belt body 13. Due to this tension, a rearward acting force F1 is generated on the first fitting 11. That is, the acting force F1 in the direction of raising the upper body of the user in the forward leaning posture is generated. At the same time, the tension of the second belt 17 produces an acting force F2 that pushes the user's left buttocks and right buttocks forward. As a result, the user can easily return from the forward leaning posture to the upright posture.

Further, as shown in FIG. 4, the assist device 10 imparts an assist force to the user even when the user is in a bent posture (bent posture) in which the upper body is tilted forward and the knees are bent. be able to. When the user changes from a bent posture to an upright posture, for example, when lifting an object or a part of the body of the person being assisted, the actuator 14 winds up the belt body 13. As a result, tension is generated in the belt body 13.

Due to this tension, a rearward acting force F1 is generated on the first fitting 11. That is, the acting force F1 in the direction of raising the upper body of the user in the forward leaning posture is generated. At the same time, the tension of the second belt 17 produces an acting force F2 that pushes the user's left buttocks and right buttocks forward. Further, a rearward acting force F3 is generated on the second fitting 12. With the acting forces F1, F2, and F3 as described above, it is possible to reduce the muscular load of the back muscles and the quadriceps muscles in the forward bending posture of the user and assist the lifting operation of the luggage.

The assist device 10 functions even when the user changes from an upright posture to a bent posture. For example, when the user lifts an object or a part of the body of the person being assisted. In this case, the actuator 14 sends out the belt body 13 while applying a braking force to the delivery of the belt body 13. That is, the motor 33 rotates in the direction in which the belt body 13 is sent out, but the motor 33 generates torque in the winding direction. As a result, tension is generated in the belt body 13. Even in this case, the assist device 10 assists the lifting motion by reducing the muscular load of the back muscles and the quadriceps muscles in the forward bending posture of the user by the acting forces F1, F2, and F3 as described above. can do.
As described above, according to the assist device 10 of the present disclosure, it is possible to reduce the muscle burden on the lumbar region in the forward bending posture and prevent low back pain.

Further, according to the assist device 10 of the present disclosure, even if the user is in a bent posture with one of the left and right leg BLs in the front and the other in the back (asymmetrical state), the second belt One of the left second belt portion 19 and the right second belt portion 20 (the side where the leg portion protrudes in front) of 17 can be automatically made longer than the other. When the first belt 16 is wound up by the actuator 14 in this state, tension also acts on the second belt 17, and the tension acts on both the left second belt portion 19 and the right second belt portion 20. Tension does not escape. Therefore, as described above, even if the user is in an asymmetrical posture, the assist device 10 of the present disclosure makes it possible to apply an appropriate assist force to the user.

Even when the user maintains the forward leaning posture, the assist device 10 of the present disclosure makes it possible to easily maintain the posture. That is, as shown in the figure on the right side of FIG. 7, the operation of the actuator 14 is stopped in the state where the user is in the first forward leaning posture, and the belt body 13 cannot be sent out. Even if the user tries to take a forward leaning posture (second forward leaning posture), the user takes a second forward leaning posture due to the tension of the belt body 13 connecting the first wearing tool 11 and the second wearing tool 12. Can't. That is, the assist device 10 tries to maintain the user's first forward leaning posture. It becomes easy for the user to maintain the first forward leaning posture. As a result, for example, when the user continues the first forward leaning posture for work for a long time, the burden on the body is reduced.

[About the information stored in the control unit 15]
The information stored in the storage device 15b of the control unit 15 will be described. Correspondence information i1 and conversion information i2 are stored in the storage device 15b.

Correspondence information i1 is information indicating the relationship between the amount of movement of the actuator 14 when the belt body 13 is wound or sent out by changing the posture of the user and the posture parameter indicating the posture of the user. In the present disclosure, the "posture parameter" is, as shown in FIG. 7, the inclination angle θL of the user's upper body with respect to the vertical line. This inclination angle θL is referred to as a posture angle θL. In the following, the posture parameter will be described as the posture angle θL of the user. The attitude parameter may be another parameter, and in addition to the attitude angle θL, it may be an angular velocity in the direction in which the attitude angle θL changes. The angular velocity is obtained by time-differentiating the attitude angle θL. Further, both the attitude angle θL and the angular velocity may be used as the attitude parameters. When the user is in an upright posture, θL = 0.

Correspondence information i1 will be specifically described. As described above, the belt body 13 is wound or sent out by changing the posture of the user, and the rotation angle of the motor 33 is detected by the rotation detector 36 as the amount of movement of the actuator 14 at that time. There is a correlation between the rotation angle θM of the motor 33 and the posture angle θL when the belt body 13 is wound or sent out by changing the posture of the user. Therefore, as shown in FIG. 8, the corresponding information i1 showing the relationship between the rotation angle θM of the motor 33 and the posture angle θL when the belt body 13 is wound or sent out by changing the posture of the user is stored in the storage device 15b. It is remembered in.

The correspondence information i1 may be a function of the rotation angle θM and the posture angle θL instead of the graph format as shown in FIG. 8, or the rotation angle θM and the posture angle θL are associated with each other. It may be a table (database).

The solid line shown in FIG. 8 is the correspondence information i1 when the user has a standard height, and the broken line shown in FIG. 8 is the correspondence information i1 when the height is lower than the standard height. Is the correspondence information i1 when the height is higher than the standard height. As described above, in the present disclosure, the corresponding information i1 is information further set for each height of the user. Correspondence information i1 for each height may be a function obtained by converting a function indicating correspondence information in the case of standard height by using a coefficient or the like, in addition to the format by graph or the format by table.

Correspondence information i1 is information generated in advance. That is, the correspondence information i1 is generated by attaching the assist device 10 to users of various heights, changing the posture angle θL in various ways, and acquiring the rotation angle θM for each posture angle θL.
Although not shown, a rotation detector for detecting the rotation angle of the drive pulley 35 may be provided to detect the rotation angle of the drive pulley 35. In this case, the storage device 15b stores corresponding information indicating the relationship between the rotation angle of the drive pulley 35 and the posture parameter (posture angle θL).

As shown in FIG. 9, the conversion information i2 is information indicating the relationship between the posture parameter (posture angle θL) and the assist force (τa, ref) to be applied to the user. This conversion information i2 is information generated in advance. That is, the conversion information i2 is generated by presetting an assist force that is assumed to be appropriate for each posture angle θL, and associating the posture angle θL with the assist force corresponding to the posture angle θL. The conversion information i2 may also be in a graph format, a table format, or a function, as in the correspondence information i1. In FIG. 9, the conversion information i2 is in the form of a table for ease of explanation. “A, B, C, D” indicating the assisting force in FIG. 9 are predetermined values, respectively. The conversion information i2 may be acquired by other means, or may be an arithmetic program by another algorithm.

As the attitude parameters, the attitude angle θL and the angular velocity in the direction in which the attitude angle θL changes are used, and the conversion information i2 is the attitude parameters (attitude angle θL and the angular velocity) and the assist force (τa, ref). It may be information indicating a relationship. In this case, for example, when the angular velocity is within a predetermined range, the conversion information i2 is set so that the assist force (τa, ref) increases as the posture angle θL increases (in the bending direction). Further, when the posture angle θL is within a predetermined range, the conversion information i2 is set so that the assist force decreases as the angular velocity increases (in the bending direction).

[About each functional unit of the control unit 15]
The functions of the posture estimation unit 42a and the determination unit 42b will be described.
A user wearing the assist device 10 changes his / her posture, and the motor 33 of the actuator 14 rotates about a predetermined angle accordingly. As the amount of movement of the actuator 14, the rotation detector 36 rotates the motor 33 at an angle of θM-. It is assumed that 1 is detected.

When the rotation angle θM-1 of the motor 33 is obtained with the change in the posture of the user, the posture estimation unit 42a uses the posture as a posture parameter based on the rotation angle θM-1 and the corresponding information i1 (see FIG. 8). The angle θL-1 is estimated.

The determination unit 42b obtains the output of the actuator, that is, the output torque of the motor 33 as a physical quantity for operating the actuator 14 based on the posture angle θL-1 obtained by the posture estimation unit 42a. The output torque of the motor 33 is obtained, for example, as follows. When the assist forces τa and ref corresponding to the posture angle θL are obtained from the conversion information i2, the output torque of the motor 33 corresponding to the assist forces τa and ref is obtained. The output torque of the motor 33 is obtained by converting from the assist forces τa and ref. Alternatively, the output torque of the motor 33 may be set in the conversion information i2 in association with the assist forces τa and ref (see FIG. 9) and may be extracted from the conversion information i2.

In the present disclosure, the physical quantity for operating the actuator 14 is the output torque of the motor 33, and the current corresponding to the output torque is given to the motor 33 as a drive current by the control of the control unit 15. The physical quantity may be other than that, and may be a current value given to the motor 33 in order to generate an output torque corresponding to the assist forces τa and ref in the motor 33.

The output torque of the motor 33 corresponding to the assist forces τa and ref may be corrected and obtained. Therefore, the determination unit 42b further has the following functions.
That is, as described above, when the attitude angle θL-1 is obtained as the attitude parameter, the determination unit 42b determines the assist forces τa and ref based on the conversion information i2 (see FIG. 9), and also determines the determined assist forces τa. , Ref is corrected. The correction is performed by the calculation of the following equation (1). That is, the correction is a correction performed by using the determined assist forces τa and ref using the “diameter (radius) rcalc of the drive pulley 35” defined below (see FIG. 10).
"Diameter (radius) of the drive pulley 35": The diameter (radius) of the drive pulley 35 including the belt body 13 (first belt 16) wound around the drive pulley 35.

In the above equation (1), "τM, cmd" is the corrected output torque of the motor 33. “Τa, ref” is a value based on the conversion information i2. “N” is the reduction ratio of the speed reducer unit 34. “Η” is the efficiency of the speed reducer unit 34. “Rcalc” is the “diameter (radius) of the drive pulley 35” and is obtained by the formula (2) described later. The “rinit” in the formula (2) is the radius of the drive pulley 35 including the belt body 13 before the posture of the user is changed. The value of this radius is, for example, a value obtained at the time of the previous change of the posture of the user by the equation (2).

In the above formula (2), "θM" is the rotation angle of the motor 33. The rotation angle θM-1 is obtained by changing the posture of the user. Here, θM = θM-1. “T” is the thickness of the belt body 13 (first belt 16). “N” is the reduction ratio of the speed reducer unit 34. As described above, "rinit" is the radius of the drive pulley 35 including the belt body 13 before the posture of the user is changed.

The correction is performed so that the belt body 13 (first belt 16) has a certain thickness t (see FIG. 10). That is, even when the motor 33 winds the belt body 13 around the drive pulley 35 with the same output, the torque in the drive pulley 35 for generating the assist force changes due to the influence of the thickness t of the belt body 13. Is.
According to the above correction, the belt wound around the drive pulley 35 when the output torque (τM, cmd) of the motor 33 is obtained as the physical quantity for operating the actuator 14 in order to obtain the assist force to be applied to the user. The influence of the thickness t of the body 13 can be eliminated.

As described above, the posture angle θL (θL-1) of the user is estimated based on the rotation angle θM (θM-1) of the motor 33 when the user changes the posture, and the posture angle is estimated. The output torque (τM, cmd) of the motor 33 is obtained based on θL (θL-1). A current corresponding to the output torque (τM, cmd) is given to the motor 33 as a drive current under the control of the control unit 15. When the correction is performed, a current corresponding to the corrected output torque of the motor 33 is given to the motor 33 as a drive current by the control of the control unit 15.

As described above, the control unit 15 obtains the posture angle θL based on the rotation angle θM of the motor when the belt body 13 is wound or sent out by changing the posture of the user. The control unit 15 is configured to control the operation of the actuator 14 (motor 33) based on the obtained posture angle θL in order to apply an assist force to the user.

Further, the physical quantity (output torque of the motor 33 or the current value given to the motor 33) for operating the actuator 14 may be obtained in consideration of the detection result of the sensor 38. That is, as described above, the control unit 15 uses the detection result by the sensor 38 in addition to the amount of movement of the actuator 14 (motor 33) when the belt body 13 is wound or sent out by changing the posture of the user. The operation of the actuator 14 (motor 33) is controlled in order to apply an assist force to the user. The case where the detection result of the sensor 38 is taken into consideration will be described below.

FIG. 11 is a block diagram illustrating a process performed by the control unit 15. As described, the block B1 of FIG. 11 is a process of estimating the posture angle θL of the user using the correspondence information i1 based on the rotation angle θM of the motor 33.

The sensor 38 is a 3-axis acceleration sensor, and detects acceleration (G) in each of the X-axis, Y-axis, and Z-axis directions orthogonal to each other. The direction of the X-axis coincides with one of the left-right directions (right) of the user in the upright posture, the direction of the Y-axis coincides with one of the front-back directions (front) of the user, and the direction of the Z-axis coincides with the use. It coincides with one (upper) in the vertical direction of the person. When the sensor 38 detects the acceleration, the determination unit 42c included in the control unit 15 performs the calculation of the following equation (3) (block B2 in FIG. 11). In the formula (3), AX is the acceleration in the X-axis direction, AY is the acceleration in the Y-axis direction, and AZ is the acceleration in the Z-axis direction.

Further, the determination unit 42c compares the calculation result α of the equation (3) with the threshold values ε1 and ε2 (block B3 in FIG. 11). The threshold value ε1 is smaller than 1 (ε1 <1), and the threshold value ε2 is larger than 1 (ε2> 1). When α is larger than ε1 and smaller than ε2 (ε1 <α <ε2), the posture parameter (posture angle θL) estimated based on the detection result of the sensor 38 (block B4 in FIG. 11) is used.

Here, when α is a value close to 1, it is presumed that the user does not perform any action other than the posture change such as walking even if the posture is changed at that position. When the user is walking, the effect is reflected in the detection result of the sensor 38, and α is larger than, for example, ε2.

When α is larger than ε1 and smaller than ε2, the sensor 38 mainly detects the component due to gravity. Therefore, the determination unit 42c adopts the posture angle θL of the user obtained by the calculation (block B4 in FIG. 11) by the following equation (4) based on the detection result of the sensor 38. That is, when α is larger than ε1 and smaller than ε2, it is appropriate that the attitude angle θL is estimated by the sensor 38. Therefore, the posture angle θL calculated by the following equation (4) is stored in the storage device 15b as θLtemp.

On the other hand, when ε1 <α <ε2 is not satisfied, that is, when α is ε1 or less, or α is ε2 or more, the rotation angle θM of the motor 33, which is obtained in the block B1, is set. The attitude angle θL estimated based on this is adopted. If ε1 <α <ε2 is not satisfied, it can be said that it is not appropriate for the sensor 38 to estimate the attitude angle θL. Therefore, the posture angle θL estimated based on the rotation angle θM is stored in the storage device 15b as θLtemp.

As described above, the sensor 38 detects the acceleration (G) every moment. Therefore, the posture angle θLtemp obtained in the past and the posture angle θLtemp obtained this time are stored in the storage device 15b. The posture angle θLtemp obtained this time is defined as “posture angle θL (N)”, and the posture angle θLtemp obtained in the past (one before this time, that is, the previous time) is defined as “posture angle θL (N-1)”. .. The determination unit 42c obtains the difference ΔθL between the posture angle θL (N) and the posture angle θL (N-1) as in the following equation (5).

The determination unit 42c further compares the absolute value of the difference ΔθL with the threshold value ε3. When the absolute value of ΔθL is equal to or less than the threshold value ε3, the posture angle θLtemp obtained this time, “posture angle θL (N)”, is determined as the posture angle of the current user.
On the other hand, when the absolute value of ΔθL exceeds the threshold value ε3, the determination unit 42c performs the calculation according to the following equation (6). The "θL (N)" obtained from the result of the calculation is determined as the posture angle of the current user.

As described above, the significance of using the difference ΔθL between the current posture angle θL (N) and the past posture angle θL (N-1) by the determination unit 42c is as follows. That is, if the difference ΔθL is not taken into consideration, for example, when the calculation result α according to the equation (3) changes from a state in which ε1 <α <ε2 is satisfied to a state in which ε1 <α <ε2 is not satisfied, the posture angle is changed. It may be determined that a large change has occurred momentarily. In this case, the assist force generated by the assist device 10 may change suddenly, that is, the rotational torque of the motor 33 may change suddenly, giving the user a sense of discomfort. However, in the present disclosure, when the absolute value of the difference ΔθL between the current posture angle θL (N) and the past posture angle θL (N-1) exceeds the threshold value ε3, it has been described by the above equation (6). As described above, the posture angle θL (N) of the current user is determined based on the posture angle θL (N-1) and the change amount ΔθL of the posture angle, which are the past results. Therefore, it is possible to prevent the assist force from suddenly changing, and it is possible to prevent the user from feeling uncomfortable.

As described above, the output torque (τM, cmd) of the motor 33 is obtained based on the posture angle θL (N) of the current user determined as described above. A current corresponding to the output torque (τM, cmd) is given to the motor 33 as a drive current under the control of the control unit 15. Further, the output torque may be corrected as described above.
The operation mode of the assist device 10 may be selected or changed based on the current user posture angle θL (N) determined as described above.

As described above, the control unit 15 included in the assist device 10 of the present disclosure performs the first estimation process of estimating the posture angle θL of the user based on the rotation angle θM of the motor 33 obtained by the rotation detector 36. It has a function to perform the function and a function to perform a second estimation process for estimating the posture angle θL of the user based on the output of the sensor 38. Then, the posture estimation unit 42a of the control unit 15 obtains the posture angle θL as the posture parameter by using the processing result of either the first estimation process or the second estimation process.

Here, the significance of the control unit 15 having a function of executing not only the first estimation process but also the second estimation process will be described. FIG. 12 is an explanatory view showing a posture in which the user leans forward with the upper body tilted forward and a posture in which the user sits with the knees bent while the upper body is along the vertical line. .. Comparing the case where the user is in a forward leaning posture as shown on the left side of FIG. 12 and the case where the user is sitting with his knees bent as shown on the right side of FIG. 12, the upper body with respect to the thighs. The bending angle θ of is the same. Therefore, according to the first estimation process, since the feeding amount of the belt body 13 is the same, the rotation angle θM of the motor 33 is the same, and the posture angle θL cannot be distinguished.

On the other hand, according to the second estimation process, the inclination angle of the upper body of the user with respect to the vertical line is calculated based on the acceleration of each axis of XYZ by the sensor 38. Therefore, the value of the inclination angle of the upper body obtained based on the acceleration of each axis of XYZ by the sensor 38 is the case of the forward leaning posture shown on the left side of FIG. 12 and the sitting position shown on the right side of FIG. It depends on the case. That is, according to the second estimation process, the user is in a forward leaning posture with the upper body leaning forward, or the user is sitting along the vertical line with respect to the upper body, but with the knees bent. It is possible to determine whether the person is in a posture.

When the user is determined to be in the forward leaning posture with the upper body leaning forward, the user is changing the posture from the forward leaning posture to the upright posture in order to lift the cargo, or The determination unit 42c can estimate the operation mode in which the posture is changed from the upright posture to the forward leaning posture in order to lift the cargo. In this case, the assist device 10 operates the actuator 14 to generate an assist force for lifting or lowering the load.
In addition, although the upper body is along the vertical line, the user is determined to be in a sitting posture with his knees bent, so that the user is sitting and working. The determination unit 42c can be estimated. In this case, for example, the assist device 10 does not generate an assist force. If an assist force similar to that in the case of lifting luggage is generated in this sitting and working posture, the user will be pulled backward and lose the balance.

[About the assist device 10 of the present disclosure]
As described above, the assist device 10 of the present disclosure (see FIG. 2) is attached to the first attachment 11 attached to the shoulder BS of the user and the left and right leg BLs of the user, respectively. (Ii) A mounting tool 12, a belt body 13, and an actuator 14 are provided. The belt body 13 is provided along the back side of the user over the first wearing tool 11 and the second wearing tool 12. The actuator 14 is provided on the first attachment 11 and is configured to enable winding and feeding of a part of the belt body 13.

The belt body 13 connects the first belt 16 that is wound and sent out by the actuator 14, the second belt 17 that is attached to the second fitting 12, and the first belt 16 and the second belt 17. It has a connecting member 18.

According to the assist device 10, the belt body 13 is provided along the back side of the user over the first wearing tool 11 and the second wearing tool 12. When the actuator 14 winds up the belt body 13 (first belt 16), tension acts on the first belt 16 and the second belt 17. The tension creates an assisting force that assists the user's work, reducing the physical burden on the user.

For example, when the user (assistant) changes from a forward leaning posture to an upright posture while supporting the load (assisted person) by hand (see FIG. 7), the actuator 14 winds up the belt body 13 to wind the belt. Tension acts on the body 13. Due to the tension, the user tends to change from a forward leaning posture to an upright posture, and the burden on the user's body is reduced. That is, the tension acting on the belt body 13 by the actuator 14 is generated as an assist force.

In the assist device 10 of the present disclosure, the actuator 14 enables a part of the belt body 13 to be wound and sent out in response to a change in the posture of the user. The control of the actuator 14 is executed by the control unit 15. The control unit 15 sets a posture parameter indicating the posture of the user based on the amount of movement of the actuator 14 (that is, the rotation angle of the motor 33) when the belt body 13 is wound or sent out by changing the posture of the user. Ask. Then, the control unit 15 controls the operation of the motor 33 based on the posture parameter in order to apply an assist force to the user.

According to the assist device 10 having the above configuration, when the user changes the posture, the belt body 13 is wound or sent out by the change, and at this time, the motor 33 rotates. There is a correlation between the change (change) in the posture of the user and the rotation angle of the motor 33. Therefore, the posture parameter is obtained based on the rotation angle, and the operation of the motor 33 is controlled based on the posture parameter in order to apply the assist force to the user. As a result, it is possible to generate an assist force according to the posture of the user.

As shown in FIG. 8, the storage device 15b of the control unit 15 has a rotation angle θM of the motor 33 when the belt body 13 is wound or sent out by changing the posture of the user, and a posture parameter (posture angle θL). Correspondence information i1 indicating the relationship between the above is stored. When the posture estimation unit 42a of the control unit 15 obtains the rotation angle θM of the motor 33 with the change in the posture of the user, the posture estimation unit 42a estimates the posture parameter (posture angle θL) based on the rotation angle θM and the corresponding information i1. To do. Based on the estimated posture parameter (posture angle θL), the determination unit 42b of the control unit 15 obtains the output torque of the motor 33 or the current value supplied to the motor 33 as a physical quantity for operating the motor 33.

According to the above configuration, when the user changes the posture to a predetermined posture and the rotation angle θM of the motor 33 at the time of the change in the posture is obtained, the posture parameter (posture) is obtained based on the corresponding information i1. The angle θL) is obtained. The posture parameter (posture angle θL) indicates the posture of the user. Based on the obtained posture parameter (posture angle θL), the physical quantity for operating the motor 33 according to the posture parameter (posture of the user) is determined. As a result, the assist device 10 can generate an assist force having an appropriate strength according to the posture of the user.

If the height of the user is different, the rotation angle of the motor 33 may be different even if the change in posture is the same. However, in the present disclosure, the correspondence information i1 is information set for each height of the user as shown in FIG. Therefore, the posture parameter (posture angle θL) can be obtained even if the heights of the users are different.

The belt body 13 (first belt 16) has a certain thickness t. Even when the motor 33 winds the belt body 13 around the drive pulley 35 with the same output, the torque in the drive pulley 35 for generating an assist force due to the influence of the thickness t of the belt body 13 (first belt 16). May change.

Therefore, in the present disclosure, the determination unit 42b of the control unit 15 determines the assist force based on the conversion information i2 when the attitude parameter (posture angle θL) is estimated, and the determined assist force is expressed by the above equation. Correct according to (1). The correction is performed using the diameter rcalc (see FIG. 10) of the drive pulley 35 including the belt body 13 in the wound state. By performing the correction, the influence of the thickness t of the belt body 13 wound around the drive pulley 35 is eliminated.

Further, in the assist device 10 of the present disclosure, the control unit 15 detects by the sensor 38 (posture detector) in addition to the rotation angle of the motor 33 when the belt body 13 is wound or sent out by changing the posture of the user. The result is also used to control the operation of the motor 33 in order to give the user an assist force.

That is, the control unit 15 has a posture estimation unit 42a that estimates the posture angle θL as a posture parameter indicating the posture of the user. The posture estimation unit 42a defines the first estimation below based on the output of the sensor 38 including the acceleration sensor, that is, based on the comparison result between the result of the above equation (3) and the threshold value (ε1, ε2). The attitude angle θL is estimated by using the processing result of either the processing or the second estimation processing defined below.
The first estimation process: the estimation process performed based on the rotation angle of the motor 33 when the belt body 13 is wound or sent out by changing the posture of the user. The second estimation process: based on the output of the sensor 38 including the acceleration sensor. Estimate processing to be performed

The control unit 15 further includes a determination unit 42b that obtains a physical quantity for operating the actuator 14 based on the estimated posture angle θL. The physical quantity is, for example, the output torque of the motor 33 or the current value given to the motor 33.

According to this configuration, when it is appropriate for the sensor 38 to estimate the attitude angle θL, that is, when α based on the equation (3) is larger than ε1 and smaller than ε2, the second estimation process is performed. Be struck. When it is not appropriate for the sensor 38 to estimate the attitude angle θL, that is, when the α is ε1 or less, or when α is ε2 or more, the first estimation process based on the rotation angle of the motor 33 Is done. The accuracy of estimating the posture of the user is increased, and the assist device 10 can generate an assist force having an appropriate strength according to the posture of the user.
Further, since the operation intention of the user, that is, the work mode can be estimated, it is possible to impart an appropriate assist force without hindering the operation of the user.

Further, in the present disclosure, as described above, in order to estimate the posture angle θL, one of the processing results of the first estimation processing and the second estimation processing is used. Therefore, the estimated posture angle θL may be significantly different between the previous time and the current time. As a result, the physical quantity for operating the actuator 14 may change significantly, which may give the user a sense of discomfort.

Therefore, in the assist device of the present disclosure, the posture estimation unit 42a repeatedly estimates the posture angle θL. When the amount of change in the posture angle θL (absolute value of the difference ΔθL) exceeds the threshold value (ε3), the amount of change in the posture angle θL (N-1) estimated in the past and the amount of change in the posture angle θL (the difference ΔθL) ), And a new attitude angle θL (N) is obtained.
In this case, even if the posture angle θL estimated by the posture estimation unit 42a is significantly different between the previous time and the current time, the posture angle θL (N-1) estimated in the past and the difference ΔθL are used as the basis. A new attitude angle θL (N) is required. Therefore, it is possible to prevent the physical quantity for operating the actuator 14 from changing significantly. Therefore, the user does not feel uncomfortable.

The following <means 1> or <means 2> can be adopted for estimating the posture angle θL.
<Means 1> First, it is determined whether or not the posture angle θL is estimated by the sensor 38, and then the first estimation process and the second estimation process are performed according to the result of the determination. One of the processes is performed, and the result of one of the processes is used.
<Means 2> First, the first estimation process and the second estimation process are executed, and then it is determined whether or not the posture angle θL is estimated by the sensor 38, and the result of the determination is determined. Accordingly, the processing result of one of the first estimation processing and the second estimation processing is used.

[Other assist device 10]
In the assist device 10 of the above disclosure, the second attachment tool 12 is attached to the leg BL of the user. As shown in FIG. 13, the second attachment 12 may be attached to the lumbar region BW of the user. In this case, the second attachment 12 may be in the shape of a waist belt or in the shape of pants. When the second attachment 12 is attached to the lumbar region BW, the actuator 14 may be attached to the first attachment 11, or may be attached to the second attachment 12. In this case, the sensor 38 for detecting the posture of the user may be provided on the second attachment 12. In FIG. 13, the actuator 14 is attached to the first fitting 11.

Also in the case of the assist device 10 shown in FIG. 13, the belt body 13 is provided along the back side of the user over the first wearing tool 11 and the second wearing tool 12. When the actuator 14 winds up the belt body 13, tension acts on the belt body 13. The tension creates an assisting force that assists the user's work, reducing the physical burden on the user.

[Other]
In order to prevent / prevent low back pain of the user, it is preferable that the second attachment 12 is attached to the leg BL. This is because the load on the lumbar BW is reduced by attaching the second attachment 12 to the leg BL.
In each form of the assist device 10, the belt body 13 is lightweight, can follow the body even if the user changes his / her posture, and follows the movement of the user. Therefore, the assist device 10 having a good fit can be obtained.
In the above disclosure, the control box 30 is provided on the rear side (back side) of the user in the first attachment 11, but may be provided on the front side of the user. In this case, the belt body 13 is provided along the back surface of the user via the shoulder BS of the user.

The linear form of the belt body 13 may be other than the illustrated form. For example, although not shown, the first mounting portion 27 of the connecting member 18 is also provided with a rotary pulley in the same manner as the second mounting portion 28, and the first belt 16 is folded back in the middle of the rotary pulley. It may be hung on. In this case, the end of the first belt 16 (opposite the drive pulley 35 side) is attached to the first fitting 11 (base 31).
Alternatively, although not shown, a rotary pulley may be attached to the second fitting 12, and the second belt 17 may be hung on the rotary pulley in a state of being folded back in the middle. In this case, both ends of the second belt 17 are attached to the attachments (third attachments) attached to the lumbar region BW.

The embodiments disclosed this time are exemplary in all respects and are not restrictive. The scope of rights of the present invention is not limited to the above-described embodiment, and includes all modifications within a range equivalent to the configuration described in the claims.

10: Assist device 11: First mounting tool 12: Second mounting tool 13: Belt body 14: Actuator 15: Control unit 15b: Storage device (storage unit) 33: Motor 35: Drive pulley (pulley)
38: Sensor 42a: Posture estimation unit 42b: Determination unit

Claims (3)

The first attachment to be worn on at least one of the user's shoulders and chest,
The second attachment to be attached to each of the left and right legs or the waist of the user,
A belt body provided along the back side of the user across the first wearing tool and the second wearing tool, and
An actuator provided on the first attachment or the second attachment and capable of winding and feeding a part of the belt body.
A control unit that executes operation control of the actuator and
A sensor provided on the first attachment or the second attachment and outputting a signal according to the posture of the user.
With
The control unit is an assist device that uses the output of the sensor to execute operation control of the actuator in order to apply an assist force to the user. The control unit
A posture estimation unit that estimates posture parameters that indicate the user's posture, and
It has a determination unit for obtaining a physical quantity for operating the actuator based on the estimated posture parameter.
Based on the output of the sensor, the posture estimation unit estimates the posture parameter using the processing result of either the first estimation process defined below or the second estimation process defined below. The assist device according to claim 1.
The first estimation process: the estimation process performed based on the amount of movement of the actuator when the belt body is wound or sent out by changing the posture of the user. The second estimation process: the estimation process performed based on the output of the sensor. The posture estimation unit repeatedly executes the estimation of the posture parameters, and then repeatedly executes the estimation.
The assist device according to claim 2, wherein when the change amount of the posture parameter exceeds the threshold value, a new posture parameter is obtained based on the posture parameter estimated in the past and the change amount.

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