JP2023007151A - Auxiliary apparatus for assisting flexion exercise of human body - Google Patents

Abstract

To provide an auxiliary apparatus capable of effectively assisting flexion exercise of a human boy that has been required.SOLUTION: An auxiliary apparatus comprises: arms 18 and 20; a link part 62 with one end 62a thereof rotatably connected to the arm 18 and the other end 62b thereof rotatably connected to the arm 20, the link part 62 bendably connecting the arms 18 and 20 between an extended position and a bent position; a lever part 64 integrally formed on one end 62a so as to extend from the one end 62a in a direction crossing a rotary shaft for the arm 18 at the one end 62a, the lever part 64 relatively rotating around the rotary shaft to a second relative position from a first relative position relative to the arm 18 when the arms 18 and 20 move to the bent position from the extended position; and an energization part 24 provided in the arm 18, and energizing the lever part 64 toward the first relative position when the lever part 64 is arranged in the second relative position.SELECTED DRAWING: Figure 2

Description

The present disclosure relates to assistive devices that assist bending and stretching exercises of the human body.

Auxiliary equipment that assists bending and stretching movements of the human body is known (for example, Patent Document 1).

JP 2011-120936 A

For example, when a person stretches their thighs and shins to stand up from a squatting position, a large load is applied to their knee joints. Conventionally, there has been a demand for an assistive device that can effectively assist such stretching movements of the human body.

In one aspect of the present disclosure, the auxiliary equipment for assisting bending and stretching exercises of a first part and a second part of the human body connected via a joint includes a first arm attached to the first part, and a first arm attached to the first part. and a link portion having one end rotatably connected to the first arm and the other end rotatably connected to the second arm. and a link part that connects the arm and the second arm so as to be able to bend and stretch between the extended position and the bent position, (2) a lever portion integrally formed at the one end, wherein when the first arm and the second arm move from the extended position to the bent position, the lever portion moves from the first relative position to the first arm with respect to the first arm; a lever provided on the first arm for relatively rotating around the rotation shaft to two relative positions, and moving the lever to the first relative position when the lever is disposed at the second relative position; and a biasing portion that biases toward the position.

According to the present disclosure, it is possible to effectively assist the extension motion of the first and second parts of the body by the action of the urging part.

1 illustrates an assistive device according to one embodiment; 2 shows the mechanism shown in FIG. 1; Figure 3 shows the first arm shown in Figure 2; Figure 3 shows the second arm shown in Figure 2; Figure 3 shows the link member shown in Figure 2; 6 is an enlarged view showing the back side of the link member shown in FIG. 5; FIG. 2 shows the assistive device when the human body shifts from the upright posture shown in FIG. 1 to the squatting posture. 4 shows a mechanism section according to another embodiment. 9 shows a sectional view along IX-IX in FIG. 8. FIG. 3 shows a mechanism section according to still another embodiment. FIG. 11 shows a state in which the mechanism portion shown in FIG. 10 is arranged at the bent position.

Hereinafter, embodiments of the present disclosure will be described in detail based on the drawings. In addition, in various embodiments described below, the same reference numerals are given to the same elements, and redundant descriptions are omitted. First, with reference to FIG. 1, an assistive device 10 according to one embodiment will be described. In the following description, the orthogonal coordinate system C in the drawing is used as a reference for directions, and for convenience, the x-axis positive direction of the coordinate system C is forward, the y-axis positive direction of the coordinate system C is left, and the z-axis positive direction is referred to as above.

The auxiliary equipment 10 is for assisting the bending and stretching motion of the thigh B1 and the shin B2 of the human body B (that is, the knee bending and stretching motion). The thigh B1 and the shin B2 are connected via the knee joint B3, and the human body B flexes and extends the thigh B1 and the shin B2 at the knee joint B3, thereby bending and stretching the knee. exercise.

The assistive device 10 includes a mechanical portion 12 and attachment bands 14 and 16 . Each of the mounting bands 14 and 16 is made of, for example, natural or chemical fiber cloth, rubber, resin, or a combination thereof, and has high flexibility and stretchability so as to fit the human body B. As shown in FIG. In this embodiment, the mounting band 14 is wrapped around the shin B2 and worn, while the mounting band 16 is worn around the thigh B1.

Mechanism 12 is disposed between mounting bands 14 and 16 . The mechanism section 12 will be described below with reference to FIGS. 2 to 6. FIG. The mechanism section 12 has arms 18 and 20 , a link member 22 and an urging section 24 . The arm 18 is attached to the mounting band 14 and attached to the shin B2 via the mounting band 14 .

Referring to FIG. 3, the arm 18 is an integral flat plate member made of metal such as aluminum, and has a body portion 26, a gear portion 28, an extension portion 30, an accommodation hole 32, and a positioning shaft 33. . The body portion 26 has an upper end portion 34 and a lower end portion 36 opposite the upper end portion 34 and extends from the upper end portion 34 to the lower end portion 36 along the axis A1.

More specifically, the main body 26 has a rectangular first portion 38 extending straight along the axis A1 and a fan-shaped second portion extending upward from the upper end of the first portion 38. 40. First portion 38 defines lower end 36 while second portion 40 defines upper end 34 . The first portion 38 is attached to the mounting band 14 (FIG. 1). The second portion 40 widens upward from the upper end of the first portion 38 .

A shaft 42 is provided at the upper end 34 . The shaft 42 has, for example, a cylindrical shape and is formed integrally with the upper end portion 34 so as to extend rightward from the upper end portion 34 . The upper end portion 34 also has an arc-shaped outer peripheral surface 44 . The outer peripheral surface 44 is arranged substantially coaxially with the shaft 42 .

The gear portion 28 has a predetermined diameter R<b>1 (for example, pitch diameter) and is formed integrally with the upper end portion 34 . More specifically, the gear portion 28 has a plurality of tooth portions 28 a aligned in the circumferential direction of the outer peripheral surface 44 of the upper end portion 34 . Each tooth portion 28 a is formed integrally with the outer peripheral surface 44 so as to protrude radially outward from the outer peripheral surface 44 .

The extension portion 30 is formed integrally with the upper end portion 34 of the body portion 26 so as to extend outward from the upper end portion 34 . More specifically, extension 30 is positioned adjacent the front side of gear portion 28 at upper end 34 and extends straight from upper end 34 along axis A2. The axis A2 is inclined at an angle θ1 with respect to the axis A1 of the body portion 26 . In this embodiment, the angle θ1 is an acute angle (eg θ1=10° to 60°).

A receiving hole 32 is formed in the extension 30 . More specifically, the accommodation hole 32 is a rectangular hole that extends straight along the axis A2 and penetrates the extension 30 in the front-rear direction. The positioning shaft 33 is arranged inside the accommodation hole 32 . Specifically, the positioning shaft 33 has its upper end integrally fixed to the inner surface 32a of the extension portion 30 defining the receiving hole 32, while its lower end is free. extends straight along the

The biasing portion 24 is housed inside the housing hole 32 . In this embodiment, the biasing portion 24 is a coil spring and is housed in the housing hole 32 so as to expand and contract in the direction of the axis A2. More specifically, the urging portion 24 is fitted into the positioning shaft 33 so that the positioning shaft 33 is inserted thereinto, and thus is positioned inside the housing hole 32 so as to be substantially coaxial with the axis A2. positioned.

The biasing portion 24 has a first end 24a that contacts the inner surface 32a of the extension portion 30 and a second end 24b that is opposite to the first end 24a. A second end 24b of the biasing portion 24 is a free end that can be displaced in the direction of the axis A2. This allows the biasing portion 24 to expand and contract in the direction of the axis A2. Note that the first end 24a of the biasing portion 24 may be fixed to the inner surface 32a.

Referring to FIG. 4, the arm 20 is an integral flat plate member made of metal such as aluminum, and has a body portion 50 and a gear portion 52 . The body portion 50 has an upper end portion 54 and a lower end portion 56 opposite to the upper end portion 54 and extends straight from the upper end portion 54 to the lower end portion 56 along the axis A3.

A shaft 58 is provided at the lower end portion 56 . The shaft 58 has, for example, a columnar shape and is formed integrally with the lower end portion 56 so as to extend rightward from the lower end portion 56 . The lower end portion 56 also has an arc-shaped outer peripheral surface 60 . The outer peripheral surface 60 is arranged substantially coaxially with the shaft 58 .

The gear portion 52 has a predetermined diameter R<b>2 (for example, pitch diameter) and is formed integrally with the lower end portion 56 . More specifically, the gear portion 52 has a plurality of tooth portions 52 a aligned in the circumferential direction of the outer peripheral surface 60 of the lower end portion 56 . Each tooth portion 52 a is formed integrally with the outer peripheral surface 60 so as to protrude radially outward from the outer peripheral surface 60 .

Teeth 52a engage teeth 28a of gear portion 28 (FIG. 3). In this embodiment, the diameter R2 of the gear portion 52 is different from the diameter R1 of the gear portion 28 . More specifically, the diameter R2 of the gear portion 52 is smaller than the diameter R1 of the gear portion 28 (R2<R1), and the ratio between the diameter R2 and the diameter R1 is set to, for example, R2:R1=12:17. be done.

Referring to FIG. 5 , link member 22 is an integral flat plate member and has link portion 62 and lever portion 64 . The link portion 62 extends straight along the axis A4, its lower end portion 62a is rotatably connected to the arm 18, and its upper end portion 62b is rotatably connected to the arm 20. As shown in FIG. More specifically, a through hole 66 is formed in the lower end portion 62 a of the link portion 62 , and a through hole 68 is formed in the upper end portion 62 b of the link portion 62 .

The shaft 42 of the arm 18 is rotatably inserted through the through hole 66 of the link portion 62 , and fasteners (not shown) such as bolts are fastened to the shaft 42 . Thereby, the upper end portion 34 of the arm 18 is connected to the lower end portion 62a of the link portion 62 so as to be relatively rotatable about the rotation axis A6 (that is, the central axis of the shaft 42). .

On the other hand, the shaft 58 of the arm 20 is rotatably inserted through the through hole 68 of the link portion 62, and fasteners (not shown) such as bolts are fastened to the shaft 58. As shown in FIG. Thereby, the lower end portion 56 of the arm 20 is connected to the upper end portion 62b of the link portion 62 so as to be relatively rotatable around the rotation axis A7 (that is, the central axis of the shaft 58).

The lever portion 64 is formed integrally with the lower end portion 62a of the link portion 62 so as to extend from the lower end portion 62a along the axis A5. The axis A5 is inclined at an angle θ2 with respect to the axis A4 and intersects (specifically, orthogonally) with the rotation axis A6 of the lower end portion 62a with respect to the arm 18 . In this embodiment, the angle θ2 is an acute angle (eg θ2=30° to 80°).

The lever portion 64 has a curved side surface 64a. The side surface 64a curves and extends from its proximal end toward its distal end so as to bulge outward. The side surface 64a may be an arcuate surface having a predetermined radius of curvature, or may be a combination of arcuate surfaces each having multiple radii of curvature.

A stopper 70 is integrally formed at the tip of the lever portion 64 . Specifically, as shown in FIG. 6, the stopper 70 extends from the distal end of the lever portion 64 toward the proximal end at a position spaced apart on the left side of the lever portion 64, and has an engaging surface 70a at the distal end thereof. have. When the arm 18 and link member 22 are assembled, as shown in FIG. It is arranged between it and the stopper 70 .

Next, functions of the assistive device 10 will be described. FIG. 1 shows an upright posture in which the thigh B1 and the shin B2 are extended and the thigh B1 and the shin B2 stand upright. In this upright position the arms 18 and 20 are in the extended position P1 shown in FIGS. When arranged at the extended position P1, the axis A1 of the arm 18, the axis A3 of the arm 20, and the axis A4 of the link portion 62 are substantially parallel to each other. Further, the lever portion 64 is arranged at the first relative position RP1 with respect to the arm 18, and the side surface 64a of the lever portion 64 contacts the second end 24b of the biasing portion 24. As shown in FIG. At this time, the biasing portion 24 is maintained in the expanded state. In addition, in the upright posture shown in FIG. 1, the body B faces forward.

On the other hand, FIG. 7 shows a squatting posture in which the thigh B1 and the shin B2 are bent at the knee joint B3. In FIG. 7, the attachment bands 14 and 16 are indicated by dotted lines for easy understanding. In the crouching posture shown in FIG. 7, the arms 18 and 20 are arranged in the bent position P2. When placed in the bent position P2, axis A1 of arm 18, axis A2 of arm 20, and axis A4 of link portion 62 are non-parallel to each other, and axes A1 and A3 form an acute angle. Also, the lever portion 64 is arranged at the second relative position RP2 with respect to the arm 18 .

As the body B shifts from the upright posture shown in FIG. 1 to the crouching posture shown in FIG. While the arm 18 rotates relative to the link portion 62, the arm 18 rotates clockwise relative to the link portion 62 around the rotation axis A6 (shaft 42) when viewed from the right side. As a result, the arms 18 and 20 bend from the extended position P1 to the bent position P2.

This bending motion of the arms 18 and 20 is guided by the engagement between the gear portion 28 of the arm 18 and the gear portion 52 of the arm 20, and the link portion 62 connecting the arms 18 and 20 so as to be able to rotate relative to each other. As a result, during the bending motion of the arms 18 and 20, the lower end portion 56 of the arm 20 revolves counterclockwise when viewed from the right side around the rotation axis A6 (shaft 42) arranged on the arm 18. So, you will be guided.

On the other hand, as the arms 18 and 20 bend from the extended position P1 to the bent position P2, the lever part 64 moves from the first relative position RP1 to the second relative position RP2 with respect to the arm 18 along the rotation axis A6 (shaft 42) in a counterclockwise direction when viewed from the right side. As the lever portion 64 rotates relative to the arm 18 in this manner, the side surface 64a of the lever portion 64 slides against the second end 24b of the biasing portion 24 and moves the second end 24b along the axis A2. in the first direction D1 (FIGS. 2 and 7). As a result, the second end 24b of the biasing portion 24 is displaced in the first direction D1 inside the accommodation hole 32, and the biasing portion 24 is compressed in the first direction D1.

In this way, when the lever portion 64 is placed at the second relative position RP2 with respect to the arm 18, the biasing portion 24 is compressed by the lever portion 64, and the side surface 64a of the lever portion 64 is compressed as a reaction force. , a force is applied in a second direction D2 opposite to the first direction D1. Thus, the biasing portion 24 biases the lever portion 64 toward the first relative position RP1.

Further, when the lever portion 64 is arranged at the second relative position RP2, the engaging surface 70a of the stopper 70 provided at the tip of the lever portion 64 engages with the biasing portion 24. As shown in FIG. The engagement of the stopper 70 with the urging portion 24 restricts the link member 22 from further rotating relative to the arm 18, thereby restricting the arms 18 and 20 from further bending. . As a result, it is possible to prevent the gear portion 52 from falling off from the gear portion 28 .

At least one of the side surface 64a of the lever portion 64 and the second end 24b of the biasing portion 24 may have a sliding material (for example, resin) with a low friction coefficient at a location where the other abuts. According to this configuration, when the arms 18 and 20 are bent to the bending position P2, the side surface 64a of the lever portion 64 can slide more smoothly with respect to the second end 24b.

Further, while the arms 18 and 20 move from the extended position P1 to the bent position P2, the side surface 64a slides and abuts against the second end 24b of the biasing portion 24. The curved shape of the side surface 64a may be determined such that the tangential direction of the side surface 64a at the contact position is substantially parallel to the axis A2.

With this configuration, the side surface 64a can exert a force on the second end 24b in the first direction D1 at all times while the arms 18 and 20 move from the extended position P1 to the bent position P2. Thereby, the biasing portion 24 can be compressed in the first direction D1 without being inclined or shifted with respect to the axis A2. On the other hand, the biasing portion 24 can apply force to the side surface 64a of the lever portion 64 in the second direction D2 parallel to the tangential direction of the side surface 64a. It can be effectively biased toward position RP1.

On the contrary, when the body B shifts from the squatting position shown in FIG. 7 to the upright position shown in FIG. While moving, the arm 18 rotates relative to the link portion 62 about the rotation axis A6 in the counterclockwise direction when viewed from the right side. As a result, the arms 18 and 20 extend from the flexed position P2 to the extended position P1.

This extension movement of the arms 18 and 20 is guided by the engagement of the gear portions 28 and 52 and the link portion 62 . As a result, during the extension motion of the arms 18 and 20, the lower end 56 of the arm 20 is guided to revolve around the pivot axis A6 arranged on the arm 18 clockwise when viewed from the right side. be.

Thus, the link portion 62 connects the arms 18 and 20 so that they can bend and stretch between the extended position P1 and the bent position P2, and the gear portions 28 and 52 move the arms 18 and 20 together with the link portion 62. invite. Accordingly, the gear portions 28 and 52 together with the link portion 62 constitute a guide mechanism 72 that guides the bending and stretching motions of the arms 18 and 20 .

As the arms 18 and 20 extend from the flexed position P2 to the extended position P1, the lever portion 64 moves relative to the arm 18 from the second relative position RP2 to the first relative position RP1 about pivot axis A6 to the right. relative rotation in the clockwise direction when viewed from above. Here, in the present embodiment, as described above, the biasing portion 24 applies a force that biases the lever portion 64 arranged at the second relative position RP2 toward the first relative position RP1. are adding.

The biasing portion 24 biases the link member 22 by applying force to the lever portion 64 so as to relatively rotate the link member 22 in the clockwise direction when viewed from the right side around the rotation axis A6. , the lower end portion 56 of the arm 20 is urged to revolve clockwise around the rotation axis A6 as viewed from the right side.

The action of the urging portion 24 assists the body B to stand up from the squatting posture to the upright posture, and as a result, the body B can stand up more easily. The body B then transitions to the upright posture shown in FIG. 1, and the arms 18 and 20 return to the extended position P1.

As described above, in the present embodiment, the assistive device 10 includes the arms 18 and 20, the link portion 62, the lever portion 64, and the biasing portion 24 so that the body B can stand up more easily. In addition, it is possible to effectively assist the extension motion of the thigh B1 and the shin B2.

In this embodiment, the auxiliary device 10 also includes a guide mechanism 72 that guides the bending and stretching motions of the arms 18 and 20 between the extended position P1 and the bent position P2 together with the link portion 62 . According to this configuration, the reproducibility of the bending and stretching motions of the arms 18 and 20 is enhanced, so that the auxiliary equipment 10 can stably assist the bending and stretching motions of the thigh B1 and the shin B2.

Further, in this embodiment, the guide mechanism 72 has gear portions 28 and 52 . With this configuration, the revolving motion of the lower end portion 56 of the arm 20 around the rotation axis A6 can be stably guided, so that the bending and stretching motions of the arms 18 and 20 can be guided more effectively. can be done.

Also, in this embodiment, the arm 18 has a body portion 26 , an extension portion 30 and a receiving hole 32 . With this configuration, the link member 22 (that is, the link portion 62 and the lever portion 64) and the biasing portion 24 can be arranged more compactly with respect to the arm 18, so that the structure of the mechanism portion 12 can be made more compact. can be done.

Further, in this embodiment, the extension portion 30 and the accommodation hole 32 extend along the axis A2, and the biasing portion 24 is a coil spring accommodated in the accommodation hole 32 so as to expand and contract in the direction of the axis A2. have. The biasing portion 24 (coil spring) is compressed in the first direction D1 of the axis A2 when the lever portion 64 is relatively rotated from the first relative position RP1 to the second relative position RP2, and the reaction force thereof is , a force is applied to the lever portion 64 in the second direction D2 to bias it toward the first relative position RP1. According to this configuration, the biasing portion 24 can effectively bias the lever portion 64 toward the first relative position RP1 by means of a member having a simple structure such as a coil spring.

In addition, in the above-mentioned embodiment, the case where the guide mechanism 72 was comprised from the gear parts 28 and 52 was described. However, various forms are conceivable as the guide mechanism. A guide mechanism 74 according to another embodiment will be described below with reference to FIGS. 8 and 9. FIG.

The mechanism portion 12' shown in FIGS. 8 and 9 has a guide mechanism 74, which is a rail portion 76 formed on the arm 18' and a joint for movably connecting the arms 18' and 20'. a member 78; The rail portion 76 is formed on the outer peripheral surface 44 of the upper end portion 34 of the arm 18'. As shown in FIG. 9 , the rail portion 76 has a T-shaped cross section and extends in the circumferential direction of the outer peripheral surface 44 .

The joint member 78 has an engagement hole 80 formed at its lower end and a pair of support walls 82 formed at its upper end. The engagement hole 80 has a T-shaped outer shape and slidably receives the rail portion 76 . The pair of support walls 82 extend upward from the upper end surface 78a of the joint member 78 so as to face each other. A through hole 82a is formed in each of the pair of support walls 82, and a shaft 84 is inserted through and fixed to the through hole 82a.

On the other hand, a through hole 56a is formed in the lower end portion 56 of the arm 20', and a shaft 84 is rotatably inserted through the through hole 56a. Shaft 84 is disposed generally parallel to shaft 58 described above, and lower end 56 of arm 20' is supported between support walls 82 of joint member 78 so as to be rotatable about shaft 84. .

Although not shown in FIG. 8, the link member 22 rotates relative to the shaft 42 formed on the arm 18' and the shaft 58 formed on the arm 20', as in the above embodiment. movably connected. A guide mechanism 74 guides the bending and stretching movements of the arms 18' and 20'.

More specifically, during bending and stretching of arms 18 and 20, joint member 78 slides along rail portion 76 and lower end 56 of arm 20' rotates relative to joint member 78 about shaft 84. move. The guide mechanism 74 guides the lower end 56 of the arm 20' to revolve around the rotation axis A6.

In the above-described embodiment, the case where the biasing portion 24, the extension portion 30, and the receiving hole 32 are provided in the arms 18, 18' has been described. However, the present invention is not limited to this, and the biasing portion 24, the extension portion 30, and the accommodation hole 32 may be provided in the arms 20, 20'. Such a configuration is shown in FIG.

In the mechanism portion 12'' shown in FIG. 10, a lever portion 64' extending outward from the upper end portion 62b of the link member 22' is formed on the upper end portion 62b of the link member 22'. An extension 30 ′ is formed at the lower end 56 . The lever portion 64' is integrally formed with the upper end portion 62b of the link member 22' so as to extend in a direction intersecting (more specifically, perpendicular to) the rotation axis A6 (shaft 58). formed.

The extension 30' is formed with a receiving hole 32' and a positioning shaft 33'. Extension 30' and receiving bore 32' extend from lower end 56 of arm 20'' along axis A8. A positioning shaft 33' is formed.The axis A8 may be slanted or perpendicular to the axis A3 of the body portion 50 of the arm 20''.

Inside the receiving hole 32', the biasing portion 24 is arranged as in the above-described embodiment. Specifically, the biasing portion 24 is positioned inside the housing hole 32 so as to be substantially coaxial with the axis A8 by being fitted on the positioning shaft 33'. A first end 24a of the biasing portion 24 is fixed to the extension 30' while a second end 24b is free.

In this embodiment, when the body B transitions from an upright posture to a squatting posture, the arms 18'' and 20'' bend from the extended position P1 shown in FIG. 10 to the bent position P2 shown in FIG. At this time, the arm 20 ″ rotates counterclockwise relative to the link portion 62 of the link member 22 ′ about the rotation axis A7 when viewed from the right side, while the arm 18 ″ rotates relative to the link portion 62 . , relative to the rotation axis A6 in the clockwise direction when viewed from the right side. As a result, the arms 18'' and 20'' bend from the extended position P1 to the bent position P2.

This bending motion of the arms 18 ″ and 20 ″ is guided by the engagement between the gear portion 52 of the arm 20 ″ and the gear portion 28 of the arm 18 ″ and the link portion 62 . Thus, during the bending motion of the arms 18'' and 20'', the lower end 56 of the arm 20'' is guided to revolve counterclockwise about the pivot axis A6 when viewed from the right side.

On the other hand, as the arms 18'' and 20'' bend from the extended position P1 to the bent position P2, the lever portion 64' moves from the first relative position RP1' to the second relative position RP2' with respect to the arm 20''. It rotates clockwise about the rotation axis A7 (shaft 58) when viewed from the right side.

When the lever portion 64' is positioned at the second relative position RP2' shown in FIG. 11 with respect to the arm 20'', the second end 24b of the biasing portion 24 is positioned on the side surface 64a' (FIG. 10) of the lever portion 64'. ) is pushed in the first direction D3 of the axis A8, and displaced in the first direction D3 in the accommodation hole 32'.As a result, the biasing portion 24 is compressed in the first direction D3. , the biasing portion 24 applies force to the side surface 64a' of the lever portion 64' in the second direction D4 opposite to the first direction D3.

As a result, the biasing portion 24 biases the lever portion 64' arranged at the second relative position RP2' toward the first relative position RP1'. The action of the urging portion 24 assists the body B to stand up from the squatting posture to the upright posture, and as a result, the body B can stand up more easily.

1 is arranged upside down, and the first portion 38 of the body portion 26 of the arm 18 is attached to the mounting band 16, while the body portion 50 of the arm 20 is attached to the mounting band 14. good too. Moreover, in the above-described embodiment, the case where the biasing portion 24 is composed of a coil spring has been described. However, the present invention is not limited to this, and the biasing portion 24 may have a pair of magnets arranged to repel each other, or a pneumatic or hydraulic cylinder.

For example, when the biasing portion 24 has a pair of magnets, one of the pair of magnets is fixed to the inner surface 32a of the accommodation hole 32, while the other of the pair of magnets is fixed to the accommodation hole 32 (or 32'). is slidably arranged in the Here, the pair of magnets are arranged in the accommodation hole 32 (or 32') so that the sides facing each other have the same polarity. Then, the lever portion 64 (or 64') is engaged with the other of the pair of magnets, and the arms 18 and 20 (or the arms 18' and 20', or the arms 18'' and 20'') are positioned at the bent position P2. The pair of magnets are arranged to be in contact (or proximity) to each other when the magnets are brought together.

At this time, the pair of magnets repel each other by magnetic force, and the biasing portion 24 biases the lever portion 64 (or 64') to the first relative position RP1 (or RP1') by magnetic force. It should be understood that even if the biasing portion 24 is composed of a cylinder, the lever portion 64 (or 64') can be biased to the first relative position RP1 (or RP1') by pneumatic or hydraulic force. .

The assistive device 10 may further include a pair of cases (not shown) that cover the mechanical portion 12, 12' or 12'' from the inside and outside. In this case, at least one of the shafts 42 and 58 The guide mechanism 72 or 74 described above can be omitted from the auxiliary equipment 10. In this case as well, the auxiliary equipment 10 is operated by the biasing portion 24 to move the human body. B's bending and stretching movements can be assisted.

Also, the extension 30 (or 30') and the receiving hole 32 (or 32') described above may be omitted from the assistive device 10. In this case, the biasing portion 24 may be attached directly to the upper ends 34 of the arms 18, 18' (or the lower ends 56 of the arms 20'').

Further, the assistive device 10 may have a plurality of mechanism portions 12, 12' or 12''. For example, the assistive device 10 may have a pair of mechanism portions 12, one of the pair of mechanism portions 12 being , the thigh B1, the shin B2 and the knee joint B3, while the other of the pair of mechanical parts 12 is arranged outside the thigh B1, the shin B2 and the knee joint B3. In this case, the pair of mechanism portions 12 may have a symmetrical structure.

Further, in the above-described embodiment, the case where the auxiliary equipment 10 is attached to the thigh B1 and the shin B2 in order to assist the bending and stretching movements of the thigh B1 and the shin B2 has been described. However, the auxiliary equipment 10 is not limited to this, and may be worn on the forearms and upper arms of the human body B, for example, in order to assist bending and stretching exercises of the forearms and upper arms. As described above, the present disclosure has been described through the embodiments, but the above-described embodiments do not limit the invention according to the scope of claims.

10 Auxiliary Equipment 12, 12', 12'' Mechanism 14, 16 Mounting Band 18, 18', 18'', 20, 20', 20'' Arm 22, 22' Link Member 24 Biasing Section 26, 50 Main Body 28, 52 gear portion 30, 30' extension portion 32, 32' accommodation hole 62 link portion 64, 64' lever portion 72, 74 guide mechanism

Claims (5)

An auxiliary device for assisting bending and stretching exercises of a first part and a second part of the human body connected via joints,
a first arm attached to the first portion and a second arm attached to the second portion;
A link portion having one end rotatably connected to the first arm and the other end rotatably connected to the second arm, wherein the first arm and the second arm are extended. a link portion that connects bendably between a position and a bent position;
A lever portion integrally formed at the one end so as to extend from the one end in a direction intersecting with a rotation axis of the one end with respect to the first arm, wherein the first arm and the second arm a lever portion that rotates about the rotation axis relative to the first arm from a first relative position to a second relative position when the arm moves from the extended position to the bent position; ,
an urging portion provided on the first arm for urging the lever portion toward the first relative position when the lever portion is disposed at the second relative position. brace. 2. The auxiliary equipment according to claim 1, further comprising a guide mechanism that guides bending and stretching movements of said first arm and said second arm between said extended position and said bent position together with said link part. The guide mechanism is
a first gear portion formed on the first arm and having a first diameter;
a second gear portion formed on the second arm and having a second diameter different from the first diameter, the second gear portion engaging the first gear portion; 3. The assistive device of claim 2, comprising: The first arm is
a main body having a first end on which the pivot shaft is arranged and a second end opposite to the first end;
an extension integrally formed with the first end to extend outwardly from the first end;
The auxiliary device according to any one of claims 1 to 3, further comprising a housing hole formed in the extension and housing the biasing section therein. the extension portion and the receiving hole extend along a second axis that is inclined with respect to the first axis of the body;
The biasing portion has a coil spring accommodated in the accommodation hole so as to expand and contract in the direction of the second axis,
The coil spring is compressed in the first direction of the second axis by the lever portion when the lever portion is relatively rotated from the first relative position to the second relative position, and a reaction force thereof is applied. 5. An auxiliary device according to claim 4, wherein a force is applied to said lever portion in a second direction opposite said first direction as a force to urge said lever portion toward said first relative position. brace.

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