CN212326882U - Integral software finger of variable rigidity and finger training ware - Google Patents

Abstract

The utility model discloses an integral software finger of variable rigidity and finger training ware. The variable-rigidity integral soft finger comprises a base structure, a through hole, a variable-rigidity structure and a fingertip structure. One end of the root structure is connected with a through hole, one end of the variable rigidity structure is connected with the other end of the root structure, the fingertip structure is connected with the other end of the variable rigidity structure, and a cavity structure is formed among the through hole, the root structure, the variable rigidity structure and the fingertip structure. The utility model discloses structure personification degree is high, when applying load, can realize having the different crooked profiles of variable rigidity, and its inside stress distribution is even, and stress concentration is less, warp harmoniously, and life is longer moreover, adopts integral shaping structure, and is better with finger laminating degree, can adapt to different crowds' people hand size.

Description

Integral software finger of variable rigidity and finger training ware

Technical Field

The utility model relates to a bionical flexible finger technical field especially relates to an integral software finger of variable rigidity and finger training ware.

Background

Motor dysfunction is the most common problem in society today, and superficial motor dysfunction occurs after neurological disease (e.g., stroke) or injury (e.g., post-traumatic arthritis). After impaired motor function, an individual will lose the ability to perform Activities of Daily Living (ADL). In order to improve hand mobility, continuous passive motion exercises involving repetitive tasks such as grasping and oppositional movements are required for patients with hand dysfunction.

The flexible finger structure in the prior art can not realize different bending profiles with variable rigidity when applying load, the inside of the structure can cause uneven stress distribution, the local stress concentration condition exists, the service life of the flexible finger is not long, radial expansion exists, the bending conversion efficiency is reduced, the manufacturing process is complex, integral forming can not be realized, and the flexible finger structure is difficult to adapt to the sizes of hands of different crowds, so that the improvement is urgently needed.

SUMMERY OF THE UTILITY MODEL

In view of the above prior art's shortcoming, the utility model aims to provide an integral software of variable rigidity finger and finger training ware for solve the flexible finger structure among the prior art when applying load, can't realize having the different crooked profiles of variable rigidity, the structure is inside to cause stress distribution inhomogeneous, there is the local stress concentration condition, make the life of flexible finger not long, and there is radial inflation, make crooked conversion efficiency reduce, the preparation technology is complicated simultaneously, unable integrated into one piece, and be difficult to adapt to the problem of different crowds ' people hand size.

To achieve the above and other related objects, the present invention provides a variable stiffness integral soft finger, comprising:

one end of the root structure is connected with the through hole;

a variable stiffness structure having one end connected to the other end of the root structure;

a fingertip structure connected to the other end of the variable stiffness structure;

a cavity structure is formed among the through hole, the root structure, the variable rigidity structure and the fingertip structure.

In an embodiment of the present invention, the variable stiffness structure includes:

one end of the first joint structure is connected with the root structure, and the other end of the first joint structure is connected with one end of the first knuckle structure;

one end of the second joint structure is connected with the other end of the first knuckle structure, and the other end of the second joint structure is connected with one end of the second knuckle structure;

and one end of the third joint structure is connected with the other end of the second finger-joint structure, and the other end of the third joint structure is connected with the finger-tip structure.

In an embodiment of the present invention, the variable stiffness structure includes:

one end of the first joint structure is connected with the root structure, and the other end of the first joint structure is connected with one end of the first knuckle structure;

and one end of the second joint structure is connected with the other end of the first knuckle structure, and the other end of the second joint structure is connected with the fingertip structure.

In an embodiment of the present invention, the first joint structure and the second joint structure are wavy non-rotating body structures, and top surfaces of the first joint structure, the second joint structure and the third joint structure are corrugated structures, and the corrugated structures include a plurality of alternately connected wave crest structures and wave trough structures; the first knuckle structure and the second knuckle structure are of a plurality of alternately connected wave crest structures and wave trough structures or flat structures.

In an embodiment of the present invention, a section structure of the wave peak structure in the radial direction includes:

a plurality of first arcs, a plurality of said first arcs being tangent to one another;

a first bottom edge line disposed between the first arcs on both sides of the bottom.

In an embodiment of the present invention, the cross-sectional structure of the trough structure in the radial direction includes:

a plurality of second arcs, a plurality of said second arcs being tangent to each other;

a second bottom edge line disposed between the second arcs on both sides of the bottom.

In an embodiment of the present invention, the minimum cross-sectional area of the cavity in the radial direction of the wave trough structure is the maximum cross-sectional area of the cavity in the radial direction of the wave crest structure

Multiple to 1 time, and on the axial middle section, the cavity height corresponding to the wave trough structure is the cavity height corresponding to the wave crest structure

To 1 fold.

In an embodiment of the present invention, the stiffness of the first knuckle structure and the second knuckle structure is greater than the stiffness of the first joint structure, the second joint structure and the third joint structure; on the axial section of the integral soft finger with variable rigidity, the corresponding distance between the wave crest structure and the wave trough structure of the first knuckle structure and the second knuckle structure is smaller than the corresponding distance between the wave crest structure and the wave trough structure of the first joint structure, the second joint structure and the third joint structure.

In an embodiment of the present invention, the corrugated structure of the wavy non-rotating body structure is provided with a groove, and the groove depth between the wave crest structure and the wave trough structure is smaller along with the decrease of the distance between the bottom surfaces at the corrugated structure near the top surface of the bottom surface.

The utility model also provides a finger training ware, finger training ware includes:

at least one variable stiffness monolithic soft finger for training a finger, the variable stiffness monolithic soft finger comprising:

one end of the root structure is connected with the through hole;

a variable stiffness structure having one end connected to the other end of the root structure;

a fingertip structure connected to the other end of the variable stiffness structure;

a cavity structure is formed among the through hole, the root structure, the variable rigidity structure and the fingertip structure;

the through hole is used for introducing fluid;

the variable stiffness integral soft finger is in contact with a finger surface or a glove.

As mentioned above, the utility model discloses an integral software finger of variable rigidity and finger training ware has following beneficial effect:

the utility model discloses an integral software finger of variable rigidity includes root structure, variable rigidity structure, fingertip structure and through-hole. The structure of the utility model is like a finger, and the personification degree is higher. The utility model discloses when applying load, can realize having the different crooked profiles of variable rigidity, its inside stress distribution is even, and stress concentration is less, warp harmoniously, and life is longer moreover, and preparation simple process adopts integral shaping structure, and is better with finger laminating degree, can adapt to different crowds' people hand size.

The utility model discloses an integral software finger of variable rigidity can distinguish different crowds knuckle joint length and position.

The utility model discloses an integral software finger of variable rigidity is integral software finger that has variable rigidity, can make it produce different rigidity through the structure of adjusting the different positions of integral software finger, consequently can realize required different hand actions among the various physiotherapy.

The utility model discloses a rigidity of the knuckle structure of the integral software finger of variable rigidity is greater than the rigidity of joint structure to can realize different crooked profiles according to the crooked degree of the different knuckle joints of human finger.

The utility model discloses a slot degree of depth that variable rigidity structure set up changes along with circumference direction position change, and it is easy to guarantee about the direction bending deformation, and the bending deformation is coordinated, and stress distribution is even, and direction rigidity is great about simultaneously, and the bearing capacity improves, and the deformation of two directions about the restriction variable rigidity software finger to make the deformation of integral software finger laminate people's finger motion more.

The utility model discloses an integral software finger of variable rigidity can be used for two kinds of application modes, including supplementary application mode and recovered application mode, under supplementary application mode, can carry out daily life activity, for example grab and hold between the fingers, under recovered application mode, can carry out different repetitive tasks to realize continuous passive motion.

The utility model discloses a variable rigidity integral software finger's deformation is mainly through the angle variation of the adjacent contained angle of crest, rather than relying on the inflation extrusion deformation production of crest both sides side, moreover the utility model discloses a section outline line of crest and trough is the pitch arc, and consequently the resistance to pressure is better.

The utility model discloses an integral software finger of variable rigidity can guarantee the more natural of knuckle and the human finger laminating of software finger, has guaranteed the performance and the laminating travelling comfort of structure.

The utility model discloses an integral software finger of variable rigidity adopts elastic material to make, when pointing the part and using as hand rehabilitation apparatus, can carry out the bending and the extension of different degrees to the hand through the pressure of adjusting fluid, can carry out suitable hyperextension rehabilitation to the finger simultaneously, can not produce rigidity restraint and oppression to hand blood vessel, muscle etc. long-time the use does not have uncomfortable sense.

The utility model discloses an integral software finger of variable rigidity still can be used as the bionical hand claw of industry, realizes grabbing, holding and drawing actions such as outward, can change the strength of snatching according to the weight of target object, can not produce the destruction to being grabbed the object.

Drawings

Fig. 1 is a schematic structural view of a variable stiffness integral soft finger according to an embodiment of the present application.

Fig. 2 is a schematic axial sectional view of a variable stiffness one-piece soft finger according to an embodiment of the present application.

Fig. 3 is a schematic axial sectional view of a variable stiffness one-piece soft finger according to another embodiment of the present application.

Fig. 4 is a schematic cross-sectional view of a peak structure of a variable stiffness one-piece soft finger according to an embodiment of the present disclosure.

Fig. 5 is a schematic cross-sectional view illustrating a valley structure of a variable stiffness one-piece soft finger according to an embodiment of the present application.

Fig. 6 is a schematic view illustrating a bending state of a variable stiffness one-piece soft finger according to an embodiment of the present application.

Fig. 7 is a schematic view of an application of a variable stiffness one-piece soft finger according to an embodiment of the present application.

Fig. 8 is a schematic view of an application of a variable stiffness one-piece soft finger according to another embodiment of the present application.

Fig. 9 is a schematic view of a variable stiffness one-piece soft finger according to still another embodiment of the present application.

Description of the element reference numerals

1 finger tip structure

2 wave crest structure

3 trough structure

4 first knuckle structure

Bottom surface corresponding to 5 wave crests

Concave cambered surface corresponding to 6 wave troughs

7-radical structure

8 through hole

9 raised structure

10 finger

11 elastic bandage

12 first joint structure

13 second knuckle structure

14 second joint structure

15 third joint structure

21 first arc line

22 first bottom edge line

31 second arc line

32 second bottom edge line

Detailed Description

The following description of the embodiments of the present invention is provided for illustrative purposes, and other advantages and effects of the present invention will be readily apparent to those skilled in the art from the disclosure herein. The present invention can also be implemented or applied through other different specific embodiments, and various details in the present specification can be modified or changed based on different viewpoints and applications without departing from the spirit of the present invention. It is to be noted that the features in the following embodiments and examples may be combined with each other without conflict.

It should be noted that the drawings provided in the following embodiments are only for illustrating the basic idea of the present invention, and the drawings only show the components related to the present invention rather than being drawn according to the number, shape and size of the components in actual implementation, and the form, amount and ratio of the components in actual implementation may be changed arbitrarily, and the layout of the components may be more complicated.

Referring to fig. 1, fig. 2 and fig. 3, fig. 1 is a schematic structural view of a variable stiffness integral soft finger according to an embodiment of the present application. Fig. 2 is a schematic axial sectional view of a variable stiffness one-piece soft finger according to an embodiment of the present application. Fig. 3 is a schematic axial sectional view of a variable stiffness one-piece soft finger according to another embodiment of the present application. The utility model provides an integral software of variable rigidity finger, whole the structure of the integral software of variable rigidity finger is integrated into one piece structure, the integral software of variable rigidity finger is asymmetric structure, axial bilateral symmetry structure about the axial. The material of the variable-rigidity integral soft finger can be, but not limited to, an elastic material, and can also be made of other materials, and the variable-rigidity integral soft finger can be set according to specific requirements. The variable stiffness one-piece soft finger includes, but is not limited to, a base structure 7, a through hole 8, a variable stiffness structure, and a fingertip structure 1. One end of the root structure 7 is connected with a through hole 8. One end of the variable stiffness structure is connected with the other end of the root structure 7. The fingertip structure 1 is connected with the other end of the variable rigidity structure. A cavity structure is formed among the through hole 8, the root structure 7, the variable rigidity structure and the fingertip structure 1, and the structure of the fingertip structure 1 can be a solid structure or a closed cavity structure.

As shown in fig. 1, 2, 3, the variable stiffness structure includes joint structures including, but not limited to, a first joint structure 12, a second joint structure 14, and a third joint structure 15, and knuckle structures including, but not limited to, a first knuckle structure 4, a second knuckle structure 13. One end of the first joint structure 12 is connected with the root structure 7, the other end of the first joint structure 12 is connected with one end of the first knuckle structure 4, one end of the second joint structure 14 is connected with the other end of the first knuckle structure 4, the other end of the second joint structure 14 is connected with one end of the second knuckle structure 13, one end of the third joint structure 15 is connected with the other end of the second knuckle structure 13, and the other end of the third joint structure 15 is connected with the fingertip structure 1. The first joint structure 12, the second joint structure 14, the third joint structure 15, the first knuckle structure 4 and the second knuckle structure 13 can be used in an index finger, a middle finger, a ring finger and a little finger, the first joint structure 12, the second joint structure 14 and the third joint structure 15 are wave-shaped non-rotating body structures, the top surfaces of the first joint structure 12, the second joint structure 14 and the third joint structure 15 are corrugated structures, each corrugated structure comprises a plurality of alternately connected peak structures 2 and valley structures 3, and the first knuckle structure 4 and the second knuckle structure 13 are a plurality of alternately connected peak structures 2 and valley structures 3 or are flat structures. The corrugated structure of the wavy non-rotating body structure is provided with grooves, the grooves are areas between the wave crest structures 2 and the wave trough structures 3, the corrugated structure is arranged on the top surface close to the bottom surface, and the depth of the grooves between the wave crest structures 2 and the wave trough structures 3 is reduced along with the reduction of the distance between the wave crest structures and the bottom surface.

As shown in fig. 1, 2 and 3, the variable stiffness structure may further include a first joint structure 12 and a second joint structure 14, one end of the first joint structure 12 is connected to the base structure 7, the other end of the first joint structure 12 is connected to one end of the first knuckle structure 4, one end of the second joint structure 14 is connected to the other end of the first knuckle structure 4, and the other end of the second joint structure 14 is connected to the fingertip structure 1. The first joint structure 12, the second joint structure 14, and the first knuckle structure 4 may be used in the thumb. The variable stiffness structure may also include a joint structure and a knuckle structure. The axial direction section of the first knuckle structure 4 and the second knuckle structure 13 is that the upper structure of the knuckle structures is tangentially connected with the trough structures 3 of the adjacent joint structures or tangentially connected with the crest structures 2 of the adjacent joint structures. The bottom surface of the knuckle structure in the axial direction is tangent to the bottom surface corresponding to the wave trough or tangent to the bottom surface corresponding to the wave crest of the joint.

As shown in fig. 1, 2 and 3, the first joint structure 12, the second joint structure 14 and the third joint structure 15 comprise a plurality of wave crest structures 2 and wave trough structures 3 which are alternately connected. The width of the wave crest structure 2 in the circumferential direction is sequentially increased along the circumferential direction of the wave crest or is kept consistent along the circumferential direction of the wave crest. Specifically, the integral soft finger with variable rigidity has integral variable rigidity, different rigidities are generated by adjusting structures of the knuckle and the joint position, the rigidities of the first knuckle structure 4 and the second knuckle structure 13 are greater than the rigidities of the first joint structure 12, the second joint structure 14 and the third joint structure 15, and on an axial section of the integral soft finger with variable rigidity, the corresponding distance between the peak structures and the trough structures of the first knuckle structure 4 and the second knuckle structure 13 is smaller than the corresponding distance between the peak structures and the trough structures of the first joint structure 12, the second joint structure 14 and the third joint structure 15, so that different hand motions required in various physical therapies can be realized.

As shown in fig. 1, 2 and 3, when the variable stiffness integral soft finger is filled with fluid through the through hole 8, the fluid may be gas or liquid, the distance between the peaks increases, the variable stiffness integral soft finger bends towards one side of the micro-corrugated surface, when the fluid is pumped out through the through hole 8 communicating with the fluid by the driving device, the distance between the peaks decreases, and the whole variable stiffness integral soft finger bends towards one side of the peak and the valley.

As shown in fig. 1, 2, and 3, the internal cavity structure of the root structure 7 is horn-shaped, one side of the joint structure of the integral type soft finger with variable stiffness is a corrugated surface including peaks and valleys, the other side of the joint structure is a micro-corrugated surface, the top surfaces of the first joint structure 12, the second joint structure 14, and the third joint structure 15 are corrugated structures, and the corrugated structures include a plurality of peak structures 2 and valley structures 3 alternately connected. The joint structure can comprise an inward concave cambered surface 6 corresponding to a wave trough, and can also comprise a bottom surface 5 corresponding to a wave crest, the base structure 7, the knuckle structure, the joint structure and the fingertip structure 1 are communicated with each other, and are connected with the knuckle and the joint structure to form a finger-shaped structure with a cavity inside, and a cavity structure is formed between the finger-shaped structure and the joint structure. The upper structure of the knuckle structure of the axial direction section can be in tangential connection with the wave trough of the adjacent joint structure and can also be in tangential connection with the wave crest of the adjacent joint structure. The bottom surface of the knuckle structure in the axial direction can be tangent to the concave cambered surface 6 corresponding to the wave trough, and can also be tangent to the bottom surface 5 corresponding to the wave crest of the joint structure. The fluid communication through hole 8 is connected to an external device, and when the fluid communication through hole 8 is connected to a driving device, a working medium, which may be, but not limited to, a fluid such as gas, water, hydraulic oil, etc., may flow in and out through the fluid communication through hole 8.

Referring to fig. 4 and 5, fig. 4 is a schematic cross-sectional view illustrating a peak structure of a variable stiffness integral soft finger according to an embodiment of the present application. Fig. 5 is a schematic cross-sectional view illustrating a valley structure of a variable stiffness one-piece soft finger according to an embodiment of the present application. The cross-sectional configuration of the peak structure 2 in the radial direction includes, but is not limited to, a first arc line 21 and a first bottom edge line 22. A plurality of said first arcs 21 are tangent to each other, and said first bottom edge line 22 is disposed between said first arcs 21 on both sides of the bottom. The cross-sectional configuration of the valley structure 3 in the radial direction includes, but is not limited to, a plurality of second arcs 31 and second bottom side lines 32. The first arc 21 comprises a parabola, a quadratic curve, a fitted line, etc. A plurality of said second arcs 31 are tangent to each other, and said second bottom edge line 32 is disposed between said second arcs 31 on both sides of the bottom. The second arc 31 comprises a parabola, a quadratic curve, a fitted line, etc. The minimum sectional area of the cavity of the wave trough structure 3 in the radial direction is the maximum sectional area of the cavity of the wave crest structure 2 in the radial direction

The cavity height corresponding to the wave trough structure 3 is 1 time of that corresponding to the wave crest structure 2 on the axial middle section

Up to 1 times, e.g. corresponding to said valley structure 3The cavity height is the cavity height corresponding to the wave crest structure 2

Double or

And (4) doubling.

As shown in fig. 4 and 5, the radial cross section of the knuckle structure may be the profile size of a peak cross section or the profile size of a valley cross section, the overall profile of the valley cross section is formed by tangency of multiple arc lines, and the second arc lines 31 on two sides of the lower region of the valley profile are tangent to the second bottom edge line 32.

Referring to fig. 6, fig. 6 is a schematic view illustrating a bending state of a variable stiffness integral soft finger according to an embodiment of the present application. The deformation of the integral soft finger with variable rigidity is mainly caused by the angle change of the adjacent included angle of the wave crest, and is not caused by the expansion extrusion deformation of the side surfaces at the two sides of the wave crest. Upon pressurization, the bending at the location of lowest stiffness will actuate the finger joints, resulting in a change in relative joint angles such that the degree of bending of the joint structures is greater than the degree of bending of the knuckle structures, which more closely conforms to the curved shape of a human finger, and thus the variable stiffness unitary soft finger is able to achieve the different hand motions required in various physical therapies.

Referring to fig. 7, 8 and 9, fig. 7 is a schematic view illustrating an application of a variable stiffness integral soft finger according to an embodiment of the present application. Fig. 8 is a schematic view of an application of a variable stiffness one-piece soft finger according to another embodiment of the present application. Fig. 9 is a schematic view of a variable stiffness one-piece soft finger according to still another embodiment of the present application. As shown in fig. 7, the method for binding the variable-stiffness integral soft finger to the finger 10 or the glove may be to arrange a plurality of protruding structures 9 on the bottom surface 5 corresponding to the wave crests, and the protruding structures 9 may be, but not limited to, semi-circular, square, or other shapes. Each protruding structure 9 is provided with a tiny pore, the pore can be penetrated with the suture line to sew up with the gloves, thereby play the fixed effect of sewing up, in addition, protruding structure 9 still plays the effect of keeping apart the buffering with micro-wave face and finger 10, reduces the extra effort that produces when filling fluid pressure great. As shown in fig. 8, the bottom surface 5 corresponding to the peak of the integral soft finger with variable stiffness can be uniformly coated with a special glue by adhesion, and the bottom surface is seamlessly adhered to the outer surface of each finger of the health glove, thereby playing a role in fixation. As shown in fig. 9, the finger joints of the integral soft finger with variable stiffness can be fixed by binding, and the elastic bands 11 are arranged at the finger joints of the integral soft finger with variable stiffness, so that the elastic bands 11 are bound with the outer surfaces of the fingers 10 of the human body or the fingers of the health glove, thereby effectively ensuring that the finger joints and the fingers have good fitting effect without affecting the performance of the integral soft finger with variable stiffness.

As shown in fig. 1, the present invention further provides a finger training device, which comprises the above-mentioned at least one variable-rigidity integral soft finger, wherein the variable-rigidity integral soft finger is used for training the finger, the through hole 8 is used for letting in fluid, and the variable-rigidity integral soft finger contacts with the surface of the finger.

To sum up, the utility model discloses an integral software finger of variable rigidity includes root structure 7, through-hole 8, variable rigidity structure and fingertip structure 1. The utility model discloses when applying load, can realize having the different crooked profiles of variable rigidity, life is longer moreover, and preparation simple process adopts integral shaping structure, can adapt to different crowds' hand size.

The above embodiments are merely illustrative of the principles and effects of the present invention, and are not to be construed as limiting the invention. Modifications and variations can be made to the above-described embodiments by those skilled in the art without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which may be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims (10)

1. A variable stiffness monolithic soft finger, comprising:

one end of the root structure is connected with the through hole;

a variable stiffness structure having one end connected to the other end of the root structure;

a fingertip structure connected to the other end of the variable stiffness structure;

a cavity structure is formed among the through hole, the root structure, the variable rigidity structure and the fingertip structure.

2. The variable stiffness one-piece soft finger according to claim 1, wherein the variable stiffness structure comprises:

one end of the first joint structure is connected with the root structure, and the other end of the first joint structure is connected with one end of the first knuckle structure;

one end of the second joint structure is connected with the other end of the first knuckle structure, and the other end of the second joint structure is connected with one end of the second knuckle structure;

and one end of the third joint structure is connected with the other end of the second finger-joint structure, and the other end of the third joint structure is connected with the finger-tip structure.

3. The variable stiffness one-piece soft finger according to claim 1, wherein the variable stiffness structure comprises:

one end of the first joint structure is connected with the root structure, and the other end of the first joint structure is connected with one end of the first knuckle structure;

and one end of the second joint structure is connected with the other end of the first knuckle structure, and the other end of the second joint structure is connected with the fingertip structure.

4. The variable stiffness one-piece soft finger according to claim 2, wherein: the first joint structure and the second joint structure are wavy non-rotating body structures, the top surfaces of the first joint structure, the second joint structure and the third joint structure are corrugated structures, and the corrugated structures comprise a plurality of alternately connected wave crest structures and wave trough structures; the first knuckle structure and the second knuckle structure are of a plurality of alternately connected wave crest structures and wave trough structures or flat structures.

5. The variable stiffness one-piece soft finger according to claim 4, wherein the cross-sectional structure of the wave crest structure in the radial direction comprises:

a plurality of first arcs, a plurality of said first arcs being tangent to one another;

a first bottom edge line disposed between the first arcs on both sides of the bottom.

6. The one-piece soft finger with variable rigidity according to claim 4, wherein the cross-sectional structure of the wave trough structure in the radial direction comprises:

a plurality of second arcs, a plurality of said second arcs being tangent to each other;

a second bottom edge line disposed between the second arcs on both sides of the bottom.

7. The variable stiffness one-piece soft finger according to claim 4, wherein the minimum cross-sectional area of the cavity of the wave trough structure in the radial direction is the maximum cross-sectional area of the cavity of the wave crest structure in the radial direction

Multiple to 1 time, and on the axial middle section, the cavity height corresponding to the wave trough structure is the cavity height corresponding to the wave crest structure

To 1 fold.

8. The variable stiffness one-piece soft finger according to claim 4, wherein: the rigidity of the first knuckle structure and the second knuckle structure is greater than the rigidity of the first joint structure, the second joint structure and the third joint structure; on the axial section of the integral soft finger with variable rigidity, the corresponding distance between the wave crest structure and the wave trough structure of the first knuckle structure and the second knuckle structure is smaller than the corresponding distance between the wave crest structure and the wave trough structure of the first joint structure, the second joint structure and the third joint structure.

9. The variable stiffness one-piece soft finger according to claim 4, wherein: the corrugated structure of the wavy non-rotating body structure is provided with grooves, the corrugated structure of the top surface close to the bottom surface, and the depth of the grooves between the wave crest structure and the wave trough structure is reduced along with the reduction of the distance between the wave crest structure and the bottom surface.

10. A finger trainer, the finger trainer comprising:

at least one variable stiffness monolithic soft finger for training a finger, the variable stiffness monolithic soft finger comprising:

one end of the root structure is connected with the through hole;

a variable stiffness structure having one end connected to the other end of the root structure;

a fingertip structure connected to the other end of the variable stiffness structure;

a cavity structure is formed among the through hole, the root structure, the variable rigidity structure and the fingertip structure;

the through hole is used for introducing fluid;

the variable stiffness integral soft finger is in contact with a finger surface or a glove.

Images