CN212096344U - Exoskeleton bionic finger and bionic manipulator - Google Patents

Abstract

The utility model discloses a bionical finger of ectoskeleton and bionical manipulator, include: the knuckle is a hollow pipe body and is sequentially connected with a rigid layer and a soft layer in an embedded mode from outside to inside; the flexible structure is used for sequentially connecting the knuckles, the flexible structure is connected with the soft layer and arranged in the rigid layer, and the soft layer and the flexible structure are communicated to form a closed air cavity. The utility model discloses the bionical finger of ectoskeleton through setting up rigid layer and soft layer respectively, when satisfying the crooked demand of knuckle flexibility, has guaranteed the rigidity of knuckle, presses close to human actual finger form more, can satisfy the various bionical demands in fields such as snatching, massage.

Description

Exoskeleton bionic finger and bionic manipulator

technical field

The utility model relates to the field of bionic machinery, in particular to an exoskeleton bionic finger and a bionic manipulator.

Background technique

At present, manipulators based on human bionics have attracted attention due to their wide application. The core of the bionic manipulator lies in the bionic finger. Most of the bionic fingers on the market adopt a pneumatic multi-chamber structure. By inflating the gas chamber, the whole soft hand is bent in a certain direction to realize the grasping function. As disclosed in Chinese utility model patent CN110142797A, a soft finger includes at least one set of pneumatic bending modules and an origami-type connection mechanism; The connecting pieces at one end are connected to the two ends of the origami telescopic module respectively, and the connecting piece at one end is connected with the pneumatic bending module; the connecting piece at the other end is connected with the adjacent pneumatic bending module or supporting mechanism; A reset leaf spring is installed between each of the connecting pieces and the origami telescopic module, and the reset leaf spring is used to provide restoring force to the corresponding connecting piece and the origami telescopic module during bending.

However, when the above solution actually grasps an object, the origami-type connecting mechanism will be deformed due to the load, resulting in reverse bending of the entire finger, resulting in poor grasping and other phenomena.

Based on this, how to provide a bionic finger whose stiffness can meet the real bionic requirements has become a technical problem that needs to be solved urgently in the industry.

Utility model content

Purpose of the utility model: In order to overcome the deficiencies in the prior art, the utility model provides a bionic finger that can meet the rigidity requirements.

Technical solution: an exoskeleton bionic finger, including:

A number of knuckles, the knuckles are hollow tube bodies, and the rigid layers and the soft layers are nested and connected in sequence from the outside to the inside;

A telescopic structure for connecting the several knuckles in sequence, the telescopic structure is connected to the soft layer and is arranged in the rigid layer, and the soft layer and the telescopic structure communicate with each other to form a closed air cavity.

Further, the horizontal two ends of the top of the rigid layer are provided with horizontal protrusions, and when every two adjacent knuckles are in a straight state, the protrusions abut each other.

Further, a protruding portion and a concave portion are respectively provided on the protrusions of each two adjacent phalanges, and when the protrusions abut each other, the protruding portion is engaged with the concave portion.

Further, horizontal two ends of the bottom of the rigid layer are provided with horizontal depressions.

Further, a heating component and a bending sensor are arranged at the bottom of the closed air cavity.

Further, the telescopic structure includes a linear bottom surface and a wave-shaped structure connecting the linear bottom surface, the wave-shaped structure includes at least one wave crest and at least one wave trough, and the wave crest and the wave trough are connected in sequence.

Further, circular depressions and circular protrusions are respectively provided on the rigid layers of each adjacent two said knuckles, and each adjacent two said knuckles can move through the circular depressions and circular protrusions. connect.

Further, the cross section of the wave-shaped structure is arc-shaped.

Further, the phalanx includes a fingertip segment, a finger pulp segment and a finger root segment, the fingertip segment, the finger pulp segment and the finger root segment are sequentially connected by the telescopic structure, and the tail end of the finger root segment is closed and closed. The trachea is communicated with the external air path, and the height of the front end of the fingertip section gradually decreases along the direction of the fingertip.

The utility model also provides a bionic manipulator, comprising: a base and the exoskeleton bionic finger as described above arranged on the base.

Beneficial effects: The bionic finger of the exoskeleton of the utility model, by separately setting the rigid layer and the soft layer, can meet the flexible bending requirements of the knuckle while ensuring the stiffness of the knuckle, which is closer to the actual finger shape of the human body, and can meet the requirements of grasping and grasping. Various bionic needs in the fields of fetching, massage and so on.

Description of drawings

1 is a schematic three-dimensional structure diagram of an embodiment of an exoskeleton bionic finger of the present invention;

Accompanying drawing 2 is the plane sectional structure schematic diagram of exoskeleton bionic finger shown in Fig. 1;

Accompanying drawing 3 is the plane structure schematic diagram of exoskeleton bionic finger shown in FIG. 1;

4 is a schematic structural diagram of a protrusion of another embodiment of the bionic finger of the exoskeleton of the present invention;

5 is a schematic three-dimensional structure diagram of an embodiment of the bionic manipulator of the present invention;

FIG. 6 is a schematic three-dimensional structure diagram of another embodiment of the bionic manipulator of the present invention.

Detailed ways

In order to make the purpose, technical solutions and advantages of the present utility model more clearly understood, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are only used to explain the present invention, and are not used to limit the present invention. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without creative work fall within the protection scope of the present invention.

It should be noted that the descriptions involving "first", "second", etc. in the present utility model are only for the purpose of description, and should not be understood as indicating or implying their relative importance or implying the indicated technical features. quantity. Thus, a feature delimited with "first", "second" may expressly or implicitly include at least one of that feature. In addition, the technical solutions between the various embodiments can be combined with each other, but must be based on the realization by those of ordinary skill in the art. When the combination of technical solutions is contradictory or cannot be realized, it should be considered that the combination of such technical solutions does not exist. , is not within the scope of protection required by the present utility model.

Referring to an embodiment of the exoskeleton bionic finger of the present utility model shown in Figures 1 to 3, it includes: several knuckles 1, and the knuckles 1 are hollow tubular bodies, and from outside to inside are rigid layers 11, soft The layers 12 are nested and connected; the telescopic structures 2 used to connect the several knuckles 1 in sequence, the telescopic structures 2 are connected to the soft layer 12 and are arranged in the rigid layer 11 , the soft layers 12 and The telescopic structures 2 communicate with each other to form a closed air cavity. The bionic finger of the exoskeleton of the utility model is provided with the rigid layer 11 and the soft layer 12 respectively, which not only meets the flexible bending requirements of the knuckle 1, but also ensures the rigidity of the knuckle 1, which is closer to the actual finger shape of the human body, and can meet the needs of Various bionic needs in grasping, massage and other fields.

In this embodiment, the rigid layer 11 is a hollow tube body made of titanium alloy, and the soft layer 12 is a hollow tube body made of silica gel. In other embodiments, the rigid layer 11 and the soft layer 12 may also be It is made of other materials, and such material changes still fall within the protection scope of the present invention. The rigid layers 11 of every two adjacent finger knuckles 1 are respectively provided with matching structures 14 with circular depressions and circular protrusions, and every two adjacent finger knuckles 1 pass through the circular depressions and circular protrusions. The protrusion realizes the movable connection, which is very easy to disassemble and maintain.

In this embodiment, the phalanx 1 includes a fingertip segment, a finger pulp segment and a finger root segment, and the fingertip segment, the finger pulp segment and the finger root segment pass through the telescopic structure 2 and the circular depression and the circular The protruding matching structures 14 are connected in sequence, the tail end of the finger root segment is closed and communicated with the external air path through the trachea, and the height of the front end of the finger tip segment gradually decreases along the fingertip direction. The settings of the fingertip segment, the finger pulp segment and the finger root segment are closer to the actual finger shape of the human body, which can provide better bionic effect, especially suitable for massage, grasping and other fields, and can more accurately simulate the grasping, Press effect.

The telescopic structure 2 includes a linear bottom surface and a wave-shaped structure arranged around the linear bottom surface. The wave-shaped structure includes a plurality of wave crests and wave troughs connected in sequence, the width of the wave crests gradually decreases along the vertical upward direction, and the width of the wave troughs along the vertical upward direction. The direction is gradually increased, and the cross-section of the wave-shaped structure is arc-shaped. In actual work, because the elastic modulus of the linear bottom surface is greater than that of the wave-shaped structure, the deformation of the wave-shaped structure is greater than that of the linear bottom surface when the closed air cavity is inflated, resulting in the expansion of the wave-shaped structure and the formation of bending When the air is deflated in the closed air cavity, the wave-shaped structure shrinks under the elastic action of the wave crest and the wave trough, forming a flat state of the soft layer. The arc-shaped cross section of the wave-shaped structure can ensure relatively good torque and resist the torsional deformation of the exoskeleton bionic finger when it is stressed.

In other embodiments, the cross-section of the linear bottom surface is "ㄩ" type, and the wave-shaped structure is located on the upper side of the linear bottom surface, which can ensure the directionality of the bending, and will not cause the radial or circumferential direction of the exoskeleton bionic finger. deformed.

In this embodiment, the horizontal two ends of the top of the rigid layer 11 are provided with horizontal protrusions 111. When every two adjacent knuckles 1 are in a straight state, the protrusions 111 abut each other. Therefore, it can be ensured that the two adjacent phalanges 1 will not be bent in the opposite direction, the axial strength is ensured, and the fingers are closer to the real human body.

As a further optimization of this embodiment, the horizontal two ends of the bottom of the rigid layer 1 are provided with horizontal depressions 112, so that when the knuckles 1 are bent, the bottom surfaces of the knuckles will not interfere with each other due to abutting against each other. The smoothness of the bending action.

In other embodiments, the protrusions 111 of every two adjacent phalanges 1 are respectively provided with protrusions and recesses 113 , when the protrusions 111 abut each other, the protrusions and the recesses The portion 113 is engaged. By arranging the protruding part and the concave part 113, the ability to resist the circumferential twisting deformation of the exoskeleton bionic finger when the protrusion 111 abuts can be further improved during occlusion, further ensuring the bending direction accuracy, and also ensuring the exoskeleton bionic finger. The strength and stiffness in the flat state are shown in Figure 4.

As a further optimization of this embodiment, in order to improve the bionic performance, it is more similar to a human finger. A heating circuit (not shown in the figure) and a temperature sensor (not shown in the figure) are set close to the bottom of the closed air cavity. The inner bottom of the closed air cavity is also provided with a bending sensor (not shown) for sensing the bending degree of the exoskeleton bionic finger. A bionic layer is provided on the lower side of the knuckle 1, and preferably, the bionic layer is made of silica gel.

The present invention also provides a bionic manipulator as shown in FIG. 5 , comprising: a base 6 and the aforementioned soft exoskeleton bionic finger arranged on the base. The base 6 can be a circular base, and the exoskeleton bionic fingers are arranged on the exoskeleton bionic fingers in an array, or it can be in the form of a human palm, and two to four exoskeleton bionic fingers are arranged in a straight line on the base. 6, and then arrange an exoskeleton bionic finger alone on one side of the linear exoskeleton bionic finger, as shown in Figure 6. In this way, a palm conforming to the actual human body is formed, which is closer to the actual grasping and pressing actions of the human body.

The above is only the preferred embodiment of the present utility model. It should be pointed out that: for those skilled in the art, without departing from the principle of the present utility model, several improvements and modifications can also be made. These improvements and Retouching should also be regarded as the protection scope of the present invention.

Claims (10)

1. An exoskeleton biomimetic finger comprising:

the knuckle is a hollow pipe body and is sequentially connected with a rigid layer and a soft layer in an embedded mode from outside to inside;

the flexible structure is used for sequentially connecting the knuckles, the flexible structure is connected with the soft layer and arranged in the rigid layer, and the soft layer and the flexible structure are communicated to form a closed air cavity.

2. The exoskeleton biomimetic finger of claim 1, wherein: horizontal protrusions are arranged at two horizontal ends of the top of the rigid layer, and when every two adjacent knuckles are in a straight state, the protrusions are abutted to each other.

3. The exoskeleton biomimetic finger of claim 2, wherein: and the bulges of every two adjacent knuckles are respectively provided with a protruding part and a concave part, and when the bulges are mutually abutted, the protruding parts are occluded with the concave parts.

4. The exoskeleton biomimetic finger of claim 2, wherein: horizontal depressions are arranged at the two horizontal ends of the bottom of the rigid layer.

5. The exoskeleton biomimetic finger of claim 1, wherein: and a heating assembly and a bending sensor are arranged at the bottom in the closed air cavity.

6. The exoskeleton bionic finger of any one of claims 1 to 5, wherein: the telescopic structure comprises a linear bottom surface and a wave-shaped structure connected with the linear bottom surface, the wave-shaped structure comprises at least one wave crest and at least one wave trough, and the wave crest and the wave trough are sequentially connected.

7. The exoskeleton biomimetic finger of claim 6, wherein: every two adjacent knuckles are respectively provided with a circular recess and a circular protrusion on the rigid layer, and every two adjacent knuckles are movably connected through the circular recess and the circular protrusion.

8. The exoskeleton biomimetic finger of claim 6, wherein: the cross section of the wave-shaped structure is arc-shaped.

9. The exoskeleton biomimetic finger of claim 6, wherein: the knuckle comprises a finger tip section, a finger abdomen section and a finger root section, the finger tip section, the finger abdomen section and the finger root section are sequentially connected through the telescopic structure, the tail end of the finger root section is closed and communicated with an external air passage through an air pipe, and the front end of the finger tip section is gradually reduced along the direction of a finger tip.

10. A biomimetic manipulator, comprising: a base and the exoskeleton biomimetic finger of any one of claims 1-9 disposed on the base.

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