CN219685633U - Five-finger manipulator with touch perception function - Google Patents

Abstract

The utility model relates to a tactile-sensing five-finger manipulator which comprises a palm module, a thumb module, a four-finger module and a tactile integrated module, wherein the thumb module and the four-finger module are sequentially connected to the palm module, the four-finger module is of four fingers with the same structure, and the thumb module is sequentially provided with an index finger part, a middle finger part, a ring finger part and a little finger part from the near to the far; the touch integrated module comprises a palm touch module and a finger touch module, wherein the palm touch module comprises a palm touch sensor arranged at the palm center of the palm module and a palm touch control board which is arranged on the palm module and connected with the palm touch sensor; the finger touch module comprises finger touch sensors arranged at the finger belly of the thumb module and the four-finger module finger and a finger touch control board which is arranged on the thumb module and the four-finger module and connected with the finger touch sensors.

Description

Five-finger manipulator with touch perception function

Technical Field

The utility model belongs to the technical field of humanoid robots, relates to a five-finger manipulator, and particularly relates to a tactile perception five-finger manipulator.

Background

At present, the existing smart manipulators at home and abroad have long-term progress and have better research results, but the smart manipulators still have some aspects needing to be lifted and improved, mainly include:

1. the integrated design of the humanoid manipulator structure-sensing-control needs to be lifted;

2. most of the existing products are of simplified design, and the degree of freedom of coupling is designed, so that the degree of freedom is low;

3. the perception capability is weak, and how to realize the full coverage touch sense of the humanoid manipulator is a difficulty of overcoming;

4. the overall reliability of the product of the humanoid dexterous hand needs to be improved, for example, the defect rate of the Shadow dexterous product is high.

Disclosure of Invention

The utility model aims to provide a tactile-sensing five-finger manipulator which solves the technical problems of imperfect integrated design, low degree of freedom, weak sensing capability and high failure rate of a humanoid manipulator in the prior art.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

the tactile perception five-finger manipulator comprises a palm module, a thumb module, a four-finger module and a tactile integrated module, wherein the thumb module and the four-finger module are sequentially connected to the palm module, the four-finger module is a four-finger head with the same structure, and the thumb module is sequentially provided with an index finger part, a middle finger part, a ring finger part and a little finger part from the near to the far;

the touch integrated module comprises a palm touch module and a finger touch module, wherein the palm touch module comprises a palm touch sensor arranged at the palm center of the palm module and a palm touch control board which is arranged on the palm module and connected with the palm touch sensor; the finger touch module comprises finger touch sensors arranged at the finger belly of the thumb module and the four-finger module finger and a finger touch control board which is arranged on the thumb module and the four-finger module and connected with the finger touch sensors.

The palm module comprises a palm main frame, a palm front shell, a palm back shell, a thumb rotary driving motor, a four-finger driving motor and a main control board, wherein the thumb rotary driving motor and the four-finger driving motor are respectively arranged on the palm main frame and are respectively in transmission connection with the thumb module and the four-finger module;

the fixed end of the thumb rotary driving motor is hinged with the palm main frame through a pin shaft mechanism, and the freedom degree of swinging around the axis of the pin shaft mechanism is provided;

the four-finger driving motors are four in number and are sequentially arranged on the palm main frame and are respectively in transmission connection with the index finger part, the middle finger part, the ring finger part and the little finger part;

the palm front shell and the back shell are sequentially fixed on the palm side and the back side of the main frame;

the main control board is arranged between the palm front shell and the back shell and is respectively and electrically connected with the thumb rotary driving motor, the four-finger driving motor and the touch integrated module;

the palm touch sensor is arranged on the palm front shell, and the palm touch control panel is arranged between the palm main frame and the back shell.

The palm module further comprises a palm soft rubber pad which is matched with the shape of the palm front shell, the palm soft rubber pad is laid on the outer surface of the palm front shell, and the palm touch sensor is located between the palm soft rubber pad and the outer side of the palm front shell.

The thumb module comprises a thumb rotary joint, a thumb rotary knuckle, a thumb proximal knuckle and a thumb distal knuckle;

the thumb rotary joint is a driving connecting block A, the upper end of the driving connecting block A is fixedly connected with the thumb rotary knuckle, the middle end of the driving connecting block A is hinged with the palm main frame, and the lower end of the driving connecting block A is hinged with the telescopic end of the thumb rotary driving motor;

the thumb rotating knuckle comprises a rotating knuckle shell and a rotating connecting knuckle, the thumb proximal knuckle comprises an extension and flexion driving motor, a thumb connecting rod and a thumb proximal shell, and the thumb terminal knuckle comprises a thumb terminal shell;

the lower end of the rotary knuckle shell is fixed with the driving connecting block A through a rotary connecting joint, and the rotary knuckle shell, the thumb near-end shell and the thumb end shell are hinged with each other from bottom to top to form a through cavity;

the telescopic end of the stretching and bending driving motor and the upper end of the thumb connecting rod are coaxially hinged below the thumb end shell, the fixed end of the stretching and bending driving motor penetrates through the cavity and is hinged with one side in the rotary knuckle shell, the lower end of the thumb connecting rod is hinged with the other side in the rotary knuckle shell, and the straight line of the thumb connecting rod is crossed with the connecting line of the hinging points of the thumb rotary knuckle, the thumb near-end knuckle and the thumb end knuckle in an X shape.

The joint of the rotary knuckle shell, the thumb near-end shell and the thumb tail-end shell is positioned at the joint of the back side and the palm side and is provided with a gap;

the thumb terminal joint comprises a driving connecting block B and a joint shaft, wherein the telescopic end of the extension and flexion driving motor is fixed with the bottom surface of the driving connecting block B, the joint shaft penetrates through the driving connecting block B and the thumb connecting rod and then is hinged with the thumb terminal shell, and the hinge point of the fixed end of the extension and flexion driving motor and the hinge point of the rotating knuckle shell is positioned below the hinge point of the rotating knuckle shell and the thumb proximal end shell.

The four-finger module comprises a base finger joint, a four-finger proximal finger joint, a four-finger middle finger joint and a four-finger distal finger joint; the base knuckle is a mounting block and is fixed at the upper end of the palm main frame, the four-finger proximal knuckle comprises a four-finger proximal shell, a driving connecting block C and a four-finger connecting rod, the four-finger middle knuckle comprises a four-finger middle end shell, the four-finger tail end knuckle comprises a four-finger tail end shell, the base knuckle, the four-finger proximal shell and the four-finger middle end shell are hinged in sequence from bottom to top, and the four-finger middle end shell is fixedly connected with the four-finger tail end shell;

the upper end of the driving connecting block C is hinged with one side of the palm center of the four-finger near-end shell, and the lower end of the driving connecting block C is hinged with the telescopic end of the four-finger driving motor;

the upper end of the four-finger connecting rod is hinged with the palm center side of the lower end of the four-finger middle end shell, and the lower end of the four-finger connecting rod is hinged with the back side of the base knuckle.

The rotary knuckle shell, the thumb near-end shell and the thumb end shell are all of split buckling structures, the rotary knuckle shell comprises a rotary knuckle 1 shell and a rotary knuckle 2 shell, the thumb near-end shell comprises a thumb near-end 1 shell and a thumb near-end 2 shell, and the thumb end shell comprises a thumb end 1 shell and a thumb end 2 shell;

the thumb terminal shell further comprises a thumb terminal middle shell, the thumb terminal middle shell is located between the thumb terminal 1 shell and the thumb terminal 2 shell, the thumb proximal end 2 shell is hinged with the thumb terminal middle shell, the finger touch sensor is applied to the inner surface of the thumb terminal 2 shell, and the finger touch control board is arranged between the thumb terminal 1 shell and the thumb terminal middle shell.

The four-finger proximal knuckle, the four-finger middle knuckle and the four-finger tail knuckle are all split buckling structures and respectively comprise a four-finger proximal 1 shell, a four-finger middle 1 shell, a four-finger tail 1 shell which are positioned on the back side of the hand, a four-finger proximal 2 shell, a four-finger middle 2 shell and a four-finger tail 2 shell which are positioned on the palm side;

the four-finger middle end 1 shell and the four-finger tail end 1 shell are of an integrated structure, the finger touch sensor is applied to the inner surface of the four-finger tail end 2 shell, and the finger touch control board is arranged in the four-finger middle end knuckle.

The palm module is characterized by further comprising motor pressing blocks fixed on the palm main frame, the four-finger driving motor is fixed on the palm main frame through the motor pressing blocks, the motor pressing blocks and the fixing surfaces of the four-finger driving motor are distributed in a step shape from high to low along the direction away from the thumb module, and fingertips of the four-finger module are different in height through the motor pressing blocks.

The palm module further comprises a palm support seat, a connecting base and a power switch, wherein the palm main frame is fixed on the palm support seat, and forms a five-finger manipulator main body together with the palm main frame, the thumb module and the four-finger module;

the connecting base is fixedly connected with the lower end of the palm supporting seat, and the five-finger manipulator main body is connected with an external manipulator and an external arm through the connecting base;

the power switch is electrically connected with the main control board.

The beneficial effects of adopting above-mentioned technical scheme to produce lie in:

according to the tactile-sensing five-finger manipulator provided by the utility model, the array type tactile sensor independently researched and developed by the company is adopted and is skillfully integrated in fingertips and palms of five fingers, so that the structural-sensing-control integrated design of the humanoid manipulator is realized, the manipulator can realize the sense of touch and slip in the grabbing process, and meanwhile, signals can be fed back to the main control board, so that the main control board can better control motors for driving the fingers to move, the safe grabbing of objects is ensured to the greatest extent, and the comprehensive performance of the tactile-sensing five-finger manipulator is in the industry leading level.

In addition, the lever structure is arranged to enable the root of the thumb to have one rotational degree of freedom, the thumb to have one extending and bending degree of freedom in a structure mode of connecting rods crossing, and the structure of connecting rods crossing is also arranged on the other four fingers, so that the other four fingers each have one extending and bending degree of freedom, and the grasping performance of the manipulator can be further improved. Meanwhile, the four fingers except for the thumb are identical in structure, the four fingers can be completely interchanged, the structure of the fingers can be simplified to the greatest extent, the processing cost and the assembly difficulty are saved, and the reliability and the control precision of the five-finger manipulator structure are greatly improved.

Drawings

Fig. 1a is a schematic diagram of the overall structure of a tactile-sensing five-finger manipulator provided by the utility model;

fig. 1b is a schematic structural diagram of the interior of the tactile-sensing five-finger manipulator provided by the utility model;

FIG. 2a is a schematic view of a thumb module of the haptic sensation five-finger manipulator of FIG. 1;

FIG. 2b is a schematic view of an exploded view of the thumb module of FIG. 2 a;

FIG. 2c is a partial cross-sectional view of the thumb rotary drive motor after connection with the thumb module;

FIG. 2d is a schematic view of a portion of the palm module where the thumb rotary drive motor is connected to the thumb module;

FIG. 3a is a schematic diagram of a four-finger module (i.e., index finger, middle finger, ring finger, little finger module) of the haptic sensation five-finger manipulator shown in FIG. 1;

FIG. 3b is a schematic diagram of an exploded structure of the four-finger module shown in FIG. 3 a;

FIG. 3c is a partial cross-sectional view of a four-finger drive motor in a palm module connected to a four-finger module;

FIG. 4 is a schematic diagram of a palm module structure in the haptic sensation five-finger manipulator of FIG. 1;

FIG. 5a is a schematic diagram of a tactile sensor integration module in a thumb module;

FIG. 5b is a schematic diagram of a tactile sensor integration module in a four-finger module;

FIG. 5c is a schematic diagram of a tactile sensor integration module in a palm module;

the figure indicates: 100. a thumb module; 101. a thumb rotating joint; 102. rotating the knuckle with the thumb; 103. a thumb proximal joint; 104. a thumb proximal knuckle; 105. a thumb terminal joint; 106. thumb tip knuckle; 1001. thumb tip 2 shell; 1002. middle shell of thumb end; 1003. thumb tip 1 shell; 1004. a thumb link; 1005. a thumb proximal end 1 housing; 1006. a thumb proximal end 2 housing; 1007. a joint shaft; 1008. driving the connecting block B; 1009. a connecting shaft 3; 1010. rotating the connecting joint; 1011. rotating the knuckle 2 housing; 1012. rotating the knuckle 1 housing; 1013. a stretch-bend driving motor;

200. an index finger part; 201. a base knuckle; 202. a basal joint; 203. four-finger proximal knuckle; 204. four-finger proximal joints; 205. middle finger joints of four fingers; 206. four finger tip knuckles; 2001. four finger tip 2 shells; 2002. four-finger middle end 1 shell; 2003. four-finger tip middle shell, 2004, four-finger middle end 2 shells; 2005. four finger tip 1 shell; 2006. four-finger connecting rod; 2007. a connecting shaft 1; 2008. a connecting shaft 2; 2009. driving the connecting block C; 2010. a motor connecting shaft; 2011. a motor transmission connecting block; 2012. four fingers proximal 2 shells; 2013a, basal 1 axis; 2013b, basal joint 2 axis; 2016. a torsion spring;

300. a middle finger; 400. ring finger part; 500. the little finger;

600. a palm module; 601. a palm main frame; 602. a four-finger drive motor; 606. a thumb rotation driving motor; 607. a motor pressing block; 608. a palm support base; 609. the base is connected; 610. a main control board; 611. a back shell of the hand; 612. a power switch; 613. palm front shell; 614. a pin shaft mechanism; 615. palm soft rubber pad;

700. a haptic integrated module; 701. a finger touch sensor; 702. a finger touch control panel; 703. palm tactile sensor; 704. palm touch control board.

Detailed Description

The present utility model will be described more fully hereinafter with reference to the accompanying drawings, in which the objects, structures, and functions of the utility model are shown.

As shown in fig. 1a and fig. 1b, the present embodiment provides a tactile-sensing five-finger manipulator, which specifically includes a palm module 600, a thumb module 100, a four-finger module and a tactile integrated module 700, wherein the thumb module 100 and the four-finger module are sequentially connected to the palm module 600, the four-finger module is four mechanical fingers with the same structure, and the four-finger module and the thumb module 100 sequentially include, from the near to the far, an index finger 200, a middle finger 300, a ring finger 400 and a little finger 500, so as to form a humanoid mechanical arm main body through the thumb module 100 and the four-finger module;

mainly, in order to enable the manipulator provided in this embodiment to achieve the perception of touch and sliding, the touch integrated module 700 includes a palm touch module and a finger touch module, where the palm touch module includes a palm touch sensor 703 disposed at the palm center of the palm module 600 and a palm touch control board 704 disposed on the palm module 600 and connected to the palm touch sensor 703, as shown in fig. 5c, by disposing the palm touch module, all components can be controlled to stop moving when the palm portion contacts a sensor threshold; in addition, the finger touch module includes finger touch sensors 701 disposed at the finger pads of the thumb module 100 and the four-finger module finger, and a finger touch control board 702 disposed on the thumb module 100 and the four-finger module and connected to the finger touch sensors 701, as shown in fig. 5a and 5b, when the object contacted between the thumb or the other four fingers reaches the sensor threshold, the corresponding finger stops moving. In this embodiment, all of the tactile sensors are array type tactile sensors developed by the company.

Further, as shown in fig. 4, the palm module 600 includes a palm main frame 601, a palm front shell 613, a back shell 611, a thumb rotation driving electric push rod 606, a four-finger driving motor 602, and a main control board 610, where the four-finger module is fixed on the palm main frame 601 through a base knuckle 201 disposed at the root of the four-finger module, and the thumb rotation driving electric push rod 606 and the four-finger driving motor 602 are respectively disposed on the palm main frame 601 and are respectively in transmission connection with the thumb module 100 and the four-finger module, and are used for driving the thumb to rotate towards the front of the palm, to make a palm motion, and to drive the other four fingers to make straightening and buckling motions;

specifically, as shown in fig. 1a and fig. 2d, the fixed end of the thumb rotation driving electric push rod 606 is hinged to the palm main frame 601 through a pin shaft mechanism 614, and has a degree of freedom of swinging around the axis of the pin shaft mechanism 614, and the telescopic end of the thumb rotation driving electric push rod 606 is hinged to one end of the thumb rotation joint 101 at the root of the thumb module 100, wherein the thumb rotation joint 101 at the root of the thumb module is hinged to the palm main frame 601, and has a degree of freedom of swinging around a hinge point with the palm main frame 601 under the driving of the thumb rotation driving electric push rod 606; meanwhile, the four-finger driving motors 602 are correspondingly and sequentially arranged on the palm main frame 601 and are respectively in transmission connection with the index finger portion 200, the middle finger portion 300, the ring finger portion 400 and the little finger portion 500.

Sequentially fixing the palm front shell 613 and the back shell 611 on the palm side and the back side of the main frame to form a complete palm shape; the main control board 610 is disposed between the front palm shell 613 and the back hand shell 611 and is electrically connected with the thumb rotary driving electric push rod 606, the four-finger driving motor 602 and the touch integrated module 700, respectively, for controlling the motion of each finger and palm of the manipulator, preferably, the main control board 610 is disposed on the main palm frame 601 at one side of the back hand shell 611;

further, as shown in fig. 5c, the palm touch sensor 703 is disposed on the outer surface of the palm front shell 613, the palm touch control board 704 is disposed between the palm main frame 601 and the back shell 611, and in order to protect the palm touch sensor 703, the palm module 600 further includes a palm soft rubber pad 615 having a shape adapted to the palm front shell 613, the palm soft rubber pad 615 is laid on the outer surface of the palm front shell 613, and the palm touch sensor 703 is located between the palm soft rubber pad 615 and the outer side of the palm front shell 613.

Further, as shown in fig. 2a, 2b, and 2c, the thumb module 100 includes a thumb rotating knuckle 102, a thumb proximal knuckle 104, a thumb distal knuckle 106, and a thumb rotating joint 101 for hinging the thumb rotating knuckle 102 and the thumb rotating driving electric push rod 606, a thumb proximal joint 103 for hinging the thumb rotating knuckle 102 and the thumb proximal knuckle 104, and a thumb distal joint 105 for hinging the thumb proximal knuckle 104 and the thumb distal knuckle 106, wherein the thumb distal joint 105 and the thumb proximal joint 103 are diagonally adjacent to the palm side and the back side, respectively, and the hinged rotating knuckle shell, thumb proximal shell and thumb distal shell form a through thumb inner cavity.

Specifically, the thumb rotary joint 101 is a driving connection block a, the upper end of the driving connection block a is fixedly connected with the thumb rotary knuckle 102, the middle end of the driving connection block a is hinged with the palm main frame 601, and the lower end of the driving connection block a is hinged with the telescopic end of the thumb rotary driving electric push rod 606;

the thumb rotary knuckle 102 comprises a rotary knuckle housing and a rotary joint 1010, the thumb proximal knuckle 104 comprises a flexion-extension drive motor 1013, a thumb link 1004, a thumb proximal housing, and the thumb distal knuckle 106 comprises a thumb distal housing;

the lower end of the rotary knuckle housing is fixed to the driving connection block a through a rotary connection joint 1010, the telescopic end of the stretch-bend driving motor 1013 is coaxially hinged to the upper end of the thumb connecting rod 1004 below the thumb terminal housing, and is close to the opposite side of the thumb terminal joint 105, namely the back side, the fixed end of the stretch-bend driving motor 1013 passes through the cavity and is hinged to one side in the rotary knuckle housing, the lower end of the thumb connecting rod 1004 is hinged to the rotary knuckle housing through a connection shaft C1009 and is located on the opposite side of the thumb proximal joint 103, and the line connecting the thumb connecting rod 1004 with the hinge points of the thumb proximal joint 103 and the thumb terminal joint 105 is in an 'X' -shaped cross structure. The above-described gearing relationship enables an active flexion-extension motion between the thumb proximal knuckle 104 and the thumb distal knuckle 106, and an underactuated flexion-extension motion between the thumb rotary knuckle 102 and the thumb proximal knuckle 104, thereby enabling the thumb to have degrees of freedom for flexion-extension.

Further, in order to prevent the shells at the joints from interfering when the thumb module 100 is flexed, gaps are left at the joints of the back side of the hand and the palm center side of the rotary knuckle shell, the thumb proximal shell and the thumb distal shell in the embodiment;

further, the thumb terminal joint 105 includes a driving connection block B1008 and a joint shaft 1007, the telescopic end of the extension driving motor 1013 is fixed to the bottom surface of the driving connection block B1008, the joint shaft 1007 passes through the driving connection block B1008 and the thumb connecting rod 1004 and is hinged to the thumb terminal shell, and the hinge point of the fixed end of the extension driving motor 1013 and the rotating knuckle shell is located below the hinge point of the rotating knuckle shell and the thumb proximal shell.

Further, for easy production and installation, the rotary knuckle housing, the thumb proximal housing and the thumb distal housing are all split-type fastening structures, the rotary knuckle housing comprises a rotary knuckle 1 housing 1012 and a rotary knuckle 2 housing 1011, the thumb proximal housing comprises a thumb proximal 1 housing 1005 and a thumb proximal 2 housing 1006, and the thumb distal housing comprises a thumb distal 1 housing 1003 and a thumb distal 2 housing 1001; the thumb tip housing further comprises a thumb tip middle housing 1002, the thumb tip middle housing 1002 is located between the thumb tip 1 housing 1003 and the thumb tip 2 housing 1001, the thumb proximal 2 housing 1006 is hinged with the thumb tip middle housing 1002, the finger touch sensor 701 is applied to the inner surface of the thumb tip 2 housing 1001, and the finger touch control board 702 is disposed between the thumb tip 1 housing 1003 and the thumb tip middle housing 1002.

Further, as shown in fig. 3a to 3c, the four-finger module includes a base knuckle 201, a four-finger proximal knuckle 203, a four-finger middle knuckle 205, a four-finger distal knuckle 206, and a base knuckle 202 for articulating the base knuckle 201 with the four-finger proximal knuckle 203, and a four-finger proximal knuckle 204 for articulating the four-finger proximal knuckle 203 with the four-finger middle knuckle 205. The base joint 202 and the four-finger proximal joint 204 are diagonally adjacent to the back of the hand and the palm of the palm, and the base joint 202 includes a base joint 1 axis 2013a and a base joint 2 axis 2013b.

Specifically, the base knuckle 201 is a mounting block and is fixed at the upper end of the palm main frame 601, the four-finger proximal knuckle 203 includes a four-finger proximal shell, a driving connection block C2009 and a four-finger connecting rod 2006, the four-finger middle knuckle 205 includes a four-finger middle shell, the four-finger tail knuckle 206 includes a four-finger tail shell, the base knuckle 201, the four-finger proximal shell and the four-finger middle shell are hinged in sequence from bottom to top, and the four-finger middle shell and the four-finger tail shell are fixedly connected; the upper end of the driving connection block C2009 is hinged with one side of the palm center of the four-finger near-end shell by a connection shaft B2008, and the lower end of the driving connection block C2009 is hinged with the telescopic end of the four-finger driving motor 602 by a motor connection shaft 2010 and a motor transmission connection block 2011; the upper end and the lower end of the four-finger connecting rod 2006 are respectively hinged with the palm side of the lower end shell of the middle end shell of the four fingers and the back side of the base knuckle 201 by a connecting shaft A2007.

In addition, for easy production and installation, the four-finger proximal knuckle 203, the four-finger middle knuckle 205, and the four-finger distal knuckle 206 are all split fastening structures, and each include a four-finger proximal 1 shell, a four-finger middle 1 shell 2002, a four-finger distal 1 shell 2005, a four-finger proximal 2 shell 2012, a four-finger middle 2 shell 2004, and a four-finger distal 2 shell 2001 on the back side of the hand; the four-finger middle end 1 shell 2002 and the four-finger tail end 1 shell 2005 are integrated, as shown in fig. 3b, the four-finger tail end shell further comprises a four-finger tail end middle shell 2003, the finger touch sensor 701 is applied on the inner surface between the four-finger tail end 2 shell 2001 and the four-finger tail end middle shell 2003, and the finger touch control board 702 is arranged in the four-finger middle end knuckle 205.

Further, in order to adjust the posture of the four-finger driving motor 602, it is convenient to be in transmission fit with four fingers, as shown in fig. 1b and fig. 4, the palm module 600 further includes a motor pressing block 607 fixed on the palm main frame 601, the four-finger driving motor 602 is fixed on the palm main frame 601 through the motor pressing block 607, the fixing surfaces of the motor pressing block 607 and the four-finger driving motor 602 are distributed in a step shape from high to low along the direction far away from the thumb module 100, and fingertips of the four-finger module have different heights through the motor pressing block 607.

Further, as shown in fig. 1b and fig. 4, the palm module 600 further includes a palm support base 608, a connection base 609, and a power switch 612, the palm main frame 601 is fixed on the palm support base 608, and forms a five-finger manipulator main body with the thumb module 100 and the four-finger module of the palm main frame 601, the connection base 609 is fixedly connected with the lower end of the palm support base 608, the five-finger manipulator main body is connected with an external manipulator and an external arm through the connection base 609, and the power switch 612 is electrically connected with the main control board 610.

It will be understood that the utility model has been described in terms of several embodiments, and that various changes and equivalents may be made to these features and embodiments by those skilled in the art without departing from the spirit and scope of the utility model. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the utility model without departing from the essential scope thereof. Therefore, it is intended that the utility model not be limited to the particular embodiment disclosed, but that the utility model will include all embodiments falling within the scope of the appended claims.

Claims (10)

1. A touch perception five-finger manipulator is characterized in that: the novel finger-type hand-held device comprises a palm module (600), a thumb module (100), a four-finger module and a touch sense integrated module (700), wherein the thumb module (100) and the four-finger module are sequentially connected to the palm module (600), the four-finger module is of four fingers with the same structure, and the thumb module (100) sequentially comprises an index finger part (200), a middle finger part (300), a ring finger part (400) and a little finger part (500) from the near to the far;

the touch integrated module (700) comprises a palm touch module and a finger touch module, wherein the palm touch module comprises a palm touch sensor (703) arranged at the palm center of the palm module (600) and a palm touch control board (704) which is arranged on the palm module (600) and connected with the palm touch sensor (703); the finger touch module comprises finger touch sensors (701) arranged at the finger belly of the thumb module (100) and the four-finger module finger, and a finger touch control board (702) arranged on the thumb module (100) and the four-finger module and connected with the finger touch sensors (701).

2. A tactile-sensing five-finger manipulator according to claim 1, wherein: the palm module (600) comprises a palm main frame (601), a palm front shell (613), a back shell (611), a thumb rotary driving electric push rod (606), a four-finger driving motor (602) and a main control board (610), wherein the thumb rotary driving electric push rod (606) and the four-finger driving motor (602) are respectively arranged on the palm main frame (601) and are respectively in transmission connection with the thumb module (100) and the four-finger module;

the fixed end of the thumb rotary driving electric push rod (606) is hinged with the palm main frame (601) through a pin shaft mechanism (614), and has the freedom degree of swinging around the axis of the pin shaft mechanism (614);

the four-finger driving motors (602) are four in number and are sequentially arranged on the palm main frame (601) and are respectively in transmission connection with the index finger part (200), the middle finger part (300), the ring finger part (400) and the little finger part (500);

the palm front shell (613) and the back shell (611) are sequentially fixed on the palm side and the back side of the main frame;

the main control board (610) is arranged between the palm front shell (613) and the back hand shell (611) and is respectively and electrically connected with the thumb rotary driving electric push rod (606), the four-finger driving motor (602) and the touch integrated module (700);

the palm touch sensor (703) is disposed on the palm front shell (613), and the palm touch control board (704) is disposed between the palm main frame (601) and the back shell (611).

3. A tactile-sensing five-finger manipulator according to claim 2, wherein: the palm module (600) further comprises a palm soft rubber pad (615) which is matched with the shape of the palm front shell (613), the palm soft rubber pad (615) is laid on the outer surface of the palm front shell (613), and the palm touch sensor (703) is located between the palm soft rubber pad (615) and the outer side of the palm front shell (613).

4. A tactile-sensing five-finger manipulator according to claim 2, wherein: the thumb module (100) comprises a thumb rotary joint (101), a thumb rotary knuckle (102), a thumb proximal knuckle (104), a thumb distal knuckle (106) and a thumb distal joint (105) for hinging the thumb proximal knuckle (104) and the thumb distal knuckle (106);

the thumb rotary joint (101) is a driving connecting block A, the upper end of the driving connecting block A is fixedly connected with the thumb rotary knuckle (102), the middle end of the driving connecting block A is hinged with the palm main frame (601), and the lower end of the driving connecting block A is hinged with the telescopic end of the thumb rotary driving electric push rod (606);

the thumb rotating knuckle (102) comprises a rotating knuckle shell and a rotating connection knuckle (1010), the thumb proximal knuckle (104) comprises an extension and flexion driving motor (1013), a thumb connecting rod (1004) and a thumb proximal shell, and the thumb terminal knuckle (106) comprises a thumb terminal shell;

the lower end of the rotary knuckle shell is fixed with the driving connecting block A through a rotary connecting joint (1010), and the rotary knuckle shell, the thumb near-end shell and the thumb end shell are hinged from bottom to top to form a through cavity;

the telescopic end of the stretching and bending driving motor (1013) is coaxially hinged below the thumb end shell with the upper end of the thumb connecting rod (1004), the fixed end of the stretching and bending driving motor (1013) penetrates through the cavity and is hinged with one side in the rotary knuckle shell, the lower end of the thumb connecting rod (1004) is hinged with the other side in the rotary knuckle shell, and the straight line of the thumb connecting rod (1004) is in X-shaped intersection with the connecting line of the hinging points of the thumb rotary knuckle (102), the thumb proximal knuckle (104) and the thumb distal knuckle (106).

5. A tactile-sensing five-finger manipulator according to claim 4, wherein: the joint of the rotary knuckle shell, the thumb near-end shell and the thumb tail-end shell is positioned at the joint of the back side and the palm side and is provided with a gap;

the thumb terminal joint (105) comprises a driving connecting block B (1008) and a joint shaft (1007), the telescopic end of the stretching driving motor (1013) is fixed with the bottom surface of the driving connecting block B (1008), the joint shaft (1007) passes through the driving connecting block B (1008) and the thumb connecting rod (1004) and then is hinged with the thumb terminal shell, and the hinge point of the fixed end of the stretching driving motor (1013) and the rotating knuckle shell is positioned below the hinge point of the rotating knuckle shell and the thumb proximal shell.

6. A tactile-sensing five-finger manipulator according to claim 2, wherein: the four-finger module comprises a base finger joint (201), a four-finger proximal finger joint (203), a four-finger middle finger joint (205) and a four-finger tail end finger joint (206); the base knuckle (201) is a mounting block and is fixed at the upper end of the palm main frame (601), the four-finger proximal knuckle (203) comprises a four-finger proximal shell, a driving connecting block C (2009) and a four-finger connecting rod (2006), the four-finger middle knuckle (205) comprises a four-finger middle end shell, the four-finger tail end knuckle (206) comprises a four-finger tail end shell, the base knuckle (201), the four-finger proximal shell and the four-finger middle end shell are hinged in sequence from bottom to top, and the four-finger middle end shell and the four-finger tail end shell are fixedly connected;

the upper end of the driving connecting block C (2009) is hinged with one side of the palm center of the four-finger near-end shell, and the lower end of the driving connecting block C is hinged with the telescopic end of the four-finger driving motor (602);

the upper end of the four-finger connecting rod (2006) is hinged with the palm side of the lower end of the four-finger middle end shell, and the lower end of the four-finger connecting rod is hinged with the back side of the base knuckle (201).

7. A tactile-sensing five-finger manipulator according to claim 4, wherein: the rotary knuckle shell, the thumb near-end shell and the thumb end shell are all of split buckling structures, the rotary knuckle shell comprises a rotary knuckle 1 shell (1012) and a rotary knuckle 2 shell (1011), the thumb near-end shell comprises a thumb near-end 1 shell (1005) and a thumb near-end 2 shell (1006), and the thumb end shell comprises a thumb end 1 shell (1003) and a thumb end 2 shell (1001);

the thumb tip shell further comprises a thumb tip middle shell (1002), the thumb tip middle shell (1002) is located between the thumb tip 1 shell (1003) and the thumb tip 2 shell (1001), the thumb proximal end 2 shell (1006) is hinged with the thumb tip middle shell (1002), the finger touch sensor (701) is applied to the inner surface of the thumb tip 2 shell (1001), and the finger touch control board (702) is arranged between the thumb tip 1 shell (1003) and the thumb tip middle shell (1002).

8. A tactile-sensing five-finger manipulator according to claim 6, wherein: the four-finger proximal knuckle (203), the four-finger middle knuckle (205) and the four-finger tail knuckle (206) are all of split buckling structures and respectively comprise a four-finger proximal 1 shell, a four-finger middle 1 shell (2002), a four-finger tail 1 shell (2005) which are positioned on the back side of the hand, a four-finger proximal 2 shell (2012), a four-finger middle 2 shell (2004) and a four-finger tail 2 shell (2001) which are positioned on the palm side;

the four-finger middle end 1 shell (2002) and the four-finger tail end 1 shell (2005) are of an integrated structure, the finger touch sensor (701) is applied on the inner surface of the four-finger tail end 2 shell (2001), and the finger touch control board (702) is arranged in the four-finger middle end knuckle (205).

9. A tactile-sensing five-finger manipulator according to claim 2, wherein: the palm module (600) further comprises motor pressing blocks (607) fixed on the palm main frame (601), the four-finger driving motor (602) is fixed on the palm main frame (601) through the motor pressing blocks (607), the motor pressing blocks (607) and the fixing surfaces of the four-finger driving motor (602) are distributed in a step shape from high to low along the direction away from the thumb module (100), and fingertips of the four-finger module are provided with different heights through the motor pressing blocks (607).

10. A tactile-sensing five-finger manipulator according to claim 2, wherein: the palm module (600) further comprises a palm support seat (608), a connecting base (609) and a power switch (612), wherein the palm main frame (601) is fixed on the palm support seat (608) and forms a five-finger mechanical arm main body together with the palm main frame (601), the thumb module (100) and the four-finger module;

the connecting base (609) is fixedly connected with the lower end of the palm supporting seat (608), and the five-finger manipulator main body is connected with an external manipulator and an external arm through the connecting base (609);

the power switch (612) is electrically connected with the main control board (610).