CN110834682A

CN110834682A - Internal friction type omnidirectional moving spherical robot

Info

Publication number: CN110834682A
Application number: CN201911283312.7A
Authority: CN
Inventors: 刘金国; 周浩; 冯靖凯
Original assignee: Shenyang Institute of Automation of CAS
Current assignee: Shenyang Institute of Automation of CAS
Priority date: 2019-12-13
Filing date: 2019-12-13
Publication date: 2020-02-25

Abstract

The invention belongs to the field of mobile robots, in particular to an internal friction type omnidirectional mobile spherical robot which comprises a spherical shell, an internal vibration attenuation module and a driving module, wherein the internal vibration attenuation module and the driving module are respectively accommodated in the spherical shell; the chassis is provided with a motor, an output shaft of the motor is connected with the omnidirectional wheel through a coupler, and the omnidirectional wheel is always abutted against the inner wall of the spherical shell through the elasticity of the damping spring. The invention has simple and reliable structure, realizes the omnidirectional movement of the spherical robot by controlling the omnidirectional wheel to rotate, and has the advantages of small volume, light weight, flexible movement, convenient carrying, strong climbing capability, convenient carrying and the like.

Description

Internal friction type omnidirectional moving spherical robot

Technical Field

The invention belongs to the field of mobile robots, and particularly relates to an internal friction type omnidirectional mobile spherical robot.

Background

Compared with traditional wheeled and crawler-type mobile robots, the spherical robot has good sealing performance and balance performance, can be moved in all directions, is convenient to carry, and is high in integration level. The existing counterweight eccentric spherical robot has the defects of weak obstacle crossing capability, inflexible turning and the like due to the increase of the mass; the variable structure spherical robot mechanism has complex design and poor ball sealing property; the internal friction type spherical robot has the advantages of flexible movement, small overall dimension, simple structure and the like. In addition, different sensors are carried on the spherical robot, and the spherical robot can be applied to different fields to complete different detection tasks.

Disclosure of Invention

The invention aims to provide an internal friction type omnidirectional moving spherical robot. The inner friction type omnidirectional moving spherical robot realizes the omnidirectional movement of the robot by controlling the omnidirectional wheel to rotate, and has the advantages of flexible movement, strong climbing capability, portability and the like.

The purpose of the invention is realized by the following technical scheme:

the invention comprises a spherical shell which is in direct contact with the ground, and an inner vibration reduction module and a driving module which are respectively accommodated in the spherical shell, wherein the spherical shell is divided into two parts which are mutually connected in a sealing way; the drive module is spherical robot's power supply, including chassis, motor, omniwheel and shaft coupling, the double-screw bolt is connected on the chassis, installs the motor on this chassis, the output shaft of motor passes through the shaft coupling and links to each other with the omniwheel, and this omniwheel passes through damping spring's elasticity all the time with the inner wall butt of spherical shell, motor drive omniwheel is rotatory, through frictional force between omniwheel and the spherical shell inner wall drives the spherical shell, and then realizes spherical robot's omnidirectional movement.

Wherein: the spherical shell is divided into two hemispherical shells which are connected in a sealing threaded manner; or, evenly seted up a plurality of screw hole A along the circumferencial direction on every hemisphere shell, screw hole A quantity on two hemisphere shells is the same, and the one-to-one correspondence, and equal threaded connection has the bolt on every screw hole A, links to each other through the connection piece between the corresponding bolt of two hemisphere shells.

The connecting piece is square and is provided with a capsule hole.

The inner vibration reduction supporting frame is a square frame, the bull's eye wheel is fixedly connected to an upper connecting plate of the inner vibration reduction supporting frame, a through hole is formed in a lower connecting plate of the inner vibration reduction supporting frame, and the upper end of the stud penetrates into the inner vibration reduction supporting frame through the through hole and is positioned through the nut.

The chassis comprises an upper chassis and a lower chassis, a motor support is arranged on the outer edge of the lower chassis, and the upper chassis is fixedly connected with the motor support.

Capsule holes are respectively formed in the upper chassis and the lower chassis at positions corresponding to the motors, and the capsule holes are radially formed in the radial direction.

The number of the motor supports is four, and each motor support is provided with a motor; the upper chassis and the lower chassis are both incomplete circles, namely, the parts of the outer edges of the upper chassis and the lower chassis corresponding to the motor support are straight line segments.

The four motors are uniformly arranged along the circumferential direction, the output shaft of each motor is connected with one omnidirectional wheel through a coupler, and the four omnidirectional wheels are arranged in two pairs in an orthogonal mode.

The coupling comprises a connecting shaft and a flange plate, wherein central holes are formed in the connecting shaft and the flange plate along the axial direction, and screw holes communicated with the central holes are formed in the connecting shaft along the radial direction; the flange plate is fixedly connected with the omnidirectional wheel, and the output shaft of the motor is inserted from the central hole and fixedly connected through a set screw arranged in the screw hole.

And a plurality of threaded holes B fixedly connected with the omnidirectional wheel are uniformly distributed on the flange plate along the circumferential direction.

The invention has the advantages and positive effects that:

the invention has simple and reliable structure, realizes the omnidirectional movement of the spherical robot by controlling the omnidirectional wheel to rotate, and has the advantages of small volume, light weight, flexible movement, convenient carrying, strong climbing capability, convenient carrying and the like.

Drawings

FIG. 1 is a schematic perspective view of the present invention in an assembled state;

FIG. 2 is a schematic view of the inner structure of the present invention with the spherical shell removed;

FIG. 3 is a second schematic view of the inner structure of the present invention with the spherical shell removed;

FIG. 4 is a schematic perspective view of an inner damping module according to the present invention;

FIG. 5 is a schematic perspective view of the inner damping frame of FIG. 4;

FIG. 6 is a schematic perspective view of a chassis in a driving module according to the present invention;

FIG. 7 is a schematic structural view of the upper base plate of FIG. 6;

FIG. 8 is a schematic structural view of the lower base plate of FIG. 6;

FIG. 9 is a schematic diagram of the distribution structure of the motor and the omni-directional wheel in the driving module according to the present invention;

FIG. 10 is a schematic view of the structure of the coupling in the driving module according to the present invention;

FIG. 11 is a schematic structural view of the driving module of the present invention after the motor and the omni wheel are mounted;

FIG. 12 is a schematic structural view of the drive module of the present invention after the shaft coupling and omni wheel are installed;

wherein: 1 is the spherical shell, 2 is the connection piece, 3 is interior damping module, 301 is interior damping carriage, 3011 is the upper junction plate, 3012 is lower connecting plate, 302 is damping spring, 303 is the backing sheet, 4 is drive module, 401 is the chassis, 4011 is last chassis, 4012 is lower chassis, 4013 is the capsule hole, 4014 is the motor support, 402 is the motor, 403 is the omniwheel, 404 is the shaft coupling, 4041 is the connecting axle, 4042 is the ring flange, 4043 is the centre bore, 4044 is screw hole B, 4045 is the screw hole, 4046 is holding screw, 5 is the double-screw bolt, 6 is the bull's eye wheel, 7 is the bolt.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1 to 3, the present invention includes a spherical shell 1, an inner vibration reduction module 3 and a driving module 4, wherein the spherical shell 1 is a part directly contacting with the ground, the inner vibration reduction module 3 and the driving module 4 are respectively accommodated in the spherical shell 1, and the spherical shell 1 is divided into two parts which are hermetically connected with each other; the spherical shell 1 of the embodiment is divided into two hemispherical shells which are connected by sealing threads; or, as shown in fig. 1, a plurality of (four in this embodiment) threaded holes a are uniformly formed in each hemispherical shell along the circumferential direction, the threaded holes a in the two hemispherical shells are the same in number and are in one-to-one correspondence, each threaded hole a is in threaded connection with a bolt 7, and the bolts 7 corresponding to the two hemispherical shells are connected through a connecting piece 2. The connecting piece 2 of this embodiment is square, and it has the capsule hole to seted up on it, improves actual assembly time gap redundancy nature. The inner damping module 3 increases the friction force by increasing the positive pressure between the omnidirectional wheel 403 and the inner wall of the spherical shell 1 to ensure the driving force, and can also play a damping role in the movement process of the spherical robot. The driving module 4 is a driving force source of the spherical robot and is fixedly connected with the inner vibration reduction module 3 through a stud 5.

As shown in fig. 3 to 5, the inner damping module 3 includes an inner damping support frame 301, a damping spring 302 and a support sheet 303, one end of the inner damping support frame 301 is connected to the driving module 4 through a stud 5, and the other end is provided with a bull's eye wheel 6; a support sheet 303 is arranged on the stud 5, and the support sheet 303 is positioned by a nut; the stud 5 between the support piece 303 and the inner vibration damping support frame 301 is sleeved with a vibration damping spring 302, and two ends of the vibration damping spring 302 are respectively abutted against the inner vibration damping support frame 301 and the support piece 303. The position of the support piece 303 can be adjusted by the nut, and the elasticity of the damping spring 302 can be adjusted, so that the positive pressure between the inner damping module 3 and the inner wall of the spherical shell 1 can be increased to improve the friction force. The bull-eye wheel 6 is always in relatively rolling contact with the inner wall of the spherical shell 1 by the elastic force of the damper spring 302. The inner vibration reduction supporting frame 301 of the embodiment is a square frame, and the bull-eye wheel 6 is fixedly connected to the upper connecting plate 3011 of the inner vibration reduction supporting frame 301 to roll on the inner wall of the spherical shell 1; a through hole 3013 is formed in a lower connecting plate 3012 of the inner vibration reduction supporting frame 301, and the upper end of the stud 5 penetrates into the inner vibration reduction supporting frame 301 through the through hole 3013 and is positioned through a nut. When the spherical robot moves and jolts, the driving module 4 drives the stud 5 and the supporting sheet 303 to move upwards, and the damping spring 302 is compressed; when the apex is reached, the damping spring 302 recovers length and the reciprocating motion acts as a damping.

As shown in fig. 6 to 9, the driving module 4 includes a chassis 401, a motor 402, an omnidirectional wheel 403 and a coupling 404, the stud 5 is connected to the chassis 401, the motor 402 is mounted on the chassis 401, an output shaft of the motor 402 is connected to the omnidirectional wheel 403 through the coupling 404, the omnidirectional wheel 403 is always abutted to the inner wall of the spherical shell 1 through the elastic force of the damping spring 302, the motor 402 drives the omnidirectional wheel 403 to rotate, the spherical shell 1 is driven by the friction force between the omnidirectional wheel 403 and the inner wall of the spherical shell 1, and the omnidirectional movement of the spherical robot is further realized. The chassis 401 of the embodiment includes an upper chassis 4011 and a lower chassis 4012, and the other end of the stud 5 is respectively and fixedly connected to the centers of the upper and

lower chassis

4011 and 4012; the outer edge of the lower chassis 4012 is provided with a motor support 4014, and the upper chassis 4011 is fixedly connected with the motor support 4014. The number of the motor supports 4014 is four, and each motor support 4014 is provided with a motor 402; the upper chassis 4011 and the lower chassis 4012 have the same shape and are both incomplete circles, that is, the outer edges of the upper chassis 4011 and the lower chassis 4012 are straight line segments corresponding to the motor support 4014. The number of the motors 402 in this embodiment is four, and the motors are uniformly arranged along the circumferential direction, an output shaft of each motor 402 is connected with one omni wheel 403 through a coupler 404, and the four omni wheels 403 are arranged in two pairs in an orthogonal manner and uniformly distributed at 90 degrees. The omni-directional wheel 403 has the characteristics of positive active rolling and lateral passive movement, and the spherical robot is moved by changing the center of gravity of the spherical robot by controlling the movement of the omni-directional wheel 403. The wheels of the omnidirectional wheel 403 are made of soft rubber materials, and the friction force between the omnidirectional wheel 403 and the inner wall of the spherical shell 1 is increased by increasing the friction coefficient, so that the driving force is improved. Capsule holes 4013 are respectively formed in the upper chassis 4011 and the lower chassis 4012 of the embodiment, corresponding to the position of each motor 402, and the capsule holes 4013 are radially formed, so that the mass of the spherical robot can be reduced, and the spherical robot can be used for fixing modules such as a control panel, a driver and a sensor.

As shown in fig. 10 to 12, the coupling 404 includes a connecting shaft 4041 and a flange 4042, the connecting shaft 4041 and the flange 4042 are axially provided with a central hole 4043, and the connecting shaft 4041 is radially provided with a screw hole 4045 communicating with the central hole 4043; a plurality of (four in this embodiment) threaded holes B4044 fixedly connected to the hub of the omni wheel 403 are uniformly distributed in the flange 4042 in the circumferential direction, and the output shaft of the motor 402 is inserted through the central hole 4043 and fixedly connected to the hub by fastening screws 4046 installed in the threaded holes 4045.

The omni-directional wheel 403 and the bull's eye wheel 6 of the present invention are prior art and will not be described herein.

The installation of the invention is as follows:

first, the motor 402 is mounted on the motor support 4014 of the lower chassis 4012, and then the flange 4042 of the coupling 404 is connected to the hub of the omni wheel 403, and the output shaft of the motor 402 is connected to the connecting shaft 4041 of the coupling 404.

Then, the bull's eye wheel 6 is connected with the upper connecting plate 3011 of the inner vibration reduction supporting frame 301, the vibration reduction spring 302 is abutted with the lower connecting plate 3012 of the inner vibration reduction supporting frame, the supporting sheet 303 is abutted with the vibration reduction spring 302 and is connected through the stud 5; and the inner damping module 3 is connected with the driving module 4 through a stud 5.

Then the connected inner vibration damping module 3 and the driving module 4 are put into one hemispherical shell, and the other hemispherical shell is attached to the hemispherical shell, and the uniformly distributed threaded holes A are opposite; finally, the two hemispherical shells are connected together by a connecting piece 2.

Claims

1. The utility model provides an internal friction formula omnidirectional movement spherical robot which characterized in that: comprises a spherical shell (1) which is directly contacted with the ground, an inner vibration reduction module (3) and a driving module (4) which are respectively contained in the spherical shell (1), wherein the spherical shell (1) is divided into two parts which are mutually connected in a sealing way, the inner vibration damping module (3) comprises an inner vibration damping supporting frame (301), a vibration damping spring (302) and a supporting sheet (303), one end of the inner vibration reduction supporting frame (301) is connected with the driving module (4) through a stud (5), the other end is provided with a bull-eye wheel (6), a supporting sheet (303) is arranged on the stud (5), a vibration damping spring (302) is sleeved on the stud (5) between the supporting sheet (303) and the inner vibration damping supporting frame (301), two ends of the damping spring (302) are respectively abutted with the inner damping supporting frame (301) and the supporting piece (303), the bull-eye wheel (6) is in relative rolling contact with the inner wall of the spherical shell (1) through the elastic force of the damping spring (302); drive module (4) is spherical robot's power supply, including chassis (401), motor (402), omniwheel (403) and shaft coupling (404), double-screw bolt (5) are connected on chassis (401), install motor (402) on this chassis (401), the output shaft of motor (402) passes through shaft coupling (404) and links to each other with omniwheel (403), and this omniwheel (403) pass through the elasticity of damping spring (302) is all the time with the inner wall butt of spherical shell (1), motor (402) drive omniwheel (403) are rotatory, through frictional force between omniwheel (403) and spherical shell (1) inner wall drives spherical shell (1), and then realize spherical robot's omnidirection removes.

2. The internal friction type omni-directional mobile spherical robot according to claim 1, wherein: the spherical shell (1) is divided into two hemispherical shells which are connected in a sealing threaded manner; or, evenly seted up a plurality of screw hole A along the circumferencial direction on every hemisphere shell, screw hole A quantity on two hemisphere shells is the same, and the one-to-one, and equal threaded connection has bolt (7) on every screw hole A, links to each other through connection piece (2) between two hemisphere shell corresponding bolt (7).

3. The internal friction type omni-directional mobile spherical robot according to claim 2, wherein: the connecting piece (2) is square and is provided with a capsule hole.

4. The internal friction type omni-directional mobile spherical robot according to claim 1, wherein: interior damping carriage (301) are square frame, on damping carriage (301) upper junction plate (3011) including bull's eye wheel (6) rigid coupling, through-hole (3013) have been seted up on lower connecting plate (3012) of interior damping carriage (301), during the upper end of double-screw bolt (5) penetrated interior damping carriage (301) by this through-hole (3013) to through the nut location.

5. The internal friction type omni-directional mobile spherical robot according to claim 1, wherein: the chassis (401) comprises an upper chassis (4011) and a lower chassis (4012), a motor support (4014) is arranged on the outer edge of the lower chassis (4012), and the upper chassis (4011) is fixedly connected with the motor support (4014).

6. The internal friction type omni-directional mobile spherical robot according to claim 5, wherein: capsule holes (4013) are respectively formed in the positions, corresponding to the motor (402), of the upper chassis (4011) and the lower chassis (4012), and the capsule holes (4013) are radially formed in the radial direction.

7. The internal friction type omni-directional mobile spherical robot according to claim 5, wherein: the number of the motor supports (4014) is four, and each motor support (4014) is provided with a motor (402); the upper chassis (4011) and the lower chassis (4012) are both incomplete circles, namely, the parts of the outer edges of the upper chassis (4011) and the lower chassis (4012) corresponding to the motor support (4014) are straight line segments.

8. The internal friction type omni-directional mobile spherical robot according to claim 1, wherein: the four motors (402) are uniformly arranged along the circumferential direction, the output shaft of each motor (402) is connected with one omnidirectional wheel (403) through a coupler (404), and the four omnidirectional wheels (403) are arranged in two pairs in an orthogonal mode.

9. The internal friction type omni-directional mobile spherical robot according to claim 1, wherein: the coupling (404) comprises a connecting shaft (4041) and a flange plate (4042), a central hole (4043) is axially formed in the connecting shaft (4041) and the flange plate (4042), and a screw hole (4045) communicated with the central hole (4043) is radially formed in the connecting shaft (4041); the flange plate (4042) is fixedly connected with the omnidirectional wheel (403), and the output shaft of the motor (402) is inserted through the central hole (4043) and fixedly connected through a set screw (4046) arranged in a screw hole (4045).

10. The internal friction omni-directional mobile spherical robot according to claim 9, wherein: and a plurality of threaded holes B (4044) fixedly connected with the omnidirectional wheel (403) are uniformly distributed on the flange plate (4042) along the circumferential direction.