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CN103707291A - Multi-degree-of-freedom parallel mechanism type controllable palletizing robot - Google Patents

Multi-degree-of-freedom parallel mechanism type controllable palletizing robot Download PDF

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Publication number
CN103707291A
CN103707291A CN201310692803.3A CN201310692803A CN103707291A CN 103707291 A CN103707291 A CN 103707291A CN 201310692803 A CN201310692803 A CN 201310692803A CN 103707291 A CN103707291 A CN 103707291A
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CN
China
Prior art keywords
connecting rod
revolute pair
link
drives
palletizing robot
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Pending
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CN201310692803.3A
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Chinese (zh)
Inventor
蔡敢为
胥刚
张�林
高德中
于腾
吕姗姗
丁侃
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Guangxi University
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Guangxi University
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Priority to CN201310692803.3A priority Critical patent/CN103707291A/en
Publication of CN103707291A publication Critical patent/CN103707291A/en
Pending legal-status Critical Current

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Abstract

The invention discloses a multi-degree-of-freedom parallel mechanism type controllable palletizing robot. The palletizing robot comprises a plurality of parallel mechanism closed-loop executing mechanism branch chains and a serial executing mechanism main chain. The mechanism closed-loop branch chains can be used for controlling a main chain connecting rod to move in a plane where a four-rod mechanism closed-loop branch chain is positioned, and spatial movement of a movable platform can be realized via movement of a plurality of parallel connecting rod branch chains and a machine body. Control is realized via composite motion of four closed-loop branch chains and the machine body, and a plurality of connecting rods are connected with the machine body, thereby realizing spatial movement of a tail end executer, small motion inertia of the tail end executer, high dynamics performance and high reliability. The mechanism has the advantages of compact structure and easiness in controlling. Rod pieces can be designed as light rods, the working space of the mechanism is large, and the gravity center of the mechanism is moved backward, thereby keeping the mechanism in a balanced state, and allowing the palletizing robot to be applied to more occasions.

Description

A kind of multiple freedom parallel mechanism formula controlled stacking robot
Technical field
The present invention relates to robot field, particularly a kind of multiple freedom parallel mechanism formula controlled stacking robot.
Background technology
Traditional serial machine people has the advantages such as simple in structure, cost is low, working space is large, and serial machine people rigidity is low comparatively speaking, can not be applied at a high speed the occasion of large carrying; Parallel robot and traditional serial machine people compare, have without accumulated error, precision compared with high, compact conformation, the feature such as bearing capacity is large, rigidity is high and end effector inertia is little, drive unit can be placed on fixed platform or approach the position of fixed platform, motion parts is lightweight like this, speed is high, and dynamic response is good; But the distinct disadvantage of the parallel robot little and complex structure that is working space.In engineering, the existing manipulator with local closed chain does not solve the problem that industrial robot exists as MOTOMAN-K10, and the general parallel institution of the Performance Ratio of the parallel robot of the closed loop subchain that contains symmetrical mechanism formula is more superior, have that working space is large, rigidity is high, bearing capacity is strong, inertia is little and end effector precision advantages of higher, can be applied in the complex jobs such as welding, spraying, carrying, handling, assembling, piling, effective raises labour efficiency, and aspect product quality and stability, is improving a lot.Adopt the manipulator of circular cylindrical coordinate type and joint coordinates type effectively and efficiently to tail house, to control, and this mechanism structure good rigidity, machine driving precision are high, working space is large, machine driving loss is little, without accumulated error, can export larger power, have and have good control function.This robot containing parallel closed loop subchain adopts indirect type of drive, can also effectively reduce the needed moment of driving joint.
Summary of the invention
The object of the present invention is to provide a kind of multiple freedom parallel mechanism formula controlled stacking robot, solve traditional serial machine people large about required moment, the low and little shortcoming of working space of rigidity.
The present invention achieves the above object by the following technical programs: a kind of multiple freedom parallel mechanism formula controlled stacking robot, and its structure and connected mode are:
Described executing agency chain is by fuselage 2, first connecting rod 3, second connecting rod 7, third connecting rod 5, the 4th connecting rod 20, the 5th connecting rod 23, the 6th connecting rod 21, seven-link assembly 11, the 8th connecting rod 12, the 9th connecting rod 18, the tenth connecting rod 14, the 11 connecting rod 15, the 12 connecting rod 26, the 13 connecting rod 27, the 14 connecting rod 29, end effector 30 and frame 1 are formed by connecting, fuselage 2 first links 31 are connected in frame 1 by the first revolute pair 31, fuselage 2 drives by the first revolute pair 31, the first revolute pair 31 drives by motor, 2 second links 32 of fuselage connect by second revolute pair 32 first connecting rod 3 one end, first connecting rod 3 drives by the second revolute pair 32, first connecting rod 3 other ends are connected with second connecting rod 7 first links 4 by the 3rd revolute pair 4, 7 second links 6 of second connecting rod are connected with third connecting rod 5 one end by the 4th revolute pair 6, third connecting rod 5 other ends are connected with the 4th connecting rod 20 first links 25 by the 5th revolute pair 25, the 4th 20 second, connecting rod link 24 is connected with the 5th connecting rod 23 one end by the 6th revolute pair 24, the 5th connecting rod 23 other ends are connected with the 6th connecting rod 21 one end by the 7th revolute pair 22, the 6th connecting rod 21 other ends are connected with the 8th connecting rod 12 first links 34 by the 4th link 34 of the 8th revolute pair 34 and seven-link assembly 11, the 3rd link of seven-link assembly 11 19 is connected by the 3rd link 19 of the 9th revolute pair 19 and the 4th connecting rod 20, seven-link assembly 11 first links 9 are connected by the 3rd link 9 of the tenth revolute pair 9 and second connecting rod 3, 11 second links of seven-link assembly 8 are connected by the 3rd link 8 of the 11 revolute pair 8 and fuselage 2, the 8th 12 second, connecting rod link 10 is connected with the tenth connecting rod 14 by the 12 revolute pair 10, the tenth connecting rod 14 other ends are connected by 18 second links 16 of the 13 revolute pair 16 and the 9th connecting rod, the 8th the 3rd, connecting rod 12 connects 13 ends and is connected with the 11 connecting rod 15 by the 14 revolute pair 13, the 11 connecting rod 15 other ends are connected by the 3rd link 17 of the 15 revolute pair 17 and the 9th connecting rod 18, the 9th connecting rod 18 first links 35 are connected with seven-link assembly 11 by the 16 revolute pair 35, the 9th the 4th, connecting rod 18 link 36 is connected with the 12 connecting rod 26 one end by being rigidly connected, the 12 connecting rod 26 other ends are connected with the 13 connecting rod 27 one end by the 17 revolute pair 37, the 12 connecting rod 26 drives by the 17 revolute pair 37, the 17 revolute pair 37 drives by motor, the 13 connecting rod 27 other ends are connected with the 14 connecting rod 29 one end by the 18 revolute pair 28, the 13 drives by the 18 revolute pair 28, the 18 revolute pair 28 drives by motor, the 14 connecting rod 29 other ends are connected with end effector 30 by the 19 revolute pair 38, end effector 30 drives by the 19 revolute pair 38, the 19 revolute pair 38 drives by motor,
Described the first revolute pair is perpendicular to frame, and the second revolute pair, the 3rd revolute pair, the 4th revolute pair, the 5th revolute pair, the 6th revolute pair, the 7th revolute pair, the 8th revolute pair, the 9th revolute pair, the tenth revolute pair, the 11 revolute pair, the 12 revolute pair, the 13 revolute pair, the 14 revolute pair and the 15 revolute pair rotation are parallel to each other.
Outstanding advantages of the present invention is:
1, by two parallel closed loop subchains, improved the rigidity of robot mechanism, and the design of closed loop subchain mechanism type improves the working space of robot greatly, can avoid the dead-centre position of mechanism, the sphere of action of micromatic setting Neng Shi robot is larger, and Neng Shi mechanism better keeps balance;
2, the industrial robot that is mounted in each joint with traditional motor is compared, the motor of the robot that mechanism connects by two parallel closed loop subchains is mounted on four-bar mechanism joint, by the kinematic pair on four-bar mechanism, drive closed loop chain movement, thereby indirectly drive tail end connecting rod, make mobility and the activity space of end effector larger, can reduce active moment;
3, compare with robot mechanism of the same type, under equal-wattage, work is more;
4, motor be arranged on connecting rod after, reduced the center of gravity of whole mechanism, and can installation power larger motor is in mechanism, and end effector can be adapted in the complex jobs such as welding, spraying, carrying, handling, assembling, piling;
5, robot mechanism endways actuator by mechanism type, controlled, can make precision higher;
6, mechanism type mechanism is connected with end effector with a with gemel connecting rod between carrying out with end, make actuator flexibility ratio higher, working space is larger than robot in the past, and with gemel connecting rod is made lighter bar, can make whole mechanism power performance better and be easy to control, can make end effector among a small circle, rotate 360 degree round angles, make mechanism can be applicable to more occasions;
7, in two parallel closed loop subchains, rod member is made lighter bar, and mechanism kinematic inertia is little, and dynamic performance is good;
8, the micromatic setting in mechanism is compared with traditional manipulator with local closed chain, and center of gravity concentrates on micromatic setting, and balance of mechanism is good, can make robot mechanism bear larger force and moment;
9, six-freedom degree makes mechanism can be applied to more occasions;
Accompanying drawing explanation
Fig. 1 is the first structural representation of a kind of multiple freedom parallel mechanism formula controlled stacking robot of the present invention.
Fig. 2 is the airframe structure schematic diagram of a kind of multiple freedom parallel mechanism formula controlled stacking robot of the present invention.
Fig. 3 is the second connecting rod schematic diagram of a kind of multiple freedom parallel mechanism formula controlled stacking robot of the present invention.
Fig. 4 is the seven-link assembly schematic diagram of a kind of multiple freedom parallel mechanism formula controlled stacking robot of the present invention.
Fig. 5 is the 8th connecting rod schematic diagram of a kind of multiple freedom parallel mechanism formula controlled stacking robot of the present invention.
Fig. 6 is the 9th connecting rod schematic diagram of a kind of multiple freedom parallel mechanism formula controlled stacking robot of the present invention.
Fig. 7 is the 13 connecting rod schematic diagram of a kind of multiple freedom parallel mechanism formula controlled stacking robot of the present invention.
Fig. 8 is the 14 connecting rod schematic diagram of a kind of multiple freedom parallel mechanism formula controlled stacking robot of the present invention.
Fig. 9 is that the mechanism of a kind of multiple freedom parallel mechanism formula controlled stacking robot of the present invention connects intention.
Figure 10 is the work schematic diagram of a kind of multiple freedom parallel mechanism formula controlled stacking robot of the present invention.
Figure 11 is the work schematic diagram of a kind of multiple freedom parallel mechanism formula controlled stacking robot of the present invention.
The specific embodiment
Below in conjunction with drawings and Examples, technical scheme of the present invention is described further.
Contrast Fig. 1, Fig. 2, Fig. 3, Fig. 4, Fig. 5 and Fig. 6, a kind of multiple freedom parallel mechanism formula controlled stacking robot, its structure and connected mode are:
Described executing agency chain is by fuselage 2, first connecting rod 3, second connecting rod 7, third connecting rod 5, the 4th connecting rod 20, the 5th connecting rod 23, the 6th connecting rod 21, seven-link assembly 11, the 8th connecting rod 12, the 9th connecting rod 18, the tenth connecting rod 14, the 11 connecting rod 15, the 12 connecting rod 26, the 13 connecting rod 27, the 14 connecting rod 29, end effector 30 and frame 1 are formed by connecting, fuselage 2 first links 31 are connected in frame 1 by the first revolute pair 31, fuselage 2 drives by the first revolute pair 31, the first revolute pair 31 drives by motor, 2 second links 32 of fuselage connect by second revolute pair 32 first connecting rod 3 one end, first connecting rod 3 drives by the second revolute pair 32, first connecting rod 3 other ends are connected with second connecting rod 7 first links 4 by the 3rd revolute pair 4, 7 second links 6 of second connecting rod are connected with third connecting rod 5 one end by the 4th revolute pair 6, third connecting rod 5 other ends are connected with the 4th connecting rod 20 first links 25 by the 5th revolute pair 25, the 4th 20 second, connecting rod link 24 is connected with the 5th connecting rod 23 one end by the 6th revolute pair 24, the 5th connecting rod 23 other ends are connected with the 6th connecting rod 21 one end by the 7th revolute pair 22, the 6th connecting rod 21 other ends are connected with the 8th connecting rod 12 first links 34 by the 4th link 34 of the 8th revolute pair 34 and seven-link assembly 11, the 3rd link of seven-link assembly 11 19 is connected by the 3rd link 19 of the 9th revolute pair 19 and the 4th connecting rod 20, seven-link assembly 11 first links 9 are connected by the 3rd link 9 of the tenth revolute pair 9 and second connecting rod 3, 11 second links of seven-link assembly 8 are connected by the 3rd link 8 of the 11 revolute pair 8 and fuselage 2, the 8th 12 second, connecting rod link 10 is connected with the tenth connecting rod 14 by the 12 revolute pair 10, the tenth connecting rod 14 other ends are connected by 18 second links 16 of the 13 revolute pair 16 and the 9th connecting rod, the 8th the 3rd, connecting rod 12 connects 13 ends and is connected with the 11 connecting rod 15 by the 14 revolute pair 13, the 11 connecting rod 15 other ends are connected by the 3rd link 17 of the 15 revolute pair 17 and the 9th connecting rod 18, the 9th connecting rod 18 first links 35 are connected with seven-link assembly 11 by the 16 revolute pair 35, the 9th the 4th, connecting rod 18 link 36 is connected with the 12 connecting rod 26 one end by being rigidly connected, the 12 connecting rod 26 other ends are connected with the 13 connecting rod 27 one end by the 17 revolute pair 37, the 12 connecting rod 26 drives by the 17 revolute pair 37, the 17 revolute pair 37 drives by motor, the 13 connecting rod 27 other ends are connected with the 14 connecting rod 29 one end by the 18 revolute pair 28, the 13 drives by the 18 revolute pair 28, the 18 revolute pair 28 drives by motor, the 14 connecting rod 29 other ends are connected with end effector 30 by the 19 revolute pair 38, end effector 30 drives by the 19 revolute pair 38, the 19 revolute pair 38 drives by motor,
Described the first revolute pair is perpendicular to frame, and the second revolute pair, the 3rd revolute pair, the 4th revolute pair, the 5th revolute pair, the 6th revolute pair, the 7th revolute pair, the 8th revolute pair, the 9th revolute pair, the tenth revolute pair, the 11 revolute pair, the 12 revolute pair, the 13 revolute pair, the 14 revolute pair and the 15 revolute pair rotation are parallel to each other.
Contrast Fig. 2, Fig. 3, Fig. 4, Fig. 5, Fig. 6 and Fig. 7, fuselage and first connecting rod motion planar can realize the spatial movement of end effector.

Claims (1)

1. a multiple freedom parallel mechanism formula controlled stacking robot, its structure and connected mode are:
Described executing agency chain is by fuselage, first connecting rod, second connecting rod, third connecting rod, the 4th connecting rod, the 5th connecting rod, the 6th connecting rod, seven-link assembly, the 8th connecting rod, the 9th connecting rod, the tenth connecting rod, the 11 connecting rod, the 12 connecting rod, the 13 connecting rod, the 14 connecting rod, end effector and frame are formed by connecting, first link of fuselage is connected in frame by the first revolute pair, fuselage drives by the first revolute pair, the first revolute pair drives by motor, second link of fuselage connects by second revolute pair first connecting rod one end, first connecting rod drives by the second revolute pair, the first connecting rod other end is connected by the 3rd first link of revolute pair and second connecting rod, second link of second connecting rod is connected with third connecting rod one end by the 4th revolute pair, the third connecting rod other end is connected with the 4th first link of connecting rod by the 5th revolute pair, the 4th second, connecting rod link is connected with the 5th connecting rod one end by the 6th revolute pair, the 5th connecting rod other end is connected with the 6th connecting rod one end by the 7th revolute pair, the 6th connecting rod other end is connected with the 8th first link of connecting rod by the 4th link of the 8th revolute pair and seven-link assembly, the 3rd link of seven-link assembly is connected by the 3rd link of the 9th revolute pair and the 4th connecting rod, first link of seven-link assembly is connected by the 3rd link of the tenth revolute pair and second connecting rod, second link of seven-link assembly is connected by the 3rd link of the 11 revolute pair and fuselage, the 8th second, connecting rod link is connected with the tenth connecting rod by the 12 revolute pair, the tenth connecting rod other end is connected by second link of the 13 revolute pair and the 9th connecting rod, the 8th the 3rd, connecting rod link is connected with the 11 connecting rod by the 14 revolute pair, the 11 connecting rod other end is connected by the 3rd link of the 15 revolute pair and the 9th connecting rod, the 9th first link of connecting rod is connected with seven-link assembly by the 16 revolute pair, the 9th the 4th, connecting rod link is connected with the 12 connecting rod one end by being rigidly connected, the 12 connecting rod other end is connected with the 13 connecting rod one end by the 17 revolute pair, the 12 connecting rod drives by the 17 revolute pair, the 17 revolute pair drives by motor, the 13 connecting rod other end is connected with the 14 connecting rod one end by the 18 revolute pair, the 13 connecting rod drives by the 18 revolute pair, the 18 revolute pair drives by motor, the 14 connecting rod other end is connected with end effector by the 19 revolute pair, end effector drives by the 19 revolute pair, the 19 revolute pair drives by motor,
Described the first revolute pair is perpendicular to frame, and the second revolute pair, the 3rd revolute pair, the 4th revolute pair, the 5th revolute pair, the 6th revolute pair, the 7th revolute pair, the 8th revolute pair, the 9th revolute pair, the tenth revolute pair, the 11 revolute pair, the 12 revolute pair, the 13 revolute pair, the 14 revolute pair and the 15 revolute pair rotation are parallel to each other.
CN201310692803.3A 2013-12-17 2013-12-17 Multi-degree-of-freedom parallel mechanism type controllable palletizing robot Pending CN103707291A (en)

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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104476536A (en) * 2014-12-10 2015-04-01 广西大学 Multi-degree-of-freedom controllable parallel type mobile robot
CN104526689A (en) * 2014-12-18 2015-04-22 广西大学 Parallel controllable mechanism type multi-freedom-degree moving stacking robot
CN104526676A (en) * 2014-12-18 2015-04-22 广西大学 Wheel type mobile robot palletizer with multiple closed-loop sub chains
CN104526690A (en) * 2014-12-18 2015-04-22 广西大学 Mechanism type mobile mechanical hand with multiple degrees of freedom
CN104626103A (en) * 2014-12-18 2015-05-20 广西大学 Multi-freedom-degree parallel mechanism type controllable moving palletizing robot
CN110024528A (en) * 2019-05-29 2019-07-19 山东理工大学 A kind of implantation methods of plant

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CN1923468A (en) * 2006-09-08 2007-03-07 清华大学 Robot for carrying and piling
US20120067156A1 (en) * 2010-09-21 2012-03-22 Hon Hai Precision Industry Co., Ltd. Robot for handling object
CN103029124A (en) * 2012-12-27 2013-04-10 广西大学 Multi-degree-of-freedom controllable mechanism type stacking robot
CN103121589A (en) * 2012-12-27 2013-05-29 广西大学 Carrying stacking mechanism

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS52135164A (en) * 1976-05-04 1977-11-11 Aida Eng Ltd Holding and conveying apparatus
US4718815A (en) * 1984-11-28 1988-01-12 Avp Robot Ab Device for carrying and adjusting a tool
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CN1923468A (en) * 2006-09-08 2007-03-07 清华大学 Robot for carrying and piling
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CN103029124A (en) * 2012-12-27 2013-04-10 广西大学 Multi-degree-of-freedom controllable mechanism type stacking robot
CN103121589A (en) * 2012-12-27 2013-05-29 广西大学 Carrying stacking mechanism

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104476536A (en) * 2014-12-10 2015-04-01 广西大学 Multi-degree-of-freedom controllable parallel type mobile robot
CN104526689A (en) * 2014-12-18 2015-04-22 广西大学 Parallel controllable mechanism type multi-freedom-degree moving stacking robot
CN104526676A (en) * 2014-12-18 2015-04-22 广西大学 Wheel type mobile robot palletizer with multiple closed-loop sub chains
CN104526690A (en) * 2014-12-18 2015-04-22 广西大学 Mechanism type mobile mechanical hand with multiple degrees of freedom
CN104626103A (en) * 2014-12-18 2015-05-20 广西大学 Multi-freedom-degree parallel mechanism type controllable moving palletizing robot
CN110024528A (en) * 2019-05-29 2019-07-19 山东理工大学 A kind of implantation methods of plant

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Application publication date: 20140409