CN102211627B - Four-leg robot mechanism based on bionic design - Google Patents
Four-leg robot mechanism based on bionic design Download PDFInfo
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- CN102211627B CN102211627B CN201110106481A CN201110106481A CN102211627B CN 102211627 B CN102211627 B CN 102211627B CN 201110106481 A CN201110106481 A CN 201110106481A CN 201110106481 A CN201110106481 A CN 201110106481A CN 102211627 B CN102211627 B CN 102211627B
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Abstract
The invention relates to a four-leg robot mechanism based on a bionic design. The four-leg robot mechanism consists of a body frame and four legs. The body frame consists of a front plate and a rear plate, two sides of the body frame are provided with flexible handles, and the robot mechanism is convenient to convey; each leg comprises a hip, a huckle, a knee and a crural part; the hip realizes two freedom degrees by adopting a differential bevel gear; the hip and the huckle are connected by an expansion sleeve to realize fast and convenient assembly and disassembly; the bevel gear drive motion is adopted by the knee; the crural part comprises a large cylinder, a small cylinder, a conical spring and a force sensor; and the large cylinder and the small cylinder are connected through the conical spring, so that the external impact force generated in the walking process of the robot can be buffered, the force sensor on a sole can acquire ground acting force, and the external environment can be conveniently sensed in real time and the robot can be subjected to balanced control conveniently. Through the bionic design idea, a spinal cord and a flexible foot mechanism of the robot are stimulated and designed, the flexibility of the robot movement is improved, the impact of the ground to the robot is reduced, and the robot mechanism has a compact structure and is convenient to install.
Description
Technical field
The invention belongs to the robot field, relate to a kind of four robot leg mechanisms based on Bionic Design.
Background technology
Along with the intensification of the mankind to realm of nature understanding, increasing intelligent bionic apparatus is developed.The intelligent bionic robot as research object, with the motion of physical construction imitated biological tissue, and then is explored its movement mechanism with the biology of occurring in nature.Development of miniaturized, lighting and adaptable bionical four robot legs are significant to the development that promotes robotics, and this type bio-robot has wide application and development prospect at aspects such as scientific research, demonstration teaching and intelligence development amusements.
That Chinese patent CN 101927793 A disclose is a kind of the variable-structure quadruped robot structure of upright motion change " crawl with "; This quadruped robot organism and four limbs that are fixed in the above; Every limbs adopt three steering wheel controls, and tiller room is a cascaded structure, and it is many that this structure connects rod member; Complex structure is not suitable for small-sized, the light bio-robot of requirement.Body is an integral body in this structure simultaneously, has limited the alerting ability of motion.
Chinese patent CN 101811525 A disclose a kind of " the hydraulic-driven quadruped robot travel mechanism with barycenter setting device "; Four legs of layout below trunk of this robot mechanism; All adopt hydraulic-driven; Every leg has and has redundant degree of freedom, has increased the complexity of mechanism controls.Hydraulic-driven has improved the volume and weight of sleeve mechanism in addition, is inconvenient to carry transportation and dismounting.
Chinese patent CN 101791994 A disclose " a kind of traveling gear of cam driving control type quadruped robot ", rear leg assemblies and the universal coupling assembling that is connected preceding rear leg assemblies before mechanism is divided into.Wherein the universal-joint coupling assembling only provides a passive mode of motion, can not be unfavorable for motion of mechanism and balance control to artificial to its control.
Summary of the invention
The objective of the invention is to overcome the deficiency of prior art; Provide a kind of structure compact more, install and carry convenient, more help improving robot motion's alerting ability, better absorb foot impacts power, have the four robot leg mechanisms based on Bionic Design of perception external environment condition effect.
Four robot leg mechanisms based on Bionic Design comprise body frame and four shanks; Article four, shank is fixed on the body frame; Article four, shank comprises hip, huckle, knee and calf; Hip connects huckle, and huckle connects knee, and knee connects calf; Body frame comprises that plate behind health header board, the health, preceding rotation flange, back rotate flange, first motor and flexible handle; The preceding flange that rotates is fixed on the health header board; The back is rotated flange and is fixed on behind the health on the plate; The preceding flange that rotates rotates flange formation revolute pair with the back; Rotate before first motor is fixed on the flange, first motor output shaft is connected to the back and rotates flange, and the two ends of flexible handle are separately fixed at behind health header board and the health on the plate; Hip comprises second motor, the first commutating tooth wheels, the first drive fixing frame, first sun finishing bevel gear cuter, bevel planet gear, planet stent, second sun finishing bevel gear cuter, the second drive fixing frame, the second commutating tooth wheels and the 3rd motor; Second motor output shaft connects the wheel for inputting of the first commutating tooth wheels; The 3rd motor output shaft connects the wheel for inputting of the second commutating tooth wheels; The output wheel of the first commutating tooth wheels connects first sun finishing bevel gear cuter; The output wheel of the second commutating tooth wheels connects second sun finishing bevel gear cuter; First sun finishing bevel gear cuter, second sun finishing bevel gear cuter and bevel planet gear and planet stent constitute rotary motion pair, and the first drive fixing frame and the second drive fixing frame are fixed on the health header board, support first sun finishing bevel gear cuter and second sun finishing bevel gear cuter and the bevel planet gear simultaneously; Huckle comprises swelling cover, thigh bar, the 4th motor and motor cabinet, and thigh bar and bevel planet gear output shaft are fixing through the swelling cover, and the 4th motor is fixed in the thigh bar through motor cabinet; Knee comprises knee joint bevel gear set, gear casing and bevel gear shaft; The input finishing bevel gear cuter of knee joint bevel gear set is installed on the 4th motor output shaft, is meshing with each other with the output finishing bevel gear cuter of knee joint bevel gear set on the knee axis, gear casing is fixed on the thigh bar, supports knee axis simultaneously; Calf comprises left leg plate, right leg plate, large cylinder, cone-shaped spring, little cylinder and force gauge; The left leg plate is connected the bevel gear shaft two ends in the knee with the right leg plate; And it is fixing with the large cylinder upper end; Large cylinder lower end hollow, little cylinder one end is enclosed within the large cylinder, and both connect through cone-shaped spring; Pin is inserted in the groove that large cylinder and little cylinder cooperatively interact, and the roundlet tube other end is equipped with force gauge.
The present invention compared with prior art has the integral structure compact, the characteristics of easy installation and removal, and the body joints of adding makes robot be fit to the high-speed motion occasion more, and the shock absorber of shank and force gauge are guaranteed the motion control reliability easily.
Description of drawings
Fig. 1 is the whole pictorial diagram of four robot leg mechanisms;
Fig. 2 is four robot leg body frame pictorial diagram;
Fig. 3 is four robot leg list leg pictorial diagram;
Fig. 4 is four robot leg hip assembly drowings;
Fig. 5 is four robot leg huckles, knee and calf assembly drowing;
Among the figure: body frame 1; Shank 2; Health header board 3; Plate 4 behind the health; The preceding flange 5 that rotates; Flange 6 is rotated in the back; First motor 7; Flexible bandage 8; Hip 9; Huckle 10; Knee 11; Calf 12; Second motor 13; The first commutating tooth wheels 14; The first drive fixing frame 15; First sun finishing bevel gear cuter 16; Bevel planet gear 17; Planet stent 18; Second sun finishing bevel gear cuter 19; The second drive fixing frame 20; The second commutating tooth wheels 21; The 3rd motor 22; Swelling cover 23; Thigh bar 24; The 4th motor 25; Motor cabinet 26; Knee joint bevel gear set 27; Gear casing 28; Bevel gear shaft 29; Left leg plate 30; Right leg plate 31; Large cylinder 32; Cone-shaped spring 33; Roundlet tube 34; Force gauge 35.
The specific embodiment
Further specify the present invention below in conjunction with accompanying drawing.
Like Fig. 1,2,3, shown in 4,5, comprise body frame 1 and four shanks 2 based on four robot leg mechanisms of Bionic Design; Article four, shank 2 is fixed on the body frame 1; Article four, shank 2 comprises hip 9, huckle 10, knee 11 and calf 12; Hip 9 connects huckle 10, and huckle 10 connects knee 11, and knee 11 connects calf 12; Body frame 1 comprises that plate 4 behind health header board 3, the health, preceding rotation flange 5, back rotate flange 6, first motor 7 and flexible handle 8; The preceding flange 5 that rotates is fixed on the health header board 3; The back is rotated flange 6 and is fixed on behind the health on the plate 4; The preceding flange 5 that rotates rotates flange 6 formation revolute pairs with the back; Rotate before first motor 7 is fixed on the flange 5, first motor, 7 output shafts are connected to the back and rotate flange 6, and the two ends of flexible handle 8 are separately fixed at behind health header board 3 and the health on the plate 4; Hip 9 comprises second motor 13, the first commutating tooth wheels 14, the first drive fixing frame 15, first sun finishing bevel gear cuter 16, bevel planet gear 17, planet stent 18, second sun finishing bevel gear cuter 19, the second drive fixing frame 20, the second commutating tooth wheels 21 and the 3rd motor 22; Second motor, 13 output shafts connect the wheel for inputting of the first commutating tooth wheels 14; The 3rd motor 22 output shafts connect the wheel for inputting of the second commutating tooth wheels 21; The output wheel of the first commutating tooth wheels 14 connects first sun finishing bevel gear cuter 16; The output wheel of the second commutating tooth wheels 21 connects second sun finishing bevel gear cuter 19; First sun finishing bevel gear cuter 16, second sun finishing bevel gear cuter 19 and bevel planet gear 17 constitute rotary motion pairs with planet stent 18, and the first drive fixing frame 15 and the second drive fixing frame 20 are fixed on the health header board 3, support first sun finishing bevel gear cuter 16 and second sun finishing bevel gear cuter 19 and the bevel planet gear 17 simultaneously; Huckle 10 comprises swelling cover 23, thigh bar 24, the 4th motor 25 and motor cabinet 26, and thigh bar 24 is fixing through swelling cover 23 with bevel planet gear 17 output shafts, and the 4th motor 25 is fixed in the thigh bar 24 through motor cabinet 26; Knee 11 comprises knee joint bevel gear set 27, gear casing 28 and bevel gear shaft 29; The input finishing bevel gear cuter of knee joint bevel gear set 27 is installed on the 4th motor 25 output shafts, is meshing with each other with the output finishing bevel gear cuter of knee joint bevel gear set 27 on the knee axis 29, gear casing 28 is fixed on the thigh bar 24, supports knee axis 29 simultaneously; Calf 12 comprises left leg plate 30, right leg plate 31, large cylinder 32, cone-shaped spring 33, roundlet tube 34 and force gauge 35; Left leg plate 30 is connected bevel gear shaft 29 two ends in the knee 11 with right leg plate 31; And fix with large cylinder 32 upper ends; Large cylinder 32 lower end hollows, roundlet tube 34 1 ends are enclosed within the large cylinder 32, and both connect through cone-shaped spring 33; Pin is inserted in the groove that large cylinder 32 and roundlet tube 34 cooperatively interact, and roundlet tube 34 other ends are equipped with force gauge 35.
Working process of the present invention is following: the output shaft of first motor 7 on the body frame 1 drives the back and rotates flange 6 rotations; Can realize the relative motion of plate 4 behind health header board 3 and the health; Strengthened the alerting ability of robot in the high-speed motion occasion, the carrying of robot can realize through flexible handle 8 very easily, and first sun finishing bevel gear cuter 16, second sun finishing bevel gear cuter 19 and the bevel planet gear 17 of hip 9 are formed the bevel type differential gears combination; Second motor 13 and the 3rd motor 22 drive first sun finishing bevel gear cuter 16 and second sun finishing bevel gear cuter 19 respectively; Both Motion Transmission are to bevel planet gear 17, and the revolution of bevel planet gear 17 and rotation realize the motion of flexion/extension, two degree of freedom of interior receipts/abduction, compact conformation; Driving torque increases, and has improved the robustness in robot motion's process.Thigh bar 24 is fixing through swelling cover 23 with bevel planet gear 17 output shafts, adopts this mode to make things convenient for the Assembly &Disassembly to the robot shank, fixing the 4th motor 25 in the thigh bar 24; Reasonable distribution shank center of gravity; The balance control that more helps robot through the rotation of the 4th motor 25 output shafts, arrives bevel gear shaft 29 with transmission of power; Left leg plate 30 is fixed on bevel gear shaft 29 two ends with right leg plate 31, has so just realized the relative motion of huckle 10 and calf 12.Large cylinder 32 hollows, roundlet tube 34 are enclosed within the large cylinder 32, and both connect through cone-shaped spring 33; Pin is inserted in the groove that large cylinder 32 and roundlet tube 34 cooperatively interact, and can prevent that roundlet tube 34 from coming off from large cylinder 32, and roundlet tube 34 other ends are equipped with force gauge 35; Receive when impacting in the vola; Roundlet tube 34 relatively moves through producing between compression cone-shaped spring 33 and the large cylinder 32, has slowed down the influence of impulse force to body movement, to adapt to rugged ground.Simultaneously, the force gauge 35 in vola is used to gather ground-surface application force, is convenient to the real-time perception external environment condition and robot is carried out balance control.
Claims (1)
1. four robot leg mechanisms based on Bionic Design is characterized in that comprising body frame (1) and four shanks (2); Article four, shank (2) is fixed on the body frame (1); Article four, shank (2) comprises hip (9), huckle (10), knee (11) and calf (12); Hip (9) connects huckle (10), and huckle (10) connects knee (11), and knee (11) connects calf (12); Body frame (1) comprises that plate (4) behind health header board (3), the health, preceding rotation flange (5), back rotate flange (6), first motor (7) and flexible handle (8); The preceding flange (5) that rotates is fixed on the health header board (3); The back is rotated flange (6) and is fixed on behind the health on the plate (4); Preceding flange (5) and back rotation flange (6) the formation revolute pair of rotating; Rotate before first motor (7) is fixed on the flange (5), first motor (7) output shaft is connected to the back and rotates flange (6), and the two ends of flexible handle (8) are separately fixed at behind health header board (3) and the health on the plate (4); Hip (9) comprises second motor (13), the first commutating tooth wheels (14), the first drive fixing frame (15), first sun finishing bevel gear cuter (16), bevel planet gear (17), planet stent (18), second sun finishing bevel gear cuter (19), the second drive fixing frame (20), the second commutating tooth wheels (21) and the 3rd motor (22); Second motor (13) output shaft connects the wheel for inputting of the first commutating tooth wheels (14); The 3rd motor (22) output shaft connects the wheel for inputting of the second commutating tooth wheels (21); The output wheel of the first commutating tooth wheels (14) connects first sun finishing bevel gear cuter (16); The output wheel of the second commutating tooth wheels (21) connects second sun finishing bevel gear cuter (19); First sun finishing bevel gear cuter (16), second sun finishing bevel gear cuter (19) and bevel planet gear (17) constitute rotary motion pair with planet stent (18), and the first drive fixing frame (15) and the second drive fixing frame (20) are fixed on the health header board (3), support first sun finishing bevel gear cuter (16) and second sun finishing bevel gear cuter (19) and bevel planet gear (17) simultaneously; Huckle (10) comprises swelling cover (23), thigh bar (24), the 4th motor (25) and motor cabinet (26); Thigh bar (24) is fixing through swelling cover (23) with bevel planet gear (17) output shaft, and the 4th motor (25) is fixed in the thigh bar (24) through motor cabinet (26); Knee (11) comprises knee joint bevel gear set (27), gear casing (28) and bevel gear shaft (29); The input finishing bevel gear cuter of knee joint bevel gear set (27) is installed on the 4th motor (25) output shaft; Be meshing with each other with the output finishing bevel gear cuter of knee joint bevel gear set (27) on the bevel gear shaft (29); Gear casing (28) is fixed on the thigh bar (24), simultaneously cone of support gear wheel shaft (29); Calf (12) comprises left leg plate (30), right leg plate (31), large cylinder (32), cone-shaped spring (33), little cylinder (34) and force gauge (35); Left leg plate (30) is connected bevel gear shaft (29) two ends in the knee (11) with right leg plate (31); And it is fixing with large cylinder (32) upper end; Large cylinder (32) lower end hollow, little cylinder (34) one ends are enclosed within the large cylinder (32), and both connect through cone-shaped spring (33); Pin is inserted in the groove that large cylinder (32) and little cylinder (34) cooperatively interact, and little cylinder (34) other end is equipped with force gauge (35).
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| Application Number | Priority Date | Filing Date | Title |
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| CN201110106481A CN102211627B (en) | 2011-04-27 | 2011-04-27 | Four-leg robot mechanism based on bionic design |
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| CN201110106481A CN102211627B (en) | 2011-04-27 | 2011-04-27 | Four-leg robot mechanism based on bionic design |
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| CN102211627A CN102211627A (en) | 2011-10-12 |
| CN102211627B true CN102211627B (en) | 2012-10-17 |
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Citations (7)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US5929585A (en) * | 1996-11-19 | 1999-07-27 | Sony Corporation | Robot system and its control method |
| EP1110679A1 (en) * | 1999-03-10 | 2001-06-27 | Mitsubishi Heavy Industries, Ltd. | Working robot |
| WO2002011956A1 (en) * | 2000-08-04 | 2002-02-14 | Robottec Co., Ltd. | Multiple-legged walking apparatus |
| CN2928631Y (en) * | 2006-07-27 | 2007-08-01 | 浙江大学 | Wave foot walking robot |
| CN101269678A (en) * | 2008-05-16 | 2008-09-24 | 武汉理工大学 | Wheeled robot with traveling system |
| CN101422907A (en) * | 2008-12-16 | 2009-05-06 | 吉林大学 | Under-actuated bipod walking robot hip-joint mechanism |
| CN101580083A (en) * | 2009-06-04 | 2009-11-18 | 浙江大学 | Knee joint mechanism of humanoid robot |
-
2011
- 2011-04-27 CN CN201110106481A patent/CN102211627B/en active Active
Patent Citations (7)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US5929585A (en) * | 1996-11-19 | 1999-07-27 | Sony Corporation | Robot system and its control method |
| EP1110679A1 (en) * | 1999-03-10 | 2001-06-27 | Mitsubishi Heavy Industries, Ltd. | Working robot |
| WO2002011956A1 (en) * | 2000-08-04 | 2002-02-14 | Robottec Co., Ltd. | Multiple-legged walking apparatus |
| CN2928631Y (en) * | 2006-07-27 | 2007-08-01 | 浙江大学 | Wave foot walking robot |
| CN101269678A (en) * | 2008-05-16 | 2008-09-24 | 武汉理工大学 | Wheeled robot with traveling system |
| CN101422907A (en) * | 2008-12-16 | 2009-05-06 | 吉林大学 | Under-actuated bipod walking robot hip-joint mechanism |
| CN101580083A (en) * | 2009-06-04 | 2009-11-18 | 浙江大学 | Knee joint mechanism of humanoid robot |
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Application publication date: 20111012 Assignee: Zhejiang Guozi Robot Technology Co., Ltd. Assignor: Zhejiang University Contract record no.: 2013330000081 Denomination of invention: Four-leg robot mechanism based on bionic design Granted publication date: 20121017 License type: Exclusive License Record date: 20130422 |
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