CN201511768U - Paddlewheel leg integrally-driven amphibian robot - Google Patents
Paddlewheel leg integrally-driven amphibian robot Download PDFInfo
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- CN201511768U CN201511768U CN2009202667090U CN200920266709U CN201511768U CN 201511768 U CN201511768 U CN 201511768U CN 2009202667090 U CN2009202667090 U CN 2009202667090U CN 200920266709 U CN200920266709 U CN 200920266709U CN 201511768 U CN201511768 U CN 201511768U
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Abstract
The utility model relates to an amphibian robot, in particular to a paddlewheel leg integrally-driven amphibian robot which comprises a front float tube, a middle front float tube, a water sealed electronic cabin, a middle rear float tube, a rear float tube, a frame and paddlewheel leg driving modules, wherein the front float tube, the middle front float tube, the water sealed electronic cabin, the middle rear float tube and the rear float tube are installed on the frame in turn, a plurality of groups of paddlewheel leg driving modules are arranged on the frame, each group is composed of two paddlewheel leg driving modules which are symmetrically installed on two sides of the frame, each paddlewheel leg driving module comprises a paddlewheel direct driving joint and a rotary joint, and the paddlewheel direct driving joint is rotatablely connected with the rotary joint. The paddlewheel leg integrally-driven amphibian robot adopts three groups of symmetrically-distributed paddlewheel leg driving modules, satisfies the demands of multiple movement modes of climbing and floating under amphibian conditions of robots, gives attention to stability, rapidness and coordination of robot movement simultaneously, and further has the characteristics of flexible movement, strong environment adaptability, prominent block exceeding ability and the like.
Description
Technical field
The utility model relates to amphibious robot, specifically a kind of amphibious robot of taking turns the integrated driving of oar leg.
Background technology
Along with in-depth and the development of each ocean power of the world to marine scientific research and ocean exploitation strategy, Very Shallow Water, breaker zone, surfzone and the beach area that flood and field is connected becomes one of key area of using and pay close attention in aspects such as scientific research in recent years, environmental monitoring, investigation sampling and military field.The under-water robot of current domestic and international research mainly comprises swim formula and creeping-type, but all there are some limitation in the operating area of these two kinds of under-water robots: at shallow water and deep water sea area, current under-water robot has certain operational capability, and Very Shallow Water, breaker zone and zone, seabeach operational capability a little less than, even can't operation; And the robot of land application is felt simply helpless especially to Very Shallow Water and breaker zone zone.Amphibious robot is a kind of extraordinary mobile robot who integrates special exercise in land and the water, different according to driver train and mode of motion, and existing amphibious robot roughly can be divided into single driving and combination flooding ejector half two big classes.No matter the amphibious robot of single drive mode is polypody, fluctuation formula, wheeled, crawler type etc., all is difficult to satisfy fully robot in water or the requirement of aspect such as speed on land, obstacle detouring, manoevreability, stability.In order to realize amphibious robot respectively in water and the High Performance motion under the various modes of land, developing amphibious robot based on the NEW TYPE OF COMPOSITE driver train becomes one of the important research direction of amphibious robot in recent years and development tendency.
The utility model content
The purpose of this utility model is to provide a kind of and has creeping and the multi-locomotion mode that swims, the well behaved amphibious robot of taking turns the integrated driving of oar leg of integrated motion, it is single to have solved existing amphibious robot mode of motion under amphibious environment, operational capability a little less than, the problem of aspect deficiencies such as rapidity, manoevreability, stability and obstacle climbing ability is for inshore ocean exploitation and utilization provide a kind of actv. hightech means.
The purpose of this utility model is achieved through the following technical solutions:
The utility model comprise preceding floating drum, in before floating drum, watertight electronic compartment, middle back floating drum, back floating drum, framework and wheel oar leg driver module, be equipped with successively on the described framework preceding floating drum, in before floating drum, watertight electronic compartment, middle back floating drum and back floating drum, be provided with many group wheel oar leg driver modules on framework, every group by two wheel oar leg driver modules are formed, symmetry is installed in framework both sides; The described oar leg driver module of taking turns comprises wheel oar leg direct drive joint and revolute joint, and wheel oar leg direct drive joint is connected with revolute joint rotationally.
Wherein: the described oar leg driver module of taking turns is three groups, six, is symmetrically distributed in front end, middle part and the rear end of framework, and six wheel oar leg driver module structures are identical; Described wheel oar leg direct drive joint of taking turns in the oar leg driver module comprises sealed module body, direct drive electric machine assembly, sealed module end cap, first axle drive shaft, wheel oar leg composite structure and propeller hub, wherein the both sides of sealed module body radially symmetry stretch out, the extension of one side is installed in rotation on the revolute joint, the extension of opposite side rotationally be fixed in framework on fixed support be connected; Described direct drive electric machine assembly is fixed in the sealed module body, be connected with the interior motor driver electrical component of watertight electronic compartment, the output shaft of direct drive electric machine assembly is connected with an end of first axle drive shaft, the other end of first axle drive shaft is connected with the wheel oar leg composite structure with its interlock, and this outside of taking turns in the middle of the oar leg composite structure is provided with the propeller hub that is connected in the first axle drive shaft other end end; Be arranged with the sealed module end cap that is tightly connected with the sealed module body on described first axle drive shaft; The sealed module end cap is set on first axle drive shaft by backup bearing, and a side of backup bearing is provided with first jam nut that is set on first axle drive shaft, and the opposite side of backup bearing is provided with first rotating seal that is set on first axle drive shaft; Wheel oar leg composite structure comprises wheel rim, wheel hub and blade, and wheel hub is hollow circuit cylinder, is connected with the first driving axle key, is connected with a plurality of uniform blades at the external peripheral surface of wheel hub, and the outer rim of each blade all is connected with wheel rim; Wheel rim is a circular arc, and each wheel rim is positioned on the circumference of same circle, and the center of circle of this circle is on the axis of wheel hub; Described revolute joint of taking turns in the oar leg driver module comprises revolution cabin body, turning motor assembly, first finishing bevel gear cuter, middle tap gear, transition axis and cabling poted assemblies, described revolution cabin body is installed on the framework, the turning motor assembly is fixed on the inside of revolution cabin body, and the output shaft of turning motor assembly is connected with an end of transition axis; The described oar leg direct drive joint of taking turns comprises the sealed module body, the both sides of sealed module body radially symmetry stretch out, wherein the extension of a side is connected with revolution cabin body rotationally, be provided with first finishing bevel gear cuter on the transition axis, be meshed with middle tap gear on the extension that is installed in sealed module body one side, rotate in driven wheel oar leg direct drive joint; Be provided with the cabling poted assemblies on the body of revolution cabin, the cable of turning motor assembly is connected by the interior motor driver electrical component of cabling poted assemblies and watertight electronic compartment; Be connected with the turning motor seat in the body of revolution cabin, the turning motor assembly is installed on the turning motor seat; The other end of transition axis is provided with rotating potentiometer, and the cable of rotating potentiometer is connected by the interior motor driver electrical component of cabling poted assemblies and watertight electronic compartment; Described revolution cabin body is connected with the extension of sealed module body one side by the swivel bearing and second rotating seal, the top of swivel bearing is provided with second jam nut that is set on the extension, also is being provided with the captive nut that is enclosed within on the sealed module body one side extension above the middle tap gear.
Advantage of the present utility model and good effect are:
1. amphibious robot of the present utility model is based on the incorporate overall structure types of wheel oar leg, adopt three groups of wheel oar leg driver modules that are symmetrically distributed, satisfy robot the creeping and the demand of the multi-locomotion mode that swims of amphibious condition, taken into account robot motion's stability, rapidity and harmony simultaneously.
2. the actuating device of amphibious robot of the present utility model adopts the leg combined travel mechanism of wheel oar that integrates wheel, leg and screw propeller function, make robot when possessing diversified mode of motion and better integrated motion performance, ensure the compactedness and the single-piece miniaturization of system architecture, alleviated the weight of robot carrier.
3. the actuating device of amphibious robot of the present utility model adopts modular design, and each is taken turns oar leg driver element and is respectively independently modular construction, does not disturb mutually each other, is convenient to the maintenance and the replacing of actuating device.
4. characteristics such as amphibious robot of the present utility model also has motion flexibly, and adaptive capacity to environment is strong, obstacle climbing ability is outstanding.
Description of drawings
Fig. 1 is a structure principle chart of the present utility model;
Fig. 2 is a structural representation of the present utility model;
Fig. 3 is the upward view of Fig. 2;
Fig. 4 is the structural representation of wheel slurry leg driver module among Fig. 2;
Fig. 5 is the structural representation of wheel oar leg composite structure among Fig. 4;
Fig. 6 a realizes schematic diagram for the utility model rectilinear creeping campaign;
Fig. 6 b is that the utility model turns to crawling exercises to realize schematic diagram;
Fig. 6 c moves for the utility model straight line swims and realizes schematic diagram;
Fig. 6 d is that the utility model turns to the motion of swimming to realize schematic diagram;
Wherein: 1 is preceding floating drum, 2 be in before floating drum, 3 is the watertight electronic compartment, and 4 is middle back floating drum, and 5 is the back floating drum, 6 is framework, 7 are wheel oar leg driver module, and 8 are wheel oar leg direct drive joint, and 9 is revolute joint, 10 is the motor driver assembly, 11 is the secondary lithium battery group, and 12 is the umbilical cable underwater electrical connector, and 13 is the GPS locating module, 14 is wireless data transmission module, 15 are the navigation attitude sensor, and 16 is control computer, and 17 is depth transducer, 18 is receiving wire, 19 is antenna, and 20 is fixed support, and 21 is the sealed module body, 22 is the direct drive electric machine assembly, 23 is first holding screw, and 24 is first jam nut, and 25 is backup bearing, 26 is first rotating seal, 27 is the sealed module end cap, and 28 is first axle drive shaft, and 29 is first flat key, 30 are wheel oar leg composite structure, 31 is propeller hub, and 32 is second rotating seal, and 33 is swivel bearing, 34 is second jam nut, 35 is rotating potentiometer, and 36 is captive nut, and 37 is transition axis, 38 is first finishing bevel gear cuter, 39 is the middle tap gear, and 40 is second holding screw, and 41 is the turning motor seat, 42 is the turning motor assembly, 43 are revolution cabin body, and 44 is the cabling poted assemblies, and 45 is wheel rim, 46 is wheel hub, and 47 is blade.
The specific embodiment
The utility model is described in further detail below in conjunction with accompanying drawing.
Shown in Fig. 1~3, the utility model comprise preceding floating drum 1, in before floating drum 2, watertight electronic compartment 3, middle back floating drum 4, back floating drum 5, framework 6 and wheel oar leg driver module 7, wherein before floating drum 1, in before floating drum 2, watertight electronic compartment 3, middle back floating drum 4 and back floating drum 5 be installed on the framework 6 by screw retention successively; Be provided with many group wheel oar leg driver modules 7 on framework 6, every group by two wheel oar leg driver modules 7 are formed, symmetry is installed in framework 6 both sides; The wheel oar leg driver module 7 of present embodiment is three groups, six, be symmetrically distributed in front end, middle part and the rear end of framework 6, six wheel oar leg driver module 7 structures are identical, include wheel oar leg direct drive joint 8 and revolute joint 9, wheel oar leg direct drive joint 8 and revolute joint 9 respectively by screw retention on framework 6, wheel oar leg direct drive joint 8 is connected with revolute joint 9 rotationally.
Watertight electronic compartment 3 of the present utility model is a prior art, comprise motor driver assembly 10, secondary lithium battery group 11, umbilical cable underwater electrical connector 12, GPS locating module 13, wireless data transmission module 14, navigation attitude sensor 15, control computer 16 and depth transducer 17, wherein secondary lithium battery group 11 is positioned at the middle part of watertight electronic compartment 3, is used to keep robot single-piece balance; Umbilical cable underwater electrical connector 12 is connected on the cover plate of watertight electronic compartment 3; Navigation attitude sensor 15 levels are installed on the base plate of watertight electronic compartment 3; Depth transducer 17 is positioned at the leading flank of watertight electronic compartment 3, handles being connected on the side plate of watertight electronic compartment 3 by watertight; Motor driver assembly 10, GPS locating module 13 and wireless data transmission module 14 are separately positioned in the watertight electronic compartment 3.In before the top of floating drum 2 receiving wire 18 of GPS locating module 13 is installed, the top of middle back floating drum 4 is equipped with the antenna 19 of wireless data transmission module 14.The acquired signal input end of control computer 16 is gathered navigation attitude data and keel depth data by navigation attitude sensor 15 and depth transducer 17, and the satellite-signal input end is by GPS locating module 13 and receiving wire 18 receiving satellite positioning signals thereof; The control output end of control computer 16 is connected to the control loop of motor driver assembly 10, and signal output part carries out wireless telecommunications by wireless data transmission module 14 and antenna 19 thereof with upper computer.
, model is 4QEC DECV 50/5 motor driver assembly 10 of the present utility model is commercial product, purchases (the manufacturer: in Suzhou an ancient unit of weight and servo Science and Technology Ltd. Switzerland Maxon company); Secondary lithium battery group 11 is commercial product, and purchasing in Weifang Wina Environmental Protection Power Co., Ltd., model is WA3610; , model is GARMINGPS15 GPS locating module 13 is commercial product, purchases in the Hezhong Sizhuang Science and Technology Co. Ltd., Beijing (manufacturer: U.S. GARMIN company); Wireless data transmission module 14 is commercial product, purchase in Shenzhen friend fastly reach the development in science and technology Co., Ltd, model is FC-203/SA; Control computer 16 is commercial product, and purchasing in Guangzhou Zhou Ligong micro controller system Co., Ltd, model is ARM7 LPC2294.
As shown in Figure 4, wheel oar leg direct drive joint 8 in the wheel oar leg driver module 7 comprises sealed module body 21, direct drive electric machine assembly 22, first jam nut 24, backup bearing 25, first rotating seal 26, sealed module end cap 27, first axle drive shaft 28, wheel oar leg composite structure 30 and propeller hub 31, wherein sealed module body 21 is the cylinder-like structure of hollow, its both sides radially symmetry stretch out, the centerline collineation of both sides extension, the extension of one side is a hollow circuit cylinder, be installed in rotation on the revolute joint 9, the extension of opposite side is connected with fixed support 20 on being fixed in framework 6 by bearing.Direct drive electric machine assembly 22 is fixed in the sealed module body 21, be electrically connected with the interior motor driver assembly 10 of watertight electronic compartment 3, one end of the output shaft of direct drive electric machine assembly 22 and first axle drive shaft 28 is affixed by first holding screw 23, the other end of first axle drive shaft 28 is realized being connected with wheel oar leg composite structure 30 by first flat key 29, this outside of taking turns in the middle of the oar leg composite structure 30 is provided with propeller hub 31, and wheel oar leg composite structure 30 is anchored on the end of first axle drive shaft, 28 other ends under the effect that screws screw by propeller hub 31.Be provided with sealed module end cap 27 at sealed module body 21 near an end of taking turns oar leg composite structure 30, sealed module end cap 27 connects the fixing of realization and sealed module body 21 by screw; Sealed module end cap 27 is set on first axle drive shaft 28 by backup bearing 25, one side of backup bearing 25 is provided with first jam nut 24 that is set on first axle drive shaft 28, the axial restraint that is used for backup bearing 25 is spacing, the opposite side of backup bearing 25 is provided with first rotating seal 26 that is set on first axle drive shaft 28, first rotating seal, 26 outsides are compressed by gland, and gland is fixed by screw and sealed module end cap.When 22 work of direct drive electric machine assembly, can drive first axle drive shaft 28 and rotate, and then driven wheel oar leg composite structure rotates., model is MAXON EC32 direct drive electric machine assembly 22 is commercial product, purchases (the manufacturer: in Suzhou an ancient unit of weight and servo Science and Technology Ltd. Switzerland Maxon company).
As shown in Figure 6, wheel oar leg composite structure 30 integrates wheel, leg and screw propeller movement characteristic and function, comprise wheel rim 45, wheel hub 46 and blade 47, wheel hub 46 has through hole, is set on first axle drive shaft 28 for hollow circuit cylinder, centre, wheel oar leg composite structure 30 by wheel hub be connected with first axle drive shaft, 28 keys, and first axle drive shaft, 28 interlocks; External peripheral surface at wheel hub 46 is connected with a plurality of uniform blades 47 (present embodiment is three), and the outer rim of each blade 47 all is connected with wheel rim 45.Wheel rim 45 is a circular arc, and each wheel rim is positioned on the circumference of same circle, and the center of circle of this circle is on the axis of wheel hub 45.Rotary screw on the propeller hub 31 by the through hole on the wheel hub 46 penetrate, by being threaded in the end of first axle drive shaft 28, to wheel oar leg composite structure axial location.
As shown in Figure 4, revolute joint 9 in the wheel oar leg driver module 7 comprises revolution cabin body 43, turning motor assembly 42, first finishing bevel gear cuter 38, middle tap gear 39, transition axis 37, cabling poted assemblies 44, captive nut 36, rotating potentiometer 35, second jam nut 34, the swivel bearing 33 and second rotating seal 32, described revolution cabin body 43 is fixed on the framework 6, by screw retention turning motor seat 41 is arranged in the revolution cabin body 43, turning motor assembly 42 is fixed on the turning motor seat 41, be arranged with first finishing bevel gear cuter 38 on the transition axis 37, second holding screw 40 is connected in first finishing bevel gear cuter 38 on the output shaft of turning motor assembly 42 in the lump with transition axis 37, the other end of transition axis 37 by bearing installation on turning motor seat 41, and pass by turning motor seat 41, link to each other with rotating potentiometer 35 then, rotating potentiometer 35 also is connected on the turning motor seat 41.The extension (as axis of revolution) of sealed module body 21 1 sides passes turning motor seat 41, also realizes by swivel bearing 33 and turns round being connected of cabin body 43 by turning round 43 insertions of cabin body; The below of swivel bearing 33 is provided with second rotating seal 32 that is enclosed within on this extension, the top is provided with second jam nut 34 that is enclosed within on this extension, the turning motor seat 41 and second jam nut 34 make the inside and outside delineation position of swivel bearing 33 respectively, and realize jointly by swivel bearing 33, second jam nut 34 and turning motor seat 41 the vertical location of sealed module body 21.This extension is provided with middle tap gear 39, the top of middle tap gear 39 also is provided with captive nut 36, middle tap gear 39 is connected on this extension and with first finishing bevel gear cuter 38 by captive nut 36 and meshes, and realizes the joint 8 revolution commutations of wheel oar leg direct drive; Be provided with cabling poted assemblies 44 on revolution cabin body 43, the cable of direct drive electric machine assembly 22 is passed, is electrically connected with motor driver assembly 10 in the watertight electronic compartment 3 through cabling poted assemblies 44 by the interstitial hole as the extension of axis of revolution; The cable of rotating potentiometer 35 and turning motor assembly 42 also is electrically connected by cabling poted assemblies 44 and watertight electronic compartment 3 interior motor driver assemblies 10.42 work of turning motor assembly drive transition axis 37 and rotate, and transition axis 37 drives the whole oar leg direct drive joint 8 revolution commutations of taking turns by the engagement of first and second finishing bevel gear cuter 38,39.Rotating potentiometer 35 is commercial product, purchases in Shanghai (the manufacturer: NOVOTECHNIK), model is WAL300 of auspicious tree Ou Mao mechanical ﹠ electronic equipment corporation, Ltd; , model is MAXON EC max 30 turning motor assembly 42 is commercial product, purchases (the manufacturer: in Suzhou an ancient unit of weight and servo Science and Technology Ltd. Switzerland Maxon company).
Principle of work of the present utility model is:
Amphibious robot of the present utility model can be realized swimming or two kinds of patterns of water-bed crawling exercises in land crawling exercises under the amphibious environment and the water.
Crawling exercises pattern: under the crawling exercises pattern, amphibious robot of the present utility model can carry out the rectilinear creeping campaign shown in Fig. 6 a or turn to crawling exercises shown in Fig. 6 b, 22 work of direct drive electric machine assembly, drive 28 rotations of first axle drive shaft, again by the rotation of first axle drive shaft, 28 driven wheel oar leg composite structures 30, realize the straight ahead of robot or retreat; When amphibious robot need turn to, turning motor assembly 42 work, drive transition axis 37 and on 38 rotations of first finishing bevel gear cuter, the engagement by first and second finishing bevel gear cuter 38,39 again, drive the whole oar leg direct drive joint 8 of taking turns and rotate, realize turning to around the line of centers of extension; Under the crawling exercises pattern, the functions of wheel oar leg composite structure 30 main performance wheel legs, the motion that ensures amphibious robot possesses rapidity, controllability and obstacle climbing ability preferably.
Swim in the water or water-bed crawling exercises pattern: in water, by adjusting buoyancy, amphibious robot can be realized respectively swimming in the water and move and water-bed crawling exercises, and water-bed crawling exercises is creeped with land and had identical principle of work; Driving by revolute joint 9 in the wheel oar leg driver module 7, amphibious robot can be realized the direct route shown in Fig. 6 c swim motion or the motion of swimming of turning to shown in Fig. 6 d, under the mode of motion that swims, 42 work of turning motor assembly, wheel oar leg composite structure 30 is rotated, vertical up to first axle drive shaft 28 with transition axis 37, under the driving of direct drive electric machine assembly 22, produce the amphibious robot required thrust of advancing, be implemented in direct route in the water motion of swimming, the effects of wheel oar leg composite structure 30 main performance screw propellers; When needing to turn in water, the blade rotation direction in the wheel oar leg composite structure 30 of framework 6 both sides is opposite, can realize the motion of swimming of robot turning in water.
Amphibious robot of the present utility model can realize creeping in land and water in the two kinds of mode of motioies that swim, and need not to change the autonomous switching that actuating device can be realized two kinds of mode of motioies.
Claims (8)
1. amphibious robot of taking turns the integrated driving of oar leg, it is characterized in that: comprise preceding floating drum (1), in before floating drum (2), watertight electronic compartment (3), middle back floating drum (4), back floating drum (5), framework (6) and wheel oar leg driver module (7), be equipped with successively on the described framework (6) preceding floating drum (1), in before floating drum (2), watertight electronic compartment (3), middle back floating drum (4) and back floating drum (5), be provided with many group wheel oar leg driver modules (7) on framework (6), every group by two wheel oar leg driver modules (7) are formed, symmetry is installed in framework (6) both sides; The described oar leg driver module (7) of taking turns comprises wheel oar leg direct drive joint (8) and revolute joint (9), and wheel oar leg direct drive joint (8) is connected with revolute joint (9) rotationally.
2. by the described amphibious robot of taking turns the integrated driving of oar leg of claim 1, it is characterized in that: the described oar leg driver module (7) of taking turns is three groups, six, be symmetrically distributed in front end, middle part and the rear end of framework (6), six wheel oar leg driver modules (7) structure is identical.
3. by claim 1 or 2 described amphibious robots of taking turns the integrated driving of oar leg, it is characterized in that: described wheel oar leg direct drive joint (8) of taking turns in the oar leg driver module (7) comprises sealed module body (21), direct drive electric machine assembly (22), sealed module end cap (27), first axle drive shaft (28), wheel oar leg composite structure (30) and propeller hub (31), wherein the both sides of sealed module body (21) radially symmetry stretch out, the extension of one side is installed in rotation on the revolute joint (9), the extension of opposite side rotationally be fixed in framework (6) on fixed support (20) be connected; Described direct drive electric machine assembly (22) is fixed in the sealed module body (21), be electrically connected with the interior motor driver assembly (10) of watertight electronic compartment (3), the output shaft of direct drive electric machine assembly (22) is connected with an end of first axle drive shaft (28), the other end of first axle drive shaft (28) is connected with the wheel oar leg composite structure (30) with its interlock, and this outside of taking turns in the middle of the oar leg composite structure (30) is provided with the propeller hub (31) that is connected in first axle drive shaft (28) other end end; Be arranged with the sealed module end cap (27) that is tightly connected with sealed module body (21) on described first axle drive shaft (28).
4. by the described amphibious robot of taking turns the integrated driving of oar leg of claim 3, it is characterized in that: described sealed module end cap (27) is set on first axle drive shaft (28) by backup bearing (25), one side of backup bearing (25) is provided with first jam nut (24) that is set on first axle drive shaft (28), and the opposite side of backup bearing (25) is provided with first rotating seal (26) that is set on first axle drive shaft (28).
5. by the described amphibious robot of taking turns the integrated driving of oar leg of claim 3, it is characterized in that: the described oar leg composite structure (30) of taking turns comprises wheel rim (45), wheel hub (46) and blade (47), wheel hub (46) is hollow circuit cylinder, is connected with first axle drive shaft (28) key, external peripheral surface at wheel hub (46) is connected with a plurality of uniform blades (47), and the outer rim of each blade (47) all is connected with wheel rim (45).
6. by the described amphibious robot of taking turns the integrated driving of oar leg of claim 5, it is characterized in that: described wheel rim (45) is circular arc, and each wheel rim is positioned on the circumference of same circle, and the center of circle of this circle is on the axis of wheel hub (45).
7. by claim 1 or 2 described amphibious robots of taking turns the integrated driving of oar leg, it is characterized in that: described revolute joint (9) of taking turns in the oar leg driver module (7) comprises revolution cabin body (43), turning motor assembly (42), first finishing bevel gear cuter (38), middle tap gear (39), transition axis (37) and cabling poted assemblies (44), described revolution cabin body (43) is installed on the framework (6), turning motor assembly (42) is fixed on the inside of revolution cabin body (43), and the output shaft of turning motor assembly (42) is connected with an end of transition axis (37); The described oar leg direct drive joint (8) of taking turns comprises sealed module body (21), the both sides of sealed module body (21) radially symmetry stretch out, wherein the extension of a side is connected with revolution cabin body (43) rotationally, be provided with first finishing bevel gear cuter (38) on the transition axis (37), be meshed with middle tap gear (39) on the extension that is installed in sealed module body (21) one sides, rotate in driven wheel oar leg direct drive joint (8); Be provided with cabling poted assemblies (44) on revolution cabin body (43), the cable of turning motor assembly (42) is electrically connected by the interior motor driver assembly (10) of cabling poted assemblies (44) and watertight electronic compartment (3).
8. by the described amphibious robot of taking turns the integrated driving of oar leg of claim 7, it is characterized in that: be connected with turning motor seat (41) in the described revolution cabin body (43), turning motor assembly (42) is installed on the turning motor seat (41); The other end of transition axis (37) is provided with rotating potentiometer (35), and the cable of rotating potentiometer (35) is electrically connected by the interior motor driver assembly (10) of cabling poted assemblies (44) and watertight electronic compartment (3); Described revolution cabin body (43) is connected with the extension of sealed module body (21) one sides by swivel bearing (33) and second rotating seal (32), the top of swivel bearing (33) is provided with second jam nut (34) that is set on the extension, also is provided with the captive nut (36) that is enclosed within on sealed module body (21) the one side extensions in the top of middle tap gear (39).
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CN2009202667090U CN201511768U (en) | 2009-11-09 | 2009-11-09 | Paddlewheel leg integrally-driven amphibian robot |
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CN102556309A (en) * | 2011-12-30 | 2012-07-11 | 张维中 | Amphibious driving wheel |
CN102050162B (en) * | 2009-11-09 | 2012-11-07 | 中国科学院沈阳自动化研究所 | Amphibious robot with integrally-driven wheel paddle legs |
CN103522853A (en) * | 2013-10-25 | 2014-01-22 | 天津大学 | Variable-structure triphibian wheeled obstacle-crossing robot |
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CN109774816A (en) * | 2019-03-10 | 2019-05-21 | 浙江工业大学 | It is a kind of to collect fixed, pivot stud function wheel leg type hexapod robot |
CN110764413A (en) * | 2019-10-29 | 2020-02-07 | 中国科学院自动化研究所 | Self-stabilization control method, system and device of wheel-leg robot |
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CN102050162B (en) * | 2009-11-09 | 2012-11-07 | 中国科学院沈阳自动化研究所 | Amphibious robot with integrally-driven wheel paddle legs |
CN102556309A (en) * | 2011-12-30 | 2012-07-11 | 张维中 | Amphibious driving wheel |
CN102556309B (en) * | 2011-12-30 | 2015-01-07 | 宁海县雁苍山电力建设有限公司 | Amphibious driving wheel |
CN103522855A (en) * | 2013-10-25 | 2014-01-22 | 天津大学 | Triphibian wheel-like type mobile robot |
CN103522854A (en) * | 2013-10-25 | 2014-01-22 | 天津大学 | Wheeled-like movable robot with capacities of flying and water passing |
CN103523109A (en) * | 2013-10-25 | 2014-01-22 | 天津大学 | Quasi-wheel wall-climbing robot |
CN103522853A (en) * | 2013-10-25 | 2014-01-22 | 天津大学 | Variable-structure triphibian wheeled obstacle-crossing robot |
CN104527352A (en) * | 2014-12-24 | 2015-04-22 | 天津理工大学 | Novel spherical amphibious robot and working method thereof |
CN105974074A (en) * | 2016-05-03 | 2016-09-28 | 中国水产科学研究院渔业机械仪器研究所 | Amphibious water quality monitoring robot |
CN109774816A (en) * | 2019-03-10 | 2019-05-21 | 浙江工业大学 | It is a kind of to collect fixed, pivot stud function wheel leg type hexapod robot |
CN109774816B (en) * | 2019-03-10 | 2024-04-02 | 浙江工业大学 | Wheel leg type six-foot robot integrating fixed and in-situ steering functions |
US20210379946A1 (en) * | 2019-09-06 | 2021-12-09 | Shanghai University | Wheel-legged amphibious mobile robot with variable attack angle |
US11752819B2 (en) * | 2019-09-06 | 2023-09-12 | Shanghai University | Wheel-legged amphibious mobile robot with variable attack angle |
CN110764413A (en) * | 2019-10-29 | 2020-02-07 | 中国科学院自动化研究所 | Self-stabilization control method, system and device of wheel-leg robot |
CN110920334A (en) * | 2019-12-13 | 2020-03-27 | 哈尔滨工程大学 | Foot paddle-wing hybrid drive type amphibious operation bionic robot and movement method |
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