CN205059786U - Polypody robot platform with visual system - Google Patents

Abstract

The utility model discloses a polypody robot platform with visual system, including the fuselage, there are a plurality of mechanical legs by steering engine driving in fuselage outside distribution, the fuselage top is provided with the visual system, and the visual system includes stereoscopic camera and single mesh camera, and stereoscopic camera and single mesh camera setting are on a casing, and the casing passes through actuating mechanism and installs on the fuselage. The utility model discloses a visual system adopts the stereoscopic camera to add single mesh camera rational arrangement of, and the dead angle of vision is little, and the blind area is little, can fix a position the object in dominant eye the place ahead, also can monitor the analysis to the both sides object simultaneously, mechanical legs adopts imitative spider design, has the three degree of freedom, and the shock attenuation is effectual, and the motion is nimble, fuselage simple and practical. Through reasonable design, simple, convenient, low -cost having built can be realized and spider polypody robot experiment platform is imitated, can be used for the complicated topography trafficability characteristic experiment of robot, experimental studies such as road trafficability characteristic.

Description

A kind of multi-foot robot platform with vision system

Technical field

The utility model belongs to robotics, is specifically related to a kind of multi-foot robot experiment porch with the imitative spider of visual performance.

Background technology

In realm of nature and human society, there is the place that some mankind cannot arrive and the special occasions that may jeopardize human life, as planetary surface, disaster generation mine, Fire prevention and struggle against terror etc., these hazardous environments are constantly explored and studies.Seek the needs that a feasible way of dealing with problems becomes scientific technological advance and progress of human society.Topographic irregularity and rugged and rough be the common feature of these environment, thus the application of wheeled robot and caterpillar type robot is restricted.

In rescue and relief work, struggle against terror and Science Explorations, multi-foot robot has unique advantage.The path of motion of multi-foot robot is the footmark of series of discrete.Often containing rock, earth, the sand even obstacle such as cliff and abrupt slope in accidental relief, can the continuous path of stable support robot very limited.Discrete point cantact ground is only needed during multi-foot robot motion, comparatively strong to the comformability of this landform, also less to the degree of tortuosity of environment.The leg of multi-foot robot has multiple degree of freedom, and the alerting ability of motion is strengthened greatly.Multi-foot robot can keep body levels by regulating the action radius of leg, also can by regulating the position of the extension degree adjustment center of gravity of leg, therefore not prone to tip over, stability is higher, can finish the work very flexibly in rescue and relief work, struggle against terror and scientific exploration, improve the efficiency of plucking.The health of multi-foot robot is separated with ground, and the advantage of this physical construction is, the health of robot can move reposefully and need not consider the degree of roughness on ground and the placement location of leg.When robot needs to carry scientific instrument and other tool work, first leg is fixed, then accurately control health motion in three dimensions, just can reach the object that object is operated.Multi-foot robot has a wide range of applications in productive life, but current in multi-foot robot research, is all in the stage of comparing the initial stage both at home and abroad.To the research of multi-foot robot to the present productive life important in inhibiting of China.

Summary of the invention

The purpose of this utility model is to provide a kind of imitative spider multi-foot robot platform adopting bionics structure, to solve the problem that current robot utilizes vision system intelligent mobile under complex-terrain.

In order to realize above-mentioned task, the utility model by the following technical solutions:

A kind of multi-foot robot platform with vision system, comprise fuselage, multiple pedipulator by servo driving is distributed with at fuselage outer side, body upper is provided with vision system, vision system comprises stereoscopic camera and monocular camera, stereoscopic camera and monocular camera are arranged on a housing, and housing is arranged on fuselage by driver train.

Further, described housing comprises and being connected and the upper mainboard be parallel to each other, middle mainboard and lower mainboard by strut member, described stereoscopic camera and monocular camera are all arranged on the outside between mainboard and middle mainboard, be provided with conv between middle mainboard and lower mainboard, conv is connected with monocular camera and stereoscopic camera.

Further, described upper mainboard is octagon plate, and eight limits of upper mainboard are parallel to each other between two; In four opposite side that upper mainboard is parallel, wherein the length of side on pair of parallel limit is greater than other length of sides to parallel edges, and this pair parallel edges is called main limit, and other limits are called secondary, described stereoscopic camera is arranged on a wherein limit on main limit, and each secondary is provided with a monocular camera.

Further, the first bumper is provided with between described vision system and driver train, first bumper comprises stay bearing plate, symmetrical multiple hollow and without the stationary magazine creel of end face, be provided with axostylus axostyle in stationary magazine creel on stay bearing plate, axle end is fixed with positioning plate, shaft rod upper sleeve is equipped with the first spring, and one end of the first spring is fixed on bottom stationary magazine creel, and the other end of the first spring is fixed on positioning plate, positioning plate is connected with vision system, and stay bearing plate is connected with described driver train.

Further, described pedipulator comprises sufficient end, support portion and connecting portion, and described support portion adopts articulated structure, comprises two parts of movable connection, and wherein a part comprises the fixed mount for installing steering wheel, and another part comprises the second bumper; Between the second bumper and described foot end, be provided with sensor group, described connecting portion is connected with support portion is movable.

Further, a steering wheel is installed at the two ends of described fixed mount separately, is respectively the first steering wheel and the second steering wheel, and the first steering wheel is connected with the second pillar by the first attaching parts, and the second steering wheel is connected with connecting portion by the second attaching parts; The 3rd steering wheel be connected with fuselage is provided with in connecting portion.

Further, the second described bumper includes bottom surface, set casing without end face, is connected in described sensor group bottom set casing by the second pillar, and sensor group is connected with described foot end by the first pillar; Set casing inside is provided with the second spring, and set casing top, the second spring are all connected with the first attaching parts, is wherein connected for movable between case top with the first attaching parts.

Further, the first described attaching parts comprises the first support, and one end of the first support is connected with the second bumper, and the other end of the first support is fixed on and is installed on the first flange of the first steering wheel.

Further, the second described attaching parts comprises the second support, and the two ends of the second support are mounted on the three-flange dish on the 3rd steering wheel respectively and are arranged on the second flange on the second steering wheel.

Further, described foot end is semi-cylindrical, and the cambered surface of foot end is distributed with the groove that many are held radial direction along foot, circumference is interspersed, and the cambered surface of foot end is divided into multiple boxed area by these grooves.

Further, described fuselage comprises casing, and the edge of casing is connected with the 3rd steering wheel on pedipulator, is provided with controller and battery in casing.

The utility model has following technical characterstic:

Vision system of the present utility model adopts stereoscopic camera to add monocular camera reasonable Arrangement, and the dead angle of vision is little, and blind area is little, can position the object in dominant eye front, also can carry out monitoring analysis to both sides object simultaneously; Pedipulator adopts imitative spider design, has three degree of freedom, good damping effect, and motion flexibly; Fuselage is simple and practical.By rational design, what can realize simple, convenient, low cost erects imitative spider multi-foot robot experiment porch, can be used in the experiment of robot complex-terrain crossing ability, the experimental studies such as road crossing ability.

Accompanying drawing explanation

Fig. 1 is integral structure schematic diagram of the present utility model;

Fig. 2 is the structural representation of vision system;

Fig. 3 is the structural representation of fuselage;

Fig. 4 is the structural representation that pedipulator and Fuselage connection divide;

Fig. 5 is the integral structure schematic diagram of pedipulator;

Fig. 6 is the structural representation of the first bumper;

Number in the figure represents: 1-vision system, 2-fuselage, 3-pedipulator, 4-stereoscopic camera, 5-connecting element, 6-upper mainboard, 7-monocular camera, 8-middle mainboard, 9-strut member, 10-lower mainboard, 11-the first bumper, 12-conv, 13-the first spring, 14-stay bearing plate, 16-the three steering wheel, 17-the second attaching parts, 18-the second steering wheel, 19-fixed mount, 20-the first steering wheel, 21-the first attaching parts, 22-the second bumper, 23-sensor group, 24-foot end, 25-controller, 26-battery, 27-casing, 28-the second spring, 29-the second pillar, 30-the first pillar, 31-the three-flange dish, 32-the second flange, 33-the first flange, 34-positioning plate, 35-axostylus axostyle, 36-stationary magazine creel.

Detailed description of the invention

Defer to technique scheme, as shown in Figures 1 to 4, a kind of multi-foot robot platform with vision system, comprise fuselage 2, outside fuselage 2, be distributed with multiple pedipulator 3 by servo driving, be provided with vision system 1 above fuselage 2, vision system 1 comprises stereoscopic camera 4 and monocular camera 7, stereoscopic camera 4 and monocular camera 7 are arranged on a housing, and housing is arranged on fuselage 2 by driver train.

This robot platform that this programme provides, adopts bionic design structure, fuselage 2 is connected with six pedipulators 3, is similar to the structure of spider.Pedipulator 3 is controlled by multiple steering wheel, this multiple degree of freedom that just made pedipulator 3 have, and more flexibly, many pedipulators 3 are distributed in outside fuselage 2 simultaneously, make in action more steady.Arrange six pedipulators 3 in this programme, the advantage of distribution is like this possibility that robot decreases lower leg crash in the process of walking, adds the robust motion of body, increases the transmission space of leg.

Vision system 1 in this programme is for gathering graphicinformation.Vision system 1 comprises a binocular solid camera 4 and multiple monocular camera 7, is distributed in casing surroundings, can 360 ° without dead angle ground gather peripheral vision information.And whole vision system 1 is also rotary, as required, make housing into rotation by driver train, so just change the visual direction of camera, to reach good control effects.

Particularly, housing comprises and to be connected by strut member 9 and the size of the upper mainboard 6 be parallel to each other, middle mainboard 8 and lower mainboard 10, three mainboards, structure are identical; Described stereoscopic camera 4 and monocular camera 7 are all arranged on the outside between mainboard 6 and middle mainboard 8, and be provided with conv 12 between middle mainboard 8 and lower mainboard 10, conv 12 is connected with monocular camera 7 and stereoscopic camera 4.Upper mainboard 6 is octagon plate, and eight limits of upper mainboard 6 are parallel to each other between two; In four opposite side that upper mainboard 6 is parallel, wherein the length of side on pair of parallel limit is greater than other length of sides to parallel edges, this a pair parallel edges is called main limit, other limits are called secondary, described stereoscopic camera 4 is arranged on a wherein limit on main limit, and each secondary is provided with a monocular camera 7.

Upper mainboard 6 is not octagon, and wherein pair of parallel limit will comparatively other length of sides some, this is called main limit to parallel edges, a main limit is installed stereoscopic camera 4 wherein, leaves sufficient room to the installation of camera.Stereoscopic camera 4 is placed on foremost, all the other six monocular cameras 7 occupy six orientation for auxiliary, in order to the work of dominant eye can be assisted, there is certain angle in the visual field of monocular camera 7 and dominant eye, namely the angle of acute angle is had between the optical axis of monocular camera 7 and the optical axis of stereoscopic camera 4, effectively in order to reduce the blind area between stereoscopic camera 4 and monocular camera 7.

Particularly, in stereoscopic camera 4 installation process, can extend out a part of stripe board on the main limit of upper mainboard 6 and middle mainboard 8, and be arranged between these two stripe board by a pair main stereoscopic camera 4, its side is locked by connecting element 5.Connecting element 5 adopts cross plate structure, utilizes bolt and nut and upper mainboard 6, middle mainboard 8 fastening.Between middle mainboard 8 and lower mainboard 10, be provided with conv 12, conv 12 is connected with described stereoscopic camera 4, monocular camera 7, and is connected with the controller 25 of robot, sends to controller 25 by after the graphicinformation conversion process of collection.

For reducing the impact shaken in robot kinematics vision system 1, the first bumper 11 is provided with between vision system 1 and driver train, as shown in Figure 6, first bumper 11 comprises stay bearing plate 14, symmetrical multiple hollow and without the stationary magazine creel 36 of end face on stay bearing plate 14, axostylus axostyle 35 is provided with in stationary magazine creel 36, axostylus axostyle 35 end winding support limited location plate 34, axostylus axostyle 35 is set with the first spring 13, one end of first spring 13 is fixed on bottom stationary magazine creel 36, the other end of the first spring 13 is fixed on positioning plate 34, positioning plate 34 is connected with the lower mainboard 10 on vision system 1 housing, stay bearing plate 14 is connected with described driver train.Driver train can adopt motor, is fixedly connected with between the output shaft of motor with stay bearing plate 14 by attaching parts.

Pedipulator 3 structure in this programme, as shown in Figure 4, Figure 5, pedipulator 3 comprises foot end 24, support portion and connecting portion, described support portion adopts articulated structure, comprise two parts of movable connection, wherein a part comprises the fixed mount 19 for installing steering wheel, and another part comprises the second bumper 22; Between the second bumper 22 and described foot end 24, be provided with sensor group 23, described connecting portion is connected with support portion is movable.A steering wheel is installed at the two ends of fixed mount 19 separately, is respectively the first steering wheel 20 and the second steering wheel 18, first steering wheel 20 is connected with the second bumper 22 by the first attaching parts 21, and the second steering wheel 18 is connected with connecting portion by the second attaching parts 17; The 3rd steering wheel 16 be connected with fuselage 2 is provided with in connecting portion.

Pedipulator 3 has in three " joints ", and first is the 3rd steering wheel 16 place, and the 3rd steering wheel 16 is connected with fuselage 2, and steering wheel can change direction, has one degree of freedom here; Second " joint " is the second steering wheel 18 place, and the second steering wheel 18 is connected with connecting portion, is second degree of freedom here; 3rd " joint " is that the first steering wheel 20, first steering wheel 20 is connected with between the second bumper 22, and can change direction and the position of the second support portion, bumper 22 place, be three degree of freedom here.Thus, this pedipulator 3 structure that this programme proposes, has multiple degree of freedom, makes it take action more nimble.Sensor group comprises multiple sensor, as infrared pickoff, force snesor etc., by the feedback of sensor to controller, adjusts the Running strategy of robot, with avoiding barrier etc.

Attaching parts mainly plays connection function, and the first attaching parts 21 comprises the first support, and one end of the first support is connected with the second bumper 22, and the other end of the first support is fixed on and is installed on the first flange 33 of the first steering wheel 20.As shown in the figure, two risers that the first attaching parts 21 comprises a base plate and arranges perpendicular to base plate, two risers are connected with two flanges of the first steering wheel 20 both sides respectively.Such first steering wheel 20 just can change the form of being somebody's turn to do " joint " by flange.And the structure of the first attaching parts 21 also ensure that in articulation process, the first steering wheel 20 is not subject to the impact of the second bumper 22.

Second attaching parts 17 and the first attaching parts 21 structural similitude, difference is, the both sides of the base plate of the second attaching parts 17 respectively distribute a pair riser, the installation direction of two pairs of risers of base plate both sides is mutually vertical, and the line (shortest distance lines) namely between the riser of two, the same side is perpendicular to the line between opposite side two risers.The riser of base plate both sides is connected with the second flange 32 on the second steering wheel 18, the 3rd steering wheel 16, three-flange dish 31 separately.Such 3rd steering wheel 16, second steering wheel 18 just can, based on the second attaching parts 17, drive the second attaching parts 17 to change the angle of different directions, to reach the object changing whole pedipulator attitude.All the time leave certain interval between above-mentioned base plate and steering wheel, such steering wheel would not touch attaching parts in operational process.

Owing to being provided with vision system 1 in the present invention, wherein have multiple precision instrument, the vibration influence therefore for system has strict requirement.For this problem, in scheme, adopt double damping pattern, except aforesaid first bumper 11, be also provided with the second bumper 22:

Second bumper 22 includes bottom surface, set casing without end face, and be connected in described sensor group 23 by the second pillar 29 bottom set casing, sensor group 23 is connected with described foot end 24 by the first pillar 30; Set casing inside is provided with the second spring 28, and set casing top, the second spring 28 are all connected with the first attaching parts 21, is wherein connected for movable between case top with the first attaching parts 21.Operationally, by the power that transmit of foot end 24, when the second bumper 22, part is absorbed counteracting by the second spring 28, and between set casing with the first attaching parts 21 movable connection be to ensure the stability connected.This structure design is easy, attractive in appearance and can expendable weight.

Foot end 24 is semi-cylindrical, and the cambered surface of sufficient end 24 is distributed with many grooves be interspersed along foot end 24 radial direction, circumference, the cambered surface of foot end 24 is divided into multiple boxed area by these grooves.These boxed area, can be regarded as protruding one by one, for the road conditions that ground is different, after being provided with this structure, can adapt to different road surface like this, whenever can ensure with ground it is linear contact lay.Utilize protruding and groove during walking, the close contact more such as projection, depression that can be trickle with ground, prevents from, in pedipulator 3 motion process, slippery conditions occurs.

As shown in Figure 3, fuselage 2 comprises casing 27, and the edge of casing 27 is connected with the 3rd steering wheel 16 on pedipulator 3, is provided with controller 25 and battery 26 in casing 27, controller 25 controls vision system 1, and in vision system 1, the information of collected by camera passes to controller 25 after being processed by conv 12; Also control the running of driver train with Time Controller 25, with change vision system 1 towards; In pedipulator 3, the running of each steering wheel is also controlled by controller 25, and the supply of the electric power of whole system is provided by battery 26.

No matter the utility model is the laying of vision system or pedipulator, all utilize bionics principle, with reference to the physiological structure of spider, this vision platform adopts the structure of a pair dominant eye and six secondary eyes, the vision being similar to spider obtains system, it is little that this structure retains dead angle, almost do not have vision dead zone in the horizontal direction, thus the object localization function of robot to dominant eye front is had significantly promote; Simultaneously due to the fit structure between secondary eye and dominant eye, make robot in the process of walking, can rotatable platform as few as possible, not only effectively reduce energy consumption, also reduce the process intensity of robot processor to video information, thus make treater can have less information processing capacity, with hoisting machine person's development speed, ensure excellent in-use performance.

Claims (10)

1. one kind has the multi-foot robot platform of vision system, comprise fuselage (2), it is characterized in that, described fuselage (2) outside is distributed with multiple pedipulator (3) by servo driving, fuselage (2) top is provided with vision system (1), vision system (1) comprises stereoscopic camera (4) and monocular camera (7), stereoscopic camera (4) and monocular camera (7) are arranged on a housing, and housing is arranged on fuselage (2) by driver train.

2. there is the multi-foot robot platform of vision system as claimed in claim 1, it is characterized in that, described housing comprises and being connected and the upper mainboard (6) be parallel to each other, middle mainboard (8) and lower mainboard (10) by strut member (9), described stereoscopic camera (4) and monocular camera (7) are all arranged on the outside between mainboard (6) and middle mainboard (8), be provided with conv (12) between middle mainboard (8) and lower mainboard (10), conv (12) is connected with monocular camera (7) and stereoscopic camera (4).

3. have the multi-foot robot platform of vision system as claimed in claim 2, it is characterized in that, described upper mainboard (6) is octagon plate, and eight limits of upper mainboard (6) are parallel to each other between two; In four opposite side that upper mainboard (6) is parallel, wherein the length of side on pair of parallel limit is greater than other length of sides to parallel edges, this a pair parallel edges is called main limit, other limits are called secondary, described stereoscopic camera (4) is arranged on a wherein limit on main limit, and each secondary is provided with a monocular camera (7).

4. there is the multi-foot robot platform of vision system as claimed in claim 1, it is characterized in that, the first bumper (11) is provided with between described vision system (1) and driver train, first bumper (11) comprises stay bearing plate (14), stay bearing plate (14) is upper symmetrical multiple hollow and without the stationary magazine creel (36) of end face, axostylus axostyle (35) is provided with in stationary magazine creel (36), axostylus axostyle (35) end winding support limited location plate (34), axostylus axostyle (35) is set with the first spring (13), one end of first spring (13) is fixed on stationary magazine creel (36) bottom, the other end of the first spring (13) is fixed on positioning plate, positioning plate is connected with vision system (1), stay bearing plate (14) is connected with described driver train.

5. there is the multi-foot robot platform of vision system as claimed in claim 1, it is characterized in that, described pedipulator (3) comprises sufficient end (24), support portion and connecting portion, described support portion adopts articulated structure, comprise two parts of movable connection, wherein a part comprises the fixed mount (19) for installing steering wheel, and another part comprises the second bumper (22); Between the second bumper (22) and described foot end (24), be provided with sensor group (23), described connecting portion is connected with support portion is movable.

6. there is the multi-foot robot platform of vision system as claimed in claim 5, it is characterized in that, a steering wheel is installed at the two ends of described fixed mount (19) separately, be respectively the first steering wheel (20) and the second steering wheel (18), first steering wheel (20) is connected with the second bumper (22) by the first attaching parts (21), and the second steering wheel (18) is connected with connecting portion by the second attaching parts (17); The 3rd steering wheel (16) be connected with fuselage (2) is provided with in connecting portion.

7. there is the multi-foot robot platform of vision system as claimed in claim 5, it is characterized in that, described foot end (24) is semi-cylindrical, the cambered surface of foot end (24) is distributed with many and holds along foot the groove that (24) are radial, circumference is interspersed, the cambered surface of sufficient end (24) is divided into multiple boxed area by these grooves.

8. there is the multi-foot robot platform of vision system as claimed in claim 6, it is characterized in that, described fuselage (2) comprises casing (27), the edge of casing (27) is connected with the 3rd steering wheel (16) on pedipulator (3), is provided with controller (25) and battery (26) in casing (27).

9. there is the multi-foot robot platform of vision system as claimed in claim 5, it is characterized in that, described the second bumper (22) includes bottom surface, set casing without end face, be connected in described sensor group (23) by the second pillar (29) bottom set casing, sensor group (23) is connected with described foot end (24) by the first pillar (30); Set casing inside is provided with the second spring (28), set casing top, the second spring (28) are all connected with the first attaching parts (21), are wherein connected for movable between set casing top with the first attaching parts (21).

10. there is the multi-foot robot platform of vision system as claimed in claim 6, it is characterized in that, described the first attaching parts (21) comprises the first support, one end of first support is connected with the second bumper (22), and the other end of the first support is fixed on and is installed on first flange (33) of the first steering wheel (20).