CN110918324A

CN110918324A - Multi-gun mixed control paint spraying robot based on visual servo

Info

Publication number: CN110918324A
Application number: CN201911314660.6A
Authority: CN
Inventors: 杨凯
Original assignee: Individual
Current assignee: Yueqing Fanshan Electric Appliance Co Ltd
Priority date: 2019-12-19
Filing date: 2019-12-19
Publication date: 2020-03-27
Anticipated expiration: 2039-12-19
Also published as: CN112403747B; CN112403747A; CN110918324B; CN112452597A; CN112452597B

Abstract

The invention discloses a multi-gun mixed control paint spraying robot based on visual servo, which comprises a chassis and a workbench, the top of the workbench is provided with a support, the top of the support is rotatably connected with a large arm through a bearing, one side of the support is provided with a main motor, one side of the large arm is rotatably connected with a connecting shell through a bearing, a wrist part is arranged on one side of the connecting shell, a spray head is arranged on one side of the wrist part, a single-point balancing device is arranged at the bottom of the chassis, a static pressure detection device is arranged inside the chassis, an annular groove is arranged at the bottom of the chassis, the single-point balancing device comprises a hydraulic prop, one end of the hydraulic prop is connected with a slide block, the slide block and the annular groove form a sliding pair, the hydraulic prop has the characteristics of wide working range and capability of mixing multi-color paint.

Description

Multi-gun mixed control paint spraying robot based on visual servo

Technical Field

The invention relates to the technical field of paint spraying, in particular to a multi-gun mixed control paint spraying robot based on visual servo.

Background

The spraying robot is an industrial robot which can automatically spray paint or other coatings. The spray painting robot mainly comprises a robot body, a computer and a corresponding control system, and the hydraulically driven spray painting robot further comprises a hydraulic oil source, such as an oil pump, an oil tank, a motor and the like. It is classified into an air spraying robot and an airless spraying robot.

The existing paint spraying robot intelligently sprays single-color paint or after spraying one color, a paint bucket is replaced, the other color is switched, and the multi-color mixed spraying effect cannot be finished; the existing spraying robot mechanical arm cannot move in a far posture, otherwise, the existing spraying robot mechanical arm needs to be adapted to a larger chassis area to maintain stability; present paint spraying robot has been in the spraying one place position, if fill electric pile back, need pack up the arm when moving to another place and be convenient for keep the focus stable when moving, need expand the arm once more when advancing to next place, work efficiency is low. Therefore, it is necessary to design a multi-gun hybrid control painting robot based on visual servo, which has a wide working range and can mix multi-color paint.

Disclosure of Invention

The invention aims to provide a multi-gun mixed control paint spraying robot based on visual servo to solve the problems in the background technology.

In order to solve the technical problems, the invention provides the following technical scheme: the utility model provides a multi-gun mixed control paint spraying robot based on visual servoing, includes chassis and workstation, the support is installed at the top of workstation, the top of support is rotated through the bearing and is connected with big arm, main motor is installed to one side of support, one side of big arm is rotated through the bearing and is connected with the connection shell, one side of connection shell is provided with the wrist, the shower nozzle is installed to one side of wrist, single-point balancing unit is installed to the bottom on chassis, the inside on chassis is provided with static pressure detection device.

Further, the ring channel has been seted up to the bottom on chassis, single-point balancing unit includes hydraulic prop, hydraulic prop's one end is connected with the slider, the slider constitutes the slip pair with the ring channel, hydraulic prop's the other end is connected with the supporting leg, the bottom of supporting leg is inwards sunken slottedly, and the inner wall in groove evenly installs the gyro wheel, the rotating electrical machines is installed to one side of supporting leg, the output shaft of rotating electrical machines is connected with the gyro wheel.

Further, the static pressure detection device includes the oil pump, there is the oil tank input of oil pump through the tube coupling, there is the overflow valve output of oil pump through the tube coupling, there are a plurality of choke valves output of oil pump still through the tube coupling, the bottom protrusion of workstation is provided with the sliding part, the top protrusion on chassis is provided with down the sliding part, the sliding part constitutes the sliding pair with last sliding part down, set up hydraulic pressure oil pocket in the sliding part down, and hydraulic pressure oil pocket passes through the tube coupling with the overflow valve.

Furthermore, the bottom of workstation evenly installs the locating lever, the spring has been cup jointed to the outside of locating lever, the locating lever activity passes the ring channel, and the bottom and the slider of locating lever contact.

Furthermore, the two sides of the support are correspondingly provided with a hybrid drive system, the hybrid drive system comprises a direction adjusting motor arranged between the two supports, an output shaft of the direction adjusting motor is sleeved with a belt wheel, the outside of the belt wheel is sleeved with a synchronous toothed belt, the belt wheel is meshed with the synchronous toothed belt, the two ends of the synchronous toothed belt are connected with hoses, one side of the support is provided with a fixing plate, one side of the big arm and one side of the wrist are both rotatably provided with a disc sheave, the outside of the disc sheave is sleeved with steel wire ropes, and the two ends of the two steel wire ropes are respectively connected with the hoses positioned at the two sides of the support.

Further, paint mixing arrangement is including installing in the epitheca of the bottom of connecting the shell, the inside of epitheca is run through and is provided with a plurality of spiral pipe, the spiral pipe is including spiraling outer tube, well pipe and the inner tube that the circumference radius reduces in proper order, the quantity of outer tube is more than well pipe, the quantity of well pipe is more than the inner tube, the bottom through connection of spiral pipe has the inferior valve, inferior valve and shower nozzle link up each other.

Further, it is provided with the paint kettle to pile up from top to bottom in the inside of connecting the shell, the through-hole has evenly been seted up to one side of paint kettle, the spiral pipe passes the through-hole, the top of paint kettle has into oil pipe through welded fastening, it link up each other with the paint kettle to advance oil pipe, every advance oil pipe and distribute in the different positions of every paint kettle's circumference, the spiral pipe links up mutually with advancing oil pipe, advance oil pipe and be connected outside pressure source.

Further, the bottom on chassis is seted up slottedly, and the inside in groove is rotated through the bearing and is connected with the revolving stage, the bottom inner wall on chassis is installed and is turned to the motor, it is vice to be provided with gear fluted disc between the output shaft of motor and the revolving stage to turn to, the bottom of revolving stage is inwards sunken, and the depressed part is provided with telescopic cylinder, telescopic cylinder's bottom is connected with the track wheelset, the track wheelset is connected with external drive moment.

Compared with the prior art, the invention has the following beneficial effects: in the invention, the raw materials are mixed,

(1) the hybrid driving system provided by the motor and the rope replaces the traditional mechanical arm driving mode, and the rope has flexibility in the transmission process, so that the motor can be moved backwards onto the rear seat, the weight of the wrist joint is reduced, and the whole machine is simpler and more compact;

(2) the flexible hose is sleeved outside the rope, so that the rope slides in the flexible hose during driving, the flexible hose keeps that the two ends of the rope can transmit torque all the time, the large arm can drive the wrist joint to various positions, and the flexible hose is a plastic body with higher hardness and does not obstruct the normal work of the mechanical arm;

(3) the single-point balancing device is arranged at the bottom of the chassis, so that the whole body can be kept balanced when the center of gravity of the mechanical arm is shifted due to any posture, the size of the chassis is reduced, the device is more flexible, the mechanical arm can be extended to a farther position, and the working range of the robot is improved;

(4) the static pressure detection device is arranged at the joint of the chassis and the workbench, the balance of the mechanical arm is maintained by static pressure, and the mechanical arm can be buffered by hydraulic force when lifted and put down, so that the noise is reduced, and the device runs stably; when the posture of the mechanical arm is greatly changed, the pressure in the cavity is changed through the throttle valve, so that the angle of the workbench deviates, then the support legs are driven to rotate around the axle center, the positioning rod sinks, so that the support legs can move to the gravity center deviation position, and the gravity center position can be automatically judged for adaptive adjustment;

(6) through being provided with paint mixing arrangement, can make the paint of different colours fully premix according to the proportion of wanting, spout polychrome paint from the shower nozzle again for spun paint can change the colour according to user's needs more fast more conveniently.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the construction of the chassis of the present invention;

FIG. 3 is a side cross-sectional structural view of the chassis of the present invention;

FIG. 4 is a hydraulic schematic diagram of the static pressure test apparatus of the present invention;

FIG. 5 is a schematic view of the mounting of the support and boom of the present invention;

FIG. 6 is a schematic diagram of the hybrid propulsion system configuration of the present invention;

FIG. 7 is a schematic view of the paint mixing apparatus of the present invention;

FIG. 8 is a schematic view from A-A of FIG. 7 of the present invention;

FIG. 9 is a schematic view of the installation of the paint bucket and coil of the present invention;

in the figure: 1. a chassis; 2. a work table; 3. a static pressure detection device; 4. a single point balancing device; 5. a hybrid drive system; 6. a paint mixing device; 11. a turntable; 111. a gear fluted disc pair; 12. a crawler belt wheel group; 13. a telescopic cylinder; 14. an annular groove; 15. a steering motor; 16. a lower sliding part; 21. a support; 211. a main motor; 22. a large arm; 23. a connecting shell; 24. a wrist portion; 241. a spray head; 25. an upper sliding part; 31. a spring; 32. positioning a rod; 33. a throttle valve; 34. an overflow valve; 35. an oil pump; 36. an oil tank; 41. supporting legs; 42. a hydraulic prop; 43. a rotating electric machine; 44. a roller; 45. a slider; 51. a fixing plate; 52. a pulley; 53. a hose; 54. a disk sheave; 55. a synchronous toothed belt; 56. a wire rope; 57. a direction-adjusting motor; 61. an upper shell; 62. a spiral tube; 621. an inner tube; 622. a middle tube; 623. an outer tube; 63. a lower case; 64. a paint bucket; 641. an oil inlet pipe; 642. and a through hole.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, the present invention provides a technical solution: a multi-gun mixed control paint spraying robot based on visual servo comprises a chassis 1 and a workbench 2, wherein the top of the workbench 2 is provided with a support 21, the top of the support 21 is rotatably connected with a large arm 22 through a bearing, one side of the support 21 is provided with a main motor 211, one side of the large arm 22 is rotatably connected with a connecting shell 23 through a bearing, one side of the connecting shell 23 is provided with a wrist 24, one side of the wrist 24 is provided with a spray head 241, the bottom of the chassis 1 is provided with a single-point balancing device 4, the chassis 1 is internally provided with a static pressure detection device 3, the static pressure detection device 3 is used for detecting the gravity center position of the mechanical arm, the single-point balancing device 4 is used for balancing the whole robot by utilizing a fulcrum, the size of the chassis 1 is reduced, meanwhile, the mechanical arm can be extended to a farther position, the working range of the robot is improved, and the main motor 211 drives the large arm 22 to move;

as shown in fig. 2-3, the bottom of the chassis 1 is provided with an annular groove 14, the single-point balancing device 4 comprises a hydraulic prop 42, one end of the hydraulic prop 42 is connected with a slide block 45, the slide block 45 and the annular groove 14 form a sliding pair, the other end of the hydraulic prop 42 is connected with a supporting leg 41, the bottom of the supporting leg 41 is recessed inwards to form a groove, the inner wall of the groove is uniformly provided with a roller 44, one side of the supporting leg 41 is provided with a rotating motor 43, the output shaft of the rotating motor 43 is connected with the roller 44, when the center of gravity shifts and needs to be rebalanced, the rotating motor 43 is started to drive the roller 44 to roll, so that the slide block 45 slides in the annular groove 14 to drive the supporting leg 41 to move to a;

as shown in fig. 3-4, the static pressure detection device 3 includes an oil pump 35, an input end of the oil pump 35 is connected with an oil tank 36 through a pipeline, an output end of the oil pump 35 is connected with an overflow valve 34 through a pipeline, an output end of the oil pump 35 is further connected with a plurality of throttle valves 33 through pipelines, an upper sliding portion 25 is convexly arranged at the bottom of the workbench 2, a lower sliding portion 16 is convexly arranged at the top of the chassis 1, the lower sliding portion 16 and the upper sliding portion 25 form a sliding pair, a hydraulic oil chamber is arranged in the lower sliding portion 16, and the hydraulic oil chamber is connected with the overflow valve 34 through a pipeline, so that the balance of the mechanical arm is normally maintained by static pressure, the mechanical arm can be buffered; when the posture of the mechanical arm is greatly changed, the pressure in the cavity is changed through the throttle valve 33, so that the angle of the workbench deviates, then the support legs are driven to rotate around the axle center, the positioning rod 32 sinks, so that the support legs 41 can be moved to the gravity center deviation position, and the gravity center position can be automatically judged for adaptive adjustment;

as shown in fig. 3, the positioning rods 32 are uniformly installed at the bottom of the workbench 2, the springs 31 are sleeved outside the positioning rods 32, the positioning rods 32 movably penetrate through the annular groove 14, the bottom of the positioning rods 32 is in contact with the sliding blocks 45, and when the center of gravity is deviated, the positioning rods 32 enter the annular groove 14 to block the position of the sliding blocks 45, so that the supporting legs 41 are moved to the center of gravity;

referring to fig. 1, 5 and 6, the hybrid driving system 5 is correspondingly installed on two sides of the support 21, the hybrid driving system 5 includes a direction-adjusting motor 57 installed between the two supports 21, a pulley 52 is sleeved on an output shaft of the direction-adjusting motor 57, a synchronous cog belt 55 is sleeved on the outside of the pulley 52, the pulley 52 is meshed with the synchronous cog belt 55, two ends of the synchronous cog belt 55 are connected with hoses 53, a fixing plate 51 is installed on one side of the support 21, a disc sheave 24 is rotatably installed on one side of the boom 22 and one side of the wrist 24, a steel wire rope 56 is sleeved on the outside of the disc sheave 24, two ends of the two steel wire ropes 56 are respectively connected with the hoses 53 located on two sides of the support 21, when the hybrid driving is performed, the hoses keep that two ends of the steel wire rope 56 can always transmit torque, so that the boom can drive the wrist to various positions, the hoses 53 are high-, the normal work of the mechanical arm is not hindered, the steel wire rope 56 can be prevented from being randomly deformed, the driving replaces the traditional mechanical arm driving mode, and the steel wire rope 56 has flexibility in the transmission process, so that the motor can be moved backwards to a rear seat, the weight of a wrist joint is reduced, and the whole machine is simpler and more compact;

as shown in fig. 7-8, the paint mixing device 6 includes an upper shell 61 installed at the bottom of the connecting shell 23, a plurality of spiral pipes 62 are arranged in the upper shell 61 in a penetrating manner, each spiral pipe 62 includes an outer pipe 623, a middle pipe 622 and an inner pipe 621, the radius of the spiral circumference of each spiral pipe is sequentially reduced, the number of the outer pipes 623 is greater than that of the middle pipes 622, the number of the middle pipes 622 is greater than that of the inner pipes 621, the bottom of each spiral pipe 62 is connected with a lower shell 63 in a penetrating manner, the lower shell 63 is communicated with the spray head 241, the arrangement mode of the spiral pipes 62 increases resistance, so that the spiral pipes cannot leak;

as shown in fig. 9, paint buckets 64 are stacked up and down inside the connecting shell 23, through holes 642 are uniformly formed in one side of each paint bucket 64, the spiral pipe 62 penetrates through the through holes 642, an oil inlet pipe 641 is fixed to the top of each paint bucket 64 through welding, the oil inlet pipe 641 is communicated with the paint buckets 64, each oil inlet pipe 641 is distributed at different positions of the circumference of each paint bucket 64, the spiral pipe 62 is communicated with the oil inlet pipe 641, the oil inlet pipe 641 is connected with an external pressure source, each oil inlet pipe 641 is used for supplying paint to the paint bucket 64, when the device is used, the pressure source enables the paint in the paint bucket 64 to be injected into the spray head 241 through the oil inlet pipe 641, and the stacked paint buckets 64 enable the paint of various colors to be loaded into the device, and when the paint is mixed, the oil inlet pipes 641 have different pressures according to the mixed;

as shown in fig. 2-3, a groove is formed in the bottom of the chassis 1, a rotating table 11 is rotatably connected inside the groove through a bearing, a steering motor 15 is installed on the inner wall of the bottom of the chassis 1, a gear-toothed disc pair 111 is arranged between an output shaft of the steering motor 15 and the rotating table 11, the bottom of the rotating table 11 is recessed inwards, a telescopic cylinder 13 is arranged at the recessed position, a crawler wheel group 12 is connected to the bottom of the telescopic cylinder 13, the crawler wheel group 12 is connected with an external driving torque, when steering is performed, the steering motor 15 is driven, the rotating table 11 drives the chassis 1 to steer through the gear-toothed disc pair 111, when positioning, the crawler wheel group 12 is retracted by the telescopic cylinder 13, when moving, the telescopic cylinder 13 pushes out the crawler wheel group again, and switching between a moving;

example (b): when using this robot that sprays paint, move whole device and remove to waiting to spray the operating position before driving caterpillar band wheelset 12, it is accurate with the arm orientation through turning to motor 15, adjust big arm 22, connect the angle of shell 23 and shower nozzle 241 respectively according to the procedure that control system set for after that, make shower nozzle 241 spray paint according to the orbit of settlement, utilize static pressure detection device 3 to detect the focus position when the focus shifts by a wide margin, make single-point balancing unit 4 just support whole robot, utilize paint mixing arrangement 6 homogeneous mixing paint during the mixed paint.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. The utility model provides a multi-gun mixed control paint spraying robot based on visual servo, includes chassis (1) and workstation (2), support (21) are installed at the top of workstation (2), the top of support (21) is rotated through the bearing and is connected with big arm (22), main motor (211) are installed to one side of support (21), one side of big arm (22) is rotated through the bearing and is connected with connection shell (23), one side of connecting shell (23) is provided with wrist (24), shower nozzle (241), its characterized in that are installed to one side of wrist (24): the single-point balance device (4) is installed at the bottom of the chassis (1), and the static pressure detection device (3) is arranged inside the chassis (1).

2. The multi-gun hybrid control painting robot based on visual servo as claimed in claim 1, wherein: annular groove (14) have been seted up to the bottom on chassis (1), single-point balancing unit (4) include hydraulic prop (42), the one end of hydraulic prop (42) is connected with slider (45), slider (45) and annular groove (14) are constituteed to slide vice, the other end of hydraulic prop (42) is connected with supporting leg (41), the bottom of supporting leg (41) is inwards sunken slottedly, and the inner wall in groove evenly installs gyro wheel (44), rotating electrical machines (43) are installed to one side of supporting leg (41), the output shaft of rotating electrical machines (43) is connected with gyro wheel (44).

3. The multi-gun hybrid control painting robot based on visual servo as claimed in claim 1, wherein: static pressure detection device (3) include oil pump (35), there is oil tank (36) input of oil pump (35) through the tube coupling, there is overflow valve (34) output of oil pump (35) through the tube coupling, there are a plurality of choke valves (33) still through the tube coupling in the output of oil pump (35), the bottom protrusion of workstation (2) is provided with sliding part (25), the top protrusion on chassis (1) is provided with down sliding part (16), sliding part (16) and last sliding part (25) constitute the slip pair down, set up the hydraulic pressure oil pocket in sliding part (16) down, and pass through the tube coupling with overflow valve (34) hydraulic pressure oil pocket.

4. The multi-gun hybrid control painting robot based on visual servo as claimed in claim 2, wherein: positioning rods (32) are uniformly installed at the bottom of the workbench (2), springs (31) are sleeved outside the positioning rods (32), the positioning rods (32) movably penetrate through the annular grooves (14), and the bottoms of the positioning rods (32) are in contact with the sliding blocks (45).

5. The multi-gun hybrid control painting robot based on visual servo as claimed in claim 1, wherein: the hybrid drive system (5) is correspondingly installed on two sides of the support (21), the hybrid drive system (5) comprises a direction-adjusting motor (57) installed between the two supports (21), a belt wheel (52) is sleeved on an output shaft of the direction-adjusting motor (57), a synchronous toothed belt (55) is sleeved on the outer portion of the belt wheel (52), the belt wheel (52) is meshed with the synchronous toothed belt (55), hoses (53) are connected to two ends of the synchronous toothed belt (55), a fixing plate (51) is installed on one side of each support (21), a disc sheave (24) is installed on one side of a large arm (22) and one side of a wrist (24) in a rotating mode, steel wire ropes (56) are sleeved on the outer portion of the disc sheave (24), and two ends of the steel wire ropes (56) are connected with the hoses (53) located on two sides of the supports (21) respectively.

6. The multi-gun hybrid control painting robot based on visual servo as claimed in claim 1, wherein: paint mixing arrangement (6) is including installing in upper shell (61) of the bottom of connecting shell (23), the inside of upper shell (61) is run through and is provided with a plurality of spiral pipe (62), spiral pipe (62) are including outer tube (623), well pipe (622) and inner tube (621) that spiral circumference radius reduces in proper order, the quantity of outer tube (623) is more than well pipe (622), the quantity of well pipe (622) is more than inner tube (621), the bottom through connection of spiral pipe (62) has lower casing (63), lower casing (63) link up each other with shower nozzle (241).

7. The multi-gun hybrid control painting robot based on visual servo as claimed in claim 6, wherein: connect the inside of shell (23) to pile up from top to bottom and be provided with paint kettle (64), through-hole (642) have evenly been seted up to one side of paint kettle (64), through-hole (642) are passed in spiral pipe (62), the top of paint kettle (64) is fixed with into oil pipe (641) through the welding, advance oil pipe (641) and link up each other with paint kettle (64), every advance oil pipe (641) and distribute in the different positions of the circumference of every paint kettle (64), spiral pipe (62) link up mutually with advancing oil pipe (641), advance oil pipe (641) and connect outside pressure source.

8. The multi-gun hybrid control painting robot based on visual servo as claimed in claim 1, wherein: the bottom of chassis (1) is seted up slottedly, and the inside in groove is connected with revolving stage (11) through the bearing rotation, the bottom inner wall of chassis (1) is installed and is turned to motor (15), be provided with between output shaft and revolving stage (11) of turning to motor (15) gear fluted disc pair (111), the bottom of revolving stage (11) is inwards sunken, and the depressed part is provided with telescopic cylinder (13), the bottom of telescopic cylinder (13) is connected with track wheelset (12), track wheelset (12) are connected with external drive moment.