CN111054540A

CN111054540A - Aircraft printing spraying device

Info

Publication number: CN111054540A
Application number: CN202010104116.5A
Authority: CN
Inventors: 不公告发明人
Original assignee: Yongkang Turen Printing Technology Co Ltd
Current assignee: Yongkang Turen Printing Technology Co Ltd
Priority date: 2020-02-20
Filing date: 2020-02-20
Publication date: 2020-04-24

Abstract

The invention discloses an aircraft printing and spraying device, which comprises a movable shell, wherein the movable shell is internally provided with a moving device, the moving device comprises a rotating cavity, a motor is fixedly arranged between the left end wall and the right end wall of the rotating cavity, a wheel carrier is fixedly arranged below the movable shell, a moving cavity positioned below the rotating cavity is arranged in the wheel carrier, a coating on the surface of an aircraft is gradually aged or falls off along with the passage of time due to the influence of weather and environmental conditions and complex airflow in flight, the spraying is required to be carried out again at the moment, the aircraft must be overhauled after flying to a certain age according to the maintenance requirement of the aircraft, the old coating must be removed during the overhaul, and a new coating is sprayed again after the defects of all parts of the aircraft are repaired.

Description

Aircraft printing spraying device

Technical Field

The invention relates to the technical field, in particular to an airplane printing and spraying device.

Background

The coating on the surface of the airplane is gradually aged or falls off along with the lapse of time due to the influence of climate and environmental conditions and complex airflow in flight, and then spraying again is needed, and according to the maintenance requirement of the airplane, after the airplane flies to a certain age, overhaul must be carried out, and old coating must be removed during overhaul, and new coating is sprayed again after the defects of all parts of the airplane are repaired, so that along with the continuous increase of the number of airplanes, the recoating work of the coating on the surface of the airplane also becomes a major business of airplane maintenance enterprises, the proportion occupied in the airplane maintenance business is more and more large, but the existing spraying printing is manually controlled, the trouble is wasted, and the cost is not saved.

Disclosure of Invention

Aiming at the technical defects, the invention provides a method which can overcome the defects.

The invention relates to an airplane printing and spraying device, which comprises a moving shell, wherein the moving shell is internally provided with a moving device, the moving device comprises a rotating cavity, a motor is fixedly arranged between the left end wall and the right end wall of the rotating cavity, a wheel carrier is fixedly arranged below the moving shell, the wheel carrier is internally provided with a moving cavity positioned below the rotating cavity, the lower end surface of the wheel carrier is provided with two wheel grooves which are symmetrical relative to the moving cavity, the left end wall and the right end wall of the rotating cavity are internally provided with lifting grooves communicated with the left end wall and the right end wall of the moving shell, the left side of the moving shell is provided with a positioning device, the positioning device comprises a positioning shell, a lifting block which extends leftwards to the left side of the left end surface of the moving shell is arranged in the lifting groove, the left end of the lifting block is fixedly connected with the, the left side of location casing is equipped with the opening rotation casing left, be equipped with first rotation groove in the left end face of rotation casing, it is connected with the polishing casing to rotate between the upper and lower end wall in first rotation groove, be equipped with burnishing device in the polishing casing and be located the printing spraying device of burnishing device below, burnishing device includes the polishing chamber, the printing spraying device is including the printing chamber, be equipped with the conversion groove that the opening is right between polishing chamber and the printing chamber, the inner wall of conversion groove is close to right side position and has set firmly the internal tooth ring, the coating casing has set firmly on the lower end wall in printing chamber, be equipped with the coating chamber in the coating casing.

Preferably, a rotating shaft is connected above the motor in a power mode, the rotating shaft is in threaded connection with the lifting block, wheels are arranged in the wheel grooves, a rotating shaft extending left and right is rotatably connected between the moving cavity and the wheel grooves, one end of the rotating shaft is fixedly connected with the axle center of the wheel, the other end of the rotating shaft is fixedly provided with a movable bevel gear positioned in the movable cavity, a rotating shaft which extends downwards into the moving cavity is dynamically connected below the motor, a moving spline sleeve positioned in the moving cavity is connected on the rotating shaft through a spline, the movable spline sleeve is rotationally connected to the movable spline sleeve block, a power bevel gear positioned below the movable spline sleeve block is fixedly arranged on the movable spline sleeve, and a movable air pump is fixedly arranged on the upper end wall of the movable cavity, and the lower end surface of the movable air pump is fixedly connected to the upper end surface of the movable spline sleeve block.

Preferably, a left end wall of the positioning housing is rotatably connected with a hollow rotating shaft extending left and right, a left end of the hollow rotating shaft is fixedly connected with a right end face of the second rotating groove, a left helical gear located in the positioning cavity is fixedly arranged on the hollow rotating shaft, a rotating shaft extending left and right is arranged at the axis of the hollow rotating shaft, a right helical gear located in the positioning cavity is fixedly arranged on the rotating shaft, the left side of the rotating shaft penetrates through the left end face of the rotating housing and is rotatably connected with the rotating housing, a positioning bevel gear is fixedly arranged at the left end of the rotating shaft, a positioning motor is fixedly arranged in a rear end wall of the positioning cavity, a rotating shaft is dynamically connected with the front side of the positioning motor, a positioning spline sleeve is connected on the rotating shaft through a spline, the positioning spline sleeve is rotatably connected on a positioning spline sleeve plate, and a first bevel gear located on the lower side of the positioning spline, the positioning device comprises a positioning cavity, a rotating shaft, a first positioning gear, a third bevel gear, a positioning air pump and a positioning spline sleeve plate, wherein the rotating shaft and the rotating shaft are connected between the front end wall and the rear end wall of the positioning cavity in a rotating mode, the rotating shaft and the rotating shaft are symmetrically arranged, the second bevel gear in threaded connection with the left bevel gear and the first positioning gear located on the rear side of the second bevel gear are fixedly arranged on the rotating shaft, the third bevel gear in threaded connection with the third bevel gear and the second positioning gear located on the rear side of the third bevel gear are fixedly arranged on the rotating shaft, the positioning air pump is fixedly arranged on the rear end wall of the positioning cavity, and the tail end of the front.

Preferably, a rotating shaft is rotatably connected between the front end face and the rear end face of the second rotating groove, a fourth bevel gear in meshed connection with the positioning bevel gear is fixedly connected to the rotating shaft, and the left end face of the rotating shell is fixedly connected to the rotating shaft.

Preferably, a working motor located on the right side of the conversion groove is fixedly arranged on the right end face of the first rotation groove, a conversion power shaft is dynamically connected to the left side of the working motor, a conversion spline sleeve is connected to the conversion power shaft through a spline, the conversion spline sleeve is rotatably connected to the conversion spline sleeve plate, a gear located on the left side of the conversion spline sleeve plate is fixedly arranged on the conversion spline sleeve, a fifth bevel gear is fixedly arranged at the tail end of the left side of the conversion power shaft, a conversion air pump located on the lower side of the working motor is fixedly arranged on the right end face of the first rotation groove, and the tail end of the left side of the conversion air pump is fixedly connected with the right end face of the conversion spline sleeve plate.

Preferably, a rotating shaft is rotatably connected to the right end wall of the polishing cavity, a sixth bevel gear is fixedly arranged on the rotating shaft, a rotating rod is fixedly connected to the left end of the rotating shaft, a rotating rod through hole communicated with the left and right end faces of the rotating rod is formed in the rotating rod, a rotating shaft and a belt rotating shaft positioned on the left side of the rotating shaft are rotatably connected between the polishing cavity and the conversion groove, a seventh bevel gear in meshing transmission with the fifth bevel gear is fixedly arranged at the lower end of the rotating shaft, a right belt pulley in the polishing cavity is fixedly arranged on the rotating shaft, an eighth bevel gear in meshing transmission with the sixth bevel gear is fixedly arranged at the top end of the rotating shaft, a left belt pulley in the polishing cavity is fixedly arranged at the top end of the belt rotating shaft, and the left belt pulley and the right belt pulley are in transmission connection through a belt, a sliding groove communicated with the polishing cavity and the conversion groove is fixedly arranged in the lower end wall of the polishing cavity, the sliding groove is positioned on the left side of the belt rotating shaft, the lower end wall of the polishing cavity is rotationally connected with a rotating shaft extending up and down, the bottom tail end of the rotating shaft is connected and matched with the bottom tail end of the belt rotating shaft through a crank connecting rod, the top tail end of the rotating shaft is fixedly connected with a swinging connecting rod extending leftwards, a swinging connecting rod hole communicated with the upper end surface and the lower end surface of the swinging connecting rod and positioned right above the sliding groove is fixedly arranged on the swinging connecting rod, a moving rod extending upwards and penetrating through the swinging connecting rod hole is arranged in the sliding groove, a moving shaft is fixedly connected with the top tail end of the moving rod, the moving shaft penetrates through the rotating rod through hole, and a moving shaft groove communicated with the polishing cavity and the outside is arranged in the left end wall of the left, the moving shaft penetrates through the moving shaft groove and is fixedly connected with a brush located on the left side of the polishing shell.

Preferably, be equipped with on the right-hand member of polishing casing and be located the left printing paint spraying port in printing chamber, the up end of coating casing has set firmly the paint spraying pump, just the paint inlet intercommunication of paint spraying pump the coating chamber, the paint outlet of paint spraying pump is connected the printing paint spraying port, the printing chamber with rotate between the switching groove and be connected with the axis of rotation that extends from top to bottom, the top end of axis of rotation has set firmly to be located the ninth bevel gear of switching inslot, the bottom end and the paint spraying pump cooperation of axis of rotation are connected.

The beneficial effects are that: this device can carry out accurate location to the incomplete position of aircraft surface, through polishing earlier in the same order of printing, carries out the reprint to the incomplete position of printing on aircraft surface, labour saving and time saving, and the burnishing device of this device can clear up the surface of unevenness moreover, has improved commonality and practicality greatly.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural view of an aircraft printing and spraying device according to the present invention;

FIG. 2 is an enlarged schematic view at A in FIG. 1;

FIG. 3 is an enlarged schematic view at B of FIG. 2;

FIG. 4 is an enlarged schematic view at C of FIG. 2;

FIG. 5 is a schematic view of D-D of FIG. 2;

FIG. 6 is a schematic diagram of the structure of E-E in FIG. 2.

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.

The invention will now be described in detail with reference to fig. 1-6, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to an airplane printing and spraying device, which comprises a movable shell 10, wherein the movable shell 10 comprises a movable device 901, the movable device 901 comprises a rotating cavity 12, a motor 26 is fixedly arranged between the left end wall and the right end wall of the rotating cavity 12, a wheel carrier 11 is fixedly arranged below the movable shell 10, a moving cavity 24 positioned below the rotating cavity 12 is arranged in the wheel carrier 11, two wheel grooves 22 symmetrical about the moving cavity 24 are arranged on the lower end surface of the wheel carrier 11, lifting grooves 15 communicated with the left end wall and the right end wall of the movable shell 10 are arranged in the left end wall and the right end wall of the rotating cavity 12, a positioning device 902 is arranged on the left side of the movable shell 10, the positioning device 902 comprises a positioning shell 40, a lifting block 13 extending to the left side of the left end surface of the movable shell 10 is arranged in the lifting groove 15, the left end of the lifting block 13 is fixedly connected with the right end surface of the positioning, the polishing device is characterized in that a positioning cavity 39 is arranged in the positioning shell 40, a rotating shell 49 with an opening facing left is arranged on the left side of the positioning shell 40, a first rotating groove 38 is arranged in the left end face of the rotating shell 49, a polishing shell 48 is rotatably connected between the upper end wall and the lower end wall of the first rotating groove 38, a polishing device 903 and a printing and spraying device 904 located below the polishing device 903 are arranged in the polishing shell 48, the polishing device 903 comprises a polishing cavity 85, the printing and spraying device 904 comprises a printing cavity 31, a conversion groove 29 with a right opening is arranged between the polishing cavity 85 and the printing cavity 31, an inner toothed ring 72 is fixedly arranged on the inner wall of the conversion groove 29 close to the right side, a coating shell 32 is fixedly arranged on the lower end wall of the printing cavity 31, and a coating cavity 33 is arranged in the coating shell 32.

Advantageously, a rotating shaft 14 is dynamically connected above the motor 26, the rotating shaft 14 is in threaded connection with the lifting block 13, a wheel 21 is arranged in the wheel groove 22, a rotating shaft 20 extending left and right is rotatably connected between the moving cavity 24 and the wheel groove 22, one end of the rotating shaft 20 is fixedly connected to the axle center of the wheel 21, a moving bevel gear 19 located in the moving cavity 24 is fixedly arranged at the other end of the rotating shaft 20, a rotating shaft 25 extending downward into the moving cavity 24 is dynamically connected below the motor 26, a moving spline housing 16 located in the moving cavity 24 is splined on the rotating shaft 25, the moving spline housing 16 is rotatably connected to the moving spline housing block 18, a power bevel gear 23 located below the moving spline housing block 18 is fixedly arranged on the moving spline housing 16, and a moving air pump 17 is fixedly arranged on the upper end wall of the moving cavity 24, the lower end surface of the movable air pump 17 is fixedly connected to the upper end surface of the movable spline sleeve block 18.

Beneficially, a hollow rotating shaft 43 extending left and right is rotatably connected to the left end wall of the positioning housing 40, the left end of the hollow rotating shaft 43 is fixedly connected to the right end face of the second rotating groove 50, a left helical gear 42 located in the positioning cavity 39 is fixedly arranged on the hollow rotating shaft 43, a rotating shaft 34 extending left and right is arranged at the axis of the hollow rotating shaft 43, a right helical gear 41 located in the positioning cavity 39 is fixedly arranged on the rotating shaft 34, the left side of the rotating shaft 34 penetrates through the left end face of the rotating housing 49 and is rotatably connected to the rotating housing 49, a positioning bevel gear 55 is fixedly arranged at the left end of the rotating shaft 34, a positioning motor 80 is fixedly arranged in the rear end wall of the positioning cavity 39, a rotating shaft 36 is dynamically connected to the front side of the positioning motor 80, and a positioning spline housing 82 is connected to the rotating shaft 36, the positioning spline housing 82 is rotatably connected to the positioning spline housing plate 81, a first bevel gear 57 positioned at the lower side of the positioning spline housing plate 81 is fixedly arranged on the positioning spline housing 82, a rotating shaft 35 and a rotating shaft 37 are rotatably connected between the front end wall and the rear end wall of the positioning cavity 39, the rotating shaft 35 and the rotating shaft 37 are symmetrically arranged about the rotating shaft 36, a second bevel gear 56 screwed with the left bevel gear 42 and a first positioning gear 83 located behind the second bevel gear 56 are fixedly arranged on the rotating shaft 35, a third bevel gear 58 in threaded connection with the third bevel gear 58 and a second positioning gear 84 located at the rear side of the third bevel gear 58 are fixedly arranged on the rotating shaft 37, a positioning air pump 86 is fixedly arranged on the rear end wall of the positioning cavity 39, and the tail end of the front side of the positioning air pump 86 is fixedly connected to the rear end face of the positioning spline sleeve plate 81.

Advantageously, a rotating shaft 45 is arranged in the rotating connection between the front end surface and the rear end surface of the second rotating groove 50, a fourth bevel gear 44 in meshing connection with the positioning bevel gear 55 is fixedly connected to the rotating shaft 45, and the left end surface of the rotating shell 49 is fixedly connected to the rotating shaft 45.

Beneficially, a working motor 70 located on the right side of the conversion groove 29 is fixedly arranged on the right end surface of the first rotation groove 38, a conversion power shaft 71 is dynamically connected to the left side of the working motor 70, a conversion spline housing 73 is spline-connected to the conversion power shaft 71, the conversion spline housing 73 is rotatably connected to a conversion spline housing plate 75, a gear 74 located on the left side of the conversion spline housing plate 75 is fixedly arranged on the conversion spline housing 73, a fifth bevel gear 65 is fixedly arranged at the left end of the conversion power shaft 71, a conversion air pump 69 located on the lower side of the working motor 70 is fixedly arranged on the right end surface of the first rotation groove 38, and the left end of the conversion air pump 69 is fixedly connected to the right end surface of the conversion spline housing plate 75.

Beneficially, a rotating shaft 53 is rotatably connected to the right end wall of the polishing cavity 85, a sixth bevel gear 52 is fixedly connected to the rotating shaft 53, a rotating rod 47 is fixedly connected to the left end of the rotating shaft 53, a rotating rod through hole 51 communicating the left and right end faces of the rotating rod 47 is formed in the rotating rod 47, a rotating shaft 60 and a belt rotating shaft 79 positioned on the left side of the rotating shaft 60 are rotatably connected between the polishing cavity 85 and the converting groove 29, a seventh bevel gear 64 engaged with the fifth bevel gear 65 is fixedly arranged at the lower end of the rotating shaft 60, a right belt pulley 61 positioned in the polishing cavity 85 is fixedly arranged on the rotating shaft 60, an eighth bevel gear 59 engaged with the sixth bevel gear 52 and positioned in the polishing cavity 85 is fixedly arranged at the top end of the rotating shaft 60, a left belt pulley 78 positioned in the polishing cavity 85 is fixedly arranged at the top end of the belt rotating shaft 79, the left belt pulley 78 and the right belt pulley 61 are connected and driven through a belt 62, a sliding groove 68 communicating the polishing cavity 85 and the conversion groove 29 is fixedly arranged in the lower end wall of the polishing cavity 85, the sliding groove 68 is positioned on the left side of the belt rotating shaft 79, a rotating shaft 63 extending up and down is rotatably connected to the lower end wall of the polishing cavity 85, the bottom end of the rotating shaft 63 is connected and matched with the bottom end of the belt rotating shaft 79 through a crank connecting rod, the top end of the rotating shaft 63 is fixedly connected with a swinging connecting rod 76 extending leftwards, a swinging connecting rod hole 77 communicating the upper end face and the lower end face of the swinging connecting rod 76 and positioned right above the sliding groove 68 is fixedly arranged on the swinging connecting rod 76, a moving rod 46 extending upwards and penetrating through the swinging connecting rod hole 77 is arranged in the sliding groove 68, and a moving shaft 28 is fixedly connected to the top end of the moving rod 46, the right end of the moving shaft 28 penetrates through the rotating rod through hole 51, a moving shaft groove 87 for communicating the polishing cavity 85 with the outside is arranged in the left end wall of the left belt pulley 78, and the moving shaft 28 penetrates through the moving shaft groove 87 and is fixedly connected with a brush 27 positioned on the left side of the polishing shell 48.

Advantageously, a printing paint spraying opening 30 located on the left side of the printing cavity 31 is fixedly arranged on the right end of the polishing shell 48, a paint spraying pump 54 is fixedly arranged on the upper end face of the paint shell 32, a paint inlet of the paint spraying pump 54 is communicated with the paint cavity 33, a paint outlet of the paint spraying pump 54 is connected with the printing paint spraying opening 30, a rotating shaft 67 extending up and down is rotatably connected between the printing cavity 31 and the conversion groove 29, a ninth bevel gear 66 located in the conversion groove 29 is fixedly arranged at the top end of the rotating shaft 67, and the bottom end of the rotating shaft 67 is in fit connection with the paint spraying pump 54.

In the initial state, the power bevel gear 23 and the movable bevel gear 19 are disengaged, and the motor 26 is not started;

when the vehicle starts to work, the motor 26 rotates to drive the rotating shaft 25 to rotate, the rotating shaft 25 drives the movable spline housing 16 and the power bevel gear 23 to rotate, the movable air pump 17 is started at the moment, the movable spline housing block 18 is pushed downwards, the power bevel gear 23 is meshed with the movable bevel gear 19, the rotating shaft 20 drives the wheels 21 on two sides to rotate, and the forward and backward rotation of the wheel carrier 11 is controlled by controlling the forward and backward rotation of the motor 26 and the extension and retraction of the ejector rod in the movable air pump 17.

The motor 26 rotates to drive the rotating shaft 14 to rotate, and further drives the lifting block 13 to move up and down, so that the brush 27 reaches an approximate position, the motor 26 is stopped, the positioning motor 80 is started to drive the sixth bevel gear 52 and the first bevel gear 57 to rotate, when the positioning air pump 86 control rod extends forwards, the first bevel gear 57 drives the first positioning gear 83, the rotating shaft 35 and the second bevel gear 56 to rotate, the second bevel gear 56 drives the second rotating groove 50 to rotate through the left bevel gear 42 and the hollow rotating shaft 43, and when the positioning air pump 86 control rod retreats backwards, the first bevel gear 57 drives the second positioning gear 84, the rotating shaft 37 and the third bevel gear 58 to rotate, and further drives the right bevel gear 41, the rotating shaft 34, the positioning bevel gear 55, the fourth bevel gear 44, the rotating shaft 45 and the rotating housing 49 to rotate, so that the brush 27 is positioned on a surface to be worked.

At this time, the working motor 70 is started, the conversion power shaft 71 drives the fifth bevel gear 65, the conversion spline housing 73 and the gear 74 to rotate, and further drives the brush 27 to rotate in the moving shaft groove 87 through the seventh bevel gear 64, the rotating shaft 60, the eighth bevel gear 59, the rotating shaft 53 and the rotating rod 47, and further drives the brush 27 to rotate in the moving shaft groove 87 through the moving shaft 28, meanwhile, the right belt pulley 61 drives the left belt pulley 78 and the belt rotating shaft 79 to rotate through the belt 62, the belt rotating shaft 79 drives the rotating shaft 63 to rotate in a reciprocating manner, and the rotating shaft 63 drives the brush 27 to move left and right through the swinging connecting rod 76, the moving rod 46 and.

When paint spraying and printing are needed, the conversion air pump 69 is started, the power rod stretches, the gear 74 is meshed with the inner gear ring 72, the polishing shell 48 rotates at the moment, the printing and spraying device 904 is driven to move to a position to be painted, the fifth bevel gear 65 is disengaged from the seventh bevel gear 64, the fifth bevel gear 65 is meshed with the ninth bevel gear 66, the paint spraying pump 54 is driven to rotate, and then the paint in the paint cavity 33 is sprayed out through the printing and spraying opening 30 by the paint spraying pump 54, so that the surface is printed and sprayed.

The above description is only an embodiment of the invention, but the scope of the invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the invention. Therefore, the protection scope of the invention should be subject to the protection scope defined by the claims.

Claims

1. The utility model provides an aircraft printing spraying device, includes the removal casing, its characterized in that: the movable shell is internally provided with a moving device, the moving device comprises a rotating cavity, a motor is fixedly arranged between the left end wall and the right end wall of the rotating cavity, a wheel carrier is fixedly arranged below the movable shell, a moving cavity positioned below the rotating cavity is arranged in the wheel carrier, the lower end surface of the wheel carrier is provided with two wheel grooves which are symmetrical relative to the moving cavity, the left end wall and the right end wall of the rotating cavity are internally provided with lifting grooves communicated with the left end wall and the right end wall of the movable shell, the left side of the movable shell is provided with a positioning device, the positioning device comprises a positioning shell, a lifting block which extends leftwards to the left side of the left end surface of the movable shell is arranged in the lifting groove, the left end of the lifting block is fixedly connected with the right end surface of the positioning shell, the positioning cavity is arranged in the positioning shell, the polishing device comprises a polishing cavity, the printing and spraying device comprises a printing cavity, a conversion groove with a rightward opening is formed between the polishing cavity and the printing cavity, an inner tooth ring is fixedly arranged at a position, close to the right side, of the inner wall of the conversion groove, a coating shell is fixedly arranged on the lower end wall of the printing cavity, and a coating cavity is formed in the coating shell.

2. An aircraft printing spray coating device according to claim 1, wherein: a rotating shaft is connected above the motor in a power mode and is in threaded connection with the lifting block, wheels are arranged in the wheel grooves, a rotating shaft extending left and right is rotatably connected between the moving cavity and the wheel grooves, one end of the rotating shaft is fixedly connected with the axle center of the wheel, the other end of the rotating shaft is fixedly provided with a movable bevel gear positioned in the movable cavity, a rotating shaft which extends downwards into the moving cavity is dynamically connected below the motor, a moving spline sleeve positioned in the moving cavity is connected on the rotating shaft through a spline, the movable spline sleeve is rotationally connected to the movable spline sleeve block, a power bevel gear positioned below the movable spline sleeve block is fixedly arranged on the movable spline sleeve, and a movable air pump is fixedly arranged on the upper end wall of the movable cavity, and the lower end surface of the movable air pump is fixedly connected to the upper end surface of the movable spline sleeve block.

3. An aircraft printing spray coating device according to claim 1, wherein: a left end wall of the positioning shell is connected with a left and right extending hollow rotating shaft in a rotating manner, the left end of the hollow rotating shaft is fixedly connected with the right end face of the second rotating groove, a left helical gear positioned in the positioning cavity is fixedly arranged on the hollow rotating shaft, a rotating shaft extending left and right is arranged at the axis of the hollow rotating shaft, a right helical gear positioned in the positioning cavity is fixedly arranged on the rotating shaft, the left side of the rotating shaft penetrates through the left end face of the rotating shell and is rotatably connected with the rotating shell, a positioning bevel gear is fixedly arranged at the left end of the rotating shaft, a positioning motor is fixedly arranged in the rear end wall of the positioning cavity, the front side of the positioning motor is in power connection with the rotating shaft, a positioning spline sleeve is in spline connection with the rotating shaft, the positioning spline sleeve is rotatably connected to a positioning spline sleeve plate, and a first bevel gear positioned on the lower side, the positioning device comprises a positioning cavity, a rotating shaft, a first positioning gear, a third bevel gear, a positioning air pump and a positioning spline sleeve plate, wherein the rotating shaft and the rotating shaft are connected between the front end wall and the rear end wall of the positioning cavity in a rotating mode, the rotating shaft and the rotating shaft are symmetrically arranged, the second bevel gear in threaded connection with the left bevel gear and the first positioning gear located on the rear side of the second bevel gear are fixedly arranged on the rotating shaft, the third bevel gear in threaded connection with the third bevel gear and the second positioning gear located on the rear side of the third bevel gear are fixedly arranged on the rotating shaft, the positioning air pump is fixedly arranged on the rear end wall of the positioning cavity, and the tail end of the front.

4. An aircraft printing spray coating device according to claim 1, wherein: a rotating shaft is rotatably connected between the front end face and the rear end face of the second rotating groove, a fourth bevel gear in meshed connection with the positioning bevel gear is fixedly connected to the rotating shaft, and the left end face of the rotating shell is fixedly connected to the rotating shaft.

5. An aircraft printing spray coating device according to claim 1, wherein: the right end face of the first rotating groove is fixedly provided with a working motor located on the right side of the conversion groove, the left side of the working motor is in power connection with a conversion power shaft, the conversion power shaft is in splined connection with a conversion spline sleeve, the conversion spline sleeve is rotationally connected onto a conversion spline sleeve plate, a gear located on the left side of the conversion spline sleeve plate is fixedly arranged on the conversion spline sleeve, the left end of the conversion power shaft is fixedly provided with a fifth bevel gear, the right end face of the first rotating groove is fixedly provided with a conversion air pump located on the lower side of the working motor, and the left end of the conversion air pump is fixedly connected with the right end face of the conversion spline sleeve plate.

6. An aircraft printing spray coating device according to claim 1, wherein: a rotating shaft is rotatably connected to the right end wall of the polishing cavity, a sixth bevel gear is fixedly arranged on the rotating shaft, a rotating rod is fixedly connected to the left end of the rotating shaft, a rotating rod through hole communicated with the left and right end faces of the rotating rod is formed in the rotating rod, a rotating shaft and a belt rotating shaft positioned on the left side of the rotating shaft are rotatably connected between the polishing cavity and the conversion groove, a seventh bevel gear in meshing transmission with the fifth bevel gear is fixedly arranged at the tail end of the lower side of the rotating shaft, a right belt pulley in the polishing cavity is fixedly arranged on the rotating shaft, an eighth bevel gear in meshing transmission with the sixth bevel gear is fixedly arranged at the tail end of the top of the rotating shaft, a left belt pulley in the polishing cavity is fixedly arranged at the tail end of the top of the belt rotating shaft, and the left belt pulley and, a sliding groove communicated with the polishing cavity and the conversion groove is fixedly arranged in the lower end wall of the polishing cavity, the sliding groove is positioned on the left side of the belt rotating shaft, the lower end wall of the polishing cavity is rotationally connected with a rotating shaft extending up and down, the bottom tail end of the rotating shaft is connected and matched with the bottom tail end of the belt rotating shaft through a crank connecting rod, the top tail end of the rotating shaft is fixedly connected with a swinging connecting rod extending leftwards, a swinging connecting rod hole communicated with the upper end surface and the lower end surface of the swinging connecting rod and positioned right above the sliding groove is fixedly arranged on the swinging connecting rod, a moving rod extending upwards and penetrating through the swinging connecting rod hole is arranged in the sliding groove, a moving shaft is fixedly connected with the top tail end of the moving rod, the moving shaft penetrates through the rotating rod through hole, and a moving shaft groove communicated with the polishing cavity and the outside is arranged in the left end wall of the left, the moving shaft penetrates through the moving shaft groove and is fixedly connected with a brush located on the left side of the polishing shell.

7. An aircraft printing spray coating device according to claim 1, wherein: the polishing device is characterized in that a printing paint spraying port located on the left side of the printing cavity is fixedly arranged on the right end of the polishing shell, a paint spraying pump is fixedly arranged on the upper end face of the coating shell, a paint inlet of the paint spraying pump is communicated with the coating cavity, a paint outlet of the paint spraying pump is connected with the printing paint spraying port, the printing cavity and the conversion groove are rotatably connected with a rotating shaft extending from top to bottom, a ninth bevel gear located in the conversion groove is fixedly arranged at the tail end of the top of the rotating shaft, and the tail end of the bottom of the rotating shaft is connected with the paint spraying pump in a matched mode.