CN219772239U - Batch coating machine for car mirror production - Google Patents

Abstract

The utility model discloses a batch coating machine for car mirror production, which comprises a machine shell, wherein a coating cavity is formed in the machine shell, the bottom surface of the coating cavity is fixedly connected with a material conveying part, the material conveying part comprises a bottom plate fixedly connected to the bottom surface of the coating cavity, the top surface of the bottom plate is provided with a top opening, the upper part of the top opening is horizontally and slidingly connected with a sliding plate, the top surface of the sliding plate is fixedly connected with a connecting plate, the top surface of the connecting plate is provided with a batch placement assembly, the batch placement assembly comprises a placement plate placed on the top surface of the connecting plate, and two air homogenizing plates are fixedly embedded in the placement plate. The batch placing assembly is provided with the plurality of placing cavities, a plurality of car mirrors can be placed in batches for batch coating, the efficiency is higher, when the car mirrors are fixed, the suction pump is utilized to generate negative pressure at the suction disc through the hose, the square tube and the air homogenizing plate, and the car mirrors are adsorbed and fixed, so that the car mirrors can be placed in the placing cavities when being fed without clamping structures, and the feeding is faster.

Description

Batch coating machine for car mirror production

Technical Field

The utility model relates to the technical field of car mirror production equipment, in particular to a batch coating machine for car mirror production.

Background

The car mirror is the mirror of car driver's cabin front end and the outer installation of door window, and its mirror surface, appearance and manipulation are all quite profound, and the quality and the installation of rear-view mirror all have corresponding industry standard, can not be random, in order to guarantee each performance of car mirror, need carry out the coating film to car rear-view mirror in car rear-view mirror production process, and present car mirror coating film machine has following defect:

at present, a clamping structure is mainly adopted to fix the car mirror during feeding of the car mirror film plating machine, and only single feeding can be performed at each time, so that the efficiency is low, and during feeding, the clamping structure is troublesome in clamping, and the fixing speed of the car mirror is influenced.

Therefore, we propose a batch coater for car mirror production to solve the above problems.

Disclosure of Invention

The utility model aims to provide a batch coating machine for car mirror production, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the batch coating machine for the production of the car mirror comprises a machine shell, wherein a coating cavity is formed in the machine shell, the bottom surface of the coating cavity is fixedly connected with a material conveying component, the material conveying component comprises a bottom plate fixedly connected to the bottom surface of the coating cavity, the top surface of the bottom plate is provided with a top opening, the upper part of the top opening is horizontally and slidingly connected with a sliding plate, the top surface of the sliding plate is fixedly connected with a connecting plate, and the top surface of the connecting plate is provided with a batch placement component;

the batch placement assembly comprises placement plates placed on the top surfaces of the connecting plates, two air distribution plates are fixedly embedded in the placement plates, a plurality of division bars are uniformly fixedly connected to the top surfaces of the placement plates, the division bars are mutually perpendicular to the air distribution plates, a plurality of placement cavities are formed in the positions, located among the division bars, of the top surfaces of the placement plates, and the positions, located among the placement cavities, of the top surfaces of the air distribution plates are communicated with a plurality of suckers;

two upper through grooves are formed on the top surface of the connecting plate corresponding to the same vertical position of the two air homogenizing plates, two lower through grooves are formed on the sliding plate corresponding to the same vertical position of the two upper through grooves, two square pipes are respectively and horizontally connected in a sliding manner in the two upper through grooves and the two lower through grooves, the top ends of the square tubes are fixedly connected and communicated with the bottom surface of the end part of the air homogenizing plate, two square tubes are communicated and connected between the bottom ends of the square tubes, the center of the bottom surface of the top opening is fixedly connected with an air suction pump, the air suction pump is communicated with one end of a hose, and the other end of the hose is communicated and connected.

Preferably, a top sliding groove is horizontally formed in the center position of the top surface of the connecting plate, a top sliding block is horizontally and movably connected in the top sliding groove, the top sliding block is fixedly connected to the end part of the bottom surface of the placing plate, a second screw rod is rotatably connected in the top sliding groove, a second threaded sleeve is fixedly connected in the top sliding block, the second screw rod is in threaded connection with the second threaded sleeve, one end of the placing plate is fixedly connected with a first small-sized gear motor, and the rotating shaft end of the first small-sized gear motor is fixedly connected with the end part of the second screw rod.

Preferably, two side sliding grooves are formed in two sides of the top opening, two side sliding blocks are horizontally and slidably connected in the side sliding grooves, the two side sliding blocks are fixedly connected to two sides of the sliding plate respectively, two first screw rods are rotatably connected in the side sliding grooves respectively, two first threaded sleeves are fixedly connected in the side sliding blocks respectively, and the first screw rods are in threaded connection with the first threaded sleeves.

Preferably, a transmission cavity is formed in one end inside the bottom plate, a double-shaft motor and two speed reducers are fixedly connected to the center of the transmission cavity, two speed reducers are fixedly connected to two rotating shafts of the double-shaft motor, two speed reducer output shafts are fixedly connected with two rotating rods respectively, two free ends of the rotating rods are fixedly connected with two driving bevel gears respectively, two first screw rod ends are located in the transmission cavity and are fixedly connected with two driven bevel gears respectively, and the driving bevel gears are connected with the driven bevel gears in a meshed mode.

Preferably, the top surface of the coating cavity is fixedly connected with a first telescopic main board and a second telescopic main board, a first bottom groove is formed in the bottom surface of the first telescopic main board, a first telescopic slave board is vertically and slidably connected in the first bottom groove, a plurality of coating heads are fixedly connected with the bottom surface of the first telescopic slave board, coating equipment is fixedly connected with the top surface of the coating cavity, the coating equipment is communicated with the plurality of coating heads through connecting pipes, and a first electric cylinder is fixedly connected between the top surface of the first bottom groove and the first telescopic slave board.

Preferably, the second bottom groove is formed in the bottom surface of the second telescopic main board, the second telescopic auxiliary board is vertically and slidably connected in the second bottom groove, a U-shaped frame is fixedly connected to the bottom surface of the second telescopic auxiliary board, two rotating rollers are respectively and rotatably connected to the two ends of the inner side of the U-shaped frame, a belt is sleeved on the outer sides of the rotating rollers, clean soft is bonded on the outer sides of the belt, a second small-sized gear motor is fixedly connected to one end of the U-shaped frame, one rotating shaft end of the second small-sized gear motor is fixedly connected to one rotating shaft end of the second small-sized gear motor, and a second electric cylinder is fixedly connected between the top surface of the second bottom groove and the second telescopic auxiliary board.

Preferably, a transparent window is fixedly connected to one side of the shell, a feeding and discharging hole is formed in the side wall of the shell, and the feeding and discharging hole is rotationally connected with the sealing door.

Compared with the prior art, the utility model has the beneficial effects that:

the batch placing assembly is provided with the plurality of placing cavities, a plurality of car mirrors can be placed in batches for batch coating, the efficiency is higher, when the car mirrors are fixed, the suction pump is utilized to generate negative pressure at the suction disc through the hose, the square tube and the air homogenizing plate, and the car mirrors are adsorbed and fixed, so that the car mirrors can be placed in the placing cavities when being fed without clamping structures, and the feeding is faster.

Drawings

FIG. 1 is a schematic diagram of a main structure of a first embodiment of the present utility model;

FIG. 2 is a schematic view showing a cut-away structure of a main body in the first and second embodiments of the present utility model;

FIG. 3 is a schematic view of an exploded structure of a material conveying member according to a first and second embodiment of the present utility model;

FIG. 4 is a schematic side sectional view of a material conveying member according to a second embodiment of the present utility model;

FIG. 5 is a schematic view showing a cross-sectional structure of a connecting plate according to a second embodiment of the present utility model;

fig. 6 is a schematic view showing a cross-sectional structure of a base plate according to a second embodiment of the present utility model.

In the figure: 1. a housing; 2. a material conveying component; 3. a first telescopic main board; 4. the second telescopic main board; 11. a film coating cavity; 12. a transparent window; 13. a material inlet and a material outlet; 14. sealing the door; 21. a bottom plate; 22. a connecting plate; 23. placing the components in batches; 211. a top opening; 212. a slip plate; 213. a lower through groove; 214. a getter pump; 215. square tubes; 216. a hose; 217. and take over; 218. a side chute; 219. a side slider; 2110. a transmission cavity; 2111. a biaxial motor; 2112. a speed reducer; 2113. a rotating rod; 2114. a drive bevel gear; 2115. a driven bevel gear; 2116. a first screw rod; 2117. a first threaded sleeve; 221. an upper through groove; 222. a top chute; 223. a top slider; 224. a second screw rod; 225. a second threaded sleeve; 226. a first small-sized gear motor; 231. placing a plate; 232. a wind homogenizing plate; 233. a parting bead; 234. a placement cavity; 235. a suction cup; 31. a first bottom groove; 32. a first telescoping slave plate; 33. a coating head; 34. coating equipment; 35. a connecting pipe; 36. a first electric cylinder; 41. a second bottom groove; 42. a second telescoping slave plate; 43. a U-shaped frame; 44. a rotating roller; 45. a belt; 46. cleaning soft cotton; 47. a second small-sized gear motor; 48. and a second electric cylinder.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1:

referring to fig. 1-3, the present utility model provides a technical solution: the batch coating machine for the production of the car mirror comprises a machine shell 1, wherein a coating cavity 11 is formed in the machine shell 1, the bottom surface of the coating cavity 11 is fixedly connected with a material conveying component 2, the material conveying component 2 comprises a bottom plate 21 fixedly connected to the bottom surface of the coating cavity 11, the top surface of the bottom plate 21 is provided with a top opening 211, the upper part of the top opening 211 is horizontally and slidingly connected with a sliding plate 212, the top surface of the sliding plate 212 is fixedly connected with a connecting plate 22, and the top surface of the connecting plate 22 is provided with a batch placement component 23;

the batch placement assembly 23 comprises a placement plate 231 placed on the top surface of the connecting plate 22, two air homogenizing plates 232 are fixedly embedded in the placement plate 231, a plurality of parting strips 233 are uniformly fixedly connected to the top surface of the placement plate 231, the parting strips 233 are mutually perpendicular to the air homogenizing plates 232, a plurality of placement cavities 234 are formed in the position, between the plurality of parting strips 233, of the top surface of the placement plate 231, a plurality of suckers 235 are communicated with the positions, in the plurality of placement cavities 234, of the air homogenizing plates 232 are used for placing car mirrors, and a plurality of car mirrors can be placed at the same time, so that the effect of batch coating is achieved;

two upper through grooves 221 are formed in the top surface of the connecting plate 22 corresponding to the same vertical position of the two air homogenizing plates 232, two lower through grooves 213 are formed in the sliding plate 212 corresponding to the same vertical position of the two upper through grooves 221, two square tubes 215 are respectively and horizontally connected in a sliding mode, the top ends of the square tubes 215 are fixedly connected and communicated with the bottom surfaces of the end portions of the air homogenizing plates 232, the bottom ends of the two square tubes 215 are communicated and connected with a connecting tube 217, an air suction pump 214 is fixedly connected to the center of the bottom surface of the top opening 211, the air suction pump 214 is communicated with one end of a hose 216, the other end of the hose 216 is communicated and connected with the connecting tube 217, negative pressure is generated at a sucker 235 by the aid of the air suction pump 214 through the hose 216, the square tubes 215 and the air homogenizing plates 232, and the vehicle mirror is adsorbed and fixed, therefore, when the vehicle mirror is fed, the vehicle mirror is only required to be placed in the placing cavity 234, clamping structures are not needed, and feeding is faster.

Example 2:

referring to fig. 2-6, in a second embodiment of the present utility model, based on the previous embodiment, a top sliding groove 222 is horizontally formed in a central position of a top surface of the connecting plate 22, a top sliding block 223 is horizontally and rotatably connected in the top sliding groove 222, the top sliding block 223 is fixedly connected to an end of a bottom surface of the placing plate 231, the top sliding groove 222 is rotatably connected to a second screw rod 224, a second threaded sleeve 225 is fixedly connected in the top sliding block 223, the second screw rod 224 is in threaded connection with the second threaded sleeve 225, one end of the placing plate 231 is fixedly connected to a first small-sized reducing motor 226, a rotating shaft end of the first small-sized reducing motor 226 is fixedly connected to an end of the second screw rod 224, and the first small-sized reducing motor 226 drives the second screw rod 224 to rotate so as to push the batch placement assembly 23 to move, so as to push the batch placement assembly from the feeding port 13, and the feeding and the discharging.

Two side sliding grooves 218 are formed in two sides of the top opening 211, two side sliding blocks 219 are horizontally and movably connected in the two side sliding grooves 218, the two side sliding blocks 219 are fixedly connected to two sides of the sliding plate 212 respectively, two first screw rods 2116 are rotatably connected to the two side sliding grooves 218 respectively, two first threaded sleeves 2117 are fixedly connected to the two side sliding blocks 219 respectively, and the first screw rods 2116 are in threaded connection with the first threaded sleeves 2117.

The transmission cavity 2110 is formed in one end inside the bottom plate 21, the center position of the transmission cavity 2110 is fixedly connected with a double-shaft motor 2111 and two speed reducers 2112, the input shafts of the two speed reducers 2112 are fixedly connected with two rotating shafts of the double-shaft motor 2111, the output shafts of the two speed reducers 2112 are fixedly connected with two rotating rods 2113 respectively, the free ends of the two rotating rods 2113 are fixedly connected with two driving bevel gears 2114 respectively, the end parts of two first screw rods 2116 are located in the transmission cavity 2110 and are fixedly connected with two driven bevel gears 2115 respectively, the driving bevel gears 2114 are meshed and connected with the driven bevel gears 2115, the first screw rods 2116 are driven to rotate through the double-shaft motor 2111, the whole batch placement assembly 23 is moved, and coating work is carried out.

The top surface rigid coupling of coating film chamber 11 first flexible mainboard 3 and second flexible mainboard 4, first flexible draw-in groove 31 is seted up to first flexible mainboard 3 bottom surface, perpendicular sliding connection is first flexible from board 32 in the first draw-in groove 31, a plurality of coating film heads 33 of first flexible from board 32 bottom surface rigid coupling, coating film chamber 11 top surface rigid coupling coating film equipment 34, coating film equipment 34 communicates a plurality of coating film heads 33 through connecting pipe 35, rigid coupling first electric jar 36 between first draw-in groove 31 top surface and the flexible from board 32, first electric jar 36 starts and drives first flexible from board 32 and move down, utilize coating film head 33 to carry out the coating film work to the car mirror.

The bottom surface of the second telescopic main board 4 is provided with a second bottom groove 41, a second telescopic slave board 42 is vertically and slidingly connected in the second bottom groove 41, a U-shaped frame 43 is fixedly connected to the bottom surface of the second telescopic slave board 42, two rotating rollers 44 are respectively and rotatably connected to the two ends of the inner side of the U-shaped frame 43, a belt 45 is sleeved on the outer side of each rotating roller 44, cleaning soft cotton 46 is adhered to the outer side of each belt 45, one end of the U-shaped frame 43 is fixedly connected with a second small speed reducing motor 47, the rotating shaft end of one rotating roller 44 is fixedly connected with the rotating shaft end of each second small speed reducing motor 47, a second electric cylinder 48 is fixedly connected between the top surface of the second bottom groove 41 and the second telescopic slave board 42, after film plating is completed, a vehicle mirror moves to the position right below the second telescopic slave board 42, and the cleaning soft cotton 46 contacts and cleans the vehicle mirror under the action of the second electric cylinder 48.

One side of the shell 1 is fixedly connected with a transparent window 12, so that the observation is convenient, the side wall of the shell 1 is provided with a feeding and discharging hole 13, and the feeding and discharging hole 13 is rotationally connected with a sealing door 14.

Example 3:

referring to fig. 1-6, in a third embodiment of the present utility model, the sealing door 14 is opened based on the two embodiments, at this time, the first small-sized speed reducing motor 226 is started to drive the batch-placing assembly 23 to translate, the batch-placing assembly 23 is moved out from the material inlet and outlet 13, at this time, a plurality of mirrors are placed in the plurality of placing cavities 234 respectively, at this time, the suction pump 214 is started to generate negative pressure at the suction cup 235, the mirrors are fixed, the first small-sized speed reducing motor 226 is turned over to move the batch-placing assembly 23 into the position right above the connecting plate 22, the sealing door 14 is closed, at this time, the sliding plate 212 drives the batch-placing assembly 23 to move to the position right below the first telescopic main plate 3 to perform film coating operation, after that, the sliding plate 212 continues to drive the batch-placing assembly 23 to move to the position of the material inlet and outlet 13, and then the sealing door 14 is opened to perform material discharging.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a car mirror production is with batch coating machine, includes casing (1), its characterized in that:

a coating cavity (11) is formed in the casing (1), a material conveying component (2) is fixedly connected to the bottom surface of the coating cavity (11), the material conveying component (2) comprises a bottom plate (21) fixedly connected to the bottom surface of the coating cavity (11), a top opening (211) is formed in the top surface of the bottom plate (21), the upper part of the top opening (211) is horizontally and slidably connected with a sliding plate (212), a connecting plate (22) is fixedly connected to the top surface of the sliding plate (212), and a batch placement assembly (23) is arranged on the top surface of the connecting plate (22);

the batch placement assembly (23) comprises a placement plate (231) placed on the top surface of the connecting plate (22), two air homogenizing plates (232) are fixedly embedded in the placement plate (231), a plurality of parting strips (233) are uniformly fixedly connected to the top surface of the placement plate (231), the parting strips (233) are mutually perpendicular to the air homogenizing plates (232), a plurality of placement cavities (234) are formed in the position, between the parting strips (233), of the top surface of the placement plate (231), and the top surface of the air homogenizing plate (232) is positioned in the plurality of placement cavities (234) and is communicated with a plurality of suckers (235);

two upper through grooves (221) are formed in the top surface of the connecting plate (22) corresponding to the same vertical position of the two air homogenizing plates (232), two lower through grooves (213) are formed in the sliding plate (212) corresponding to the same vertical position of the two upper through grooves (221), two square pipes (215) are respectively and horizontally connected in a sliding mode in the upper through grooves (221) and the two lower through grooves (213), the top ends of the square pipes (215) are fixedly connected and communicated with the bottom surfaces of the end portions of the air homogenizing plates (232), two square pipes (215) are communicated with each other and are connected with connecting pipes (217), an air suction pump (214) is fixedly connected with the bottom surfaces of the top opening (211), one end of a hose (216) is communicated with the air suction pump (214), and the other end of the hose (216) is communicated with the connecting pipes (217).

2. The batch coater for vehicle mirror production according to claim 1, wherein: top spout (222) are offered to connecting plate (22) top surface central point put level, top slider (223) are connected in horizontal migration in top spout (222), top slider (223) rigid coupling is placing board (231) bottom surface tip, second lead screw (224) are connected in top spout (222) internal rotation, rigid coupling second screw thread sleeve (225) in top slider (223), second lead screw (224) threaded connection second screw thread sleeve (225), place board (231) internal end rigid coupling first small-size gear motor (226), first small-size gear motor (226) pivot end rigid coupling second lead screw (224) tip.

3. The batch coater for vehicle mirror production according to claim 1, wherein: two sideslip grooves (218) are formed in two sides of the top opening (211), two sideslip grooves (218) are connected with two sideslips (219) in a horizontal sliding mode, the two sideslips (219) are fixedly connected to two sides of a sliding plate (212) respectively, two first screw rods (2116) are connected to the two sideslips grooves (218) in a rotating mode respectively, two first threaded sleeves (2117) are fixedly connected to the two sideslips (219) respectively, and the first screw rods (2116) are connected with the first threaded sleeves (2117) in a threaded mode.

4. A bulk coater for vehicular mirror production according to claim 3, wherein: the novel double-shaft transmission device is characterized in that a transmission cavity (2110) is formed in one end inside the bottom plate (21), a double-shaft motor (2111) and two speed reducers (2112) are fixedly connected to the center of the transmission cavity (2110), two input shafts of the speed reducers (2112) are fixedly connected to two rotating shafts of the double-shaft motor (2111), two output shafts of the speed reducers (2112) are fixedly connected with two rotating rods (2113) respectively, two free ends of the rotating rods (2113) are fixedly connected with two driving bevel gears (2114) respectively, and two ends of a first screw rod (2116) are located in the transmission cavity (2110) and fixedly connected with two driven bevel gears (2115) respectively, and the driving bevel gears (2114) are meshed and connected with the driven bevel gears (2115).

5. The batch coater for vehicle mirror production according to claim 1, wherein: coating film chamber (11) top surface rigid coupling first flexible mainboard (3) and second flexible mainboard (4), first kerve (31) are seted up to first flexible mainboard (3) bottom surface, first flexible slave plate (32) of perpendicular sliding connection in first kerve (31), a plurality of coating film heads (33) of first flexible slave plate (32) bottom surface rigid coupling, coating film chamber (11) top surface rigid coupling coating film equipment (34), coating film equipment (34) communicate a plurality of coating film heads (33) through connecting pipe (35), rigid coupling first electric jar (36) between first kerve (31) top surface and the first flexible slave plate (32).

6. The batch coater for vehicle mirror production according to claim 5, wherein: the utility model discloses a flexible slave plate of motor vehicle, including flexible mainboard (4) of motor vehicle, flexible slave plate (42) of motor vehicle, flexible master plate (4) of motor vehicle, second kerve (41) are seted up to flexible mainboard (4) bottom surface of second, perpendicular sliding connection second flexible slave plate (42) in second kerve (41), flexible slave plate (42) bottom surface rigid coupling U type frame (43) of second, two roller (44) are connected in rotation respectively to the inboard both ends of U type frame (43), two roller (44) outside cup joint belt (45), clean soft (46) of belt (45) outside bonding, the small-size gear motor (47) of second of U type frame (43) one end rigid coupling, one of them roller (44) pivot end of second small-size gear motor (47) pivot end rigid coupling, rigid coupling second electric cylinder (48) between flexible slave plate (42) of second kerve (41) top surface.

7. The batch coater for vehicle mirror production according to claim 1, wherein: the transparent window (12) is fixedly connected to one side of the shell (1), the side wall of the shell (1) is provided with a feeding and discharging hole (13), and the feeding and discharging hole (13) is rotationally connected with the sealing door (14).