CN112517319B - Optical disk spin coating equipment for manufacturing optical disk - Google Patents

Abstract

The invention discloses optical disk spin-coating equipment for manufacturing optical disks, which relates to the technical field of optical disk manufacturing devices and comprises an operation bottom plate, a bearing plate and a cross beam, wherein the upper surface of the operation bottom plate is fixedly connected with a support, the upper surface of the support is fixedly connected with an operation box, the inner wall of the operation box is rotatably connected with a rotating column through a bearing, the upper surface of the rotating column is fixedly connected with an operation table, the upper surface of the operation table is fixedly connected with a limiting column, and an optical disk is placed on the upper surface of the operation table. According to the invention, through the mutual cooperation of the structures, the dye is diffused by the self-rotation of the optical disc when the optical disc is dripped, and the diffused dye is uniformly spin-coated, so that the spin-coating effect of the optical disc is ensured, the effect of preventing the dye from splashing around in the spin-coating process is achieved, and the problems that the traditional optical disc spin-coating equipment is inconvenient to use, the spin-coating is not uniform, and the spin-coating effect of the optical disc cannot be ensured are solved.

Description

Optical disk spin coating equipment for manufacturing optical disk

Technical Field

The invention relates to the technical field of optical disk manufacturing devices, in particular to optical disk spin-coating equipment for manufacturing optical disks.

Background

With the wide use of VCD and DVD machines, almost every family has some optical discs, and the high-definition vivid tone quality and clear images of the optical discs are favored by many people, in the production and manufacturing process of the optical discs, the surface of the optical discs needs to be spin-coated with dyes.

Disclosure of Invention

The invention aims to provide optical disc spin-coating equipment for manufacturing an optical disc, which has the effects of enabling a dye to be diffused by the aid of autorotation of the optical disc when the optical disc is dripped, uniformly spin-coating the diffused dye, ensuring the spin-coating effect of the optical disc, avoiding the dye from splashing around in the spin-coating process, and solving the problems that the traditional optical disc spin-coating equipment is inconvenient to use, the spin-coating is not uniform, and the spin-coating effect of the optical disc cannot be ensured.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a CD spin coating equipment for CD is made, includes operation bottom plate, bearing plate and crossbeam, the last fixed surface of operation bottom plate is connected with the support, the last fixed surface of support is connected with the operation box, the inner wall of operation box rotates through the bearing and is connected with the rotary column.

The last fixed surface of rotary column is connected with the operation panel, the last fixed surface of operation panel is connected with spacing post, the CD has been placed to the upper surface of operation panel, the spacing groove has been seted up on the surface of bearing plate, the inner wall sliding connection of spacing groove has the slide, the fixed surface of slide is connected with the connecting plate, the underrun bearing of connecting plate rotates and is connected with the pivot, the fixed surface of pivot is connected with the gear, the tooth meshing of gear has the rack plate, cell body one has been seted up in the front of slide, the inner wall of cell body one is followed to the surface of rack plate slides, the bottom surface fixedly connected with of pivot extends the post, the fixed surface that extends the post is connected with drips the stub bar, the surface that extends the post is provided with docking mechanism, the surface of slide is provided with actuating.

Preferably, the driving mechanism comprises an electric push rod, the outer wall of the electric push rod is fixedly connected with the bottom surface of the cross beam, the push rod head of the electric push rod is fixedly connected with the surface of the sliding plate, the bottom surface of the cross beam is fixedly connected with an inclined rod, the surface of the inclined rod is connected with a moving block in a sliding manner, the surface of the moving block is fixedly connected with the back side of the rack plate, and the end part of the rack plate is provided with a smearing mechanism.

Preferably, docking mechanism includes two stoppers, two the opposite side of stopper all is connected with the fixed surface who extends the post, the sleeve piece has been cup jointed to the armshaft that extends the post, groove body two has been seted up to the inside of sleeve piece, two the surface of stopper all slides along the inner wall of groove body two, two fixture blocks of the bottom surface fixedly connected with of sleeve piece, two draw-in grooves have been seted up to the upper surface of spacing post.

Preferably, paint the mechanism and include the curved bar, the tip of curved bar and the tip fixed connection of rack board, the barrel has been cup jointed to the bottom of curved bar, the even board is scribbled to the bottom surface fixedly connected with of barrel, the last fixed surface of operation bottom plate is connected with the limiting plate, the inner wall along the limiting plate of the armshaft of scribbling the even board slides, the opening that supplies to scribble the even board and pass and remove is seted up to the side of operation panel.

Preferably, the inner wall of the operating platform is fixedly connected with a first block, the surface of the first block is rotatably connected with a driving shaft, the surface of the driving shaft is fixedly connected with a door body, the surface of the driving shaft is sleeved with a torsion spring, one side of the torsion spring is fixedly connected with the surface of the first block, and the other side of the torsion spring is fixedly connected with the surface of the door body.

Preferably, the inner wall of the limiting column is slidably connected with two block bodies II, the opposite sides of the two block bodies II are fixedly connected with abutting plates, the opposite sides of the two block bodies II are fixedly connected with first reset springs, and the opposite sides of the first reset springs are fixedly connected with the inner wall of the limiting column.

Preferably, the bottom surface of the extension column is fixedly connected with a second return spring, and the bottom surface of the second return spring is fixedly connected with the inner wall of the second groove body.

Preferably, the size of the clamping groove is matched with that of the clamping block.

Compared with the prior art, the invention has the following beneficial effects:

when the device is used, an operator firstly places the optical disk on the operating platform, the limiting column penetrates through a central hole of the optical disk, the surface of the optical disk is dripped through the dripping head, so that dye is dripped on the surface of the optical disk, the sliding plate slides downwards along the inner wall of the limiting groove to drive the connecting plate to move downwards synchronously, the rotating shaft is driven to move downwards through the downward movement process of the connecting plate, the rotating shaft moves downwards to drive the extending column to move downwards, the optical disk is rotated through the extending column and the butting mechanism arranged on the surface of the extending column, and the dye dripped on the surface of the optical disk is uniformly distributed on the surface of the optical disk due to the centrifugal force generated by the rotation of the optical disk.

According to the invention, through the arrangement of the gear, the rack plate, the electric push rod, the inclined rod and the moving block, an operator starts the electric push rod, the sliding plate is driven to slide downwards along the inner wall of the limiting groove through the extension of the electric push rod head, so that the connecting plate is driven to move downwards synchronously, the rotating shaft is driven to move downwards through the downward movement process of the connecting plate, the extending column is driven to move downwards through the downward movement of the rotating shaft, the gear and the rack plate are driven to move downwards synchronously through the downward synchronous movement process of the rotating shaft and the sliding plate, the moving block is driven to move downwards and rightwards along the surface of the inclined rod through the downward movement process of the rack plate, so that the rack plate is pushed to move rightwards along the inner wall of the first groove body, the gear is driven to rotate through the rightward movement process of the rack plate along the.

The invention is provided with the first groove body, the extending column, the limiting block, the sleeve block, the second groove body, the clamping block and the clamping groove, the extending column rotates to drive the two limit blocks to abut against the inner wall of the second groove body, so that the sleeve block rotates, and the sleeve block is driven to synchronously move downwards in the downward movement process of the extension column, when the sleeve block moves downwards to enable the two clamping blocks to be abutted against the upper surface of the limiting column, the extension column continues to move downwards and extrudes the second return spring, so that the two clamping blocks cling to the upper surface of the limiting column, and simultaneously, the sleeve block rotates to drive the two clamping blocks to synchronously rotate, when the two clamping blocks rotate to be positioned at the same position with the two clamping grooves, the two clamping blocks are respectively clamped with the two clamping grooves through the elastic force of the second spring, the sleeve block drives the operating platform to rotate simultaneously when rotating, thereby driving the optical disc to rotate, and the centrifugal force generated by the rotation of the optical disc enables the dye dropped on the surface of the optical disc to be uniformly distributed on the surface of the optical disc.

The invention drives the curved bar to move rightwards synchronously by arranging the curved bar, the cylinder body, the coating uniform plate and the limiting plate, drives the curved bar to move rightwards by the process that the rack plate moves rightwards, drives the cylinder body to move rightwards by the process that the curved bar moves rightwards, drives the coating uniform plate to move rightwards under the limiting action of the limiting plate by the rightward movement of the cylinder body, pushes the door body to overcome the elastic force of the torsion spring to rotate by the process that the coating uniform plate moves rightwards by the rightward movement of the limiting plate, so that the coating uniform plate passes through the opening to move towards the direction close to the optical disk and moves to the upper surface of the optical disk, and the coating uniform plate coats the dye on the surface of the optical disk by the rotation of the optical disk, the spin coating operation of the optical disk can be automatically completed by the processes, the spin coating of the dye is more uniform, after the spin coating is completed, an operator only needs to, and the clamping block moves upwards to be separated from the clamping groove, so that the optical disk stops rotating, and an operator can take out the optical disk conveniently.

According to the invention, through the arrangement of the first block body, the driving shaft, the torsion spring and the door body, when the uniform coating plate moves leftwards, the door body is abutted against the bottom surface of the uniform coating plate under the elastic force of the torsion spring, so that dyes attached to the bottom surface of the uniform coating plate are scraped, and when the uniform coating plate moves leftwards to be separated from the door body, the door body is rotated through the elastic force of the torsion spring, so that an opening is plugged again.

According to the invention, by arranging the block bodies II, the abutting plates and the first return springs, when the equipment is used, an operator firstly pulls the two abutting plates in opposite directions, so that the two abutting plates push the two block bodies II to move relatively and extrude the two first return springs, at the moment, the optical disk is placed on the operating platform, the limiting column penetrates through the central hole of the optical disk, at the moment, the two abutting plates are loosened, the two block bodies II move back to back through the elastic restoring force of the two first return springs, so that the two abutting plates are pushed to move back to abut against the inner wall of the central hole of the optical disk, and the optical disk is limited on the operating platform, so that the subsequent spin-coating operation is completed.

Drawings

FIG. 1 is a front cross-sectional view of the structure of the present invention;

FIG. 2 is a right side view of a portion of the structure of FIG. 1 in accordance with the present invention;

FIG. 3 is a top view of a portion of the structure of FIG. 1 in accordance with the present invention;

FIG. 4 is an enlarged view of a portion of the structure of FIG. 1 in accordance with the present invention;

FIG. 5 is a cross-sectional view of the structure of FIG. 4 at C-C in accordance with the present invention;

FIG. 6 is a top cross-sectional view of a portion of the structure of FIG. 3 in accordance with the present invention;

FIG. 7 is an enlarged view of the structure of FIG. 1 at A in accordance with the present invention;

FIG. 8 is a schematic representation of the motion of the structure of FIG. 7 according to the present invention;

fig. 9 is an enlarged view of the structure of fig. 3 at B according to the present invention.

In the figure: 1. operating the bottom plate; 2. a support; 3. an operation box; 4. turning the column; 5. an operation table; 6. a limiting column; 7. an optical disc; 8. a cross beam; 9. a bearing plate; 10. a limiting groove; 11. a slide plate; 12. a connecting plate; 13. a rotating shaft; 14. a gear; 15. a rack plate; 16. a first tank body; 17. extending the column; 18. a limiting block; 19. sleeving blocks; 20. a second tank body; 21. a clamping block; 22. a card slot; 23. an electric push rod; 24. a diagonal bar; 25. a moving block; 26. a curved bar; 27. a barrel; 28. uniformly coating a board; 29. a limiting plate; 30. a first block body; 31. a drive shaft; 32. a torsion spring; 33. a second block body; 34. a butt joint plate; 35. a first return spring; 36. a second return spring; 37. an opening; 38. a door body; 39. and (4) a material dropping head.

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 to 9, the present invention provides a technical solution: the utility model provides a CD spin coating equipment for CD-ROM is made, includes operation bottom plate 1, bearing plate 9 and crossbeam 8, and the last fixed surface of operation bottom plate 1 is connected with support 2, and the last fixed surface of support 2 is connected with operation box 3, and the inner wall of operation box 3 rotates through the bearing and is connected with rotary column 4.

The upper surface of the rotating column 4 is fixedly connected with an operating platform 5, the upper surface of the operating platform 5 is fixedly connected with a limiting column 6, an optical disk 7 is placed on the upper surface of the operating platform 5, a limiting groove 10 is formed in the surface of a bearing plate 9, a sliding plate 11 is connected to the inner wall of the limiting groove 10 in a sliding manner, a connecting plate 12 is fixedly connected to the surface of the sliding plate 11, a rotating shaft 13 is rotatably connected to the bottom surface of the connecting plate 12 through a bearing, a gear 14 is fixedly connected to the surface of the rotating shaft 13, a rack plate 15 is meshed with teeth of the gear 14, a groove body I16 is formed in the front surface of the sliding plate 11, the surface of the rack plate 15 slides along the inner wall of the groove body I16, an extending column 17 is fixedly connected to the bottom surface of the rotating shaft 13, a material dripping head 39 is fixedly connected to the surface of the extending column 17, when the equipment is used, an operator firstly places the optical, make the dyestuff drip on the surface of CD 7, slide 11 slides down along the inner wall of spacing groove 10, thereby drive connecting plate 12 and carry out simultaneous movement downwards, the process through connecting plate 12 downstream drives pivot 13 and carries out the downstream, pivot 13 downstream drives extension post 17 downstream, and rotate through extension post 17 and the docking mechanism who extends the surface setting of post 17 makes CD 7 rotate, CD 7 rotates the centrifugal force that produces and makes its surface drip's dyestuff evenly distributed on the surface of CD 7, the surface that extends post 17 is provided with docking mechanism, slide 11's surface is provided with actuating mechanism.

In the above scheme, specifically, the driving mechanism includes an electric push rod 23, an outer wall of the electric push rod 23 is fixedly connected with a bottom surface of the cross beam 8, a push rod head of the electric push rod 23 is fixedly connected with a surface of the sliding plate 11, a bottom surface of the cross beam 8 is fixedly connected with an inclined rod 24, a surface of the inclined rod 24 is slidably connected with a moving block 25, a surface of the moving block 25 is fixedly connected with a back side of the rack plate 15, an end portion of the rack plate 15 is provided with a smearing mechanism, an operator starts the electric push rod 23 to drive the sliding plate 11 to slide downwards along an inner wall of the limiting groove 10 by extending out of the push rod head of the electric push rod 23, so as to drive the connecting plate 12 to move downwards synchronously, the rotating shaft 13 is driven to move downwards by a downward movement process of the connecting plate 12, the rotating shaft 13 moves downwards to drive the extending column 17 to move downwards, the gear 14, and the moving block 25 is driven to move towards the lower right along the surface of the inclined rod 24 in the process of moving downwards through the rack plate 15, so that the rack plate 15 is pushed to move towards the right side along the inner wall of the first groove body 16, the gear 14 is driven to rotate in the process of moving towards the right side along the inner wall of the first groove body 16 through the rack plate 15, and the extending column 17 is driven to rotate through the rotation of the gear 14.

In the above scheme, specifically, the docking mechanism includes two limiting blocks 18, opposite sides of the two limiting blocks 18 are fixedly connected with the surface of the extending column 17, a sleeve block 19 is sleeved on a shaft arm of the extending column 17, a second groove body 20 is formed inside the sleeve block 19, surfaces of the two limiting blocks 18 slide along the inner wall of the second groove body 20, two clamping blocks 21 are fixedly connected with the bottom surface of the sleeve block 19, two clamping grooves 22 are formed in the upper surface of the limiting column 6, a second return spring 36 is fixedly connected with the bottom surface of the extending column 17, the bottom surface of the second return spring 36 is fixedly connected with the inner wall of the second groove body 20, the extending column 17 rotates to drive the two limiting blocks 18 to abut against the inner wall of the second groove body 20, so that the sleeve block 19 rotates, the sleeve block 19 is driven to move down synchronously by the downward movement process of the extending column 17, when the sleeve block 19 moves downward to cause the two clamping blocks, extension post 17 continues downstream and extrudees two reset spring 36, when making two fixture blocks 21 hug closely the upper surface of spacing post 6, rotate through cover block 19 and drive two fixture blocks 21 and carry out synchronous rotation, when two fixture blocks 21 rotate to be in same position with two draw-in grooves 22, elastic force through two reset spring 36 makes two fixture blocks 21 respectively with two draw-in grooves 22 joint, drive operation panel 5 when cover block 19 rotates this moment simultaneously and rotate, thereby drive CD 7 and rotate, CD 7 rotates the centrifugal force that produces and makes its surface drip's dyestuff evenly distributed on CD 7's surface.

In the above scheme, specifically, the smearing mechanism includes a curved bar 26, an end of the curved bar 26 is fixedly connected with an end of a rack plate 15, a cylinder 27 is sleeved at a bottom end of the curved bar 26, a bottom surface of the cylinder 27 is fixedly connected with a leveling plate 28, an upper surface of the operating base plate 1 is fixedly connected with a limiting plate 29, a shaft arm of the leveling plate 28 slides along an inner wall of the limiting plate 29, an opening 37 through which the leveling plate 28 passes and moves is formed in a side surface of the operating platform 5, the curved bar 26 is driven to synchronously move to the right through a process of moving the rack plate 15 to the right, the cylinder 27 is driven to move to the right through a process of moving the curved bar 26 to the right, the leveling plate 28 is driven to move to the right under the limiting effect of the limiting plate 29 by moving to the cylinder 27 to move to the right, the door body 38 is driven to rotate by overcoming the elastic force of the torsion spring 32 through a process of moving the leveling plate 28 to the right, so that the, and move to the upper surface of CD 7, and make through the rotation of CD 7 scribble even plate 28 and scribble the dyestuff on CD 7 surface even, can accomplish the spin coating operation of CD 7 automatically through the above-mentioned process, and make the spin coating of dyestuff more even, after the spin coating is accomplished, operating personnel only need make withdrawing of electric putter 23 push rod head drive slide 11 along the inner wall of spacing groove 10 upwards sliding, and make fixture block 21 rebound and draw-in groove 22 separation, make CD 7 stall, thereby make things convenient for operating personnel to take out CD 7.

In the above scheme, specifically, the inner wall of the console 5 is fixedly connected with the first block 30, the surface of the first block 30 is rotatably connected with the driving shaft 31, the surface of the driving shaft 31 is fixedly connected with the door body 38, the surface of the driving shaft 31 is sleeved with the torsion spring 32, one side of the torsion spring 32 is fixedly connected with the surface of the first block 30, and the other side of the torsion spring 32 is fixedly connected with the surface of the door body 38, as shown in fig. 8, when the leveling plate 28 moves to the left, the door body 38 is abutted to the bottom surface of the leveling plate 28 under the elastic force of the torsion spring 32, so that dyes attached to the bottom surface of the leveling plate 28 are scraped, and when the leveling plate 28 moves to the left to be separated from the door body 38, the door body 38 is rotated through the elastic force of the torsion spring 32, so that.

In the above scheme, specifically, the inner wall of the limiting column 6 is slidably connected with two block bodies two 33, opposite sides of the two block bodies two 33 are fixedly connected with the abutting plate 34, opposite sides of the two block bodies two 33 are fixedly connected with the return springs one 35, opposite sides of the return springs one 35 are fixedly connected with the inner wall of the limiting column 6, the size of the clamping groove 22 is matched with that of the clamping block 21, when the device is used, an operator firstly pulls the two abutting plates 34 in opposite directions, so that the two abutting plates 34 push the two block bodies two 33 to move relatively and extrude the two return springs one 35, at this time, the optical disc 7 is placed on the operating platform 5, the limiting column 6 penetrates through the central hole of the optical disc 7, at this time, the two abutting plates 34 are loosened, the two block bodies two 33 move back to back through the elastic restoring force of the two return springs one 35, so that the two abutting plates 34 are pushed to move back to abut against the inner wall of the, thereby positioning the optical disc 7 on the operation table 5 for the completion of the subsequent spin-coating operation.

The working principle is as follows: when the optical disc spin coating equipment for manufacturing the optical disc is used, an operator firstly pulls the two abutting plates 34 towards the opposite direction, so that the two abutting plates 34 push the two block bodies two 33 to move relatively and extrude the two return springs one 35, at the moment, the optical disc 7 is placed on the operating platform 5, the limiting column 6 penetrates through the central hole of the optical disc 7, at the moment, the two abutting plates 34 are loosened, the two block bodies two 33 move back to back through the elastic restoring force of the two return springs one 35, so that the two abutting plates 34 move back to abut against the inner wall of the central hole of the optical disc 7, so that the optical disc 7 is limited on the operating platform 5, so that the subsequent spin coating operation is completed, after the limiting of the optical disc 7 is completed, the operator firstly drips the surface of the optical disc 7 through the dripping head 39, so that dye drips on the surface of the optical disc 7, then the operator starts the electric push rod 23, the electric push rod 23 drives the sliding plate 11 to slide downwards along the inner wall of the limiting groove 10 by extending out of the rod head, so as to drive the connecting plate 12 to move downwards synchronously, the rotating shaft 13 is driven to move downwards by the downward movement process of the connecting plate 12, the extending column 17 is driven to move downwards by the downward movement of the rotating shaft 13, the gear 14 and the rack plate 15 are driven to move downwards synchronously by the downward synchronous movement process of the rotating shaft 13 and the sliding plate 11, the moving block 25 is driven to move downwards and rightwards along the surface of the inclined rod 24 by the downward movement process of the rack plate 15, so as to push the rack plate 15 to move rightwards along the inner wall of the first groove body 16, the gear 14 is driven to rotate by the movement process of the rack plate 15 moving rightwards along the inner wall of the first groove body 16, the extending column 17 is driven to rotate by the rotation of the gear 14, and the two limiting blocks 18 are abutted, the sleeve block 19 is rotated, the sleeve block 19 is driven to synchronously move downwards through the downward movement process of the extension column 17, when the sleeve block 19 moves downwards to enable the two fixture blocks 21 to abut against the upper surface of the limiting column 6, the extension column 17 continues to move downwards and extrudes the second return spring 36, the two fixture blocks 21 are enabled to cling to the upper surface of the limiting column 6, the two fixture blocks 21 are driven to synchronously rotate through the rotation of the sleeve block 19, when the two fixture blocks 21 rotate to be positioned at the same position with the two clamping grooves 22, the two fixture blocks 21 are respectively clamped with the two clamping grooves 22 through the elastic force of the second return spring 36, the operating platform 5 is driven to rotate simultaneously when the sleeve block 19 rotates, so as to drive the optical disk 7 to rotate, the dye dropped on the surface of the optical disk 7 is uniformly distributed on the surface of the optical disk 7 through the centrifugal force generated by the rotation of the optical disk 7, the curved rod 26 is driven to synchronously move to the right through the, the cylinder 27 is driven to move rightwards through the process that the curved rod 26 moves rightwards, the cylinder 27 moves rightwards to drive the coating uniform plate 28 to move rightwards under the limiting effect of the limiting plate 29, the door body 38 is pushed to overcome the elastic force of the torsion spring 32 to rotate through the process that the coating uniform plate 28 moves rightwards, so that the coating uniform plate 28 passes through the opening 37 to move towards the direction close to the optical disk 7 and moves to the upper surface of the optical disk 7, the coating uniform plate 28 coats the dye on the surface of the optical disk 7 uniformly through the rotation of the optical disk 7, the spin coating operation of the optical disk 7 can be automatically completed through the processes, the spin coating of the dye is more uniform, after the spin coating is completed, an operator only needs to retract the push rod head of the electric push rod 23 to drive the sliding plate 11 to slide upwards along the inner wall of the limiting groove 10, the fixture block 21 moves upwards to be separated from the fixture groove 22, and the, thereby make things convenient for operating personnel to take out CD 7 to scribble even board 28 and move left and separate with CD 7, and as shown in fig. 8, scribble even board 28 and move left, make door body 38 butt scribble the bottom surface of even board 28 under the elastic force of torsion spring 32 to scrape off scribbling the adnexed dyestuff of even board 28 bottom surface, when scribbling even board 28 and move left and separate with door body 38, thereby make door body 38 rotate through the elastic force of torsion spring 32 and carry out the shutoff again to opening 37.

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

Claims (5)

1. An optical disc spin coating apparatus for optical disc manufacturing, comprising an operation base plate (1), a bearing plate (9) and a cross member (8), characterized in that: the upper surface of the operation bottom plate (1) is fixedly connected with a support (2), the upper surface of the support (2) is fixedly connected with an operation box (3), and the inner wall of the operation box (3) is rotatably connected with a rotary column (4) through a bearing;

the upper surface of the rotary column (4) is fixedly connected with an operation table (5), the upper surface of the operation table (5) is fixedly connected with a limiting column (6), the upper surface of the operation table (5) is provided with an optical disk (7), the surface of the bearing plate (9) is provided with a limiting groove (10), the inner wall of the limiting groove (10) is connected with a sliding plate (11) in a sliding manner, the surface of the sliding plate (11) is fixedly connected with a connecting plate (12), the bottom surface of the connecting plate (12) is rotatably connected with a rotating shaft (13) through a bearing, the surface of the rotating shaft (13) is fixedly connected with a gear (14), teeth of the gear (14) are meshed with a rack plate (15), the front of the sliding plate (11) is provided with a first groove body (16), the surface of the rack plate (15) slides along the inner wall of the first groove body (16), and the bottom surface of the rotating, the surface of the extension column (17) is fixedly connected with a material dripping head (39), the surface of the extension column (17) is provided with a butt joint mechanism, and the surface of the sliding plate (11) is provided with a driving mechanism;

the driving mechanism comprises an electric push rod (23), the outer wall of the electric push rod (23) is fixedly connected with the bottom surface of a cross beam (8), the push rod head of the electric push rod (23) is fixedly connected with the surface of a sliding plate (11), the bottom surface of the cross beam (8) is fixedly connected with an inclined rod (24), the surface of the inclined rod (24) is slidably connected with a moving block (25), the surface of the moving block (25) is fixedly connected with the back side of a rack plate (15), and the end part of the rack plate (15) is provided with a smearing mechanism;

docking mechanism includes two stopper (18), two the opposite side of stopper (18) all is connected with the fixed surface who extends post (17), the armshaft that extends post (17) has cup jointed sleeve piece (19), two (20) of cell body have been seted up to the inside of sleeve piece (19), two the inner wall of two (20) of cell body is all followed on the surface of stopper (18) slides, two fixture blocks (21) of bottom surface fixedly connected with of sleeve piece (19), two draw-in grooves (22) have been seted up to the upper surface of spacing post (6).

2. An optical disc spin coating apparatus for optical disc manufacturing according to claim 1, wherein: the smearing mechanism comprises a curved bar (26), the end of the curved bar (26) is fixedly connected with the end of a rack plate (15), a cylinder (27) is sleeved at the bottom end of the curved bar (26), a smearing plate (28) is fixedly connected to the bottom surface of the cylinder (27), a limiting plate (29) is fixedly connected to the upper surface of the operation bottom plate (1), a shaft arm of the smearing plate (28) slides along the inner wall of the limiting plate (29), and an opening (37) for the smearing plate (28) to pass through and move is formed in the side surface of the operation table (5);

the inner wall fixedly connected with block (30) of operation panel (5), the surface of block (30) is rotated and is connected with drive shaft (31), the fixed surface of drive shaft (31) is connected with a door body (38), torsion spring (32) have been cup jointed on the surface of drive shaft (31), one side and the fixed surface of block (30) of torsion spring (32) are connected, the opposite side and the fixed surface of door body (38) of torsion spring (32) are connected.

3. An optical disc spin coating apparatus for optical disc manufacturing according to claim 1, wherein: the inner wall sliding connection of spacing post (6) has two blocks two (33), two the equal fixedly connected with butt joint board (34) of the back of the body side of two (33), two the equal fixedly connected with reset spring (35) of the opposite side of block two (33), two the opposite side of reset spring (35) all with the inner wall fixed connection of spacing post (6).

4. An optical disc spin coating apparatus for optical disc manufacturing according to claim 1, wherein: the bottom surface of the extension column (17) is fixedly connected with a second reset spring (36), and the bottom surface of the second reset spring (36) is fixedly connected with the inner wall of the second groove body (20).

5. An optical disc spin coating apparatus for optical disc manufacturing according to claim 1, wherein: the size of the clamping groove (22) is matched with that of the clamping block (21).

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