CN114438577B - Optical lens shell anti-oxidation coating device - Google Patents

Abstract

The present disclosure relates to film plating apparatuses, and particularly to an anti-oxidation film plating apparatus for an optical lens housing. The invention provides an optical lens housing anti-oxidation film plating device for plating films on a plurality of lens housings. An anti-oxidation film plating device of an optical lens shell comprises a base, a mounting rack, an electrolytic cell, a collecting box, a blanking mechanism and a rotating mechanism; the right side of the upper part of the base is provided with a mounting frame, the upper side of the base is provided with an electrolytic cell, a collecting box is connected between the upper side of the left part of the electrolytic cell and the base, the lower side of the mounting frame is provided with a discharging mechanism, and the discharging mechanism is provided with a rotating mechanism. According to the invention, the five lens shells are respectively placed on the five rollers by people, and then the lens shells are moved into the electrolytic cell, so that the reacted gas contacts with the lens shells, the effect of coating the plurality of lens shells is realized, and the working efficiency is improved.

Description

Optical lens shell anti-oxidation coating device

Technical Field

The present disclosure relates to film plating apparatuses, and particularly to an anti-oxidation film plating apparatus for an optical lens housing.

Background

The camera can all have the camera shell when production, is used for protecting the camera and increasing the pleasing to the eye of camera, and current camera shell is after processing, people can be immediately to its coating film in order to prevent that the camera shell from being oxidized thereby influences pleasing to the eye, and current coating device is when carrying out the coating film to the camera shell, mainly places single camera shell in inclosed space and uses coating film mechanism to carry out the coating film to it, just so reduced work efficiency, consumed the manpower simultaneously.

Patent application: CN212983038U, publication day 20210416, discloses a vacuum coating apparatus for uniformly heating a workpiece, which opens a protective door through a handle, then fixes the workpiece to a workbench, closes the protective door, then energizes a control panel, and then enables a first synchronous motor and a second synchronous motor to work through the control panel, moves a heater and a reflecting cover to a position right above the workbench, then starts the heater, and enables a rotating motor to work through an operation button inside the control panel, the rotating motor can drive the workbench to rotate, and then controls the operation button to enable the heater to move left and right on a beam, so that coating is more uniform.

The anti-oxidation film plating device for the optical lens shell is designed for plating films on a plurality of lens shells, so that the effect that the existing film plating equipment can only perform film plating on a single workpiece is overcome.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides an anti-oxidation film plating device for optical lens shells, which is used for plating films on a plurality of lens shells, so as to overcome the defect that the existing film plating device can only be used for plating films on a single workpiece.

In order to achieve the above object, the present invention is realized by the following scheme: the utility model provides an optical lens shell anti-oxidation coating film device, including base, mounting bracket, electrolytic cell, collecting box, unloading mechanism and slewing mechanism, base upper portion right side is equipped with the mounting bracket, and the base upside is equipped with the electrolytic cell, is connected with the collecting box that is used for collecting the camera lens shell that the coating film accomplished between electrolytic cell left part upside and the base, and the mounting bracket downside is equipped with the unloading mechanism that drives the camera lens shell and remove, is equipped with on the unloading mechanism and drives camera lens shell pivoted slewing mechanism.

As the improvement of above-mentioned scheme, unloading mechanism is including first installation piece, bracing piece, guide arm and electric putter, and both sides all slidingtype are equipped with the guide arm around the mounting bracket, are connected with first installation piece between two guide arm upside, and first installation piece contacts with the mounting bracket, and first installation piece lower part left side evenly is equipped with five bracing pieces, and electric putter who drives the lens housing downwardly moving is all installed to both sides around the mounting bracket, and two electric putter telescopic links all are connected with first installation piece.

As the improvement of above-mentioned scheme, slewing mechanism is equipped with the baffle box including cylinder, baffle box, gear motor and belt, bracing piece downside, and the baffle box left side is close to upside rotation and is equipped with the cylinder that is used for driving lens housing pivoted, and the cylinder is connected with homonymy bracing piece rotation, and the cylinder has five, and gear motor is installed to the inside right side downside of baffle box, and gear motor has five, has the belt through the drive wheel winding between gear motor output shaft and the homonymy cylinder, and the belt has five.

As the improvement of above-mentioned scheme, still including the discharge mechanism who realizes automatic unloading, discharge mechanism is including first piston rod, the second piston rod, the hydraulic tank, the connecting pipe, the third piston rod, first spring, first hinge piece, first torsional spring and second hinge piece, mounting bracket right side partial downside is equipped with the connecting pipe, the even slidingtype in connecting pipe left side is equipped with four first piston rods, first piston rod is connected with electrolysis Chi Huadong formula, both sides all slidingtype are equipped with the second piston rod around the connecting pipe, the second piston rod is connected with electrolysis Chi Huadong formula, both sides partial right downside all is equipped with the hydraulic tank around the mounting bracket, the hydraulic tank is connected with the connecting pipe, all be connected with first spring between two hydraulic tank downside of third piston rod upper portion front and back both sides and the hydraulic tank of homonymy, first spring winds on the third piston rod, both sides all are connected with first torsional spring between first torsional spring and the third piston rod around the first hinge piece, first torsional spring winds on first hinge piece, first torsional spring both sides all are equipped with the hinge piece, both sides are connected with the second torsional spring contact with the second hinge piece, both sides are all articulated with the second hinge piece.

As the improvement of above-mentioned scheme, still including buffer gear, buffer gear is including buffer board and second spring, and both sides all are equipped with four second springs around the collection incasement bottom, and the second spring has eight, is connected with the buffer board between eight second spring upside, and the buffer board is connected with the collection case slidingtype, evenly opens nine water diversion grooves on the buffer board.

As a further preferred scheme, the automatic feeding device further comprises a feeding mechanism for realizing automatic feeding, the automatic feeding device comprises a second mounting block, a first rotating shaft, a first connecting rod, a second connecting rod, a third connecting rod, a hinging rod, a second torsion spring, a unidirectional gear, racks and a third torsion spring, wherein the second mounting block is arranged on the left side of the upper portion of the mounting frame, the first rotating shaft is rotatably arranged on the second mounting block, the first connecting rod is arranged on the front and rear sides of the first rotating shaft, the first connecting rod is in contact with the second mounting block, the second connecting rod is rotatably arranged between the left sides of the two first connecting rods, the third connecting rod is rotatably connected with the second connecting rod, the left sides of the second connecting rod are uniformly hinged with five hinging rods, ten second torsion springs are respectively arranged between the front and rear sides of the hinging rod and the second connecting rod, unidirectional gears are respectively arranged on the front and rear sides of the first rotating shaft, racks are respectively arranged on the front and rear sides of the upper portion of the first mounting block, the unidirectional gear is in contact with the same side of the second rotating shaft, the third connecting rod is rotatably connected with the third connecting rod, and the third torsion spring is rotatably connected between the front and the third connecting rod.

As the improvement of above-mentioned scheme, still including the stop gear who blocks the camera lens shell, stop gear is equipped with the second pivot including second pivot, gag lever post and fourth torsional spring, bracing piece left side rotation, and there are five second pivots, is equipped with the gag lever post in the second pivot, all is connected with the fourth torsional spring between both sides and the adjacent bracing piece around the gag lever post, and the fourth torsional spring has ten, and the fourth torsional spring winds in the second pivot.

As an improvement of the scheme, six through holes are uniformly formed on the upper side of the right part of the electrolytic cell.

The invention has the advantages that: 1. according to the invention, the five lens shells are respectively placed on the five rollers by people, and then the lens shells are moved into the electrolytic cell, so that the reacted gas is contacted with the lens shells, the effect of coating the plurality of lens shells is realized, and the working efficiency is improved;

2. the third piston rod moves upwards, so that the hydraulic pressure in the hydraulic tank is changed under the pushing of the third piston rod, and the first piston rod and the second piston rod move leftwards, so that the first piston rod and the second piston rod push the lens shell into the collecting tank, the effect of automatic discharging is achieved, and labor is saved;

3. the lens housing is pushed onto the buffer plate through the first piston rod and the second piston rod, so that the buffer plate moves downwards, the second spring is compressed, the buffering effect is achieved, and the lens housing is prevented from being damaged when falling into the collecting box.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present invention.

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

Fig. 3 is a partial perspective view of the present invention.

Fig. 4 is a schematic view of a first three-dimensional structure of the blanking mechanism of the present invention.

Fig. 5 is a schematic diagram of a second three-dimensional structure of the blanking mechanism of the present invention.

Fig. 6 is a schematic perspective view of a rotating mechanism according to the present invention.

Fig. 7 is a partial perspective sectional view of the turning mechanism of the present invention.

Fig. 8 is a schematic perspective view of the discharging mechanism of the present invention.

Fig. 9 is a perspective sectional view of the discharging mechanism of the present invention.

Fig. 10 is an enlarged view of the present invention at a.

Fig. 11 is a schematic perspective view of a buffer mechanism according to the present invention.

Fig. 12 is a schematic perspective view of a first part of a feeding mechanism according to the present invention.

Fig. 13 is a schematic perspective view of a second part of the feeding mechanism according to the present invention.

Fig. 14 is a schematic partial perspective view of a limiting mechanism according to the present invention.

Fig. 15 is an enlarged view of the present invention at B.

Wherein: the device comprises a base, a 2-mounting frame, a 3-electrolytic cell, a 4-collecting box, a 5-blanking mechanism, a 51-first mounting block, a 52-supporting rod, a 53-guiding rod, a 54-electric push rod, a 6-rotating mechanism, a 61-roller, a 62-isolation box, a 63-speed reduction motor, a 64-belt, a 7-discharging mechanism, a 71-first piston rod, a 711-second piston rod, a 72-hydraulic box, a 73-connecting pipe, a 74-third piston rod, a 75-first spring, a 76-first hinging block, a 77-first torsion spring, a 78-second hinging block, a 8-buffering mechanism, a 81-buffering plate, a 82-second spring, a 83-diversion groove, a 9-feeding mechanism, a 91-second mounting block, a 92-first rotating shaft, a 93-first connecting rod, a 94-second connecting rod, a 95-third connecting rod, a 96-hinging rod, a 97-second torsion spring, a 98-unidirectional gear, a 99-rack, a 910-third torsion spring, a 10-limiting mechanism, a 101-second rotating shaft, a 102-limiting rod and a 103-fourth torsion spring.

Detailed Description

The invention will be further described with reference to the accompanying drawings and detailed description below:

example 1

Referring to fig. 1-7, the optical lens housing anti-oxidation coating device comprises a base 1, a mounting frame 2, an electrolytic cell 3, a collecting box 4, a blanking mechanism 5 and a rotating mechanism 6, wherein the right side of the upper part of the base 1 is provided with the mounting frame 2, the upper side of the base 1 is provided with the electrolytic cell 3, six through holes are evenly formed in the upper side of the right part of the electrolytic cell 3, the collecting box 4 is connected between the upper side of the left part of the electrolytic cell 3 and the base 1, the collecting box 4 is used for collecting a lens housing with coating completed, the lower side of the mounting frame 2 is provided with the blanking mechanism 5, and the blanking mechanism 5 is provided with the rotating mechanism 6.

Referring to fig. 4 and 5, the blanking mechanism 5 includes a first mounting block 51, support rods 52, guide rods 53 and electric push rods 54, the guide rods 53 are slidably disposed on the front side and the rear side of the mounting frame 2, the first mounting block 51 is connected between the upper sides of the two guide rods 53 through bolts, the first mounting block 51 is in contact with the mounting frame 2, five support rods 52 are uniformly disposed on the left side of the lower portion of the first mounting block 51, the electric push rods 54 are fixedly connected on the front side and the rear side of the mounting frame 2 through bolts, and the telescopic rods of the two electric push rods 54 are connected with the first mounting block 51.

Referring to fig. 6 and 7, the rotating mechanism 6 includes a drum 61, a separation box 62, a gear motor 63 and a belt 64, the separation boxes 62 are welded at the lower sides of the support rods 52, five separation boxes 62 are provided, the drum 61 is rotatably arranged at the upper side of the left side of the separation boxes 62, the drum 61 is rotatably connected with the support rods 52 at the same side, five separation boxes 61 are fixedly connected with the gear motor 63 through bolts at the lower right side in the separation boxes 62, five gear motors 63 are provided, a belt 64 is wound between the output shaft of the gear motor 63 and the drum 61 at the same side through a driving wheel, and five belts 64 are provided.

When people need to carry out the coating film to the lens housing, people can use this kind of optical lens housing anti-oxidation coating film device, at first, people place five processing completion and need the camera lens housing of coating film respectively on five cylinders 61, after placing the completion, people start electric putter 54, electric putter 54 telescopic link shortens down and drives first installation piece 51 and move down, thereby make guide arm 53 move down, make bracing piece 52 move down, cylinder 61 and baffle box 62 move down, and then the camera lens housing moves down, when the camera lens housing moves to suitable position, first installation piece 51 contacts with mounting bracket 2, at this moment people close electric putter 54, then people start gear motor 63, gear motor 63 output shaft rotates and drives belt 64 to rotate, thereby make cylinder 61 rotate, make the camera lens housing rotate, at this moment, the reaction takes place in electrolytic cell 3, make the gas that the reaction is accomplished contact with the camera lens housing, thereby form the metal film on the camera lens housing, thereby realized the effect of automatic coating film, simultaneously, cylinder 61 drives the camera lens housing and is rotated, make the camera lens housing by even coating film, when the coating film is accomplished, people close gear motor 63, at the same time, people start electric putter 54, at the same time, electric putter 63 moves up, make the camera lens housing up, and then move up to the camera lens housing 53, when people move up, and make the camera lens housing up, thereby make the camera lens housing is moved up, when people move up, and move up the camera lens housing 54, thereby make the camera lens housing is moved, so that people move up, make the camera lens housing is finished, make the people move up, and move up, thereby take the camera lens housing, can move up, and move, thereby take the effect, can move, and move the film, can move the film, and move the film.

Example 2

On the basis of embodiment 1, referring to fig. 8-10, discharging mechanism 7 is still including, discharging mechanism 7 is including first piston rod 71, second piston rod 711, hydraulic pressure case 72, connecting pipe 73, third piston rod 74, first spring 75, first hinge piece 76, first torsional spring 77 and second hinge piece 78, the welding of the right side partial downside of mounting bracket 2 has connecting pipe 73, the even slidingtype in connecting pipe 73 left side is equipped with four first piston rods 71, first piston rod 71 is connected with the through-hole slidingtype on electrolytic cell 3, the front and back both sides of connecting pipe 73 are all slidingtype and are equipped with second piston rod 711, the through-hole slidingtype on second piston rod 711 and electrolytic cell 3 is equipped with hydraulic pressure case 72, hydraulic pressure case 72 is connected with connecting pipe 73, all be connected with first spring 75 between the lower side of two hydraulic pressure cases 72, first spring 75 winds on third piston rod 74, the first torsional spring 77 is all connected with first torsional spring 77 in the right side of both sides of hinge piece 76, the first hinge piece 76 is equipped with the right side of both sides of being connected with first torsional spring 76 around the right side between the right side of the third piston rod 74.

Referring to fig. 11, the camera lens is characterized by further comprising a buffer mechanism 8, wherein the buffer mechanism 8 comprises a buffer plate 81 and second springs 82, four second springs 82 are arranged on the front side and the rear side of the inner bottom of the collecting box 4, eight second springs 82 are connected between the upper sides of the eight second springs 82, the buffer plate 81 is connected with the collecting box 4 in a sliding mode, nine water diversion grooves 83 are uniformly formed in the buffer plate 81, and the water diversion grooves 83 are used for draining of the camera lens housing.

Referring to fig. 12-14, the feeding mechanism 9 further comprises a second mounting block 91, a first rotating shaft 92, a first connecting rod 93, a second connecting rod 94, a third connecting rod 95, a hinge rod 96, a second torsion spring 97, a one-way gear 98, racks 99 and a third torsion spring 910, wherein the second mounting block 91 is welded on the left side of the upper portion of the mounting frame 2, the first rotating shaft 92 is rotatably arranged on the second mounting block 91, the first connecting rod 93 is in contact with the second mounting block 91, the second connecting rod 94 is rotatably arranged between the left sides of the two first connecting rods 93, the front side and the rear side of the left part of the second mounting block 91 are rotatably provided with the third connecting rod 95, the third connecting rod 95 is rotatably connected with the second connecting rod 94, the left side of the second connecting rod 94 is uniformly hinged with the five hinge rods 96, the second torsion spring 97 is rotatably connected with the front side and the rear side of the second connecting rod 94, the second torsion spring 97 is wound on the hinge rod 96, the front side and the rear side of the first connecting rod 92 is rotatably connected with the racks 92, the front side and the rear side of the second connecting rod 94 is rotatably connected with the racks 910, and the front side of the first connecting rod 92 is rotatably connected with the racks 910, and the front side and the rear side of the second connecting rod 92 is rotatably connected with the first torsion spring 910, and the front side of the second connecting rod is rotatably connected with the rack 910.

Referring to fig. 14-15, the lens holder further comprises a limiting mechanism 10, the limiting mechanism 10 comprises a second rotating shaft 101, limiting rods 102 and fourth torsion springs 103, the second rotating shafts 101 are rotatably arranged on the left sides of the supporting rods 52, five second rotating shafts 101 are welded on the second rotating shafts 101, the limiting rods 102 are used for clamping a lens housing, the fourth torsion springs 103 are connected between the front side and the rear side of the limiting rods 102 and the adjacent supporting rods 52, ten fourth torsion springs 103 are arranged, and the fourth torsion springs 103 are wound on the second rotating shafts 101.

When the second hinge block 78 contacts with the first hinge block 76 at the same side, the second hinge block 78 drives the first hinge block 76 to move upwards due to the larger elastic force of the first torsion spring 77, so that the third piston rod 74 moves upwards, the first spring 75 is compressed, at the moment, under the pushing of the third piston rod 74 and the hydraulic action in the hydraulic tank 72, the first piston rod 71 and the second piston rod 711 move leftwards, so that the first piston rod 71 and the second piston rod 711 push the lens housing into the collecting tank 4, thereby realizing the automatic blanking effect, saving manpower, and simultaneously the second hinge block 78 is continuously driven by the guide rod 53 to move upwards, so that the second hinge block 78 pushes the first hinge block 76 to rotate, so that the first torsion spring 77 is torsionally deformed, when the second hinge block 78 continues to move upwards and away from the first hinge block 76, the first torsion spring 77 resets to drive the first hinge block 76 to reset, and simultaneously the first spring 75 resets to drive the third piston rod 74 to move downwards to reset, under the action of hydraulic pressure, the first piston rod 71 and the second piston rod 711 move rightwards, the guide rod 53 moves downwards to drive the second hinge block 78 to move downwards, and when the second hinge block 78 contacts with the first hinge block 76 on the same side, the third piston rod 74 is blocked in the hydraulic tank 72 to enable the second hinge block 78 to rotate, the third piston rod 74 does not move, and meanwhile the first torsion spring 77 has larger elasticity, and at the moment, the first hinge block 76 does not rotate, so that the guide rod 53 continues to drive the second hinge block 78 to move downwards to stop.

The first piston rod 71 and the second piston rod 711 push the lens housing onto the buffer plate 81, so that the buffer plate 81 adaptively moves downwards, the second spring 82 is adaptively compressed, the buffering effect is achieved, the phenomenon that the lens housing falls into the collecting box 4 to be damaged after film coating is completed is avoided, water vapor on the lens housing is converged into water drops to flow into the bottom of the collecting box 4 through the water diversion groove 83, the draining collecting effect is achieved, when draining is completed, people collect the lens housing, and the second spring 82 drives the buffer plate 81 to reset.

Firstly, five lens housings are respectively placed on five hinging rods 96, a first mounting block 51 moves upwards to drive a rack 99 to move upwards, so that a roller 61 moves upwards, when the rack 99 moves upwards to be in contact with a one-way gear 98, the rack 99 drives the one-way gear 98 to rotate, so that a first rotating shaft 92 rotates, a third torsion spring 910 is torsionally deformed, so that a first connecting rod 93 rotates, a second connecting rod 94 rotates, a third connecting rod 95 rotates, so that the hinging rods 96 and the lens housings rotate, when the second connecting rod 94 rotates, under the pulling of the third connecting rod 95, the second connecting rod 94 and the hinging rods 96 rotate to be in a horizontal state, at the moment, the lens housings fall on the roller 61, the first mounting block 51 moves downwards to drive the rack 99 to move downwards, the roller 61 moves downwards, at the moment, the one-way gear 98 idles, the roller 61 continues to move downwards, when the lens housing is pulled to the roller 61, the third torsion spring 910 resets to drive the first rotating shaft 92 to rotate reversely, so that the first connecting rod 93 rotates reversely, the second connecting rod 94 rotates reversely with the hinge rod 96, the third connecting rod 95 rotates reversely, the roller 61 and the limit rod 102 continue to move downwards while the hinge rod 96 rotates reversely, so that the lens housing moves leftwards on the roller 61, when the roller 61 and the limit rod 102 clamp the lens housing, the second connecting rod 94 drives the hinge rod 96 to rotate reversely, so that the hinge rod 96 rotates under the action of resistance force, the second torsion spring 97 twists and deforms, the fourth torsion spring 103 deforms slightly, the second rotating shaft 101 and the limit rod 102 rotate slightly, thereby realizing the limiting effect, avoiding the sliding of the lens housing, when the hinge rod 96 is far away from the lens housing, the second torsion spring 97 resets to drive the hinge rod 96 to reset, at this time, the hinge rod 96 and the second connecting rod 94 are in a horizontal state under the pulling of the third connecting rod 95, and meanwhile, the lens housing falls on the roller 61, so that the fourth torsion spring 103 resets to drive the limiting rod 102 to reset, and the second rotating shaft 101 reversely rotates, thereby realizing the feeding effect.

The technical principles of the embodiments of the present invention are described above in connection with specific embodiments. The description is only intended to explain the principles of the embodiments of the invention and should not be taken in any way as limiting the scope of the embodiments of the invention. Based on the explanations herein, those skilled in the art will recognize other embodiments of the present invention without undue burden, and those ways that are within the scope of the present invention.

Claims (5)

1. The utility model provides an optical lens shell anti-oxidation coating film device, including base (1), mounting bracket (2), electrolytic cell (3) and collecting box (4), base (1) upper portion right side is equipped with mounting bracket (2), base (1) upside is equipped with electrolytic cell (3), be connected with between electrolytic cell (3) left part upside and base (1) and be used for collecting box (4) of the camera lens shell that the coating film is accomplished, characterized in that, unloading mechanism (5) and slewing mechanism (6), mounting bracket (2) downside is equipped with unloading mechanism (5) that drive the camera lens shell and remove, be equipped with slewing mechanism (6) that drive the camera lens shell and rotate on unloading mechanism (5); the blanking mechanism (5) comprises a first mounting block (51), supporting rods (52), guide rods (53) and electric push rods (54), the guide rods (53) are arranged on the front side and the rear side of the mounting frame (2) in a sliding mode, the first mounting block (51) is connected between the upper sides of the two guide rods (53), the first mounting block (51) is in contact with the mounting frame (2), five supporting rods (52) are uniformly arranged on the left side of the lower portion of the first mounting block (51), the electric push rods (54) for driving the lens shell to move downwards are arranged on the front side and the rear side of the mounting frame (2), and the two electric push rods (54) are connected with the first mounting block (51) in a telescopic mode; the rotating mechanism (6) comprises rollers (61), isolating boxes (62), gear motors (63) and belts (64), wherein the isolating boxes (62) are arranged on the lower sides of the supporting rods (52), the number of the isolating boxes (62) is five, the rollers (61) for driving the lens shell to rotate are rotatably arranged on the upper left sides of the isolating boxes (62), the rollers (61) are rotatably connected with the supporting rods (52) on the same side, the number of the rollers (61) is five, the gear motors (63) are arranged on the lower right sides in the isolating boxes (62), the number of the gear motors (63) is five, the belt (64) is wound between the output shafts of the gear motors (63) and the rollers (61) on the same side through driving wheels, and the number of the belts (64) is five; the automatic discharging device is characterized by further comprising a discharging mechanism (7) for realizing automatic discharging, wherein the discharging mechanism (7) comprises a first piston rod (71), a second piston rod (711), a hydraulic tank (72), a connecting pipe (73), a third piston rod (74), a first spring (75), a first hinging block (76), a first torsion spring (77) and a second hinging block (78), the right side of the mounting frame (2) is provided with the connecting pipe (73), four first piston rods (71) are uniformly and slidably arranged on the left side of the connecting pipe (73), the first piston rods (71) are slidably connected with the electrolytic tank (3), the second piston rods (711) are slidably arranged on the front side and the rear side of the connecting pipe (73), the second piston rods (711) are slidably connected with the electrolytic tank (3), the front side and the rear side of the mounting frame (2) are respectively provided with the hydraulic tank (72), the third piston rods (74) are slidably arranged between the lower sides of the two hydraulic tanks (72), the front side and the rear side of the upper part of the third piston rods (74) are slidably arranged on the first springs (74), the first piston rods (74) are respectively hinged with the first piston rods (74), the left side and the right side of the first hinging block (76) are connected with a first torsion spring (77) between the third piston rod (74), the first torsion spring (77) is wound on the first hinging block (76), the first torsion spring (77) is four, the right sides of the two guide rods (53) are all hinged with second hinging blocks (78), and the second hinging blocks (78) are contacted with the first hinging blocks (76) on the same side after moving.

2. The anti-oxidation coating device for the optical lens shell according to claim 1, further comprising a buffer mechanism (8), wherein the buffer mechanism (8) comprises a buffer plate (81) and second springs (82), four second springs (82) are respectively arranged on the front side and the rear side of the inner bottom of the collecting box (4), eight second springs (82) are connected between the upper sides of the eight second springs (82), the buffer plate (81) is slidably connected with the collecting box (4), and nine water diversion grooves (83) are uniformly formed in the buffer plate (81).

3. The anti-oxidation coating device for the optical lens shell according to claim 2, further comprising a feeding mechanism (9) for realizing automatic feeding, wherein the feeding mechanism (9) comprises a second mounting block (91), a first rotating shaft (92), a first connecting rod (93), a second connecting rod (94), a third connecting rod (95), a hinging rod (96), a second torsion spring (97), a one-way gear (98), a rack (99) and a third torsion spring (910), the second mounting block (91) is arranged on the left side of the upper part of the mounting frame (2), a first rotating shaft (92) is rotatably arranged on the second mounting block (91), first connecting rods (93) are respectively arranged on the front side and the rear side of the first rotating shaft (92), the first connecting rods (93) are in contact with the second mounting block (91), a second connecting rod (94) is rotatably arranged between the left sides of the two first connecting rods (93), the front side and the rear side of the left side of the second mounting block (91) are respectively rotatably provided with a third connecting rod (95), the third connecting rod (95) is rotatably connected with the second connecting rod (94), the second connecting rod (94) is uniformly hinged with the second torsion spring (96) on the front side and the right side of the second connecting rod (96), the second connecting rod (96) is rotatably connected with the front side and the second torsion spring (96), both sides all are equipped with one-way gear (98) around first pivot (92), and both sides all are equipped with rack (99) around first installation piece (51) upper portion, and rack (99) remove the back and contact with homonymous one-way gear (98), all are connected with third torsional spring (910) between both sides around first pivot (92) and second installation piece (91), and third torsional spring (910) are around on first pivot (92).

4. An anti-oxidation coating device for an optical lens housing as claimed in claim 3, further comprising a limiting mechanism (10) for clamping the lens housing, wherein the limiting mechanism (10) comprises a second rotating shaft (101), limiting rods (102) and fourth torsion springs (103), the second rotating shaft (101) is rotatably arranged on the left side of the supporting rod (52), the second rotating shaft (101) is provided with five limiting rods (102), the fourth torsion springs (103) are respectively connected between the front side and the rear side of the limiting rods (102) and the adjacent supporting rod (52), the number of the fourth torsion springs (103) is ten, and the fourth torsion springs (103) are wound on the second rotating shaft (101).

5. The anti-oxidation coating device for the optical lens shell according to claim 1, wherein six through holes are uniformly formed on the upper side of the right part of the electrolytic cell (3).