CN114473763A

CN114473763A - Cambered surface burnishing device is used in processing of optical lens shell

Info

Publication number: CN114473763A
Application number: CN202210151085.8A
Authority: CN
Inventors: 曾婷
Original assignee: Shangrao Xingjieda Photoelectric Technology Co ltd
Current assignee: Dongguan Beixiang Industrial Co ltd
Priority date: 2022-02-14
Filing date: 2022-02-14
Publication date: 2022-05-13
Anticipated expiration: 2042-02-14
Also published as: CN114473763B

Abstract

The invention relates to a cambered surface polishing device, in particular to a cambered surface polishing device for processing an optical lens shell. The invention provides a cambered surface polishing device for processing an optical lens shell, which can enhance the smoothness of a cambered surface. The utility model provides an optical lens shell processing is with cambered surface burnishing device, is equipped with the stabilizer blade including stabilizer blade, framework, first support, cylinder, polishing strip and second support etc. the framework bottom is equipped with the stabilizer blade, and the left and right sides all is equipped with first support in the framework, and equal rotary type is equipped with the cylinder between both sides and the first support lower part around between the first support upper portion, and the wraparound has the polishing strip between the cylinder, and the first support middle part outside all is equipped with the second support. The rotatory piece anticlockwise rotation of left and right sides drives optical lens shell anticlockwise rotation, so, the contact surface motion direction of optical lens shell bottom and polishing belt top is opposite for optical lens shell cambered surface polishing is more smooth.

Description

Cambered surface burnishing device is used in processing of optical lens shell

Technical Field

The invention relates to a cambered surface polishing device, in particular to a cambered surface polishing device for machining an optical lens shell.

Background

The optical lens housing is made of transparent optical materials such as glass and the like and has one or more curved surfaces, the edges of the optical lens housing are rough after the optical lens housing is produced, and in order to enable the optical lens housing to be put into market for use, the edges of the curved surfaces of the optical lens housing are required to be subjected to deep polishing processing so as to meet various requirements of the market.

Patent application CN213106041U, published as 20210504, discloses a polishing device for processing an optical lens shell, wherein one side of the surface of a base platform is fixedly provided with a first electric push rod, the other side of the surface of the base platform is fixedly provided with a second electric push rod, the piston rod ends of the first electric push rod and the second electric push rod are fixedly provided with a fixed plate, the upper surface of the fixed plate is fixedly provided with a water tank, one side of the water tank is fixedly communicated with a water pipe, one end of the water pipe, far away from the water tank, is fixedly provided with a nozzle, the lower surface of the fixed plate is fixedly provided with a motor, the output shaft end of the motor is fixedly provided with a polishing disk, the surface of the base platform is fixedly provided with an H-shaped supporting seat, the surface of the base platform is provided with a water tank, the device places optical lenses on the H-shaped supporting seat, can avoid various risks brought by the fixation of a mechanical clamping jaw, avoids loss, and is provided with the water tank, the polishing dust remover can polish and remove dust on one side of the optical lens, and reduces the harm of the dust to human bodies. However, the device only polishes the optical lens shell through the polishing disc in a unidirectional motion, and the polishing effect is not good.

In view of the above, it is important to develop a new cambered surface polishing device for processing an optical lens housing, which can enhance the smoothness of a cambered surface, so as to enhance the processing effect of the optical lens housing.

Disclosure of Invention

The invention aims to overcome the defect that the polishing and grinding mode of the existing device has poor grinding effect, and provides an arc surface polishing device for processing an optical lens shell, which can enhance the smoothness of an arc surface.

The technical scheme is as follows: the utility model provides an optical lens shell is cambered surface burnishing device for processing, including the stabilizer blade, the framework, first support, the cylinder, the polishing belt, the second support, the gyro wheel, actuating mechanism and reversal mechanism, the framework bottom is equipped with the stabilizer blade, stabilizer blade top bilateral symmetry is connected with first support, first support is located the framework, equal rotary type is equipped with the cylinder between both sides and the first support lower part around between the first support upper portion, the round joint has the polishing belt between the cylinder, first support middle part outside all is equipped with the second support, second support upper portion is equipped with the gyro wheel to even rotary type in the past after to, the gyro wheel all with polishing belt top contact, be equipped with actuating mechanism between the cylinder left end of left side and lower part in the framework, be equipped with reversal mechanism between the cylinder right-hand member of preceding lower part and lower part in the framework.

As an improvement of the scheme, the first sliding rod, the first sliding block, the driving motor, the first U-shaped rod and the first T-shaped rod form a driving mechanism, the first sliding rod is arranged on the left side in the frame body, the first sliding block is arranged in the middle of the right side of the first sliding rod in a sliding mode, the driving motor is arranged at the bottom of the first sliding block, the first U-shaped rod is arranged at the end of an output shaft of the driving motor, the first T-shaped rod is arranged at the left end of a roller at the lower portion of the first sliding rod, and the first T-shaped rod is in contact fit with the first U-shaped rod.

As an improvement of the proposal, a double-shaft motor, a first threaded rod, a first threaded sleeve, a rotating block, a first transmission component, a second T-shaped rod, a second sliding block, a third bracket, a second U-shaped rod and a second transmission component form a reversal mechanism, the double-shaft motor is arranged in the middle of the front lower part in the frame body, the output shaft end parts of the left side and the right side of the double-shaft motor are respectively provided with the first threaded rod, the first threaded sleeve is arranged on the first threaded rod in a threaded manner, the upper parts of the first sliding block and the second sliding block are respectively provided with the rotating block in a rotating manner, the first transmission component is wound between the rotating block on the left side and the first U-shaped rod, the right end of a roller on the lower part is provided with the second T-shaped rod, the second sliding rod is arranged on the right side in the frame body, the second sliding block is arranged on the left side of the second sliding rod, the second sliding block and the first sliding block are respectively connected with the first threaded sleeve on the same side, the rear lower part of the second sliding block is provided with the third bracket, and a second U-shaped rod is rotatably arranged at the lower part of the third support, the second U-shaped rod is in contact fit with the second T-shaped rod, and a second transmission assembly is connected between the rotating block on the right side and the second U-shaped rod in a winding manner.

As the improvement of above-mentioned scheme, still including preventing excursion mechanism, the pressurization case, the second threaded rod, the second thread bush, the gasbag, third slide bar and first spring constitute prevents excursion mechanism, rotatory piece middle part all runs through the formula and is equipped with the pressurization case, both sides all are equipped with the third slide bar about the pressurization incasement, it is connected with the second threaded rod all to slidingtype between two adjacent third slide bars, first slider and second slider top all are equipped with the second thread bush, the second threaded rod and the second thread bush threaded connection of homonymy, pressurization incasement inner all communicates there is the gasbag, the third slide bar outside all is around there being first spring, first spring both ends respectively with second threaded rod and third slide bar connection.

As the improvement of above-mentioned scheme, still including dust fall mechanism, storage water tank, screw cap, shower nozzle and valve constitute dust fall mechanism, are equipped with the storage water tank between the upper portion left and right sides behind in the frame, and storage water tank left end screw thread formula is equipped with the screw cap, and bottom intercommunication has the shower nozzle in the middle of the storage water tank, and upper portion rotary type is equipped with the valve behind the shower nozzle.

As the improvement of the scheme, the water storage tank water-saving valve further comprises a pushing mechanism, a sliding sleeve, a pushing block, a second spring, a first torsion spring and the pushing block form the pushing mechanism, the sliding sleeve is arranged on the left portion of the water storage tank, the pushing block is arranged on the lower portion of the sliding sleeve in a sliding mode, the right rear end of the pushing block is in contact fit with a valve, the second spring is connected between the pushing block and the sliding sleeve, the first torsion spring is wound on the valve, two ends of the first torsion spring are respectively connected with the valve and the water storage tank, the pushing block is arranged on the upper portion of the first sliding block, and the left front end of the pushing block is in contact fit with the pushing block.

As an improvement of the proposal, the utility model also comprises a wiping mechanism, a first shifting block, a slide rail, a third spring and a slide rod, wipe the piece, the fourth spring, second shifting block and second torsion spring constitute and clean the mechanism, rotatory piece front side all is equipped with first shifting block, the top left and right sides all is equipped with the slide rail in the framework, the equal slidingtype in slide rail front side is equipped with the slide bar, all around having the third spring on the slide rail, the third spring both ends are connected with slide rail and slide bar respectively, sliding connection has the piece of wiping between the slide bar lower part, all around having the fourth spring on the slide bar, the fourth spring both ends respectively with the slide bar with clean the piece and be connected, the equal rotary type in slide bar bottom is equipped with the second shifting block, first shifting block backward rotation all can contact with the second shifting block, the second shifting block left and right sides all around having second torsion spring, second torsion spring both ends are connected with slide bar and second shifting block respectively.

As an improvement of the scheme, the first sliding rod and the second sliding rod are both T-shaped.

By adopting the technical scheme, the invention at least has the following advantages:

1. the rotating blocks on the left side and the right side rotate anticlockwise to drive the optical lens shell to rotate anticlockwise, so that the moving direction of a contact surface of the bottom of the optical lens shell and the top of the polishing belt is opposite, and the cambered surface of the optical lens shell is polished more smoothly;

2. the air bag expanded by air blowing clamps and limits the hollow part in the middle of the optical lens shell, so that the optical lens shell is prevented from shifting in the polishing process, and the thrown finished product is irregular;

3. when polishing operation is carried out, cold water can be sprayed out on the optical lens shell through the spray head, so that the effects of cooling and dust settling while polishing are realized, chips are prevented from splashing, and the polishing smoothness can be improved;

4. the pushing block pushes the valve to rotate anticlockwise to open through the pushing block, and the first torsion spring resets to drive the valve to rotate clockwise to close, so that the effects of automatically controlling water spraying and water stopping are achieved, and the operation is simple and efficient;

5. the piece of wiping contacts with anticlockwise rotation's optical lens shell top, and the direction of motion is opposite, so, can reach the high efficiency and wipe the clastic effect of optical lens shell cambered surface for the optical lens shell is more smooth.

Drawings

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

FIG. 2 is a schematic view of a first partial body structure according to the present invention.

FIG. 3 is a schematic view of a second partial body structure according to the present invention.

Fig. 4 is a perspective view of a third embodiment of the present invention.

Fig. 5 is a schematic perspective view of the driving mechanism of the present invention.

Fig. 6 is a partial perspective view of the driving mechanism of the present invention.

Fig. 7 is a schematic perspective view of a first reversing mechanism according to the present invention.

Fig. 8 is a schematic perspective view of a second reversing mechanism according to the present invention.

Fig. 9 is a schematic perspective view of the anti-shift mechanism of the present invention.

Fig. 10 is a schematic view of a first partial body structure of the anti-deviation mechanism of the present invention.

Fig. 11 is a schematic view of a second partial structure of the anti-shift mechanism of the present invention.

Fig. 12 is a schematic perspective view of the dustfall mechanism of the present invention.

Fig. 13 is a partial perspective view of the dustfall mechanism of the present invention.

Fig. 14 is a schematic perspective view of a first pushing mechanism according to the present invention.

Fig. 15 is a schematic perspective view of a second pushing mechanism of the present invention.

Fig. 16 is a schematic perspective view of a first wiping mechanism according to the present invention.

Fig. 17 is a schematic perspective view of a second wiping mechanism according to the present invention.

Number designation in the figures: 1. a foot, 2, a frame, 3, a first bracket, 4, a roller, 5, a polishing belt, 6, a second bracket, 7, a roller, 8, a driving mechanism, 81, a first sliding rod, 82, a first sliding block, 83, a driving motor, 84, a first U-shaped rod, 85, a first T-shaped rod, 9, a reversing mechanism, 91, a double-shaft motor, 92, a first threaded rod, 93, a first threaded sleeve, 94, a rotating block, 95, a first transmission component, 96, a second T-shaped rod, 97, a second sliding rod, 98, a second sliding block, 99, a third bracket, 910, a second U-shaped rod, 911, a second transmission component, 10, an anti-deviation mechanism, 101, a pressurizing box, 102, a second threaded rod, 103, a second threaded sleeve, 104, an air bag, 105, a third sliding rod, 106, a first spring, 11, a dust falling mechanism, 111, a water storage tank, 112, a threaded cover, 113, a spray head, 114, a valve, 12, a pushing mechanism, 121. a sliding sleeve, 122, a pushing block, 123, a second spring, 124, a first torsion spring, 125, a pushing block, 13, a wiping mechanism, 131, a first shifting block, 132, a sliding rail, 133, a third spring, 134, a sliding rod, 135, a wiping block, 136, a fourth spring, 137, a second shifting block, 138, a second torsion spring.

Detailed Description

The above-described scheme is further illustrated below with reference to specific examples. It should be understood that these examples are for illustrative purposes and are not intended to limit the scope of the present application. The conditions used in the examples may be further adjusted according to the conditions of the particular manufacturer, and the conditions not specified are generally the conditions in routine experiments.

Example 1

A cambered surface polishing device for processing an optical lens shell is disclosed, as shown in figures 1, 2, 3 and 4, and comprises support legs 1, a frame body 2, a first support 3, rollers 4, a polishing belt 5, a second support 6, rollers 7, a driving mechanism 8 and a reversing mechanism 9, wherein a rectangular groove is formed in the middle of the front upper part of the frame body 2, the support legs 1 are arranged at the bottom of the frame body 2, the top parts of the support legs 1 are bilaterally and symmetrically connected with the first support 3, the first support 3 is positioned in the frame body 2, the rollers 4 are respectively arranged between the front side and the rear side of the upper part of the first support 3 and between the lower part of the first support 3 through bearings, the polishing belt 5 is connected between the rollers 4 in a winding manner, the second support 6 is arranged on the outer side of the middle part of the first support 3 in a welding manner, the rollers 7 are uniformly arranged on the upper part of the second support 6 through the bearings from front to rear, the rollers 7 are respectively contacted with the top part of the polishing belt 5, the driving mechanism 8 is arranged between the left end of the rollers 4 at the left side and the lower part in the frame body 2, a reversing mechanism 9 is provided between the front lower part of the frame 2 and the right end of the lower roller 4.

As shown in fig. 5 and 6, the driving mechanism 8 includes a first sliding rod 81, a first sliding block 82, a driving motor 83, a first U-shaped rod 84 and a first T-shaped rod 85, the first sliding rod 81 is welded on the left side in the frame body 2, the first sliding rod 81 is T-shaped, the first sliding block 82 is slidably arranged in the middle of the right side of the first sliding rod 81, the driving motor 83 is bolted to the bottom of the first sliding block 82, the first U-shaped rod 84 is arranged at the end of an output shaft of the driving motor 83 through a coupler, the first T-shaped rod 85 is arranged at the left end of the lower roller 4 through a key connection mode, and the first T-shaped rod 85 is in contact fit with the first U-shaped rod 84.

As shown in fig. 7 and 8, the reversing mechanism 9 includes a double-shaft motor 91, a first threaded rod 92, a first threaded sleeve 93, a rotating block 94, a first transmission assembly 95, a second T-shaped rod 96, a second sliding rod 97, a second sliding block 98, a third bracket 99, a second U-shaped rod 910 and a second transmission assembly 911, the double-shaft motor 91 is mounted in the middle of the front lower portion in the frame body 2 by means of bolts, the first threaded rod 92 is disposed at the end portion of the output shaft at the left and right sides of the double-shaft motor 91, the first threaded sleeve 93 is disposed on the first threaded rod 92 in a threaded manner, the rotating block 94 is disposed at the upper portion of each of the first sliding block 82 and the second sliding block 98 by a bearing, the first transmission assembly 95 is wound between the rotating block 94 at the left side and the first U-shaped rod 84, the first transmission assembly 95 is composed of two belt pulleys and a belt, the two belt pulleys are disposed on the rotating block 94 at the left side and the first U-shaped rod 84 respectively, the belt is wound between the two belt pulleys, the right end of the lower roller 4 is keyed with a second T-shaped rod 96, a second sliding rod 97 is arranged on the right side in the frame body 2, the second sliding rod 97 is also T-shaped, a second sliding block 98 is arranged on the left side of the second sliding rod 97 in a sliding mode, the second sliding block 98 and the first sliding block 82 are respectively connected with the first threaded sleeve 93 on the same side, a third support 99 is arranged on the rear lower portion of the second sliding block 98, a second U-shaped rod 910 is rotatably arranged on the lower portion of the third support 99, the second U-shaped rod 910 is in contact fit with the second T-shaped rod 96, a second transmission assembly 911 is wound between the right rotating block 94 and the second U-shaped rod 910, the second transmission assembly 911 is also composed of two belt pulleys and a belt, the two belt pulleys are respectively arranged on the right rotating block 94 and the second U-shaped rod 910, and the belt is wound between the two belt pulleys.

The cambered surface polishing device for processing the optical lens shell can be used when the cambered surface of the optical lens shell needs to be polished, firstly, people put the optical lens shell to be polished on the top of a polishing belt 5 through a rectangular groove and locate between rollers 7, then, a double-shaft motor 91 is started to control output shafts on two sides of the double-shaft motor 91 to rotate forwards, so that a first threaded sleeve 93 is driven to move inwards through a first threaded rod 92, the first threaded sleeve 93 on the left side drives a first sliding block 82 to slide rightwards, the first sliding block 82 drives a driving motor 83 and a rotating block 94 on the left side to move rightwards, the driving motor 83 drives the first U-shaped rod 84 to move rightwards, the first U-shaped rod 84 and the rotating block 94 on the left side drive a first transmission component 95 to move rightwards together, the first threaded sleeve 93 on the right side drives a second sliding block 98 to slide leftwards, the second sliding block 98 drives a third bracket 99 and the rotating block 94 on the right side to move leftwards, the third bracket 99 drives the second U-shaped rod 910 to move leftwards, the second U-shaped rod 910 and the right-hand rotary block 94 drive the second transmission assembly 911 to move leftwards, so that the two rotary blocks 94 approach to contact with the optical lens housing in opposite directions, the first U-shaped rod 84 and the second U-shaped rod 910 respectively contact with the first T-shaped rod 85 and the second T-shaped rod 96, the dual-shaft motor 91 is turned off, the driving motor 83 is started, the output shaft of the driving motor 83 rotates to drive the first U-shaped rod 84 to rotate, the first U-shaped rod 84 drives the first T-shaped rod 85 to rotate anticlockwise to drive the roller 4 to rotate anticlockwise to drive the second T-shaped rod 96 and the polishing belt 5 to rotate anticlockwise, meanwhile, the first U-shaped rod 84 drives the left-hand rotary block 94 to rotate through the first transmission assembly 95, the second T-shaped rod 96 drives the second U-shaped rod 910 to rotate anticlockwise, the second U-shaped rod 910 drives the right-hand rotary block 94 to rotate anticlockwise through the second transmission assembly 911, the rotating blocks 94 on the left and right sides rotate anticlockwise to drive the optical lens housing to rotate anticlockwise, so that the bottom of the optical lens housing and the contact surface on the top of the polishing belt 5 move in opposite directions, the optical lens housing is polished more smoothly, after polishing is completed, the driving motor 83 is turned off, and the output shafts on the two sides of the double-shaft motor 91 are turned on again and controlled to rotate reversely, so that the first threaded rod 92 drives the first threaded sleeve 93 to move outwards, the first threaded sleeve 93 on the left side drives the first sliding block 82 to slide leftwards, the first sliding block 82 drives the driving motor 83 and the rotating block 94 on the left side to move leftwards, the driving motor 83 drives the first U-shaped rod 84 to move leftwards, the first U-shaped rod 84 and the rotating block 94 on the left side together drive the first transmission assembly 95 to move leftwards, the first threaded sleeve 93 on the right side drives the second sliding block 98 to slide rightwards, the second sliding block 98 drives the third bracket 99 and the rotating block 94 on the right side to move rightwards, the third bracket 99 drives the second U-shaped rod 910 to move rightwards, the second U-shaped rod 910 and the right rotary block 94 together drive the second transmission assembly 911 to move rightwards, so that the two rotary blocks 94 are away from the optical lens housing, the first U-shaped rod 84 and the second U-shaped rod 910 are not in contact with the first T-shaped rod 85 and the second T-shaped rod 96 respectively, finally the dual-shaft motor 91 is turned off, and the polished optical lens housing is taken out through the rectangular groove.

Example 2

On the basis of the embodiment 1, as shown in fig. 4, 9, 10 and 11, the anti-deviation mechanism 10 further includes an anti-deviation mechanism 10, the anti-deviation mechanism 10 includes a pressurizing box 101, a second threaded rod 102, a second threaded sleeve 103, an air bag 104, a third sliding rod 105 and a first spring 106, the middle portion of the rotating block 94 is provided with the pressurizing box 101 in a penetrating manner, the upper and lower sides of the inside of the pressurizing box 101 are provided with the third sliding rod 105, the second threaded rod 102 is connected between two adjacent third sliding rods 105 in a sliding manner, the tops of the first slider 82 and the second slider 98 are provided with the second threaded sleeve 103, the second threaded rod 102 and the second threaded sleeve 103 on the same side are connected in a threaded manner, the inner end of the pressurizing box 101 is communicated with the air bag 104, the outer side of the third sliding rod 105 is wound with the first spring 106, and two ends of the first spring 106 are respectively connected with the second threaded rod 102 and the third sliding rod 105.

The first sliding block 82 and the second sliding block 98 move left and right to respectively drive the second threaded sleeves 103 on the left and right sides to move left and right, the rotating block 94 moves left and right to drive the pressurizing box 101 on the rotating block to move left and right, so as to drive the air bag 104 and the third sliding rod 105 to move left and right, the third sliding rod 105 drives the second threaded rod 102 and the first spring 106 to move left and right, in addition, when the rotating block 94 rotates anticlockwise, the rotating block 94 enables the pressurizing box 101, the second threaded rod 102, the air bag 104, the third sliding rod 105 and the first spring 106 to rotate anticlockwise together, under the matching of the threads of the second threaded sleeve 103, the second threaded rod 102 slides inwards along the third sliding rod 105 while rotating, the first spring 106 is stretched, the second threaded rod 102 pushes the gas in the pressurizing box 101 into the air bag 104, so that the air bag 104 expands by blowing gas, the air bag 104 clamps and limits the hollow part in the middle of the optical lens shell, thereby preventing the optical lens shell from deviating in the polishing process, thereby it is irregular to lead to the finished product of throwing out, after finishing polishing, the output shaft of control driving motor 83 reverses earlier, driving motor 83's output shaft drives first U-shaped pole 84 and reverses, first U-shaped pole 84 drives left rotation piece 94 through first transmission subassembly 95 and clockwise rotates, thereby make pressure tank 101, second threaded rod 102, gasbag 104, third slide bar 105 and first spring 106 clockwise rotation together, under the cooperation of second thread bush 103 screw thread, outwards slides along third slide bar 105 when second threaded rod 102 clockwise turning, first spring 106 resets, second threaded rod 102 is with the gas extraction in the gasbag 104 in the pressure tank 101, make gasbag 104 lose heart flat, gasbag 104 loosens the optical lens shell, make things convenient for people to take out the optical lens shell that the polishing was accomplished.

As shown in fig. 4, 12 and 13, the dust suppression device further includes a dust suppression mechanism 11, the dust suppression mechanism 11 includes a water storage tank 111, a threaded cap 112, a nozzle 113 and a valve 114, the water storage tank 111 is installed between the left side and the right side of the upper rear portion in the frame 2 in a bolt manner, the frame 2 is passed through the left side of the water storage tank 111, the threaded cap 112 is arranged at the left end of the water storage tank 111 in a threaded manner, the nozzle 113 is communicated with the bottom of the middle of the water storage tank 111, and the valve 114 is rotatably arranged at the upper rear portion of the nozzle 113.

People unscrew threaded cover 112, screw up threaded cover 112 after pouring into the cold water of capacity into storage water tank 111, stretch out the hand through the rectangular channel afterwards and get into the internal rotation of framework 2 and open valve 114, cold water passes through shower nozzle 113 and outwards spouts, so when polishing the operation, cold water can spray on the optical lens shell, realize polishing the effect of cooling dust fall on one side, avoid the piece to splash, and can improve the smoothness of polishing, accomplish the polishing back, people's antiport closes valve 114.

As shown in fig. 4, 14 and 15, the water storage tank further includes a pushing mechanism 12, the pushing mechanism 12 includes a sliding sleeve 121, a pushing block 122, a second spring 123, a first torsion spring 124 and a pushing block 125, the sliding sleeve 121 is fixedly disposed at the left portion of the water storage tank 111, the pushing block 122 is slidably disposed at the lower portion of the sliding sleeve 121, the right rear end of the pushing block 122 is in contact with the valve 114, the second spring 123 is connected between the pushing block 122 and the sliding sleeve 121, the first torsion spring 124 is wound on the valve 114, two ends of the first torsion spring 124 are respectively connected with the valve 114 and the water storage tank 111, the pushing block 125 is disposed at the upper portion of the first sliding block 82, and the left front end of the pushing block 122 is in contact with the pushing block 125.

The first sliding block 82 slides left and right to drive the pushing block 125 to move left and right, when the pushing block 125 slides right to contact with the pushing block 122, the pushing block 125 pushes the valve 114 to rotate counterclockwise through the pushing block 122 to open, the second spring 123 is compressed by the pushing block 122, the first torsion spring 124 is deformed in a torsional mode, when the pushing block 125 slides left to be separated from the pushing block 122, the second spring 123 resets to drive the pushing block 122 to slide left, and the first torsion spring 124 resets to drive the valve 114 to rotate clockwise to close, so that the effects of automatically controlling water spraying and water stopping are achieved.

As shown in fig. 4, 16 and 17, the cleaning device 13 further comprises a cleaning mechanism 13, the cleaning mechanism 13 comprises a first shifting block 131, a sliding rail 132, a third spring 133, a sliding rod 134, a cleaning block 135, a fourth spring 136, a second shifting block 137 and a second torsion spring 138, the first shifting block 131 is fixedly connected to the front side of the rotating block 94, the sliding rails 132 are welded to the left and right sides of the top portion of the frame 2, the sliding rod 134 is slidably arranged on the front side of the sliding rail 132, the third spring 133 is wound on the sliding rail 132, both ends of the third spring 133 are respectively connected to the sliding rail 132 and the sliding rod 134, the cleaning block 135 is slidably connected between the lower portions of the sliding rods 134, the fourth spring 136 is wound on the sliding rod 134, both ends of the fourth spring 136 are respectively connected to the sliding rod 134 and the cleaning block 135, the second shifting block 137 is rotatably arranged at the bottom of the sliding rod 134, the first shifting block 131 can be in contact with the second shifting block 137 in a backward rotation mode, the second shifting block 137 is wound on both sides of the left and right sides of the second shifting block 137, both ends of the second torsion spring 138 are connected with the sliding rod 134 and the second dial 137, respectively.

The rotating block 94 rotates counterclockwise to drive the first shifting block 131 to rotate counterclockwise to contact with the second shifting block 137, the first shifting block 131 drives the sliding rod 134 to move backward together through the second shifting block 137, the third spring 133 is compressed, the sliding rod 134 drives the wiping block 135 to move backward, when the third spring 133 is compressed to the limit, the sliding rod 134 stops moving, at this time, the first shifting block 131 drives the second shifting block 137 to swing backward, the second torsion spring 138 is twisted and deformed, when the first shifting block 131 rotates counterclockwise and is separated from the second shifting block 137, the second torsion spring 138 resets to drive the second shifting block 137 to swing forward, and the third spring 133 resets to drive the sliding rod 134 to slide forward, thereby driving the wiping block 135 to move forward, the wiping block 135 contacts with the top of the optical lens housing rotating counterclockwise, and the moving direction is opposite, so that the effect of efficiently wiping the arc-face chippings of the optical lens housing can be achieved, make optical lens shell more smooth, and in the process of wiping, under fourth spring 136 elastic fit, wipe piece 135 and can slide from top to bottom according to the unsmooth condition adaptability of optical lens shell cambered surface.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by the present specification, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. A cambered surface polishing device for processing an optical lens shell comprises support legs (1), a frame body (2), a first support (3), rollers (4), a polishing belt (5), a second support (6) and rollers (7), wherein the support legs (1) are arranged at the bottom of the frame body (2), the first support (3) is symmetrically connected to the top of each support leg (1) in a bilateral mode, the first support (3) is positioned in the frame body (2), the rollers (4) are rotatably arranged on the front side and the rear side between the upper portions of the first support (3) and on the lower portion of the first support (3), the polishing belt (5) is wound between the rollers (4), the second support (6) is arranged on the outer side of the middle portion of the first support (3), the rollers (7) are uniformly and rotatably arranged on the upper portions of the second support (6) from front to rear, the rollers (7) are in contact with the top of the polishing belt (5), and the cambered surface polishing device is characterized by further comprising a driving mechanism (8) and a reversing mechanism (9), a driving mechanism (8) is arranged between the left side in the frame body (2) and the left end of the roller (4) at the lower part, and a reversing mechanism (9) is arranged between the front lower part in the frame body (2) and the right end of the roller (4) at the lower part.

2. The cambered surface polishing device for processing the optical lens shell as claimed in claim 1, wherein the first sliding rod (81), the first sliding block (82), the driving motor (83), the first U-shaped rod (84) and the first T-shaped rod (85) form a driving mechanism (8), the first sliding rod (81) is arranged on the left side in the frame (2), the first sliding block (82) is arranged in the middle of the right side of the first sliding rod (81) in a sliding manner, the driving motor (83) is arranged at the bottom of the first sliding block (82), the first U-shaped rod (84) is arranged at the end of an output shaft of the driving motor (83), the first T-shaped rod (85) is arranged at the left end of the lower roller (4), and the first T-shaped rod (85) is in contact fit with the first U-shaped rod (84).

3. The cambered surface polishing device for processing the optical lens shell as recited in claim 2, wherein a reversing mechanism (9) is formed by a double-shaft motor (91), a first threaded rod (92), a first threaded sleeve (93), a rotating block (94), a first transmission component (95), a second T-shaped rod (96), a second sliding rod (97), a second sliding block (98), a third bracket (99), a second U-shaped rod (910) and a second transmission component (911), the double-shaft motor (91) is arranged in the middle of the front lower portion in the frame body (2), the first threaded rods (92) are arranged at the end portions of output shafts at the left side and the right side of the double-shaft motor (91), the first threaded sleeve (93) is arranged on the first threaded rod (92) in a threaded manner, the rotating block (94) is arranged at the upper portions of the first sliding block (82) and the second sliding block (98) in a rotating manner, the first transmission component (95) is connected between the rotating block (94) at the left side and the first U-shaped rod (84) in a winding manner, the right end of a roller (4) on the lower portion is provided with a second T-shaped rod (96), the right side in a frame body (2) is provided with a second sliding rod (97), the left side of the second sliding rod (97) is provided with a second sliding block (98) in a sliding mode, the second sliding block (98) and the first sliding block (82) are respectively connected with a first threaded sleeve (93) on the same side, the rear lower portion of the second sliding block (98) is provided with a third support (99), the lower portion of the third support (99) is rotatably provided with a second U-shaped rod (910), the second U-shaped rod (910) is in contact fit with the second T-shaped rod (96), and a second transmission assembly (911) is wound between a rotating block (94) on the right side and the second U-shaped rod (910).

4. The cambered surface polishing device for processing the optical lens shell as recited in claim 3, further comprising an anti-deviation mechanism (10), wherein the anti-deviation mechanism (10) is composed of a pressure box (101), a second threaded rod (102), a second threaded sleeve (103), an air bag (104), a third sliding rod (105) and a first spring (106), the pressure box (101) is arranged in the middle of the rotary block (94) in a penetrating manner, the third sliding rods (105) are arranged on the upper side and the lower side in the pressure box (101), the second threaded rod (102) is connected between every two adjacent third sliding rods (105) in a sliding manner, the second threaded sleeve (103) is arranged on the top of each of the first sliding block (82) and the second sliding block (98), the second threaded rod (102) and the second threaded sleeve (103) on the same side are connected in a threaded manner, the inner end of each pressure box (101) is communicated with the air bag (104), and the first spring (106) is wound on the outer side of each third sliding rod (105), two ends of the first spring (106) are respectively connected with the second threaded rod (102) and the third sliding rod (105).

5. The arc polishing device for processing the optical lens housing as claimed in claim 4, further comprising a dust-settling mechanism (11), wherein the water storage tank (111), the threaded cap (112), the nozzle (113) and the valve (114) form the dust-settling mechanism (11), the water storage tank (111) is arranged between the left side and the right side of the upper rear portion in the frame (2), the threaded cap (112) is arranged at the left end of the water storage tank (111) in a threaded manner, the nozzle (113) is communicated with the bottom of the middle of the water storage tank (111), and the valve (114) is rotatably arranged at the upper rear portion of the nozzle (113).

6. The arc polishing device for processing the optical lens shell as claimed in claim 5, further comprising a pushing mechanism (12), wherein the pushing mechanism (12) is composed of a sliding sleeve (121), a pushing block (122), a second spring (123), a first torsion spring (124) and a pushing block (125), the sliding sleeve (121) is arranged at the left part of the water storage tank (111), the pushing block (122) is arranged at the lower part of the sliding sleeve (121) in a sliding manner, the right rear end of the pushing block (122) is in contact fit with the valve (114), the second spring (123) is connected between the pushing block (122) and the sliding sleeve (121), the first torsion spring (124) is wound on the valve (114), two ends of the first torsion spring (124) are respectively connected with the valve (114) and the water storage tank (111), the pushing block (125) is arranged at the upper part of the first sliding block (82), and the left front end of the pushing block (122) is in contact fit with the pushing block (125).

7. The cambered surface polishing device for processing the optical lens shell according to claim 6, further comprising a wiping mechanism (13), wherein the wiping mechanism (13) is composed of a first shifting block (131), a slide rail (132), a third spring (133), a slide rod (134), a wiping block (135), a fourth spring (136), a second shifting block (137) and a second torsion spring (138), the first shifting block (131) is arranged on the front side of the rotating block (94), the slide rails (132) are arranged on the left side and the right side of the inner top of the frame body (2), the slide rod (134) is arranged on the front side of the slide rail (132) in a sliding manner, the third spring (133) is wound on the slide rail (132), two ends of the third spring (133) are respectively connected with the slide rail (132) and the slide rod (134), the wiping block (135) is connected between the lower parts of the slide rod (134) in a sliding manner, and the fourth spring (136) is wound on the slide rod (134), the both ends of fourth spring (136) are connected with slide bar (134) and wiping piece (135) respectively, and the equal rotary type in slide bar (134) bottom is equipped with second shifting block (137), and first shifting block (131) backward rotation homoenergetic enough contacts with second shifting block (137), and second torsion spring (138) have all been around to the second shifting block (137) left and right sides, and second torsion spring (138) both ends are connected with slide bar (134) and second shifting block (137) respectively.

8. The device for polishing the curved surface of the optical lens housing as claimed in claim 7, wherein the first sliding bar (81) and the second sliding bar (97) are T-shaped.