CN108311457B - Spraying and cleaning equipment for optical lenses - Google Patents

Abstract

The invention discloses an optical lens spray cleaning device, comprising: a frame part; the cleaning part is connected with the frame part and comprises a floating sprayer; a transmission part located at one side of the front surface of the cleaning part; and the clamp part is connected with the transmission part, and the transmission part drives the clamp part to circularly move so as to enable the clamp part to pass through the floating sprayer. The invention has the characteristics of high cleaning efficiency and high cleanliness.

Description

Spraying and cleaning equipment for optical lenses

Technical Field

The invention relates to the field of cleaning equipment, in particular to optical lens spray cleaning equipment.

Background

In the production process of the lens, dust in the air is inevitably adsorbed by static electricity, so that the cleanliness of the lens is influenced, and the follow-up coating, assembling and other processes are influenced. The traditional cleaning method is to manually clean by using wiping materials (gauze and dust-free paper) and chemical reagents (gasoline, ethanol, acetone and diethyl ether) through soaking, wiping and other means. The method is time-consuming, labor-consuming, poor in cleanliness and not suitable for the modern large-scale optical cleaning industry.

Disclosure of Invention

The invention mainly aims to provide an optical lens spray cleaning device, which aims to improve the cleaning efficiency and the cleaning degree during cleaning of an optical lens.

In order to achieve the above object, the present invention provides an optical lens spray cleaning apparatus, comprising: a frame part; the cleaning part is connected with the frame part and comprises a floating sprayer; a transmission part located at one side of the front surface of the cleaning part; and the clamp part is connected with the transmission part, and the transmission part drives the clamp part to circularly move so as to enable the clamp part to pass through the floating sprayer.

Optionally, the floating sprayer includes: the guide sleeve is connected with the frame part; the first end of the mounting seat is connected with the guide sleeve; the telescopic cylinder is connected with the second end of the mounting seat; the telescopic rod penetrates through the guide sleeve and is connected with the telescopic cylinder; and the spray head is connected to the end part of the telescopic rod.

Optionally, the spray head comprises a first nozzle and a second nozzle, the spraying directions of the first nozzle and the second nozzle are opposite, and a storage space is reserved between the first nozzle and the second nozzle.

Optionally, the transmission part comprises a revolution disc, the clamp part is connected with the revolution disc, the cleaning part is provided with a feeding position, a floating spraying position, a drying position and a discharging position, and the feeding position, the floating spraying position, the drying position and the discharging position are sequentially arranged around the revolution disc; the floating sprayer is arranged at the floating spraying position; the optical lens spray cleaning equipment further comprises a feeder arranged at the feeding position, a drying component arranged at the drying position and a discharger arranged at the discharging position.

Optionally, the transmission part further includes: the end part of the first motor is provided with a speed changer; the rotating shaft is connected with the speed changer and is provided with a first driving wheel; and the first end of the cam divider is provided with a first driven wheel, the first driven wheel is connected with the first driving wheel through a synchronous belt, and the second end of the cam divider is connected with the circle center of the revolution disc.

Optionally, at least one floating sprayer is arranged in the floating spraying position; the drying assembly comprises an air cutter and an air dryer, the air cutter and the air dryer are arranged in parallel along the periphery of the revolution disc, the air cutter is close to the floating sprayer, and the air dryer is close to the discharger.

Optionally, the fixture includes a self-rotating fixture, the self-rotating fixture including: the bottom of the fixed seat is connected with the transmission part, and the upper part of the fixed seat is provided with a bracket; the clamping jaw is rotationally connected with the fixing seat, a second driven wheel is arranged in the middle of the clamping jaw, a clamping cylinder is arranged at the upper part of the clamping jaw, and the clamping cylinder is connected with a bracket of the fixing seat; and the second motor is connected with the fixed seat, and a second driving wheel matched with the second driven wheel is arranged at the end part of the second motor.

Optionally, the optical lens spray cleaning device further includes a first conveying part, the first conveying part includes: the feeding bracket is arranged at the side of the feeding position; a feed conveyor connected to the feed bracket; the first position sensor is connected with the feeding bracket and is positioned at a feeding section of the feeding conveyor belt; and the sheet pushing device is connected with the feeding bracket and is arranged towards the feeding position.

Optionally, the optical lens spray cleaning device further includes a second conveying part, the second conveying part includes: the discharging support is arranged at the side of the discharging level; the discharging conveyor is connected with the discharging bracket; and the second position sensor is connected with the discharging bracket.

Optionally, the optical lens spray cleaning device further comprises a lens lifter connected with the frame part, wherein the upper end of the lens lifter faces the transmission part, and the transmission part drives the clamp part to circularly move through the lens lifter.

According to the technical scheme, the revolution disc is adopted to drive the rotation clamp, so that the optical lens is driven by the revolution disc to sequentially pass through the floating sprayer and the drying assembly for cleaning, the optical lens is not required to be clamped again between different cleaning procedures, and the cleaning efficiency is improved; according to the technical scheme, the optical lens is clamped by the autorotation clamp, and rotates along with the autorotation clamp during cleaning, so that the optical lens is favorable for multi-angle spraying and drying, and the cleanliness is improved; the spray device is a floating spray device, and the spray head can move up and down during cleaning of the optical lens, so that the cleaning angle is further enlarged, and the cleanliness is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of an embodiment of a spray cleaning apparatus for an optical lens according to the present invention;

FIG. 2 is a top view of FIG. 1;

FIG. 3 is a schematic view of the transmission part of FIG. 1;

FIG. 4 is a schematic view of the spin chuck of FIG. 1;

fig. 5 is a schematic view of the floating spray assembly of fig. 1.

Reference numerals illustrate:

the achievement of the objects, functional features and advantages of the present invention will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

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

It should be noted that, if directional indications (such as up, down, left, right, front, and rear … …) are included in the embodiments of the present invention, the directional indications are merely used to explain the relative positional relationship, movement conditions, etc. between the components in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are correspondingly changed.

In addition, if there is a description of "first", "second", etc. in the embodiments of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present invention.

The invention provides an optical lens spray cleaning device.

In an embodiment of the present invention, as shown in fig. 1, 2 and 5, the optical lens spray cleaning apparatus includes: a frame portion 100; a cleaning part 200, the cleaning part 200 being connected with the frame part 100, the cleaning part 200 including a floating shower 210; a driving part 300, wherein the driving part 300 is positioned at one side of the front surface of the cleaning part 200; and the clamp part 400 is connected with the transmission part 300, and the transmission part 300 drives the clamp part 400 to circularly move so that the clamp part 400 passes through the floating sprayer 210. Specifically, the cleaning portion 200 is connected to the upper portion of the frame portion 100, the cleaning portion 200 is located below the clamp portion 400, and the transmission portion 300 includes a revolution disc 310, where the revolution disc 310 drives the clamp portion 400 to perform a circular motion. After the clamp part 400 clamps the optical lens, the revolution disc 310 drives the clamp part 400 to rotate to the floating sprayer 210 for spraying, the optical lens is continuously rotated after the spraying is finished, then the optical lens is dismounted to complete one cycle, and then the revolution disc 310 drives the clamp part 400 to rotate to clamp the optical lens, and the next cycle is entered. The floating sprayer 210 of the embodiment can move up and down when spraying the optical lens, the spraying position is changed on the optical lens, the optical lens can be washed at multiple angles, and the cleanliness and the cleaning efficiency are improved. The transmission unit according to the present embodiment is not limited to the above embodiment, and may be: the transmission part comprises a crawler belt, the clamp is arranged on the crawler belt, the crawler belt drives the clamp to circularly move, and the circular movement route is rectangular; or, the transmission part comprises a ring piece, the clamp is arranged on the inner side of the ring piece, the ring piece drives the clamp to rotate, and an included angle is formed between the ring piece and the horizontal plane.

Further, as shown in fig. 3, the transmission part 300 further includes a first motor 320, and a transmission 330 is disposed at an end of the first motor 320; a rotating shaft 340, wherein the rotating shaft 340 is connected with the transmission 330, and the rotating shaft 340 is provided with a first driving wheel 341; a first driven wheel 351 is arranged at a first end of the cam divider 350, the first driven wheel 351 is connected with the first driving wheel 341 through a synchronous belt, and a second end of the cam divider 350 is connected with the circle center of the revolution disc 310; the switch bracket 360, the rotating shaft 340 is arranged on the switch bracket 360, and the switch bracket 360 is provided with a proximity switch 361. The transmission 330 in this embodiment employs a speed reducer, but is not limited to the speed reducer, and may be a gearbox in other embodiments. In this embodiment, the first motor 320 adjusts the rotation speed with a speed reducer, then drives the rotation shaft 340 to rotate, the first driving wheel 341 on the rotation shaft 340 drives the first driven wheel 351 to rotate through a synchronous belt, the first driven wheel 351 is connected with the cam divider 350, the cam divider 350 drives the revolution disc 310 to rotate, the cam divider 350 is used for adjusting the rotation state of the revolution disc 310, and when the clamp part 400 rotates to the floating sprayer 210, the revolution disc 310 stops for a period of time, so that the optical lens is sufficiently cleaned, and the cleanliness is improved.

Further, as shown in fig. 2 and 5, the cleaning part 200 has a feeding position, a floating spray position, a drying position, and a discharging position, and the feeding position, the floating spray position, the drying position, and the discharging position are sequentially disposed around the revolution plate; the floating sprayer 210 is arranged at the floating spraying position; the optical lens spray cleaning device further comprises a feeder 220 arranged at the feeding position, a drying assembly 230 arranged at the drying position and a discharger 240 arranged at the discharging position. Two floating spray assemblies 250 are arranged in the floating spray position, four floating sprayers 210 are arranged in each floating spray assembly 250, and the two floating spray assemblies 250 are arranged in parallel along the periphery of the revolution disc 310; the drying assembly 230 includes an air cutter 231 and an air dryer 232, the air cutter 231 and the air dryer 232 being juxtaposed along the circumference of the revolution plate 310, the air cutter 231 being adjacent to the floating shower 210, the air dryer 232 being adjacent to the discharger 240. In this embodiment, six processes of the feeder 220, the two floating spray assemblies 250, the air cutter 231, the air dryer 232, and the discharger 240 are sequentially arranged along the rotation direction of the revolution plate, and the discharger 220 is adjacent to the feeder 240. The optical lens is clamped by the clamp part 400 from the feeder 220, the revolution disc 310 drives the optical lens on the clamp part 400 to be sequentially cleaned by the two floating spray assemblies 250, then enters the air cutter 231 to cut off water by air, then is dried in the air dryer 232, and then the clamp part 400 is disassembled in the discharger 240. The drying assembly according to this embodiment is not limited to the solution in which the air cutter and the air dryer are disposed in the drying assembly, and may be: only an air dryer is arranged in the drying assembly; alternatively, an air dryer and a heater are provided in the drying assembly. The floating spray position in this embodiment is not limited to the scheme in which two floating spray assemblies are provided in the floating spray position, and may be: a floating spray assembly is arranged in the floating spray position, and a floating sprayer is arranged in the floating spray assembly; or three floating spray assemblies are arranged in the floating spray position, and two floating sprayers are arranged in each floating spray assembly.

Further, as shown in fig. 4 and 5, in the present embodiment, the jig section 400 includes 4 sets of rotation jigs 410, but is not limited to 4 sets, and may be 1 set or 6 sets; the rotation jig 410 in this embodiment includes: the fixed seat 411, the bottom of the fixed seat 411 is connected with the revolution plate 310, and a bracket is arranged at the upper part of the fixed seat 411; the clamping jaw 412 is rotationally connected with the fixing seat 411, a second driven wheel 413 is arranged in the middle of the clamping jaw 412, a clamping cylinder 414 is arranged at the upper part of the clamping jaw 412, and the clamping cylinder 414 is connected with a bracket of the fixing seat 411; and a second motor 415, the second motor 415 is connected with the fixing seat 411, and a second driving wheel 416 matched with the second driven wheel 413 is arranged at the end of the second motor 415. The clamping cylinder 414 drives the clamping jaw 412 to grasp and disassemble the optical lens, after the clamping jaw 412 grasps the optical lens, the second motor 415 can drive the clamping jaw 412 to rotate through the second driving wheel 416 and the second driven wheel 413, so that the optical lens is driven to rotate, the optical lens can be enabled to be sprayed by water flow in more area when being sprayed, the cleaning efficiency and the cleanliness of the optical lens are improved, the optical lens can rotate when being winded, the water of the mirror surface can be removed through centrifugal effect, the winded dewatering effect is better in cooperation with the optical lens, the optical lens can rotate when being air-dried, the relative speed of the air flow and the mirror surface can be increased, meanwhile, the mirror surface can be more uniformly subjected to the air flow, the drying speed is improved, the partial non-drying condition of the mirror surface is greatly reduced, and the drying effect is good.

Further, as shown in fig. 5, the floating shower 210 includes: a guide sleeve 211, wherein the guide sleeve 211 is connected with the frame part 100, and a mounting seat 212, and a first end of the mounting seat 212 is connected with the guide sleeve 211; a telescopic cylinder 213, wherein the telescopic cylinder 213 is connected with the second end of the mounting base 212; a telescopic rod 214, wherein the telescopic rod 214 passes through the guide sleeve 211 and is connected with a telescopic cylinder 213; and a nozzle 215, wherein the nozzle 215 is connected to the end of the telescopic rod 214. When the floating sprayer 210 sprays in a floating manner, the telescopic cylinder 213 drives the spray head 215 on the telescopic rod 214 to move up and down along the direction of the telescopic rod, the spray head sprays water flow, more cleaning sites can be provided compared with the traditional fixed spraying, the spraying cleaning efficiency can be greatly improved, and the mirror surface can be sprayed in an all-around manner by matching with the rotation clamp 410 in the embodiment, so that the cleanliness is high.

Further, as shown in fig. 5, the spray head 215 includes a first nozzle 216 and two second nozzles 217, the spray directions of the first nozzle 216 and the second nozzles 217 are opposite, the first nozzle 216 is connected with the telescopic rod 214 through a copper pipe, the copper pipe is L-shaped, so that a storage space is left between the first nozzle 216 and the second nozzles 217, and the storage space can accommodate an optical lens clamped by the rotation clamp 410, so that one surface of the lens is sprayed by the first nozzle 216, the other surface of the lens is sprayed by the second nozzle 217, and the two surfaces of the optical lens are simultaneously sprayed during spraying and cleaning, thereby improving the cleaning efficiency of the optical lens. The spray head of this embodiment is not limited to the above-mentioned scheme, and in other embodiments, the spray head may also include two first nozzles and three second nozzles, the spraying direction of first nozzle and second nozzle is relative, and first nozzle passes through the plastic tubing and is connected with the telescopic link, and plastics are the U type for leave the thing space between first nozzle and the second nozzle.

Further, as shown in fig. 2, in the present embodiment, the optical lens spray cleaning apparatus further includes a first conveying part 500, and the first conveying part 500 includes: a feed bracket 510, the feed bracket 510 being disposed laterally of the feed level; a feed conveyor 520, wherein the feed conveyor 520 is connected with the feed bracket 510, and the feed conveyor 520 is a conveyor belt; the first position sensors 530, the first position sensors 530 are connected to the feeding support 510, the first position sensors 530 are located at the feeding section of the feeding conveyor belt, two first position sensors 530 are provided in this embodiment, and are disposed front and back in the running direction of the conveyor belt, and the first position sensors 530 near the feeding section are used for feeding confirmation detection: sensing whether an optical lens exists or not, confirming that the conveyer belt continues to run after the optical lens exists, and locating and counting the lens by a first position sensor 530 far away from the feeding section: stopping counting for a moment after the lens runs under the sensor, continuing to run 1 optical lens interval, and sensing that 1 optical lens runs 1 optical lens interval until the count is full of 4; and 4 groups of pusher 540, wherein the pusher 540 is connected with the feeding support 510, the pusher 540 is arranged towards the feeding position, the interval of the pusher 540 is consistent with the interval of the lenses, the pusher 540 pushes the 4 optical lenses into the feeder 220, and the counting detection is performed again, the pusher 540 is not limited to 4 groups, but may be 2 groups or 3 groups in other embodiments. The automatic feeding device of this embodiment is favorable to improving the degree of automation of equipment, reduces the human cost, improves the clean efficiency of optical lens.

Further, as shown in fig. 2, the optical lens spray cleaning device further includes a second conveying portion 600, where the second conveying portion 600 is disposed at an angle of 120 ° with respect to the first conveying portion 500, and the second conveying portion 600 includes: the discharging support 610 is arranged at the side of the discharging level, and the discharging support 610 is arranged at the side of the discharging level; an outfeed conveyor 620, where the outfeed conveyor 620 is connected to the outfeed support 610, and in this embodiment, the outfeed conveyor 620 uses a conveyor belt; and, the second position sensor 630 is connected with the discharging support 610, in this embodiment, the portion of the discharging support 610 corresponding to the discharging level is provided with 4 equidistant second position sensors 630, the second position sensor 630 is a flat photoelectric sensor, and the flat photoelectric sensor is used for lens positioning and counting detection: when 4 (1 group) lenses enter the conveyor belt, 1 flat photoelectric sensor is corresponding to the upper part of each lens, the conveyor belt starts to run after the lenses are sensed, and meanwhile, the sensors which do not sense the lenses leak the lenses 1 time (the whole running process can be accumulated); still be equipped with 1 flat photoelectric sensor and detect for the location: determining a waiting discharging position of the conveyor belt, wherein the flat photoelectric sensor is adjacent to the 4 equidistant flat photoelectric sensors, and the 4 equidistant flat photoelectric sensors and the flat photoelectric sensors are sequentially arranged along the discharging direction; and 1 flat photoelectric sensor is also arranged for detecting the feeding position of the lens, and the flat photoelectric sensor is positioned at the tail end of the feeding conveyor. The automatic discharging device of this embodiment is favorable to improving the degree of automation of equipment, reduces the human cost, improves the clean efficiency of optical lens.

Further, as shown in fig. 1, the optical lens spray cleaning device further includes a lens lifter 700, in this embodiment, the lens lifter 700 uses a lens lifter cylinder, but is not limited to a lens lifter cylinder, in other embodiments, a hydraulic lens lifter may also be used, in this embodiment, the lens lifter cylinder is connected with the frame portion 100, the upper end of the lens lifter cylinder faces the transmission portion 300, the lens lifter cylinder is disposed below the feeder 220, when the transmission portion 300 drives the fixture portion 400 to circularly move through the lens lifter cylinder, the lens lifter 540 pushes the optical lens into the feeder 220, and then falls above the lens lifter cylinder, the lens lifter lifts the optical lens, so that the fixture portion 400 clamps the optical lens, and the lens lifter improves the clamping efficiency of the optical lens, thereby improving the efficiency of the whole cleaning process.

Further, as shown in fig. 1, the optical lens spray cleaning device further includes a housing 800, the housing 800 is disposed at the top of the frame 100, and an observation window 810 is disposed on the outer wall of the housing 800 corresponding to the four stations of the two floating spray assemblies 250, the air cutter 231 and the dryer 232, so as to facilitate observation of the running status of the cleaning procedure; the bottom of the frame 100 has adjustable legs, casters, and a water pan. The whole equipment and the related tools are mainly made of stainless steel and aluminum alloy materials, and an oxide film is arranged on the surface of the aluminum alloy materials, so that rust prevention is facilitated.

The optical lens spray cleaning device in this embodiment provides a wind source for the air cutter 231 and the air dryer 232 by a fan, and is connected with a Programmable Logic Controller (PLC), the PLC is connected with an LCD touch screen and an audible and visual alarm, the audible and visual alarm is arranged at the top of the outer cover, and the cleaning program can be controlled by the LCD touch screen in this embodiment.

According to the technical scheme, the first conveying part 500 is adopted for automatic feeding, the sheet lifter 700 and the clamping jaw 412 are matched for automatic clamping, then the feeding position is driven by the revolution disc 310 to be transferred into a spraying cleaning process, the clamping jaw rotates in the spraying cleaning process, the floating sprayer 210 moves up and down at the moment, after the cleaning process is finished, the revolution disc 310 drives the lens on the clamping jaw 412 to enter a wind cutting process for dehydration, then enter an air drying process, finally, the lens is dismounted on the discharger 240, and the lens enters the second conveying part 600 for automatic discharging.

The foregoing description is only of the preferred embodiments of the present invention and is not intended to limit the scope of the invention, and all equivalent structural changes made by the description of the present invention and the accompanying drawings or direct/indirect application in other related technical fields are included in the scope of the invention.

Claims (6)

1. An optical lens spray cleaning apparatus, comprising:

a frame part;

the cleaning part is connected with the frame part and comprises a floating sprayer;

a transmission part positioned at one side of the front surface of the cleaning part; the method comprises the steps of,

the clamp part is connected with the transmission part, and the transmission part drives the clamp part to circularly move so as to enable the clamp part to pass through the floating sprayer;

the guide sleeve is connected with the frame part;

the first end of the mounting seat is connected with the guide sleeve;

the telescopic cylinder is connected with the second end of the mounting seat;

the telescopic rod penetrates through the guide sleeve and is connected with the telescopic cylinder; the method comprises the steps of,

the spray head is connected to the end part of the telescopic rod;

the transmission part comprises a revolution disc, the clamp part is connected with the revolution disc, the cleaning part is provided with a feeding position, a floating spraying position, a drying position and a discharging position, and the feeding position, the floating spraying position, the drying position and the discharging position are sequentially arranged around the revolution disc;

the floating sprayer is arranged at the floating spraying position;

the optical lens spray cleaning equipment further comprises a feeder arranged at the feeding position, a drying component arranged at the drying position and a discharger arranged at the discharging position;

the transmission part further includes:

the end part of the first motor is provided with a speed changer;

the rotating shaft is connected with the speed changer and is provided with a first driving wheel; and

the first end of the cam divider is provided with a first driven wheel, the first driven wheel is connected with the first driving wheel through a synchronous belt, and the second end of the cam divider is connected with the circle center of the revolution disc;

the fixture includes a self-rotating fixture, the self-rotating fixture including:

the bottom of the fixed seat is connected with the transmission part, and the upper part of the fixed seat is provided with a bracket;

the clamping jaw is rotationally connected with the fixing seat, a second driven wheel is arranged in the middle of the clamping jaw, a clamping cylinder is arranged at the upper part of the clamping jaw, and the clamping cylinder is connected with a bracket of the fixing seat; the method comprises the steps of,

the second motor is connected with the fixing seat, and a second driving wheel matched with the second driven wheel is arranged at the end part of the second motor.

2. The optical lens spray cleaning device of claim 1, wherein the spray head comprises a first nozzle and a second nozzle, the first nozzle being opposite to the second nozzle in the spray direction, and a space for placing objects being left between the first nozzle and the second nozzle.

3. The optical lens spray cleaning apparatus of claim 1,

at least one floating sprayer is arranged in the floating spraying position;

the drying assembly comprises an air cutter and an air dryer, the air cutter and the air dryer are arranged in parallel along the periphery of the revolution disc, the air cutter is close to the floating sprayer, and the air dryer is close to the discharger.

4. The optical lens spray cleaning apparatus of claim 1, further comprising a first conveyor section comprising:

the feeding bracket is arranged at the side of the feeding position;

a feed conveyor connected to the feed bracket;

the first position sensor is connected with the feeding bracket and is positioned at a feeding section of the feeding conveyor belt; the method comprises the steps of,

the sheet pushing device is connected with the feeding support, and the sheet pushing device faces to the feeding position.

5. The optical lens spray cleaning apparatus of claim 1, further comprising a second conveying section comprising:

the discharging support is arranged at the side of the discharging level;

the discharging conveyor is connected with the discharging bracket; the method comprises the steps of,

the second position sensor is connected with the discharging bracket.

6. The optical lens spray cleaning apparatus according to any one of claims 1 to 5, further comprising a lens lifter connected to the frame portion, wherein an upper end of the lens lifter faces a transmission portion, and the transmission portion drives the clamp portion to move circularly through the lens lifter.

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