CN114905370A

CN114905370A - Cooling water circulation system is used in optical lens production

Info

Publication number: CN114905370A
Application number: CN202210567991.6A
Authority: CN
Inventors: 周继根; 罗朝伟
Original assignee: Chengdu Hongzheng Optical Co ltd
Current assignee: Chengdu Hongzheng Optical Co ltd
Priority date: 2022-05-24
Filing date: 2022-05-24
Publication date: 2022-08-16

Abstract

The application relates to a cooling water circulation system for optical lens production, and belongs to the field of cooling water recycling technology. It includes storage water tank, water delivery groove and water pump, be provided with first baffle in the storage water tank, first baffle separates the storage water tank for filter chamber and water storage chamber, water delivery groove one end is linked together, the other end is linked together with the filter chamber of storage water tank with the mill delivery port, be provided with filtering mechanism in the storage water tank, filtering mechanism filters the cooling water of filter chamber in to carry the cooling water after will filtering to the water storage intracavity, the water pump sets up on the storage water tank and is linked together with the water storage chamber, the water pump is carried the water in the water storage intracavity to the mill machine. This application has the effect of water economy resource.

Description

Cooling water circulation system is used in optical lens piece production

Technical Field

The application relates to the field of cooling water recycling technology, in particular to a cooling water circulation system for optical lens production.

Background

With the rapid development of the social and economic level and the soaring of the manufacturing industry, the requirements of light industry, heavy industry, scientific research and production life on optical lenses are increasingly greater, and the application fields of the optical lenses are also increasingly wide. In the production process of the optical lens, the optical lens needs to be ground by a milling and grinding machine, and a circular sheet blank is initially processed and molded to be ground into an arc surface.

In the grinding process of the optical lens, the optical lens is deformed or damaged due to high temperature generated by the contact between the optical lens and the grinding wheel, and therefore cooling water is generally used for heat dissipation and temperature reduction. In the prior art, after cooling water cools the optical lens being ground, the cooling water containing glass chips is generally discharged directly to the environment.

In view of the above-mentioned related art, the inventors consider that the cooling water is directly discharged, water resources are wasted, and production costs are increased.

Disclosure of Invention

In order to the water economy resource, this application provides a cooling water circulating system is used in optical lens production.

The application provides a cooling water circulating system for optical lens production adopts following technical scheme:

the utility model provides a cooling water circulation system is used in optical lens piece production, includes storage water tank, water delivery tank and water pump, be provided with first baffle in the storage water tank, first baffle separates the storage water tank for filter chamber and water storage chamber, water delivery tank one end is linked together, the other end is linked together with the filter chamber of milling machine delivery port, be provided with filter mechanism in the storage water tank, filter mechanism filters the cooling water of filter chamber to carry the cooling water after will filtering to the storage water intracavity, the water pump sets up on the storage water tank and is linked together with the water storage chamber, the water pump is carried the water of storage water intracavity to milling machine.

By adopting the technical scheme, cooling water used by the milling and grinding machine is conveyed into the filtering cavity through the water conveying groove, the cooling water in the filtering cavity is filtered under the action of the filtering mechanism, the filtered clean cooling water flows into the water storage cavity to be stored, and the water pump conveys the cooling water filtered in the water storage cavity to the milling and grinding machine for the milling and grinding machine to use when grinding the optical lens; the cooling water is recycled, so that water resources are saved, and the cost in the optical lens processing process is saved.

Optionally, a second partition plate is further arranged in the water storage tank, the second partition plate partitions a settling chamber in the water storage tank, the settling chamber and the water storage chamber are respectively located on two sides of the filtering chamber, and the water delivery tank is communicated with the settling chamber.

Through adopting above-mentioned technical scheme, the cooling water that has the glass piece is carried to settling chamber in, and the glass piece that weight is big is subsided and is piled up in settling chamber's bottom, and the less cooling water of glass piece content overflows and flows into the filter chamber behind the second baffle, realizes carrying out prefilter to the cooling water.

It is optional, be provided with the third baffle in the storage water tank and be located between first baffle and the second baffle, the dry chamber is separated out to third baffle and first baffle in the storage water tank, filtering mechanism includes the honeycomb duct, absorbs water cotton rope and extrusion subassembly, the third baffle is higher than first baffle, the honeycomb duct slope sets up between first baffle and third baffle, honeycomb duct parallel arrangement has many, many the slope lower extreme of honeycomb duct all with the top overlap joint of first baffle the slope highest end of honeycomb duct all is connected with the third baffle, absorb water cotton rope sets up in the honeycomb duct, just the one end that absorbs water cotton rope extends to the filter chamber after passing the third baffle, the extrusion subassembly sets up in the dry chamber and is arranged in extrudeing the cotton rope that absorbs water in the honeycomb duct.

By adopting the technical scheme, one end of the water-absorbing cotton rope extends into the filtering cavity, the other end of the water-absorbing cotton rope is positioned in the guide pipe, and because a plurality of small gaps are formed in the water-absorbing cotton rope, water in the filtering cavity is continuously conveyed along the water-absorbing cotton rope under the action of capillary phenomenon, so that cooling water in the filtering cavity is conveyed into the guide pipe, and then conveyed into the water storage cavity along the guide pipe for storage, thereby achieving the effect of conveniently filtering water in the filtering cavity; the extrusion subassembly can extrude the cotton rope that absorbs water in the honeycomb duct simultaneously, extrudees the water in the cotton rope that absorbs water to the honeycomb duct in, and the cotton rope that absorbs water after the extrusion is in relatively dry state, and the cotton rope that absorbs water of relatively dry plays the effect that absorbs water to the water in the rose box to the speed of absorbing water of the cotton rope that absorbs water has been accelerated, has promoted the filtration efficiency of cooling water.

Optionally, the extrusion subassembly includes extrusion stem and driving piece, the cross sectional shape of honeycomb duct is the semi-annular, the opening of honeycomb duct is upwards, the extrusion stem parallels and is located the top of honeycomb duct with the honeycomb duct, the inner wall laminating of extrusion stem and honeycomb duct, many the extrusion stem passes through the connecting rod and connects, the driving piece is connected with the connecting rod and is used for driving the extrusion stem and remove on vertical direction.

Through taking above-mentioned technical scheme, driving piece drive extrusion stem moves on vertical direction, and when the extrusion stem removed to in the water conservancy diversion pipe, the extrusion stem extruded the cotton rope that absorbs water to reach and be convenient for carry out extruded effect to the cotton rope that absorbs water.

Optionally, the driving piece includes install bin, driving motor, annular rack and incomplete gear, the install bin sets up in the storage water tank and is located the honeycomb duct below, the vertical setting of annular rack is in the install bin, the top connection of annular rack is provided with the slide bar, the slide bar slides and is connected with the connecting rod after passing the install bin, driving motor sets up on the install bin, just driving motor's output shaft extends to in the install bin, incomplete gear coaxial line is fixed to be set up on driving motor's output shaft, incomplete gear meshes with the annular rack mutually.

Through taking above-mentioned technical scheme, start driving motor, driving motor's output shaft drives incomplete gear and rotates, and incomplete gear meshes with two inside walls of annular rack in proper order mutually to drive annular rack reciprocating motion in vertical direction, thereby drive the extrusion stem reciprocating motion in vertical direction, reach the effect that the drive extrusion stem of being convenient for moved in vertical direction.

Optionally, a plurality of diversion trenches are communicated with the water delivery tank, the diversion trenches are communicated with the water outlet of the milling and grinding machine, cleaning assemblies are arranged in the diversion trenches, and the cleaning assemblies are used for cleaning the inner walls of the diversion trenches.

By adopting the technical scheme, the plurality of diversion trenches are respectively communicated with the plurality of milling machines, so that the wastewater generated by the plurality of milling machines is collected and conveyed, the cooling water used by each milling machine is prevented from being independently conveyed to the water storage tank, and the cost is saved; at the in-process of carrying the cooling water, the inevitable meeting of glass piece deposits in the cooling water is in the bottom of guiding gutter, utilizes the clearance subassembly to clear up the guiding gutter, avoids the too much and jam of glass piece deposit in the guiding gutter to a certain extent.

Optionally, the clearance subassembly includes the clearance frame, clearance frame both sides all are provided with the gyro wheel, the gyro wheel slides and sets up the top at the guiding gutter, the both sides and the bottom of clearance frame all are provided with the brush board, the inner wall of going to the guiding gutter on the brush board is provided with the brush hair, be provided with on the clearance frame and be used for driving the gyro wheel and carry out pivoted servo motor.

Through taking above-mentioned technical scheme, servo motor drive gyro wheel rotates to drive clearance frame removes along the guiding gutter, when clearance frame removes, the brush board on the clearance frame is scrubbed the lateral wall and the diapire of guiding gutter, avoids the glass piece deposit in the cooling water to a certain extent in the guiding gutter.

Optionally, an air pump is arranged in the cleaning frame, an output end of the air pump is communicated with the air delivery pipe, nozzles are arranged on two sides and the bottom of the cleaning frame, and the nozzles are communicated with the air delivery pipe.

Through adopting above-mentioned technical scheme, when clearing up the guiding gutter, the air pump inhales the air and carries to the shower nozzle blowout through the gas-supply pipe, and the glass piece that spun air current brushed down the brush board blows along the guiding gutter, has promoted the clearance effect.

In summary, the present application includes at least one of the following beneficial technical effects:

1. conveying cooling water used by the milling and grinding machine into a filtering cavity through a water conveying groove, filtering the cooling water in the filtering cavity under the action of a filtering mechanism, allowing the filtered clean cooling water to flow into a water storage cavity for storage, and conveying the filtered cooling water in the water storage cavity to the milling and grinding machine by a water pump for the milling and grinding machine to use when grinding an optical lens; the cooling water is recycled, so that water resources are saved, and the cost in the processing process of the optical lens is saved;

2. a plurality of small gaps are formed in the water absorbing cotton rope, and meanwhile, the water absorbing cotton rope has water absorbing property, so that under the action of capillary phenomenon, water in the filter cavity is conveyed into the flow guide pipe through the water absorbing cotton rope and then is input into the water storage cavity through the flow guide pipe, and the effect of conveniently filtering cooling water in the filter cavity is achieved;

3. servo motor drive gyro wheel rotates, and then drives clearance frame and remove along the guiding gutter, and the clearance frame is at the removal in-process, and the brush hair on the brush board brushes guiding gutter inner wall and diapire to clear up the guiding gutter, avoid the glass piece deposit in the cooling water to a certain extent and block up the guiding gutter in the guiding gutter.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present application.

Fig. 2 is a partial sectional view for illustrating the structure of the water storage tank in the embodiment of the present application.

Fig. 3 is a partial sectional view for showing the structure of the pressing assembly in the embodiment of the present application.

Fig. 4 is a schematic structural diagram for showing a cleaning assembly in the embodiment of the present application.

Description of reference numerals:

1. a water storage tank; 11. a filter chamber; 12. a water storage cavity; 13. a settling chamber; 14. a drying chamber; 2. a water delivery tank; 21. a diversion trench; 3. a water pump; 4. a first separator; 5. a filtering mechanism; 51. a flow guide pipe; 52. a water absorbent cotton rope; 53. an extrusion assembly; 531. an extrusion stem; 532. a drive member; 5321. installing a box; 5322. a drive motor; 5323. an annular rack; 5324. an incomplete gear; 5325. a slide bar; 533. a connecting rod; 6. a second separator; 7. a third separator; 8. cleaning the assembly; 81. cleaning the frame; 82. a roller; 83. brushing the board; 84. a servo motor; 85. an air pump; 86. a gas delivery pipe; 87. and (4) a spray head.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

The embodiment of the application discloses cooling water circulating system is used in optical lens production, refer to fig. 1, a cooling water circulating system is used in optical lens production includes storage water tank 1, water delivery groove 2 and water pump 3, storage water tank 1 is upper end open-ended rectangle box, install first baffle 4 and second baffle 6 in storage water tank 1, first baffle 4 parallels with second baffle 6, and the equal perpendicular to storage water tank 1's of face between them length direction, first baffle 4 separates storage water tank 1 for sedimentation chamber 13 with second baffle 6, filter chamber 11 and water storage chamber 12, the one end of water delivery groove 2 is linked together with the delivery port of milling machine, the other end just is located sedimentation chamber 13 with storage water tank 1 overlap joint. The height of the second clapboard 6 is lower than that of the water storage tank 1, the water conveying tank 2 conveys cooling water used by the milling and grinding machine into the sedimentation cavity 13, and the cooling water in the sedimentation cavity 13 overflows from the top plate of the second clapboard 6 into the filter cavity 11. The filtering mechanism 5 is installed in the water storage tank 1 and is used for filtering the cooling water in the filtering cavity 11, and the filtered cooling water is conveyed to the water storage cavity 12 for storage. The water pump 3 is arranged on the water storage tank 1 and communicated with the water storage cavity 12, and the output end of the water pump 3 conveys the filtered cooling water to the milling and grinding machine for secondary use through a water pipe.

Cooling water used by the milling and grinding machine is conveyed into the settling chamber 13 through the water conveying tank 2, glass fragments with larger weight in the cooling water are settled and accumulated at the bottom of the settling chamber 13, the cooling water with less glass fragments on the surface layer in the settling chamber 13 flows into the filtering chamber 11 through the top of the second partition plate 6, the filtering mechanism 5 filters the cooling water in the filtering chamber 11, and the filtered cooling water is conveyed into the water storage chamber 12; the cooling water after the water storage chamber 12 is filtered is stored, and the cooling water in the water storage chamber 12 is conveyed to the milling and grinding machine through the water pump 3 for secondary use, so that the recycling of the cooling water is realized.

Referring to fig. 1 and 2, a third partition plate 7 is installed in the water storage tank 1 and between the first partition plate 4 and the second partition plate 6, the plate surface of the third partition plate 7 is parallel to the plate surfaces of the first partition plate 4 and the second partition plate 6, and the first partition plate 4 and the third partition plate 7 separate a drying chamber 14 in the water storage tank 1. The height of the third partition 7 is higher than the height of the first partition 4 and the second partition 6. The filtering mechanism 5 comprises a guide pipe 51, a water absorption cotton rope 52 and an extrusion assembly 53, wherein the guide pipe 51 is installed between the first partition plate 4 and the third partition plate 7 in a plurality of ways, the guide pipes 51 are parallel to each other and are installed obliquely, the inclined lowest end of the guide pipe 51 is lapped and installed on the top end of the first partition plate 4, and the inclined highest end of the guide pipe 51 is connected with the third partition plate 7. One end of the water absorption cotton rope 52 is positioned in the draft tube 51, the other end of the water absorption cotton rope passes through the third partition plate 7 and then extends into the filter cavity 11, and the water absorption cotton rope 52 is formed by weaving a plurality of fine cotton threads. The squeezing assembly 53 is installed in the water storage tank 1 and located in the drying chamber 14, and the squeezing assembly 53 squeezes the absorbent cotton string 52 in the flow guide pipe 51.

There are a lot of gaps in the cotton rope 52 that absorbs water, also have the space between the cotton fiber simultaneously, and the one end that the cotton rope 52 that absorbs water is located filter chamber 11 absorbs water, and under capillary phenomenon's effect, water is carried along the cotton rope 52 that absorbs water to the cotton rope 52 that absorbs water carries the water in filter chamber 11 to during the honeycomb duct 51, water flows into to store in the water storage chamber 12 along honeycomb duct 51. The squeezing component 53 squeezes the absorbent cotton rope 52 in the draft tube 51, so as to discharge the water in the absorbent cotton rope 52. Meanwhile, the water absorption cotton rope 52 in the draft tube 51 is in a relatively dry state after being extruded out, so that the water absorption is enhanced, the cooling water is conveyed to one end in the draft tube 51 from one end in the filter chamber 11 by the water absorption cotton rope 52, and the filtering efficiency is improved.

Referring to fig. 2 and 3, the extrusion assembly 53 includes an extrusion rod 531 and a driving member 532, the cross-sectional shape of the draft tube 51 is semi-annular, the opening of the draft tube 51 is vertically upward, the extrusion rod 531 is installed above the draft tube 51, the draft tubes 51 are in one-to-one correspondence with the extrusion rods 531, the extrusion rods 531 are parallel to the draft tube 51 and are located right above the draft tube 51, and the outer wall of the extrusion rod 531 is attached to the inner wall of the draft tube 51. A connecting rod 533 is connected between the extrusion rods 531, the driving member 532 is installed in the drying chamber 14, the driving member 532 passes through a gap between two adjacent draft tubes 51 and then is connected to the connecting rod 533, and the driving member 532 drives the connecting rod 533 to move in the vertical direction.

Referring to fig. 3, the driving member 532 includes a mounting box 5321, a driving motor 5322, an annular rack 5323 and an incomplete gear 5324, the mounting box 5321 is a rectangular box, and the mounting box 5321 is fixedly mounted on the bottom wall of the drying cavity 14 in the water storage tank 1 through supports at four corners of the bottom thereof. The annular rack 5323 is vertically installed in the installation box 5321, two ends of the annular rack 5323 are fixedly connected with sliding rods 5325 along the length direction of the annular rack 5323, the top surface of the installation box 5321 and the ground are provided with sliding holes in a relative mode, and the sliding rods 5325 at the two ends of the annular rack 5323 penetrate through the two sliding holes in a sliding mode respectively. The sliding rod 5325 at the top of the annular rack 5323 is fixedly connected with the connecting rod 533. The sliding rod 5325 is provided with a limiting block, and when the annular rack 5323 descends to the lowest point under the action of the incomplete gear 5324, the limiting block is abutted against the installation box 5321, so that the annular rack 5323 is prevented from moving downwards under the action of gravity to be abutted against the installation box 5321. The driving motor 5322 is fixedly mounted on the side wall of the mounting box 5321, an output shaft of the driving motor 5322 penetrates through the mounting box 5321 and extends into the mounting box 5321, the output shaft of the driving motor 5322 is perpendicular to the annular rack 5323, the incomplete gear 5324 is coaxially and fixedly mounted on the output shaft of the driving motor 5322, and the incomplete gear 5324 is meshed with the annular rack 5323.

The driving motor 5322 is started, the driving motor 5322 drives the incomplete gear 5324 to rotate, the incomplete gear 5324 is meshed with two inner side walls of the annular rack 5323 in sequence when rotating, the annular rack 5323 is driven to reciprocate in the vertical direction, the annular rack 5323 drives the extrusion rod 531 to reciprocate in the vertical direction, when the extrusion rod 531 enters the draft tube 51, the extrusion rod 531 extrudes the absorbent cotton rope 52 in the draft tube 51, water in the absorbent cotton rope 52 is extruded, and the extruded water flows into the water storage cavity 12 along the draft tube 51.

Referring to fig. 1, a plurality of diversion trenches 21 are installed on the side surface of the water delivery groove 2 in a communicating manner, the diversion trenches 21 are communicated with the water outlets of the milling and grinding machines, and one diversion trench 21 can correspond to one or more milling and grinding machines, so that cooling water used by the plurality of milling and grinding machines is subjected to centralized treatment, and the cost is saved. When the cooling water containing the glass cullet flows through the diversion trench 21, the glass cullet is inevitably deposited on the inner wall of the diversion trench 21, and the water delivery effect of the diversion trench 21 is affected after a long time. Therefore, the guide groove 21 is provided with the cleaning assembly 8, and the cleaning assembly 8 cleans the inner wall of the guide groove 21.

Referring to fig. 4, the cleaning assembly 8 includes a cleaning frame 81, the cleaning frame 81 is a rectangular frame, a plurality of rollers 82 are rotatably mounted on both sides of the top of the cleaning frame 81, the rollers 82 on both sides of the cleaning frame 81 are respectively slidably connected to the side walls on both sides of the diversion trench 21, and the cleaning frame 81 moves along the length direction of the diversion trench 21 under the action of the rollers 82. A rotating shaft is fixedly arranged between the two opposite rollers 82, a servo motor 84 is arranged on the cleaning frame 81, and the servo motor 84 is connected with the rotating shaft and is used for driving the rotating shaft to rotate. Brush plates 83 are fixedly mounted on two sides and the bottom of the cleaning frame 81, and bristles are arranged on the brush plates 83 facing the inner wall of the diversion trench 21. The servo motor 84 drives the rotation shaft to rotate, and further drives the roller 82 to rotate, so as to drive the cleaning frame 81 to move along the length direction of the diversion trench 21. When the cleaning frame 81 moves, the brush plates 83 on the two side surfaces and the bottom surface of the cleaning frame 81 brush the inner wall of the guide groove 21, so that the glass scraps deposited on the inner wall of the guide groove 21 are cleaned.

Referring to fig. 4, an air pump 85 is further installed in the cleaning rack 81, an output end of the air pump 85 is communicated with an air pipe 86, the air pipe 86 is arranged on two side walls and at the bottom of the cleaning rack 81, a plurality of nozzles 87 are communicated and installed on the air pipe 86, and the nozzles 87 extend towards the inner wall of the diversion trench 21. In the process that clearance frame 81 removed along guiding gutter 21, brush board 83 brushes the glass piece of deposit on guiding gutter 21 inner wall, and air pump 85 inhales the air and carries the blowout to shower nozzle 87 with the air through air-supply pipe 86 after the air, blows the glass piece after brushing, has further promoted the clearance effect of guiding gutter 21.

The implementation principle of the cooling water circulation system for optical lens production in the embodiment of the application is as follows: the cooling water that has the glass piece after the milling and grinding machine used is carried to settling chamber 13 through water delivery groove 2, the cooling water subsides in settling chamber 13, accomplish prefiltering, the less cooling water of glass piece content flows into filter chamber 11 after subsiding, the cotton rope 52 that absorbs water, under the effect of cotton rope 52 capillary phenomenon that absorbs water, the cotton rope 52 that absorbs water is located the one end of filter chamber 11 and carries water to the one end that is located honeycomb duct 51, extrusion pole 531 reciprocates in vertical direction simultaneously, the cotton rope 52 that absorbs water in the honeycomb duct 51 extrudes, the water in the cotton rope 52 that absorbs water is carried to storage chamber 12 through honeycomb duct 51 and is stored, water pump 3 carries the water in storage chamber 12 to the milling and grinding machine and carries out the secondary use, the used of cooling water among the optical lens production process has been realized, the water economy resource.

Finally, it should be noted that: in the description of the present application, it is to be noted that the terms "vertical", "upper", "lower", "horizontal", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present application.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims

1. The utility model provides a cooling water circulation system is used in optical lens production which characterized in that: including storage water tank (1), water delivery groove (2) and water pump (3), be provided with first baffle (4) in storage water tank (1), first baffle (4) are separated storage water tank (1) for filter chamber (11) and water storage chamber (12), water delivery groove (2) one end is linked together, the other end is linked together with filter chamber (11) of milling machine delivery port, be provided with filtering mechanism (5) in storage water tank (1), filtering mechanism (5) filters the cooling water in filter chamber (11) to carry the cooling water after filtering to in water storage chamber (12), water pump (3) set up on storage water tank (1) and are linked together with water storage chamber (12), water pump (3) are carried the water in water storage chamber (12) to milling machine.

2. The cooling water circulation system for optical lens production according to claim 1, wherein: still be provided with second baffle (6) in storage water tank (1), second baffle (6) separate sedimentation chamber (13) in storage water tank (1), sedimentation chamber (13) and water storage chamber (12) are located the both sides of filter chamber (11) respectively, water delivery groove (2) are linked together with sedimentation chamber (13).

3. The cooling water circulation system for optical lens production according to claim 1, wherein: the water storage tank (1) is internally provided with a third partition plate (7) between the first partition plate (4) and the second partition plate (6), the third partition plate (7) and the first partition plate (4) are used for separating a drying cavity (14) in the water storage tank (1), the filtering mechanism (5) comprises a guide pipe (51), a water absorption cotton rope (52) and an extrusion assembly (53), the third partition plate (7) is higher than the first partition plate (4), the guide pipe (51) is obliquely arranged between the first partition plate (4) and the third partition plate (7), the guide pipe (51) is parallelly provided with a plurality of guide pipes, the lowest oblique ends of the plurality of guide pipes (51) are lapped with the top of the first partition plate (4), the highest oblique ends of the guide pipe (51) are connected with the third partition plate (7), the water absorption cotton rope (52) is arranged in the guide pipe (51), and one end of the water absorption cotton rope (52) extends into the filtering cavity (11) after penetrating through the third partition plate (7), the squeezing component (53) is arranged in the drying cavity (14) and is used for squeezing the absorbent cotton rope (52) in the guide pipe (51).

4. The cooling water circulation system for optical lens production according to claim 3, wherein: extrusion subassembly (53) are including extrusion stem (531) and driving piece (532), the cross sectional shape of honeycomb duct (51) is the semicircle form, the opening of honeycomb duct (51) is upwards, extrusion stem (531) parallel and lie in the top of honeycomb duct (51) with honeycomb duct (51), the laminating of the inner wall of extrusion stem (531) and honeycomb duct (51), many extrusion stem (531) are connected through connecting rod (533), driving piece (532) are connected with connecting rod (533) and are used for driving extrusion stem (531) and move on vertical direction.

5. The cooling water circulation system for optical lens production according to claim 4, wherein: the driving piece (532) comprises an installation box (5321), a driving motor (5322), an annular rack (5323) and an incomplete gear (5324), the installation box (5321) is arranged in the water storage tank (1) and located below the guide pipe (51), the annular rack (5323) is vertically arranged in the installation box (5321), a sliding rod (5325) is connected to the top end of the annular rack (5323), the sliding rod (5325) penetrates through the installation box (5321) in a sliding mode and then is connected with the connecting rod (533), the driving motor (5322) is arranged on the installation box (5321), an output shaft of the driving motor (5322) extends into the installation box (5321), the incomplete gear (5324) is coaxially and fixedly arranged on the output shaft of the driving motor (5322), and the incomplete gear (5324) is meshed with the annular rack (5323).

6. The cooling water circulation system for optical lens production according to claim 1, wherein: the water conveying tank (2) is provided with a plurality of guide grooves (21) in a communicated mode, the guide grooves (21) are communicated with a water outlet of the milling and grinding machine, cleaning assemblies (8) are arranged in the guide grooves (21), and the cleaning assemblies (8) are used for cleaning the inner walls of the guide grooves (21).

7. The cooling water circulation system for optical lens production according to claim 6, wherein: clearance subassembly (8) are including clearance frame (81), clearance frame (81) both sides all are provided with gyro wheel (82), gyro wheel (82) slide and set up the top at guiding gutter (21), the both sides and the bottom of clearance frame (81) all are provided with brush board (83), the inner wall of going towards guiding gutter (21) on brush board (83) is provided with the brush hair, be provided with on clearance frame (81) and be used for driving gyro wheel (82) to carry out pivoted servo motor (84).

8. The cooling water circulation system for optical lens production according to claim 7, wherein: an air pump (85) is arranged in the cleaning frame (81), an output end of the air pump (85) is communicated with an air conveying pipe (86), spray heads (87) are arranged on two sides and the bottom of the cleaning frame (81), and the spray heads (87) are communicated with the air conveying pipe (86).