CN115947119A - Automatic conveying equipment for optical glass production - Google Patents

Abstract

The invention relates to the technical field of optical glass conveying, in particular to automatic conveying equipment for optical glass production, which comprises a conveying unit for conveying optical glass and a processing unit for carrying out surface processing on the optical glass, wherein the conveying unit is fixedly provided with the processing unit, and the processing unit 2 comprises a first cleaning frame, a second cleaning frame, a Y-shaped pipeline, a collecting tank, a filtering frame and a drying lamp frame.

Description

Automatic conveying equipment for optical glass production

Technical Field

The invention relates to the technical field of optical glass conveying, in particular to automatic conveying equipment for optical glass production.

Background

The optical glass is a glass capable of changing the propagation direction of light and changing the relative spectral distribution of ultraviolet, visible or infrared light, and can be used for manufacturing lenses, prisms, reflectors, windows and the like in optical instruments.

After the optical glass is formed, the optical glass needs to be conveyed through corresponding equipment to prevent the optical glass from being damaged and broken in the conveying process, and in order to enable the optical glass to be put into use immediately after the optical glass is conveyed, the surface of the optical glass can be cleaned in the conveying process, so that the time spent before subsequent use is reduced, and the use efficiency of the optical glass is improved. And use traditional processing mode to need to remove optical glass to cleaning equipment through conveying equipment and handle, consequently need spend certain time, and shift the easy collision that takes place in-process, lead to optical glass to damage, optical glass after the clearance is placed again and is carried on conveying equipment, very easily by secondary pollution, influences optical glass's subsequent use.

Disclosure of Invention

In order to solve the technical problem, the invention provides automatic conveying equipment for optical glass production.

The automatic conveying equipment for optical glass production comprises a conveying unit for conveying optical glass and a processing unit for performing surface treatment on the optical glass, wherein the processing unit is fixedly mounted on the conveying unit.

The transportation unit comprises a first workbench, two electric telescopic rods are fixedly mounted at the right end of the first workbench and symmetrically arranged around the two electric telescopic rods, a second workbench is fixedly mounted at the right end of the electric telescopic rods jointly, and a support frame is fixedly mounted between the first workbench and the second workbench.

The processing unit comprises a first cleaning frame, a first cleaning frame is fixedly mounted at the upper end of the middle of the supporting frame, a second cleaning frame is fixedly mounted at the lower end of the middle of the supporting frame, the first cleaning frame and the second cleaning frame are connected through a Y-shaped pipeline, a collecting groove is fixedly mounted at the right end of the workbench, the length of the collecting groove is larger than that of the supporting frame, a filter frame is fixedly mounted between the collecting groove and the Y-shaped pipeline, and a drying lamp frame is fixedly mounted at the upper end of the first cleaning frame.

The first preferred technical scheme is as follows: the first working table comprises a fixed table, a conveying roller is uniformly and rotatably connected to the fixed table, a rubber sleeve is fixedly mounted on the surface of the conveying roller, a chain wheel is fixedly mounted at the rear end of the conveying roller, the chain wheel is connected through a toothed chain belt in a transmission mode, a first motor is fixedly mounted at the rear end of the fixed table through a motor base, and an output shaft of the first motor is fixedly connected with the leftmost chain wheel through a shaft coupling.

The preferred technical scheme is as follows: the support frame includes the telescopic bracket, fixed mounting has a set of telescopic bracket group between workstation one and the workstation two, telescopic bracket group comprises two telescopic bracket from beginning to end, telescopic bracket looks remote site evenly is connected with the sliding block, be connected with the slope support with sliding fit's mode between the sliding block, fixed connection between leftmost sliding block and the workstation one, fixed connection between sliding block and the workstation two on rightmost side, sliding block and telescopic bracket middle part fixed connection at the very middle part, it is connected with the cylinder roller to rotate between the relative sliding block from beginning to end, the cylinder roller is stainless steel.

The preferred technical scheme is three: the cleaning frame comprises a first electric push rod, the upper end of the middle of the support frame is fixedly provided with the first electric push rod, the tail end of the first electric push rod is fixedly provided with a first pipeline grid, the lower end of the first pipeline grid is uniformly and fixedly provided with a first rotary cleaning ball, and the lower end of the first pipeline grid is fixedly provided with a first cleaning brush plate.

The preferable technical scheme is four: the cleaning frame comprises a second electric push rod, the lower end of the middle of the support frame is fixedly provided with the second electric push rod, the tail end of the second electric push rod is fixedly provided with a second pipeline grid, the upper end of the second pipeline grid is uniformly and fixedly provided with a second rotary cleaning ball, the upper end of the second pipeline grid is fixedly provided with a second cleaning brush plate, and the height of the second cleaning brush plate is larger than that of the first cleaning brush plate.

The preferred technical scheme is five: the collecting vat includes the rectangle box, and a workstation right-hand member fixed mounting has the rectangle box, and four pyramid recess have been seted up to rectangle box upper end, and the fillet has been seted up to four pyramid recess corners, and four pyramid recess downside has been seted up and has been collected the mouth, and rectangle box lower extreme just is located and collects a downside fixed mounting and have slope crotch box, and fixed mounting has the filter stand between slope crotch box and the Y venturi tube way.

The preferred technical scheme is six: the filter frame comprises a connecting pipe, the tail end of the inclined hook box is fixedly provided with the connecting pipe, the tail end of the Y-shaped pipeline is fixedly provided with a water pump, a filter plate is fixedly arranged in the connecting pipe, and the tail end of the connecting pipe is fixedly connected with the water pump.

The preferred technical scheme is seven: the difference between the second workbench and the first workbench is only that sliding wheels are uniformly and fixedly installed at the lower end of the second workbench.

The preferred technical scheme is eight: the telescopic support comprises a C-shaped fixing sleeve, the C-shaped fixing sleeve is symmetrically and fixedly arranged at the front and back of the first working table and the opposite end of the first working table, the left and right opposite C-shaped fixing sleeves are connected with a moving sleeve in a sliding fit mode, and the middle sliding block and the middle of the moving sleeve are fixedly connected at the middle part.

The preferable technical scheme is nine: the inclined support comprises an inclined rod I, the inclined rod I is connected between the sliding blocks in a sliding fit mode, the middle of the inclined rod I is rotatably connected with an inclined rod II, and the two ends of the inclined rod II are connected with the adjacent sliding blocks in a sliding fit mode.

The invention has the following beneficial effects: 1. according to the automatic conveying equipment for optical glass production, the conveying unit is used for conveying the optical glass, the processing unit is used for cleaning the surface of the optical glass, the optical glass does not need to be transferred in the whole process, the optical glass can be prevented from being damaged in the transferring process, and parts in contact with the optical glass are different and have a certain distance before and after cleaning, so that the optical glass can be prevented from being secondarily polluted, and the cleanliness of the optical glass is ensured.

2. The conveying unit is arranged in the glass plate conveying device, the sliding blocks are positioned through the telescopic supports, the distance between the sliding blocks is guaranteed to be the same through the inclined supports, when the distance between the second workbench and the first workbench is changed, the distance between the sliding blocks is changed, the glass plate is supported through the cylindrical roller, when the glass plate on the first workbench extrudes the glass plate on the cylindrical roller, the glass plate on the cylindrical roller smoothly moves to the right to the second workbench, and the glass plate needs to be cleaned and dried on the cylindrical roller, so that the cylindrical roller is made of stainless steel.

3. The processing unit provided by the invention controls the distance between the cleaning brush plate and the upper end surface of the glass plate through the electric push rod, so that the upper end surface of the glass plate moving rightwards is cleaned, and impurities with strong adhesive force on the upper surface of the glass can be separated from the glass plate.

4. The processing unit provided by the invention controls the distance between the sliding blocks through the matching of the first inclined rod and the second inclined rod, ensures that the distances between the adjacent sliding blocks are the same, washes the upper surface of the glass plate through the rotating cleaning ball to separate impurities from the glass plate, and cleans the upper end surface of the glass plate moving rightwards through the cleaning brush plate to separate the impurities with strong surface adhesive force from the glass plate.

Drawings

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

Fig. 2 is a schematic front sectional plan view of the present invention.

Fig. 3 is a schematic rear perspective view of the present invention.

Fig. 4 is a schematic structural diagram of a front view plane of the present invention.

Fig. 5 is a sectional view taken along line B-B of fig. 4 in accordance with the present invention.

Fig. 6 is a cross-sectional view taken along line C-C of fig. 4 in accordance with the present invention.

Fig. 7 is a front perspective view of the telescopic bracket of the present invention.

Fig. 8 is a cross-sectional view taken along line D-D of fig. 6 in accordance with the present invention.

In the figure: 1. a transport unit; 11. a first workbench; 111. a fixed table; 112. a transport roller; 113. a rubber sleeve; 114. a sprocket; 115. a toothed chain belt; 116. a first motor; 12. a second workbench; 121. a sliding wheel; 13. a support frame; 131. a telescoping support; 1311. a C-shaped fixing sleeve; 1312. moving the sleeve; 132. a slider; 133. a tilt bracket; 1331. a first inclined rod; 1332. a second inclined rod; 134. a cylindrical roll; 14. an electric telescopic rod; 2. a processing unit; 21. a first cleaning frame; 211. an electric push rod I; 212. a pipeline grid I; 213. rotating the cleaning ball I; 214. cleaning the first brush plate; 22. a second cleaning frame; 221. a second electric push rod; 222. a second pipeline grid; 223. rotating the cleaning ball II; 224. cleaning a second brush plate; 23. a Y-shaped duct; 24. collecting tank; 241. a rectangular box; 242. a quadrangular pyramid-shaped groove; 243. a collection port; 244. an inclined hook box; 25. a filter frame; 251. a connecting pipe; 252. a water pump; 253. a filter plate; 26. and drying the lamp bracket.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, an automatic conveying apparatus for optical glass production includes a conveying unit 1 for conveying optical glass and a processing unit 2 for performing surface treatment on the optical glass, wherein the processing unit 2 is fixedly mounted on the conveying unit 1.

With reference to fig. 1, the transportation unit 1 includes a first working platform 11, two electric telescopic rods 14 are fixedly mounted at the right end of the first working platform 11, the two electric telescopic rods 14 are symmetrically arranged in front and back, the right ends of the electric telescopic rods 14 are fixedly connected with a second working platform 12, and a support frame 13 is fixedly mounted between the first working platform 11 and the second working platform 12; firstly, the distance between a first workbench 11 and a second workbench 12 is adjusted according to the size of a glass plate to be conveyed, the second workbench 12 is pushed rightwards through an electric telescopic rod 14, the distance between the second workbench 12 and the first workbench 11 is enabled to be appropriate, the first workbench 11 and the second workbench 12 jointly support a support frame 13, the glass plate is placed on the first workbench 11 and transported rightwards, the glass plate is moved to the upper end of the support frame 13, and the surface of the glass plate is cleaned and dried through a processing unit 2.

Referring to fig. 1 and 3, the processing unit 2 includes a first cleaning rack 21, the first cleaning rack 21 is fixedly mounted at the upper end of the middle of the support frame 13, a second cleaning rack 22 is fixedly mounted at the lower end of the middle of the support frame 13, the first cleaning rack 21 and the second cleaning rack 22 are connected through a Y-shaped pipeline 23, a collecting tank 24 is fixedly mounted at the right end of the first workbench 11, the length of the collecting tank 24 is greater than that of the support frame 13, a filter rack 25 is fixedly mounted between the collecting tank 24 and the Y-shaped pipeline 23, and a drying lamp holder 26 is fixedly mounted at the upper end of the first cleaning rack 21; cooperate through wash rack one 21 and wash rack two 22, wash both ends about the glass board, in the cleaning process, sewage drops and collects in collecting vat 24, filters sewage through filter stand 25, and the water after the filtration flows back and carries out used repeatedly to wash rack one 21 and wash rack two 22, realizes the cyclic utilization to water, carries out drying process to the glass surface through stoving lighting fixture 26.

Referring to fig. 2 and 3, the first working table 11 includes a fixed table 111, a transport roller 112 is uniformly rotatably connected to the fixed table 111, a rubber sleeve 113 is fixedly installed on the surface of the transport roller 112, chain wheels 114 are fixedly installed at the rear ends of the transport roller 112, the chain wheels 114 are in transmission connection through a chain belt 115, a first motor 116 is fixedly installed at the rear end of the fixed table 111 through a motor base, and an output shaft of the first motor 116 is fixedly connected with the leftmost chain wheel 114 through a coupling; drive sprocket 114 through motor 116 and rotate, under the drive of chain belt 115, all sprockets 114 rotate with transport roller 112 is synchronous, transport the glass board, reduce the vibration degree in the transportation through rubber sleeve 113, prevent that the glass board from receiving the damage in the transportation.

Referring to fig. 6 and 7, the supporting frame 13 includes a telescopic bracket 131, a group of telescopic bracket sets is fixedly installed between the first workbench 11 and the second workbench 12, each telescopic bracket set is composed of two telescopic brackets 131 at the front and at the back, sliding blocks 132 are uniformly connected to opposite ends of the telescopic brackets 131, inclined brackets 133 are connected between the sliding blocks 132 in a sliding fit manner, the sliding block 132 at the leftmost side is fixedly connected with the first workbench 11, the sliding block 132 at the rightmost side is fixedly connected with the second workbench 12, the sliding block 132 at the middlemost part is fixedly connected with the middle part of the telescopic bracket 131, cylindrical rollers 134 are rotatably connected between the sliding blocks 132 at the front and at the back, and the cylindrical rollers 134 are made of stainless steel; the sliding blocks 132 are positioned through the telescopic supports 131, the distance between the sliding blocks 132 is guaranteed to be the same through the inclined supports 133, when the distance between the second workbench 12 and the first workbench 11 is changed, the distance between the sliding blocks 132 is changed accordingly, the glass plate is supported through the cylindrical rollers 134, when the glass plate on the first workbench 11 extrudes the glass plate on the cylindrical rollers 134, the glass plate on the cylindrical rollers 134 moves rightwards to the second workbench 12, and the glass plate needs to be cleaned and dried on the cylindrical rollers 134, so that the cylindrical rollers 134 are made of stainless steel.

Referring to fig. 2, 3 and 5, the first cleaning frame 21 includes a first electric push rod 211, the first electric push rod 211 is fixedly installed at the upper end of the middle part of the support frame 13, a first pipeline grid 212 is fixedly installed at the tail end of the first electric push rod 211, a first rotary cleaning ball 213 is uniformly and fixedly installed at the lower end of the first pipeline grid 212, and a first cleaning brush plate 214 is fixedly installed at the lower end of the first pipeline grid 212; the distance between the first cleaning brush plate 214 and the upper end face of the glass plate is controlled through the first electric push rod 211, so that the first cleaning brush plate 214 can clean the upper end face of the glass plate moving rightwards, and impurities with strong adhesion on the upper surface of the glass can be removed; the upper surface of the glass plate is washed by rotating the first cleaning ball 213, so that impurities are separated from the glass plate, and the upper end surface of the glass plate moving rightwards is cleaned by the first cleaning brush plate 214, so that the impurities with strong surface adhesion force are separated from the glass plate.

Referring to fig. 2, the second cleaning frame 22 includes a second electric push rod 221, the second electric push rod 221 is fixedly mounted at the lower end of the middle of the support frame 13, a second pipeline grid 222 is fixedly mounted at the tail end of the second electric push rod 221, a second rotary cleaning ball 223 is uniformly and fixedly mounted at the upper end of the second pipeline grid 222, a second cleaning brush plate 224 is fixedly mounted at the upper end of the second pipeline grid 222, and the height of the second cleaning brush plate 224 is greater than that of the first cleaning brush plate 214; since the second cleaning brush plate 224 needs to pass through the gap between the cylindrical rollers 134 to contact the optical glass, the height of the second cleaning brush plate 224 is greater than the height of the first cleaning brush plate 214, and the first rotary cleaning ball 213 and the second rotary cleaning ball 223 are both in the prior art.

Referring to fig. 2, 4 and 5, the collecting tank 24 includes a rectangular box 241, the rectangular box 241 is fixedly mounted at the right end of the first workbench 11, a quadrangular pyramid-shaped groove 242 is formed at the upper end of the rectangular box 241, fillets are formed at corners of the quadrangular pyramid-shaped groove 242, a collecting opening 243 is formed at the lower side of the quadrangular pyramid-shaped groove 242, an inclined hook box 244 is fixedly mounted at the lower end of the rectangular box 241 and located at the lower side of the collecting opening 243, and a filter frame 25 is fixedly mounted between the inclined hook box 244 and the Y-shaped pipeline 23; collect sewage to collecting the mouth 243 through four pyramid-shaped grooves 242, and then discharge to slope hook box 244, be convenient for sewage fast gathering to collecting the mouth 243 through four pyramid-shaped grooves 242, prevent through the fillet of seting up that impurity in the sewage from stagnating at four pyramid-shaped grooves 242 corners, lead to four corners of four pyramid-shaped grooves 242 to remain impurity, increase follow-up clean process, make the transportation process in through slope hook box 244, when filtering stand 25 stop work, sewage is detained in slope hook box 244 and can not flow back to four pyramid-shaped grooves 242.

Referring to fig. 3 and 5, the filter frame 25 includes a connection pipe 251, the connection pipe 251 is fixedly installed at the end of the inclined hook box 244, the water pump 252 is fixedly installed at the end of the y-shaped pipe 23, the filter plate 253 is fixedly installed in the connection pipe 251, and the end of the connection pipe 251 is fixedly connected with the water pump 252; the sewage is transported by the water pump 252 and filtered by the filter plate 253, so that the quality of the water entering the first cleaning rack 21 and the second cleaning rack 22 is ensured to meet the standard.

Referring to fig. 2, the second worktable 12 is different from the first worktable 11 only in that the lower end of the second worktable 12 is uniformly and fixedly provided with a sliding wheel 121; the second worktable 12 is smoothly moved by the sliding wheel 121.

Referring to fig. 6, 7 and 8, the telescopic bracket 131 includes C-shaped fixing sleeves 1311, the C-shaped fixing sleeves 1311 are symmetrically and fixedly installed at the front and back of the end opposite to the first workbench 11 and the second workbench 12, the left and right C-shaped fixing sleeves 1311 are connected with the moving sleeve 1312 in a sliding fit manner, the middle sliding block 132 at the middle part is fixedly connected with the middle part of the moving sleeve 1312, the left sliding block 132 at the left part is fixedly connected with the first workbench 11, the right sliding block 132 at the right part is fixedly connected with the second workbench 12, and the rest sliding blocks 132 are connected with the moving sleeve 1312 in a sliding fit manner; the function of adjusting the distance between the first workbench 11 and the second workbench 12 is realized by matching the C-shaped fixing sleeve 1311 with the moving sleeve 1312.

Referring to fig. 6 and 8, the tilt bracket 133 includes a first tilt rod 1331, the first tilt rod 1331 is connected between the sliding blocks 132 in a sliding fit manner, a second tilt rod 1332 is rotatably connected to the middle of the first tilt rod 1331, and the left and right ends of the second tilt rod 1332 are connected to the adjacent sliding blocks 132 in a sliding fit manner; the distance between the sliding blocks 132 is controlled by the cooperation of the first inclined rod 1331 and the second inclined rod 1332, so as to ensure that the distance between the adjacent sliding blocks 132 is the same.

During specific work, firstly, the distance between the first workbench 11 and the second workbench 12 is adjusted according to the size of a glass plate to be conveyed, the second workbench 12 is pushed rightwards through the electric telescopic rod 14, the distance between the second workbench 12 and the first workbench 11 is enabled to be appropriate, the support frame 13 is supported between the first workbench 11 and the second workbench 12, the glass plate is placed on the first workbench 11 and transported rightwards to be moved to the upper end of the support frame 13, the surface of the glass plate is cleaned and dried through the processing unit 2, the upper end and the lower end of the glass plate are cleaned through the matching of the first cleaning frame 21 and the second cleaning frame 22, in the cleaning process, sewage drops into the collecting groove 24 to be collected, the sewage is filtered through the filter frame 25, the filtered water flows back to the first cleaning frame 21 and the second cleaning frame 22 to be reused, the recycling of the water is achieved, and the drying treatment is carried out on the surface of the glass through the matching of the drying lamp frame 26 and the existing air drying device.

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

Claims (10)

1. An automatic conveying equipment for optical glass production comprises a conveying unit (1) for conveying optical glass and a processing unit (2) for carrying out surface treatment on the optical glass, and is characterized in that: the transportation unit (1) is fixedly provided with a processing unit (2); wherein:

the transportation unit (1) comprises a first workbench (11), two electric telescopic rods (14) are fixedly mounted at the right end of the first workbench (11), the two electric telescopic rods (14) are symmetrically arranged in front and back, a second workbench (12) is fixedly mounted at the right end of the electric telescopic rods (14) together, and a support frame (13) is fixedly mounted between the first workbench (11) and the second workbench (12);

processing unit (2) are including wash rack (21), support frame (13) middle part upper end fixed mounting has wash rack (21), support frame (13) middle part lower extreme fixed mounting has wash rack two (22), be connected through Y venturi tube way (23) between wash rack (21) and wash rack two (22), workstation one (11) right-hand member fixed mounting has collecting vat (24), the length of collecting vat (24) is greater than the length of support frame (13), fixed mounting has filter stand (25) between collecting vat (24) and Y venturi tube way (23), wash rack (21) upper end fixed mounting has stoving lighting fixture (26).

2. The automated conveying apparatus for optical glass production according to claim 1, wherein: workstation (11) are including fixed station (111), evenly rotate on fixed station (111) and be connected with transportation roller (112), transportation roller (112) fixed surface installs rubber sleeve (113), the equal fixed mounting in transportation roller (112) rear end has sprocket (114), sprocket (114) are connected through the drive of chain toothed belt (115), fixed station (111) rear end has motor one (116) through motor cabinet fixed mounting, motor one (116) output shaft passes through shaft coupling and sprocket (114) fixed connection leftmost.

3. The automated conveying apparatus for optical glass production according to claim 1, wherein: support frame (13) are including telescopic bracket (131), fixed mounting has a set of telescopic bracket group between workstation (11) and workstation two (12), telescopic bracket group comprises two telescopic bracket (131) around, telescopic bracket (131) looks remote site evenly is connected with sliding block (132), be connected with inclined bracket (133) with sliding fit's mode between sliding block (132), fixed connection between leftmost sliding block (132) and workstation (11), fixed connection between sliding block (132) and the workstation two (12) on rightmost side, sliding block (132) and telescopic bracket (131) middle part fixed connection at the middle part, it is connected with cylinder roller (134) to rotate between the relative sliding block (132) of front and back, cylinder roller (134) are stainless steel material.

4. The automated conveying apparatus for optical glass production according to claim 1, wherein: the cleaning frame I (21) comprises an electric push rod I (211), the upper end of the middle of the support frame (13) is fixedly provided with the electric push rod I (211), the tail end of the electric push rod I (211) is fixedly provided with a pipeline grid I (212), the lower end of the pipeline grid I (212) is uniformly and fixedly provided with a rotary cleaning ball I (213), and the lower end of the pipeline grid I (212) is fixedly provided with a cleaning brush plate I (214).

5. The automated conveying apparatus for optical glass production according to claim 1, wherein: the second cleaning frame (22) comprises a second electric push rod (221), a second electric push rod (221) is fixedly mounted at the lower end of the middle of the support frame (13), a second pipeline grid (222) is fixedly mounted at the tail end of the second electric push rod (221), a second rotary cleaning ball (223) is uniformly and fixedly mounted at the upper end of the second pipeline grid (222), a second cleaning brush plate (224) is fixedly mounted at the upper end of the second pipeline grid (222), and the height of the second cleaning brush plate (224) is greater than that of the first cleaning brush plate (214).

6. The automated conveying apparatus for optical glass production according to claim 1, wherein: the collecting tank (24) comprises a rectangular box (241), the right end of the workbench I (11) is fixedly provided with the rectangular box (241), the upper end of the rectangular box (241) is provided with a quadrangular pyramid-shaped groove (242), corners of the quadrangular pyramid-shaped groove (242) are provided with round corners, the lower side of the quadrangular pyramid-shaped groove (242) is provided with a collecting port (243), the lower end of the rectangular box (241) is fixedly provided with an inclined hook box (244) located at the lower side of the collecting port (243), and a filter frame (25) is fixedly arranged between the inclined hook box (244) and the Y-shaped pipeline (23).

7. The automated conveying apparatus for optical glass production according to claim 1, wherein: the filter frame (25) comprises a connecting pipe (251), the connecting pipe (251) is fixedly installed at the tail end of the inclined hook box (244), a water pump (252) is fixedly installed at the tail end of the Y-shaped pipeline (23), a filter plate (253) is fixedly installed in the connecting pipe (251), and the tail end of the connecting pipe (251) is fixedly connected with the water pump (252).

8. The automated conveying apparatus for optical glass production according to claim 1, wherein: the second workbench (12) is different from the first workbench (11) only in that sliding wheels (121) are uniformly and fixedly mounted at the lower end of the second workbench (12).

9. The automated conveying apparatus for optical glass production according to claim 3, wherein: the telescopic support (131) comprises a C-shaped fixing sleeve (1311), the C-shaped fixing sleeve (1311) is symmetrically and fixedly mounted at the front and back of the opposite end of the first workbench (11) and the second workbench (12), the left and right opposite C-shaped fixing sleeves (1311) are connected with a moving sleeve (1312) in a sliding fit mode, and the middle of the middle sliding block (132) is fixedly connected with the middle of the moving sleeve (1312).

10. The automated conveying apparatus for optical glass production according to claim 3, wherein: the inclined support (133) comprises first inclined rods (1331), the first inclined rods (1331) are connected between the sliding blocks (132) in a sliding fit mode, the middle of each first inclined rod (1331) is rotatably connected with a second inclined rod (1332), and the left end and the right end of each second inclined rod (1332) are connected with the adjacent sliding blocks (132) in a sliding fit mode.

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