CN114833682A

CN114833682A - Optical lens piece equipment of polishing that precision appearance was used

Info

Publication number: CN114833682A
Application number: CN202210518518.9A
Authority: CN
Inventors: 张泽鹏; 王琛云
Original assignee: Individual
Current assignee: Shenzhen Shunyuan Optical Co ltd
Priority date: 2022-05-12
Filing date: 2022-05-12
Publication date: 2022-08-02
Anticipated expiration: 2042-05-12
Also published as: CN114833682B

Abstract

The invention relates to the technical field of polishing of optical lenses, in particular to optical lens polishing equipment for a precision instrument, which comprises a polishing mechanism, a first cleaning mechanism, an extrusion mechanism and a second cleaning mechanism, wherein scraps polished by a lens are washed through a water inlet pipe, when the scraps and water fall to the upper end of a water permeable plate, the scraps are accumulated at the upper end of the water permeable plate, the water is discharged out of the equipment through the water permeable plate and a sponge through a water outlet pipe, a third hydraulic telescopic rod is started to clean the scraps, the extrusion rod pushes a piston when a pushing block reaches the leftmost end, so that the pushing block can clean the scraps to a second shell, the scraps can be further filtered through the sponge, the piston moves leftwards and simultaneously pulls a first steel wire rope to drive a wire mesh to extrude the sponge, water in the sponge is extruded out, the third hydraulic telescopic rod moves leftwards and simultaneously drives a second steel wire rope to pull the cleaning block to clean a glass window, the cleaning of the attached scraps on the glass window is convenient for observing the polishing condition.

Description

Optical lens piece equipment of polishing that precision appearance was used

Technical Field

The invention relates to the technical field of optical lens polishing, in particular to an optical lens polishing device for a precision instrument.

Background

The optical glass lens is originally used for manufacturing lenses, namely pimples on common window glass or wine bottles, is similar to a crown, and is named from crown glass or crown glass, the glass is extremely uneven and foamy, the crown glass and the flint glass with a large lead content are also available, the stirring glass paste is found to be capable of manufacturing glass with uniform quality in about 1790 France people skin, Louis and Monard, and dozens of optical glasses are developed in several years, wherein the invention of barium crown glass with high refractive index is one of important achievements of a Schottky glass factory.

However, the conventional optical lens polishing equipment can generate a large amount of scraps in the polishing process, the scraps are continuously thrown around, and the scraps are accumulated in the equipment after long-time work, so that the normal operation of the equipment is affected if the scraps are required to be cleaned in time.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides optical lens polishing equipment for a precision instrument.

The technical scheme adopted by the invention for solving the technical problems is as follows: an optical lens polishing device for a precision instrument comprises a polishing mechanism, a first cleaning mechanism, an extrusion mechanism and a second cleaning mechanism, wherein the first cleaning mechanism is arranged at the lower end of the polishing mechanism; the piece of polishing the lens is washed through the inlet tube, when piece and water fall to the upper end of porous disk, the piece is piled up in the upper end of porous disk, water passes through porous disk and sponge through outlet pipe discharge apparatus, it clears up the piece to start third hydraulic telescoping rod, the stripper bar can promote the piston when promoting the piece and reacing the leftmost end, it will clear up the piece to the second casing to promote the piece like this, can further filter the piece through setting up the sponge, can stimulate first wire rope and drive wire netting extrusion sponge when the piston moves left, extrude the moisture in the sponge, can drive second wire rope pulling clearance piece and clean the glass window when third hydraulic telescoping rod moves left, it is convenient for observe the circumstances of polishing to clear up adnexed piece on the glass window.

Specifically, the polishing mechanism comprises a first hydraulic telescopic rod, the lower end of the first hydraulic telescopic rod is fixedly connected with a second hydraulic telescopic rod, the side wall of the second hydraulic telescopic rod is connected with a shell in a sliding manner, one end of the second hydraulic telescopic rod is fixedly connected with a stepping motor, one end of the stepping motor is tightly attached to the lens, one end of the shell is fixedly connected with a first shell, one end of the first shell is fixedly connected with a motor, one end of the motor is fixedly connected with a rotating rod, one end of the rotating rod is fixedly connected with a polishing block, one end of the first shell is fixedly connected with the shell, one end of the shell is provided with a sliding door, one end of the sliding door is fixedly connected with a handle, the upper end of the shell is provided with a glass window, the upper end of the lens is provided with a water inlet pipe, and the side wall of the water inlet pipe is fixedly connected with the shell; at first, carry out the centre gripping through circuit board control second hydraulic telescoping rod to the lens fixed, polish to lens laminating sanding block through controlling first hydraulic telescoping rod and step motor, the starter motor, the motor rotates and drives the dwang and rotate, the dwang rotates and drives sanding block and rotate, sanding block rotates and polishes the lens, can produce more piece when polishing the lens, in time wash the lens through the inside water of intaking.

Specifically, the first cleaning mechanism comprises a third hydraulic telescopic rod, one end of the third hydraulic telescopic rod is fixedly connected with the first shell, one end of the third hydraulic telescopic rod is fixedly connected with a pushing block, the side wall of the pushing block is fixedly connected with an extrusion rod, the lower end of the pushing block is provided with a water permeable plate, the side wall of the water permeable plate is fixedly connected with a shell, the lower end of the water permeable plate is provided with a sponge, the lower end of the sponge is provided with a wire mesh, the side wall of the wire mesh is slidably connected with the shell, one end of the extrusion rod is provided with a piston, one end of the piston is fixedly connected with a first sliding block, one end of the first sliding block is slidably connected with the second shell, one end of the second shell is fixedly connected with the shell, the side wall of the piston is fixedly connected with a first spring, and one end of the first spring is fixedly connected with the second shell; piece and water fall to the upper end of porous disk, regularly start third hydraulic telescoping rod, third hydraulic telescoping rod moves left and drives and promote the piece and move left, the in-process that promotes the piece and move left can drive the stripper bar and move left, can clear up the piece of piling up in the porous disk upper end left promoting the piece, can promote the piston when the stripper bar reachs the leftmost end, the first spring of piston can compress, the piece can be promoted the piece and promote the second casing like this, wash clastic water and can further filter the piece through the porous disk through the sponge.

Specifically, the extrusion mechanism comprises a first steel wire rope, one end of the first steel wire rope is fixedly connected with the piston, the side wall of the first steel wire rope is tightly attached to a first rotating pin, one end of the first rotating pin is rotatably connected with the shell, the lower end of the first steel wire rope is fixedly connected with a wire netting, the lower end of the wire netting is provided with a water outlet pipe, and the side wall of the water outlet pipe is fixedly connected with the shell; the first steel wire rope can be pulled to move upwards in the leftward movement process of the piston, the first steel wire rope can drive the wire netting to move upwards in the upward movement process, and the wire netting can extrude the sponge in the upward movement process.

Specifically, the second cleaning mechanism comprises a second steel wire rope, one end of the second steel wire rope is fixedly connected with a third hydraulic telescopic rod, the side wall of the second steel wire rope is rotatably connected with a second rotating pin, one end of the second rotating pin is rotatably connected with the shell, one end of the second steel wire rope is fixedly connected with a cleaning block, one end of the cleaning block is fixedly connected with a second sliding block, the second sliding block is arranged in a sleeve, the sleeve is arranged in the shell, a second spring is arranged at the lower end of the second sliding block and tightly attached to the lower end of the second sliding block, the second spring is arranged in the sleeve, and the upper end of the cleaning block is tightly attached to the glass window; there can be more piece attached to glass window bottom influence observation sight at the in-process of polishing, can stimulate second wire rope at the in-process of third hydraulic telescoping rod motion left and move left, and second wire rope motion left can drive the clearance piece and clean the glass window, is convenient for observe the condition of polishing.

The invention has the beneficial effects that:

(1) according to the optical lens polishing equipment for the precision instrument, fragments obtained by polishing the lens are washed through the water inlet pipe, when the fragments and water fall to the upper end of the water permeable plate, the fragments are accumulated at the upper end of the water permeable plate, and the water passes through the water permeable plate and the sponge and is discharged out of the equipment through the water outlet pipe.

(2) According to the optical lens polishing equipment for the precision instrument, the third hydraulic telescopic rod is started to clean the fragments, the extrusion rod pushes the piston when the pushing block reaches the leftmost end, so that the pushing block can clean the fragments to the second shell, the fragments can be further filtered by arranging the sponge, and the first steel wire rope can be pulled to drive the wire mesh to extrude the sponge while the piston moves leftwards, so that the moisture in the sponge is extruded out.

(3) According to the optical lens polishing equipment for the precision instrument, the third hydraulic telescopic rod moves leftwards and simultaneously drives the second steel wire rope to pull the cleaning block to clean the glass window, and the chips attached to the glass window are cleaned, so that the polishing condition can be observed conveniently.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view of the overall structure provided by the present invention;

FIG. 2 is a cross-sectional view of the overall structure shown in FIG. 1;

FIG. 3 is an enlarged view of the portion A shown in FIG. 2;

FIG. 4 is a schematic view of the connection structure of the piston and the first sliding block shown in FIG. 2;

FIG. 5 is a schematic view of a connection structure between the first sliding block and the second housing shown in FIG. 2;

FIG. 6 is a schematic view of a connection structure between the cleaning block and the second sliding block shown in FIG. 2.

In the figure: 1. a polishing mechanism; 11. a first hydraulic telescopic rod; 12. a second hydraulic telescopic rod; 13. a lens; 14. an electric motor; 15. rotating the rod; 16. grinding blocks; 17. a housing; 18. a first housing; 19. sliding the door; 110. a handle; 111. a glass window; 112. a water inlet pipe; 113. a stepping motor; 2. a first cleaning mechanism; 21. a third hydraulic telescopic rod; 22. a pushing block; 23. an extrusion stem; 24. a water permeable plate; 25. a sponge; 26. a wire mesh; 27. a piston; 28. a first spring; 29. a second housing; 210. a first slider; 3. an extrusion mechanism; 31. a first wire rope; 32. a first rotation pin; 33. a water outlet pipe; 4. a second cleaning mechanism; 41. a second wire rope; 42. a second rotation pin; 43. cleaning the block; 44. a second slider; 45. a sleeve; 46. a second spring.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

As shown in fig. 1-6, the optical lens polishing apparatus for a precision instrument according to the present invention includes a polishing mechanism 1, a first cleaning mechanism 2, an extruding mechanism 3, and a second cleaning mechanism 4, wherein the first cleaning mechanism 2 is disposed at a lower end of the polishing mechanism 1, the extruding mechanism 3 is disposed at a lower end of the first cleaning mechanism 2, and the second cleaning mechanism 4 is disposed at an upper end of the extruding mechanism 3; the chippings polished by the lens 13 are washed through the water inlet pipe 112, when the chippings and water fall to the upper end of the water permeable plate 24, the chippings are accumulated at the upper end of the water permeable plate 24, the water is discharged out of the device through the water outlet pipe 33 through the water permeable plate 24 and the sponge 25, the third hydraulic telescopic rod 21 is started to clean the chippings, when the pushing block 22 reaches the leftmost end, the pressing rod 23 pushes the piston 27, so that the pushing block 22 cleans the debris to the second shell 29, the debris can be further filtered by arranging the sponge 25, when the piston 27 moves leftwards, the first wire rope 31 is pulled to drive the wire mesh 26 to squeeze the sponge 25, so that the water in the sponge 25 is squeezed out, when the third hydraulic telescopic rod 21 moves leftwards, the second steel wire rope 41 is driven to pull the cleaning block 43 to clean the glass window 111, and the adhered chips on the glass window 111 are cleaned, so that the polishing condition can be observed conveniently.

Specifically, the polishing mechanism 1 comprises a first hydraulic telescopic rod 11, the lower end of the first hydraulic telescopic rod 11 is fixedly connected with a second hydraulic telescopic rod 12, the side wall of the second hydraulic telescopic rod 12 is slidably connected with a shell 17, one end of the second hydraulic telescopic rod 12 is fixedly connected with a stepping motor 113, one end of the stepping motor 113 is tightly attached to a lens 13, one end of the shell 17 is fixedly connected with a first shell 18, one end of the first shell 18 is fixedly connected with a motor 14, one end of the motor 14 is fixedly connected with a rotating rod 15, one end of the rotating rod 15 is fixedly connected with a polishing block 16, one end of the first shell 18 is fixedly connected with the shell 17, one end of the shell 17 is provided with a sliding door 19, one end of the sliding door 19 is fixedly connected with a handle 110, the upper end of the shell 17 is provided with a glass window 111, the upper end of the lens 13 is provided with a water inlet pipe 112, the side wall of the water inlet pipe 112 is fixedly connected with the shell 17; at first carry out the centre gripping through circuit board control second hydraulic telescoping rod 12 to lens 13 fixed, polish to lens 13 laminating sanding block 16 through controlling first hydraulic telescoping rod 11 and step motor 113, starter motor 14, motor 14 rotates and drives dwang 15 and rotate, dwang 15 rotates and drives sanding block 16 and rotate, sanding block 16 rotates and polishes lens 13, can produce more piece when polishing lens 13, water through inlet tube 112 inside in time washes lens 13.

Specifically, the first cleaning mechanism 2 comprises a third hydraulic telescopic rod 21, one end of the third hydraulic telescopic rod 21 is fixedly connected with the first shell 18, one end of the third hydraulic telescopic rod 21 is fixedly connected with a pushing block 22, the side wall of the pushing block 22 is fixedly connected with an extrusion rod 23, the lower end of the pushing block 22 is provided with a water permeable plate 24, the side wall of the water permeable plate 24 is fixedly connected with the shell 17, the lower end of the permeable plate 24 is provided with a sponge 25, the lower end of the sponge 25 is provided with a wire netting 26, the side wall of the wire mesh 26 is connected with the shell 17 in a sliding way, one end of the extrusion rod 23 is provided with a piston 27, one end of the piston 27 is fixedly connected with the first sliding block 210, one end of the first sliding block 210 is slidably connected with the second shell 29, one end of the second shell 29 is fixedly connected with the shell 17, the side wall of the piston 27 is fixedly connected with the first spring 28, and one end of the first spring 28 is fixedly connected with the second shell 29; piece and water fall to the upper end of porous disk 24, regularly start third hydraulic telescoping rod 13, third hydraulic telescoping rod 13 moves left and drives and promote piece 22 and move left, the in-process that promotes piece 22 and move left can drive the extrusion stem 23 and move left, can clear up the piece of piling up in the porous disk 24 upper end left promoting piece 22, can promote piston 27 when extrusion stem 23 reachs the leftmost end, piston 27 can compress first spring 28, the piece can be promoted piece 22 and promote second casing 29 like this, wash clastic water and can further filter the piece through sponge 25 through porous disk 24.

Specifically, the extrusion mechanism 3 includes a first steel wire rope 31, one end of the first steel wire rope 31 is fixedly connected with the piston 27, the side wall of the first steel wire rope 31 is tightly attached to a first rotating pin 32, one end of the first rotating pin 32 is rotatably connected with the outer shell 17, the lower end of the first steel wire rope 31 is fixedly connected with the wire netting 26, the lower end of the wire netting 26 is provided with a water outlet pipe 33, and the side wall of the water outlet pipe 33 is fixedly connected with the outer shell 17; when the piston 27 moves to the left, the first wire rope 31 is pulled to move upwards, the first wire rope 31 drives the wire 26 to move upwards when moving upwards, and the wire 26 presses the sponge 25 when moving upwards.

Specifically, the second cleaning mechanism 4 includes a second wire rope 41, one end of the second wire rope 41 is fixedly connected to the third hydraulic telescopic rod 21, a side wall of the second wire rope 41 is rotatably connected to a second rotating pin 42, one end of the second rotating pin 42 is rotatably connected to the housing 17, one end of the second wire rope 41 is fixedly connected to the cleaning block 43, one end of the cleaning block 43 is fixedly connected to a second sliding block 44, the second sliding block 44 is disposed inside the sleeve 45, the sleeve 45 is disposed inside the housing 17, a second spring 46 is disposed at a lower end of the second sliding block 44, the second spring 46 is disposed inside the sleeve 45, and an upper end of the cleaning block 43 is tightly attached to the glass window 111; more chips can be attached to the bottom end of the glass window 111 to influence the observation sight in the polishing process, the second steel wire rope 41 can be pulled to move leftwards in the leftward movement process of the third hydraulic telescopic rod 21, and the second steel wire rope 41 can drive the cleaning block 43 to wipe the glass window 111 in the leftward movement process, so that the polishing condition can be observed conveniently.

When the invention is used, the second hydraulic telescopic rod 12 is controlled by the circuit board to clamp and fix the lens 13, the first hydraulic telescopic rod 11 and the stepping motor 113 are controlled to polish the lens 13 attached to the polishing block 16, the motor 14 is started, the motor 14 rotates to drive the rotating rod 15 to rotate, the rotating rod 15 rotates to drive the polishing block 16 to rotate, the polishing block 16 rotates to polish the lens 13, more debris is generated when the lens 13 is polished, the lens 13 is timely washed by water in the water inlet pipe 112, the debris and the water fall to the upper end of the water permeable plate 24, the third hydraulic telescopic rod 13 is started at regular time, the third hydraulic telescopic rod 13 moves leftwards to drive the pushing block 22 to move leftwards, the pushing block 22 drives the extrusion rod 23 to move leftwards in the process of moving leftwards, and the pushing block 22 cleans the debris accumulated at the upper end of the water permeable plate 24 leftwards, when the extrusion rod 23 reaches the leftmost end, the piston 27 is pushed, the piston 27 compresses the first spring 28, the fragments are pushed to the second shell 29 by the pushing block 22, water for washing the fragments can further filter the fragments through the sponge 25 through the water permeable plate 24, finally clean water can be discharged from the water outlet pipe 33, the first steel wire rope 31 can be pulled to move upwards in the leftward movement process of the piston 27, the first steel wire rope 31 can drive the wire net 26 to move upwards in the upward movement process, the wire net 26 can extrude the sponge 25 in the upward movement process, more fragments can be attached to the bottom end of the glass window 111 to influence the observation sight line in the polishing process, the second steel wire rope 41 can be pulled to move leftwards in the leftward movement process of the third hydraulic telescopic rod 21, the cleaning block 43 can be driven to clean the glass window 111 by the leftward movement of the second steel wire rope 41, and the polishing condition can be observed conveniently.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the embodiments and descriptions given above are only illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides an optical lens piece equipment of polishing that precision instruments used which characterized in that: the polishing machine comprises a polishing mechanism (1), a first cleaning mechanism (2), an extrusion mechanism (3) and a second cleaning mechanism (4), wherein the first cleaning mechanism (2) is arranged at the lower end of the polishing mechanism (1), the extrusion mechanism (3) is arranged at the lower end of the first cleaning mechanism (2), and the second cleaning mechanism (4) is arranged at the upper end of the extrusion mechanism (3);

grinding machanism (1) includes first hydraulic telescoping rod (11), first hydraulic telescoping rod (11) lower extreme and second hydraulic telescoping rod (12) fixed connection, second hydraulic telescoping rod (12) lateral wall and shell (17) sliding connection, second hydraulic telescoping rod (12) one end and step motor (113) fixed connection, step motor (113) one end closely laminates with lens (13), shell (17) one end and first casing (18) fixed connection, first casing (18) one end and motor 14 fixed connection.

2. An optical lens polishing apparatus for a precision instrument as set forth in claim 1, wherein: grinding machanism (1) still includes dwang (15), motor (14) one end and dwang (15) fixed connection, dwang (15) one end and sanding block (16) fixed connection, first casing (18) one end and shell (17) fixed connection, shell (17) one end is equipped with sliding door (19), sliding door (19) one end and handle (110) fixed connection, shell (17) upper end is equipped with glass window (111), lens (13) upper end is equipped with inlet tube (112), inlet tube (112) lateral wall and shell (17) fixed connection.

3. An optical lens polishing apparatus for a precision instrument as set forth in claim 2, wherein: first clearance mechanism (2) include third hydraulic telescoping rod (21), third hydraulic telescoping rod (21) one end and first casing (18) fixed connection, third hydraulic telescoping rod (21) one end with promote piece (22) fixed connection, promote piece (22) lateral wall and extrusion stem (23) fixed connection, it is equipped with porous disk (24) to promote piece (22) lower extreme, porous disk (24) lateral wall and shell (17) fixed connection.

4. An optical lens polishing apparatus for a precision instrument as set forth in claim 3, wherein: first clearance mechanism (2) still include sponge (25), porous disk (24) lower extreme is equipped with sponge (25), sponge (25) lower extreme is equipped with wire netting (26), wire netting (26) lateral wall and shell (17) sliding connection, extrusion stem (23) one end is equipped with piston (27).

5. An optical lens polishing apparatus for a precision instrument as set forth in claim 4, wherein: first clearance mechanism (2) still include first sliding block (210), piston (27) one end and first sliding block (210) fixed connection, first sliding block (210) one end and second casing (29) sliding connection, second casing (29) one end and shell (17) fixed connection, piston (27) lateral wall and first spring (28) fixed connection, first spring (28) one end and second casing (29) fixed connection.

6. An optical lens polishing apparatus for a precision instrument as set forth in claim 5, wherein: the extrusion mechanism (3) comprises a first steel wire rope (31), and one end of the first steel wire rope (31) is fixedly connected with the piston (27).

7. An optical lens polishing apparatus for a precision instrument as claimed in claim 6, wherein: extrusion mechanism (3) still include first round pin (32) that rotates, first wire rope (31) lateral wall is closely laminated with first round pin (32) that rotates, first round pin (32) one end that rotates is rotated with shell (17) and is connected, first wire rope (31) lower extreme and wire netting (26) fixed connection, wire netting (26) lower extreme is equipped with outlet pipe (33), outlet pipe (33) lateral wall and shell (17) fixed connection.

8. An optical lens polishing apparatus for a precision instrument as set forth in claim 7, wherein: the second cleaning mechanism (4) comprises a second steel wire rope (41), and one end of the second steel wire rope (41) is fixedly connected with the third hydraulic telescopic rod (21).

9. An optical lens polishing apparatus for a precision instrument as set forth in claim 8, wherein: second clearance mechanism (4) still include second rotating pin (42), second wire rope (41) lateral wall rotates with second rotating pin (42) to be connected, second rotating pin (42) one end rotates with shell (17) to be connected, second wire rope (41) one end and clearance piece (43) fixed connection, clearance piece (43) one end and second sliding block (44) fixed connection.

10. An optical lens polishing apparatus for a precision instrument as set forth in claim 9, wherein: second clearance mechanism (4) still include sleeve (45), second sliding block (44) set up inside sleeve (45), sleeve (45) set up inside shell (17), second sliding block (44) lower extreme is equipped with second spring (46) and closely laminates, second spring (46) set up inside sleeve (45), clearance piece (43) upper end and glass window (111) closely laminate.