CN115229604A

CN115229604A - Optical lens piece chamfer processing equipment

Info

Publication number: CN115229604A
Application number: CN202210942465.3A
Authority: CN
Inventors: 刘武
Original assignee: Jiangxi Xinhe Photoelectric Co ltd
Current assignee: Jiangxi Xinhe Photoelectric Co ltd
Priority date: 2022-08-08
Filing date: 2022-08-08
Publication date: 2022-10-25

Abstract

The invention relates to the technical field of chamfering, in particular to optical lens chamfering equipment. The invention provides an optical lens chamfering processing device which can limit an optical lens and is not easy to fall off. An optical lens chamfering processing device comprises a processing rack; the bottom in the processing rack is connected with a servo motor; the bottom in the processing machine frame is connected with a guide frame; the middle part of the guide frame is rotatably connected with the rotating support frame, and the lower part of the rotating support frame is connected with an output shaft of the servo motor; the optical lens is placed at the top of the rotary support frame; the upper part in the processing rack is connected with the righting clamping mechanism; the left side in the processing frame is connected with a polishing adjusting mechanism. According to the invention, the first spring is reset to drive the rotating clamping block to move inwards to clamp and limit the optical lens, so that the optical lens can be prevented from being separated from the rotating support frame during polishing.

Description

Optical lens piece chamfer processing equipment

Technical Field

The invention relates to the technical field of chamfering, in particular to optical lens chamfering equipment.

Background

In the production and processing industry of optical lenses, chamfering is generally required to be carried out on the produced lenses, especially in the processing of high-precision optical lenses, and besides the requirement on plane precision, the requirements on appearance precision and chamfering angle of the high-precision optical lenses are also high.

The patent publication is CN216179193U, discloses an optical lens piece excircle chamfer processingequipment, the first install bin of base top left side fixedly connected with, fixing base right side fixedly connected with optical lens piece adsorbs the seat, base top right side fixedly connected with work box, work box top fixedly connected with collects the box, the inside fixedly connected with elevating system of first install bin, the inside fixedly connected with disassembly body of work box, the spout is seted up in the first install bin left and right sides, spout surface sliding connection has the second install bin, second install bin top and fixing base bottom are connected. However, when the device is used for positioning the optical lens, the optical lens is only adsorbed by the optical lens adsorption seat, then the optical lens is driven to rotate to be in contact with the grinding wheel, and the optical lens is polished by the grinding wheel, so that the optical lens is easy to fall off, and economic loss is caused.

To sum up, need to develop one kind and can carry out spacing, and be difficult to the optical lens chamfer processing equipment that drops to optical lens.

Disclosure of Invention

Aiming at overcoming the defect that the optical lens is easy to fall off when being polished because the optical lens is only adsorbed by the optical lens adsorption seat when being fixed in the prior art, the invention provides the optical lens chamfering processing equipment which can limit the optical lens and is difficult to fall off.

In order to achieve the above purpose, the invention is realized by the following scheme: an optical lens chamfering apparatus comprising:

processing the frame;

the bottom in the processing rack is connected with a servo motor;

the bottom in the processing machine frame is connected with a guide frame;

the middle part of the guide frame is rotatably connected with the rotating support frame, and the lower part of the rotating support frame is connected with an output shaft of the servo motor;

the optical lens is placed at the top of the rotary support frame;

the upper part in the processing rack is connected with a positive clamping mechanism for clamping the optical lens, and the positive clamping mechanism moves towards the inner side to clamp the optical lens so as to prevent the optical lens from moving during polishing;

the polishing adjusting mechanism is connected with the polishing adjusting mechanism used for polishing the optical lenses on the left side inside the processing rack, controls the polishing adjusting mechanism to move left, and drives the polishing adjusting mechanism to polish the optical lenses of different models.

Further, it is particularly preferable that the right clamping mechanism includes:

the top in the processing rack is connected with a cylinder;

the telescopic clamping assembly is connected with telescopic clamping assembly at the telescopic link downside of cylinder, and telescopic clamping assembly is used for pressing from both sides tight spacing to optical lens piece, prevents that optical lens piece breaks away from with the rotation support frame when polishing.

Furthermore, it is particularly preferred that the telescopic clamping assembly comprises:

the lower side of a telescopic rod of the air cylinder is connected with the three-way connecting plate;

the outer sides of the three-way connecting plates are evenly and alternately connected with three first L-shaped connecting rods in a sliding manner;

the bottoms of the three first L-shaped connecting rods are rotatably connected with the rotating clamping blocks for clamping the optical lens;

the first spring, three first L shape connecting rod inboard all with three-dimensional connecting plate internal connection have a spring, through first spring reset, drive first L shape connecting rod and rotate and press from both sides tight piece and move towards the inboard and press from both sides tight spacing to optical lens, prevent that optical lens can take place the displacement when polishing.

Further, it is particularly preferable that the dressing adjustment mechanism includes:

the middle part of the left wall in the processing rack is connected with a guide rod;

the right side of the guide rod is connected with a sliding block in a sliding manner;

the left side of the guide rod is sleeved with a second spring, and two ends of the second spring are respectively connected with the processing rack and the sliding block;

the polishing motor is connected inside the sliding block;

the polishing wheel is connected with the polishing wheel on the output shaft of the polishing motor, the polishing wheel is in contact with the edge of the optical lens, the polishing motor and the polishing wheel are driven to move left through the pulling sliding block to move left, the polishing motor and the polishing wheel are driven to move left to give way for the optical lenses of different models, and the polishing wheel is prevented from influencing the feeding of the optical lenses of different models.

Further, it is particularly preferable that the optical lens driving device further includes a return mechanism for automatically releasing the optical lens, and the return mechanism includes:

the left side, the right side and the rear side of the inner wall of the processing rack are both connected with guide rails;

the lower parts of the three guide rails are connected with sliding plates in a sliding way;

the lower parts of the three guide rails are sleeved with two third springs, and two ends of each third spring are respectively connected with the lower parts of the guide rails and the bottom of the sliding plate;

the elastic pull ropes are connected to the outer sides of the three first L-shaped connecting rods, the left end of the elastic pull rope on the left side penetrates through the sliding plate on the left side to be connected with the left lower side of the inner wall of the processing rack, the right end of the elastic pull rope on the right side penetrates through the sliding plate on the right side to be connected with the right lower side of the inner wall of the processing rack, and the rear end of the elastic pull rope on the rear side penetrates through the sliding plate on the rear side to be connected with the rear lower side of the inner wall of the processing rack;

the top of each of the three sliding plates is connected with a second L-shaped connecting rod, the inner sides of the three second L-shaped connecting rods are in contact with the three-way connecting plate, the sliding plates are driven to move upwards through the second L-shaped connecting rods to tension the elastic pull ropes, and the elastic pull ropes drive the first L-shaped connecting rods and the rotating clamping blocks to move outwards to automatically loosen the optical lenses.

In addition, it is especially preferred that still include the positioning mechanism that polishes that is used for driving slider automatic movement, polish positioning mechanism including:

the left side of the sliding block is connected with the U-shaped connecting plate;

the right side of the upper part of the U-shaped connecting plate is connected with an arc rod;

the rotating sleeve is rotatably connected to the front side and the rear side of the arc-shaped rod, the rotating sleeve, the arc-shaped rod and the U-shaped connecting plate are driven to move to the left by moving the rotating clamping block to the outer side, and the U-shaped connecting plate is used for driving the sliding block to automatically move to the left.

Further, it is particularly preferable that the optical lens processing apparatus further includes an upper pressing mechanism for positioning the optical lens, the upper pressing mechanism including:

the connecting rod is rotatably connected inside a telescopic rod of the air cylinder;

the bottom of the connecting rod is connected with a pressing plate used for positioning the optical lens;

the pressing plate is connected with the lower portion of the cylinder, the top end of the cylinder is in contact with the telescopic rod of the cylinder, the cylinder moves downwards through the pressing plate to be in contact with the optical lens, and the pressing plate is driven to compress the optical lens under the action of the fourth spring.

In addition, it is particularly preferable that the optical lens cleaning apparatus further includes a lower suction mechanism for sucking the optical lens, and the lower suction mechanism includes:

the rotary support frame is hollow, and the inside of the rotary support frame is connected with the air pumping frame in a sliding manner;

the bottom of the air exhaust frame and the bottom in the rotating support frame are connected with a fifth spring;

rubber adsorbs the cover, and the frame top of bleeding is connected with rubber and adsorbs the cover, and rubber adsorbs the cover and is rotating support frame upper portion, down takes out optical lens and the air between the rotation support frame through the frame down removal of bleeding, adsorbs optical lens on rotating the support frame, can't drive optical lens when preventing to rotate the support frame and rotate.

The invention has the following advantages: according to the invention, the rotary clamping block is driven to move inwards to clamp and limit the optical lens by resetting the first spring, so that the optical lens can be prevented from being separated from the rotary supporting frame during polishing; the three-way connecting plate moves upwards to drive the second L-shaped connecting rod and the sliding plate to move upwards, so that the elastic pull rope is tensioned, and the first L-shaped connecting rod is driven by the elastic pull rope to move outwards, so that the optical lens is automatically loosened by rotating the clamping block; the clamping block is rotated to move towards the outer side to drive the rotating sleeve and the arc-shaped rod, so that the U-shaped connecting plate automatically drives the sliding block and the polishing motor to move towards the left side, the polishing motor can be automatically driven to move, the sliding block does not need to be manually controlled to drive the polishing motor to move towards the left side, and operation trouble can be reduced; the pressing plate moves downwards to be in contact with the optical lens, so that the pressing plate presses the optical lens, and the optical lens is prevented from being driven to move upwards when the rotating clamping block moves upwards; drive the rubber through optical lens and adsorb the cover and down remove to make air exhaust frame down remove with optical lens and rotate the air between the support frame and down take out, make optical lens adsorbed on rotating the support frame, so, can further fix optical lens, stability when improving optical lens and polish.

Drawings

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

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

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

Fig. 4 is a schematic sectional perspective view of the normal clamping mechanism of the present invention.

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

Fig. 6 is an enlarged schematic perspective view of the invention at a.

Fig. 7 is a schematic sectional perspective view of the return mechanism of the present invention.

FIG. 8 is an enlarged perspective view of the present invention at B.

Fig. 9 is a schematic perspective view of the sanding positioning mechanism of the present invention.

Fig. 10 is a perspective view of the upper pressing mechanism of the present invention.

Fig. 11 is a schematic sectional perspective view of the lower adsorption mechanism of the present invention.

In the figure: 1. the device comprises a processing rack, 2, a servo motor, 3, a rotary supporting frame, 4, a guide frame, 5, an optical lens, 6, a righting clamping mechanism, 61, an air cylinder, 62, a three-way connecting plate, 63, a first L-shaped connecting rod, 64, a rotary clamping block, 65, a first spring, 7, a grinding adjusting mechanism, 71, a guide rod, 72, a sliding block, 73, a second spring, 74, a grinding motor, 75, a grinding wheel, 8, a returning mechanism, 81, a guide rail, 82, a sliding plate, 83, a third spring, 84, an elastic pull rope, 85, a second L-shaped connecting rod, 9, a grinding positioning mechanism, 91, a U-shaped connecting plate, 92, an arc-shaped rod, 93, a rotary sleeve, 10, an upper pressing mechanism, 101, a connecting rod, 102, a pressing plate, 103, a fourth spring, 11, a lower adsorption mechanism, 1101, an air suction frame, 1102, a rubber adsorption sleeve, 1103 and a fifth spring.

Detailed Description

The invention is further described with reference to the following drawings and detailed description:

example 1

The utility model provides an optical lens piece chamfer processing equipment, as shown in figure 1, figure 2 and figure 3, including processing frame 1, servo motor 2, rotate the support frame 3, leading truck 4, optical lens piece 5, positive clamping mechanism 6 and polishing adjustment mechanism 7, the bottom has servo motor 2 through the bolt rigid coupling in processing frame 1, the bottom has leading truck 4 through the bolt rigid coupling in processing frame 1, leading truck 4 middle part rotary type is connected with and rotates support frame 3, the output shaft that rotates support frame 3 lower part and servo motor 2 passes through the coupling joint, optical lens piece 5 has been placed at rotation support frame 3 top, upper portion is connected with positive clamping mechanism 6 in processing frame 1, positive clamping mechanism 6 is used for pressing from both sides tight optical lens piece 5, the inside left side of processing frame 1 is connected with polishing adjustment mechanism 7, polishing adjustment mechanism 7 is used for polishing optical lens piece 5.

As shown in fig. 2 and 4, the normal clamping mechanism 6 includes a cylinder 61 and a telescopic clamping assembly, the cylinder 61 is fixedly connected to the top of the processing frame 1 through a bolt, the telescopic rod of the cylinder 61 is connected to the telescopic clamping assembly, and the telescopic clamping assembly is used for clamping and limiting the optical lens 5, so as to prevent the optical lens 5 from separating from the rotating support frame 3 when being polished.

As shown in fig. 2 and 4, the telescopic clamping assembly includes a three-way connecting plate 62, first L-shaped connecting rods 63, a rotary clamping block 64 and first springs 65, the three-way connecting plate 62 is connected to the lower side of the telescopic rod of the cylinder 61, three first L-shaped connecting rods 63 are slidably connected to the outer side of the three-way connecting plate 62 at regular intervals, the rotary clamping block 64 is rotatably connected to the bottoms of the three first L-shaped connecting rods 63, the rotary clamping block 64 is used for clamping the optical lens 5, and the first springs 65 are connected to the inner sides of the three first L-shaped connecting rods 63 and the three-way connecting plate 62.

As shown in fig. 1, 2, 5 and 6, the polishing adjusting mechanism 7 includes a guide rod 71, a slider 72, a second spring 73, a polishing motor 74 and a polishing wheel 75, the guide rod 71 is welded at the middle of the left wall in the processing frame 1, the slider 72 is slidably connected to the right side of the guide rod 71, the second spring 73 is sleeved on the left side of the guide rod 71, two ends of the second spring 73 are respectively connected with the processing frame 1 and the slider 72, the polishing motor 74 is connected inside the slider 72, the polishing wheel 75 is connected to the output shaft of the polishing motor 74, and the polishing wheel 75 is in contact with the edge of the optical lens 5.

When the device is used, the sliding block 72 is pulled to the left, the second spring 73 is compressed at the moment, the sliding block 72 drives the polishing motor 74 and the polishing wheel 75 to move to the left, then the optical lens 5 is placed at the top of the rotating support frame 3, then the air cylinder 61 is started, the telescopic rod of the air cylinder 61 extends to drive the three-way connecting plate 62, the first L-shaped connecting rod 63 and the rotating clamping block 64 to move downwards, meanwhile, a worker manually pulls the first L-shaped connecting rod 63 and the rotating clamping block 64 to the outer side, at the moment, the first spring 65 is stretched, so that the rotating clamping block 64 cannot be limited by the optical lens 5 when the rotating clamping block 64 moves downwards, after the position is reduced to a certain degree, the air cylinder 61 is closed, the first L-shaped connecting rod 63 is loosened, at the moment, the first spring 65 resets, the rotating clamping block 64 is driven to move inwards to reset to be contacted with the optical lens 5, and the rotating clamping block 64 clamps the optical lens 5, and thus, can carry on spacingly to optical lens 5, avoid optical lens 5 to take place the displacement when polishing, loosen slider 72 afterwards, second spring 73 resets this moment, drive slider 72, grinding motor 74 and grinding wheel 75 move to the right and reset, make grinding wheel 75 contact with the edge of optical lens 5, start servo motor 2 and grinding motor 74 afterwards, servo motor 2 drives rotation support frame 3 and optical lens 5 and rotate, grinding motor 74 drives grinding wheel 75 and rotates, make grinding wheel 75 polish the edge of optical lens 5, so, can polish optical lens 5 of different models, finish polishing, close grinding motor 74 and servo motor 2, will polish the finished optical lens 5 and take out afterwards, first spring 65 resets this moment, drive first L-shaped connecting rod 63 and rotate and press from both sides tight piece 64 and move to the inboard and reset, restart cylinder 61, the telescopic rod of the control cylinder 61 contracts to drive the three-way connecting plate 62, the first L-shaped connecting rod 63 and the rotating clamping block 64 to move upwards for resetting.

Example 2

On the basis of embodiment 1, as shown in fig. 1, 2, 7 and 8, the optical lens processing device further includes a return mechanism 8, the return mechanism 8 is used for automatically releasing the optical lens 5, the return mechanism 8 includes a guide rail 81, sliding plates 82, three springs 83, elastic pull ropes 84 and three second L-shaped connecting rods 85, the guide rails 81 are welded on the left side, the right side and the rear side of the inner wall of the processing rack 1, the sliding plates 82 are connected to the lower portions of the three guide rails 81 in a sliding manner, the two third springs 83 are sleeved on the lower portions of the three guide rails 81, the six third springs 83 are provided, the two ends of the third springs 83 are respectively connected to the lower portions of the guide rails 81 and the bottoms of the sliding plates 82, the elastic pull ropes 84 are connected to the outer sides of the three first L-shaped connecting rods 63, the left ends of the left elastic pull ropes 84 penetrate through the left sliding plates 82 to be connected to the left lower portions of the inner wall of the processing rack 1, the right ends of the right elastic pull ropes 84 penetrate the sliding plates 82 to be connected to the right lower portions of the inner wall of the processing rack 1, the rear ends of the rear elastic pull ropes 84 penetrate the rear sliding plates 82 to be connected to the lower portions of the inner wall of the processing rack 1, the three second L-shaped connecting rods 85 are welded to be connected to the three third L-shaped connecting plates 62. When the three-way connecting plate 62 moves downward, the third spring 83 in the initial state of the stretching state resets at this time, the sliding plate 82 and the second L-shaped connecting rod 85 are driven to move downward, the elastic pulling rope 84 is loosened, at this time, the first L-shaped connecting rod 63 moves inward and resets under the resetting action of the first spring 65, the rotating clamping block 64 is driven to move inward to clamp the optical lens 5, when the three-way connecting plate 62 moves upward and resets, the second L-shaped connecting rod 85 and the sliding plate 82 are driven to move upward, the third spring 83 is stretched at this time, the elastic pulling rope 84 is tensioned, the first L-shaped connecting rod 63 and the rotating clamping block 64 are driven to move outward through the elastic pulling rope 84, the rotating clamping block 64 automatically releases the optical lens 5, and thus, the optical lens 5 can be automatically released and clamped automatically, the rotating clamping block 64 does not need to be manually controlled by a worker to release the optical lens 5, and the operation difficulty is reduced.

As shown in fig. 1, 2 and 9, the polishing machine further comprises a polishing positioning mechanism 9, the polishing positioning mechanism 9 is used for driving the sliding block 72 to move automatically, the polishing positioning mechanism 9 comprises a U-shaped connecting plate 91, an arc-shaped rod 92 and a rotating sleeve 93, the U-shaped connecting plate 91 is welded on the left side of the sliding block 72, the arc-shaped rod 92 is welded on the right side of the upper part of the U-shaped connecting plate 91, and the rotating sleeve 93 is rotatably connected to the front side and the rear side of the arc-shaped rod 92. When rotating clamping block 64 and moving toward the outside, it moves toward the left side automatically to drive and rotate cover 93 and arc pole 92, and then drive slider 72 and grinding motor 74 through U-shaped connecting plate 91 and move toward the left side, so, can realize that automatic drive grinding motor 74 removes, just need not manual control slider 72 and drive grinding motor 74 and move toward the left side, can reduce troublesome poeration, when rotating clamping block 64 and moving toward the inboard, slider 72 is under the reset action of second spring 73, drive grinding motor 74, U-shaped connecting plate 91, arc pole 92 and rotation cover 93 move to the right side and reset.

As shown in fig. 1, 2 and 10, the optical lens positioning device further includes an upper pressing mechanism 10, the upper pressing mechanism 10 is used for positioning the optical lens 5, the upper pressing mechanism 10 includes a connecting rod 101, a pressing plate 102 and a fourth spring 103, the connecting rod 101 is rotatably connected inside the telescopic rod of the cylinder 61, the pressing plate 102 is connected to the bottom of the connecting rod 101, the pressing plate 102 is used for positioning the optical lens 5, the fourth spring 103 is connected to the lower portion of the pressing plate 102, and the top end of the fourth spring 103 is in contact with the telescopic rod of the cylinder 61. When the telescopic link of cylinder 61 is elongated, drive connecting rod 101 and clamp plate 102 down move to with optical lens 5 contact, fourth spring 103 plays the cushioning effect here, drive clamp plate 102 simultaneously and compress tightly optical lens 5, can drive optical lens 5 and up move when avoiding rotating clamp block 64 and up moving, when the telescopic link of cylinder 61 contracts, drive connecting rod 101 and clamp plate 102 up move and reset, make clamp plate 102 loosen optical lens 5.

As shown in fig. 2 and fig. 11, the optical lens cleaning device further includes a lower adsorption mechanism 11, the lower adsorption mechanism 11 is used for adsorbing the optical lens 5, the lower adsorption mechanism 11 includes an air suction frame 1101, a rubber adsorption sleeve 1102 and a fifth spring 1103, the rotating support frame 3 is of a hollow type, the rotating support frame 3 is connected with the air suction frame 1101 in a sliding manner, the fifth spring 1103 is connected to the bottom of the air suction frame 1101 and the inner bottom of the rotating support frame 3, the rubber adsorption sleeve 1102 is connected to the top of the air suction frame 1101, and the rubber adsorption sleeve 1102 is sleeved on the upper portion of the rotating support frame 3. Put optical lens 5 at rotation support frame 3 and rubber absorption cover 1102 top, when clamp plate 102 down moves extrusion optical lens 5, drive optical lens 5 and move down, optical lens 5 drives rubber absorption cover 1102 and moves down, rubber absorption cover 1102 drives air exhaust frame 1101 and moves down, fifth spring 1103 is compressed this moment, make air exhaust frame 1101 take out the air between optical lens 5 and the rotation support frame 3 down, adsorb optical lens 5 on rotation support frame 3, so, can further fix a position optical lens 5, stability when improving optical lens 5 and polish, when clamp plate 102 up moves to when separating with optical lens 5, fifth spring 1103 resets this moment, drive air exhaust frame 1101 and rubber absorption cover 1102 and move up and reset, make air exhaust frame 1101 push out in the rotation support frame 3, thereby make rotation support frame 3 no longer adsorb optical lens 5.

It should be understood by those skilled in the art that the above embodiments do not limit the present invention in any way, and all technical solutions obtained by using equivalent alternatives or equivalent variations fall within the scope of the present invention.

Claims

1. An optical lens piece chamfer processing equipment, characterized by: comprises the following steps:

a processing frame (1);

the bottom in the processing rack (1) is connected with the servo motor (2);

the guide frame (4) is connected with the bottom in the processing rack (1);

the middle part of the guide frame (4) is rotatably connected with the rotating support frame (3), and the lower part of the rotating support frame (3) is connected with an output shaft of the servo motor (2);

the optical lens (5) is placed at the top of the rotary support frame (3);

the upper part in the processing rack (1) is connected with a righting clamping mechanism (6) for clamping the optical lens (5), and the righting clamping mechanism (6) moves towards the inner side to clamp the optical lens (5) so as to prevent the optical lens (5) from displacing during polishing;

polishing adjusting mechanism (7), processing frame (1) inside left side is connected with and is used for polishing adjusting mechanism (7) to optical lens (5), and control polishing adjusting mechanism (7) moves left, drives polishing adjusting mechanism (7) and polishes optical lens (5) of different models.

2. The optical lens chamfering apparatus as claimed in claim 1, wherein: the righting clamping mechanism (6) comprises:

the air cylinder (61) is connected to the inner top of the processing rack (1);

the telescopic clamping assembly is connected with the telescopic clamping assembly at the lower side of a telescopic rod of the cylinder (61), and the telescopic clamping assembly is used for clamping and limiting the optical lens (5) and preventing the optical lens (5) from being separated from the rotating support frame (3) when being polished.

3. The optical lens chamfering processing apparatus as claimed in claim 2, wherein: the telescopic clamping assembly comprises:

the lower side of a telescopic rod of the cylinder (61) is connected with the three-way connecting plate (62);

the outer sides of the three-way connecting plates (62) are evenly and alternately connected with three first L-shaped connecting rods (63) in a sliding manner;

the bottoms of the three first L-shaped connecting rods (63) are respectively and rotatably connected with a rotating clamping block (64) used for clamping the optical lens (5);

first spring (65), three first L shape connecting rod (63) inboard all with three-way connecting plate (62) internal connection have first spring (65), reset through first spring (65), drive first L shape connecting rod (63) and rotate and press from both sides tight piece (64) and move to the inboard and press from both sides tight spacing to optical lens (5), prevent that optical lens (5) can take place the displacement when polishing.

4. An optical lens chamfering processing apparatus according to claim 3, wherein: the grinding adjusting mechanism (7) comprises:

the middle part of the left wall in the processing rack (1) is connected with a guide rod (71);

the right side of the guide rod (71) is connected with the sliding block (72) in a sliding manner;

the second spring (73) is sleeved on the left side of the guide rod (71), and two ends of the second spring (73) are respectively connected with the processing rack (1) and the sliding block (72);

a grinding motor (74), wherein the inside of the sliding block (72) is connected with the grinding motor (74);

grinding wheel (75), be connected with grinding wheel (75) on the output shaft of grinding motor (74), grinding wheel (75) and optical lens (5) edge contact are turned left through pulling slider (72), drive grinding motor (74) and grinding wheel (75) and turn left the removal and be used for giving optical lens (5) of different models the position of stepping down, prevent that grinding wheel (75) from influencing optical lens (5) material loading of different models.

5. The optical lens chamfering apparatus according to claim 4, wherein: still including return mechanism (8) that are used for automatic unclamping optical lens (5), return mechanism (8) including:

the left side, the right side and the rear side of the inner wall of the processing rack (1) are connected with the guide rails (81);

the lower parts of the three guide rails (81) are connected with the sliding plates (82) in a sliding way;

the lower parts of the three guide rails (81) are sleeved with two third springs (83), and two ends of each third spring (83) are respectively connected with the lower parts of the guide rails (81) and the bottoms of the sliding plates (82);

elastic pull ropes (84) are connected to the outer sides of the three first L-shaped connecting rods (63), the left end of the elastic pull rope (84) on the left side penetrates through the sliding plate (82) on the left side to be connected with the left lower side of the inner wall of the processing rack (1), the right end of the elastic pull rope (84) on the right side penetrates through the sliding plate (82) on the right side to be connected with the right lower side of the inner wall of the processing rack (1), and the rear end of the elastic pull rope (84) on the rear side penetrates through the sliding plate (82) on the rear side to be connected with the rear lower side of the inner wall of the processing rack (1);

second L-shaped connecting rod (85), three slide (82) top all is connected with second L-shaped connecting rod (85), three second L-shaped connecting rod (85) inboard all contacts with three-way connecting plate (62), drives slide (82) through second L-shaped connecting rod (85) and moves up and take-up elasticity stay cord (84), elasticity stay cord (84) drive first L-shaped connecting rod (63) and rotate clamp tight piece (64) and move towards the lateral side and be used for automatic release optical lens (5).

6. The optical lens chamfering apparatus according to claim 5, wherein: still including being used for driving slider (72) automatically move's positioning mechanism (9) of polishing, positioning mechanism (9) of polishing including:

the left side of the sliding block (72) is connected with the U-shaped connecting plate (91);

the right side of the upper part of the U-shaped connecting plate (91) is connected with an arc-shaped rod (92);

the rotary sleeve (93) is rotatably connected with the front side and the rear side of the arc-shaped rod (92) in a rotating mode, the rotary sleeve (93), the arc-shaped rod (92) and the U-shaped connecting plate (91) are driven to move to the left by moving the rotary clamping block (64) to the outer side, and the U-shaped connecting plate (91) is used for driving the sliding block (72) to automatically move to the left.

7. The optical lens chamfering apparatus according to claim 6, wherein: the optical lens positioning device further comprises an upper pressing mechanism (10) used for positioning the optical lens (5), wherein the upper pressing mechanism (10) comprises:

the connecting rod (101) is rotatably connected inside a telescopic rod of the cylinder (61);

the bottom of the connecting rod (101) is connected with a pressing plate (102) used for positioning the optical lens (5);

the lower portion of the pressing plate (102) is connected with the fourth spring (103), the top end of the fourth spring (103) is in contact with a telescopic rod of the air cylinder (61), the pressing plate (102) moves downwards to be in contact with the optical lens (5), and the pressing plate (102) is driven to compress the optical lens (5) under the action of the fourth spring (103).

8. The optical lens chamfering apparatus as claimed in claim 1, wherein: further comprises a lower adsorption mechanism (11) used for adsorbing the optical lens (5), wherein the lower adsorption mechanism (11) comprises:

the rotary support frame (3) is hollow, and the inside of the rotary support frame (3) is connected with the air extraction frame (1101) in a sliding manner;

the bottom of the air extraction frame (1101) and the bottom in the rotary support frame (3) are connected with a fifth spring (1103);

rubber adsorbs cover (1102), and air exhaust frame (1101) top is connected with rubber and adsorbs cover (1102), and rubber adsorbs cover (1102) cover and is taken out down with the air between optical lens (5) and rotation support frame (3) through air exhaust frame (1101) down moving, adsorbs optical lens (5) on rotation support frame (3), can't drive optical lens (5) when preventing rotation support frame (3) and rotate.