CN114571318A

CN114571318A - Laser lens grinding device

Info

Publication number: CN114571318A
Application number: CN202210219841.6A
Authority: CN
Inventors: 刘群; 张玉军
Original assignee: Harbin University
Current assignee: Harbin University
Priority date: 2022-03-08
Filing date: 2022-03-08
Publication date: 2022-06-03
Anticipated expiration: 2042-03-08
Also published as: CN114571318B

Abstract

The invention relates to lens polishing, in particular to a laser lens polishing device which comprises a processing bracket, a clamping mechanism, a supporting mechanism, a lifting mechanism, a rotating mechanism, a swinging mechanism, an expanding mechanism and a polishing mechanism, wherein the processing bracket comprises a bottom bracket, a supporting ring and a gear ring frame, the clamping mechanism comprises a gear ring, a gear and a clamping arc plate, the supporting mechanism comprises a telescopic mechanism I and an arc cavity I, spheroid I and sucking disc I, elevating system includes telescopic machanism I and lifting support, slewing mechanism includes swivel becket, slip post and threaded rod, slewing mechanism includes swing bracket, rotating electrical machines, the swing connecting rod, slip connecting rod and circular arc cavity II, expanding mechanism includes spheroid II, telescopic machanism III, telescopic machanism IV, spheroid III, telescopic machanism V and spheroid IV, grinding mechanism is including the frame of polishing, circular arc cavity III and circular arc cavity IV, the radian that the camera lens was polished can be adjusted according to the user demand of difference.

Description

Laser lens grinding device

Technical Field

The invention relates to lens polishing, in particular to a laser lens polishing device.

Background

The optical lens has irreplaceable importance in the optics field, only a few countries in the world have comparatively perfect optical lens grinding technology at present, there is not a technology of adjusting the circular arc degree of polishing according to the user demand of difference in the prior art, for example patent No. CN214771042U, the name is an ultra-thin glass-plastic 4K lens grinding device, although the technical scheme of clamping and polishing the lens has been proposed in this patent, this patent does not point out how to adjust the radian of polishing according to the user demand of difference yet.

Disclosure of Invention

The invention aims to provide a laser lens polishing device which can adjust the polishing radian of a lens according to different use requirements.

The purpose of the invention is realized by the following technical scheme:

a laser lens polishing device comprises a processing bracket, a clamping mechanism, a supporting mechanism, a lifting mechanism, a rotating mechanism, a swinging mechanism, an expanding mechanism and a polishing mechanism;

the processing support comprises a bottom support, a support ring and a gear ring frame, wherein the support ring is fixedly connected to the bottom support, and the gear ring frame is fixedly connected to the support ring;

the clamping mechanism comprises a gear ring, a plurality of gears and clamping arc plates, the gear ring is rotationally connected to a gear ring frame, a power mechanism I for driving the gear ring to rotate is arranged on the gear ring, the power mechanism I is preferably a servo motor, the gears are provided with a plurality of gears, the gears are rotationally connected to a support ring, each gear is fixedly connected with a clamping arc plate, and the gears are in meshing transmission with the gear ring;

the support mechanism comprises a telescopic mechanism I, an arc cavity I, a ball I and suckers I, the arc cavity I is fixedly connected to the telescopic end of the telescopic mechanism I, the ball I is in clearance fit with the arc cavity I, the suckers I are fixedly connected to the ball I, sensors are arranged on the suckers I, the support mechanism is provided with a plurality of telescopic mechanisms I, the telescopic mechanisms I are fixedly connected to the bottom support, the sensors are connected with an upper computer, and the telescopic mechanisms I are connected with the upper computer;

the lifting mechanism comprises a telescopic mechanism II and a lifting support, the telescopic end of the telescopic mechanism II is fixedly connected with the lifting support, and the telescopic mechanism II is fixedly connected to the bottom support;

the rotating mechanism comprises a rotating ring, a sliding column and a threaded rod, the sliding column is fixedly connected to the rotating ring, the threaded rod is rotatably connected to the rotating ring, a power mechanism II for driving the threaded rod to rotate is arranged on the threaded rod, the power mechanism II is preferably a servo motor, the rotating ring is rotatably connected to the lifting support, a power mechanism IV for driving the rotating ring to rotate is arranged on the rotating ring, and the power mechanism IV is preferably a servo motor;

the swing mechanism comprises a swing support, a rotating motor, a swing connecting rod, a sliding connecting rod and an arc cavity II, the rotating motor is fixedly connected to the swing support, the swing support is connected to the threaded rod through threads, the swing support is connected to the sliding column in a sliding mode, the output shaft of the rotating motor is connected with the swing connecting rod in a rotating mode, the sliding connecting rod is connected to the swing connecting rod in a sliding mode, a power mechanism III for driving the swing connecting rod to rotate is arranged on the swing connecting rod, the power mechanism III is preferably a servo motor, and the arc cavity II is fixedly connected to the swing support;

the expansion mechanism comprises a ball II, a telescopic mechanism III, a telescopic mechanism IV, a ball III, a telescopic mechanism V and a ball IV, the ball II is in clearance fit in the arc cavity II, the lower end of the sliding connecting rod is hinged to the ball II, the lower end of the ball II is fixedly connected with a plurality of telescopic mechanisms III, the telescopic end of each telescopic mechanism III is fixedly connected with the telescopic mechanism IV, the telescopic end of each telescopic mechanism IV is fixedly connected with the ball III, the lower end of the ball II is fixedly connected with the telescopic mechanism V, and the telescopic end of the telescopic mechanism V is fixedly connected with the ball IV;

grinding machanism is including polishing frame, circular arc cavity III and circular arc cavity IV, and the last a plurality of circular arc cavities of fixedly connected with of polishing frame III, and a plurality of spheroid III clearance fit respectively are in a plurality of circular arc cavities III, and last a fixedly connected with circular arc cavity IV of polishing frame, spheroid IV clearance fit is in circular arc cavity IV.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic diagram of an overall structure of a laser lens polishing apparatus according to the present invention;

FIG. 2 is a schematic view of a processing fixture according to the present invention;

FIG. 3 is a schematic structural view of a clamping mechanism of the present invention;

FIG. 4 is a schematic view of the support mechanism of the present invention;

FIG. 5 is a schematic cross-sectional view of the support mechanism of the present invention;

FIG. 6 is a schematic view of the lift mechanism of the present invention;

FIG. 7 is a schematic view of the rotating mechanism of the present invention;

FIG. 8 is a schematic view of the swing mechanism of the present invention;

FIG. 9 is a schematic view of the expansion mechanism of the present invention;

figure 10 is a schematic diagram of the sanding mechanism of the present invention.

In the figure: processing the bracket 1; a bottom bracket 11; a support ring 12; a ring gear frame 13; a clamping mechanism 2; a ring gear 21; a gear 22; clamping the arc plate 23; a support mechanism 3; a telescoping mechanism I31; the arc cavity I32; a sphere I33; a suction cup I34; a lifting mechanism 4; a telescoping mechanism II 41; a lifting bracket 42; a rotating mechanism 5; a rotating ring 51; a slide post 52; a threaded rod 53; a swing mechanism 6; a swing bracket 61; a rotating electric machine 62; a swing link 63; a slide link 64; the arc cavity II 65; an expanding mechanism 7; a sphere II 71; a telescoping mechanism III 72; a telescoping mechanism IV 73; sphere III 74; a telescoping mechanism V75; a sphere IV 76; a polishing mechanism 8; a grinding frame 81; a circular arc cavity III 82; and the arc cavity IV 83.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1 to 10, in order to solve the technical problem of how to adjust the curvature of the lens polishing according to different requirements, the structure and function of a laser lens polishing apparatus will be described in detail;

a laser lens polishing device comprises a processing bracket 1, a clamping mechanism 2, a supporting mechanism 3, a lifting mechanism 4, a rotating mechanism 5, a swinging mechanism 6, an expanding mechanism 7 and a polishing mechanism 8;

when the device is used, the polishing mechanism 8 is driven by the expansion mechanism 7 to expand and deform, so that the bending angle of the polishing mechanism 8 is adjusted, the rotating mechanism 5 drives the swinging mechanism 6 to rotate, the swinging mechanism 6 drives the expansion mechanism 7 to rotate, the expansion mechanism 7 drives the polishing mechanism 8 to rotate, and the polishing mechanism 8 polishes the lens;

furthermore, a swinging mechanism 6 capable of swinging is further arranged, the position of the swinging mechanism 6 on the rotating mechanism 5 is adjusted, so that the rotating mechanism 5 drives the swinging mechanism 6 to eccentrically rotate when rotating, meanwhile, the swinging mechanism 6 adjusts the inclination degree of the expansion mechanism 7, further, the expansion mechanism 7 drives the polishing mechanism 8 to rotate, the inclination degree of the polishing mechanism 8 is adjusted, further, when the rotating mechanism 5 rotates, the polishing mechanism 8 is driven to eccentrically rotate, and the surface of the lens is polished in a large range and in multiple angles;

further, the polishing machine is also provided with a processing support 1, a clamping mechanism 2, a supporting mechanism 3 and a lifting mechanism 4, wherein the clamping mechanism 2 can clamp lenses with different sizes, the supporting mechanism 3 supports the bottoms of the lenses with different shapes, and the lifting mechanism 4 can adjust the height of the rotating mechanism 5 so as to adjust the height of the polishing mechanism 8, further adjust the height of the polishing mechanism 8 during polishing and meet different polishing requirements;

the structure of the processing holder 1 is explained in detail below as shown in fig. 2;

the machining support 1 comprises a bottom support 11, a support ring 12 and a gear ring frame 13, wherein the support ring 12 is fixedly connected to the bottom support 11, and the gear ring frame 13 is fixedly connected to the support ring 12;

the structure of the clamping mechanism 2 is explained in detail as shown in fig. 3;

the clamping mechanism 2 comprises a gear ring 21, gears 22 and clamping arc plates 23, wherein the gear ring 21 is rotationally connected to the gear ring frame 13, a power mechanism I for driving the gear ring 21 to rotate is arranged on the gear ring 21, the power mechanism I is preferably a servo motor, the gears 22 are provided with a plurality of gears 22, the gears 22 are rotationally connected to the support ring 12, each gear 22 is fixedly connected with the clamping arc plate 23, and the gears 22 are in meshing transmission with the gear ring 21;

the structure of the support mechanism 3 will be described in detail below as shown in fig. 4 and 5;

the supporting mechanism 3 comprises a telescopic mechanism I31, an arc cavity I32, a ball I33 and a sucker I34, the arc cavity I32 is fixedly connected to the telescopic end of the telescopic mechanism I31, the ball I33 is in clearance fit with the arc cavity I32, the sucker I34 is fixedly connected to the ball I33, a plurality of sensors are arranged on the sucker I34, the supporting mechanism 3 is provided, the telescopic mechanisms I31 are fixedly connected to the bottom support 11, the sensors are connected with an upper computer, and the telescopic mechanisms I31 are connected with the upper computer;

the structure of the lifting mechanism 4 will be described in detail below as shown in fig. 6;

the lifting mechanism 4 comprises a telescopic mechanism II 41 and a lifting support 42, the telescopic end of the telescopic mechanism II 41 is fixedly connected with the lifting support 42, and the telescopic mechanism II 41 is fixedly connected to the bottom support 11;

the structure of the rotating mechanism 5 will be described in detail below as shown in fig. 7;

the rotating mechanism 5 comprises a rotating ring 51, a sliding column 52 and a threaded rod 53, the sliding column 52 is fixedly connected to the rotating ring 51, the threaded rod 53 is rotatably connected to the rotating ring 51, a power mechanism II for driving the threaded rod 53 to rotate is arranged on the threaded rod 53, the power mechanism II is preferably a servo motor, the rotating ring 51 is rotatably connected to the lifting support 42, a power mechanism IV for driving the rotating ring 51 to rotate is arranged on the rotating ring 51, and the power mechanism IV is preferably a servo motor;

the structure of the swing mechanism 6 will be described in detail below as shown in fig. 8;

the swing mechanism 6 comprises a swing support 61, a rotating motor 62, a swing connecting rod 63, a sliding connecting rod 64 and an arc cavity II 65, wherein the swing support 61 is fixedly connected with the rotating motor 62, the swing support 61 is connected with the threaded rod 53 through threads, the swing support 61 is connected with the sliding column 52 in a sliding manner, an output shaft of the rotating motor 62 is rotatably connected with the swing connecting rod 63, the swing connecting rod 63 is slidably connected with the sliding connecting rod 64, the swing connecting rod 63 is provided with a power mechanism III for driving the swing connecting rod to rotate, the power mechanism III is preferably a servo motor, and the arc cavity II 65 is fixedly connected with the swing support 61;

the structure of the expanding mechanism 7 will be described in detail below as shown in fig. 9;

the expansion mechanism 7 comprises a ball II 71, a telescopic mechanism III 72, a telescopic mechanism IV 73, a ball III 74, a telescopic mechanism V75 and a ball IV 76, the ball II 71 is in clearance fit in the arc cavity II 65, the lower end of the sliding connecting rod 64 is hinged to the ball II 71, the lower end of the ball II 71 is fixedly connected with a plurality of telescopic mechanisms III 72, the telescopic end of each telescopic mechanism III 72 is fixedly connected with the telescopic mechanism IV 73, the telescopic end of each telescopic mechanism IV 73 is fixedly connected with the ball III 74, the lower end of the ball II 71 is fixedly connected with the telescopic mechanism V75, and the telescopic end of the telescopic mechanism V75 is fixedly connected with the ball IV 76;

the structure of the grinding mechanism 8 will be described in detail below as shown in fig. 10;

the polishing mechanism 8 comprises a polishing frame 81, arc cavities III 82 and arc cavities IV 83, the polishing frame 81 is fixedly connected with a plurality of arc cavities III 82, a plurality of spheres III 74 are respectively in clearance fit in the arc cavities III 82, the polishing frame 81 is fixedly connected with the arc cavities IV 83, and the spheres IV 76 are in clearance fit in the arc cavities IV 83;

the following structural drawings 1 to 10 explain the functions of the processing bracket 1, the clamping mechanism 2, the supporting mechanism 3, the lifting mechanism 4, the rotating mechanism 5, the swinging mechanism 6, the expanding mechanism 7 and the grinding mechanism 8 in detail;

when the processing device is used, a lens to be processed is placed on the suckers I34 of the plurality of supporting mechanisms 3, as shown in fig. 1, the plurality of supporting mechanisms 3 are uniformly distributed around the lens, the supporting mechanism 3 is also arranged in the middle of the bottom side of the lens, and the plurality of supporting mechanisms 3 support the lens;

as shown in fig. 4, the bottom surface of the lens may be an arc or a convex surface, and the sphere i 33 is in clearance fit with the arc cavity i 32, so that the suction cups i 34 can swing, each suction cup i 34 can be ensured to be sucked on the lens, and the fixing effect of the lens is ensured;

because the bottom surface of the lens can be an arc or a convex surface, in order to ensure that the gravity center of the lens is positioned on the supporting mechanism 3 positioned in the middle part, each sucker I34 is provided with a sensor, the sensor is preferably a weight sensor, in order that the sensors on the plurality of supporting mechanisms 3 around can measure corresponding weight, the sensor is connected with an upper computer through a common electric control means in the field, a plurality of telescopic mechanisms I31 are connected with the upper computer through a common electric control means in the field, the telescopic mechanisms I31 can be hydraulic cylinders or electric push rods, the sensors transmit the corresponding weight to the upper computer, the upper computer controls the telescopic ends of the telescopic mechanisms I31 to extend out or retract, further the weight on the supporting mechanisms 3 is adjusted, the gravity center of the lens is ensured to be positioned on the supporting mechanism 3 positioned in the middle part, and further, when the upper surface of the lens is machined, the bottom surface and the upper surface of the lens can correspond, the center of gravity of the lens is positioned at the center of the lens;

the power mechanism I is started, the power mechanism I can be fixedly connected to the machining support 1, an output shaft of the power mechanism I drives the gear ring 21 to rotate, the gear ring 21 drives the gears 22 to rotate, the gears 22 respectively drive the clamping arc plates 23 to rotate, and the clamping arc plates 23 deflect to clamp the side edges of the lenses to fix the lenses;

when the polishing height of the polishing mechanism 8 needs to be adjusted, the telescopic mechanism II 41 is started, the telescopic mechanism II 41 can be a hydraulic cylinder or an electric push rod, the telescopic end of the telescopic mechanism II 41 drives the lifting support 42 to move, the lifting support 42 drives the rotating mechanism 5 to move, the rotating mechanism 5 drives the swinging mechanism 6 to move, the swinging mechanism 6 drives the expanding mechanism 7 to move, the expanding mechanism 7 drives the polishing mechanism 8 to move, and then the polishing height of the polishing mechanism 8 is adjusted;

further, when the polishing mechanism 8 enters the polishing position, a power mechanism IV is started, the power mechanism IV can be fixedly connected to the lifting support 42, the power mechanism IV drives the rotating mechanism 5 to rotate, the rotating mechanism 5 drives the polishing mechanism 8 to rotate, and the polishing mechanism 8 polishes the lens;

when the polishing range of the polishing mechanism 8 needs to be adjusted, the power mechanism II is started, the power mechanism II can be fixedly connected to the rotating ring 51, an output shaft of the power mechanism II drives the threaded rod 53 to rotate, the threaded rod 53 drives the swinging mechanism 6 to rotate through threads, and then the position of the swinging mechanism 6 is adjusted, so that the swinging mechanism 6 rotates on the eccentric position of the rotating mechanism 5, and the polishing range of the polishing mechanism 8 is adjusted;

further, when the polishing angle of the polishing mechanism 8 needs to be adjusted, the rotating motor 62 is started, an output shaft of the rotating motor 62 drives the swinging connecting rod 63 and the sliding connecting rod 64 to rotate by a certain angle, and further the expansion mechanism 7 is adjusted to rotate by a certain angle, the expansion mechanism 7 drives the polishing mechanism 8 to rotate by a certain angle, the power mechanism iii is started, the power mechanism iii can be fixedly connected to an output shaft of the rotating motor 62, the output shaft of the power mechanism iii drives the swinging connecting rod 63 to rotate, the swinging connecting rod 63 drives the sliding connecting rod 64 to swing, the sliding connecting rod 64 drives the sphere ii 71 to swing, and the sphere ii 71 drives the polishing mechanism 8 to swing, so that the polishing angle of the polishing mechanism 8 is adjusted;

further, when the polishing radian of the polishing mechanism 8 needs to be adjusted, the telescoping mechanism iii 72, the telescoping mechanism iv 73 and the telescoping mechanism v 75 are started, the telescoping mechanism iii 72, the telescoping mechanism iv 73 and the telescoping mechanism v 75 can be hydraulic cylinders or electric push rods, the polishing frame 81 is driven to deform when the telescoping mechanism iii 72, the telescoping mechanism iv 73 and the telescoping mechanism v 75 move, and then the curved shape of the polishing frame 81 is adjusted, so that the polishing frame 81 can be adjusted to be a convex surface or a concave surface, and further different polishing requirements are met;

as shown in fig. 10, the polishing frame 81 is composed of elastic steel wires which are staggered transversely and longitudinally, and the lower side surfaces of the elastic steel wires are provided with polishing surfaces, so that the polishing frame 81 can be expanded and deformed to meet different polishing requirements, and the lower sides of the elastic steel wires are fixedly connected with fine polishing sand to form the polishing surfaces.

Claims

1. The utility model provides a laser lens grinding device, includes slewing mechanism (5) and swing mechanism (6) of connection on slewing mechanism (5), its characterized in that: the swing mechanism (6) is connected with an expansion mechanism (7), and the expansion mechanism (7) is in clearance fit with a polishing mechanism (8) capable of expanding and deforming.

2. The laser lens grinding device according to claim 1, characterized in that: the rotating mechanism (5) comprises a rotating ring (51) and a sliding column (52) fixedly connected to the rotating ring (51), and a threaded rod (53) is connected to the rotating ring (51) in a rotating mode.

3. The laser lens polishing device according to claim 2, wherein: swing mechanism (6) are including swing support (61) and rotating electrical machines (62) of fixed connection on swing support (61), and swing support (61) are through threaded connection on threaded rod (53), and swing support (61) sliding connection is on slip post (52), rotates on the output shaft of rotating electrical machines (62) and is connected with swing connecting rod (63), and sliding connection has sliding connecting rod (64) on swing connecting rod (63), fixedly connected with circular arc cavity II (65) on swing support (61).

4. A laser lens grinding apparatus according to claim 3, wherein: expansion mechanism (7) are including spheroid II (71) and a plurality of telescopic machanism III (72) of fixed connection at spheroid II (71) lower extreme, equal fixedly connected with telescopic machanism IV (73) are served in the flexible of every telescopic machanism III (72), equal fixedly connected with spheroid III (74) are served in the flexible of every telescopic machanism IV (73), the lower extreme fixedly connected with telescopic machanism V (75) of spheroid II (71), fixedly connected with spheroid IV (76) are served in the flexible of telescopic machanism V (75), spheroid II (71) clearance fit is in circular arc cavity II (65), the lower extreme of sliding connecting rod (64) articulates on spheroid II (71).

5. The laser lens polishing device according to claim 4, wherein: grinding machanism (8) are including polishing frame (81) and a plurality of circular arc cavity III (82) of fixed connection on polishing frame (81), and fixedly connected with circular arc cavity IV (83) are gone up in polishing frame (81), and a plurality of spheroid III (74) are clearance fit respectively in a plurality of circular arc cavity III (82), and spheroid IV (76) clearance fit is in circular arc cavity IV (83).

6. A laser lens grinding apparatus according to claim 1, wherein; the lifting mechanism (4) is further included, and the rotating mechanism (5) is rotatably connected to the lifting mechanism (4).

7. The laser lens polishing device according to claim 6, wherein: the lifting mechanism (4) comprises a telescopic mechanism II (41) and a lifting support (42) fixedly connected to the telescopic end of the telescopic mechanism II (41).

8. The laser lens polishing device according to claim 6, wherein: the automatic clamping device is characterized by further comprising a processing support (1) and a clamping mechanism (2) which is rotatably connected to the processing support (1), a plurality of supporting mechanisms (3) are fixedly connected to the bottom of the processing support (1), and a lifting mechanism (4) is fixedly connected to the processing support (1).

9. The laser lens polishing device according to claim 8, wherein: the clamping mechanism (2) comprises a gear ring (21) and a plurality of gears (22) meshed on the gear ring (21), and each gear (22) is fixedly connected with a clamping arc plate (23).

10. The laser lens polishing device according to claim 8, wherein: supporting mechanism (3) include that telescopic machanism I (31) and fixed connection are in telescopic machanism I (31) the circular arc cavity I (32) of holding that stretch out and draw back, clearance fit has spheroid I (33) on circular arc cavity I (32), fixedly connected with sucking disc I (34) are gone up in spheroid I (33), be provided with the sensor on sucking disc I (34), the equal fixed connection in a plurality of telescopic machanism I (31) is on bottom support (11), a plurality of sensors all with the host computer connection, a plurality of telescopic machanism I (31) all with the host computer connection.