CN112960915B

CN112960915B - Bonding tool for optical glass and application method thereof

Info

Publication number: CN112960915B
Application number: CN202110341989.2A
Authority: CN
Inventors: 陈宇光; 李明杰; 黄泽兵; 潘敏忠
Original assignee: Fuzhou Fulan Optical Instrument Co ltd
Current assignee: Fuzhou Fulan Optical Instrument Co ltd
Priority date: 2021-03-30
Filing date: 2021-03-30
Publication date: 2023-11-21
Anticipated expiration: 2041-03-30
Also published as: CN112960915A

Abstract

The utility model relates to an optical glass bonding tool and a use method thereof, wherein the optical glass bonding tool comprises two bases arranged on a horizontal workbench plate, and the centers of the two bases are symmetrically arranged; the base comprises a horizontal L-shaped base and an L-shaped angle plate vertically fixed at the inner angle of the L-shaped base; the outer side end face of one side of the L-shaped base extends outwards to form an extension plate, and the middle part of the end face of the other side extends outwards to form a middle baffle; a micrometer is vertically arranged in the middle of the extension plate; the micrometer on the extension plate is provided with a fixed sleeve fixed with the extension plate, and the tail end of the screw rod of the micrometer abuts against the side end of the middle baffle of the other base after passing through the extension plate; the middle part of the middle baffle is vertically provided with a micrometer, a fixed sleeve of the micrometer is fixed with the middle baffle, and the tail end of the micrometer abuts against the side end of the side edge of the L-shaped base on the other base after a screw rod of the micrometer passes through the middle baffle; the base is also provided with a plurality of vacuum adsorption mechanisms for adsorbing the glass sheets.

Description

Bonding tool for optical glass and application method thereof

Technical Field

The utility model relates to an optical glass bonding tool and a using method thereof, and belongs to the technical field of optical lens processing.

Background

When manufacturing an optical device, a part of the light transmitting lens with a special-shaped or multi-edge structure is difficult to produce and cannot meet the required surface quality requirement if the traditional integral grinding and forming mode is adopted. Therefore, in order to meet the production requirements and quality requirements, it is generally necessary to split the light-transmitting lens into a plurality of pieces of glass, and to perform the production by pasting the respective pieces of glass after polishing. In addition, in the adhesion, it is generally necessary to grind corresponding inclined surfaces at both ends of the glass as adhesion surfaces to achieve the adhesion.

The Chinese patent application No. CN211921335U discloses a glass bonding tool, which comprises a substrate and a positioning part positioned on the upper surface of the substrate, wherein the positioning part is provided with a positioning table extending upwards, the side surface of the positioning table is provided with a plurality of positioning surfaces for placing glass and bonding the glass, and the positioning part is provided with a positioning groove for accommodating the bottom of the glass. The glass bonding tool can provide stable and convenient positioning and pasting auxiliary effects for bonding glass, has good shearing quality and has certain adjustable performance suitable for different output structures. However, the precision of the glass on the optical device is highly required, and the glass bonding tool obviously cannot achieve the function of precision adjustment.

Disclosure of Invention

In order to overcome the problems, the utility model provides the bonding tool for the optical glass and the using method thereof, and the bonding tool for the optical glass has the advantages of simple structure, strong practicability, simplicity and convenience in operation, and can be used for stably and conveniently completing glass bonding work and finely adjusting bonding precision.

The technical scheme of the utility model is as follows:

an optical glass bonding tool comprises two bases arranged on a horizontal workbench plate, wherein the centers of the two bases are symmetrically arranged; the base comprises a horizontal L-shaped base and an L-shaped angle plate vertically fixed at the inner angle of the L-shaped base; the outer side end face of one side of the L-shaped base extends outwards to form an extension plate, and the middle part of the end face of the other side extends outwards to form a middle baffle; a micrometer is vertically arranged in the middle of the extension plate; the micrometer on the extension plate is provided with a fixed sleeve fixed with the extension plate, and the tail end of the screw rod of the micrometer abuts against the side end of the middle baffle of the other base after passing through the extension plate; the middle part of the middle baffle is vertically provided with a micrometer, a fixed sleeve of the micrometer is fixed with the middle baffle, and the tail end of the micrometer abuts against the side end of the side edge of the L-shaped base on the other base after a screw rod of the micrometer passes through the middle baffle; the base is also provided with a plurality of vacuum adsorption mechanisms for adsorbing the glass sheets.

Further, each side edge of the base corresponding to the L-shaped base is provided with the vacuum adsorption mechanism; the vacuum adsorption mechanism comprises a sucker and a vacuumizing pump; the sucking disc stretches into the inner side end surface of the L-shaped angle plate and is used for sucking glass sheets; the sucker is communicated with the vacuumizing pump through a hose.

Further, an outer side plate is vertically fixed above the tail end of each side edge of the L-shaped base; the upper end of the outer side plate is flush with the upper end of the L-shaped angle plate; the vacuumizing pump is fixed on the outer end face of the outer side plate; the sucking disc is arranged between the L-shaped angle plate and the outer side plate.

Further, a horizontal bracket is fixed between the L-shaped angle plate and the outer side plate; the hose is arranged on the bracket in a penetrating way.

Furthermore, horizontal limit protruding points are fixed on the inner side wall surface of the L-shaped base, the inner side wall surface of the L-shaped corner plate and the inner side wall surface of the outer side plate; on the same inner side wall surface of the base, the inner side end surfaces of all the limit protruding points are positioned on the same vertical plane, and the vertical plane is parallel to the inner side wall surface of the base; all limit bumps are arranged in a matrix on the same inner side wall surface of the base, and the sucking disc is positioned at the center of the matrix.

Further, the device also comprises an annular spring ring; the spring is sleeved on the outer side end surfaces of the L-shaped angle plate and the outer side plate; the spring ring provides elastic force to enable the two bases to be close to each other.

The application method of the bonding tool for the optical glass comprises the following specific steps:

step one: installing a glass sheet;

respectively placing two glass sheets on the inner sides of an L-shaped angle plate and an outer side plate on each side of a base, simultaneously enabling the connecting surfaces between the two glass sheets to be attached, then starting a vacuum pump to enable a sucker to absorb the glass sheets, and enabling the outer side end surfaces of the glass sheets to be attached to limiting protruding points;

step two: a combination of bases;

assembling two bases which have absorbed glass sheets, abutting the screw tail end of a micrometer on an extension plate of one base against the side end of a middle baffle of the other base, abutting the screw tail end of the micrometer on the middle baffle of one base against the side end of the side edge of an L-shaped base on the other base, and splicing the glass sheets to form a quadrangular prism structure to complete the assembly of the two bases; finally, sleeving the spring ring on the outer end surfaces of the L-shaped angle plate and the outer side plate;

step three: adjusting a micrometer;

according to the requirements of the bonding precision of the glass sheet and the product, the precision of the micrometer is adjusted to finely adjust the distance between the two bases;

step four: sticking a glass sheet;

after the distance between the two bases is adjusted, injecting glue to the connecting surfaces between the glass sheets, and penetrating the glue into the glass sheets to finish bonding work;

step five: removing the die;

after the glass sheet is bonded, the spring ring is disassembled, and the two bases are moved outwards, so that the light transmission device with the quadrangular prism structure is obtained.

The utility model has the following beneficial effects:

1. the bonding tool for the optical glass is simple in structure, high in practicability and convenient to operate, and can be used for stably and conveniently completing glass bonding operation and fine-adjusting bonding precision.

2. The fine adjustment of the pasting precision can be realized by a micrometer arranged on the extension plate and the middle baffle plate.

3. The spring ring is arranged, and the spring ring provides elasticity to enable the bases to be close to each other, so that the bases cannot be automatically close to each other after the micrometer is turned down, and the adjustment accuracy is ensured.

Drawings

FIG. 1 is a schematic view of the overall structure of the present utility model when a glass sheet is placed.

Fig. 2 is a schematic diagram of the overall structure of the present utility model.

Fig. 3 is a top view of fig. 2.

Fig. 4 is a partial enlarged view at a of fig. 3.

Fig. 5 is a schematic structural view of the base of the present utility model.

Fig. 6 is a top view of fig. 5.

The reference numerals in the drawings are as follows:

1. a work platen; 2. a base; 21. an L-shaped base; 22. an L-shaped angle plate; 23. an extension plate; 24. a middle baffle; 25. an outer panel; 26. limiting protruding points; 3. a vacuum adsorption mechanism; 31. a suction cup; 32. a hose; 33. a vacuum pump; 34. a bracket; 4. a micrometer; 41. fixing the sleeve; 42. a differentiating pipe; 43. a knob; 44. a screw; 5. a spring ring; 6. and (3) a glass sheet.

Detailed Description

The utility model will now be described in detail with reference to the drawings and to specific embodiments.

Referring to fig. 1-6, an optical glass bonding tool comprises two bases 2 arranged on a horizontal working table plate 1, wherein the two bases 2 are arranged in a central symmetry manner; the base 2 comprises a horizontal L-shaped base 21 and an L-shaped corner plate 22 vertically fixed at the inner angle of the L-shaped base 21; the outer side end surface of one side of the L-shaped base 21 extends outwards to form an extension plate 23, and the middle part of the end surface of the other side extends outwards to form a middle baffle 24; a micrometer 4 is vertically arranged in the middle of the extension plate 23; a micrometer 4 on the extension plate 23, wherein a fixed sleeve 41 of the micrometer is fixed with the extension plate 23, and a screw 44 of the micrometer abuts against the side end of the middle baffle 24 of the other base 2 after penetrating through the extension plate 23; the middle part of the middle baffle 24 is vertically provided with a micrometer 4, a fixed sleeve 41 of the micrometer is fixed with the middle baffle 24, and after a screw 44 of the micrometer passes through the middle baffle 24, the tail end of the micrometer abuts against the side end of the side edge of the L-shaped base 21 on the other base 2; the base 2 is also provided with a plurality of vacuum adsorption mechanisms 3 for adsorbing glass sheets 6.

According to the above description, the bonding tool for optical glass comprises a base 2, a vacuum adsorption mechanism 3 and a micrometer 4. The base 2 comprises an L-shaped base 21 and an L-shaped corner plate 22 fixed at the inner corner of the L-shaped base 21, wherein the inner corner of the L-shaped corner plate 22 corresponds to the position of the connecting surface of the two glass sheets 6. The vacuum suction mechanism 3 is used for sucking the glass sheet 6. The two sides of the L-shaped base 21 are correspondingly provided with an extension plate 23 and a middle baffle 24, and the extension plate 23 and the middle baffle 24 are correspondingly provided with a micrometer 4 respectively. By adjusting the micrometer 4, the position between the two bases 2 can be finely adjusted so as to finely adjust the bonding precision between the glass sheets 6, thereby meeting the precision requirement of the optical glass.

When fine tuning is performed, firstly, correction is ensured to be performed on the micrometer 4, the same reading is kept on the differential tube 42 of the four micrometer 4, then, the two bases 2 are combined, the tail end of the screw rod 44 of the micrometer 4 on the extension plate 23 of one base 2 is abutted against the side end of the middle baffle 24 of the other base 2, and then, the tail end of the screw rod 44 of the micrometer 4 on the middle baffle 24 of one base 2 is abutted against the side end of the side edge of the L-shaped base 21 on the other base 2, so that the tail end of the screw rod 44 of the micrometer 4 of each base 2 is ensured to be abutted against the other base 2. Then, the pitch between the glass sheets 6 is finely adjusted according to the accuracy requirement of the light transmission device of the bonded quadrangular prism structure. If the interval between the glass sheets 6 is too large, the knob 43 on the differentiating pipe 42 is reversely rotated, so that the tail end of the screw rod 44 of the micrometer 4 is retracted, and the two bases 2 are close to each other (through the elasticity of the spring ring 5), so that the interval between the glass sheets 6 can be finely adjusted and reduced; otherwise, if the interval between the glass sheets 6 is too small, the knob 43 on the differentiating pipe 42 is rotated forward, so that the tail end of the screw rod 44 of the micrometer 4 extends out, and the two bases 2 are further away from each other, so that the interval between the glass sheets 6 can be finely adjusted and increased.

Further, the base 2 is provided with the vacuum adsorption mechanism 3 on each side corresponding to the L-shaped base 21; the vacuum adsorption mechanism 3 comprises a sucker 31 and a vacuumizing pump 33; the sucking disc 31 extends into the inner side end surface of the L-shaped angle plate 22 and is used for sucking the glass sheet 6; the sucking disc 31 is communicated with the vacuumizing pump 33 through a hose 32.

Further, an outer plate 25 is vertically fixed above the end of each side of the L-shaped base 21; the upper end of the outer side plate 25 is flush with the upper end of the L-shaped angle plate 22; the vacuumizing pump 33 is fixed on the outer end surface of the outer side plate 25; the suction cups 31 are arranged between the L-shaped corner plate 22 and the outer side plate 25.

Further, a horizontal bracket 34 is fixed between the L-shaped corner plate 22 and the outer side plate 25; the hose 32 is threaded onto the bracket 34.

Further, horizontal limit protruding points 26 are fixed on the inner side wall surface of the L-shaped base 21, the inner side wall surface of the L-shaped corner plate 22 and the inner side wall surface of the outer side plate 25; on the same inner side wall surface of the base 2, the inner side end surfaces of all the limit protruding points 26 are positioned on the same vertical plane, and the vertical plane is parallel to the inner side wall surface of the base 2; on the same inner side wall surface of the base 2, all limit bumps 26 are arranged in a matrix, and the sucking disc 31 is positioned at the center of the matrix.

In particular, the position of the suction cup 31 should be closer to the outer side of the base 2 than the end of the limit bump 26, so as to ensure that the glass sheet 6 can be reliably abutted against the limit bump 26 after the suction cup 31 sucks the glass sheet 6.

Further, the device also comprises an annular spring ring 5; the spring ring 5 is sleeved on the outer end surfaces of the L-shaped angle plate 22 and the outer side plate 25; the spring ring 5 provides elastic force to bring the two bases 2 close to each other. The spring ring 5 is mainly used for enabling the two bases 2 to be close to each other through elastic force after the size of the micrometer 4 is reduced, so that errors are corrected.

step one: mounting of the glass sheet 6;

two glass sheets 6 are respectively placed on the inner sides of the L-shaped angle plate 22 and the outer side plate 25 of each side edge of the base 2, the connecting surfaces of the two glass sheets 6 are attached, then the vacuumizing pump 33 is started to enable the sucking disc 31 to suck the glass sheets 6, and the outer side end surfaces of the glass sheets 6 are attached to the limiting protruding points 26.

A combination of bases 2;

assembling two bases 2 which have absorbed glass sheets 6, abutting the tail end of a screw rod 44 of a micrometer 4 on an extension plate 23 of one base 2 against the side end of a middle baffle 24 of the other base 2, abutting the tail end of the screw rod 44 of the micrometer 4 on the middle baffle 24 of one base 2 against the side end of the side edge of an L-shaped base 21 on the other base 2, and splicing the glass sheets 6 to form a quadrangular prism structure to complete the assembly of the two bases 2; finally, the spring coil 5 is fitted over the outer end surfaces of the L-shaped corner plate 22 and the outer side plate 25.

Step three: adjustment of the micrometer 4;

the distance between the two bases 2 is finely adjusted by adjusting the precision of the micrometer 4 according to the requirements of the bonding precision of the glass sheet 6 and the product.

Step four: sticking the glass sheet 6;

after the distance between the two bases 2 is adjusted, glue is injected to the connecting surfaces between the glass sheets 6, and the glue permeates the glass sheets 6 to complete bonding work.

In particular, a plurality of vertically penetrating through holes may be formed in the table plate 1. When the base 2 is placed, the position of the connection surface between the glass sheets 6 is located as above the through holes as possible. In this way, the excessive glue will flow away from the through hole, and the excessive glue will not accumulate, adhere to the glass sheet 6 or adhere to the working table 1, so that the cleaning is convenient.

Step five: removing the die;

after the glass sheet 6 is bonded, the spring ring 5 is disassembled, and the two bases 2 are moved outwards to obtain the light transmission device with the quadrangular prism structure.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present utility model.

Claims

1. An optical glass's bonding frock, its characterized in that: comprises two bases (2) arranged on a horizontal workbench plate (1), wherein the two bases (2) are arranged in a central symmetry manner; the base (2) comprises a horizontal L-shaped base (21) and an L-shaped corner plate (22) vertically fixed at the inner angle of the L-shaped base (21); the outer side end face of one side edge of the L-shaped base (21) extends outwards to form an extension plate (23), and the middle part of the end face of the other side edge extends outwards to form a middle baffle plate (24); a micrometer (4) is vertically arranged in the middle of the extension plate (23); a micrometer (4) on the extension plate (23), wherein a fixed sleeve (41) of the micrometer is fixed with the extension plate (23), and the tail end of a screw rod (44) abuts against the side end of a middle baffle plate (24) of the other base (2) after passing through the extension plate (23); the middle part of the middle baffle plate (24) is vertically provided with a micrometer (4), a fixed sleeve (41) of the micrometer is fixed with the middle baffle plate (24), and the tail end of a screw rod (44) of the micrometer abuts against the side end of the side edge of the L-shaped base (21) on the other base (2) after passing through the middle baffle plate (24); the base (2) is also provided with a plurality of vacuum adsorption mechanisms (3) for adsorbing the glass sheets (6);

also comprises an annular spring ring (5); the spring ring (5) is sleeved on the outer end surfaces of the L-shaped angle plate (22) and the outer side plate (25); the spring ring (5) provides elastic force to enable the two bases (2) to be close to each other.

2. The bonding tool for optical glass according to claim 1, wherein: each side edge of the base (2) corresponding to the L-shaped base (21) is provided with the vacuum adsorption mechanism (3); the vacuum adsorption mechanism (3) comprises a sucker (31) and a vacuumizing pump (33); the sucking disc (31) stretches into the inner side end surface of the L-shaped angle plate (22) and is used for sucking the glass sheet (6); the sucker (31) is communicated with the vacuumizing pump (33) through a hose (32).

3. The bonding tool for optical glass according to claim 2, wherein: an outer side plate (25) is vertically fixed above the tail end of each side edge of the L-shaped base (21); the upper end of the outer side plate (25) is level with the upper end of the L-shaped corner plate (22); the vacuumizing pump (33) is fixed on the outer end surface of the outer side plate (25); the suction cup (31) is arranged between the L-shaped corner plate (22) and the outer side plate (25).

4. An optical glass bonding tool according to claim 3, wherein: a horizontal bracket (34) is fixed between the L-shaped angle plate (22) and the outer side plate (25); the hose (32) is arranged on the bracket (34) in a penetrating way.

5. The bonding tool for optical glass according to claim 4, wherein: horizontal limit protruding points (26) are fixed on the inner side wall surface of the L-shaped base (21), the inner side wall surface of the L-shaped corner plate (22) and the inner side wall surface of the outer side plate (25); on the same inner side wall surface of the base (2), the inner side end surfaces of all the limit protruding points (26) are positioned on the same vertical plane, and the vertical plane is parallel to the inner side wall surface of the base (2); all limit bumps (26) are arranged in a matrix on the same inner side wall surface of the base (2), and the sucker (31) is positioned in the center of the matrix.

6. The application method of the bonding tool for the optical glass is characterized by comprising the following steps of: an optical glass bonding tool according to claim 5, comprising the following specific steps:

step one: mounting of the glass sheet (6);

two glass sheets (6) are respectively placed on the inner sides of an L-shaped angle plate (22) and an outer side plate (25) of each side of a base (2), meanwhile, the connecting surfaces between the two glass sheets (6) are attached, then a vacuum pump (33) is started to enable a sucker (31) to absorb the glass sheets (6), and the outer side end surfaces of the glass sheets (6) are attached to limit protruding points (26);

step two: a combination of bases (2);

assembling two bases (2) which have absorbed glass sheets (6), abutting the tail end of a screw (44) of a micrometer (4) on an extension plate (23) of one base (2) against the side end of a middle baffle (24) of the other base (2), abutting the tail end of the screw (44) of the micrometer (4) on the middle baffle (24) of one base (2) against the side end of the side edge of an L-shaped base (21) on the other base (2), and splicing the glass sheets (6) to form a quadrangular prism structure to complete the assembly of the two bases (2); finally, sleeving the spring ring (5) on the outer end surfaces of the L-shaped angle plate (22) and the outer side plate (25);

step three: adjusting a micrometer (4);

according to the requirements of the bonding precision of the glass sheet (6) and the product, the precision of the micrometer (4) is adjusted to finely adjust the distance between the two bases (2);

step four: adhering the glass sheet (6);

after the distance between the two bases (2) is adjusted, injecting glue to the connecting surface between the glass sheets (6), and penetrating the glue into the glass sheets (6) to finish bonding work;

step five: removing the die;

after the glass sheet (6) is bonded, the spring ring (5) is disassembled, and the two bases (2) are moved outwards, so that the light transmission device with the quadrangular prism structure is obtained.