CN221133401U - Anti-collision cleaning equipment for optical glass after processing - Google Patents

Abstract

The utility model relates to the technical field of optical glass cleaning, in particular to anti-collision cleaning equipment after optical glass processing, which comprises a mounting plate, wherein an ultrasonic cleaner is arranged in front of the mounting plate, a first lifting module is arranged on the front surface of the mounting plate close to one side edge, a second lifting module is arranged on the front surface of the mounting plate close to the other side edge, a guide plate is fixedly connected to the upper surface of the mounting plate close to the front surface, and connecting frames are arranged on the outer surfaces of the guide plate and the first lifting module.

Description

Anti-collision cleaning equipment for optical glass after processing

Technical Field

The utility model relates to the technical field of optical glass cleaning, in particular to anti-collision cleaning equipment after optical glass processing.

Background

The utility model provides a belt cleaning device is used for getting rid of the spot on optical glass surface, and optical glass is commonly used in optical instrument's lens, and ultrasonic cleaner commonly used in the prior art clears up optical glass, and the device in the prior art exists certain drawback, like bulletin number CN218743612U, an optical glass cleaning equipment of record, including cleaning tank, elevating system, backup pad and glass support frame, elevating system includes actuating mechanism and the moving part of being connected with actuating mechanism, and above-mentioned device realizes simple lift, but is single-station operation when using, after the work or material rest rises (during unloading and material loading), the cleaning tank of device belongs to idle state, leads to the cleaning efficiency of device low.

Disclosure of utility model

The utility model aims at: in order to solve the problem of low cleaning efficiency of single-station operation of the existing part device, the anti-collision cleaning equipment for the optical glass after processing is provided.

The aim of the utility model can be achieved by the following technical scheme:

The utility model provides an anticollision cleaning equipment behind optical glass processing, includes the mounting panel, ultrasonic cleaner has been placed in the place ahead of mounting panel, the front surface of mounting panel is close to one side edge position and is provided with lifting module No. one, the front surface of mounting panel is close to opposite side edge position and is provided with lifting module No. two, the upper surface of mounting panel is close to front surface position fixedly connected with deflector, the surface of deflector and lifting module No. one all is provided with the link, the lower surface of mounting panel is close to central point puts fixedly connected with step motor, step motor's output fixedly connected with worm.

The method is further characterized in that: the ultrasonic cleaning machine is characterized in that a cleaning liquid inlet pipe is embedded and connected to the position, close to the upper surface, of one side surface of the ultrasonic cleaning machine, and a cleaning liquid discharge pipe is embedded and connected to one side surface of the ultrasonic cleaning machine.

The method is further characterized in that: the lower surface of mounting panel is close to rear surface position fixedly connected with supporting leg, the preceding fixedly connected with limit frame of mounting panel, the upper surface fixedly connected with mounting bracket of mounting panel, worm and mounting bracket rotate to be connected.

The method is further characterized in that: the rear surface embedding of mounting bracket rotates and is connected with a pivot, the surface fixedly connected with worm wheel of a pivot, the surface fixedly connected with gear wheel of a pivot, worm and worm wheel meshing are connected.

The method is further characterized in that: the lifting module comprises a connecting seat, a second rotating shaft, a conical gear, a third rotating shaft, a second conical gear, a second gear, a damping block, a rubber damping pad and a first rack, wherein the first rack is embedded in the front surface of the limiting frame and is connected with the first rack in a sliding mode, the connecting seat is fixedly connected with the upper surface of the first rack, the second rotating shaft is connected with the upper surface of the connecting seat in a rotating mode, the third rotating shaft is connected with the upper surface of the second rotating shaft in a fixedly connected mode, one end of the third rotating shaft is fixedly connected with the second conical gear, the other end of the third rotating shaft is fixedly connected with the second gear, one end of the third rotating shaft is connected with the damping block in a nested mode, and one side surface of the damping block is connected with the rubber damping pad in an embedded mode.

The method is further characterized in that: the connecting frame is fixedly connected with the second rotating shaft, the guide rail is fixedly connected with the upper surface of the guide plate, and the second rack is fixedly connected with the front surface of the guide plate close to the center.

The method is further characterized in that: the lifting module is identical to the lifting module in structure, a cleaning frame is fixedly connected to the outer surface of the connecting frame, a rubber separation net is fixedly connected to the inner part of the cleaning frame, a gear and a rack are in meshed connection, a gear and a gear are in meshed connection, and a damping block is in sliding connection with the guide rail.

The utility model has the beneficial effects that:

Through the lifting module I, the rubber separation net inside the cleaning frame separates a plurality of optical glasses, batch storage of the optical glasses is realized, when a connecting frame on the lifting module I ascends, a damping block slides in a guide rail, the damping block is matched with a rubber damping pad to provide friction resistance to fix a rotating shaft III, the rotating shaft III cannot rotate, when the connecting frame continues to move upwards, a gear II is contacted with a rack II on a guide plate, the gear II rotates and overcomes the resistance of a rubber damping pad under the influence of the rack II, and at the moment, the gear II is matched with a bevel gear II to drive the bevel gear I to rotate, so that the rotating shaft II drives the connecting frame to outwards turn;

Through the lifting module No. two that sets up, the link upset on the lifting module No. two makes the link on the lifting module No. two be located ultrasonic cleaner's top, at this moment, no. two gears and No. two rack separation, no. three pivot on the lifting module No. two is fixed by the rubber damping pad, therefore, when lifting module No. two drives the link and continuously descends, the link angle can not change, at this moment, the washing frame on the lifting module No. two gets into ultrasonic cleaner's inside, ultrasonic cleaner clears up the optical lens in the washing frame, make two washing frames get into ultrasonic cleaner in turn, can realize duplex position operation, when the optical lens in one of them washs the frame washs, can carry out drainage, unloading or material loading operation to the lens in another washing frame, improve device's work efficiency, and drive structure is provided power by single step motor, device drive structure's cost is saved.

Drawings

The utility model is further described below with reference to the accompanying drawings.

FIG. 1 is a schematic view of the overall structure of the present utility model;

FIG. 2 is a schematic diagram of the transmission structure of the present utility model;

FIG. 3 is a schematic diagram of a first lifting module in a split structure according to the present utility model;

FIG. 4 is a schematic diagram of a stepper motor drive configuration of the present utility model;

Fig. 5 is an enlarged view of fig. 3 a of the present utility model.

In the figure: 1. an ultrasonic cleaner; 101. a cleaning liquid inlet pipe; 102. a cleaning liquid discharge pipe; 2. a mounting plate; 201. support legs; 202. a limit frame; 203. a mounting frame; 3. a stepping motor; 301. a worm; 302. a first rotating shaft; 303. a worm wheel; 304. a first gear; 4. a guide plate; 401. a guide rail; 402. a second rack; 5. a lifting module I; 501. a connecting seat; 502. a second rotating shaft; 503. a first bevel gear; 504. a third rotating shaft; 505. a secondary bevel gear; 506. a second gear; 507. a damping block; 508. a rubber damping pad; 509. a first rack; 6. a lifting module II; 7. a connecting frame; 701. cleaning a frame; 702. a rubber separation net.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below in conjunction with the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-5, an anti-collision cleaning device for optical glass after processing comprises a mounting plate 2, an ultrasonic cleaner 1 is placed in front of the mounting plate 2, a first lifting module 5 is arranged on the front surface of the mounting plate 2 near one side edge position, a second lifting module 6 is arranged on the front surface of the mounting plate 2 near the other side edge position, a guide plate 4 is fixedly connected on the upper surface of the mounting plate 2 near the front surface position, a connecting frame 7 is arranged on the outer surfaces of the guide plate 4 and the first lifting module 5, a stepping motor 3 is fixedly connected on the lower surface of the mounting plate 2 near the central position, a worm 301 is fixedly connected at the output end of the stepping motor 3, a first rotating shaft 302 is rotatably connected on the rear surface of the mounting frame 203 in an embedded manner, a worm gear 303 is fixedly connected on the outer surface of the first rotating shaft 302, a first gear 304 is fixedly connected on the outer surface of the first rotating shaft 302, the worm 301 and the worm wheel 303 are in meshed connection, when the device is used, the initial state of the device is shown in fig. 1, the structure of the lifting module No. two 6 and the structure of the lifting module No. one 5 are the same, and the connection mode of the lifting module No. two 6 and the lifting module No. one 5 and the gear No. one 304 is also the same, therefore, in the state shown in fig. 1, the optical glass is placed inside a cleaning frame 701 on the lifting module No. two 6, a plurality of optical glass is separated by a rubber separation net 702 inside the cleaning frame 701, batch storage of the optical glass is realized, then a stepping motor 3 is started, the output end of the stepping motor 3 drives the worm 301 to rotate, the worm 301 drives the worm wheel 303 to rotate, the gear No. one 304 can rotate, at the moment, the gear No. one 304 drives two racks No. 509 to move along a limiting frame 202, a connecting frame 7 on the lifting module No. two 6 moves downwards, the connecting frame 7 on the lifting module 5 is moved upwards.

The ultrasonic cleaning machine comprises an ultrasonic cleaning machine 1, a cleaning liquid inlet pipe 101, a cleaning liquid discharge pipe 102, a supporting leg 201, a limiting frame 202, a mounting plate 2, a mounting frame 203, a worm 301 and the mounting frame 203, wherein the cleaning liquid inlet pipe 101 is embedded and connected to one side surface of the ultrasonic cleaning machine 1 close to the upper surface, the cleaning liquid discharge pipe 102 is embedded and connected to one side surface of the ultrasonic cleaning machine 1, the supporting leg 201 is fixedly connected to the lower surface of the mounting plate 2 close to the rear surface, the limiting frame 202 is fixedly connected to the front surface of the mounting plate 2, the mounting frame 203 is fixedly connected to the upper surface of the mounting plate 2, the worm 301 is rotationally connected with the mounting frame 203, a lifting module 5 comprises a connecting seat 501, a second rotating shaft 502, a conical gear 503, a third rotating shaft 504, a second conical gear 505, a second gear 506, Damping block 507, rubber damping pad 508 and a rack 509, the front surface of limit frame 202 is embedded with a rack 509 in sliding connection, the upper surface of rack 509 is fixedly connected with connecting seat 501, the upper surface of connecting seat 501 is rotatably connected with a second rotating shaft 502, the upper surface of second rotating shaft 502 is fixedly connected with a first conical gear 503, the other side surface of connecting seat 501 is rotatably connected with a third rotating shaft 504, one end of third rotating shaft 504 is fixedly connected with a second conical gear 505, the other end of third rotating shaft 504 is fixedly connected with a second gear 506, one end of third rotating shaft 504 is nested and connected with damping block 507, a rubber damping pad 508 is embedded and connected on one side surface of the damping block 507, the connecting frame 7 is fixedly connected with the second rotating shaft 502, the upper surface of the guide plate 4 is fixedly connected with the guide rail 401, the front surface of the guide plate 4 is fixedly connected with the second rack 402 near the center, the first lifting module 5 and the second lifting module 6 have the same structure, the outer surface of the connecting frame 7 is fixedly connected with the cleaning frame 701, the rubber separation net 702 is fixedly connected inside the cleaning frame 701, the first gear 304 is in meshed connection with the first rack 509, the second bevel gear 505 is in meshed connection with the first bevel gear 503, the damping block 507 is in sliding connection with the guide rail 401, when the connecting frame 7 on the lifting module 5 ascends, the damping block 507 slides in the guide rail 401, the damping block 507 is matched with the rubber damping cushion 508 to provide friction resistance to fix the rotating shaft III 504, so that the rotating shaft III 504 cannot rotate, when the connecting frame 7 continues to move upwards, the gear II 506 is contacted with the rack II 402 on the guide plate 4, the gear II 506 rotates and overcomes the resistance of the rubber damping cushion 508, at the moment, the gear II 506 is matched with the gear II 505 to drive the gear I conical gear 503 to rotate, so that the rotating shaft II 502 drives the connecting frame 7 to outwards overturn, similarly, the connecting frame 7 on the lifting module No. 6 is turned over, so that the connecting frame 7 on the lifting module No. 6 is positioned above the ultrasonic cleaner 1, at this time, the gear No. 506 and the rack No. 402 are separated, and the rotating shaft No. three 504 on the lifting module No. 6 is fixed by the rubber damping pad 508, so that the angle of the connecting frame 7 is not changed when the lifting module No. 6 drives the connecting frame 7 to continuously descend, at this time, the cleaning frame 701 on the lifting module No. 6 enters the inside of the ultrasonic cleaner 1, the ultrasonic cleaner 1 cleans the optical lenses in the cleaning frame 701, and the two cleaning frames 701 alternately enter the ultrasonic cleaner 1, the double-station operation can be realized, and when one of the cleaning frames 701 is used for cleaning the optical lenses, the other cleaning frame 701 can be used for filtering, blanking or feeding the lenses, so that the working efficiency of the device is improved.

Working principle: when the device is used, the initial state of the device is shown in fig. 1, the structures of the lifting module No. two 6 and the lifting module No. one 5 are the same, and the connection modes of the lifting module No. two 6 and the lifting module No. one 5 and the gear No. one 304 are also the same, so that in the state shown in fig. 1, optical glass is placed inside a cleaning frame 701 on the lifting module No. two 6, a plurality of optical glass is separated by a rubber separation net 702 inside the cleaning frame 701, batch storage of the optical glass is realized, a stepping motor 3 is started, the output end of the stepping motor 3 drives a worm 301 to rotate, the worm 301 drives a worm wheel 303 to rotate, so that the gear No. one 304 can rotate, at the moment, the gear No. one 304 drives two racks No. one 509 to move along a limiting frame 202, a connecting frame 7 on the lifting module No. two 6 moves downwards, and the connecting frame 7 on the lifting module No. one 5 moves upwards;

When the connecting frame 7 on the lifting module 5 ascends, the damping block 507 slides in the guide rail 401, the damping block 507 is matched with the rubber damping pad 508 to provide friction resistance to fix the third rotating shaft 504, so that the third rotating shaft 504 cannot rotate, when the connecting frame 7 continues to move upwards, the second gear 506 is contacted with the second rack 402 on the guide plate 4, the second gear 506 rotates and overcomes the resistance of the rubber damping pad 508, at the moment, the second gear 506 is matched with the second bevel gear 505 to drive the first bevel gear 503 to rotate, the second rotating shaft 502 can drive the connecting frame 7 to turn outwards, the connecting frame 7 on the second lifting module 6 is turned over, the connecting frame 7 on the second lifting module 6 is located above the ultrasonic cleaner 1, at the moment, the second gear 506 is separated from the second rack 402, the third rotating shaft 504 on the second lifting module 6 is fixed by the rubber damping pad 508, therefore, when the second lifting module 6 drives the connecting frame 7 to continuously descend, the angle of the connecting frame 7 is not changed, the second lifting module 6 is matched with the second bevel gear 505 to drive the connecting frame 7 to turn outwards, the connecting frame 7 can be alternately turned over, the second lifting module 6 is alternately cleaned, the second lifting module 1 is cleaned, the second ultrasonic cleaner 1 is alternately cleaned, the second ultrasonic cleaner 1 is alternately cleaned, and the second ultrasonic cleaner 1 is used, and the ultrasonic cleaner 1 is alternatively, and the ultrasonic cleaner 1 is cleaned.

In the description of the present specification, reference to the terms "one embodiment," "example," "specific example," and the like, means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present utility model. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing is merely illustrative and explanatory of the utility model, as various modifications and additions may be made to the particular embodiments described, or in a similar manner, by those skilled in the art, without departing from the scope of the utility model or exceeding the scope of the utility model as defined in the claims.

Claims (7)

1. The utility model provides an anti-collision cleaning equipment behind optical glass processing, includes mounting panel (2), its characterized in that, ultrasonic cleaner (1) have been placed in the place ahead of mounting panel (2), the front surface of mounting panel (2) is close to one side edge position and is provided with lifting module (5) No. one, the front surface of mounting panel (2) is close to opposite side edge position and is provided with lifting module (6) No. two, the upper surface of mounting panel (2) is close to front surface position fixedly connected with deflector (4), the surface of deflector (4) and lifting module (5) all is provided with link (7), the lower surface of mounting panel (2) is close to central point puts fixedly connected with step motor (3), the output fixedly connected with worm (301) of step motor (3).

2. The anti-collision cleaning device for optical glass processing according to claim 1, wherein a cleaning liquid inlet pipe (101) is embedded and connected to a position, close to the upper surface, of one side surface of the ultrasonic cleaner (1), and a cleaning liquid outlet pipe (102) is embedded and connected to one side surface of the ultrasonic cleaner (1).

3. The anti-collision cleaning device after optical glass processing according to claim 1, wherein a supporting leg (201) is fixedly connected to the lower surface of the mounting plate (2) close to the rear surface, a limit frame (202) is fixedly connected to the front surface of the mounting plate (2), a mounting frame (203) is fixedly connected to the upper surface of the mounting plate (2), and the worm (301) is rotationally connected with the mounting frame (203).

4. A post-processing anti-collision cleaning device according to claim 3, wherein a first rotating shaft (302) is rotatably connected to the rear surface of the mounting frame (203), a worm wheel (303) is fixedly connected to the outer surface of the first rotating shaft (302), a first gear (304) is fixedly connected to the outer surface of the first rotating shaft (302), and the worm (301) is in meshed connection with the worm wheel (303).

5. The anti-collision cleaning device after optical glass processing according to claim 4, wherein the lifting module (5) comprises a connecting seat (501), a second rotating shaft (502), a first conical gear (503), a third rotating shaft (504), a second conical gear (505), a second gear (506), a damping block (507), a rubber damping pad (508) and a first rack (509), the front surface of the limiting frame (202) is embedded and slidingly connected with the first rack (509), the upper surface of the first rack (509) is fixedly connected with the connecting seat (501), the upper surface of the connecting seat (501) is rotationally connected with the second rotating shaft (502), the upper surface of the second rotating shaft (502) is rotationally connected with the first conical gear (503), the other side surface of the connecting seat (501) is rotationally connected with the third rotating shaft (504), one end of the third rotating shaft (504) is fixedly connected with the second conical gear (505), the other end of the third rotating shaft (504) is fixedly connected with the second gear (506), and one end of the third rotating shaft (507) is connected with the damping pad (508).

6. The anti-collision cleaning device for optical glass processing according to claim 5, wherein the connecting frame (7) is fixedly connected with the second rotating shaft (502), the guide rail (401) is fixedly connected to the upper surface of the guide plate (4), and the second rack (402) is fixedly connected to the front surface of the guide plate (4) near the center.

7. The anti-collision cleaning device for optical glass processing according to claim 6, wherein the first lifting module (5) and the second lifting module (6) have the same structure, a cleaning frame (701) is fixedly connected to the outer surface of the connecting frame (7), a rubber separation net (702) is fixedly connected to the inner part of the cleaning frame (701), the first gear (304) is in meshed connection with the first rack (509), the second bevel gear (505) is in meshed connection with the first bevel gear (503), and the damping block (507) is in sliding connection with the guide rail (401).