CN221883471U - Detection device for optical lens processing - Google Patents

Abstract

The utility model discloses a detection device for optical lens processing, comprising a workbench, a support frame is provided on the workbench, a detector body is provided on the support frame, a display electrically connected to the detector body is provided on the workbench, a positioning slider is rotatably provided on the workbench, a positioning block is symmetrically provided on the positioning slider, a rotating shaft is rotatably provided on the positioning block, a clamping block is provided on the rotating shaft, a clamping mechanism is provided on the clamping block, a group of matching groove wheels are provided on the rotating shaft, a rotating groove wheel is rotatably provided on the positioning block, a transmission belt is provided on the rotating groove wheel and the matching groove wheel, a rotating motor is provided on the positioning block, and an output end of the rotating motor is connected to the rotating groove wheel. Compared with the prior art, the utility model has the advantages of realizing flipping and rotation of the optical lens, conveniently obtaining a comprehensive detection range, and improving detection efficiency.

Description

A detection device for optical lens processing

Technical Field

The utility model relates to the technical field of lens detection devices, in particular to a detection device for optical lens processing.

Background Art

Optical lenses are made of high-purity oxides of silicon, boron, sodium, potassium, zinc, lead, magnesium, calcium, barium, etc. mixed according to a specific formula, melted at high temperature in a platinum crucible, stirred evenly with ultrasound to remove bubbles, and then slowly cooled for a long time. During the optical lens processing operation, the optical lens needs to be inspected to confirm whether the surface of the optical lens is smooth, whether there are any traces, etc. When inspecting the optical lens, a detection device is required.

Existing inspection devices for optical lens processing usually include a placement table and an optical inspection instrument. The optical inspection instrument is placed on the placement table. When in use, the optical lens is placed on the placement table, and then the optical inspection instrument is started. The optical inspection instrument inspects the optical lens and determines whether it is qualified or not. When this type of inspection device is used in practice, it is impossible to flip or rotate the optical lens, which results in the need to adjust the position and angle of the optical lens multiple times and fix it to obtain a comprehensive inspection range, thereby reducing the inspection efficiency.

Utility Model Content

The technical problem to be solved by the utility model is to provide a detection device for optical lens processing which can be conveniently turned over and rotated.

In order to solve the above technical problems, the technical solution provided by the utility model is: a detection device for optical lens processing, including a workbench, a support frame is provided on the workbench, a detector body is provided on the support frame, a display electrically connected to the detector body is provided on the workbench, a positioning slider is rotatably provided on the workbench, positioning blocks are symmetrically provided on the positioning slider, a rotating shaft is rotatably provided on the positioning block, a clamping block is provided on the rotating shaft, a clamping mechanism is provided on the clamping block, a group of matching groove wheels are provided on the rotating shaft, a rotating groove wheel is rotatably provided on the positioning block, a transmission belt is provided on the rotating groove wheel and the matching groove wheel, a rotating motor is provided on the positioning block, and the output end of the rotating motor is connected to the rotating groove wheel.

As an improvement, the clamping mechanism includes a limit screw, a threaded sleeve, a limit slide, a limit block and a fixed block. The limit screw is rotatably set on a group of the clamping blocks, the limit screw is connected with a threaded sleeve by a thread, the limit slide is set on another group of the clamping blocks, the limit slide is slidably provided with a limit block, the limit block is connected to the threaded sleeve, and multiple groups of fixed blocks are symmetrically provided on the limit block. The clamping block is provided with an adjusting motor, and the output end of the adjusting motor is connected to the limit screw.

As an improvement, a connecting groove is provided on the fixing block, and the circumference of the connecting groove is a rounded structure.

As an improvement, the limit blocks are symmetrically arranged in two groups, the limit screw is provided with a bidirectional thread, and the threaded sleeves and the limit blocks are arranged correspondingly.

As an improvement, the inner side of the fixing block is an arc-shaped structure, which better fits the optical lens, thereby better clamping and fixing the optical lens.

As an improvement, an electric push rod is provided on the workbench, and a supporting plate is provided at the telescopic end of the electric push rod.

As an improvement, a positioning slide groove is provided on the workbench, the positioning slide groove is a circular structure, and the positioning slider is slidably connected to the positioning slide groove.

As an improvement, a matching rack is provided on the positioning slider, a driving motor is provided on the workbench, a driving gear is connected to the output end of the driving motor, and the driving gear is meshed with the matching rack.

The advantages of the utility model compared with the prior art are:

The rotating motor drives the matching groove wheel to rotate through the rotating groove wheel and the transmission belt, and the matching groove wheel drives the clamping mechanism to rotate through the rotating shaft and the clamping block. The clamping mechanism conveniently clamps the optical lens, thereby realizing the flipping of the optical lens. At the same time, with the cooperation of the rotating positioning slider, the optical lens can be rotated, which facilitates the acquisition of a comprehensive detection range and improves the detection efficiency.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic structural diagram of a detection device for optical lens processing according to the present invention.

FIG. 2 is a second structural schematic diagram of a detection device for optical lens processing according to the present invention.

FIG. 3 is a third structural schematic diagram of a detection device for optical lens processing according to the present invention.

FIG. 4 is an enlarged view of part A of a detection device for processing optical lenses of the present invention.

As shown in the figure: 1. Workbench; 2. Support frame; 3. Tester body; 4. Display; 5. Positioning slide; 6. Positioning slider; 7. Matching rack; 8. Driving motor; 9. Driving gear; 10. Electric push rod; 11. Support plate; 12. Positioning block; 13. Rotating shaft; 14. Clamping block; 15. Limit screw; 16. Threaded sleeve; 17. Limit slide column; 18. Limit block; 19. Fixed block; 20. Connecting groove; 21. Adjusting motor; 22. Matching groove wheel; 23. Rotating groove wheel; 24. Transmission belt; 25. Rotating motor.

DETAILED DESCRIPTION

The utility model is further described in detail below in conjunction with the accompanying drawings.

In conjunction with Figures 1 to 4, a detection device for optical lens processing includes a workbench 1, a support frame 2 is provided on the workbench 1, a detector body 3 is provided on the support frame 2, a display 4 electrically connected to the detector body 3 is provided on the workbench 1, the detector body 3 detects the optical lens, and the display 4 displays the detection result, a positioning slider 6 is rotatably provided on the workbench 1, a positioning slide groove 5 is provided on the workbench 1, the positioning slide groove 5 is a circular structure, the positioning slider 6 is slidably connected to the positioning slide groove 5, a matching rack 7 is provided on the positioning slider 6, a drive motor 8 is provided on the workbench 1, a drive gear 9 is connected to the output end of the drive motor 8, the drive gear 9 is meshed with the matching rack 7, and the drive motor The machine 8 drives the driving gear 9 to rotate, and the driving gear 9 drives the positioning slide block 6 to rotate along the positioning slide groove 5 through the matching rack 7. The positioning slide block 6 is symmetrically provided with positioning blocks 12, and the positioning block 12 is rotatably provided with a rotating shaft 13, and the rotating shaft 13 is provided with a clamping block 14, and the clamping block 14 is provided with a clamping mechanism. A group of the rotating shafts 13 are provided with matching groove wheels 22, and the positioning block 12 is rotatably provided with a rotating groove wheel 23. The rotating groove wheel 23 and the matching groove wheel 22 are provided with a transmission belt 24. The positioning block 12 is provided with a rotating motor 25, and the output end of the rotating motor 25 is connected to the rotating groove wheel 23. The workbench 1 is provided with an electric push rod 10, and the telescopic end of the electric push rod 10 is provided with a supporting plate 11 for convenient placement of optical lenses.

In conjunction with Figures 1 to 4, the clamping mechanism includes a limit screw 15, a threaded sleeve 16, a limit slide 17, a limit block 18 and a fixed block 19. The limit screw 15 is rotatably arranged on a group of the clamping blocks 14. The limit screw 15 is connected with a threaded sleeve 16 by a thread. The limit slide 17 is arranged on another group of the clamping blocks 14. The limit slide 17 is slidably provided with a limit block 18, and the limit block 18 is connected to the threaded sleeve 16. Two groups of limit blocks 18 are symmetrically arranged. The limit screw 15 is provided with a bidirectional thread. The threaded sleeve 16 is correspondingly arranged with the limit block 18. A plurality of groups of fixed blocks 19 are symmetrically arranged on the limit block 18. The inner sides of the fixed blocks 19 are all arc-shaped structures. A connecting groove 20 is provided on the fixed block 19. The circumference of the connecting groove 20 is all rounded structure. An adjusting motor 21 is provided on the clamping block 14, and the output end of the adjusting motor 21 is connected to the limit screw 15.

During the specific implementation of the utility model, the electric push rod 10 is operated to extend, and the electric push rod 10 drives the supporting plate 11 to move upward, and the optical lens is placed on the supporting plate 11, and the adjustment motor 21 is started, and the adjustment motor 21 drives the limit screw 15 to rotate, and the threaded sleeve 16 drives the limit block 18 to slide along the limit slide column 17 and approach each other, and the fixed blocks 19 approach each other to clamp and fix the optical lens, and the detector body 3 is started, and the detector body 3 detects the optical lens, and the detection result is displayed on the display 4. When the optical lens needs to be rotated, the electric push rod 10 is operated to shorten, and the electric push rod 10 drives the supporting plate 11 to move downward. The supporting plate 11 is separated from the optical lens, and the driving motor 8 is started. The driving motor 8 drives the driving gear 9 to rotate. The driving gear 9 drives the positioning slider 6 to rotate along the positioning slide groove 5 through the matching rack 7, and the positioning block 12 rotates synchronously, thereby realizing the rotation of the optical lens. When the optical lens needs to be flipped, the rotating motor 25 is started. The rotating motor 25 drives the matching groove wheel 22 to rotate through the rotating groove wheel 23 and the transmission belt 24. The matching groove wheel 22 drives the limit block 18 to rotate through the rotating shaft 13 and the clamping block 14. The limit block 18 rotates, thereby realizing the flipping of the optical lens, conveniently obtaining a comprehensive detection range, and improving the detection efficiency.

The above description of the utility model and its implementation methods is not restrictive. The drawings show only one implementation method of the utility model, and the actual structure is not limited thereto. In short, if ordinary technicians in this field are inspired by it and design structural methods and embodiments similar to the technical solution without creativity without departing from the purpose of the invention of the utility model, they should all fall within the protection scope of the utility model.

Claims (8)

1. The utility model provides a detection device is used in optical lens processing, includes workstation (1), is equipped with support frame (2) on workstation (1), is equipped with detector body (3) on support frame (2), is equipped with display (4) be connected with detector body (3) electricity on workstation (1), its characterized in that: the rotary positioning device is characterized in that a positioning sliding block (6) is rotationally arranged on the workbench (1), a positioning block (12) is symmetrically arranged on the positioning sliding block (6), a rotating shaft (13) is rotationally arranged on the positioning block (12), a clamping block (14) is arranged on the rotating shaft (13), a clamping mechanism is arranged on the clamping block (14), a group of rotary sheaves (22) are arranged on the rotating shaft (13), rotary sheaves (23) are rotationally arranged on the positioning block (12), a transmission belt (24) is arranged on the rotary sheaves (23) and the rotary sheaves (22), a rotary motor (25) is arranged on the positioning block (12), and the output end of the rotary motor (25) is connected with the rotary sheaves (23).

2. The optical lens processing inspection device according to claim 1, wherein: the clamping mechanism comprises a limiting screw (15), a thread bush (16), a limiting slide column (17), a limiting block (18) and a fixed block (19), wherein the limiting screw (15) is rotationally arranged on one group of the clamping blocks (14), the limiting screw (15) is provided with the thread bush (16) through threaded connection, the limiting slide column (17) is arranged on the other group of the clamping blocks (14), the limiting slide column (17) is provided with the limiting block (18) in a sliding manner, the limiting block (18) is connected with the thread bush (16), a plurality of groups of fixed blocks (19) are symmetrically arranged on the limiting block (18), an adjusting motor (21) is arranged on the clamping blocks (14), and the output end of the adjusting motor (21) is connected with the limiting screw (15).

3. The optical lens processing inspection device according to claim 2, wherein: the fixed block (19) is provided with a communication groove (20), and the circumference of the communication groove (20) is of a round corner structure.

4. The optical lens processing inspection device according to claim 2, wherein: two groups of limiting blocks (18) are symmetrically arranged, two-way threads are arranged on the limiting screw rod (15), and the thread sleeve (16) is arranged corresponding to the limiting blocks (18).

5. A detection device for optical lens processing according to claim 3, wherein: the inner sides of the fixed blocks (19) are arc-shaped structures.

6. The optical lens processing inspection device according to claim 1, wherein: an electric push rod (10) is arranged on the workbench (1), and a supporting plate (11) is arranged at the telescopic end of the electric push rod (10).

7. The optical lens processing inspection device according to claim 1, wherein: the workbench (1) is provided with a positioning chute (5), the positioning chute (5) is of a circular structure, and the positioning slide block (6) is in sliding connection with the positioning chute (5).

8. The optical lens processing inspection device according to claim 1, wherein: the positioning sliding block (6) is provided with a matching rack (7), the workbench (1) is provided with a driving motor (8), the output end of the driving motor (8) is connected with a driving gear (9), and the driving gear (9) is meshed with the matching rack (7).