CN220542814U - Post-production detection device for glass ceramic lens - Google Patents

Abstract

The utility model relates to the technical field of glass lens detection and discloses a post-production detection device for glass-ceramic lenses, which comprises a workbench, wherein two movable plates are respectively arranged on two sides of the top of the workbench, clamping plates are respectively fixed on one sides of the two movable plates, which are close to each other, a light-gathering cylinder is fixed on the top of the workbench, a light-transmitting placing table is arranged on the top of the light-gathering cylinder, a light source is arranged in the light-gathering cylinder and on the top of the workbench, the light-transmitting placing table is made of glass, a support column is fixed on the top of the workbench, and a magnifying glass is arranged on one side of the support column. The magnifying glass is limited by the movable crank without being held by a user, the position and the angle of the magnifying glass can be adjusted by the damping telescopic rod and the movable crank, the light source is conveniently provided for the lens by the aid of the light source, the visual field definition of the user can be improved, and accordingly the detection accuracy is improved.

Description

Post-production detection device for glass ceramic lens

Technical Field

The utility model relates to the technical field of glass lens detection, in particular to a post-production detection device for a glass ceramic lens.

Background

The lens is an optical element with a spherical surface part and made of transparent substances, and the lens consists of a plurality of lenses, namely a plastic lens and a glass lens; a good-quality camera is provided with a glass lens, the imaging effect is better than that of a plastic lens, and the camera plays an important role in astronomical, military, traffic, medical and artistic fields; the lens is inevitably defective in production, such as pits, bubbles, scratches and the like, and the defects not only affect the appearance of the element, but also affect the functions of the element and the system in which the element is positioned, so that the lens after production needs to be detected.

For example, in the patent application with the publication number CN 210834099U, a set of hemispherical fixing blocks are provided, the telescopic supporting component is used to connect with the fixing platform, when in use, the optical glass lens is fixed on the hemispherical fixing blocks, the angle of the optical glass lens can be changed by using external force, and the magnifying glass can be used to observe any position of the surface conveniently.

In use, the optical glass lens is fixed on the hemispherical fixing block, and the surface of the optical glass lens is observed by using the magnifier, but when the light is dim, the light device is required to be held by a hand to lighten and detect the glass lens, and meanwhile, the magnifier is held to observe, so that the method is inconvenient and complicated.

Disclosure of Invention

The utility model aims to provide a post-production detection device for a glass ceramic lens, which solves the problem that the lens is inconvenient to lighten in the prior art.

The utility model provides the following technical scheme: the utility model provides a detection device behind glass ceramic lens production, includes the workstation, the both sides at workstation top are provided with two fly leaves respectively, two one side that the fly leaf is close to each other is fixed with splint respectively, the top of workstation is fixed with a spotlight section of thick bamboo, the top of spotlight section of thick bamboo is provided with the printing opacity and places the platform, the light source is installed at the inside of spotlight section of thick bamboo and the top of workstation, the construction material that the platform was placed in the printing opacity is glass, the top of workstation is fixed with the pillar, one side of pillar is provided with the magnifying glass.

As the optimization of the technical scheme, the two sides of the top of the workbench are respectively provided with the movable grooves, two movable grooves are connected with the bidirectional screw rod in a common rotation mode, two ends of the bidirectional screw rod are respectively connected with the sliding blocks in a threaded mode, and the tops of the two sliding blocks are respectively fixedly connected with the two movable plates.

As the preferable of the technical scheme, one end of the bidirectional screw rod penetrates through the workbench to extend to one side of the workbench and is fixedly connected with a handle.

As the preferable mode of the technical scheme, the two clamping plates are rotatably connected with a plurality of groups of balls on one side close to each other.

As the optimization of the technical scheme, the top of the light condensation barrel is provided with the sliding groove, the bottom of the light transmission placing table is fixedly provided with the sliding ring, and the sliding ring is in sliding connection with the sliding groove.

As the optimization of the technical scheme, the knob is fixed on the outer surface of the light-transmitting placing table, and a plurality of groups of convex strips are uniformly fixed on the outer surface of the knob.

As the optimization of the technical scheme, one side of the support column is fixedly provided with a damping telescopic rod, the telescopic end of the damping telescopic rod is movably connected with a movable crank, and one end of the movable crank, which is far away from the damping telescopic rod, is movably connected with the magnifying glass.

As the optimization of the technical scheme, an auxiliary rod is fixedly connected to one side of the movable crank, which is far away from the magnifier.

Compared with the prior art, the utility model has the beneficial effects that:

according to the utility model, the lens to be detected is placed on the top of the light-transmitting placing table, the light source is emitted by the light source and passes through the light-transmitting placing table through the light-gathering cylinder to be placed on the lens, so that the detection environment is improved, when the lens is required to be observed in all directions, the knob can be rotated to drive the light-transmitting placing table to rotate so as to drive the slip ring to slide in the sliding groove, the lens is rotated, the better lens is observed, the auxiliary rod is pulled to drive the movable crank to rotate, the magnifier is placed above the lens, the lens is observed and detected through the magnifier, meanwhile, the auxiliary rod is pulled to drive the damping telescopic rod to stretch so as to adjust the position of the magnifier, the magnifier is limited through the movable crank without being held by a user, the position and angle of the magnifier can be adjusted through the damping telescopic rod and the movable crank, the light source is arranged to provide the light source for the lens conveniently, and the visual field definition of the user can be improved, and the detection accuracy is improved.

Drawings

FIG. 1 is a schematic diagram showing the overall three-dimensional structure of a post-production inspection device for glass ceramic lenses;

FIG. 2 is a schematic diagram showing the structure of a detector for concentrating light after glass-ceramic lens production;

FIG. 3 is a schematic cross-sectional view of a device for inspecting glass-ceramic lenses after production;

fig. 4 is a schematic structural diagram of a post-production inspection device post of a glass ceramic lens.

In the figure: 100-working table; 101-a condensing cylinder; 102-a light-transmitting placing table; 103-sliding grooves; 104-slip rings; 105-knob; 106-a light source; 200-a movable plate; 201-clamping plate; 202-balls; 203-a bidirectional screw rod; 204-a slider; 205-handle; 300-prop; 301-damping telescopic rod; 302-a movable crank; 303-magnifier; 304-auxiliary bar.

Description of the embodiments

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model.

Example 1

As shown in fig. 1-4, the present utility model provides a technical solution: the utility model provides a detection device after microcrystalline glass lens production, including workstation 100, the both sides at workstation 100 top are provided with two fly boards 200 respectively, the one side that two fly boards 200 are close to each other is fixed with splint 201 respectively, the top of workstation 100 is fixed with spotlight section of thick bamboo 101, the top of spotlight section of thick bamboo 101 is provided with the printing opacity and places platform 102, the inside of spotlight section of thick bamboo 101 and the top of workstation 100 install light source 106, the construction material that the platform 102 was placed in the printing opacity is glass, the top of workstation 100 is fixed with pillar 300, one side of pillar 300 is provided with magnifying glass 303, spout 103 has been seted up at the top of spotlight section of thick bamboo 101, the bottom that the platform 102 was placed in the printing opacity is fixed with sliding ring 104, sliding ring 104 and spout 103 sliding connection, the surface that the platform 102 was placed in the printing opacity is fixed with knob 105, the surface of knob 105 evenly is fixed with the multiunit sand grip, one side of pillar 300 is fixed with damping telescopic link 301, the flexible end swing joint of damping telescopic link 301 has movable crank 302, the one end that damping telescopic link 301 kept away from damping telescopic link 301 and magnifying glass 303 swing joint, one side that movable crank 302 kept away from magnifying glass 303 is fixedly connected with auxiliary rod 304.

As an implementation manner in this embodiment, as shown in fig. 1-3, a lens to be detected is placed on top of the transparent placing table 102, a light source 106 is started to emit light source, and the light source passes through the transparent placing table 102 through the condensing tube 101 to be placed on the lens, so as to improve the detection environment, when the lens is required to be observed in all directions, the knob 105 can be rotated to drive the transparent placing table 102 to rotate so as to drive the slip ring 104 to slide in the sliding groove 103, the lens is rotated, and the lens is observed better, so that the light source 106 is convenient to provide light source for the lens, the visual field definition of a user can be improved, and the detection accuracy is improved.

As an implementation manner in this embodiment, as shown in fig. 4, the auxiliary rod 304 is pulled to drive the movable crank 302 to rotate, the magnifier 303 is placed above the lens, the lens is observed and detected by the magnifier 303, meanwhile, the auxiliary rod 304 is pulled to drive the damping telescopic rod 301 to stretch and retract so as to adjust the position of the magnifier 303, the magnifier 303 is limited by the movable crank 302 without being held by a user, and the position and the angle of the magnifier 303 can be adjusted by the damping telescopic rod 301 and the movable crank 302.

Example 2

As shown in fig. 3, based on the same concept as that of the above embodiment 1, the present embodiment further provides a post-production detection device for a glass-ceramic lens, which comprises a workbench 100, two movable plates 200 are respectively disposed on two sides of the top of the workbench 100, clamping plates 201 are respectively fixed on one sides of the two movable plates 200, which are close to each other, a condensing barrel 101 is fixed on the top of the workbench 100, a light-transmitting placing table 102 is disposed on the top of the condensing barrel 101, a light source 106 is mounted on the top of the workbench 100, the light-transmitting placing table 102 is made of glass, an magnifier 303 is disposed on one side of the support 300, movable grooves are respectively configured on two sides of the top of the workbench 100, two bidirectional screw rods 203 are connected in a co-rotating manner in the two movable grooves, two ends of the bidirectional screw rods 203 are respectively connected with sliding blocks 204 in a threaded manner, one ends of the bidirectional screw rods 203 extend through the workbench 100 to one sides thereof and are fixedly connected with handles 205, and one sides of the two clamping plates 201 are respectively connected with multiple groups of balls 202 in a rotating manner.

As an implementation manner in this embodiment, as shown in fig. 3, the handle 205 is turned to drive the bidirectional screw 203 to rotate, so as to drive the two sliding blocks 204 to approach each other, so as to drive the two movable plates 200 to approach each other, so that the two clamping plates 201 gradually approach the lens, and finally contact the lens, and the bidirectional screw 203 and the sliding blocks 204 are arranged to facilitate the transmission of the movable plates 200 to approach each other, so that the lenses with different specifications are clamped and fixed, the applicability of the device is improved, the friction force to the lenses can be reduced by the balls 202, the rigid contact is reduced, and the handle 205 is arranged to facilitate the operation of a user.

Working principle: when the device is used, a lens to be detected is placed on the top of the light-transmitting placing table 102, the two-way screw 203 is driven to rotate through the rotating handle 205, the two sliding blocks 204 are driven to be close to each other, the two movable plates 200 are driven to be close to each other, the two clamping plates 201 are gradually close to the lens, the lens is finally contacted with the lens, the light source 106 is started to emit the light source, the light source penetrates through the light-transmitting placing table 102 and is placed on the lens through the light-gathering barrel 101, the detection environment is improved, the movable crank 302 is driven to rotate through the pulling auxiliary rod 304, the magnifier 303 is placed above the lens, the lens is observed and detected through the magnifier 303, meanwhile, the damping telescopic rod 301 is driven to stretch and retract to adjust the position of the magnifier 303 through the pulling auxiliary rod 304, the rotatable knob 105 drives the light-transmitting placing table 102 to rotate, the sliding ring 104 is driven to slide in the sliding groove 103, and the friction force to the lens is reduced, so that the ball 202 can rotate the lens better.

The above embodiments are only for illustrating the technical solution of the present utility model, and are not limiting.

Claims (8)

1. Post-production detection device for glass ceramic lenses, comprising a workbench (100), and being characterized in that: two movable plates (200) are respectively arranged on two sides of the top of the workbench (100), clamping plates (201) are respectively fixed on one sides, close to each other, of the movable plates (200), a light-gathering cylinder (101) is fixed on the top of the workbench (100), a light-transmitting placing table (102) is arranged on the top of the light-gathering cylinder (101), a light source (106) is arranged in the light-gathering cylinder (101) and on the top of the workbench (100), the light-transmitting placing table (102) is made of glass, a support column (300) is fixed on the top of the workbench (100), and a magnifying glass (303) is arranged on one side of the support column (300).

2. The post-production detection device for glass ceramic lenses according to claim 1, wherein: two sides of the top of the workbench (100) are respectively provided with a movable groove, two movable grooves are connected with a bidirectional screw rod (203) in a common rotation mode, two ends of the bidirectional screw rod (203) are respectively connected with a sliding block (204) in a threaded mode, and the tops of the two sliding blocks (204) are respectively fixedly connected with two movable plates (200).

3. The post-production detection device for glass ceramic lenses according to claim 2, wherein: one end of the bidirectional screw rod (203) penetrates through the workbench (100) to extend to one side of the workbench, and is fixedly connected with a handle (205).

4. The post-production detection device for glass ceramic lenses according to claim 1, wherein: and a plurality of groups of balls (202) are rotatably connected to one side, close to each other, of each clamping plate (201).

5. The post-production detection device for glass ceramic lenses according to claim 1, wherein: a sliding groove (103) is formed in the top of the light condensation barrel (101), a sliding ring (104) is fixed to the bottom of the light transmission placing table (102), and the sliding ring (104) is connected with the sliding groove (103) in a sliding mode.

6. The post-production detection device for glass ceramic lenses according to claim 1, wherein: the outer surface of the light-transmitting placing table (102) is fixedly provided with a knob (105), and a plurality of groups of convex strips are uniformly fixed on the outer surface of the knob (105).

7. The post-production detection device for glass ceramic lenses according to claim 1, wherein: a damping telescopic rod (301) is fixed on one side of the support column (300), a movable crank (302) is movably connected to the telescopic end of the damping telescopic rod (301), and one end, far away from the damping telescopic rod (301), of the movable crank (302) is movably connected with a magnifying glass (303).

8. The post-production inspection device for glass ceramic lenses according to claim 7, wherein: an auxiliary rod (304) is fixedly connected to one side of the movable crank (302) far away from the magnifier (303).