CN218847080U

CN218847080U - Optical glass thickness detection microscope carrier

Info

Publication number: CN218847080U
Application number: CN202223167949.XU
Authority: CN
Inventors: 陈珊
Original assignee: Zhejiang TBest Electronic Information Technology Co ltd
Current assignee: Zhejiang TBest Electronic Information Technology Co ltd
Priority date: 2022-11-29
Filing date: 2022-11-29
Publication date: 2023-04-11
Anticipated expiration: 2032-11-29

Abstract

The utility model provides an optical glass thickness detects microscope carrier, include: a detection table; the placing opening is formed in the detection table; the support frame is fixedly arranged at the top of the detection table, first through holes are formed in two sides of the interior of the support frame, a first moving rod is arranged in each first through hole, a pressing plate is fixedly arranged at the bottom of each first moving rod, and a first spring is arranged on the surface of each first moving rod and positioned at the top of each pressing plate; the second through hole is formed in the pressing plate, and a second moving rod is arranged in the second through hole. The utility model provides a pair of optical glass thickness detects microscope carrier can be fast and can detect its more quantity's optical glass to holistic practicality has been improved, and simple structure, and convenient operation is convenient for read and is detected the structure, thereby has improved work efficiency.

Description

Optical glass thickness detection microscope carrier

Technical Field

The utility model relates to an optical glass field especially relates to an optical glass thickness detects microscope carrier.

Background

The optical glass can change the propagation direction of light and can change the relative spectral distribution of ultraviolet, visible or infrared light.

Along with the continuous improvement of science and technology, thereby various different optical instruments have appeared, thereby need use optical glass when making optical instrument, and optical glass in optical instrument needs to use the optical glass of different thickness according to the actual condition, thereby need use the detection microscope carrier when measuring optical glass.

The existing optical glass thickness detection carrying platform is used for clamping and fixing optical glass of the carrying platform, the detected thickness is inconvenient and quick to find out when the carrying platform is used for measuring, and the detection work can not be quickly carried out on a plurality of optical glasses of the carrying platform, so that the working efficiency is reduced.

Therefore, it is necessary to provide an optical glass thickness detection stage to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides an optical glass thickness detection microscope carrier has solved and has detected the microscope carrier and carried out the centre gripping fixed to its optical glass mostly when using, and inconvenient quick the thickness of seeing out that detects when measuring, and can not be quick carry out detection achievement to its a plurality of optical glass to work efficiency's problem has been reduced.

In order to solve the technical problem, the utility model provides a pair of optical glass thickness detection microscope carrier, include: a detection table;

the placing opening is formed in the detection table;

the support frame is fixedly arranged at the top of the detection table, first through holes are formed in two sides of the interior of the support frame, a first moving rod is arranged in each first through hole, a pressing plate is fixedly arranged at the bottom of each first moving rod, and a first spring is arranged on the surface of each first moving rod and positioned at the top of each pressing plate;

the second through hole, the second through hole is seted up in the inside of clamp plate, the inside of second through hole is provided with the second carriage release lever, the surface of second carriage release lever is provided with the scale bar, the top fixed mounting of second carriage release lever has the stopper, the bottom fixed mounting of second carriage release lever has the contact plate, the top of contact plate just is located the surface of second carriage release lever is provided with the second spring.

Preferably, the detection table is internally provided with openings on two sides of the placing opening.

Preferably, a pull rod is fixedly installed at the top of the first movable rod.

Preferably, the bottom of examining test table is provided with the base, circular spout has been seted up at the top of base, the equal sliding connection in both sides of circular spout inside has the arc slider, the top fixed mounting of arc slider has the connecting block.

Preferably, the top of the connecting block and the bottom of the detection table are fixedly installed, and a connecting rod is fixedly installed on the outer side of the connecting block.

Preferably, a third through hole is formed in the right side inside the connecting rod, an inserting rod is arranged inside the third through hole, and a tension spring is arranged on the surface of the inserting rod and located at the top of the connecting rod.

Preferably, the clamping grooves are formed in the two sides of the top of the base.

Compared with the prior art, the utility model provides a pair of optical glass thickness detects microscope carrier has following beneficial effect:

the utility model provides an optical glass thickness detects microscope carrier, thereby can be fast and can detect its optical glass of more quantity through detecting the platform, place mouth, support frame, first running through, first carriage release lever, clamp plate, first spring, second through hole, second carriage release lever, contact plate, scale bar, stopper, second spring isotructure between mutually supporting, thereby whole practicality has been improved, and simple structure, convenient operation is convenient for read and is detected the structure, thereby work efficiency has been improved.

Drawings

Fig. 1 is a schematic structural diagram of a first embodiment of an optical glass thickness detection stage according to the present invention;

FIG. 2 is a schematic view of the bottom of the platen shown in FIG. 1;

FIG. 3 is a schematic view of the top of the inspection station shown in FIG. 1;

fig. 4 is a schematic structural diagram of a second embodiment of an optical glass thickness detection stage according to the present invention;

FIG. 5 is a schematic view of the top of the circular chute of FIG. 4;

fig. 6 is an enlarged view of the portion a shown in fig. 4.

Reference numbers in the figures: 1. the detection device comprises a detection table, 2, a placement opening, 3, an opening, 4, a support frame, 5, a first through hole, 6, a first moving rod, 7, a pull rod, 8, a pressure plate, 9, a first spring, 10, a second through hole, 11, a second moving rod, 12, a contact plate, 13, a scale bar, 14, a limiting block, 15 and a second spring,

151. the base, 16, circular spout, 17, arc slider, 18, connecting block, 19, connecting rod, 20, third through hole, 21, inserted bar, 22, draw-in groove, 23, extension spring.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and embodiments.

First embodiment

Please refer to fig. 1, fig. 2 and fig. 3 in combination, wherein fig. 1 is a schematic structural diagram of a first embodiment of an optical glass thickness detection stage according to the present invention; FIG. 2 is a schematic view of the bottom of the platen shown in FIG. 1; fig. 3 is a schematic structural view of the top of the inspection station shown in fig. 1. An optical glass thickness detection stage comprising: a detection table 1;

the placing port 2 is formed in the detection table 1;

the supporting frame 4 is fixedly installed at the top of the detection table 1, first through holes 5 are formed in two sides of the interior of the supporting frame 4, first moving rods 6 are arranged in the first through holes 5, a pressing plate 8 is fixedly installed at the bottom of the first moving rods 6, and first springs 9 are arranged on the surfaces of the first moving rods 6 and located at the top of the pressing plate 8;

second through hole 10, second through hole 10 is seted up in the inside of clamp plate 8, the inside of second through hole 10 is provided with second carriage release lever 11, the surface of second carriage release lever 11 is provided with scale bar 13, the top fixed mounting of second carriage release lever 11 has stopper 14, the bottom fixed mounting of second carriage release lever 11 has contact plate 12, the top of contact plate 12 just is located the surface of second carriage release lever 11 is provided with second spring 15.

The position of the second moving rod 11 is fixed by the limiting block 14 matching with the contact plate 12, so that the second moving rod 11 is prevented from being separated from the inside of the second through hole 10, and the pressing plate 8 can move upwards to drive the limiting block 14, the second moving rod 11 and other structures to move.

Detect the inside of platform 1 and be located place the both sides of mouth 2 and all seted up opening 3.

Thereby can make things convenient for the staff to take out through opening 3 and place 2 inside objects of mouth, enlarge the inner space a little to the staff of being convenient for takes the object.

And a pull rod 7 is fixedly arranged at the top of the first movable rod 6.

Thereby can make things convenient for the staff to operate through pull rod 7, reduce the operation degree of difficulty.

The utility model provides a pair of working principle of optical glass thickness detection microscope carrier is as follows:

carry out the majority or single optical glass when carrying out thickness detection work as required, through manual upwards pulling pull rod 7, thereby the atress rebound through pull rod 7 drives first carriage bar 6 and carries out the rebound, and first carriage bar 6 at this moment carries out the rebound in the inside of first through-hole 5, thereby the rebound of rethread first carriage bar 6 drives clamp plate 8 and carries out the rebound, thereby the rebound of rethread first carriage bar 6 extrudees first spring 9, make its first spring 9 take place elastic deformation, thereby the rebound through clamp plate 8 drives second through-hole 10 and carries out the simultaneous movement again.

And the second moving rod 11 and the contact plate move downwards due to the elastic deformation of the second spring 15, when the pressing plate 8 moves upwards and drives the second through hole 10 to move upwards, and at this time, the second through hole 10 moves upwards on the surface of the second moving rod 11, and at this time, the position of the second moving rod 11 does not change, and then the pressing plate 8 moves upwards until the second through hole 10 moves to the topmost part of the second moving rod 11, at this time, because of the existence of the stopper 14, so that in this case, the stopper 14 is driven to move upwards by the upward movement of the pressing plate 8, the second moving rod 11 is driven to move upwards by the upward movement of the stopper 14, and at this time, the structures such as the second moving rod 11, the second through hole 10, the pressing plate 8 and the like move synchronously, and then the second spring 15 and the contact plate 12 are driven to move upwards by the upward movement of the second moving rod 11, and the contact plate 12 moves upwards inside the placing opening 2 until the contact plate 12 is separated from the placing opening 2, and the number of the contact plates placed in the optical glass placing opening 2 is detected according to the number of the contact plates placed glass to be placed in the flat glass placing opening, and the glass placed state is detected at this time, and the glass is placed glass placed in the glass placing opening.

Until the placing is completed, the pull rod 7 is pulled upwards by loosening, the pressing plate 8 is pushed downwards to move downwards through the elastic deformation of the first spring 9, the first moving rod 6 is driven by the downward movement of the pressing plate 8, the first moving rod 6 moves downwards in the first through hole 5 until the bottom of the pressing plate 8 contacts with the top of the detection table 1, the contact plate 12 is pushed downwards through the elastic deformation of the second spring 15 while the pressing plate 8 moves downwards, the contact plate 12 moves downwards, the second moving rod 11 is driven by the downward movement of the contact plate 12 to move downwards, the second moving rod 11 moves downwards in the second through hole 10, and the contact plate 12 contacts with the bottom of the contact plate 12 and the top of the optical glass placed in the placing opening 2.

Since the depth of the placing port 2 and the thickness of the pressing plate 8 are known, when the bottom of the contact plate 12 is in contact with the top inside the placing port 2 when no object is placed in the placing port 2, the pressing plate 8 is in contact with the top of the detection table 1, and the zero position of the scale bar 13 on the surface of the second moving rod 11 and the top side line of the pressing plate 8 are in a flat state at this time, and when optical glass is placed in the placing port 2, the bottom of the contact plate 12 is in contact with the top of the object, and the bottom of the pressing plate 8 is in contact with the top of the detection table 1, in this state, a part of the second moving rod 11 does not extend into the second through hole 10 and the placing port 2, and the length of the part is the thickness of the optical glass, and then the data on the scale bar 13 on the surface of the second moving rod 11 is read.

After the measurement is completed, the placing port 2 is opened by repeating the above-mentioned operations, and the optical glass is manually taken out from the opening 3.

through examining test table 1, place mouthful 2, support frame 4, first through hole 5, first carriage release lever 6, clamp plate 8, first spring 9, second through hole 10, second carriage release lever 11, contact plate 12, scale bar 13, stopper 14, the light glass who just can be to its more quantity fast of mutually supporting between the second spring 15 isotructure detects the work, thereby holistic practicality has been improved, and simple structure, convenient operation is convenient for read and is detected the structure, thereby work efficiency has been improved.

Second embodiment

Referring to fig. 4, fig. 5 and fig. 6 in combination, based on the optical glass thickness detection stage provided in the first embodiment of the present application, a second embodiment of the present application provides another optical glass thickness detection stage. The second embodiment is only the preferred mode of the first embodiment, and the implementation of the second embodiment does not affect the implementation of the first embodiment alone.

Specifically, the difference between the optical glass thickness detection stage provided by the second embodiment of the present application lies in that, an optical glass thickness detection stage is provided, the bottom of the detection table 1 is provided with a base 151, a circular chute 16 is formed at the top of the base 151, arc-shaped sliding blocks 17 are slidably connected to two sides of the inside of the circular chute 16, and a connecting block 18 is fixedly mounted at the top of each arc-shaped sliding block 17.

The circular sliding groove 16 and the arc-shaped sliding block 17 are matched with each other, so that the detection table 1 can rotate on the top of the base 151 conveniently.

The top of the connecting block 18 and the bottom of the detection table 1 are fixedly installed, and a connecting rod 19 is fixedly installed on the outer side of the connecting block 18.

A third through hole 20 is formed in the right side of the inner portion of the connecting rod 19, an inserting rod 21 is arranged in the third through hole 20, and a tension spring 23 is arranged on the surface of the inserting rod 21 and located at the top of the connecting rod 19.

The clamping grooves 22 are formed in two sides of the top of the base 151.

The quantity of draw-in groove 22 is two, and draw-in groove 22 and inserted bar 21's use size looks adaptation to can make inserted bar 21 inject the inside of draw-in groove 22 and carry out mutual rigidity to its test table 1 and base 151, thereby just can make inserted bar 21 receive decurrent power that draws all the time through the elastic deformation of extension spring 23, thereby can make its inserted bar 21 can be stable insert the inside at draw-in groove 22.

when examining test table 1 and examining time measuring simultaneously carrying out most optical glass, and detect the operation for the convenience of the staff, thereby can upwards stimulate the inserted bar according to the needs of reality, atress rebound through inserted bar 21, and inserted bar 21 at this moment carries out the rebound in the inside of third through hole 20, thereby rethread inserted bar 21's rebound stretches extension spring 23, make its extension spring 23 take place elastic deformation, thereby rethread inserted bar 21's rebound makes inserted bar 21 gradual break away from in the inside of draw-in groove 22, until complete break away from can, thereby make connecting rod 19 lose with the fixed state of base 151, and then make at this moment and examine and lose between test table 1 and the base 151 by fixed state.

The detection table 1 is rotated manually, the connecting block 18 is driven to rotate through the rotation of the detection table 1 under the action of stress, the arc-shaped sliding block 17 is driven to rotate through the rotation of the connecting block 18, the arc-shaped sliding block 17 rotates inside the circular sliding groove 16, the arc-shaped sliding block 17 rotates to drive the connecting rod 19, the third through hole 20, the inserted rod 21, the tension spring 23 and other structures to rotate until the arc-shaped sliding block 17 rotates one hundred eighty degrees, the front side of the detection table 1 rotates one hundred eighty degrees to form a reverse side, the reverse side of the detection table rotates one hundred eighty degrees, the inserted rod 21 corresponds to the position of the clamping groove 22 on the other side at the moment, the inserted rod 21 is pulled upwards through loosening, the inserted rod 21 is pulled downwards through the elastic deformation of the tension spring 23, the inserted rod 21 is inserted into the third through hole 20 to move downwards, the inserted rod 21 moves downwards in the clamping groove 22 matched with the current position state, and the detection table 1 is fixed in position.

through mutually supporting between base 151, circular spout 16, arc slider 17, connecting block 18, connecting rod 19, third through hole 20, inserted bar 21, draw-in groove 22, extension spring 23 isotructure thereby can detect platform 1 and rotate it to can carry it to detect platform 1 and rotate the working direction who detects platform 1 as required when carrying out most detection achievement, thereby can be convenient for the staff reads the detection data of different positions, thereby whole practicality and variety have been improved.

The above-mentioned only be the embodiment of the present invention, not consequently the restriction of the patent scope of the present invention, all utilize the equivalent structure or equivalent flow transform made of the content of the specification and the attached drawings, or directly or indirectly use in other relevant technical fields, all including in the same way the patent protection scope of the present invention.

Claims

1. The utility model provides an optical glass thickness detection microscope carrier which characterized in that includes: a detection table;

the placing opening is formed in the detection platform;

the detection platform comprises a detection platform, a support frame and a first moving rod, wherein the support frame is fixedly arranged at the top of the detection platform, first through holes are formed in two sides of the interior of the support frame, the interior of each first through hole is provided with the first moving rod, the bottom of the first moving rod is fixedly provided with a pressing plate, and a first spring is arranged on the surface of the first moving rod and positioned at the top of the pressing plate;

2. The optical glass thickness detection stage as claimed in claim 1, wherein openings are formed in the detection stage at two sides of the placement opening.

3. The optical glass thickness detection stage as claimed in claim 1, wherein a pull rod is fixedly mounted on the top of the first moving rod.

4. The optical glass thickness detection platform according to claim 1, wherein a base is arranged at the bottom of the detection platform, a circular sliding groove is formed in the top of the base, arc-shaped sliding blocks are slidably connected to two sides of the inside of the circular sliding groove, and a connecting block is fixedly mounted on the top of each arc-shaped sliding block.

5. The optical glass thickness detection stage as claimed in claim 4, wherein the top of the connecting block is fixedly mounted with the bottom of the detection stage, and the outer side of the connecting block is fixedly mounted with a connecting rod.

6. The optical glass thickness detection stage as claimed in claim 5, wherein a third through hole is formed in the right side of the inside of the connecting rod, and an inserting rod is arranged inside the third through hole.

7. The optical glass thickness detection stage as claimed in claim 6, wherein a tension spring is disposed on the surface of the insertion rod and on the top of the connection rod.

8. The optical glass thickness detection carrier as claimed in claim 6, wherein both sides of the top of the base are provided with a slot.