CN217365062U - Diatom electron microscope sample access arrangement - Google Patents

Abstract

The utility model discloses a diatom electron microscope detection sample access device, wherein a plurality of first two-dimensional code areas for marking the positions of storage boxes are arranged on the side surface of a storage cabinet, and the positions of the first two-dimensional code areas correspond to the grid positions along the moving direction of a drawer one by one; the sample outer box is coated with a layer of sealing outer film; the top surface of the sample base is provided with a layer of carbon conductive film for sticking a diatom electron microscope detection sample, and the carbon conductive film is covered with anti-pollution adhesive paper; a second two-dimensional code area for marking the position of the inner box is arranged on the outer end face of each inner box cover; the double box body is combined with the sealed outer film and the anti-pollution adhesive paper, and multiple anti-pollution measures are taken, so that the diatom electron microscope sample is well prevented from being polluted in the storage and use processes; the first two-dimensional code is associated with the second two-dimensional code and corresponds to a diatom electron microscope detection sample data management system, so that a target sample and related information can be found quickly and accurately when case evidence is reviewed.

Description

Diatom electron microscope sample access arrangement that detects

Technical Field

The utility model relates to a diatom electron microscope detection facility field especially relates to a diatom electron microscope test sample access arrangement.

Background

At present, the diatom inspection technology combining microwave digestion, vacuum filtration and scanning electron microscope has the advantages of accuracy, high efficiency, sensitivity and the like, and has high application value in the fields of forensic diatom science, diatom ecology, diatom taxonomy and the like.

However, in the process of applying the technology, the existing diatom electron microscope sample storage facility has the following problems:

on one hand, because the diatom inspection technology is very sensitive, if the sample is slightly polluted, a false positive result appears, and the existing diatom electron microscope sample storage facility has insufficient anti-pollution measures, so that the sample is very easy to be polluted;

on the other hand, the existing storage facilities for the diatom electron microscope sample lack electronic information identification, and the sample is difficult to be effectively managed, so that the target sample and related information are difficult to be quickly and accurately found out when the subsequent case evidence is subjected to reexamination.

Therefore, the existing diatom electron microscope sample storage facilities need to be improved.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a diatom electron microscope detects sample access arrangement to solve the technical problem who proposes in the above-mentioned background art, how to prevent promptly that diatom electron microscope sample is depositing the in-process very easily by polluting, can ensure to find target sample and relevant information fast, accurately again simultaneously.

The technical scheme of the utility model as follows: a diatom electron microscope detection sample storing and taking device comprises a storage cabinet provided with a plurality of layers of drawer holes, wherein a drawer with a handle is arranged in each layer of drawer hole, and the interior of each drawer is divided into a plurality of lattices through a grating plate;

a plurality of first two-dimensional code areas used for marking the positions of the diatom electron microscope detection samples are arranged on the side face of the storage cabinet, and the positions of the first two-dimensional code areas correspond to the positions of grids along the moving direction of the drawer one by one;

each storage box comprises an outer box and a plurality of inner boxes; the outer box consists of an outer box body, an outer box cover and an inner box bracket; the inner box bracket is arranged in the outer box body and used for positioning a plurality of inner boxes at intervals; the outer box cover is used for being buckled at the opening part of the outer box body, and a layer of sealing outer thin film is coated outside the whole outer box;

each inner box consists of an inner box body, an inner box cover and an inserting hole seat; the jack seat is positioned in the inner box body and is vertically connected to the inner bottom surface of the inner box body; the inner box cover is used for buckling the opening part of the inner box body;

the sample base is connected to the jack seat, and the center of the bottom surface of the sample base is integrally connected with an inserting column which can be inserted into the jack seat in a matching manner and is used for fixing the sample base above the jack seat; the top surface of the sample base is provided with a layer of carbon conductive film for sticking a diatom electron microscope detection sample, and the carbon conductive film is covered with anti-pollution adhesive paper;

be used for placing an interior box in every check, all be provided with a second two-dimensional code district that is used for sign diatom electron microscope detection sample position on the outer terminal surface of every interior lid, and the information correlation in second two-dimensional code district and first two-dimensional code district.

Diatom electron microscope detect sample access arrangement, wherein: the part of the outer box cover is hinged at the edge of the opening part of the outer box body to form an integrally connected flip structure.

Diatom electron microscope detect sample access arrangement, wherein: the outer box is of a square cubic structure.

Diatom electron microscope detect sample access arrangement, wherein: the outer box body, the outer box cover and the inner box support are all made of transparent plastics.

Diatom electron microscope detect sample access arrangement, wherein: the part of the inner box cover is hinged at the edge of the opening part of the inner box body to form an integrally connected flip structure.

Diatom electron microscope detect sample access arrangement, wherein: the bottom of the jack seat and the inner box body form an integrally connected structure.

Diatom electron microscope detect sample access arrangement, wherein: the inner box is in a circular cylinder structure.

Diatom electron microscope detect sample access arrangement, wherein: the inner box body, the inner box cover and the jack seat are all made of transparent plastics.

Diatom electron microscope detect sample access arrangement, wherein: the number of rows inside a single drawer is the same as the number of inner boxes in a single storage box.

Diatom electron microscope detect sample access arrangement, wherein: the storage cabinet is provided with 5 layers of drawer holes; the interior of a single drawer is divided into 4 rows and 6 columns of square lattices by a grating plate; 2 rows and 3 columns of cylindrical inner boxes are arranged in a single square storage box.

Compare with the facility of depositing of current diatom electron microscope sample, the utility model discloses diatom electron microscope detects sample access arrangement's beneficial effect is:

1) the double box body is combined with the sealed outer film and the anti-pollution adhesive paper, and multiple anti-pollution measures are taken, so that the diatom electron microscope sample is well prevented from being polluted in the storage and use processes;

2) the first two-dimensional code on the side face of the storage cabinet is associated with the second two-dimensional code on the inner box cover and corresponds to the diatom electron microscope detection sample data management system, and therefore the target sample and related information can be found quickly and accurately when the case physical evidence is rechecked.

Drawings

The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way; the shapes, the proportional sizes and the like of the various components in the drawings are only schematic and are used for helping the understanding of the invention, and the shapes, the proportional sizes and the like of the various components of the invention are not particularly limited; the skilled person in the art can, under the teaching of the present invention, choose various possible shapes and proportional dimensions to implement the invention according to the specific situation.

FIG. 1 is a right side schematic view of a storage cabinet for a diatom electron microscope detection sample storing and taking device of the present invention;

FIG. 2 is an enlarged schematic view of the top view structure of the drawer used in the device for storing and taking samples for diatom electron microscope detection of the present invention;

FIG. 3 is an enlarged schematic view of the top view of the storage box of the device for storing and taking samples for diatom electron microscopy;

FIG. 4 is an enlarged schematic view of the front view structure of the storage box of the device for storing and taking samples for diatom electron microscope detection of the present invention;

the various reference numbers in the figures are summarized: the storage cabinet 100, the first two-dimensional code area 110, the drawer 200, the handle 210, the grid plate 220, the grid 230, the storage box 300, the outer box 310, the outer box 311, the outer box cover 312, the inner box support 313, the sealed outer film 314, the inner box 320, the inner box 321, the inner box cover 322, the jack seat 323, the sample base 324, the plug column 325, the carbon conductive film 326, the anti-pollution adhesive paper 327, and the second two-dimensional code area 328.

Detailed Description

The following detailed description and examples of the present invention are provided in connection with the accompanying drawings, which are set forth for the purpose of illustration only and are not intended to limit the invention.

Referring to fig. 1 in combination with fig. 2, fig. 3 and fig. 4, the device for storing and taking samples for diatom electron microscopy according to the present invention includes a storage cabinet 100, a drawer 200 and a storage box 300; the storage cabinet 100 is provided with a plurality of layers of drawer holes from top to bottom, and a drawer 200 with a handle 210 can be placed in each layer of drawer holes; the interior of each drawer 200 is divided into a plurality of rows and columns of compartments 230 by a grill plate 220.

The side surfaces of the storage cabinets 100 are provided with a plurality of first two-dimensional code areas 110 in an arrangement manner, and the first two-dimensional code areas are used for adhering or spraying corresponding first two-dimensional codes so as to identify the positions of the diatom electron microscope detection samples in an electronic information manner, namely, the diatom electron microscope detection samples of a certain case are arranged on the layer number and the row number of the storage cabinet 100, and the positions of the first two-dimensional code areas 110 correspond to the positions of the grids 230 in the moving direction of the drawer 200 in a one-to-one manner.

Each of the storage cases 300 includes an outer (sample) case 310 and a plurality of inner (sample) cases 320; wherein, the outer box 310 is composed of an outer box body 311, an outer box cover 312 and an inner box support 313; the inner box bracket 313 is arranged in the outer box body 311 and is used for positioning a plurality of inner boxes 320 at intervals; the outer case cover 312 is fastened to the opening of the outer case body 311 to seal the inner space of the outer case body 311; and is covered with a sealing outer film 314 over the entire outer casing 310.

Each inner box 320 consists of an inner box body 321, an inner box cover 322 and a jack seat 323; the jack seat 323 is positioned inside the inner box body 321, and the jack seat 323 is vertically connected to the inner bottom surface of the inner box body 321; the inner case cover 322 is adapted to be fastened to the mouth of the inner case 321 to seal the inner space of the inner case 321.

The jack seat 323 is also connected with a sample base 324, and the center of the bottom surface of the sample base 324 is integrally connected with a jack column 325 which can be inserted into the jack seat 324 in a matching way and is used for fixing the sample base 324 above the jack seat 323; the top surface of the sample base 324 is provided with a layer of carbon conductive film 326 for adhering a diatom electron microscope detection sample, and the carbon conductive film 326 is covered with an anti-pollution adhesive paper 327.

Each grid 230 is used for placing an inner box 320, and the outer end face of each inner box cover 322 is provided with a second two-dimensional code area 328 for adhering or spraying a corresponding second two-dimensional code so as to mark the position of the diatom electron microscope detection sample in an electronic information mode, namely, the diatom electron microscope detection sample of a certain case is arranged in the row and the column of the drawer 200; and the second two-dimensional code of the second two-dimensional code area 328 is correlated with the first two-dimensional code of the first two-dimensional code area 110.

Preferably, a part of the outer box cover 312 is hinged to the edge of the mouth of the outer box 311 to form an integrally connected flip structure, so as to reduce the production cost and prevent the outer box 311 from covering the outer box cover 312 incorrectly.

Preferably, the outer casing 310 has a square cubic structure, and a relatively simple grid plate 220 can be used to divide the interior of the drawer 200 into a plurality of rows and a plurality of columns of square lattices 230, so as to reduce the production cost.

Preferably, the outer case 311, the outer case cover 312 and the inner case holder 313 are made of transparent plastics, so that the user can clearly see the inner case 320 contained inside the outer case 310.

Preferably, the inner box cover 322 is partially hinged to the edge of the opening of the inner box body 321 to form an integrally connected flip structure, so as to reduce the production cost and facilitate the one-handed operation of the user.

Preferably, the inner case 320 has a circular column structure to reduce the production cost and facilitate the taking and placing.

Preferably, the inner box body 321, the inner box cover 322 and the jack seat 323 are all made of transparent plastics, so as to facilitate the inspection of the diatom electron microscope to detect whether the sample is contaminated.

Specifically, the number of rows of compartments 230 within a single drawer 200 is the same as the number of inner boxes 320 within a single storage compartment 300, and with one inner box 320 per compartment 230, to ensure that all inner boxes 320 within a single storage compartment 300 are able to fill all compartments 230 within the same row of drawers 200.

In the embodiment of the device for storing and taking samples for diatom electron microscope detection of the present invention, the storage cabinet 100 is provided with 5 layers of drawer holes; the interior of a single drawer 200 is divided into 4 rows and 6 columns of square lattices 230 via a grid plate 220; the single square-shaped storage box 300 is placed with 2 rows and 3 columns of cylindrical inner boxes 320 therein.

The utility model discloses diatom electron microscope detects sample access arrangement's preparation, use and the process of reexamining are:

all of the components of the storage case 300 are fabricated and assembled in a clean room environment, including: firstly, adhering a black high-purity carbon conductive film 326 to the top surface of the sample base 324, and covering an anti-pollution adhesive paper 327 on the carbon conductive film 326; then the inserting column 325 of the sample base 324 is inserted into the inserting hole seat 323 of the inner box body 321, and the inner box cover 322 is buckled; then, putting a plurality of inner boxes 320 into the same outer box body 311, and buckling the outer box cover 312; finally, the whole outer box 310 is completely covered by a layer of sealing outer film 314 in a vacuum environment to form the storage box 300.

When the storage box 300 is used for the first time, the sealed outer film 314 of the storage box 300 is firstly torn off in a clean environment, the outer box cover 312 is opened, and one inner box 320 is taken out; then the inner box cover 322 of the inner box 320 is opened, the sample base 324 is pulled out from the jack seat 323 of the inner box body 321 by using tweezers, the anti-pollution adhesive paper 327 is torn off by using the tweezers, and the diatom electron microscope detection sample of the current case is adhered to the carbon conductive film 326; then, the sample base 324 is inserted back into the socket 323 of the inner box 321, and the inner box cover 322 is quickly buckled; then, a second two-dimensional code related to the current case is sprayed or attached to a second two-dimensional code area 328 of the inner box cover 322, and the second two-dimensional code can be generated by a diatom electron microscope detection sample data management system; thus, the operation of all the inner cases 320 in the outer case 311 is completed; finally, all the inner boxes 320 in the same outer box 311 are placed in the grid 230 of the same row of the drawer 200, and the first two-dimensional code related to the current case is sprayed or pasted on the first two-dimensional code area 110 on the side of the storage cabinet 100 corresponding to the grid 230 of the same row of the drawer 200, and the first two-dimensional code can be generated by a diatom electron microscope detection sample data management system.

When case evidence needs to be reviewed subsequently, the first two-dimensional code and the second two-dimensional code related to the current case can be called out from the diatom electron microscope detection sample data management system, so that the specific position and related information of the stored target sample can be easily determined, including information such as the number of the current case, the type and name of the diatom electron microscope sample, the processing process, the detection result, the storage position, the name of a detector, the detection time and the like, and therefore the target sample can be quickly and accurately found from a large number of sample storage cabinets 100 and can be taken out for review in a clean environment.

Those not described in detail in this specification are well within the skill of those in the art.

It should be understood that the above description is only a preferred embodiment of the present invention, and should not be construed as limiting the technical scope of the present invention, and that the person skilled in the art can add, subtract, replace, change or modify the above description within the spirit and principle of the present invention, and all the technical solutions of the add, subtract, change or modify should belong to the protection scope of the appended claims.

Claims (10)

1. The utility model provides a diatom electron microscope detects sample access arrangement, is provided with a drawer that has the handle, its characterized in that including the storing compartment that is provided with multilayer drawer hole in every layer of drawer hole: the interior of each drawer is divided into a plurality of lattices by a grating plate;

a plurality of first two-dimensional code areas used for marking the positions of the diatomite electron microscope detection samples are arranged on the side surface of the storage cabinet, and the positions of the first two-dimensional code areas correspond to the positions of grids along the moving direction of the drawer one by one;

each storage box comprises an outer box and a plurality of inner boxes; the outer box consists of an outer box body, an outer box cover and an inner box bracket; the inner box bracket is arranged in the outer box body and used for positioning a plurality of inner boxes at intervals; the outer box cover is used for being buckled at the opening part of the outer box body, and a layer of sealing outer thin film is coated outside the whole outer box;

each inner box consists of an inner box body, an inner box cover and an inserting hole seat; the jack seat is positioned in the inner box body and is vertically connected to the inner bottom surface of the inner box body; the inner box cover is used for buckling the opening part of the inner box body;

the sample base is connected to the jack seat, and the center of the bottom surface of the sample base is integrally connected with an inserting column which can be inserted into the jack seat in a matching manner and is used for fixing the sample base above the jack seat; the top surface of the sample base is provided with a layer of carbon conductive film for sticking a diatom electron microscope detection sample, and the carbon conductive film is covered with anti-pollution adhesive paper;

be used for placing an interior box in every check, all be provided with a second two-dimensional code district that is used for sign diatom electron microscope detection sample position on the outer terminal surface of every interior lid, and the information correlation in second two-dimensional code district and first two-dimensional code district.

2. The diatom electron microscope detection sample access device of claim 1, wherein: the part of the outer box cover is hinged at the edge of the opening part of the outer box body to form an integrally connected flip structure.

3. The diatom electron microscope detection sample access device of claim 1, wherein: the outer box is of a square cubic structure.

4. The diatom electron microscope detection sample access device of claim 1, wherein: the outer box body, the outer box cover and the inner box support are all made of transparent plastics.

5. The diatom electron microscope detection sample access device of claim 1, wherein: the part of the inner box cover is hinged at the edge of the opening part of the inner box body to form an integrally connected flip structure.

6. The diatom electron microscope detection sample access device of claim 1, wherein: the bottom of the jack seat and the inner box body form an integrally connected structure.

7. The device for accessing samples for diatom electron microscope detection according to claim 1, wherein: the inner box is in a circular cylinder structure.

8. The device for accessing samples for diatom electron microscope detection according to claim 1, wherein: the inner box body, the inner box cover and the jack seat are all made of transparent plastics.

9. The diatom electron microscope detection sample access device of claim 1, wherein: the number of rows inside a single drawer is the same as the number of inner boxes in a single storage box.

10. The device for accessing samples for diatomite electronic microscope detection according to any one of claims 1 to 9, wherein: the storage cabinet is provided with 5 layers of drawer holes; the interior of a single drawer is divided into 4 rows and 6 columns of square lattices by a grating plate; 2 rows and 3 columns of cylindrical inner boxes are arranged in the single square storage box.

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