CN220683125U - Microorganism detection box - Google Patents

Abstract

The utility model discloses a microorganism detection kit, which relates to the field of microorganism detection kits. According to the utility model, through the arrangement of the torsion spring, the shell, the clamping plate, the supporting plate and the test tube rack, a worker pulls the handle, the closed door cover is propped open through the device main body, then the worker continuously pulls the shell downwards through the handle to be placed on the ground, then the worker takes out the detection reagent from the hole groove, after the worker finishes detecting and collecting microorganisms, the worker finally pulls the handle to move the shell upwards, and the limiting plate can limit the movement of the shell, so that the detection reagent can be prevented from being damaged as much as possible in the process of taking the detection reagent.

Description

Microorganism detection box

Technical Field

The utility model relates to the field of microorganism detection kits, in particular to a microorganism detection kit.

Background

The microorganism refers to bacteria, viruses, fungi and other small protozoa, microalgae and the like, the detection kit is used for storing the rapid detection reagent, namely the detection reagent filled with the relevant reagent, and the detection reagent storage racks are arranged in the conventional rapid detection kit for the microorganism, so that a plurality of detection reagents with the reagents are placed in the conventional rapid detection kit for storage and transportation.

The utility model provides a microorganism detection box body that current application number is 202121897664.4, including the kit, the top one side of kit rotates there is the lid, the through-hole has been seted up at the top of kit, the surface that is located the inside through-hole of kit rotates there is the sleeve, the inner wall slip of through-hole has the backing plate, the below of backing plate is equipped with and contracts the spring, the both sides of backing plate are fixed with the fixture block, telescopic bottom inner wall is equipped with the supporting shoe with fixture block looks adaptation, the one end and the bottom fixed connection of backing plate of contracting spring, the other end and the inner wall fixed connection of through-hole of contracting spring, the upper surface of backing plate is flutedly, the recess is the arcuation, though this technical scheme is convenient for the staff through going up and down takes out detect reagent, but the reaction force of spring is difficult to control, the following phenomenon probably can appear when leading to the spring to pop out detect reagent, firstly, the spring is direct flies to cause the loss with detect reagent bullet, secondly, spring aftershock makes probably appear between backing plate and the detect reagent and the bottom is impaired.

Disclosure of Invention

Based on the above, the utility model aims to provide a microorganism detection box so as to solve the technical problem that detection reagents are easy to damage in the using process.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a microorganism detection box, includes the device main part, device main part external surface is connected with the shell, the shell bottom is provided with the limiting plate, shell external surface is connected with the handle, the shell top is connected with the door closure, be connected with first torsional spring between shell and the door closure, device main part internal connection has splint, be connected with the second torsional spring between splint and the device main part, the inside both sides of device main part are fixed with the backup pad, device main part is inside and the backup pad top all are connected with the test-tube rack, the hole groove has been seted up at the test-tube rack top, hole inslot wall is provided with the rubber pad.

Through adopting above-mentioned technical scheme, staff at first pulls down the handle that the shell surface is connected, roof the closed door closure through the device main part and open, then the staff continues to pull down the shell through the handle and place in ground, afterwards, staff takes out the test tube rack with detection reagent from among the hole groove of test tube rack, this step reduces the risk of being damaged when making detection reagent take out, wait that the staff detects the microorganism and collect after again putting into the hole groove with detection reagent, after the detection reagent of a row uses up, at this moment, staff can take out the test tube rack of backup pad top through rotatory splint, thereby can take out unused detection reagent in another test tube rack, take out the test tube rack that will take out again after the detection reagent, then rotatory splint, make splint and backup pad hold the test tube rack, wait to detect the work, the staff rotates splint again and takes out the test tube rack again, then put into another test tube rack in detection reagent, afterwards put down the backup pad top again, hold the test tube rack through splint, pull the handle again and put into the hole groove, after waiting for the microorganism detection reagent to collect, after the time, a row of detection reagent uses, the time can restrict the test tube rack to move up, at the time can limit the door closure can continue to remove the detection reagent through rotatory power that can be removed in the first torsion spring to the detection reagent of the process as far as possible.

Further, the device main part internally connected has the foam pad, inside detect reagent of having placed of test-tube rack.

By adopting the technical scheme, the foam pad can protect the detection reagent from being knocked down in the shaking process of the detection box, and the detection reagent is placed in the test tube rack.

Further, one test tube rack is fixedly connected with the device main body, and the other test tube rack is detachably connected with the supporting plate.

By adopting the technical scheme, after the detection reagent in the other test tube rack is used, the other test tube rack can be taken out, and then the detection reagent in the test tube rack is taken out for use.

Further, the clamping plate is rotatably connected with the device main body, and the clamping plate is abutted with the other test tube rack.

Through adopting above-mentioned technical scheme, be connected with the second torsional spring between splint and the device main part to can reach rotatory splint and grasp the test-tube rack.

Further, sixteen hole grooves are formed, eight hole grooves are formed in one group and divided into two groups, and the two groups of hole grooves are respectively formed in the tops of the two test tube racks.

By adopting the technical scheme, the detection reagent can be placed in the hole groove, and the detection reagent can be taken out from the other test tube rack to continue working after one row of detection reagent is used up.

Further, the limiting plate is movably connected with the device main body.

Through adopting above-mentioned technical scheme, the limiting plate can restrict the shell and continue upward movement in the removal process, plays a spacing effect.

Further, two door covers are arranged and are both connected with the shell in a rotating mode.

Through adopting above-mentioned technical scheme, when the shell moves down, thereby the door closure at shell top is opened the detection box by the device main part jack-up, and when the shell moved up, the door closure was closed through the rotation force of first torsional spring.

In summary, the utility model has the following advantages:

according to the utility model, through the arrangement of the torsion spring, the shell, the clamping plate, the supporting plate and the test tube rack, firstly, a worker pulls down the handle connected with the outer surface of the shell, the closed door cover is propped up through the device main body, then, the worker continues to pull down the shell through the handle and place the shell on the ground, then, the worker takes out the detection reagent from the hole slot of the test tube rack, the risk of damage is reduced when the detection reagent is taken out, after the detection reagent is used up, the worker can take out the test tube rack above the supporting plate through the rotating clamping plate, so that the unused detection reagent can be taken out from the other test tube rack, the taken out test tube rack is put back to the top of the supporting plate, then the clamping plate is rotated, the clamping plate and the supporting plate clamp the test tube rack, after the detection work is finished, the worker pulls the handle to move the shell upwards, the limiting plate can limit the shell to move upwards continuously, and the door cover can be closed through the rotating force of the first torsion spring, and the detection reagent can be prevented from being damaged in the process of taking out the detection reagent.

Drawings

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

FIG. 2 is a schematic cross-sectional view of a device body according to the present utility model;

FIG. 3 is a schematic view of a door cover according to the present utility model;

fig. 4 is a schematic diagram of a test tube rack structure according to the present utility model;

FIG. 5 is a schematic view of the torsion spring structure of the present utility model.

In the figure: 1. a device body; 2. a housing; 3. a handle; 4. a first torsion spring; 5. a door cover; 6. a clamping plate; 7. a second torsion spring; 8. a test tube rack; 9. a support plate; 10. a foam pad; 11. a hole groove; 12. a rubber pad; 13. a detection reagent; 14. and a limiting plate.

Detailed Description

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. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the utility model.

Hereinafter, an embodiment of the present utility model will be described in accordance with its entire structure.

1-5, including device main part 1, device main part 1 external surface is connected with shell 2, shell 2 bottom is provided with limiting plate 14, limiting plate 14 can play base and spacing effect, shell 2 external surface is connected with handle 3, shell 2 top is connected with door closure 5, be connected with first torsional spring 4 between shell 2 and the door closure 5, can make door closure 5 play the effect of closing the detection box through the rotation force closure of first torsional spring 4, device main part 1 internal connection has splint 6, be connected with second torsional spring 7 between splint 6 and the device main part 1, thereby can make splint 6 rotatory centre gripping test-tube rack 8 through the rotation force of second torsional spring 7, device main part 1 inside both sides are fixed with backup pad 9, device main part 1 inside and backup pad 9 top all are connected with test-tube rack 8, hole groove 11 has been seted up at test-tube rack 8 top, the inner wall of hole groove 11 is provided with rubber pad 12, rubber pad 12 can increase friction force makes detection reagent 13 be difficult for droing and avoid detection reagent 13 and pipe rack 8 direct touching.

Referring to fig. 1-4, in the above embodiment, the device main body 1 is internally connected with the foam pad 10, the test tube rack 8 is internally provided with the test reagent 13, the foam pad 10 can protect the test reagent 13 from being broken in the shaking process of the test box, the test reagent 13 is placed in the test tube rack 8, one test tube rack 8 is fixedly connected with the device main body 1, the other test tube rack 8 is detachably connected with the support plate 9, after the test reagent 13 in the other test tube rack 8 is used up, the other test tube rack 8 can be taken out, then the test reagent 13 in the test tube rack 8 is taken out for use, the clamping plate 6 is rotationally connected with the device main body 1, the clamping plate 6 is abutted against the other test tube rack 8, and thus, the second torsion spring 7 is connected between the clamping plate 6 and the device main body 1, the test tube rack 8 can be clamped by the rotating clamping plate 6, sixteen holes 11 are formed, eight holes are divided into two groups, the two groups of holes 11 are respectively formed in the tops of the two groups, the test reagent 13 can be placed in the holes 11, and after one row of test reagent 13 is used up, the test reagent 13 can be taken out from the other test tube rack 8 continuously.

Referring to fig. 1, 2, 3 and 5, in the above embodiment, the limiting plate 14 is movably connected with the device main body 1, the limiting plate 14 can limit the housing 2 to move upwards continuously in the moving process, two door covers 5 are provided to play a limiting role, and the two door covers 5 are both connected with the housing 2 in a rotating manner, when the housing 2 moves downwards, the door cover 5 at the top of the housing 2 is pushed open by the device main body 1 to open the detection box, and when the housing 2 moves upwards, the door cover 5 is closed by the rotating force of the first torsion spring 4.

The implementation principle of the embodiment is as follows: firstly, the staff pulls down the handle 3 connected with the outer surface of the shell 2, the closed door cover 5 is propped open through the device main body 1, then the staff continues to pull down the shell 2 to be placed on the ground through the handle 3, then the staff pulls out the detection reagent 13 from the hole groove 11 of the test tube rack 8, the step reduces the damage risk when the detection reagent 13 is taken out, after a row of detection reagents 13 are used, the staff can take out the test tube rack 8 above the supporting plate 9 through the rotating clamping plate 6, so that the unused detection reagent 13 can be taken out from the other test tube rack 8, the taken test tube rack 8 is put back to the top of the supporting plate 9 after the detection reagent 13 is taken out, then the clamping plate 6 clamps the test tube rack 8 with the supporting plate 9, after the detection work is finished, the staff pulls the handle 3 to move the shell upwards, the limiting plate 14 can limit the shell 2 to move upwards continuously in the moving process, and the door cover 5 can be closed through the rotating force of the first torsion spring 4.

Although embodiments of the utility model have been shown and described, the detailed description is to be construed as exemplary only and is not limiting of the utility model as the particular features, structures, materials, or characteristics may be combined in any suitable manner in any one or more embodiments or examples, and modifications, substitutions, variations, etc. may be made in the embodiments as desired by those skilled in the art without departing from the principles and spirit of the utility model, provided that such modifications are within the scope of the appended claims.

Claims (7)

1. A microorganism detection cartridge comprising a device body (1), characterized in that: the device comprises a device body (1), wherein an outer surface of the device body (1) is connected with a shell (2), a limiting plate (14) is arranged at the bottom of the shell (2), a handle (3) is connected to the outer surface of the shell (2), a door cover (5) is connected to the top of the shell (2), a first torsion spring (4) is connected between the shell (2) and the door cover (5), a clamping plate (6) is connected to the inner side of the device body (1), a second torsion spring (7) is connected between the clamping plate (6) and the device body (1), supporting plates (9) are fixed to the two sides of the inner side of the device body (1), test tube racks (8) are connected to the inner side of the device body (1) and the top of the supporting plates (9), a hole groove (11) is formed in the top of the test tube racks (8), and rubber pads (12) are arranged on the inner wall of the hole groove (11).

2. A microbiological detection cartridge according to claim 1 wherein: the device is characterized in that the device body (1) is internally connected with a foam pad (10), and a detection reagent (13) is placed in the test tube rack (8).

3. A microbiological detection cartridge according to claim 1 wherein: one test tube rack (8) is fixedly connected with the device main body (1), and the other test tube rack (8) is detachably connected with the supporting plate (9).

4. A microbiological detection cartridge according to claim 3 wherein: the clamping plate (6) is rotationally connected with the device main body (1), and the clamping plate (6) is abutted with the other test tube rack (8).

5. A microbiological detection cartridge according to claim 1 wherein: sixteen hole grooves (11) are formed, eight holes are formed in one group and divided into two groups, and the two groups of hole grooves (11) are respectively formed in the tops of the two test tube racks (8).

6. A microbiological detection cartridge according to claim 1 wherein: the limiting plate (14) is movably connected with the device main body (1).

7. A microbiological detection cartridge according to claim 1 wherein: the two door covers (5) are arranged, and the two door covers (5) are both connected with the shell (2) in a rotating way.