CN215953645U - Cold-stored module of full-automatic blood coagulation analysis appearance reagent - Google Patents

Abstract

The utility model provides a reagent refrigeration module of a full-automatic coagulation analyzer, which is convenient to operate and safe to operate. The utility model provides a cold-stored module of full-automatic blood coagulation analysis appearance reagent, includes case, storage rack and the cooling part that top-down set gradually, the storage box surface is equipped with a plurality of storage chambers that are used for holding reagent pipe, the storage chamber wall sets up with the storage box surface is contained angle slope, be equipped with position sensor between storage box and the storage rack, the cooling part is located the storage rack lower part and is met bottom the storage box. According to the utility model, the storage cavity is obliquely arranged at an included angle with the surface of the storage box, so that the reagent tube in the storage cavity is obliquely arranged, and the residual amount of the reagent in the reagent tube can be reduced relative to the horizontally arranged reagent tube; through sliding connection's case and storage rack, form pull formula structure, for prior art's fixed structure, can make things convenient for operating personnel to remove and take the reagent pipe.

Description

Cold-stored module of full-automatic blood coagulation analysis appearance reagent

Technical Field

The utility model relates to a working module of a full-automatic coagulation analyzer, in particular to a reagent refrigeration module of the full-automatic coagulation analyzer.

Background

The blood coagulation analyzer is used for analyzing the functions of blood coagulation and anticoagulation, fibrinolysis and anti-fibrinolysis of the blood of a patient. The fully automatic coagulation analyzer stores reagents through a reagent refrigeration module so that a sample and the reagents are added to a detection module for mixed detection during operation.

Among the prior art, the structure of reagent refrigeration module is comparatively simple, does not consider how convenient reagent of taking when the design to and how prevent after taking the reagent and the full-automatic blood coagulation analysis appearance start the equipment operation trouble that the operation caused when reagent does not playback.

In summary, the design of the reagent refrigeration module in prior art coagulation analyzer products does not adequately address the above-mentioned problems and risks, which is detrimental to ease of operation and safety of use.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a reagent refrigeration module of a full-automatic coagulation analyzer, which is convenient to operate and safe to operate, and solves the problems in the background technology.

The technical scheme adopted by the utility model for solving the technical problems is as follows:

the utility model provides a cold-stored module of full-automatic blood coagulation analysis appearance reagent, includes case, storage rack and the cooling part that top-down set gradually, the storage box surface is equipped with a plurality of storage chambers that are used for holding reagent pipe, the storage chamber wall sets up with the storage box surface is contained angle slope, be equipped with position sensor between storage box and the storage rack, the cooling part is located the storage rack lower part and is met bottom the storage box.

Preferably, the bottom of the storage box is connected with the surface of the storage rack in a sliding mode.

Preferably, the storage box is provided with a handle at a side portion thereof.

Preferably, the bottom of each storage cavity is provided with an upper drainage groove, the upper drainage grooves of adjacent storage cavities are communicated, and the bottom of at least one storage cavity is also provided with a drainage hole which is a through hole.

Preferably, the storage cavity comprises a large reagent tube storage cavity and a small reagent tube storage cavity, and the volume ratio of the large reagent tube storage cavity to the small reagent tube storage cavity is 1.5-3: 1.

preferably, the surface of the storage rack is provided with a sliding groove which is used for accommodating the bottom of the storage box and slides relative to the bottom of the storage box.

Preferably, the surface of the storage rack is provided with a lower drainage groove, and the lower drainage groove is communicated with the bottom of the storage cavity.

Preferably, the cooling component comprises a refrigeration piece, and the refrigeration piece is arranged at the lower part of the storage rack and connected with the bottom of the storage box.

Preferably, the cooling component further comprises a cooling fin, and the cooling fin is arranged at the bottom of the refrigerating fin.

Preferably, the cooling member further includes a fan provided at a bottom of the heat sink.

The utility model has the beneficial effects that:

(1) according to the utility model, the storage cavity is obliquely arranged at an included angle with the surface of the storage box, so that the reagent tube in the storage cavity is obliquely arranged, and the residual amount of the reagent in the reagent tube can be reduced relative to the horizontally arranged reagent tube;

(2) according to the utility model, the drawing structure is formed by the storage box and the storage rack which are connected in a sliding manner, and compared with the fixed structure in the prior art, the reagent tube drawing structure is convenient for operators to move and take reagent tubes;

(3) according to the utility model, through the position sensor between the storage box and the storage rack, the situation that the full-automatic coagulation analyzer is signaled to operate and work after the storage box moves in place is ensured, and the use safety of equipment is ensured;

(4) according to the utility model, accumulated water generated by cooling of the reagent tube at the bottom of the storage cavity is discharged in time through the upper water discharge groove at the bottom of the storage cavity and the lower water discharge groove on the surface of the storage rack, so that the cold storage effect of the reagent is ensured.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic view showing an inner structure of the storage case of the present invention;

FIG. 3 is a perspective view of the storage case of the present invention;

fig. 4 is a schematic top view of the present invention.

In the figure: 1. the reagent box comprises a storage box, 2, a storage rack, 3, a cooling component, 4, a reagent tube, 5, a storage cavity, 6, a position sensor, 7, a handle, 201, a sliding groove, 202, a lower water drainage groove, 301, a refrigerating sheet, 302, a radiating fin, 303, a fan, 501, an upper water drainage groove, 502, a water drainage hole, 503, a large reagent tube storage cavity, 504 and a small reagent tube storage cavity.

Detailed Description

The technical solution of the present invention is further specifically described below by way of specific examples in conjunction with the accompanying drawings. It is to be understood that the practice of the utility model is not limited to the following examples, and that any variations and/or modifications may be made thereto without departing from the scope of the utility model.

In the present invention, all parts and percentages are by weight, unless otherwise specified, and the equipment and materials used are commercially available or commonly used in the art. The methods in the following examples are conventional in the art unless otherwise specified. The components or devices in the following examples are, unless otherwise specified, standard parts or parts known to those skilled in the art, the structure and principle of which are known to those skilled in the art through technical manuals or through routine experimentation.

Example 1:

fig. 1 shows a reagent refrigeration module of a fully automatic coagulation analyzer, which comprises a storage box 1, a storage rack 2 and a cooling component 3 arranged in sequence from top to bottom.

The surface of the storage box 1 is provided with 14 storage cavities 5 for containing the reagent tubes 4, and as shown in fig. 2, the wall surface of each storage cavity 5 is obliquely arranged at an included angle with the surface of the storage box 1.

As shown in fig. 3, a position sensor 6 is provided between the storage box 1 and the storage rack 2. The position sensor 6 can be a photoelectric position sensor or an inductive position sensor, the photoelectric position sensor is selected in the embodiment and is arranged on the storage rack 2 and is arranged opposite to the back surface of the storage box 1, when the storage box 1 leaves the storage rack 2, the photoelectric position sensor transmits a corresponding electric signal to a control part of the full-automatic coagulation analyzer, the full-automatic coagulation analyzer stops working, only when the relative distance between the back surface of the storage box 1 and the storage rack 2 is a preset position, the photoelectric position sensor transmits a corresponding electric signal to the control part of the full-automatic coagulation analyzer, and the full-automatic coagulation analyzer can start working.

The cooling member 3 is provided at the lower portion of the storage rack 2 and is connected to the bottom of the storage box 1.

By the technical scheme, the reagent tube in the storage cavity is obliquely arranged, so that the residual amount of the reagent in the reagent tube can be reduced relative to the horizontally-arranged reagent tube; in addition, the position sensor between the storage box and the storage rack guarantees that the storage box can not only send a signal to the full-automatic coagulation analyzer to operate and work after moving in place, and the use safety of the equipment is guaranteed.

Example 2:

fig. 1 shows a reagent refrigeration module of a fully automatic coagulation analyzer, which comprises a storage box 1, a storage rack 2 and a cooling component 3 arranged in sequence from top to bottom.

The surface of the storage box 1 is provided with 14 storage cavities 5 for accommodating reagent tubes 4, as shown in fig. 2, the wall surface of the storage cavity 5 and the surface of the storage box 1 are inclined at an included angle, in order to obtain a better inclination effect, the included angle between the wall surface of the storage cavity 5 and the surface of the storage box 1 is 75-85 degrees, and in the embodiment, the included angle is 80 degrees.

The storage chamber 5 comprises a large reagent tube storage chamber 503 and a small reagent tube storage chamber 504, and the ratio of the volume of the large reagent tube storage chamber 503 to the volume of the small reagent tube storage chamber 504 is 1.5-3: in this embodiment, the volume ratio of 2: 1.

the bottom of the storage box 1 is connected with the surface of the storage rack 2 in a sliding manner, and the surface of the storage rack 2 is provided with a sliding chute 201 which is used for accommodating the bottom of the storage box 1 and slides relative to the bottom of the storage box 1. In order to conveniently pull the storage box 1, a handle 7 is arranged on the side of the storage box 1.

As shown in fig. 3, the storage chambers 5 are provided at the bottom thereof with upper drain grooves 501, and the upper drain grooves 501 of adjacent storage chambers 5 are communicated with each other. As shown in fig. 4, at least one storage chamber 5 is further provided with a drain hole 502 at the bottom, and the drain hole 502 is a through hole. The surface of the storage rack 2 is provided with a lower drainage groove 202, and the lower drainage groove 202 is communicated with a drainage hole 502. The accumulated water at the bottom of the storage chamber 5 is collected to the drain hole 502 through the respective upper drain grooves 501, and is then discharged from the lower drain groove 202 in time.

A position sensor 6 is arranged between the storage box 1 and the storage rack 2. The position sensor 6 can be a photoelectric position sensor or an inductive position sensor, the photoelectric position sensor is selected in the embodiment and is arranged on the storage rack 2 and is arranged opposite to the back surface of the storage box 1, when the storage box 1 leaves the storage rack 2, the photoelectric position sensor transmits a corresponding electric signal to a control part of the full-automatic coagulation analyzer, the full-automatic coagulation analyzer stops working, only when the relative distance between the back surface of the storage box 1 and the storage rack 2 is a preset position, the photoelectric position sensor transmits a corresponding electric signal to the control part of the full-automatic coagulation analyzer, and the full-automatic coagulation analyzer can start working.

The cooling member 3 is provided at the lower portion of the storage rack 2 and is connected to the bottom of the storage box 1. The cooling member 3 includes a cooling fin 301, a heat sink 302, and a fan 303. The refrigeration piece 301 is arranged at the lower part of the storage rack 2 and is connected with the bottom of the storage box 1, the refrigeration piece 301 is communicated with an external refrigeration component, and the inside of the refrigeration piece is communicated with refrigeration liquid. The cooling fin 302 is arranged at the bottom of the cooling fin 301, and the fan 303 is arranged at the bottom of the cooling fin 302.

By the technical scheme, the reagent tube in the storage cavity is obliquely arranged, so that the residual amount of the reagent in the reagent tube can be reduced relative to the horizontally-arranged reagent tube; the storage box and the storage rack form a drawing structure, and compared with a fixed structure in the prior art, the reagent tube storage rack is convenient for operators to move and take reagent tubes; the position sensor between the storage box and the storage rack ensures that the signal is sent to the full-automatic coagulation analyzer to operate and work after the storage box moves in place, so that the use safety of the equipment is ensured; the upper drainage groove at the bottom of the storage cavity and the lower drainage groove on the surface of the storage rack can drain accumulated water generated by the cold of the reagent tube at the bottom of the storage cavity in time, so that the cold storage effect of the reagent is ensured.

The above-described embodiments are only preferred embodiments of the present invention, and are not intended to limit the present invention in any way, and other variations and modifications may be made without departing from the spirit of the utility model as set forth in the claims.

Claims (10)

1. The utility model provides a cold-stored module of full-automatic blood coagulation analysis appearance reagent which characterized in that: this cold-stored module of full-automatic blood coagulation analysis appearance reagent includes case (1), storage rack (2) and cooling part (3) that top-down set gradually, case (1) surface is equipped with a plurality of storage chamber (5) that are used for holding reagent pipe (4), storage chamber (5) wall is contained angle slope setting with case (1) surface, be equipped with position sensor (6) between case (1) and storage rack (2), storage rack (2) lower part and meet bottom case (1) are located in cooling part (3).

2. The reagent refrigeration module of the fully automatic coagulation analyzer according to claim 1, wherein: the bottom of the storage box (1) is connected with the surface of the storage rack (2) in a sliding manner.

3. The reagent refrigeration module of the fully automatic coagulation analyzer according to claim 1, wherein: the side part of the storage box (1) is provided with a handle (7).

4. The reagent refrigeration module of the fully automatic coagulation analyzer according to claim 1, wherein: an upper drainage groove (501) is formed in the bottom of each storage cavity (5), the upper drainage grooves (501) of adjacent storage cavities (5) are communicated with each other, a drainage hole (502) is formed in the bottom of at least one storage cavity (5), and the drainage hole (502) is a through hole.

5. The reagent refrigeration module of the fully automatic coagulation analyzer according to claim 1, wherein: the storage cavity (5) comprises a large reagent tube storage cavity (503) and a small reagent tube storage cavity (504), and the volume ratio of the large reagent tube storage cavity (503) to the small reagent tube storage cavity (504) is 1.5-3: 1.

6. the reagent refrigeration module of the fully automatic coagulation analyzer according to claim 1, wherein: the surface of the storage rack (2) is provided with a sliding chute (201) which is used for accommodating the bottom of the storage box (1) and slides relative to the bottom of the storage box (1).

7. The reagent refrigeration module of the fully automatic coagulation analyzer according to claim 1, wherein: the surface of the storage rack (2) is provided with a lower drainage groove (202), and the lower drainage groove (202) is communicated with the bottom of the storage cavity (5).

8. The reagent refrigeration module of the fully automatic coagulation analyzer according to claim 1, wherein: the cooling component (3) comprises a refrigeration piece (301), and the refrigeration piece (301) is arranged on the lower portion of the storage rack (2) and connected with the bottom of the storage box (1).

9. The reagent refrigeration module of the fully automatic coagulation analyzer according to claim 8, wherein: the cooling component (3) further comprises a cooling fin (302), and the cooling fin (302) is arranged at the bottom of the refrigeration fin (301).

10. The reagent refrigeration module of the fully automatic coagulation analyzer according to claim 9, wherein: the cooling component (3) further comprises a fan (303), and the fan (303) is arranged at the bottom of the radiating fin (302).

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