CN214277598U - Standing mechanism of blood testing machine - Google Patents

Abstract

The utility model relates to a blood test machine's mechanism of stewing, including anchor clamps and a plurality of sensor of stewing, the system of stewing has a plurality of reagent pipe static groove and a plurality of blood sampling pipe static groove on the anchor clamps, every reagent pipe static groove with every blood sampling pipe static groove all corresponds and sets up one the sensor of stewing, reagent pipe static groove corresponds the induction end of sensor of stewing is located the top in reagent pipe static groove, the blood sampling pipe static groove corresponds the induction end of sensor of stewing is located the top in blood sampling pipe static groove. The utility model is provided with the reagent tube standing groove and the blood sampling tube standing groove, so that the reagent tube and the blood sampling tube are separately kept standing to prevent confusion; and still be provided with the sensor that stews, only when the sensor that stews does not sense reagent pipe or heparin tube, extracting device just can remove reagent pipe or heparin tube to the reagent pipe that this sensor that stews corresponds groove or the heparin tube groove of quiescing, guarantees to stew successfully.

Description

Standing mechanism of blood testing machine

Technical Field

The utility model relates to a blood test machine's mechanism of stewing belongs to medical instrument technical field.

Background

The basic steps of blood test are: 1. collecting a specimen, and extracting venous blood of a patient by a clinical nurse; 2. conveying the specimen, and immediately conveying the specimen to a clinical laboratory after blood sampling; 3. receiving and processing a specimen, and adding a reagent required by the test into the specimen by a clinical laboratory; 4. and (5) testing and preserving the specimen on a machine. When the specimen is processed, the specimen needs to be turned over firstly and then kept stand for one minute; the specimen is turned over after the reagent is added and then is kept still for one minute, but the original specimen and the processed specimen are put together and kept still and are easy to be confused. And the utility model discloses the people automatic extracting device who has designed, extracting device press from both sides and get heparin tube or reagent pipe and remove to the department of stewing, but extracting device can't distinguish whether heparin tube or reagent pipe have been placed in the department of should stewing, consequently appear extracting device easily and place a plurality of heparin tubes or reagent pipe in the department of stewing, lead to the failure of stewing.

SUMMERY OF THE UTILITY MODEL

The utility model aims at the shortcoming of prior art, provide a blood test machine's that separately stews mechanism of stewing with heparin tube and reagent pipe.

For realizing the purpose the utility model adopts the technical proposal that:

the standing mechanism of the blood testing machine comprises a standing clamp and a plurality of standing sensors, wherein a plurality of reagent tube standing grooves and a plurality of blood sampling tube standing grooves are formed in the standing clamp, each reagent tube standing groove and each blood sampling tube standing groove are correspondingly provided with one standing sensor, the sensing end of each standing sensor corresponding to the reagent tube standing groove is located above the reagent tube standing groove, and the sensing end of each standing sensor corresponding to the blood sampling tube standing groove is located above the blood sampling tube standing groove.

As a further optimization of the above technical solution: the blood test device is characterized in that the standing clamp is also provided with a fixed groove, the bottom of the fixed groove is provided with a fixed hole, and a screw penetrates through the fixed hole to fix the standing clamp on the blood test machine.

As a further optimization of the above technical solution: the reagent tube standing grooves are three in number and are uniformly distributed on the right half part of the standing clamp.

As a further optimization of the above technical solution: the blood collection tube standing grooves are three in number and are uniformly distributed on the left half part of the standing clamp.

Compared with the prior art, the utility model is provided with the reagent tube standing groove and the blood sampling tube standing groove, so that the reagent tube and the blood sampling tube are separately kept standing to prevent confusion; and still be provided with the sensor that stews, only when the sensor that stews does not sense reagent pipe or heparin tube, extracting device just can remove reagent pipe or heparin tube to the reagent pipe that this sensor that stews corresponds groove or the heparin tube groove of quiescing, guarantees to stew successfully.

Drawings

Fig. 1 is a schematic perspective view of a blood testing machine according to the present invention.

Fig. 2 is a schematic perspective view of the front frame and devices on the front frame in the blood testing machine of the present invention.

Fig. 3 is a schematic perspective view of the dispensing device of the blood testing machine of the present invention.

Fig. 4 is a schematic perspective view of the present invention.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and the following detailed description. As shown in fig. 1-4, the blood testing machine of the present invention comprises a feeding device 1, a material taking device 2, a batching device 3 and a material moving device 4 and a testing device 5 on a rear frame 8, which are sequentially arranged from front to back on a front frame 6. After the blood sample is collected, heparin tube and other materials are put into in the loading attachment 1, after the loading attachment 1 material loading, 2 clamps of extracting device are got heparin tube and other materials on the loading attachment 1 move to set for the position in the dosing unit 3, blood in the heparin tube warp dosing unit 3 sample and add the sample that the test needs and form the sample that awaits measuring, move material device 4 with the sample that awaits measuring and move to carry out the blood test in the verifying attachment 5.

In the above technical scheme: as shown in FIG. 3, the dispensing device 3 comprises a screw-capping mechanism 31, a turning mechanism 32, a standing mechanism 33, a cover-pulling code-scanning mechanism 34, a suction head positioning mechanism 35, a specimen-to-be-tested transferring mechanism 36, and a reagentBottle positioning mechanism 37, reagent feeding mechanism 38, dosing unit 3 is fixed to front frame 6 by a dosing plate 301 at the bottom. The cover screwing mechanism 31 is responsible for opening and closing the cover of the reagent tube; the turnover mechanism 32 is responsible for turning over the blood sampling tube or the reagent tube; the cover-pulling code-scanning mechanism 34 is responsible for scanning bar codes on the blood collection tubes and opening and closing covers of the blood collection tubes; the sucker positioning mechanism 35 is responsible for moving the sucker; the sample transfer mechanism 36 to be tested is responsible for moving the measuring cup 7; the reagent bottle positioning mechanism 37 is used for placing glass bottles P1, P2 and P3 containing various reagents required by blood tests; the reagent supply mechanism 38 is adapted to receive vials containing other reagents required for blood testing, such as CaCl₂And (3) a reagent.

In the above technical scheme: the standing mechanism 33 is responsible for standing the blood sampling tube and the reagent tube, as shown in fig. 4, the standing mechanism 33 comprises a standing fixture 331 and a plurality of standing sensors 332, the standing fixture 331 is provided with a plurality of reagent tube standing grooves 3311 and a plurality of blood sampling tube standing grooves 3312, the bottom of each reagent tube standing groove 3311 is higher than that of each blood sampling tube standing groove 3312 because the reagent tube is smaller than the blood sampling tube, and each reagent tube standing groove 3311 and each blood sampling tube standing groove 3312 are correspondingly provided with one standing sensor 332. The sensing end of the sensor 332 corresponding to the reagent tube standing groove 3311 is located above the reagent tube standing groove 3311, and the sensing end of the sensor 332 corresponding to the blood collection tube standing groove 3312 is located above the blood collection tube standing groove 3312. The stationary fixture 331 further has a fixing groove 3313, a fixing hole 3314 is formed at the bottom of the fixing groove 3313, and a screw passes through the fixing hole 3314 to fix the stationary fixture 331 to the dispensing plate 301. In this embodiment, three reagent tube standing grooves 3311 are provided, and are uniformly distributed on the right half of the standing jig 331; the blood collecting tube standing grooves 3312 are provided with three grooves, which are uniformly distributed on the left half part of the standing jig 331, and the fixing grooves 3313 are also provided with three grooves. Sensor 332 stews is used for whether reagent pipe has been placed on the response reagent pipe groove 3311 that stews, perhaps whether has placed the blood sampling tube on the response blood sampling tube groove 3312 that stews, and only when sensor 332 stews not sensing reagent pipe or blood sampling tube, extracting device 2 just can place reagent pipe or blood sampling tube to this reagent pipe that sensor 332 corresponds that stews groove or blood sampling tube groove of steving. After the blood sampling tube or the reagent tube is turned over by the turning mechanism 32, the material taking device 2 moves the blood sampling tube or the reagent tube to the standing mechanism 33, and the blood sampling tube and the reagent tube stand respectively.

The foregoing has described in detail preferred embodiments of the present invention. It should be understood that numerous modifications and variations can be devised by those skilled in the art in light of the teachings of the present invention without undue experimentation. Therefore, all should fall into the protection scope of the utility model, the technical scheme that the design of this technical field technical personnel according to the utility model can be obtained through logic analysis, reasoning or limited experiment on prior art's basis, all should fall into.

Claims (3)

1. The standing mechanism of the blood testing machine is characterized by comprising a standing clamp (331) and a plurality of standing sensors (332), wherein the standing clamp (331) is provided with a plurality of reagent tube standing grooves (3311) and a plurality of blood collection tube standing grooves (3312), each reagent tube standing groove (3311) and each blood collection tube standing groove (3312) are correspondingly provided with one standing sensor (332), the sensing end of the standing sensor (332) corresponding to the reagent tube standing groove (3311) is positioned above the reagent tube standing groove (3311), and the sensing end of the standing sensor (332) corresponding to the blood collection tube standing groove (3312) is positioned above the blood collection tube standing groove (3312).

2. The resting mechanism for a blood testing machine according to claim 1, wherein the resting jig (331) further comprises a fixing groove (3313), a fixing hole (3314) is formed at the bottom of the fixing groove (3313), and a screw is passed through the fixing hole (3314) to fix the resting jig (331) to the blood testing machine.

3. The standing mechanism of a blood testing machine according to claim 1, wherein the number of the reagent tube standing grooves (3311) is three, and the reagent tube standing grooves are uniformly distributed on the right half of the standing jig (331);

the blood collection tube standing grooves (3312) are three in number and are uniformly distributed on the left half part of the standing clamp (331).

Images