CN214824320U - In-vitro diagnostic reagent subpackaging reaction tube pipe pressing device - Google Patents

Abstract

An in vitro diagnostic reagent subpackages the reaction tube pressure tube ware, the diagnostic reagent subpackages the field, includes: the utility model discloses a problem that eight rows of reaction tubes are soft and easy to break when taking out can be solved to the unanimous atress, has guaranteed the integrality that the reaction tube was taken out, can also play the effect of protection to the reagent in the reaction tube simultaneously, and then can also improve work efficiency; the utility model discloses can once only all take out the reaction tube, can also singly take out one row of appointed reaction tube simultaneously, can adjust according to the needs of diagnosis and take out, avoid all taking out reaction tube back reaction tube and empty, make inside reagent spill, can also avoid making the reaction tube that mixes simultaneously.

Description

In-vitro diagnostic reagent subpackaging reaction tube pipe pressing device

Technical Field

The utility model belongs to diagnostic reagent partial shipment field, especially an external diagnostic reagent partial shipment reaction tube pipe press ware.

Background

Due to the vigorous implementation of in-vitro diagnosis technology, various diagnostic product consumables are derived, one of eight rows of diagnostic reaction tubes is one of eight reaction tubes, the eight reaction tubes in one row are placed in a tube support, and the eight reaction tubes are soft and easy to break due to the soft material and uneven stress, so that the eight reaction tubes are easy to break when taken out of the eight row of tube support, and the diagnosis of a reagent is influenced.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problems in the prior art and providing a tube pressing device for a split charging reaction tube of an in vitro diagnostic reagent.

The purpose is achieved, the utility model adopts the following technical scheme that:

an in vitro diagnostic reagent dispensing reaction tube pressure tube device, comprising: backup pad assembly, clamping device and unit control device, backup pad assembly and clamping device sliding connection, backup pad assembly lower extreme is provided with unit control device, the backup pad assembly includes: the clamping device comprises a supporting plate, a guide pillar, a spring and a convex pillar assembly, wherein the guide pillar is vertically and fixedly connected to the upper end of the supporting plate, the spring is sleeved on the guide pillar, the clamping device is connected with the guide pillar in a sliding mode, and a unit control device is arranged at the lower end of the supporting plate.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model provides an in vitro diagnostic reagent split charging reaction tube pipe press, the utility model can solve the problem that eight rows of reaction tubes are soft and easy to break when taking out due to the consistent stress, thereby ensuring the completeness of the reaction tube taking out, and simultaneously playing a role in protecting the reagent in the reaction tube, and further improving the working efficiency; the utility model discloses can once only all take out the reaction tube, can also singly take out one row of appointed reaction tube simultaneously, can adjust according to the needs of diagnosis and take out, avoid all taking out reaction tube back reaction tube and empty, make inside reagent spill, can also avoid making the reaction tube that mixes simultaneously.

Drawings

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

FIG. 2 is a schematic view of a support plate assembly;

FIG. 3 is a schematic view of a post assembly;

FIG. 4 is a schematic view of the structure of the clamping device;

FIG. 5 is a schematic view of the slide apparatus;

FIG. 6 is a front view of the inversion column;

FIG. 7 is a schematic view of a lug assembly arrangement.

Detailed Description

The technical solution of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiment of the present invention, and it is obvious that the described embodiment is only a part of the embodiments of the present invention, rather than all embodiments, and all other embodiments obtained by a person of ordinary skill in the art without creative work belong to the protection scope of the present invention based on the embodiments of the present invention.

An in vitro diagnostic reagent dispensing reaction tube pressure tube device, comprising: backup pad assembly 1, clamping device 2 and unit controlling means 3, backup pad assembly 1 and clamping device 2 sliding connection, 1 lower extreme of backup pad assembly is provided with unit controlling means 3, backup pad assembly 1 includes: the device comprises a supporting plate 1-1, guide pillars 1-3, springs 1-4 and convex column assemblies 1-5, wherein the guide pillars 1-3 are vertically and fixedly connected to the upper end of the supporting plate 1-1, the springs 1-4 are sleeved on the guide pillars 1-3, a clamping device 2 is slidably connected with the guide pillars 1-3, and a unit control device 3 is arranged at the lower end of the supporting plate 1-1.

The support plate assembly 1 further includes: the positioning device comprises positioning columns 1-2, the supporting plate 1-1 is provided with the positioning columns 1-2, the number of the positioning columns 1-2 is two, the two positioning columns 1-2 are symmetrically arranged, the number of the guide columns 1-3 and the number of the springs 1-4 are two, the two guide columns 1-3 are symmetrically arranged, and the number of the convex column assemblies 1-5 is multiple.

A plurality of the lug assemblies 1-5 each include: 1-5-1 convex column, 1-5-2 upper baffle, 1-5-3 spring and 1-5-4 lower baffle, the convex column 1-5-1 penetrates through the supporting plate 1-1 in a sliding manner, an upper baffle 1-5-2 is arranged on the convex column 1-5-1, the upper baffle 1-5-2 is positioned above the supporting plate 1-1, the lower end of the convex column 1-5-1 is provided with a lower baffle 1-5-4, the convex column 1-5-1 is sleeved with a spring 1-5-3, the spring 1-5-3 is positioned between the supporting plate 1-1 and the lower baffle plate 1-5-4, and the convex column assemblies 1-5 are arranged in a rectangular array.

The clamping device 2 comprises: the novel anti-slip device comprises a handle 2-1, a rotating column 2-2, a cross rod 2-3, anti-slip pads 2-4 and a spring II 2-5, wherein the lower end of one side of the handle 2-1 is rotatably connected with the rotating column 2-2, the cross rod 2-3 is horizontally fixed on one side face of the rotating column 2-2, one end of the spring II 2-5 is fixedly connected with the cross rod 2-3, the other end of the spring II 2-5 is fixedly connected with the handle 2-1, the anti-slip pads 2-4 are arranged at the lower end of the handle 2-1, the anti-slip pads 2-4 are arranged in a plurality, lugs are arranged at two ends of the handle 2-1, and the handle 2-1 is slidably connected with the guide column 1-3 through the lugs.

The unit control device 3 includes: the device comprises a shell 3-1, a sliding rod 3-2 and a sliding device 3-3, wherein the shell 3-1 is arranged at the lower end of the supporting plate 1-1, the sliding rod 3-2 is horizontally and fixedly connected inside the shell 3-1, and the sliding rod 3-2 is in sliding connection with the sliding device 3-3.

The sliding device 3-3 includes: the device comprises a sliding block 3-3-1, a hinged column 3-3-2, a turnover column 3-3-3 and a spring III 3-3-4, wherein the sliding block 3-3-1 is connected with the sliding block 3-2 in a sliding mode, the upper end of the sliding block 3-3-1 is vertically and fixedly connected with the hinged column 3-3-2, the middle of the turnover column 3-3-3 is rotatably connected with the hinged column 3-3-2, a transverse plate is arranged on the turnover column 3-3-3, one end of the spring III 3-3-4 is fixedly connected with the turnover column 3-3-3, and the other end of the spring III 3-3-4 is fixedly connected with the sliding block 3-3-1.

The utility model discloses the theory of operation is:

placing a reaction tube to be reacted in a tube support, aligning the tube support to a handle 2-1 when the reaction tube is reacted and needs to be detected, then pinching a cross rod 2-3 to compress a spring II 2-5, simultaneously driving a rotating column 2-2 to be in rotating fit with the handle 2-1 to clamp the tube support, wherein an anti-slip pad 2-4 plays a role in preventing the tube support from sliding off, then pressing the handle 2-1 downwards to slide downwards along a guide column 1-3, simultaneously compressing the spring 1-4, the spring 1-4 and the spring II 2-5 play a role in resetting, the handle 2-1 downwards moves to drive the tube support to downwards move, the two outer side surfaces of the tube support downwards move to contact with the positioning column 1-2, the positioning column 1-2 plays a role in positioning, and can position the tube support between the two positioning columns 1-2, the deviation generated when the pipe bracket moves downwards is prevented from influencing the taking out of the reaction pipe; the pipe bracket moves downwards, the convex columns 1-5-1 arranged on the plurality of convex column assemblies 1-5 are inserted into the pipe bracket, the reaction pipe can be ejected out, and then the reaction pipe can be completely taken out; the pipe bracket moves horizontally downwards, and is uniformly stressed when contacting the convex column 1-5-1, so that the reaction pipe can be prevented from being broken; the upper baffle 1-5-2 plays a role of limiting the convex column 1-5-1, and prevents the convex column 1-5-1 from moving downwards when the pipe bracket moves downwards to contact with the convex column 1-5-1; when the reaction tube is completely taken out, the cross rods 2-3 are loosened, the tube support is taken down, and then the tube support is driven to reset through the action of the springs 1-4 and the springs 2-5, so that the next taking can be carried out. When a single row of reaction tubes need to be taken out, the tube support is moved to the position above the positioning column 1-2 through the handle 2-1, then the sliding block 3-3-1 is pushed to slide along the sliding rod 3-2, the cross rod arranged on the turnover column 3-3-3 is aligned to the row of reaction tubes need to be taken out, then the turnover column 3-3-3 is pressed downwards, the turnover column 3-3-3 rotates by taking the hinged column 3-3-2 as the center of a circle, the turnover column 3-3-3 rotates to push the row of convex columns 1-5-1 to move upwards through the cross rod, meanwhile, the springs 1-5-3 are compressed, the lower baffle plate 1-5-4 plays the role of the limiting spring 1-5-3, the row of convex columns 1-5-1 move upwards to take out the row of reaction tubes in the tube support, the single row of reaction tubes is taken out, the turnover column 3-3-3 is loosened to reset under the action of the spring III 3-3-4 after the reaction tubes are taken out, and the convex column 1-5-1 is driven to reset under the action of the spring I1-5-3, so that one-time taking is completed.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (6)

1. The utility model provides an in vitro diagnostic reagent partial shipment reaction tube pipe press which characterized in that: the method comprises the following steps: backup pad assembly (1), clamping device (2) and unit controlling means (3), backup pad assembly (1) and clamping device (2) sliding connection, backup pad assembly (1) lower extreme is provided with unit controlling means (3), backup pad assembly (1) includes: the device comprises a supporting plate (1-1), guide columns (1-3), springs (1-4) and a convex column assembly (1-5), wherein the guide columns (1-3) are vertically and fixedly connected to the upper end of the supporting plate (1-1), the springs (1-4) are sleeved on the guide columns (1-3), a clamping device (2) is connected with the guide columns (1-3) in a sliding mode, and a unit control device (3) is arranged at the lower end of the supporting plate (1-1).

2. The in vitro diagnostic reagent dispensing reaction tube pressure tube device of claim 1, wherein: the support plate assembly (1) further comprises: the positioning device comprises positioning columns (1-2), wherein the supporting plate (1-1) is provided with the positioning columns (1-2), the number of the positioning columns (1-2) is two, the two positioning columns (1-2) are symmetrically arranged, the number of the guide columns (1-3) and the number of springs (1-4) are two, the number of the guide columns (1-3) is symmetrically arranged, and the number of the convex column assemblies (1-5) is multiple.

3. The in vitro diagnostic reagent dispensing reaction tube pressure tube device of claim 2, wherein: a plurality of said lug assemblies (1-5) each comprising: the device comprises a convex column (1-5-1), an upper baffle plate (1-5-2), a first spring (1-5-3) and a lower baffle plate (1-5-4), wherein the convex column (1-5-1) penetrates through a support plate (1-1) in a sliding manner, the upper baffle plate (1-5-2) is arranged on the convex column (1-5-1), the upper baffle plate (1-5-2) is positioned above the support plate (1-1), the lower end of the convex column (1-5-1) is provided with the lower baffle plate (1-5-4), the first spring (1-5-3) is sleeved on the convex column (1-5-1), and the first spring (1-5-3) is positioned between the support plate (1-1) and the lower baffle plate (1-5-4), the convex column assemblies (1-5) are arranged in a rectangular array.

4. The in vitro diagnostic reagent dispensing reaction tube pressure tube device of claim 1, wherein: the clamping device (2) comprises: a handle (2-1), a rotating column (2-2), a cross bar (2-3), a non-slip mat (2-4) and a second spring (2-5), the lower end of one side of the handle (2-1) is rotationally connected with a rotating column (2-2), a cross bar (2-3) is horizontally fixed on one side surface of the rotating column (2-2), one end of the second spring (2-5) is fixedly connected with the cross rod (2-3), the other end of the second spring (2-5) is fixedly connected with the handle (2-1), the lower end of the handle (2-1) is provided with a plurality of anti-skid pads (2-4), the two ends of the handle (2-1) are provided with lugs, and the handle (2-1) is connected with the guide columns (1-3) in a sliding mode through the lugs.

5. The in vitro diagnostic reagent dispensing reaction tube pressure tube device of claim 1, wherein: the unit control device (3) includes: the device comprises a shell (3-1), a sliding rod (3-2) and a sliding device (3-3), wherein the shell (3-1) is arranged at the lower end of the supporting plate (1-1), the sliding rod (3-2) is horizontally and fixedly connected inside the shell (3-1), and the sliding rod (3-2) is in sliding connection with the sliding device (3-3).

6. The in vitro diagnostic reagent dispensing reaction tube pressure tube device of claim 5, wherein: the sliding device (3-3) comprises: a slide block (3-3-1), a hinged column (3-3-2), a turnover column (3-3-3) and a spring III (3-3-4), the sliding block (3-3-1) is connected with the sliding rod (3-2) in a sliding way, the upper end of the sliding block (3-3-1) is vertically and fixedly connected with a hinged column (3-3-2), the middle part of the turning column (3-3-3) is rotationally connected with the hinged column (3-3-2), a transverse plate is arranged on the turning column (3-3-3), one end of the spring III (3-3-4) is fixedly connected with the overturning column (3-3-3), and the other end of the spring III (3-3-4) is fixedly connected with the sliding block (3-3-1).

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