CN113559753B - Detection subassembly that adjuvant vaccine used - Google Patents

Abstract

The invention provides a detection assembly for adjuvant vaccines, comprising: the first conveying part is suitable for receiving and conveying the jig plate; the oscillating part is positioned at the conveying end of the first conveying part and is suitable for receiving the jig plate; the buffer part is positioned at the conveying end of the oscillating part, and the oscillating part is higher than the buffer part; when the first conveying part conveys the jig plate to the oscillating part, the jig plate is clamped by the oscillating part and oscillates in a reciprocating manner; when the first conveying part continuously conveys the jig plate, the oscillating part obliquely guides the jig plate to the jig plate, is limited between the oscillating part and the buffering part and stands still; when the oscillating part continuously inclines, the jig plate is guided and buffered to the lower part of the oscillating part through the buffer part; the oscillating part can receive the jig plate and oscillate the jig plate to enable the solution in the jig to oscillate uniformly; the inclined guide of the oscillating part can facilitate the extraction of the solution, and simultaneously can guide the used jig plate to the buffer part for recycling.

Description

Detection subassembly that adjuvant vaccine used

Technical Field

The invention relates to reagent detection, in particular to a detection component for adjuvant vaccines.

Background

In bacterin development process, often need carry out various detections to bacterin, and in testing process, need use blending machine or oscillator to carry out intensive mixing usually after to closing the tool board that holds bacterin mixed solution to can not carry out batch mixing, when extracting the mixed solution in the tool board simultaneously, can't extract the mixed solution totally, it is very necessary to provide one kind and can shake even mixed solution and can be convenient for the detection subassembly that adjuvant bacterin that mixed solution extracted was used.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: in the testing process, need use blending machine or oscillator to carry out the intensive mixing behind the mixed solution to closing the tool board that holds the bacterin usually to can not carry out batch mixing, during the mixed solution in the extraction tool board simultaneously, can't extract the mixed solution totally.

The invention provides a detection component for adjuvant vaccines, which can shake up a mixed solution and can facilitate the extraction of the mixed solution, and aims to solve the problems in the prior art.

The technical scheme adopted by the invention for solving the technical problems is as follows: a detection assembly for an adjuvant vaccine, comprising: the first conveying part is suitable for receiving and conveying the jig plate; the oscillating part is positioned at the conveying end of the first conveying part and is suitable for receiving the jig plate; a buffer portion located at a transport end of the oscillating portion, the oscillating portion being higher than the buffer portion; when the first conveying part conveys the jig plate to the oscillating part, the jig plate is clamped by the oscillating part and oscillates in a reciprocating manner; when the first conveying part continuously conveys the jig plates, the oscillating part obliquely guides the jig plates to the jig plate clamp, and the jig plate clamp is limited between the oscillating part and the buffering part and stands still; when the oscillating part continuously inclines, the jig plate is guided and buffered to the lower part of the oscillating part through the buffering part.

Preferably, the oscillating part comprises an oscillating frame and an oscillating plate, the oscillating plate is rotatably arranged in the oscillating frame, and when the jig plate is conveyed to the oscillating plate, the oscillating plate reciprocally rotates the oscillating jig plate; when the first conveying part continuously conveys the jig plate, the oscillating plate rotates to be inclined downwards, and the jig plate is guided to the buffer part below the oscillating plate; when the oscillating plate rotates to be vertical, the jig plate slides down.

Preferably, the buffer part comprises a flexible buffer plate arranged in a mirror image manner and a first limiting column fixed on the buffer plate, one end of the buffer plate is fixedly connected with the oscillation frame, the other end of the buffer plate is arranged below the oscillation plate, when the jig plate is guided by the oscillation plate to slide to the buffer plate, the buffer plate deforms downwards and supports the jig plate, and meanwhile, the first limiting column abuts against the jig plate; when the jig plate slides down, the buffer plate resets upwards, the first limiting column resets towards the oblique upper side, the jig plate is buffered, and the jig plate is guided to move towards the resetting direction of the first limiting column.

Preferably, the top of the oscillation plate is provided with an oscillation bump, and the oscillation bump is matched with the oscillation notch at the bottom of the jig plate.

Preferably, the oscillation bump can be matched with the blocking bump at the bottom of the jig plate.

Preferably, the buffer part further comprises a second limiting column, the second limiting column is arranged on the buffer plate, the height of the second limiting column is smaller than that of the first limiting column, when the buffer plate is used for receiving and taking the jig plate, the jig plate is clamped between the first limiting column and the second limiting column, and the second limiting column can support the jig plate.

Preferably, the buffer part further includes a stopper disposed on a side wall of the oscillation frame, and a top of the stopper can support the buffer plate bent downward.

Preferably, the side wall of the buffer plate is attached to the inner wall of the oscillation frame.

Preferably, the detection assembly for adjuvant vaccines further comprises a second conveying part, the second conveying part is arranged below the oscillation plate, and the second conveying part is suitable for receiving and conveying the jig plate guided to be rebounded by the first limiting column.

Preferably, the second conveying unit has a conveying direction opposite to a conveying direction of the first conveying unit.

The invention has the beneficial effects that:

1. the jig plate can be conveyed to the oscillation part through the first conveying part to oscillate, so that the use convenience is improved simply and reliably.

2. The oscillating part can receive the jig plate and oscillate the jig plate, so that the solution in the jig oscillates uniformly.

3. The inclined guide of the oscillating part can facilitate the extraction of the solution, and simultaneously can guide the used jig plate to the buffer part for recycling.

4. The buffering part can guide and buffer the jig plate which is used up to the recovery area, so that the damage of the jig plate is reduced, and the economic benefit is improved.

Drawings

The invention is further illustrated with reference to the following figures and examples.

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

FIG. 2 is a top view of the preferred embodiment of the present invention;

FIG. 3 is a cross-sectional view taken along the line A in FIG. 2;

FIG. 4 is an enlarged view at B in FIG. 3;

FIG. 5 is a partial cross-sectional view of a preferred embodiment of the sensing assembly of the present invention;

FIG. 6 is a diagram of the operation of a preferred embodiment of the detection assembly of the present invention;

FIG. 7 is a diagram of the operation of a preferred embodiment of the detection assembly of the present invention;

FIG. 8 is a diagram of the operation of a preferred embodiment of the detection assembly of the present invention;

FIG. 9 is a diagram of the operation of the preferred embodiment of the detection assembly of the present invention.

In the figure:

000. a jig plate; 010. an oscillation gap; 020. blocking the bump; 030. a detection hole;

100. a first conveying section;

200. an oscillating unit; 210. an oscillating frame; 220. an oscillating plate; 230. oscillating the bump; 240. a rotating electric machine;

300. a buffer section; 310. a buffer plate; 320. a first limit post; 330. a second limit post; 340. a limiting block;

400. a second conveying part.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention. On the contrary, the embodiments of the invention include all changes, modifications and equivalents coming within the spirit and terms of the claims appended hereto.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "axial", "radial", "circumferential", and the like, indicate orientations and positional relationships based on the orientations and positional relationships shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be considered as limiting the present invention.

Furthermore, the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art. In addition, in the description of the present invention, "a plurality" means two or more unless otherwise specified.

As shown in fig. 1 to 9, the present invention provides a detection kit for an adjuvant vaccine, comprising: a first conveying part 100, wherein the first conveying part 100 is suitable for receiving and conveying the jig plate 000; the oscillating part 200, the oscillating part 200 is located at the end of the first conveying part 100, the oscillating part 200 is suitable for receiving the jig plate 000; a buffer part 300, wherein the buffer part 300 is positioned at the end of the transportation of the oscillating part 200, and the oscillating part 200 is higher than the buffer part 300; wherein, when the first conveying part 100 conveys the jig plate 000 to the oscillating part 200, the jig plate 000 is clamped by the oscillating part 200 and oscillates back and forth; when the first conveying part 100 continuously conveys the jig plates 000, the oscillating part 200 slantingly guides the jig plates 000 to be clamped and limited between the oscillating part 200 and the buffer part 300 and to be kept still; when the oscillating portion 200 is continuously tilted, the jig plate 000 is guided and buffered below the oscillating portion 200 through the buffer portion 300; the functions performed by the above components are explained one by one below.

Jig plate 000

Tool board 000 is the container that bears of adjuvant bacterin, and a plurality of inspection hole 030 are seted up to the top of tool board 000, and inspection hole 030 is suitable for bearing adjuvant bacterin and detect reagent etc. and oscillation notch 010 is seted up to the bottom of tool board 000 to tool board 000's bottom an organic whole is provided with blocks lug 020.

First conveying section 100

The first conveying part 100 is a linear moving pair and comprises a conveying belt, a lead screw guide rail, a linear guide rail and the like; the first conveying unit 100 can support the jig board 000 and convey the jig board 000.

Second conveying part 400

The second conveying part 400 is also a linear moving pair and comprises a conveying belt, a lead screw guide rail, a linear guide rail and the like; the second conveying unit 400 can support the jig board 000 and convey the jig board 000.

Oscillating part 200

The oscillating portion 200 is disposed at the end of the first conveying portion 100, in short, the jig board 000 can be conveyed to the oscillating portion 200 by the first conveying portion 100 to start oscillation;

further, the oscillating portion 200 includes an oscillating plate 220 and an oscillating frame 210, the oscillating portion 200 is rotatably disposed in the oscillating frame 210, the oscillating plate 220 is connected to a rotating shaft of a rotating motor 240 fixed to a side wall of the oscillating frame 210, the oscillating plate 220 performs reciprocating rotation by rotation of the rotating motor 240, and the vibration jig plate 000 is implemented;

further, when the jig plate 000 is conveyed to the oscillation notch 010 at the bottom of the jig plate 000 by the first conveying part 100 and is clamped at the oscillation bump 230 of the oscillation plate 220, the first conveying part 100 stops conveying, the reagent to be mixed is added into the jig plate 000, and the oscillation plate 220 oscillates the jig plate 000 in a reciprocating manner, in short, when the oscillation notch 010 is clamped at the oscillation bump 230, the jig plate 000 can be prevented from sliding in the oscillation process, so that the reagent in the jig plate 000 is prevented from scattering;

further, after the oscillation is finished, one end of the oscillation plate 220, which is far away from the first conveying part 100, tilts up the jig plate 000 to tilt and raise the mixed reagent in the detection hole 030 to one side, so that the mixed reagent is convenient to extract, and the mixed reagent is prevented from being retained at the bottom of the detection hole 030;

further, the oscillation plate 220 is continuously tilted away from the end of the first conveying part 100 to enable the oscillation notch 010 to slide out of the oscillation bump 230, the first conveying part 100 continuously conveys the jig plate 000 away from the first conveying part 100, when the oscillation plate 220 completely supports the jig plate 000, the oscillation plate 220 is tilted away from the end of the first conveying part 100, the jig plate 000 can slide down along the way, one end of the jig plate 000 slides into the buffer part 300 and is supported by the buffer part 300, the other end of the jig plate 000 still stays on the oscillation plate 220, and meanwhile, the blocking bump 020 at the bottom of the jig plate 000 can be limited by the oscillation bump 230 to avoid that the jig plate 000 slides out of the buffer part 300 due to overlarge inertia;

further, when the oscillation plate 220 continues to rotate to the vertical state, the oscillation plate 220 loses the supporting function of the jig plate 000, and the jig plate 000 can slide down to the second conveying part 400 disposed under the oscillation plate 220 and be recovered by the second conveying part 400.

Buffer part 300

The buffer part 300 can receive the jig plate 000 which slides down from the oscillating part 200;

the buffering part 300 includes two buffer plates 310 and a first limiting post 320 fixed on each buffer plate 310, the buffer plates 310 are flexible plates, one end of each buffer plate 310 is fixed on the oscillating frame 210, the other end of each buffer plate 310 is arranged below the oscillating plate 220, the initial state of each buffer plate 310 is horizontal, when the jig plate 000 slides to the buffer plate 310, the first limiting post 320 can abut against the jig plate 000, the jig plate 000 is prevented from continuously sliding to the root of the buffer plate 310, and meanwhile, the buffer plates 310 begin to deform downwards and buffer the jig plate 000;

further, a second limiting column 330 is arranged at one end of the buffer plate 310 close to the first conveying part 100, the height of the second limiting column 330 is smaller than that of the first limiting column 320, when the jig plate 000 is pressed on the buffer plate 310, the bottom of the jig plate 000 can be supported by the second limiting column 330, and the jig plate 000 is prevented from sliding down due to overlarge deformation of the buffer plate 310;

furthermore, one side wall of the buffer plate 310 is attached to the side wall of the oscillating frame 210, so that the buffer plate 310 can be prevented from twisting when bearing the jig plate 000, and the service life of the buffer plate 310 is prolonged; meanwhile, the side wall of the oscillating frame 210 is provided with the limiting block 340, and the limiting block 340 can support the buffer plate 310 when the buffer plate 310 deforms, so that the buffer plate 310 is prevented from being broken due to deformation fatigue.

Further, when the jig plate 000 falls, the buffer plate 310 can be reset upward, and the first positioning posts 320 are reset obliquely upward, so that the jig plate 000 can be guided to rebound to the second conveying part 400 and conveyed by the second conveying part 400.

The working process is as follows:

first, the jig plate 000 filled with the adjuvant vaccine is transported from the first transporting part 100 to the oscillating plate 220;

then, a detection reagent is added to the jig plate 000;

secondly, the oscillating plate 220 oscillates the jig plate 000 to fully mix the reagents in the jig plate 000;

thirdly, the oscillating plate 220 is inclined to extract the mixed reagent;

then, the oscillating plate 220 is continuously tilted, and the jig plate 000 slides down on the buffer plate 310;

next, the oscillating plate 220 is rotated to be in a vertical state, the oscillating plate 220 falls, and the buffer plate 310 rebounds to guide the jig plate 000 to rebound to the second conveying part 400;

finally, the second conveying unit 400 returns the empty jig plate 000.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, a schematic representation of the term does not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (7)

1. A detection assembly for an adjuvanted vaccine, comprising:

a first conveying section (100), said first conveying section (100) being adapted to take up and convey a jig plate (000);

an oscillating part (200), wherein the oscillating part (200) is positioned at the conveying end of the first conveying part (100), and the oscillating part (200) is suitable for receiving a jig plate (000);

a buffer (300), the buffer (300) being located at a transport end of the oscillating portion (200), the oscillating portion (200) being higher than the buffer (300); wherein

When the first conveying part (100) conveys the jig plate (000) to the oscillating part (200), the jig plate (000) is clamped by the oscillating part (200) and oscillates in a reciprocating manner;

when the first conveying part (100) continuously conveys the jig plates (000), the oscillating part (200) obliquely guides the jig plates (000) to the jig plates (000), is clamped and limited between the oscillating part (200) and the buffer part (300) and stands still;

when the oscillating part (200) continuously inclines, the jig plate (000) is guided and buffered below the oscillating part (200) through the buffer part (300);

the oscillating part (200) comprises an oscillating frame (210) and an oscillating plate (220), the oscillating plate (220) is rotatably arranged in the oscillating frame (210), wherein

When the jig plate (000) is conveyed to the oscillating plate (220), the oscillating plate (220) rotates the oscillating jig plate (000) in a reciprocating manner;

when the first conveying part (100) continuously conveys the jig plate (000), the oscillating plate (220) rotates to be inclined downwards, and the jig plate (000) is guided to the buffer part (300) positioned below the oscillating plate (220);

when the oscillating plate (220) rotates to be vertical, the jig plate (000) slides down;

buffering portion (300) including flexible buffer board (310) that the mirror image set up with fix first spacing post (320) on buffer board (310), the one end of buffer board (310) with oscillating frame (210) fixed connection, the other end setting of buffer board (310) is in the below of oscillating plate (220), wherein

When the jig plate (000) is guided by the oscillating plate (220) to slide down to the buffer plate (310), the buffer plate (310) deforms downward and supports the jig plate (000), and the first limiting columns (320) abut against the jig plate (000);

when the jig plate (000) slides down, the buffer plate (310) resets upwards, the first limiting column (320) resets towards the oblique upper direction, the jig plate (000) is buffered, and the jig plate (000) is guided to move towards the resetting direction of the first limiting column (320);

the buffer part (300) further comprises a second limiting column (330), the second limiting column (330) is arranged on the buffer plate (310), and the height of the second limiting column (330) is smaller than that of the first limiting column (320), wherein

When the jig plate (000) is taken in from the buffer plate (310), the jig plate (000) is clamped between the first limiting column (320) and the second limiting column (330), and the second limiting column (330) can support the jig plate (000).

2. The detection kit for an adjuvanted vaccine of claim 1,

the top of the oscillating plate (220) is provided with an oscillating lug (230), and the oscillating lug (230) is matched with an oscillating notch (010) at the bottom of the jig plate (000).

3. The detection kit for an adjuvanted vaccine of claim 2,

the oscillating lug (230) can be matched with a blocking lug (020) at the bottom of the jig plate (000).

4. The detection kit for an adjuvanted vaccine of claim 3,

the buffer part (300) further comprises a limit block (340) arranged on the side wall of the oscillating frame (210), and the top of the limit block (340) can support the buffer plate (310) which is bent downwards.

5. The detection kit for an adjuvanted vaccine of claim 4,

the side wall of the buffer plate (310) is attached to the inner wall of the oscillating frame (210).

6. The detection kit for an adjuvanted vaccine of claim 5, wherein,

the detection assembly for adjuvant vaccine further comprises a second conveying part (400), wherein the second conveying part (400) is arranged below the oscillating plate (220), and the second conveying part (400) is suitable for receiving and conveying the jig plate (000) which is guided to rebound by the first limiting column (320).

7. The detection kit for an adjuvanted vaccine of claim 6,

the second conveying unit (400) has a conveying direction opposite to the conveying direction of the first conveying unit (100).

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