阅读说明：本技术 一种独立自动加液检测装置 (Independent automatic liquid feeding detection device ) 是由 李大伟 杨帆 杨致亭 叶学松 梁波 王江勇 于 2021-11-09 设计创作，主要内容包括：本发明提供了一种独立自动加液检测装置,包括外壳,所述外壳内由上到下依次设置有垂直加液模块、反应杯平移模块、暗室检测模块和自动混匀模块,所述外壳包括上壳、中壳和下壳,所述下壳上设置有提供反应杯滑动的轨道槽,所述轨道槽的一端开设有进杯口,另一端开设有掉杯口,所述轨道槽由进杯口到掉杯口依次设置有换轨位、预激发混匀位、激发检测位、抽废液位和掉杯位。可有效减少占用的体积,有效保证内部暗室的形成,且对反应杯的加液、混匀、检测及抽液都在暗室内进行,杜绝反应杯与外界的接触,避免污染,到达内部后自动形成暗室,杜绝光线进入,从根源上解决了外界光线对实验的影响,确保光子计数器读数的准确性,为实验检测提供准确数据。(The invention provides an independent automatic liquid adding detection device which comprises a shell, wherein a vertical liquid adding module, a reaction cup translation module, a darkroom detection module and an automatic mixing module are sequentially arranged in the shell from top to bottom, the shell comprises an upper shell, a middle shell and a lower shell, a track groove for sliding a reaction cup is arranged on the lower shell, one end of the track groove is provided with a cup inlet, the other end of the track groove is provided with a cup falling opening, and the track groove is sequentially provided with a rail changing position, a pre-excitation mixing position, an excitation detection position, a waste liquid level and a cup falling position from the cup inlet to the cup falling opening. The volume that can effectively reduce to occupy, effectively guarantee the formation of inside darkroom, and liquid feeding, mixing, detection and the drawing liquid to the reaction cup all go on in the darkroom, stop reaction cup and external contact, avoid polluting, reach inside back automatic formation darkroom, stop light and get into, solved the influence of external light to the experiment from the root, ensure the accuracy of photon counter reading, detect for the experiment and provide accurate data.)

1. The utility model provides an independent automatic liquid feeding detection device which characterized in that: the utility model discloses a reaction cup translation module, darkroom detection module and automatic mixing module, including the shell, by last perpendicular liquid feeding module, reaction cup translation module, darkroom detection module and the automatic mixing module of having set gradually under to in the shell, the shell includes epitheca, mesochite and inferior valve, be provided with on the inferior valve and provide the gliding track groove of reaction cup, the one end in track groove has been seted up into the rim of a cup, and the rim of a cup has been seted up to the other end, reaction cup translation module includes along advancing the rim of a cup to falling rim of a cup reciprocating motion's pusher dog, the pusher dog is connected with the first power device of its motion of drive, the track groove is by advancing the rim of a cup to falling the rim of a cup set gradually trade the rail position, arouse mixing position in advance, arouse the detection position, take out useless liquid level and fall the cup position, automatic mixing module with it corresponds to arouse the detection position.

2. The device for detecting the independent automatic liquid feeding according to claim 1, wherein: the automatic blending module comprises a blending wheel and a second power device for driving the blending wheel to rotate, the blending wheel is located in a pre-excitation blending position in the track groove, and a plurality of bulges are arranged on the blending wheel along the circumferential direction.

3. The device for detecting the independent automatic liquid feeding according to claim 1, wherein: the vertical liquid adding module is arranged above the reaction cup translation module and comprises a lifting plate and a third power device for driving the lifting plate to be close to or far away from the pusher dog.

4. The device according to claim 3, wherein: the lifter plate is provided with the priming liquid needle in advance in the corresponding position of inciting mixing in advance, is provided with the priming liquid needle in laser detection position correspondence, is provided with the waste liquid needle in drawing waste liquid position correspondence.

5. The device according to claim 3, wherein: the output end of the third power device is connected with a second lead screw, the second lead screw is arranged along the vertical direction, a second nut is sleeved on the second lead screw and fixedly connected with the lifting plate, guide shafts are arranged on two sides of the second lead screw, one end of each guide shaft is fixed on the third mounting plate, and the other end of each guide shaft penetrates through the lifting plate and is connected with the middle shell.

6. The device according to claim 3, wherein: the lifter plate has set gradually first baffle, second baffle and third baffle along the horizontal direction, it is provided with first spout, second spout and third spout to correspond on the inferior valve, first baffle slides along first spout, the second baffle slides along the second spout, the third baffle slides along the third spout.

7. The device according to claim 6, wherein: the first spout sets up and is advancing rim of a cup department, the length of first spout is greater than the length of advancing the rim of a cup, the second spout sets up and arouses and detect the position, the second spout is the setting of U type, the both sides of second spout are located arouses the both sides of detecting the position, two tip of second spout are located the inferior valve respectively, the third spout sets up and falls the rim of a cup, the length of third spout is greater than the length that falls the rim of a cup.

8. The device according to claim 6, wherein: the darkroom detection module comprises a photon counter corresponding to the excitation detection position, the photon counter is fixed on the lower shell, a detection port is formed in the lower shell and communicates the photon counter with the track groove, and the detection port corresponds to the excitation detection position.

9. The device according to claim 8, wherein: the utility model discloses a spring, including first baffle, first spout, second baffle, spring cover, detection mouth department, detection shaft, guide shaft, sealed shell, detection shaft, spring cover, lower extreme, the lower extreme of fourth baffle is located the upper end of spring, the guide shaft can be followed to the fourth baffle and slides, the spring periphery still is provided with sealed shell, sealed shell installs on the inferior valve, the bottom at the inferior valve is fixed to the one end of guide shaft, and the other end is fixed on sealed shell, the both ends of fourth baffle with the sliding direction coincidence setting of second baffle is followed to the both ends of second spout.

10. An independent automatic liquid feeding detection device according to any one of claims 1 to 9, characterized in that: the cup falling port is also provided with a cup outlet shell which is fixed on the middle shell and the lower shell, a cup outlet channel is arranged in the cup outlet shell, one end of the cup outlet channel is communicated with the cup falling port, the other end of the cup outlet channel is provided with a cup outlet, and the cup outlet is arranged at the bottom of the cup outlet shell.

Technical Field

The invention relates to a luminescence immunoassay analyzer, in particular to an independent automatic liquid adding detection device.

Background

At present, the detection of the luminescence immunoassay analyzer is mostly carried out in situ to form a darkroom, but the detection of the in situ formed darkroom is greatly influenced by space and a motion structure, the formed darkroom has a larger structure and occupies more space, and the detection of the existing luminescence immunoassay analyzer is mostly carried out by separately adding liquid, uniformly mixing and detecting, so that the contact frequency of the solution in the reaction cup and the outside is increased, the pollution is easy to occur, and the detection result is influenced.

Disclosure of Invention

The invention aims to overcome the defects of the traditional technology and provides an independent automatic liquid adding detection device.

The aim of the invention is achieved by the following technical measures: the utility model provides an independent automatic liquid feeding detection device which characterized in that: the utility model discloses a reaction cup translation module, darkroom detection module and automatic mixing module, including the shell, by last perpendicular liquid feeding module, reaction cup translation module, darkroom detection module and the automatic mixing module of having set gradually under to in the shell, the shell includes epitheca, mesochite and inferior valve, be provided with on the inferior valve and provide the gliding track groove of reaction cup, the one end in track groove has been seted up into the rim of a cup, and the rim of a cup has been seted up to the other end, reaction cup translation module includes along advancing the rim of a cup to falling rim of a cup reciprocating motion's pusher dog, the pusher dog is connected with the first power device of its motion of drive, the track groove is by advancing the rim of a cup to falling the rim of a cup set gradually trade the rail position, arouse mixing position in advance, arouse the detection position, take out useless liquid level and fall the cup position, automatic mixing module with it corresponds to arouse the detection position.

As a preferred scheme, the automatic blending module comprises a blending wheel and a second power device for driving the blending wheel to rotate, the blending wheel is located at a pre-excitation blending position in the track groove, and a plurality of bulges are arranged on the blending wheel along the circumferential direction.

As a preferable scheme, the vertical liquid adding module is arranged above the reaction cup translation module, and the vertical liquid adding module comprises a lifting plate and a third power device for driving the lifting plate to be close to or far away from the pusher dog.

As a preferred scheme, the lifter plate is correspondingly provided with a pre-excitation liquid needle at a pre-excitation mixing position, an excitation liquid needle is correspondingly arranged at a laser detection position, and a waste liquid needle is correspondingly arranged at a waste liquid extraction position.

As a preferred scheme, the output end of the third power device is connected with a second lead screw, the second lead screw is arranged along the vertical direction, a second nut is sleeved on the second lead screw and fixedly connected with the lifting plate, guide shafts are arranged on two sides of the second lead screw, one end of each guide shaft is fixed on the third mounting plate, and the other end of each guide shaft penetrates through the lifting plate and is connected with the middle shell.

As a preferred scheme, the lifter plate has set gradually first baffle, second baffle and third baffle along the horizontal direction, correspond on the inferior valve and be provided with first spout, second spout and third spout, first baffle slides along first spout, the second baffle slides along the second spout, the third baffle slides along the third spout.

As a preferred scheme, first spout sets up and is advancing rim of a cup department, the length of first spout is greater than the length of advancing the rim of a cup, the second spout sets up and is arousing detection position, the second spout is the setting of U type, the both sides of second spout are located arouses the both sides of detecting the position, two tip of second spout are located the inferior valve respectively, the third spout sets up and falls the rim of a cup, the length of third spout is greater than the length that falls the rim of a cup.

As a preferred scheme, the darkroom detection module comprises a photon counter corresponding to the excitation detection position, the photon counter is fixed on the lower shell, a detection port is formed in the lower shell, the photon counter is communicated with the track groove through the detection port, and the detection port corresponds to the excitation detection position.

As a preferred scheme, detection mouth department is provided with the fourth baffle, fourth baffle lower extreme is provided with the spring, the spring suit is on the guide bar, the lower extreme of fourth baffle is located the upper end of spring, the guide shaft can be followed to the fourth baffle and slided, the spring periphery still is provided with sealed shell, sealed shell is installed on the inferior valve, the bottom at the inferior valve is fixed to the one end of guide bar, and the other end is fixed on sealed shell, the both ends of fourth baffle with the sliding direction coincidence setting of second baffle is followed to the both ends of second spout.

As a preferred scheme, a cup outlet shell is further arranged at the cup falling opening and fixed on the middle shell and the lower shell, a cup outlet channel is arranged in the cup outlet shell, one end of the cup outlet channel is communicated with the cup falling opening, the other end of the cup outlet channel is provided with a cup outlet, and the cup outlet is arranged at the bottom of the cup outlet shell.

Due to the adoption of the technical scheme, compared with the prior art, the invention has the advantages that: through with perpendicular liquid feeding module, reaction cup translation module, darkroom detection module and automatic mixing module set gradually from top to bottom in the shell, can effectively reduce the volume that occupies, four modules all set up in the shell, effectively guarantee the formation of inside darkroom, and the liquid feeding to the reaction cup, the mixing, detect and draw liquid and all go on in the darkroom, stop reaction cup and external contact, avoid polluting, reach inside back automatic formation darkroom, stop light and get into, the influence of external light to the experiment has been solved from the root, ensure the accuracy of photon counter reading, detect and provide accurate data for the experiment.

The invention is further described with reference to the following figures and detailed description.

Drawings

FIG. 1 is a schematic structural diagram of a housing of an independent automatic liquid feeding detection device according to the present invention.

FIG. 2 is a schematic diagram of the internal structure of an independent automatic liquid feeding detection device according to the present invention.

FIG. 3 is a schematic structural diagram of a cuvette translation module and a vertical liquid feeding module of the apparatus for detecting an independent automatic liquid feeding according to the present invention.

FIG. 4 is a schematic structural diagram of a cuvette translation module of an independent automatic liquid feeding detection apparatus according to the present invention.

Fig. 5 is a schematic structural view of a vertical liquid adding module of the independent automatic liquid adding detection device of the invention.

FIG. 6 is a schematic diagram of a track groove structure of an independent automatic liquid feeding detection device according to the present invention.

FIG. 7 is a schematic diagram of a fourth baffle structure of the automatic liquid feeding detecting device of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

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", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Example (b): as shown in figures 1-7, an independent automatic liquid feeding detection device comprises a shell, a vertical liquid feeding module, a reaction cup translation module, a darkroom detection module and an automatic mixing module are sequentially arranged in the shell from top to bottom, the four modules are independently assembled, the four modules are assembled into a whole after the assembly is finished and then connected with a machine, the four modules are arranged along the vertical direction, compared with the prior art that the four modules are arranged along the horizontal direction, the occupied volume can be effectively reduced, the four modules are all arranged in the shell, the formation of an internal darkroom is effectively ensured, the liquid feeding, mixing, detection and liquid pumping of the reaction cup are all carried out in the darkroom, the contact of the reaction cup and the outside is avoided, the pollution is avoided, the darkroom is automatically formed after the reaction cup reaches the inside, the light entering is avoided, the influence of external light on the experiment is fundamentally solved, and the reading accuracy of a photon counter is ensured, and accurate data are provided for experimental detection.

The housing comprises an upper shell 1 at the top and a middle shell 2 in the middle and a lower shell 3 at the lower end.

As shown in fig. 2-4, a track groove 4 for sliding the reaction cup is disposed on the lower shell 3, one end of the track groove 4 is provided with a cup inlet 5, the other end is provided with a cup falling opening 6, the reaction cup translation module comprises a pusher dog 7 reciprocating along the cup inlet 5 to the cup falling opening 6, the pusher dog 7 is connected with a first power device for driving the pusher dog to move, the first power device is a first motor 8, the first motor 8 is mounted on one side of the middle shell 2 through a first mounting plate 21, an output end of the first motor 8 is connected with a first lead screw 9, the first lead screw 9 is located in the middle shell 2 and is disposed along a horizontal direction, in this embodiment, a disposition direction of the first lead screw 9 is an arrangement direction from the cup inlet 5 to the cup falling opening 6, a first nut 10 is disposed on the first lead screw 9, the first nut 10 is fixedly connected with the pusher dog 7, a first guide rail 11 facing the first lead screw 9 is further disposed on the lower shell 3, the first guide rail 11 is arranged in parallel with the first screw 9, and the first nut 10 is provided with a first slide block 22 which slides along the first guide rail 11. As shown in fig. 4, the track groove 4 is provided with an upward opening, and the track groove 4 is sequentially provided with a track changing position 12, a pre-excitation blending position 13, an excitation detection position 14, a waste liquid extraction position 15 and a cup dropping position 16 from the cup inlet 5 to the cup dropping opening 6.

As shown in fig. 2, 4 and 6, the automatic blending module includes a blending wheel 17 and a second power device for driving the blending wheel 17 to rotate, the blending wheel 17 is located at a pre-excitation blending position 13 in the track groove 4, the blending wheel 17 is provided with a plurality of protrusions along the circumferential direction, and when the blending wheel 17 rotates, the reaction cup is driven to move up and down along the track groove 4 under the action of the protrusions, so as to achieve blending of the solution in the cup. In this embodiment, second power device is second motor 18, and second motor 18 installs on inferior valve 3 through second mounting panel 19, and second motor 18 passes through belt 20 and is connected with blending wheel 17 transmission, drives blending wheel 17 and rotates, realizes the mixing.

As shown in fig. 2, 3 and 5, the vertical liquid adding module is disposed above the reaction cup translation module, the vertical liquid adding module includes a lifting plate 23 and a third power device for driving the lifting plate 23 to approach or be far away from the pusher dog 7, the third power device is a third motor 24, the third motor 24 is fixedly mounted on the upper shell 1 through a third mounting plate 25, the lifting plate 23 is correspondingly provided with a pre-excited liquid needle 26 at a pre-excited blending position 13, an excited liquid needle 27 is correspondingly disposed at a laser detection position, a waste liquid needle 45 is correspondingly disposed at a waste liquid extraction position 15, an output end of the third power device is connected with a second lead screw 28, the second lead screw 28 is disposed along a vertical direction, a second nut 29 is sleeved on the second lead screw 28, the second nut 29 is fixedly connected with the lifting plate 23, two sides of the second lead screw 28 are both provided with guide shafts 30, one end of the guide shafts 30 is fixed on the third mounting plate 25, the other end passes through the lifting plate 23 and is connected with the middle shell 2, in the embodiment, the third mounting plate 25 is fixedly connected with the middle shell 2 through the connecting rod 31, and the lifting plate 23 is driven by the third motor 24 to move up and down, so that the pre-excitation liquid needle 26 is used for adding the pre-excitation liquid into the reaction cup, the excitation liquid needle 27 is used for adding the excitation liquid into the reaction cup, and the waste liquid needle 45 is used for extracting the waste liquid in the reaction cup.

In this embodiment, as shown in fig. 2 and 5, the lifting plate 23 is sequentially provided with a first baffle 32, a second baffle 33 and a third baffle 34 along the horizontal direction, as shown in fig. 6, the lower shell 3 is correspondingly provided with a first sliding chute 35, a second sliding chute 36 and a third sliding chute 37, the first sliding chute 35 is disposed at the cup inlet 5, the length of the first sliding chute 35 is greater than that of the cup inlet 5, the first baffle 32 slides into the first sliding chute 35 under the driving of the lifting plate 23, and separates the track groove 4 from the part outside the cup inlet 5. The second chute 36 is arranged at the excitation detection position 14, the second chute 36 is in a U-shaped arrangement, two sides of the second chute 36 are located at two sides of the excitation detection position 14, two end parts of the second chute are respectively located in the lower shell 3, the second baffle 33 slides into the second chute 36 under the driving of the lifting plate 23, and the second baffle 33 completely separates the excitation detection position 14 from the rest parts of the track groove 4. The third chute 37 is arranged at the cup dropping opening 6, the length of the third chute 37 is greater than that of the cup dropping opening 6, and the third baffle 34 is driven by the lifting plate 23 to slide into the third chute 37 to separate the track groove 4 from the part outside the cup dropping opening 6.

As shown in fig. 2-4, the darkroom detection module comprises a photon counter 38 corresponding to the excitation detection position 14, the photon counter 38 is fixed on the lower shell 3, a detection port is arranged on the lower shell 3, the detection port connects the photon counter 38 with the track groove 4, corresponding to the excitation detection position 14, in this embodiment, as shown in fig. 2 and 7, a fourth baffle 39 is disposed at the detection port, a spring 40 is disposed at the lower end of the fourth baffle 39, the spring 40 is sleeved on a guide rod 41, the lower end of the fourth baffle 39 is disposed at the upper end of the spring 40, the fourth baffle 39 can slide along the guide shaft 30, a sealing shell 42 is further disposed at the periphery of the spring 40, the sealing shell 42 is mounted on the lower shell 3, the inside of the sealing shell is a closed space, one end of the guide rod 41 is fixed at the bottom of the lower shell 3, the other end of the guide rod is fixed on the sealing shell 42, the fourth baffle 39 covers the detection port under the action of the spring 40, and shields the photon counter 38. As shown in fig. 6, the length of the fourth baffle 39 is equal to that of the second chute 36, two ends of the fourth baffle 39 are located at two ends of the second chute 36, during detection, the second baffle 33 slides down along the second chute 36, when contacting with the fourth baffle 39, the fourth baffle 39 is pushed back into the sealing shell 42, the detection port is opened, the photon counter 38 is aligned to the excitation detection position 14 for reading, and is automatically closed after reading, a light-shielding environment is provided for the photon counter 38, so that the photon counter 38 is effectively protected, damage to the photon counter 38 during operation of the reaction cup and damage to the photon counter 38 by external strong light are avoided, and stability of reading photon values is ensured.

As shown in fig. 1, a cup outlet shell 43 is further arranged at the cup falling opening 6, the cup outlet shell 43 is fixed on the middle shell 2 and the lower shell 3, a cup outlet channel is arranged in the cup outlet shell 43, one end of the cup outlet channel is communicated with the cup falling opening 6, the other end of the cup outlet channel is provided with a cup outlet 44, and the cup outlet 44 is arranged at the bottom of the cup outlet shell 43. Go out cup shell 43 and both can provide out the cup passageway, provide the direction for dropping of reaction cup, can block again that light directly gets into through falling rim of a cup 6, block the back through going out cup shell 43, can pass through rim of a cup 44 and enter into the light in track groove 4 through going out the cup passageway and already weak, through the sheltering from of third baffle 34 and second baffle 33, can guarantee not to influence the reading of photon counter 38.

The reaction cup enters the track groove 4 from the cup inlet 5 to reach the rail changing position 12, the pusher 7 is positioned at the rail changing position 12 and receives the reaction cup, the first motor 8 is started, the pusher 7 and the reaction cup are driven by the first nut 10 to reach the pre-excitation blending position 13 along the track groove 4, the third motor 24 in the vertical liquid adding module drives the pre-excitation liquid needle 26 to vertically descend to the pre-excitation blending position 13 through the lifting plate 23 for sample adding, the pre-excitation liquid is added and then ascends to the original point position, the second motor 18 in the automatic blending module drives the blending wheel 17 to rotate for blending the liquid in the reaction cup, after the blending is completed, the reaction cup translation module pushes the reaction cup to the excitation detection position 14 through the pusher 7, after the pre-excitation liquid is added to the original point position, the vertical liquid adding module drives the excitation liquid needle 27 to vertically descend to the excitation detection position 14 for sample adding, during the descending process, the reaction cup is slidingly pressed to the fourth baffle 39 along the second chute 36 through the second baffle 33, the reaction cup is pressed to the lower part, the probe of the photon counter 38 leaks out, the exciting liquid needle 27 injects exciting liquid at the moment, photons are generated after injection, the photon counter 38 counts the generated photons, the third motor 24 returns to the original position after the photon counter 38 finishes the injection, a light barrier of the photon counter 38 returns to the upper part under the elastic force of a spring 40 below the light barrier, the probe of the photon counter 38 is blocked, the reaction cup translation module pushes the reaction cup to the waste liquid extraction position 15, the vertical liquid adding module descends vertically again, the liquid in the reaction cup is extracted by the waste liquid needle 45, the lifting plate 23 of the vertical liquid adding module returns to the original position, the reaction cup translation module pushes the reaction cup to the cup falling position 16, the reaction cup falls into the cup discharging shell 43 from the cup falling opening 6 and finally falls out from the cup discharging opening 44, and after the completion, the reaction cup translation module returns to the original position, so that the whole device operation process is realized.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. 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.