CN210294040U - Analysis container - Google Patents

Abstract

The utility model provides an analysis container, analysis container is used for holding the luminous reactant that awaits measuring, analysis container includes container body and detection container, the container body has detection container seat, detection container is located in the detection container seat; the detection container is provided with a cavity for accommodating luminous reactants, the inner cavity wall of the cavity is provided with a reflecting material, and light emitted by the luminous reactants is reflected back to the cavity through the inner cavity wall after being directed to the inner cavity wall of the detection container. The utility model provides an analysis container, it is not good to have avoided among the prior art analysis container light-resistant effect, reduces the problem of the accuracy that detects.

Description

Analysis container

Technical Field

The utility model relates to a medical treatment field of detection especially relates to an analysis container.

Background

The analysis container used for specific analysis of the objects to be detected, such as human blood, in the prior art has the defects of poor light-shielding effect, influence on the detection effect of the analysis container and reduction in the detection accuracy.

SUMMERY OF THE UTILITY MODEL

The utility model provides an analysis container, it is not good to have avoided among the prior art analysis container light-resistant effect, reduces the problem of the accuracy that detects.

The utility model provides an analysis container, analysis container is used for holding the luminous reactant that awaits measuring, analysis container includes container body and detection container, the container body has detection container seat, detection container is located in the detection container seat; the detection container is provided with a cavity for accommodating luminous reactants, the inner cavity wall of the cavity is provided with a reflecting material, and light emitted by the luminous reactants is reflected back to the cavity through the inner cavity wall after being directed to the inner cavity wall of the detection container.

Wherein, the outer cavity wall of the cavity is provided with a shading material, and the shading material is used for isolating external light.

The cavity wall of the cavity is of a two-layer structure, and the inner cavity wall and the outer cavity wall are stacked to form the cavity wall of the cavity.

The detection container is embedded in the detection container seat and surrounded by the container body, and the container body is provided with a light shielding material which is used for isolating external light.

Wherein the shading material is black in color.

The detection container and the container body are integrally formed, and the cavity of the detection container is an accommodating cavity with an opening formed in the container body.

The inner cavity wall is provided with a reflecting material layer, or the inner cavity wall is made of a reflecting material, and light emitted by the luminous reactant is emitted to the inner cavity wall and is reflected back to the cavity through the reflecting material.

The surface of the container body, which has the same direction with the opening of the detection container, is provided with a groove around the opening in a concave manner, and the detection device is clamped with the groove to seal the detection container.

The analysis container comprises a flexible convex part, the flexible convex part is arranged around the groove peripheral wall of the groove, and when the detection device is clamped with the groove, the flexible convex part is in sealing and abutting contact with the detection device so as to fill a gap between the groove and the detection device.

The container body is further provided with a reagent cavity and a sample cavity, and the reagent cavity and the sample cavity are used for containing a reagent and a sample respectively.

The container body is provided with a connecting groove, and the connecting groove is used for being clamped with a mechanism for carrying the analysis container.

The utility model discloses a set up the detection container on the analysis container, luminous reactant holds in the cavity that detects the container, the light that luminous reactant sent is emitted to behind the inner chamber wall of cavity, warp inner chamber wall reflects back in the cavity to avoid the light that luminous reactant sent to emit and detect the container and lose, guarantee the light-resistant effect, improved the collection rate of photon, thereby improve the accuracy that detects.

Drawings

In order to more clearly illustrate the technical solution of the present invention, the drawings required for the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an analysis vessel provided in an embodiment of the present application;

FIG. 2 is a schematic view of an exploded structure of the analysis vessel provided in FIG. 1;

fig. 3 is a schematic structural view of another embodiment of the analysis vessel provided in fig. 1.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1-2, fig. 1 is a schematic structural diagram of an analysis container 100, the analysis container 100 is used for accommodating a luminescent reactant to be detected, the analysis container 100 includes a container body 10 and a detection container 20, the container body 10 has a detection container seat 11, and the detection container 20 is located in the detection container seat 11; the detection container 20 is provided with a cavity 21 for accommodating luminous reactants, the inner cavity wall 22 of the cavity 21 is provided with a reflective material, and light emitted by the luminous reactants is reflected back to the cavity 21 through the inner cavity wall 22 after being directed to the inner cavity wall 22 of the detection container 20.

When the luminescent reactant in the detection container 20 is detected, a detection device (not shown) is opposite to the detection container 20, and seals the opening of the detection container 20 to detect the luminescent reactant, and the detection device acquires the number of photons generated in the luminescent reactant, so as to obtain a detection result through conversion.

The utility model discloses a set up detection container 20 on analysis container 100, luminous reactant holds in detection container 20's cavity 21, the light that luminous reactant sent is emitted to behind cavity 21's the inner chamber wall 22, warp inner chamber wall 22 reflects back in the cavity 21 to the light that avoids luminous reactant to send is emitted and is detected container 20 or is absorbed and the loss by the inner chamber wall 22 of being detected container 20, provides strict light-resistant environment for detection device detects, guarantees the light-resistant effect, has improved the collection rate of photon, thereby improves the accuracy that detects.

As shown in fig. 1, the container body 10 is a strip-shaped body, the container body 10 has a top surface 12, and the detection container holder 11 is formed in the top surface 12 in a recessed manner. The container body 10 is further provided with a reagent cavity 13 and a sample cavity 14, specifically, the reagent cavity 13 and the sample cavity 14 are formed on the top surface 12 at intervals in a concave manner, and the detection container seat 11, the reagent cavity 13 and the sample cavity 14 are sequentially arranged at intervals. In this embodiment, the reagent chamber 13 and the sample chamber 14 are used for accommodating a reagent and a sample, respectively. The number of the reagent chambers 13 can be set according to actual needs. When the detection is performed, the reagent in the reagent cavity 13 and the sample in the sample cavity 14 are transferred to the detection container 20, then the sample added into the detection container 20 is incubated, after the incubation, the unreacted waste liquid in the detection container 20 is sucked out, and the reactant which is reacted is left in the detection container 20, and then the excitation liquid is injected into the detection container 20, and the light emitting condition of the reactant is detected. The detection container seat 11 is used for accommodating the detection container 20, the shape of the detection container 20 is the same as that of the detection container seat 11, so that the detection container 20 is tightly attached to the detection container seat 11 when being installed on the detection container seat 11, heat can be uniformly and quickly transferred to the detection container 20 from the container body 10 in the incubation process of the detection container 20, the incubation effect of reactants in the detection container 20 is better, the reactants react more fully, and more accurate experimental results are obtained. Of course, in other embodiments, the container body 10 is not provided with a sample chamber 14.

The container body 10 and the detection container 20 have the same surface facing the opening, and a groove 16 is recessed around the opening, that is, the top surface 12 has a groove 16 recessed around the opening, and the detection device is engaged with the groove 16 to seal the detection container 20. Specifically, detection device includes connecting portion, and is right as detection device when detecting the luminous condition of the reactant in the detection container 20 detects, connecting portion stretch into recess 16 and with recess 16 block to guarantee detection device when detecting the luminous condition of reactant detection device with cavity 21 forms inclosed space, in other words, outside light can't pass through detection device with get into between the cavity 21 detection device with in the space that cavity 21 formed, in order to guarantee strict light-resistant environment, avoid ambient light to the influence of testing result, improve the collection efficiency of photon, thereby the testing result is more accurate.

Further, the analysis container 100 includes a flexible protrusion (not shown) disposed around the groove peripheral wall of the groove 16, and when the detection device is engaged with the groove 16, the flexible protrusion and the detection device are in sealing contact with each other to fill a gap between the groove 15 and the detection device. This application is through setting up flexible convex part, has airproofed detection device with space between the cavity 21 further avoids the influence of ambient light to the testing result, improves the collection efficiency of photon to the testing result is more accurate.

The vessel body 10 is provided with a connecting groove 15, and the connecting groove 15 is used for engaging with a mechanism for transporting the analysis vessel 100. In this embodiment, the connection groove 15 is concavely disposed in the middle of the top surface 12, so as to ensure that the mechanism for carrying the analysis container 100 carries the analysis container 100, and therefore, the analysis container 100 is not easy to drop when being carried, so that the connection groove 15 and the mechanism for carrying the analysis container 100 are ensured to be clamped stably, the whole detection process is ensured to be smoothly performed, and the detection efficiency is improved.

The analysis container 100 further comprises a sealing film (not shown) disposed on the top surface 12 for sealing the openings of the detection container 20, the reagent chamber 13 and the sample chamber 14, thereby preventing contaminants from entering the detection container 20, the reagent chamber 13 and the sample chamber 14, so that the contaminants do not affect the detection result, and simultaneously, the reagent and the sample can be conveniently stored, thereby ensuring the accuracy of the detection result.

The detection container 20 and the container body 10 include, but are not limited to, the following embodiments:

in one embodiment, as shown in fig. 1-2, the detection container 20 is embedded in the detection container holder 11 and surrounded by the container body 10, in other words, the detection container 20 and the container body 10 are two independent bodies, the detection container 20 is fixed in the container body 10, and the specific detection container 20 is fixed in the detection container holder 11 of the detection body. In this embodiment, the detection container 20 is fixed in the detection container holder 11 by interference fit. Of course, in other embodiments, the detection container 20 is fixed in the detection container holder 11 by a heat transfer colloid. The detection container 20 and the detection container holder 11 can also be fixed in other fixing manners, as long as the detection container 20 and the detection container holder 11 are tightly attached.

The inner cavity wall 22 of the cavity 21 is made of a reflective material, specifically, the inner cavity wall 22 is made of a reflective material, that is, the detection container 20 is made of a material having a reflective light, and the light emitted by the luminescent reactant is directed to the inner cavity wall 22 and reflected back into the cavity 21 through the reflective material. Optionally, the reflective material is an opaque monochromatic material, such as a blue material, overlapped with the luminescent spectrum of the reactant, so as to ensure that light emitted by the luminescent reactant is reflected back into the cavity 21 through the inner cavity wall 22 after being directed to the inner cavity wall 22 of the cavity 21, ensure that the light emitted by the reactant is effectively reflected back into the cavity 21, improve the collection rate of photons, and further improve the accuracy of detection. Of course, in other embodiments, the reflective material may also be white. The inner cavity wall 22 may further be provided with a reflective material layer, in other words, the detection container 20 may be made of a material with any color, the inner cavity wall 22 may be provided with an emitting material layer for reflecting light emitted by the luminescent material, the reflective material layer may be connected to the inner cavity wall 22 through an adhesive layer, optionally, the reflective material layer is made of a reflective material, the reflective material may be a white or opaque monochromatic material with overlapped luminescent spectrum segments of the luminescent reactant, the light emitted by the luminescent reactant is directed to the inner cavity wall 22, and is reflected back to the cavity 21 through the reflective material, so that the collection rate of photons is improved, and the accuracy of detection is further improved.

The container body 10 has a light blocking material for blocking external light. Specifically, vessel 10 is made by having the shading material, and is optional, the colour of shading material is black, and black shading material has better light-shielding effect to prevent that external environment's light from passing through get into in vessel 10 among the detection vessel 20, avoid the influence of ambient light to the testing result, improve the collection efficiency of photon, thereby the testing result is more accurate. In other embodiments, the inner surface of the detection container holder 11 is provided with a light shielding material layer, or the outer surface of the container body 10 is provided with a light shielding material layer, optionally, the light shielding material layer is black in color, so that a better light shielding effect is achieved.

In other embodiments, the cavity wall of the cavity 21 is a two-layer structure, and the inner cavity wall 22 and the outer cavity wall are stacked to form the cavity wall of the cavity 21. The inner cavity wall 22 has a reflective material, and the outer cavity wall of the cavity 21 has a light blocking material for isolating external light. Specifically, the outer cavity wall is made of a light shielding material, optionally, the color of the light shielding material is black, and the black light shielding material has a better light shielding effect, so that light of an external environment is prevented from entering the inner cavity wall 22 through the outer cavity wall, the influence of the ambient light on a detection result is avoided, the photon collection efficiency is improved, and the detection result is more accurate.

In another embodiment, as shown in fig. 3, different from the previous embodiment, the detection container 20 is integrally formed with the container body 10, the cavity 21 of the detection container 20 is an accommodating cavity with an opening formed in the container body 10, in other words, the container body 10 is not provided with a detection container seat, and the detection container 20 is an accommodating cavity recessed in the top surface 12. The container body 10 is made of a material for reflecting light, optionally, the reflecting material is an opaque monochromatic material, such as a blue material, overlapped with a luminous spectrum section of the reactant, so as to ensure that light emitted by the luminous reactant is reflected back into the cavity 21 through the inner cavity wall 22 after being directed to the inner cavity wall 22 of the cavity 21, ensure that the light emitted by the reactant is effectively reflected back into the cavity 21, improve the collection rate of photons, and further improve the detection accuracy, and meanwhile, the detection container 20 and the container body 10 are integrally formed, so that the manufacturing process of the analysis container 100 is simpler, and the production efficiency of the analysis container 100 is improved. Of course, in other embodiments, the reflective material may also be white. Or, container body 10 all can be made by the material of arbitrary shading colour, the inner chamber wall 22 of cavity 21 is equipped with the reflecting material layer, the reflecting material layer is made by reflecting material, the reflecting material can be white or the luminous spectral band of reactant overlap's opaque monochromatic material, the light that luminous reactant sent is to inner chamber wall 22, the warp reflecting material reflects back in the cavity 21, has improved the collection rate of photon, and then has improved the accuracy of detection.

The utility model discloses a set up on analysis container 100 and detect container 20, luminous reactant holds in the cavity 21 that detects container 20, the light that luminous reactant sent is emitted to behind the inner chamber wall 22 of cavity 21, warp inner chamber wall 22 reflects back in the cavity 21 to avoid the light that luminous reactant sent to emit and detect container 20 and the loss, guarantee the light-resistant effect, improved the collection rate of photon, thereby improve the accuracy that detects.

The embodiments of the present invention have been described in detail, and the principles and embodiments of the present invention have been explained herein using specific embodiments, and the above description of the embodiments is only used to help understand the method and the core idea of the present invention; meanwhile, for the general technical personnel in the field, according to the idea of the present invention, there are changes in the specific implementation and application scope, to sum up, the content of the present specification should not be understood as the limitation of the present invention.

Claims (11)

1. An analysis vessel for containing a luminescent reactant to be detected, characterized in that the analysis vessel comprises a vessel body having a detection vessel seat in which the detection vessel is located, and a detection vessel; the detection container is provided with a cavity for accommodating luminous reactants, the inner cavity wall of the cavity is provided with a reflecting material, and light emitted by the luminous reactants is reflected back to the cavity through the inner cavity wall after being directed to the inner cavity wall of the detection container.

2. The analysis vessel of claim 1, wherein the outer chamber wall of the chamber has a light blocking material for blocking external light.

3. The analysis vessel of claim 2, wherein the walls of the chamber are of two-layer construction, the inner and outer chamber walls overlying the walls of the chamber.

4. The analysis container according to claim 1, wherein the detection container is embedded in the detection container holder and surrounded by the container body, and the container body has a light shielding material for shielding external light.

5. An analysis vessel according to any of claims 2 to 4, wherein the light-blocking material is black in colour.

6. The analysis container of claim 1, wherein the detection container is integrally formed with the container body, and the cavity of the detection container is a receiving cavity with an opening formed in the container body.

7. An analysis vessel according to any of claims 1 to 4, wherein the inner chamber wall is provided with a layer of reflective material or is made of a reflective material, light emitted by the luminescent reagent being directed towards the inner chamber wall and reflected back into the chamber via the reflective material.

8. The analysis container according to claim 7, wherein a recess is provided around the opening on a surface of the container body facing the same direction as the opening of the detection container, and the detection device is engaged with the recess to close the detection container.

9. The analysis container according to claim 8, wherein the analysis container comprises a flexible projection provided around a groove peripheral wall of the recess, the flexible projection sealingly abutting the detection means to fill a gap between the recess and the detection means when the detection means is engaged with the recess.

10. The analysis container of claim 1, wherein the container body further comprises a reagent chamber and a sample chamber, the reagent chamber and the sample chamber being configured to hold a reagent and a sample, respectively.

11. The analysis container of claim 1, wherein the container body is provided with an attachment slot for engaging with a mechanism for handling the analysis container.

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