CN116081057A - Matrix type spliced kit for comparing performances of different reagents - Google Patents

Abstract

The invention provides a matrix-type splicing kit for performance comparison of different reagents, which includes a support mechanism, the support mechanism includes a square placement base for lifting and placing kit materials, and the top surface of the square placement base is installed There is an assembly frame, the surface of the assembly frame is provided with slots for placing test tubes, the edges of the slots for placing test tubes are provided with connecting bumps, and the surfaces of the connecting bumps are correspondingly interspersed with placement conduits. The present invention: through the provided square base and assembly frame, its main purpose is to install according to the combination of the assembly frame, and the purpose is to construct a more suitable splicing structure from the multiple reagent box placement tubes above.

Description

A matrix splicing kit for performance comparison of different reagents

technical field

The invention relates to the field of medical technology, in particular to a matrix splicing kit for performance comparison of different reagents.

Background technique

The kit refers to a box used to contain chemical reagents such as chemical components, drug residues, and virus types. Generally used by hospitals and pharmaceutical companies;

Among them, the "a splicing kit" disclosed by the application number "CN201920870653.3" is also an increasingly mature technology, which records "comprising a first kit body and a second kit body, the first kit body and the second kit body are plastic structures, the first kit body has a first kit matching surface, and at least one first kit splicing hole is opened on the first kit fitting surface, and the second reagent kit The box body has a second kit matching surface, and a second kit splicing block is arranged on the second kit fitting surface, and the second kit splicing block corresponds to the number of splicing holes of the first kit and has the same shape and position. Anastomosis, the splicing piece of the second kit is interference-fitted with the splicing hole of the first kit.Compared with the prior art, the present invention has two kit bodies, which can place both different reagents, and the two kit bodies can Spliced together, it can also be used separately. At the same time, the present invention is more compatible with the detection equipment during detection and is more convenient to use", but the kit also has the following defects in actual use:

1) Compared with the comparison document, the monitoring scheme adopted can only extract reagents for a single one of them, and then conduct detection based on an external monitoring unit, which will obviously easily lead to insufficient detection efficiency of a single reagent;

2) Moreover, the kit itself is inflexible and cannot be spliced again according to the materials of different kits, which makes the splicing of the kit itself difficult;

3) It is more difficult in the matrix splicing based on the kit, and the kits are generally spliced according to the matrix of a variety of different reagent materials, which will lead to too single matrix splicing, resulting in matrix splicing. During the sampling process of the kit itself, it is difficult, and it is impossible to compare the performance of different reagents.

Contents of the invention

The purpose of the present invention is to provide a matrix splicing kit for performance comparison of different reagents, so as to solve the problems raised by the above-mentioned background technology.

In order to achieve the above object, the present invention provides the following technical solutions: a matrix splicing kit for performance comparison of different reagents, a matrix splicing kit for performance comparison of different reagents, including support mechanism, the support mechanism includes a square placement base for lifting and placing reagent box materials, the top surface of the square placement base is equipped with an assembly frame, and the surface of the assembly frame is provided with slots for placing test tubes, so The edges of the slots for placing the test tubes are provided with connecting bumps, and the surfaces of the connecting bumps are correspondingly interspersed with placement conduits, wherein the sides of several placement conduits are provided with connecting slots in a vertical and horizontal cross.

As a preferred solution of the present invention: a telescopic displacement mechanism is installed laterally on the back edge of the square placement base, and the telescopic displacement mechanism includes a lifting seat installed on the side of the square placement base, wherein the lifting seat Both sides of the board surface are symmetrically provided with nuts.

As a preferred solution of the present invention: a connecting vertical rod is arranged in the hole of the nut, square mounting brackets are symmetrically arranged on the two side walls of the connecting vertical rod, and the square mounting brackets located in the middle area are installed in parallel. Slide push mechanism.

As a preferred solution of the present invention: the sliding push mechanism includes a hinged base arranged in the middle of both ends of the square assembly bracket, the two side walls of the hinged base are symmetrically provided with sliding struts, and the sliding struts The middle part of the sliding seat has a sliding seat, wherein the sliding displacement of the top surface of the sliding seat is provided with a slide table, and a guide rail is installed transversely on the top middle part of the slide table, and a support pad is provided on the top middle part of the guide rail, and the support pad A number of limit screw holes are provided on the board surface of the board.

As a preferred solution of the present invention: a row of batch detection mechanism is provided at the bottom of the support pad, and the batch detection mechanism includes a square support plate installed in the middle of the bottom end of the support pad, wherein the bottom of the square support plate Several sampling casings for sampling are arranged on the surface, and the bottom of the sampling casing and the placement conduit below are set by infrared sensors.

As a preferred solution of the present invention: a drive motor is fixedly installed at both corner positions of the front end of the slide table, and a drive screw is installed on the output end of the drive motor, and one end of the drive screw is connected to the front end. The square support plate transmits telescopic displacement through the screw rod and nut thread structure.

As a preferred solution of the present invention: a number of detachable strip-shaped slots are respectively opened on the top area of the square placement base, and the strip-shaped slots are slidably and buckled with the other half of the protruding end. The bottom of each independent placement conduit is equipped with a magnetic bump, and the bottom structure of the magnetic bump is magnetically adsorbed to the pad placement area at the lower end.

As a preferred solution of the present invention: the inside of the sampling sleeve is equipped with an electric negative pressure extractor for drawing reagent raw materials, and the bottom telescopic end of the electric negative pressure extractor is sealed with the internal negative pressure structure of the sampling sleeve. In communication, each independent liquid outlet located on the electric negative pressure extractor communicates inductively with an external sample analysis unit through a hose.

As a preferred solution of the present invention: the driving motor, the electric negative pressure extractor and the infrared sensor are uniformly electrically connected to the analysis sensing unit, and the analysis sensing unit is electrically connected to an external controller.

Compared with prior art, the beneficial effect of the present invention is:

1) The main purpose of the square base and assembly frame is to separate the space from the desktop, and to construct a more suitable splicing and matching kit structure for the multiple kit placement tubes above. The flexible combination and placement of test tubes is achieved, and the automatic sampling sensing method is adopted to avoid manual extraction by personnel and improve the efficiency of extraction. The sampling extraction means of the kit is set around the induction of infrared rays. Greatly improved the positioning accuracy between the extraction end and the sampling port of the kit;

2) Through the structure of the drive motor and the transmission rod shaft, the roller structure used to adjust the output end controls the position of the sampling sleeve at the bottom. According to the displacement of the front and rear ends, the sliding seat and the sliding displacement structure are set. In order to achieve the control of the position of the sampling sleeve, so that after a row is extracted, the automatic screw rod will be pulled forward and then extracted, so that a better comparison can be achieved;

3) Compared with the comparison document, this kind of scheme can achieve random splicing of kits of different specifications and types, and the technical means adopted are according to the strip groove at the bottom of the kit and the sliding of the raised unit In this way, users can combine kits of different specifications and sizes, and then splice them together, or achieve flexible conversion according to the actual sampling quantity of the kits, bringing more convenient splicing solutions.

Description of drawings

Fig. 1 is the front view structure schematic diagram of the present invention;

Fig. 2 is a schematic diagram of the back structure of the present invention;

Fig. 3 is a schematic diagram of the structure of the square placement base of the present invention;

Fig. 4 is a schematic diagram of the structure of the sliding seat of the present invention;

Fig. 5 is a schematic diagram of the structure of the placement catheter of the present invention;

Fig. 6 is a schematic diagram of the structure of the assembly frame of the present invention.

In the figure: 1. Supporting mechanism; 11. Square placing base; 12. Assembly frame; 13. Test tube placing slot; 14. Connecting bump; 15. Placement catheter; 151. Magnetic bump; 17. Pad placement area; 171. Strip groove; 172. Protruding end; 2. Telescopic displacement mechanism; 21. Lifting seat; 22. Connecting pole; 23. Square assembly bracket; 3. Slide push mechanism; 31. Hinged base; 32. Sliding strut; 33. Sliding seat; 34. Sliding table; 35. Guide rail; 36. Limit screw hole; 37. Driving motor; 4. Batch detection mechanism; 41. Square support plate ; 42. Sampling casing.

Detailed ways

The technical solutions in the embodiments of the present invention will be clearly and completely described below in conjunction with the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are only some, not all, embodiments of the present invention. Based on the embodiments of the present invention, all other embodiments obtained by persons of ordinary skill in the art without making creative efforts belong to the protection scope of the present invention.

Please refer to Figures 1-6, the present invention provides a technical solution: a matrix splicing kit for performance comparison of different reagents, including a support mechanism 1, and the support mechanism 1 includes materials for lifting and placing the kit The square placement base 11, the top surface of the square placement base 11 is equipped with an assembly frame 12, the surface of the assembly frame 12 is provided with a test tube placement slot 13, and the edge of the test tube placement slot 13 is provided with a connecting protrusion 14 The surfaces of the connecting bumps 14 are correspondingly interspersed with placing conduits 15 , and the sides of several placing conduits 15 are provided with connecting slots 16 criss-cross.

In this embodiment: the rear edge of the square placement base 11 is horizontally equipped with a telescopic displacement mechanism 2, and the telescopic displacement mechanism 2 includes a lifting seat 21 installed on the side of the square placement base 11, wherein the plate of the lifting seat 21 Both sides of the surface are symmetrically provided with nuts.

During the period, the base 11 and the lifting seat 21 are placed according to a square shape, so that they can be supported by the base and isolated from the dust above the test table, preventing bacterial dust from falling from the table top to the surface of the kit, and improving the monitoring process. accuracy.

In this embodiment: a connecting pole 22 is arranged in the hole of the nut, and square assembly brackets 23 are arranged symmetrically on the two side walls of the connecting pole 22, and the square assembly bracket 23 located in the middle area is installed in parallel with a sliding push Institution 3.

Through the provided square assembly bracket 23 and connecting pole 22, it is used to assemble according to the sliding splicing type of various connecting poles 22, splicing out the placement structure of the sliding push mechanism 3, and realizing the rapid detection of various kit reagents sampling.

In this embodiment: the sliding push mechanism 3 includes a hinged base 31 arranged in the middle of both ends of the square assembly bracket 23, the two side walls of the hinged base 31 are symmetrically provided with sliding struts 32, and the middle of the sliding struts 32 Sliding seat 33 is arranged, wherein the top surface sliding displacement of sliding seat 33 is provided with slide table 34, and the top middle part of slide table 34 is horizontally provided with guide rail 35, and the top middle part of guide rail 35 is provided with support backing plate, and the support backing plate A plurality of limit screw holes 36 are provided on the board.

Through the provided support plate and limit screw hole 36, the sliding and telescoping of the guide rail 35 is realized. The purpose of this is to realize the kit Rapid drawing and processing of internal raw liquid.

In this embodiment: a row of batch detection mechanism 4 is arranged at the bottom of the support pad, and the batch detection mechanism 4 includes a square support plate 41 installed in the middle of the bottom end of the support pad, wherein the bottom surface of the square support plate 41 is provided with Several sampling sleeves 42 are used for sampling, and the bottom of the sampling sleeves 42 and the placement conduit 15 below are set by infrared sensors.

Through the provided sampling sleeve 42 and the placement conduit 15, the placement of the conduit 15 structure is connected, so that the liquid inside the reagent box can be quickly drawn. This simple process is based on the fact that the infrared sensor first senses the sampling sleeve 42. Achieved prior positioning.

In this embodiment: the two corners of the front end of the sliding table 34 are fixedly installed with a drive motor 37, and the output end of the drive motor 37 is equipped with a drive screw. The telescopic displacement is transmitted through the screw rod and nut thread structure.

Through the provided driving screw and the square support plate 41, the threaded driving of the driving screw is achieved, so that the structure for controlling the front end to draw liquid can move forward and backward, and analyze one by one individually after initially drawing a row of reagent solutions.

In this embodiment: the top area of the square placement base 11 is also provided with several detachable strip-shaped slots 171, which slide and buckle with the other half of the raised end 172. A magnetic bump 151 is mounted on the bottom of each independent placement conduit 15 , and the bottom structure of the magnetic bump 151 is magnetically adsorbed to the pad placement area 17 at the lower end.

The purpose of this is to solve the problem that only one of the kits can be sampled and tested in the comparison file. Instead, the magnetic adsorption function is used to accurately place the bottoms of multiple kits into various slots. In order to prevent accidents in the extraction of the extraction end and the independent kit caused by the machine during sampling.

In this embodiment: the inside of the sampling sleeve 42 is provided with an electric negative pressure extractor 43 for drawing reagent raw materials, and the telescopic end of the bottom of the electric negative pressure extractor 43 is in sealing communication with the internal negative pressure structure of the sampling sleeve 42. Each independent liquid outlet located on the electric negative pressure extractor 43 is inductively communicated with an external sample analysis unit through a hose.

In this embodiment: the driving motor 37, the electric negative pressure extractor 43 and the infrared sensor are uniformly electrically connected to the analysis sensing unit, and the analysis sensing unit is electrically connected to an external controller.

It is convenient to realize the programmed control of various power consumption structures.

In specific use, the first step: first, the user needs to take out a large number of verified kits;

Step 2: Place the kit:

According to the placement of the kits, the user will take out a large number of kits in batches and then place them on the surface of various connection bumps 14 in sequence, and then the user will place the base 11 according to each independent detachable square, corresponding to the test tubes. The slots 13 are classified to splicing and setting the positions of multiple rows of catheters 15 together, so that the performance comparison of different reagents of the same kind can be monitored in batches according to the needs. The vertical sliding of the vertical rod 22 ensures that the position of the sampling sleeve 42 is adjusted to the top of the connecting slot 16, and then the user determines the driving motor 37, which is driven by the output end of the driving motor 37. At this time, the screw rod at the transmission end realizes rotation , when the screw mandrel rotates, it pushes the position of the guide rail 35 in the middle to realize the front displacement;

Step 3: Take a sample inside the kit:

Combined with the extraction structure, when the pipe fitting structure at the lower end is touched, the extraction is realized. After the extraction is completed, the various sampling conduits at the bottom are disassembled according to the matrix splicing, so as to realize liberalization according to the number of samples of different specifications. stitching;

Step 4: Solve the problems pointed out in the comparison documents: the kit tubes are easy to fall and difficult to compare:

In addition, in order to solve the problem of splicing and sorting different types of reagent kits in batches, this type of technology is adopted in this scheme: first, they are classified according to the number of different reagent kits, and secondly, personnel need to place the catheter 15 around the magnetic bump 151 The bottom is placed into the connection slot 16 by magnetic attraction, according to the number of placement, and then according to the sliding splicing between the strip groove 171 and the raised end 172, so that two adjacent side-by-side structures can be spliced together, so that According to different types of kits, different row structures can be combined, and the detection data can be compared between rows.

The content that is not described in detail in this description belongs to the prior art known to those skilled in the art. Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still implement the foregoing Modifications to the technical solutions recorded in the examples, or equivalent replacements for some of the technical features, within the spirit and principles of the present invention, any modifications, equivalent replacements, improvements, etc., shall be included in the scope of protection of the present invention within.

Claims (9)

1. The utility model provides a matrix concatenation formula kit for different kinds of reagent performance are compared, includes supporting mechanism (1), its characterized in that, supporting mechanism (1) is including being used for lifting square base (11) of placing the kit material, square top surface mounting who places base (11) has assembly jig (12), slotting (13) have been seted up to the surface distribution of assembly jig (12), slotting (13) are placed to the test tube's slot position edge is provided with connecting lug (14), connecting lug (14)'s surface all corresponds the interlude is equipped with places pipe (15), wherein a plurality of the avris crisscross of placing pipe (15) is equipped with connecting slot (16).

2. The matrix splice kit for performance comparison of different types of reagents according to claim 1, wherein: the telescopic displacement mechanism (2) is transversely mounted on the edge of the back face of the square placement base (11), the telescopic displacement mechanism (2) comprises a supporting and lifting seat (21) mounted on the side of the square placement base (11), and nuts are symmetrically arranged on two sides of the surface of the board of the supporting and lifting seat (21).

3. A matrix splice kit for performance comparison of heterogeneous reagents according to claim 2, wherein: the connecting vertical rods (22) are arranged in the hole sites of the nuts, square assembly brackets (23) are symmetrically arranged on the edges of two side walls of the connecting vertical rods (22), and the square assembly brackets (23) located in the middle area are parallelly provided with the sliding pushing mechanism (3).

4. A matrix splice kit for performance comparison of heterogeneous reagents according to claim 3, wherein: the sliding pushing mechanism (3) comprises a hinged base (31) arranged at the middle parts of two ends of a square assembly bracket (23), sliding supporting rods (32) are symmetrically arranged on two side walls of the hinged base (31), sliding seats (33) are arranged in the middle of the sliding supporting rods (32) in a sliding mode, sliding tables (34) are arranged on the top surfaces of the sliding seats (33) in a sliding displacement mode, guide rails (35) are transversely arranged at the middle parts of the tops of the sliding tables (34), supporting base plates are arranged at the middle parts of the tops of the guide rails (35), and a plurality of limiting screw holes (36) are formed in the surfaces of the supporting base plates.

5. The matrix splice kit for performance comparison of heterogeneous reagents of claim 4, wherein: a row of batch detection mechanism (4) is established to the bottom of supporting the backing plate, batch detection mechanism (4) are including installing square fagging (41) that set up in supporting backing plate bottom middle part, wherein the bottom surface of square fagging (41) all is provided with sample sleeve pipe (42) that a plurality of is used for the sample, place pipe (15) of the bottom of sample sleeve pipe (42) and below are through infrared inductor response setting.

6. The matrix splice kit for performance comparison of heterogeneous reagents of claim 4, wherein: the driving device is characterized in that driving motors (37) are fixedly arranged at two side angle positions of the forefront end of the sliding table (34), driving screw rods are arranged at the output ends of the driving motors (37) in a transmission mode, and one ends of the driving screw rods and square supporting plates (41) arranged at the front end of the driving screw rods are in transmission telescopic displacement through screw rods and nut thread structures.

7. The matrix splice kit for performance comparison of different types of reagents according to claim 6, wherein: the top area of the square placement base (11) is also provided with a plurality of detachable strip-shaped grooves (171), the strip-shaped grooves (171) are in sliding buckling connection with the other half of the protruding ends (172), the bottoms of the independent placement guide pipes (15) are respectively provided with a magnetic lug (151), and the bottom structures of the magnetic lugs (151) are magnetically adsorbed with the pad connection placement areas (17) at the lower ends.

8. The matrix splice kit for performance comparison of heterogeneous reagents of claim 5, wherein: the inside of sampling sleeve (42) is built-in with electric negative pressure extractor (43) that are used for drawing reagent raw materials, the flexible end in bottom of electric negative pressure extractor (43) communicates with each other with the inside negative pressure structure seal of sampling sleeve (42), is located each independent liquid outlet end of electric negative pressure extractor (43) is through hose and external sample analysis unit response intercommunication.

9. The matrix splice kit for performance comparison of different types of reagents according to claim 6, wherein: the driving motor (37), the electric negative pressure extractor (43) and the infrared sensor are electrically connected with the uniform analysis sensing unit, and the analysis sensing unit is electrically connected with the external controller.

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