CN219777641U - Automatic detector for food industry - Google Patents

Abstract

The utility model relates to an automatic detector for the food industry, which comprises a machine table, a rear vertical frame, a detection table, a reagent conveying component, a plurality of reaction detection tanks, a sample positioning component, a triaxial movement component and a sampling needle, wherein the reaction detection tanks comprise reaction tanks internally provided with reaction chambers, magnetic stirring rods and glucose detection sensors which are placed in the reaction tanks, and magnetic stirrers which are arranged on the machine table and used for driving the magnetic stirring rods, sample injection holes which are convenient for the insertion of the sampling needle are arranged at the top of the reaction tanks, and liquid inlet holes and liquid outlet holes which are connected with the reagent conveying component are arranged on the side surfaces of the reaction tanks. The three-axis motion assembly is used for driving the sampling needle to automatically extract the sample in the sample tube into the reaction detection pool for detection, and the reagent is quantitatively sent into the reaction detection pool through the reagent conveying assembly, so that automatic test is realized, the detection efficiency is high, and particularly, the large-scale detection in the industrial industry is realized.

Description

Automatic detector for food industry

Technical Field

The utility model relates to a material conversion rate device, in particular to an automatic detector for the food industry.

Background

The food industry provides the food types that mankind is richer, and it makes the food more easily obtain, and food is more abundant, can customize food according to customer's demand, and each material content accords with relevant standard after the food of same batch is accomplished to the production for the food has better taste, safer, and the nutrition accords with the standard. In order to solve the problems, the nutrient substances in the food are required to be detected in the food production process, the existing detection mode is usually manually sampled and then put into a test tube for detection, the whole detection mode is controlled by personnel, the detection efficiency is low, and the detection method is not suitable for occasions needing a large amount of detection in the food industry.

Disclosure of Invention

In view of the shortcomings of the prior art, it is an object of the present utility model to provide an automated detector for the food industry.

The technical scheme adopted for solving the technical problems is as follows: an automatic detector for food industry comprises a machine table, a rear vertical frame arranged on the rear side of the top surface of the machine table, a detection table arranged on the top surface of the machine table on the front side of the rear vertical frame, a reagent conveying component arranged on the top surface of the machine table, a plurality of reaction detection tanks arranged on the rear side of the detection table, a sample positioning component arranged on the detection table and a triaxial movement component arranged on the rear vertical frame, a sampling needle arranged on the triaxial movement component, wherein the reaction detection tanks comprise a reaction tank with a reaction cavity, a magnetic stirring rod and a glucose detection sensor arranged in the reaction tank, a magnetic stirrer arranged on the machine table and used for driving the magnetic stirring rod, a sample injection hole convenient for inserting the sampling needle is arranged at the top of the reaction tank, and a liquid inlet and a liquid outlet connected with the reagent conveying component are arranged on the side of the reaction tank.

Preferentially, the sample positioning component comprises a positioning cavity with an upward opening, a radiating fin arranged at the bottom of the positioning cavity, a semiconductor refrigerating fin arranged at the top of the radiating fin and a reagent basket arranged in the positioning cavity, wherein the refrigerating surface of the semiconductor refrigerating fin is positioned at the bottom of the positioning cavity.

Preferably, the heat sink is provided with a heat dissipation fan for dissipating heat from the heat sink.

Preferably, the reagent conveying component comprises a conveying frame and a metering pump arranged on the conveying frame, and an inlet and an outlet of the metering pump are respectively connected with the reagent container and the reaction tank.

Preferentially, a cleaning cavity with an opening at the top is arranged on the detection table, and a cleaning liquid inlet and outlet hole is arranged on the side face of the cleaning cavity.

Preferentially, the reagent basket comprises a sample rack, a cover plate arranged at the top of the sample rack, and a handle arranged on the cover plate, wherein a test tube hole for facilitating insertion of a sample test tube is formed in the cover plate, and the cover plate is used for covering the top opening of the positioning cavity.

Preferably, the reaction tank is provided with an overflow port.

Preferentially, the triaxial motion assembly comprises an X-axis sliding rail horizontally arranged at the top of the rear vertical frame, an X-axis sliding seat in sliding fit with the X-axis sliding rail, a Y-axis sliding rail horizontally arranged on the X-axis sliding seat, a Y-axis sliding seat in sliding fit with the Y-axis sliding rail, a Z-axis sliding rail vertically arranged on the Y-axis sliding seat and a Z-axis sliding seat in sliding fit with the Z-axis sliding rail, the sampling needle is arranged on the Z-axis sliding seat, an X-axis driving synchronous belt group is arranged on the rear vertical frame, the X-axis sliding seat is connected with the X-axis driving synchronous belt group, a Y-axis driving screw assembly is arranged on the X-axis sliding seat, the X-axis driving synchronous belt group is used for driving the X-axis sliding seat to horizontally slide left and right, the Y-axis driving screw assembly is used for driving the Y-axis sliding seat to horizontally slide back and forth, and the Z-axis driving screw assembly is used for driving the Z-axis sliding seat to vertically move.

The beneficial effects of the utility model are as follows: the three-axis motion assembly is used for driving the sampling needle to automatically extract the sample in the sample tube into the reaction detection pool for detection, and the reagent is quantitatively sent into the reaction detection pool through the reagent conveying assembly, so that automatic test is realized, the detection efficiency is high, and particularly, the large-scale detection in the industrial industry is realized.

Drawings

The utility model will be further described with reference to the drawings and examples.

Fig. 1 is a schematic perspective view of the whole of the present utility model.

Fig. 2 is a schematic perspective view of a sample positioning assembly of the present utility model.

FIG. 3 is a schematic perspective view of a reaction detection cell of the present utility model.

FIG. 4 is a schematic cross-sectional view of a reaction cell of the present utility model.

In the drawings, 1 part of the machine table, 2 parts of the detection table, 3 parts of the rear vertical frame, 4 parts of the reagent conveying assembly, 41 parts of the conveying frame, 42 parts of the metering pump, 5 parts of the X-axis sliding rail, 6.X parts of the driving synchronous belt group, 7.Y parts of the sliding seat, 8.Y parts of the driving screw rod assembly, 9.X parts of the sliding seat, 10 parts of the Y-axis sliding rail, 11 parts of the Z-axis sliding rail, 12 parts of the sampling needle, 13 parts of the sample positioning assembly, 14 parts of the Z-axis sliding seat, 15 parts of the driving screw rod assembly, 16 parts of the sample injection hole, 17 parts of the cooling fin, 18 parts of the positioning cavity, 19 parts of the reaction tank, 20 parts of the overflow hole, 21 parts of the liquid outlet hole, 22 parts of the cooling fan, 23 parts of the semiconductor cooling fin, 24 parts of the reagent basket, 241 parts of the sample frame, 242 parts of the cover plate, 243 parts of the test tube hole, 244 parts of the handle, 25 parts of the cleaning cavity, 26 parts of the magnetic stirrer, 27 parts of the liquid inlet hole, 28 parts of the glucose detection sensor and 29 parts of the magnetic stirring rod.

Description of the embodiments

The present utility model will now be described in detail with reference to the drawings and the specific embodiments thereof, wherein the exemplary embodiments and the description are for the purpose of illustrating the utility model only and are not to be construed as limiting the utility model.

Examples

Referring to fig. 1, an automatic detector for food industry includes a machine 1, a rear stand 3 disposed at the rear side of the top surface of the machine 1, a detection table 2 disposed at the top surface of the machine 1 at the front side of the rear stand 3, a reagent conveying component 4 disposed at the top surface of the machine 1, a plurality of reaction detecting tanks disposed at the rear side inside the detection table 2, a sample positioning component 13 disposed at the front side of the reaction detecting tank on the detection table 2, a triaxial motion component disposed on the rear stand 3, a sampling needle 12 disposed on the triaxial motion component, and a reaction tank 19 including a reaction chamber 30 disposed therein, a magnetic stirring rod 29 and a glucose detecting sensor 28 disposed in the reaction tank 19, a magnetic stirrer 26 disposed on the machine 1 for driving the magnetic stirring rod 29, a sample inlet hole 21 disposed at the top of the reaction tank 19 for facilitating insertion of the sampling needle 12, and a liquid inlet hole 27 connected with the reagent conveying component 4 disposed at the side of the reaction tank 19.

Referring to fig. 2, the sample positioning assembly 13 includes a positioning cavity 18 with an upward opening, a heat sink 17 disposed at the bottom of the positioning cavity 18, a semiconductor cooling plate 23 disposed at the top of the heat sink 17, and a reagent basket 24 disposed in the positioning cavity 18, wherein a cooling surface of the semiconductor cooling plate 23 is disposed at the bottom of the positioning cavity 18. The semiconductor refrigeration piece 23 is utilized to provide proper temperature for the positioning cavity 18, so that the sample is at proper temperature before reaction, the detection precision is improved, and the whole structure is simple.

Referring to fig. 1, the heat sink 17 is provided with a heat dissipating fan 22 for dissipating heat from the heat sink 17, so as to prevent heat from being accumulated on the heat sink 17 and further improve the efficiency of the semiconductor refrigerating fin 23.

Referring to fig. 1, the reagent conveying assembly 4 includes a conveying frame 41 and a metering pump 42 disposed on the conveying frame 41, wherein an inlet and an outlet of the metering pump 42 are respectively connected with the reagent container and the reaction tank 19, and the metering pump 42 is used for accurately and quantitatively providing the detection reagent, so that the accuracy is improved and the waste of the reagent is reduced.

Referring to fig. 1, the detecting table 2 is provided with a cleaning cavity 25 with an opening at the top, and a cleaning solution inlet and outlet hole (not shown in the figure) is formed on the side surface of the cleaning cavity 25, so as to clean the residue in the sampling needle 12, and improve the detecting precision.

Referring to fig. 2, the reagent basket 24 includes a sample rack 241, a cover plate 242 disposed on the top of the sample rack 241, and a handle 244 disposed on the cover plate 242, wherein a test tube hole 243 for facilitating insertion of a sample test tube is formed in the cover plate 242, and the cover plate 242 is used for covering the top opening of the positioning cavity 18, so as to facilitate taking and placing a plurality of sample test tubes at a time, and facilitate taking and placing by personnel or a mechanical arm.

Referring to fig. 3, in order to prevent the liquid from overflowing the reaction tank 19, an overflow port 20 is provided on the reaction tank 19.

Referring to fig. 1, the three-axis motion assembly includes an X-axis sliding rail 5 horizontally disposed on top of the rear vertical frame 3, an X-axis sliding seat 9 slidably engaged with the X-axis sliding rail 5, a Y-axis sliding rail 10 horizontally disposed on the X-axis sliding seat 9, a Y-axis sliding seat 7 slidably engaged with the Y-axis sliding rail 10, a Z-axis sliding rail 11 vertically disposed on the Y-axis sliding seat 7, and a Z-axis sliding seat 14 slidably engaged with the Z-axis sliding rail 11, the sampling needle 12 is disposed on the Z-axis sliding seat 14, an X-axis driving synchronous belt group 6 is disposed on the rear vertical frame 3, the X-axis sliding seat 9 is connected with the X-axis driving synchronous belt group 6, a Y-axis driving screw assembly 8 is disposed on the X-axis sliding seat 9, a Z-axis driving screw assembly 15 is disposed on the Y-axis sliding seat 7, the X-axis driving synchronous belt group 6 is used for driving the X-axis sliding seat 9 to horizontally slide left and right, the Y-axis driving screw assembly 8 is used for driving the Y-axis sliding seat 7 to horizontally slide back and forth, and the Z-axis driving screw assembly 15 is used for driving the Z-axis driving screw assembly 14 to move up and down. The triaxial motion assembly can realize the movement of the sampling needle 12 in a three-dimensional space, realize the suction and injection of a sample and the cleaning of the sampling needle 12, and is convenient for automatic operation.

During operation, a worker places the reagent basket 24 filled with the sample test tube in the positioning cavity 18, the sampling needle 12 stretches into the sample test tube under the drive of the triaxial moving assembly to absorb a certain amount of sample, the sampling needle 12 after absorbing the sample injects the sample into the reaction tank 19 under the drive of the triaxial moving assembly, the metering pump 42 starts to work to inject the reagent into the reaction tank 19 according to the set brightness, the sampling needle 12 moves into the cleaning cavity 25 under the drive of the triaxial moving assembly to repeatedly throughput cleaning liquid to clean the sampling needle 12, meanwhile, the magnetic stirrer 26 works to drive the magnetic stirring rod 29 to rotate to stir the liquid in the reaction tank 19, the glucose detection sensor 28 works to detect the result, and the liquid in the reaction tank 19 is discharged after the detection is completed.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present utility model.

Claims (8)

1. The utility model provides an automatic detector for food industry, its characterized in that, including the board, set up in the back grudging post of board top surface rear side, set up in the detection platform of back grudging post front side board top surface, set up in reagent conveying component of board top surface, set up in a plurality of reaction detection ponds of detecting the inside rear side of platform, set up in reaction detection pond front side sample positioning component on the detection platform, set up in triaxial motion subassembly on the back grudging post, set up in sample needle on the triaxial motion subassembly, reaction detection pond include the reaction tank of interior reaction chamber of setting up, place in magnetism stirring rod and the glucose detection sensor in the reaction tank, set up in be used for driving on the board magnetism stirring rod's magnetism agitator, the reaction tank top is equipped with the sample injection hole that is convenient for sample needle male, the reaction tank side be equipped with the inlet opening, the play liquid hole that reagent conveying component is connected.

2. The automated inspection instrument of claim 1, wherein the sample positioning assembly comprises a positioning cavity with an upward opening, a heat sink disposed at the bottom of the positioning cavity, a semiconductor refrigeration sheet disposed at the top of the heat sink, and a reagent basket disposed in the positioning cavity, wherein the refrigeration surface of the semiconductor refrigeration sheet is disposed at the bottom of the positioning cavity.

3. An automated inspection apparatus for the food industry according to claim 2, wherein the heat sink is provided with a heat sink fan for dissipating heat from the heat sink.

4. The automated inspection instrument for the food industry of claim 1, wherein the reagent delivery assembly comprises a carriage, a metering pump disposed on the carriage, and an inlet and an outlet of the metering pump are respectively connected to the reagent container and the reaction tank.

5. The automated inspection instrument for the food industry of claim 2, wherein the reagent basket comprises a sample rack, a cover plate arranged at the top of the sample rack, and a handle arranged on the cover plate, wherein a test tube hole for facilitating insertion of a sample test tube is arranged on the cover plate, and the cover plate is used for covering the top opening of the positioning cavity.

6. An automated inspection apparatus for the food industry as defined in claim 1 wherein the inspection station is provided with a top open cleaning chamber having cleaning fluid access openings in the sides thereof.

7. An automated inspection apparatus for the food industry as defined by claim 1 wherein the reaction cell is provided with an overflow port.

8. The automated inspection instrument for the food industry according to any one of claims 1 to 7, wherein the three-axis motion assembly comprises an X-axis slide rail horizontally disposed on the top of the rear vertical frame, an X-axis slide carriage slidably engaged with the X-axis slide rail, a Y-axis slide rail horizontally disposed on the X-axis slide carriage, a Y-axis slide carriage slidably engaged with the Y-axis slide rail, a Z-axis slide carriage vertically disposed on the Y-axis slide carriage, a Z-axis slide carriage slidably engaged with the Z-axis slide rail, the sampling needle is disposed on the Z-axis slide carriage, an X-axis drive synchronous belt set is disposed on the rear vertical frame, the X-axis slide carriage is connected with the X-axis drive synchronous belt set, a Y-axis drive screw assembly is disposed on the X-axis slide carriage, the X-axis drive synchronous belt set is used for driving the X-axis slide carriage to horizontally slide left and right, the Y-axis drive screw assembly is used for driving the Y-axis slide carriage to horizontally slide back and forth, and the Z-axis drive screw assembly is used for driving the Z-axis slide carriage to move up and down.