CN211076391U - Charging mechanism for product packaging - Google Patents

Abstract

The utility model discloses a charging mechanism for product packaging, which comprises a supporting frame, wherein a first vibrating screen and a second vibrating screen are sequentially arranged on the supporting frame from top to bottom, a first sieve plate and a second sieve plate are sequentially arranged on the bottom wall of the first vibrating screen along the material conveying direction, a first material receiving funnel is arranged on the bottom wall of the first vibrating screen below the first sieve plate, and a second material receiving funnel is arranged on the bottom wall of the first vibrating screen below the second sieve plate; the lower end of the second material receiving funnel is connected with a feed hopper of a second vibrating screen through a pipeline, a third sieve plate and a fourth sieve plate are sequentially arranged on the bottom wall of the second vibrating screen along the material conveying direction of the second vibrating screen, a third material receiving funnel is arranged on the bottom wall of the second vibrating screen below the third sieve plate, and a fourth material receiving funnel is arranged on the bottom wall of the second vibrating screen below the fourth sieve plate; the utility model discloses can effectually carry out the particle size classification to beans product for the particle size of same rank beans product keeps unanimous basically.

Description

Charging mechanism for product packaging

Technical Field

The utility model relates to a device field for the packing, in particular to charging mechanism for product packaging.

Background

In the fine-packing sale of bean products such as soybeans, mung beans, red beans, black beans and the like, the particle sizes of beans in the same packaging bag are required to be basically consistent, and large deviation cannot occur, so that the bean products need to be subjected to particle classification before being packaged, and then the bean products with different levels of particle sizes are packaged in bags respectively. To this end, the applicant proposes a loading mechanism for packaging products, which allows the grain classification of the legume products before packaging them, so that the grain size of the legume products of the same grade remains substantially the same.

SUMMERY OF THE UTILITY MODEL

To the problem mentioned in the background art, the utility model aims at providing a charging mechanism for product packaging can carry out the particle classification of beans product before beans product bagging-off packing for the granularity size of same rank beans product keeps unanimous basically.

The above technical purpose of the present invention can be achieved by the following technical solutions:

a loading mechanism for product packaging comprises a supporting frame, and further comprises a first fan, a first conveying pipe, a first hopper, a second fan, a second conveying pipe and a second hopper, wherein two ends of the first conveying pipe are respectively connected with an air outlet of the first fan and a feeding end of the first hopper, a first loading pipe is arranged below the first hopper, and a first valve is arranged on the first loading pipe; two ends of the second conveying pipe are respectively connected with an air outlet of a second fan and a feeding end of a second hopper, a second charging pipe is arranged below the second hopper, and a second valve is arranged on the second charging pipe; the support frame is sequentially provided with a first vibrating screen and a second vibrating screen from top to bottom, the bottom wall of the first vibrating screen body is sequentially provided with a first screen plate and a second screen plate along the material conveying direction, the bottom wall of the first vibrating screen body is provided with a first material receiving funnel below the first screen plate, and the bottom wall of the first vibrating screen body is provided with a second material receiving funnel below the second screen plate; the lower end of the second material receiving funnel is connected with a feed hopper of a second vibrating screen through a pipeline, a third sieve plate and a fourth sieve plate are sequentially arranged on the bottom wall of the second vibrating screen along the material conveying direction of the second vibrating screen, a third material receiving funnel is arranged on the bottom wall of the second vibrating screen below the third sieve plate, a fourth material receiving funnel is arranged on the bottom wall of the second vibrating screen below the fourth sieve plate, the diameters of sieve pores of the first sieve plate and the third sieve plate are the same and are smaller than the diameters of sieve pores of the second sieve plate and the fourth sieve plate, and the diameter of the sieve pore of the second sieve plate is larger than the diameter of the sieve pore of the fourth sieve plate; the lower extreme that first connect material funnel and third to connect the material funnel all is linked together through pipeline and first conveyer pipe, the lower extreme that the fourth connects the material funnel is linked together through pipeline and second conveyer pipe.

Further, the first material funnel that connects, the second connect material funnel, the third connect material funnel and the fourth connect the lower port department of material funnel to respectively be connected with a nozzle stub, and the lower extreme of each nozzle stub respectively is connected with a hose, the first hose that connects the material funnel to connect is linked together with first conveyer pipe through first unloading pipe, the second connects the hose that the material funnel connects to link to each other with the feeder hopper of second shale shaker, the third connects the hose that the material funnel connects to be linked together with first conveyer pipe through third unloading pipe, the fourth connects the hose that the material funnel connects to be linked together with the second conveyer pipe through fourth unloading pipe.

Furthermore, the hose is a cloth bag pipe, and the upper end and the lower end of the cloth bag pipe are respectively sleeved on the corresponding connected pipes through pipe hoops.

Furthermore, a first measuring scale is arranged below the first charging pipe, and a manual valve is selected as the first valve.

Furthermore, a second measuring scale is arranged below the second charging pipe, and a manual valve is selected as the second valve.

To sum up, the utility model discloses mainly have following beneficial effect:

1. the utility model discloses can effectually carry out the particle size classification to beans product, and can be with beans product according to four ranks of particle size difference, process the utility model discloses a hierarchical back for the particle size of same rank beans product keeps unanimous basically.

2. Be provided with first measurement balance and second measurement balance for the bagging-off volume of beans product is accurate.

Drawings

Fig. 1 is a schematic structural view of a loading mechanism for product packaging of the present invention;

FIG. 2 is a top view of a bottom wall of a first vibratory screen body of a loading mechanism for product packaging in accordance with the present invention;

fig. 3 is a top view of the second vibrating screen bottom wall of the loading mechanism for packaging products according to the present invention.

Reference numerals: 1. a support frame; 2. a first vibrating screen; 3. a second vibrating screen; 4. a first screen deck; 5. a second screen deck; 6. a first receiving funnel; 7. a second receiving hopper; 8. a third screen deck; 9. a fourth sieve plate; 10. a third receiving funnel; 11. a fourth receiving funnel; 12. a first fan; 13. a first delivery pipe; 14. a first hopper; 15. a second fan; 16. a second delivery pipe; 17. a second hopper; 18. a first charging pipe; 19. a first valve; 20. a second charging pipe; 21. a second valve; 22. a hose; 23. a first blanking pipe; 24. a third blanking pipe; 25. a fourth blanking pipe; 26. a first measuring scale; 27. and a second measuring scale.

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 work belong to the protection scope of the present invention.

Referring to fig. 1, 2 and 3, the loading mechanism for product packaging comprises a supporting frame 1, and further comprises a first fan 12, a first conveying pipe 13, a first hopper 14, a second fan 15, a second conveying pipe 16 and a second hopper 17, wherein two ends of the first conveying pipe 13 are respectively connected with an air outlet of the first fan 12 and a feeding end of the first hopper 14, a first loading pipe 18 is arranged below the first hopper 14, and a first valve 19 is arranged on the first loading pipe 18; two ends of the second conveying pipe 16 are respectively connected with an air outlet of the second fan 15 and a feeding end of the second hopper 17, a second charging pipe 20 is arranged below the second hopper 17, and a second valve 21 is arranged on the second charging pipe 20; a first vibrating screen 2 and a second vibrating screen 3 are sequentially arranged on the support frame 1 from top to bottom, a first screen plate 4 and a second screen plate 5 are sequentially arranged on the bottom wall of the screen body of the first vibrating screen 2 along the material conveying direction, a first material receiving funnel 6 is arranged on the bottom wall of the screen body of the first vibrating screen 2 below the first screen plate 4, and a second material receiving funnel 7 is arranged on the bottom wall of the screen body of the first vibrating screen 2 below the second screen plate 5; the lower end of a second material receiving funnel 7 is connected with a feed hopper of a second vibrating screen 3 through a pipeline, a third screen plate 8 and a fourth screen plate 9 are sequentially arranged on the bottom wall of the screen body of the second vibrating screen 3 along the material conveying direction, a third material receiving funnel 10 is arranged on the bottom wall of the screen body of the second vibrating screen 3 and below the third screen plate 8, a fourth material receiving funnel 11 is arranged on the bottom wall of the screen body of the second vibrating screen 3 and below the fourth screen plate 9, the screen hole diameters of the first screen plate 4 and the third screen plate 8 are the same and are smaller than those of the second screen plate 5 and the fourth screen plate 9, and the screen hole diameter of the second screen plate 5 is larger than that of the fourth screen plate 9; the lower ends of the first material receiving funnel 6 and the third material receiving funnel 10 are communicated with a first conveying pipe 13 through a pipeline, and the lower end of the fourth material receiving funnel 11 is communicated with a second conveying pipe 16 through a pipeline.

The utility model discloses a theory of operation: bean products to be bagged enter the first vibrating screen 2 from a feed hopper of the first vibrating screen 2, move from right to left (the direction shown in figure 1) under the action of the first vibrating screen 2, sequentially pass through the first sieve plate 4 and the second sieve plate 5, when passing through the first sieve plate 4, part of the bean products with the granularity smaller than the diameter of the sieve pores of the first sieve plate 4 enter the first material receiving funnel 6, then enter the first conveying pipe 13, and are blown into the first hopper 14 under the action of the first fan 12; when passing through the second sieve plate 5, the bean products with the particle size smaller than the sieve pore diameter of the second sieve plate 5 enter the second material receiving funnel 7, then enter the second vibrating screen 3 through the feed hopper of the second vibrating screen 3, and the bean products with the particle size larger than the sieve pore diameter of the second sieve plate 5 are discharged from the left end discharge port of the first vibrating screen 2 and are collected through an external material receiving device.

The legume products entering the second vibrating screen 3 move from left to right (direction shown in figure 1) under the action of the second vibrating screen 3, sequentially pass through a third screen plate 8 and a fourth screen plate 9, when passing through the third screen plate 8, the legume products with the particle size smaller than the diameter of the screen holes of the third screen plate 8 enter a third material receiving funnel 10, then enter a first conveying pipe 13, and are blown into a first hopper 14 under the action of a first fan 12; when passing through the fourth sieve plate 9, the bean products with the particle size smaller than the sieve pore diameter of the fourth sieve plate 9 enter the fourth receiving hopper 11, then enter the second conveying pipe 16, are blown into the second hopper 16 under the action of the second fan 15, and the bean products with the particle size larger than the sieve pore diameter of the fourth sieve plate 9 are discharged from the right end discharge port of the second vibrating screen 3 and are collected by an external receiving device.

The grain size of the bean product is divided into four grades, namely a first grade, a second grade, a third grade and a fourth grade from large to small; the legume product introduced into the first hopper 14 is a legume product of a fourth particle size, a packaging bag is placed under the first filling tube 18, and the legume product in the first hopper 14 is filled into the packaging bag by opening the first valve 19; the bean products entering the second hopper 17 are bean products with a third grade grain size, a packaging bag is placed below the second charging pipe 20, and the second valve 21 is opened to charge the bean products in the second hopper 17 into the packaging bag; the bean products discharged from a discharge port at the right end of the second vibrating screen 3 are bean products with the second-level granularity, and are collected, bagged and packaged by an external receiving device; the beans product of being the beans product of first order granularity by the left end discharge gate discharge of first shale shaker 2 is collected and is packed in bags by external receiving device.

To sum up, the utility model discloses can effectually carry out the particle size classification to beans product, and can be with beans product according to four ranks of particle size difference, process the utility model discloses a hierarchical back for the particle size of same rank beans product keeps unanimous basically.

Referring to fig. 1, the lower ports of a first receiving funnel 6, a second receiving funnel 7, a third receiving funnel 10 and a fourth receiving funnel 11 are respectively connected with a short tube, the lower end of each short tube is respectively connected with a hose 22, the hose 22 connected with the first receiving funnel 6 is communicated with a first conveying pipe 13 through a first discharging pipe 23, the hose 22 connected with the second receiving funnel 7 is connected with the feeding hopper of a second vibrating screen 3, the hose 22 connected with the third receiving funnel 10 is communicated with the first conveying pipe 13 through a third discharging pipe 24, and the hose 22 connected with the fourth receiving funnel 11 is communicated with a second conveying pipe 16 through a fourth discharging pipe 25; the influence of the vibration of the first vibrating screen 2 and the second vibrating screen 3 on each conveying pipeline is reduced by arranging each hose 22; the hose 22 chooses the sack pipe for use, and the upper end and the lower extreme of sack pipe are located corresponding continuous pipe through the ferrule cover respectively for the installation of hose 22 is all very convenient with demolish, and the sack pipe is compared in the ability of transmission vibrations such as rubber hose, wire hose littleer moreover, makes the vibration of first shale shaker 2 and second shale shaker 3 minimum to each pipeline's influence.

Referring to fig. 1, a first measuring scale 26 is arranged below the first charging pipe 18, a manual valve is used as the first valve 19, a second measuring scale 27 is arranged below the second charging pipe 20, a manual valve is used as the second valve 21, and the first measuring scale 26 and the second measuring scale 27 are arranged to enable the bagging amount of the bean products to be accurate.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The loading mechanism for product packaging comprises a support frame (1) and is characterized by further comprising a first fan (12), a first conveying pipe (13), a first hopper (14), a second fan (15), a second conveying pipe (16) and a second hopper (17), wherein two ends of the first conveying pipe (13) are respectively connected with an air outlet of the first fan (12) and a feeding end of the first hopper (14), a first loading pipe (18) is arranged below the first hopper (14), and a first valve (19) is arranged on the first loading pipe (18); two ends of the second conveying pipe (16) are respectively connected with an air outlet of a second fan (15) and a feeding end of a second hopper (17), a second charging pipe (20) is arranged below the second hopper (17), and a second valve (21) is arranged on the second charging pipe (20); a first vibrating screen (2) and a second vibrating screen (3) are sequentially arranged on the support frame (1) from top to bottom, a first screen plate (4) and a second screen plate (5) are sequentially arranged on the bottom wall of the screen body of the first vibrating screen (2) along the material conveying direction of the first vibrating screen, a first material receiving hopper (6) is arranged on the bottom wall of the screen body of the first vibrating screen (2) below the first screen plate (4), and a second material receiving hopper (7) is arranged on the bottom wall of the screen body of the first vibrating screen (2) below the second screen plate (5); the lower end of the second material receiving funnel (7) is connected with a feed hopper of a second vibrating screen (3) through a pipeline, a third screen plate (8) and a fourth screen plate (9) are sequentially arranged on the bottom wall of the screen body of the second vibrating screen (3) along the material conveying direction of the second vibrating screen, a third material receiving funnel (10) is arranged on the bottom wall of the screen body of the second vibrating screen (3) and below the third screen plate (8), a fourth material receiving funnel (11) is arranged on the bottom wall of the screen body of the second vibrating screen (3) and below the fourth screen plate (9), the diameters of the screen holes of the first screen plate (4) and the third screen plate (8) are the same and are smaller than the diameters of the screen holes of the second screen plate (5) and the fourth screen plate (9), and the diameter of the screen hole of the second screen plate (5) is larger than the diameter of the screen hole of the fourth screen plate (9); the lower ends of the first material receiving funnel (6) and the third material receiving funnel (10) are communicated with the first conveying pipe (13) through pipelines, and the lower end of the fourth material receiving funnel (11) is communicated with the second conveying pipe (16) through pipelines.

2. The loading mechanism for packaging products of claim 1, wherein: the first material receiving funnel (6), the second material receiving funnel (7), the third material receiving funnel (10) and the fourth material receiving funnel (11) are respectively connected with a short pipe at the lower port, the lower end of each short pipe is respectively connected with a hose (22), the hose (22) connected with the first material receiving funnel (6) is communicated with the first conveying pipe (13) through the first material receiving pipe (23), the hose (22) connected with the second material receiving funnel (7) is connected with the feed hopper of the second vibrating screen (3), the hose (22) connected with the third material receiving funnel (10) is communicated with the first conveying pipe (13) through the third material receiving pipe (24), and the hose (22) connected with the fourth material receiving funnel (11) is communicated with the second conveying pipe (16) through the fourth material receiving pipe (25).

3. The loading mechanism for packaging products of claim 2, wherein: the hose (22) is a cloth bag pipe, and the upper end and the lower end of the cloth bag pipe are respectively sleeved on the corresponding connected pipes through pipe hoops.

4. The loading mechanism for product packaging as set forth in any one of claims 1-3, wherein: a first measuring scale (26) is arranged below the first charging pipe (18), and the first valve (19) is a manual valve.

5. The loading mechanism for product packaging as set forth in any one of claims 1-3, wherein: a second measuring scale (27) is arranged below the second charging pipe (20), and the second valve (21) is a manual valve.

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