CN219215461U - Automatic quantitative split charging equipment - Google Patents

Abstract

The utility model belongs to the technical field of scented tea production, and particularly relates to automatic quantitative split charging equipment. The beneficial effects of the utility model are as follows: through the structure, when the scented tea is subpackaged and filled, manual collocation is not needed, the automatic quantitative filling device can automatically and quantitatively fill, accurately control the component during subpackaging, avoid the error of manual quantitative, reduce the input of manpower, improve the working efficiency of scented tea subpackaging, and promote the development of scented tea production work.

Description

Automatic quantitative split charging equipment

Technical Field

The utility model belongs to the technical field of scented tea production, and particularly relates to automatic quantitative split charging equipment.

Background

Scented tea, also known as scented tea, i.e., tea prepared by infusing flowers, leaves or fruits of plants is a special type of reprocessed tea in China. And the scented tea is required to be split-packed after being produced and processed, and the scented tea is filled into split-packing boxes to be processed into finished products for sale.

The existing flower tea split charging mode is basically that flower tea is manually filled into split charging boxes by workers, or semi-automatically filled by machines, the split charging components of the two split charging modes are not accurate enough, the split charging cannot be quantitatively carried out, and generally, the split charging modes are that the workers can quantitatively carry out the split charging according to the feeling, certain errors necessarily exist, in addition, the existing split charging mode is low in working efficiency, and a large amount of manpower can be wasted.

Disclosure of Invention

In view of the above problems, an object of the present utility model is to: the automatic quantitative split charging equipment solves the problems that the existing scented tea split charging mode cannot be quantitatively filled, the manual split charging efficiency is low, and the quantification is error.

In order to achieve the above purpose, the utility model adopts the technical scheme that: the utility model provides an automatic ration partial shipment equipment, includes conveyer, conveyer's downside evenly is provided with the bracing piece, the bilateral symmetry formula in the middle of the conveyer is provided with the dead lever, one side of dead lever upside is provided with material feeding unit, one side both sides fixedly connected with fixed plate that material feeding unit is close to the dead lever, the other end and the dead lever fixed connection of fixed plate, material feeding unit is close to the one end downside of dead lever and is provided with down the hopper, down the hopper sets up between the dead lever, just hopper and dead lever fixed connection down, the downside fixedly connected with bin of hopper, the bin is close to one side of dead lever all with dead lever fixed connection, the downside of bin is provided with the unloading valve, the downside of unloading valve is provided with partial shipment shell, be provided with the quarter butt between partial shipment shell and the dead lever, the other end fixedly connected with weighing machine of quarter butt, the opposite side and the dead lever fixed connection of weighing machine, the downside fixedly connected with ration box, the side fixedly connected with ration valve is provided with the sensor, the sensor is connected with the box under the box, the sensor is located to the side of partial shipment valve.

The beneficial effects of the utility model are as follows: through the structure, when the scented tea is subpackaged and filled, manual collocation is not needed, the automatic quantitative filling device can automatically and quantitatively fill, accurately control the component during subpackaging, avoid the error of manual quantitative, reduce the input of manpower, improve the working efficiency of scented tea subpackaging, and promote the development of scented tea production work.

To screen out the debris;

as a further improvement of the above technical scheme: the feeding device is characterized in that a feeding hole is formed in the upper side of the storage box, the lower end of the discharging hopper is connected with the storage box in an inserting mode through the feeding hole, a screening plate is fixedly connected to the upper side of the inner side of the storage box, a certain gap is reserved between one side, close to the fixing rod, of the screening plate and the inner side wall of the storage box, screening holes are uniformly formed in the upper side of the screening plate, a blanking plate is arranged on the lower side of the screening plate, the periphery of the blanking plate is fixedly connected with the storage box, a discharging hole is formed in one side of the storage box, the blanking plate is an inclined plane gradually decreasing towards the discharging hole, a discharging shell I is connected to the storage box in an inserting mode through the discharging hole, a switching shell I is fixedly connected to the other end of the discharging shell I, a discharging shell II is fixedly connected to one side of the switching shell, an auxiliary rod is fixedly connected to the upper side of the switching shell, and the other side of the auxiliary rod is fixedly connected with a feeding device.

The beneficial effects of this improvement are: in the process of conveying scented tea, some broken residues can be generated due to the problems of extrusion and the like, and the broken residues can be screened out through the structure, so that the split charging quality is improved.

In order to enhance the slag screening effect;

as a further improvement of the above technical scheme: the vibrating rod is arranged in the middle of the lower side of the material sieving plate and is clung to the material sieving plate, one end of the vibrating rod, which is far away from the discharge hole, penetrates through the storage box to be fixedly connected with a second vibrating motor, and the second vibrating motor is fixedly connected with the storage box.

The beneficial effects of this improvement are: through the structure, when the scented tea passes through the material sieving plate, the material sieving plate can vibrate, so that the cleaning effect of the broken slag in the scented tea is enhanced.

In order to limit the position of the split boxes;

as a further improvement of the above technical scheme: one side of the fixed rod, which is far away from the second vibration motor, is fixedly connected with a first limiting plate, the other ends of the first limiting plates are close to each other, and the other ends of the first limiting plates are provided with a second limiting plate.

The beneficial effects of this improvement are: when the split charging box is put on the conveying device, the split charging box is required to be manually placed, the manual placement is more random, the split charging box can deviate from the center line position sometimes, the quantitative valve and the split charging box deviate, scented tea can be sprayed out during split charging, and the split charging box can be made to arrive under the quantitative valve through the structure.

To enable adjustment of size;

as a further improvement of the above technical scheme: the first limiting plate is rotationally connected with the second limiting plate, and a knob is arranged on the upper side of the connection part of the first limiting plate and the second limiting plate.

The beneficial effects of this improvement are: the size of the split charging box is not necessarily fixed, and through the structure, the space and the angle of the limiting plates II are adjusted, so that the split charging box can be suitable for filling split charging boxes with different sizes.

In order to ensure the split charging effect;

as a further improvement of the above technical scheme: the downside of positioning sensor is provided with electric telescopic handle, one side that electric telescopic handle is close to the dead lever and dead lever fixed connection, the equal fixedly connected with vibrating motor of the other end of electric telescopic handle is first, the equal fixedly connected with rubber piece of opposite side of vibrating motor first.

The beneficial effects of this improvement are: when the scented tea is filled, the scented tea is easy to stack up due to the straight falling, and even overflows into the split charging boxes, so that the scented tea can be uniformly distributed in the split charging boxes when being split charged through the structure.

None of the parts of the device are the same as or can be implemented using prior art.

Drawings

FIG. 1 is a schematic diagram of the front structure of the present utility model;

FIG. 2 is an enlarged view of the portion A of FIG. 1 in accordance with the present utility model;

FIG. 3 is a right side cross-sectional view of the bin of the present utility model;

FIG. 4 is a front cross-sectional view of the bin of the present utility model;

in the figure: 1. a transfer device; 2. a support rod; 3. a fixed rod; 4. a feeding device; 5. a fixing plate; 6. discharging a hopper; 7. a storage box; 71. a feed inlet; 72. a screening plate; 73. screening holes; 74. a vibrating rod; 75. a vibration motor II; 76. a blanking plate; 77. a discharge port; 78. a blanking valve; 8. a first discharging shell; 9. a transfer case; 10. a second discharging shell; 11. an auxiliary lever; 12. split charging the shell; 13. a short bar; 14. a weighing device; 15. a dosing valve; 16. packaging the components into boxes; 17. positioning a sensor; 18. an electric telescopic rod; 19. a first vibration motor; 20. a rubber block; 21. a first limiting plate; 22. a limiting plate II; 23. and (5) a knob.

Detailed Description

In order that those skilled in the art may better understand the technical solutions of the present utility model, the following detailed description of the present utility model with reference to the accompanying drawings is provided for exemplary and explanatory purposes only and should not be construed as limiting the scope of the present utility model.

Example 1:

as shown in fig. 1-4: the utility model provides an automatic ration partial shipment equipment, includes conveyer 1, conveyer 1's downside evenly is provided with bracing piece 2, conveyer 1 middle bilateral symmetry is provided with dead lever 3, one side of dead lever 3 upside is provided with material feeding unit 4, one side both sides fixedly connected with fixed plate 5 that material feeding unit 4 is close to dead lever 3, the other end and the dead lever 3 fixed connection of fixed plate 5, material feeding unit 4 is close to the one end downside of dead lever 3 and is provided with down hopper 6, down hopper 6 sets up between dead lever 3, just down hopper 6 and dead lever 3 fixed connection, down hopper 6's downside fixedly connected with bin 7, bin 7 is close to one side of dead lever 3 all with dead lever 3 fixed connection, bin 7's downside is provided with unloading valve 78, the downside of unloading valve 78 is provided with partial shipment shell 12, be provided with quarter 13 between partial shipment shell 12 and the dead lever 3, partial shipment shell 12 and quarter 13 fixed connection, the one end downside is provided with down hopper 6 and is provided with weight sensor 13, the equal to weigh down hopper 13, the equal side is provided with weight sensor 16 and is connected with the constant head tank 17, the constant head tank 16 is provided with between the constant head tank 3, the constant head tank 16 is connected with the constant head tank 16, the constant head tank is provided with the constant head tank 17.

Example 2:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, an automatic quantitative subpackaging device comprises a conveying device 1, wherein a supporting rod 2 is uniformly arranged at the lower side of the conveying device 1, a fixing rod 3 is symmetrically arranged at two sides in the middle of the conveying device 1, a feeding device 4 is arranged at one side of the upper side of the fixing rod 3, a fixing plate 5 is fixedly connected at two sides of one side of the feeding device 4, which is close to the fixing rod 3, the other end of the fixing plate 5 is fixedly connected with the fixing rod 3, a blanking hopper 6 is arranged at the lower side of one end of the feeding device 4, which is close to the fixing rod 3, the blanking hopper 6 is arranged between the fixing rods 3, and is fixedly connected with the fixing rod 3, a stock box 7 is fixedly connected at the lower side of the blanking hopper 6, one side of the stock box 7, which is close to the fixing rod 3, is fixedly connected with the fixing rod 3, the lower side of the storage box 7 is provided with a blanking valve 78, the lower side of the blanking valve 78 is provided with a split charging shell 12, a short rod 13 is arranged between the split charging shell 12 and a fixed rod 3, the split charging shell 12 is fixedly connected with the short rod 13, the other end of the short rod 13 is fixedly connected with a weighing device 14, the other side of the weighing device 14 is fixedly connected with the fixed rod 3, the lower side of the split charging shell 12 is fixedly connected with a quantitative valve 15, the right lower side of the quantitative valve 15 is provided with a split charging box 16, a positioning sensor 17 is arranged between the split charging box 16 and the fixed rod 3, the positioning sensor 17 is fixedly connected with the fixed rod 3, a feed inlet 71 is arranged on the upper side of the storage box 7, the lower end of the lower charging hopper 6 is spliced with the storage box 7 through the feed inlet 71, the upper side of the inner side of the storage box 7 is fixedly connected with a screen 72, the utility model discloses a feeding device, including bin 7, sieve flitch 72, auxiliary rod 7, bin 7, changeover shell 9's one side fixedly connected with ejection of compact shell two 10, changeover shell 9's upside fixedly connected with auxiliary rod 11, auxiliary rod 11's opposite side and material feeding device 4 fixed connection, the sieve flitch 76 is all left certain clearance with bin 7's inside wall that is close to dead lever 3, sieve flitch 72, the downside of sieve flitch 72 is provided with blanking plate 76, blanking plate 76 is around with bin 7 fixed connection, discharge gate 77 has been seted up to one side of bin 7, blanking plate 76 is the inclined plane that reduces gradually to discharge gate 77, bin 7 has one of ejection of compact shells 8 through the discharge gate 77 grafting, one of the other end fixedly connected with changeover shell 9 of ejection of compact shell 9, changeover shell 9's upside fixedly connected with auxiliary rod 11.

Example 3:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, an automatic quantitative subpackaging device comprises a conveying device 1, wherein a supporting rod 2 is uniformly arranged at the lower side of the conveying device 1, a fixing rod 3 is symmetrically arranged at two sides in the middle of the conveying device 1, a feeding device 4 is arranged at one side of the upper side of the fixing rod 3, a fixing plate 5 is fixedly connected at two sides of one side of the feeding device 4, which is close to the fixing rod 3, the other end of the fixing plate 5 is fixedly connected with the fixing rod 3, a blanking hopper 6 is arranged at the lower side of one end of the feeding device 4, which is close to the fixing rod 3, the blanking hopper 6 is arranged between the fixing rods 3, and is fixedly connected with the fixing rod 3, a stock box 7 is fixedly connected at the lower side of the blanking hopper 6, one side of the stock box 7, which is close to the fixing rod 3, is fixedly connected with the fixing rod 3, the lower side of the storage box 7 is provided with a blanking valve 78, the lower side of the blanking valve 78 is provided with a split charging shell 12, a short rod 13 is arranged between the split charging shell 12 and a fixed rod 3, the split charging shell 12 is fixedly connected with the short rod 13, the other end of the short rod 13 is fixedly connected with a weighing device 14, the other side of the weighing device 14 is fixedly connected with the fixed rod 3, the lower side of the split charging shell 12 is fixedly connected with a quantitative valve 15, the right lower side of the quantitative valve 15 is provided with a split charging box 16, a positioning sensor 17 is arranged between the split charging box 16 and the fixed rod 3, the positioning sensor 17 is fixedly connected with the fixed rod 3, a feed inlet 71 is arranged on the upper side of the storage box 7, the lower end of the lower charging hopper 6 is spliced with the storage box 7 through the feed inlet 71, the upper side of the inner side of the storage box 7 is fixedly connected with a screen 72, the utility model discloses a vibrating screen, including sieve flitch 72, bin 7, auxiliary rod 11, sieve flitch 72, sieve flitch 76's downside is provided with blanking plate 76, blanking plate 76 all around and bin 7 fixed connection, discharge gate 77 has been seted up to one side of bin 7, blanking plate 76 is the inclined plane that gradually reduces to discharge gate 77, bin 7 has discharge shell one 8 through the grafting of discharge gate 77, the other end fixedly connected with adapter shell 9 of discharge shell one 8, one side fixedly connected with discharge shell two 10 of adapter shell 9, the upside fixedly connected with auxiliary rod 11 of adapter shell 9, the opposite side and the material feeding unit 4 fixed connection of auxiliary rod 11, the downside middle part of sieve flitch 72 is provided with vibrations pole 74, vibrations pole 74 is hugged closely bin 72 and is set up, the one end that discharge gate 77 was kept away from to the discharge gate 77 runs through bin 7 to outside fixedly connected with motor two 75, vibration box 7 fixed connection.

Example 4:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, an automatic quantitative subpackaging device comprises a conveying device 1, wherein a supporting rod 2 is uniformly arranged at the lower side of the conveying device 1, a fixing rod 3 is symmetrically arranged at two sides in the middle of the conveying device 1, a feeding device 4 is arranged at one side of the upper side of the fixing rod 3, a fixing plate 5 is fixedly connected at two sides of one side of the feeding device 4, which is close to the fixing rod 3, the other end of the fixing plate 5 is fixedly connected with the fixing rod 3, a blanking hopper 6 is arranged at the lower side of one end of the feeding device 4, which is close to the fixing rod 3, the blanking hopper 6 is arranged between the fixing rods 3, and is fixedly connected with the fixing rod 3, a stock box 7 is fixedly connected at the lower side of the blanking hopper 6, one side of the stock box 7, which is close to the fixing rod 3, is fixedly connected with the fixing rod 3, the lower side of bin 7 is provided with unloading valve 78, the downside of unloading valve 78 is provided with sub-packaging shell 12, be provided with quarter butt 13 between sub-packaging shell 12 and the dead lever 3, sub-packaging shell 12 and quarter butt 13 fixed connection, the other end fixedly connected with of quarter butt 13 weighs ware 14, the opposite side of weighing ware 14 all is with dead lever 3 fixed connection, the downside fixedly connected with ration valve 15 of sub-packaging shell 12, be provided with sub-packaging box 16 under the ration valve 15, be provided with positioning sensor 17 between sub-packaging box 16 and the dead lever 3, positioning sensor 17 and dead lever 3 fixed connection, one side of dead lever 3 that keeps away from vibrating motor second 75 is all fixedly connected with limiting plate one 21, limiting plate one 21's the other end is close to each other, limiting plate one 21's the other end is provided with limiting plate two 22.

Example 5:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, an automatic quantitative subpackaging device comprises a conveying device 1, wherein a supporting rod 2 is uniformly arranged at the lower side of the conveying device 1, a fixing rod 3 is symmetrically arranged at two sides in the middle of the conveying device 1, a feeding device 4 is arranged at one side of the upper side of the fixing rod 3, a fixing plate 5 is fixedly connected at two sides of one side of the feeding device 4, which is close to the fixing rod 3, the other end of the fixing plate 5 is fixedly connected with the fixing rod 3, a blanking hopper 6 is arranged at the lower side of one end of the feeding device 4, which is close to the fixing rod 3, the blanking hopper 6 is arranged between the fixing rods 3, and is fixedly connected with the fixing rod 3, a stock box 7 is fixedly connected at the lower side of the blanking hopper 6, one side of the stock box 7, which is close to the fixing rod 3, is fixedly connected with the fixing rod 3, the lower side of the storage box 7 is provided with a blanking valve 78, the lower side of the blanking valve 78 is provided with a split charging shell 12, a short rod 13 is arranged between the split charging shell 12 and a fixed rod 3, the split charging shell 12 is fixedly connected with the short rod 13, the other end of the short rod 13 is fixedly connected with a weighing device 14, the other side of the weighing device 14 is fixedly connected with the fixed rod 3, the lower side of the split charging shell 12 is fixedly connected with a quantitative valve 15, the right lower side of the quantitative valve 15 is provided with a split charging box 16, a positioning sensor 17 is arranged between the split charging box 16 and the fixed rod 3, the positioning sensor 17 is fixedly connected with the fixed rod 3, one side of the fixed rod 3 far away from a vibration motor II 75 is fixedly connected with a limiting plate I21, the other ends of the limiting plate I21 are mutually close, the other ends of the limiting plate I21 are provided with limiting plate II 22, the first limiting plate 21 is rotationally connected with the second limiting plate 22, and a knob 23 is arranged on the upper side of the connection position of the first limiting plate 21 and the second limiting plate 22.

Example 6:

as shown in fig. 1 to 4, as a further optimization of the above embodiment, an automatic quantitative subpackaging device comprises a conveying device 1, wherein a supporting rod 2 is uniformly arranged at the lower side of the conveying device 1, a fixing rod 3 is symmetrically arranged at two sides in the middle of the conveying device 1, a feeding device 4 is arranged at one side of the upper side of the fixing rod 3, a fixing plate 5 is fixedly connected at two sides of one side of the feeding device 4, which is close to the fixing rod 3, the other end of the fixing plate 5 is fixedly connected with the fixing rod 3, a blanking hopper 6 is arranged at the lower side of one end of the feeding device 4, which is close to the fixing rod 3, the blanking hopper 6 is arranged between the fixing rods 3, and is fixedly connected with the fixing rod 3, a stock box 7 is fixedly connected at the lower side of the blanking hopper 6, one side of the stock box 7, which is close to the fixing rod 3, is fixedly connected with the fixing rod 3, the lower side of the storage box 7 is provided with a blanking valve 78, the lower side of the blanking valve 78 is provided with a split charging shell 12, a short rod 13 is arranged between the split charging shell 12 and a fixed rod 3, the split charging shell 12 is fixedly connected with the short rod 13, the other end of the short rod 13 is fixedly connected with a weighing device 14, the other sides of the weighing device 14 are fixedly connected with the fixed rod 3, the lower side of the split charging shell 12 is fixedly connected with a quantitative valve 15, the right lower side of the quantitative valve 15 is provided with a split charging box 16, a positioning sensor 17 is arranged between the split charging box 16 and the fixed rod 3, the positioning sensor 17 is fixedly connected with the fixed rod 3, the lower side of the positioning sensor 17 is provided with an electric telescopic rod 18, one side of the electric telescopic rod 18 close to the fixed rod 3 is fixedly connected with the fixed rod 3, the other ends of the electric telescopic rod 18 are fixedly connected with a vibrating motor 19, the other side of the vibration motor I19 is fixedly connected with a rubber block 20.

The working principle and the using flow of the utility model are as follows: when in use, scented tea is continuously conveyed to the lower hopper 6 through the feeding device 4, the scented tea falls into the lower hopper 6 and then enters the storage box 7 through the feeding hole 71, the scented tea falls down onto the screening plate 72, the broken slag doped in the scented tea falls down from the screening hole 73 to the blanking plate 76, then enters the first discharging shell 8 through the discharging hole 77, then enters the second discharging shell 10 through the switching shell 9 and then is discharged to the outside to be collected, the second vibrating motor 75 is started, the second vibrating motor 75 drives the screening hole 73 to vibrate through the vibrating rod 74, the screening effect on the broken slag can be enhanced, meanwhile, the scented tea slides down from the screening plate 72 to the bottom of the storage box 7, the blanking valve 78 is opened, the scented tea enters the split charging shell 12 from the blanking valve 78, the scented tea accumulates in the split charging shell 12, when the split charging shell 16 is conveyed through the conveying device 1, the limit plate 21 and the limit plate 22 are passed, when reaching the position right below the quantitative valve 15, after the positioning sensor 17 catches the position of the split charging box 16, the conveying device 1 stops conveying, the blanking valve 78 is closed, the weighing device 14 weighs the scented tea in the split charging box 12, the quantitative valve 15 is opened, the scented tea falls from the quantitative valve 15 into the split charging box 16, meanwhile, the electric telescopic rod 18 is started, the electric telescopic rod 18 pushes the vibration motor I19, the vibration motor I19 pushes the rubber block 20 to clamp the split charging box 16, the vibration motor I19 is started, the vibration motor I19 drives the split charging box 16 through the rubber block 20 to vibrate, the scented tea is uniformly distributed after entering the split charging box 16, gaps among the scented tea can be reduced, in addition, some smaller particles in the scented tea can enter the bottommost layer, according to the rated mass volume of the split charging box 16, after the rated mass released from the split charging box 12 by the quantitative valve 15, the quantitative valve 15 is closed, the electric telescopic rod 18 controls the first vibration motor 19 and the rubber block 20 to retract, the blanking valve 78 is opened, scented tea continues to enter the split charging shell 12 from the storage box 7, the conveying device 1 is started, the split charging box 16 is conveyed out forwards along with the conveying device 1, and the operation is repeated. Through the structure, when the scented tea is subpackaged and filled, manual collocation is not needed, the automatic quantitative filling device can automatically and quantitatively fill, accurately control the component during subpackaging, avoid the error of manual quantitative, reduce the input of manpower, improve the working efficiency of scented tea subpackaging, and promote the development of scented tea production work.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The principles and embodiments of the present utility model have been described herein with reference to specific examples, the description of which is intended only to facilitate an understanding of the method of the present utility model and its core ideas. The foregoing is merely illustrative of the preferred embodiments of the utility model, and it is noted that there is virtually no limit to the specific structure which may be imposed by those skilled in the art without departing from the spirit of the utility model, and that modifications, adaptations, or variations of the foregoing features may be combined in a suitable manner; such modifications, variations and combinations, or the direct application of the inventive concepts and aspects to other applications without modification, are contemplated as falling within the scope of the present utility model.

Claims (6)

1. An automatic quantitative partial shipment equipment, its characterized in that: including conveyer (1), conveyer (1) downside evenly is provided with bracing piece (2), conveyer (1) middle bilateral symmetry is provided with dead lever (3), one side of dead lever (3) upside is provided with material feeding unit (4), one side both sides fixedly connected with fixed plate (5) that material feeding unit (4) are close to dead lever (3), the other end and the dead lever (3) fixed connection of fixed plate (5), material feeding unit (4) are close to one end downside of dead lever (3) and are provided with down hopper (6), down hopper (6) set up between dead lever (3), just down hopper (6) and dead lever (3) fixed connection, the downside fixedly connected with bin (7) of down hopper (6), one side that bin (7) are close to dead lever (3) all is connected with dead lever (3) fixed, the downside of bin (7) is provided with blanking valve (78), blanking valve (78) are close to one end downside of dead lever (3) is provided with down hopper (6), down hopper (6) and are provided with 13, 13 and are divided into weighing shell (13) and are connected with 13, 13 and are divided into separately to be connected with between 13, the other side of weighing device (14) all with dead lever (3) fixed connection, the downside fixedly connected with ration valve (15) of partial shipment shell (12), the downside of ration valve (15) is provided with partial shipment box (16), be provided with between partial shipment box (16) and dead lever (3) positioning sensor (17), positioning sensor (17) and dead lever (3) fixed connection.

2. An automated metering dispensing apparatus as claimed in claim 1 wherein: feed inlet (71) have been seted up to the upside of bin (7), feed inlet (71) are pegged graft with bin (7) are passed through to the lower extreme of lower hopper (6), inboard upside fixedly connected with sieve flitch (72) of bin (7), one side that sieve flitch (72) are close to dead lever (3) all leaves certain clearance with the inside wall of bin (7), sieve material hole (73) have evenly been seted up to the upside of sieve flitch (72), the downside of sieve flitch (72) is provided with blanking board (76), discharge gate (77) have been seted up all around with bin (7) fixed connection to one side of bin (7), blanking board (76) are the inclined plane that reduces to discharge gate (77) gradually, bin (7) are pegged graft through discharge gate (77) and are had discharge shell one (8), the other end fixedly connected with switching shell (9) of discharge shell one (8), the downside is provided with blanking board (76) and auxiliary connection device (11) on one side (11) of discharge shell (4).

3. An automated metering dispensing apparatus as claimed in claim 2 wherein: the vibrating screen is characterized in that a vibrating rod (74) is arranged in the middle of the lower side of the screening plate (72), the vibrating rod (74) is tightly attached to the screening plate (72), one end, far away from a discharge hole (77), of the vibrating rod (74) penetrates through the storage box (7) to be fixedly connected with a vibrating motor II (75), and the vibrating motor II (75) is fixedly connected with the storage box (7).

4. An automated metering dispensing apparatus as claimed in claim 1 wherein: one side of the fixed rod (3) far away from the vibration motor II (75) is fixedly connected with a limiting plate I (21), the other ends of the limiting plates I (21) are close to each other, and the other ends of the limiting plates I (21) are provided with limiting plates II (22).

5. An automated metering dispensing apparatus as claimed in claim 4 wherein: the first limiting plate (21) is rotationally connected with the second limiting plate (22), and a knob (23) is arranged on the upper side of the connecting position of the first limiting plate (21) and the second limiting plate (22).

6. An automated metering dispensing apparatus as claimed in claim 1 wherein: the positioning sensor is characterized in that an electric telescopic rod (18) is arranged on the lower side of the positioning sensor (17), one side, close to the fixed rod (3), of the electric telescopic rod (18) is fixedly connected with the fixed rod (3), the other end of the electric telescopic rod (18) is fixedly connected with a first vibration motor (19), and the other side of the first vibration motor (19) is fixedly connected with a rubber block (20).

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