CN109515785B

CN109515785B - Quantitative packaging equipment and quantitative packaging method for vermicelli

Info

Publication number: CN109515785B
Application number: CN201811593082.XA
Authority: CN
Inventors: 杜毅; 邢春芳; 赵建周; 李正斌; 陈朝大; 侯凡博; 王勇强; 李鑫
Original assignee: Anyang Institute of Technology
Current assignee: Anyang Institute of Technology
Priority date: 2018-12-25
Filing date: 2018-12-25
Publication date: 2023-10-24
Anticipated expiration: 2038-12-25
Also published as: CN109515785A

Abstract

The utility model provides a bean vermicelli ration partial shipment equipment, includes throws material conveyer belt, throws hopper, bean vermicelli separator, weighing device, plastic hopper, partial shipment conveyer belt, support, throw the hopper and set up on the support, set up at throwing hopper one side and throw the material conveyer belt, throw the discharge end of material conveyer belt and be located and throw the hopper top, set up bean vermicelli separator below throwing the hopper, set up a plurality of partial shipment spouts in annular cover bottom, set up vibrating motor in partial shipment spout bottom, set up weighing device in the exit of partial shipment spout, set up the plastic funnel below weighing box, set up the partial shipment conveyer belt below the plastic funnel, set up photoelectric switch in the position that corresponds with the plastic funnel on the partial shipment conveyer belt, set up partial shipment box on the conveyer belt. The invention can automatically operate the procedures of separating, weighing and shaping vermicelli, reduces labor intensity and effectively improves the efficiency and precision of vermicelli production.

Description

Quantitative packaging equipment and quantitative packaging method for vermicelli

Technical Field

The invention relates to the field of automatic production of vermicelli, in particular to quantitative vermicelli packaging equipment and a quantitative vermicelli packaging method.

Background

In the large-scale production of vermicelli, the separation, weighing and shaping of the vermicelli at present are main procedures of vermicelli production, and because the texture of the vermicelli is soft, automatic equipment is not easy to split, and the procedures of the separation, weighing and shaping of the vermicelli at present are mostly finished manually, so that the labor intensity is high, the sorting efficiency is low, and the weighing precision is unstable. If the automatic equipment can be adopted to replace manual operation, the automatic procedures of vermicelli automatic separation, weighing and shaping can be realized, and the efficiency and the precision of vermicelli production can be effectively improved.

Disclosure of Invention

The present invention aims to overcome the above-mentioned problems in the current vermicelli production.

The invention provides a quantitative vermicelli packaging device, which comprises a feeding conveyor belt, a feeding hopper, a vermicelli separating device, a weighing device, a shaping hopper, a packaging box, a packaging conveyor belt and a bracket, wherein the feeding hopper is arranged on the bracket, one side of the feeding hopper is provided with the feeding conveyor belt, the discharge end of the feeding conveyor belt is positioned above the feeding hopper, the vermicelli separating device is arranged below the feeding hopper, the vermicelli separating device comprises a separating cylinder, a separating motor, an annular cover and a packaging chute, the separating cylinder is arranged below the feeding hopper, the separating cylinder is a cylindrical container with an upper opening, grid-shaped openings are uniformly arranged on the side wall of the separating cylinder, the bottom center of the separating cylinder is connected with a rotating shaft of the separating motor, the separating motor can drive the separating cylinder to rotate, the annular cover is arranged outside the separating cylinder, the annular cover is fixedly connected with the bracket, a plurality of split charging sliding grooves are formed in the bottom of the annular cover, a vibrating motor is arranged at the bottom of the split charging sliding grooves, a weighing device is arranged at the outlet of the split charging sliding grooves, the weighing device comprises a weighing box which is a container with an opening at the upper part, a weighing box bottom plate and the side wall of the weighing box are of a split structure, a weighing sensor is arranged below the weighing box bottom plate, the middle part of the weighing box bottom plate is fixedly connected with a weighing contact of the weighing sensor, a connecting rod is arranged at the bottom of the weighing sensor, one end of the connecting rod is fixedly connected with the bottom of the weighing sensor, a rotating shaft is arranged at the other end of the connecting rod and is fixedly connected with the weighing sensor, two ends of the rotating shaft are rotatably connected with the bracket through bearings, a turnover motor is arranged at the end part of the rotating shaft, the turnover motor drives the rotating shaft to rotate for a certain angle, the connecting rod and the weighing box bottom plate are driven to rotate together, a shaping funnel is arranged below the weighing box, a sub-packaging conveyor belt is arranged below the shaping hopper, a photoelectric switch is arranged at a position on the sub-packaging conveyor belt corresponding to the shaping hopper, and a sub-packaging box is arranged on the conveyor belt.

Further the annular cover is in an inverted funnel shape with a small upper part and a large lower part.

Further, two split charging sliding grooves are formed in the bottom of the annular cover.

Further, the edges of the grid-shaped openings on the side wall of the separating cylinder are required to be processed smoothly, so that the surfaces of the vermicelli are prevented from being scratched.

Further baffle plates are arranged on two sides below the weighing box and in the discharging direction, so that splashing during discharging is prevented.

When the weighing sensor at the bottom of the weighing box senses that the vermicelli reaches the preset weight, firstly, a vibrating motor at the bottom of the dispensing chute is closed to prevent the vermicelli from continuously entering the weighing box, and a bottom plate of the weighing box is opened to enable the vermicelli to slide into a shaping hopper, and the shaping hopper falls into the dispensing box, at the moment, the dispensing conveyor is started to convey the dispensing box containing the vermicelli to a designated position, and a photoelectric switch senses whether the next dispensing box is in place or not, and the quantitative dispensing of the vermicelli is achieved after the next dispensing box is in place.

The invention has the beneficial effects that: the quantitative vermicelli packaging equipment and the quantitative vermicelli packaging method provided by the invention can automatically operate the procedures of separating, weighing and shaping vermicelli, reduce the labor intensity and effectively improve the efficiency and the precision of vermicelli production.

Drawings

Fig. 1 is a schematic structural view of a quantitative vermicelli packaging device according to the invention.

Fig. 2 is a schematic view of a bottom view structure of a quantitative vermicelli packaging device according to the present invention.

FIG. 3 is a schematic view of the structure of the weighing box.

FIG. 4 is a schematic partial cross-sectional view of the structure of the hopper, separator bowl, separator motor and annular shroud.

Detailed Description

In order to more fully explain the practice of the invention, examples of the practice of the invention are provided. These examples are merely illustrative of the present invention and do not limit the scope of the invention.

The invention will be explained in further detail with reference to the accompanying drawings, in which: 1: a feeding conveyor belt; 2: a charging hopper; 3: an annular cover; 4: a bracket; 5: a split charging conveyor belt; 6: packaging the components into boxes; 7: shaping a hopper; 8: a weighing box; 9: split charging sliding grooves; 10: separating the motor; 11: a vibration motor; 12: a turnover motor; 13: a connecting rod; 14: a weighing box bottom plate; 15: a weighing sensor; 16: a baffle; 17: a separation cylinder; 18: and grid-shaped openings.

As shown in the attached drawing, the quantitative vermicelli packaging equipment comprises a feeding conveyor belt 1, a feeding hopper 2, a vermicelli separating device, a weighing device, a shaping hopper 7, a packaging box 6, a packaging conveyor belt 5 and a bracket 4, and is characterized in that: the feeding hopper is arranged on a bracket, a feeding conveyor belt is arranged on one side of the feeding hopper, the discharge end of the feeding conveyor belt is positioned above the feeding hopper, a vermicelli separating device is arranged below the feeding hopper, the vermicelli separating device comprises a separating cylinder, a separating motor 10, an annular cover 3 and a split charging chute 9, the separating cylinder is arranged below the feeding hopper, the separating cylinder 17 is a cylindrical container 17 with an upper opening, grid-shaped openings 18 are uniformly arranged on the side wall of the separating cylinder 17, the center of the bottom of the separating cylinder 17 is connected with a rotating shaft of the separating motor 10, the separating motor 10 can drive the separating cylinder to rotate, the separating motor 10 is fixedly connected with the bracket, the annular cover is arranged outside the separating cylinder and fixedly connected with the bracket, a plurality of split charging chutes are arranged at the bottom of the annular cover, a vibrating motor 11 is arranged at the bottom of the split charging chute, a weighing device is arranged at the outlet of the split charging chute 9, the weighing device comprises a weighing box 8, the weighing box 8 is a container with an opening at the upper part, a weighing box bottom plate 14 and the side wall of the weighing box are of a split structure, a weighing sensor 15 is arranged below the weighing box bottom plate 14, the middle part of the weighing box bottom plate is fixedly connected with a weighing contact of the weighing sensor 15, a connecting rod 13 is arranged at the bottom of the weighing sensor 15, one end of the connecting rod is fixedly connected with the bottom of the weighing sensor, the other end of the connecting rod is provided with a rotating shaft and is fixedly connected with the rotating shaft, two ends of the rotating shaft are rotatably connected with a bracket through bearings, a turnover motor 12 is arranged at the end part of the rotating shaft, the turnover motor 12 drives the rotating shaft to rotate for a certain angle so as to drive the connecting rod and the weighing box bottom plate to rotate together, a shaping funnel 7 is arranged below the weighing box, a split charging conveyor belt is arranged below the shaping funnel 7, a photoelectric switch is arranged at a position corresponding to the shaping funnel on the split charging conveyor belt, a dispensing box 6 is provided on the conveyor.

The annular cover is in an inverted funnel shape with a small upper part and a large lower part for facilitating the vermicelli to fall on the chute.

In this scheme, annular cover bottom sets up two partial shipment spouts, certainly can set up more partial shipment spouts as required.

Because the vermicelli is separated by the centrifugal force when the separating cylinder rotates and is thrown out from the grid-shaped opening of the separating cylinder, the edges of the grid-shaped opening on the side wall of the separating cylinder need to be processed smoothly in order to prevent the surface of the vermicelli from being scratched.

In order to prevent the vermicelli from falling into the shaping hopper 7 due to too high sliding speed when the weighing box is opened, baffles 16 can be arranged on two sides below the weighing box 8 and in the discharging direction to prevent the vermicelli from splashing during discharging.

When the quantitative vermicelli packing equipment is used, equipment is started, vermicelli is put on a feeding conveyor belt, the vermicelli is fed and conveyed into a separating device, the vermicelli is evenly thrown out of a grid-shaped opening on the side wall of the separating tube under the rapid rotation of the separating tube, the thrown vermicelli slides into a packing chute along the inner wall of an annular cover, the vermicelli slides into a weighing box 8 along the packing chute, when a weighing sensor at the bottom of the weighing box senses that the vermicelli reaches a preset weight in the weighing box, a vibrating motor at the bottom of the packing chute is firstly closed, the vermicelli is prevented from continuously entering the weighing box, a bottom plate of the weighing box is opened, the vermicelli slides into a shaping hopper, and falls into the packing box along the shaping hopper, at the moment, the packing conveyor belt is started, the packing box filled with the vermicelli is conveyed to a designated position, whether the next packing box is positioned or not is sensed through a photoelectric switch, and the quantitative vermicelli packing process is repeated after the next packing box is positioned.

Having described embodiments of the present invention in detail, it will be apparent to those skilled in the art that various changes and modifications can be made therein without departing from the scope and spirit of the invention as defined in the appended claims, and any simple, equivalent changes and modifications to the above examples are intended to be within the scope of the present invention and the invention is not limited to the embodiments as set forth in the specification.

Claims

1. The utility model provides a bean vermicelli ration partial shipment equipment, includes throw material conveyer belt, throws hopper, bean vermicelli separator, weighing device, plastic hopper, divides dress box, partial shipment conveyer belt, support, its characterized in that: the feeding hopper is arranged on the support, a feeding conveyor belt is arranged on one side of the feeding hopper, the discharge end of the feeding conveyor belt is positioned above the feeding hopper, a vermicelli separating device is arranged below the feeding hopper and comprises a separating cylinder, a separating motor, an annular cover and a split charging chute, the separating cylinder is arranged below the feeding hopper and is a cylindrical container with an upper opening, grid-shaped openings are uniformly arranged on the side wall of the separating cylinder, the center of the bottom of the separating cylinder is connected with a rotating shaft of the separating motor, the separating motor can drive the separating cylinder to rotate, the separating motor is fixedly connected with the support, the annular cover is arranged outside the separating cylinder and fixedly connected with the support, a plurality of split charging chutes are arranged at the bottom of the annular cover, a vibrating motor is arranged at the bottom of the split charging chute, a weighing device is arranged at the outlet of the split charging chute and comprises a weighing box which is a container with an upper opening, the weighing box bottom plate and the side wall of the weighing box are of a split structure, a weighing sensor is arranged below the weighing box bottom plate, the middle part of the weighing box bottom plate is fixedly connected with a weighing contact of the weighing sensor, the bottom of the weighing sensor is provided with a connecting rod, one end of the connecting rod is fixedly connected with the bottom of the weighing sensor, the other end of the connecting rod is provided with a rotating shaft and is fixedly connected with the rotating shaft, two ends of the rotating shaft are rotatably connected with a bracket through bearings, a turnover motor is arranged at the end part of the rotating shaft, the turnover motor drives the rotating shaft to rotate by a certain angle so as to drive the connecting rod and the weighing box bottom plate to rotate together, a shaping hopper is arranged below the weighing box, a split charging conveyor belt is arranged below the shaping hopper, a photoelectric switch is arranged at a position corresponding to the shaping hopper on the split charging conveyor belt, the split charging box is arranged on the conveyor belt, the annular cover is in the shape of an inverted hopper with the upper part being small and the lower part, two sides below the weighing box and the discharging direction are provided with baffles, prevent splashing during discharging.

2. The vermicelli quantitative packaging equipment according to claim 1, wherein: two split charging sliding grooves are formed in the bottom of the annular cover.

3. The vermicelli quantitative packaging equipment according to claim 1, wherein: the edge of the grid-shaped opening on the side wall of the separating cylinder needs to be treated smoothly, so that the surface of the vermicelli is prevented from being scratched.

4. A quantitative vermicelli packaging method, which is characterized by comprising the following steps when using the quantitative vermicelli packaging equipment of any one of claims 1-3: firstly, starting equipment, throwing the vermicelli on a feeding conveyor belt, conveying the vermicelli into a separating device, throwing the vermicelli out of a grid-shaped opening on the side wall of a separating cylinder uniformly under the rapid rotation of the separating cylinder, sliding the thrown vermicelli into a split charging chute along the inner wall of an annular cover, sliding the vermicelli into a weighing box along the split charging chute, when a weighing sensor at the bottom of the weighing box senses that the vermicelli in the weighing box reaches a preset weight, firstly, closing a vibrating motor at the bottom of the split charging chute to prevent the vermicelli from continuously entering the weighing box, opening a bottom plate of the weighing box, sliding the vermicelli into a shaping hopper, falling into the split charging box along the shaping hopper, starting the split charging conveyor belt at the moment, conveying the split charging box filled with the vermicelli to a designated position, sensing whether the next split charging box is in place or not through a photoelectric switch, and repeating the process after the next split charging box is in place or not, thereby achieving the purpose of quantitatively split charging the vermicelli.