CN112874893A

CN112874893A - Automatic processing assembly line and processing method for pleurotus eryngii

Info

Publication number: CN112874893A
Application number: CN202110021983.7A
Authority: CN
Inventors: 王健兴
Original assignee: Fujian Qixun Food Co ltd
Current assignee: Fujian Qixun Food Co ltd
Priority date: 2021-01-08
Filing date: 2021-01-08
Publication date: 2021-06-01
Anticipated expiration: 2041-01-08
Also published as: CN112874893B

Abstract

The invention provides an automated processing line for pleurotus eryngii, which comprises a film covering device for covering a film on pleurotus eryngii strains, a slicing device for slicing the grown pleurotus eryngii, a strip cutting device for cutting the sliced pleurotus eryngii into strips at the downstream of the slicing device, and a packaging device for packaging the strips of pleurotus eryngii at the downstream of the strip cutting device. According to the automatic processing assembly line for the pleurotus eryngii, disclosed by the invention, the pleurotus eryngii is sliced and sliced into strips through the front and back matching of the slicing device and the strip cutting device, and then the pleurotus eryngii is packaged through the packaging device, so that the automatic processing assembly line is formed, the processing efficiency is increased, and the cost is saved. An automated processing method of pleurotus eryngii comprises the following steps: a. cleaning pleurotus eryngii; b. slicing to form flaky pleurotus eryngii; c. slicing the flaky pleurotus eryngii to form strip-shaped pleurotus eryngii; d. and (5) boxing and packaging. The automatic processing method of the pleurotus eryngii, disclosed by the invention, is automatic, convenient and quick, and improves the processing efficiency of the pleurotus eryngii.

Description

Automatic processing assembly line and processing method for pleurotus eryngii

Technical Field

The invention relates to the technical field of agricultural food processing, in particular to an automatic pleurotus eryngii processing assembly line and a processing method.

Background

Abalone mushroom, a kind of edible mushroom that grows in the european mediterranean region, the middle east and north africa, but also in parts of asia, is named because it has the aroma of almond and the fleshy flesh like the taste of abalone, and is relatively troublesome to process and package, and is time-consuming.

Accordingly, the present inventors have made extensive studies to solve the above problems and have made the present invention.

Disclosure of Invention

The invention aims to provide an automatic pleurotus eryngii processing line which can automatically slice, cut and package pleurotus eryngii and improve the production efficiency.

The invention aims to provide an automatic pleurotus eryngii processing method, which enables pleurotus eryngii to be processed efficiently and quickly.

In order to achieve the purpose, the invention adopts the following technical scheme:

the utility model provides an automatic assembly line of processing of apricot bao mushroom which characterized in that: comprises a slicing device for slicing pleurotus eryngii, a slitting device for slitting the sliced pleurotus eryngii into strips at the downstream of the slicing device, and a packaging device for packaging the strips of pleurotus eryngii at the downstream of the slitting device.

The laminating device comprises a granulator for granulating pleurotus eryngii strains into granules, a receiving device which is positioned at an output port of the granulator and receives the granules and soaks the granules with liquid in the granules, and a powder wrapping device which is positioned at an output port of the receiving device and wraps the granules with powder and laminated film.

The supporting device comprises a supporting disc for supporting particles, a containing box for containing liquid and allowing the supporting disc to soak, and a driver for driving the supporting disc to lift, rotate and overturn.

The bottom and the side wall of the bearing plate are provided with through holes with the diameter smaller than that of the particles.

The driver comprises a turnover motor fixedly connected with the side wall of the bearing plate, a lifting driving cylinder for driving the turnover motor to lift, and a rotating motor for driving the lifting driving cylinder to horizontally rotate.

Wrap up in whitewashed device and wrap up in the vibration transmission band of powder including being located the vibration of accepting the device delivery outlet to and be used for installing the vibration transmission band and accept and wrap up in the transmission channel of the good granule of powder tectorial membrane.

The slicing device comprises a transmission channel for transmitting the pleurotus eryngii and a cutter piece arranged at the output end of the transmission channel.

The transmission way comprises a first transmission belt and a second transmission belt which have the same transmission direction and are respectively positioned above and below the pleurotus eryngii, and a first guide member and a second guide member which are positioned between the first transmission belt and the second transmission belt and guide the pleurotus eryngii.

The first guide piece and the second guide piece are arranged in an axisymmetric manner by taking the transmission direction of the first transmission belt as an axis.

The first guide piece comprises a first guide plate in contact with pleurotus eryngii, a first vertical plate for mounting the first guide plate, and a first elastic piece fixed between the first guide plate and the first vertical plate.

The structure of the second guide member is identical to that of the first guide member.

The slitting device comprises a first conveying piece for conveying flaky pleurotus eryngii, a second conveying piece which is arranged above the first conveying piece and matched with the first conveying piece, and a multi-knife assembly which is arranged on the first conveying piece and the second conveying piece and used for cutting.

The first conveying piece comprises a plurality of first conveying belts arranged side by side, and a gap is formed between every two adjacent first conveying belts; the multiple-blade assembly includes a plurality of blades respectively disposed in the gap.

The second conveying piece comprises a plurality of second conveying belts which are respectively positioned on the same vertical surface with the first conveying belts.

The packaging device comprises a conveying device located at the output part of the slitting device, a stacking device arranged at the output part of the conveying device and used for stacking and guiding the strip-shaped pleurotus eryngii, a packaging box located below the stacking device, a box conveying belt used for conveying the packaging box, and a sealing device arranged on one side of the box conveying belt and used for sealing the packaging box.

Pile up the device and pile up the way including the funnel of accepting strip apricot bao mushroom, connect the direction of funnel delivery outlet to and two installation directions pile up the way and carry out first blocking device and the second blocking device that blocks.

The first blocking device comprises a first blocking plate, a first rack, a first gear and a first driving motor, wherein the first blocking plate penetrates through one side wall of the guide stacking channel and is arranged in the guide stacking channel, the first rack is connected below the first blocking plate, the first gear is matched with the first rack, and the first driving motor is fixedly installed on the outer wall of the guide stacking channel and drives the first gear to rotate.

The cover sealing device comprises a sealing cover which is covered on the packaging box, a grabbing component which is covered on the packaging box by the grabbing sealing cover, and a placing frame which is used for placing the sealing cover.

Snatch the subassembly and including the absorption mouth that absorbs sealed lid, drive absorption mouth reciprocates lifting cylinder to and drive lifting cylinder is placing and putting up pivoted rotation motor between the packing carton.

An automated processing method of pleurotus eryngii comprises the following steps:

a. cleaning pleurotus eryngii;

b. slicing to form flaky pleurotus eryngii;

c. slicing the flaky pleurotus eryngii to form strip-shaped pleurotus eryngii;

d. and (5) boxing and packaging.

And in the step b, slicing the pleurotus eryngii by adopting a slicing device, carrying out pleurotus eryngii transmission on the transmission channel, and slicing the pleurotus eryngii by descending the cutter piece.

And c, cutting the flaky pleurotus eryngii into strips by adopting a strip cutting device, wherein the first conveying piece and the second conveying piece are matched for conveying the flaky pleurotus eryngii, and the multi-blade assembly cuts the flaky pleurotus eryngii to form a plurality of pleurotus eryngii strips.

In the step d, the packaging device is adopted to stack and package strip-shaped pleurotus eryngii, the first blocking device is in an open state, the strip-shaped pleurotus eryngii enters the guide stacking channel along the funnel and is placed on the second blocking device, when the stack is full, the first blocking device is closed, the second blocking device is opened to enable the stacked strip-shaped pleurotus eryngii to fall into the packaging box, and the box conveying belt conveys the packaging box to the cover sealing device for cover sealing.

After the technical scheme is adopted, the pleurotus eryngii automatic processing assembly line provided by the invention slices and strips the pleurotus eryngii through the front and back matching of the slicing device and the strip cutting device, and then packages the pleurotus eryngii through the packaging device, so that an automatic processing production assembly line is formed, the processing efficiency is increased, and the cost is saved.

The automatic processing method of the pleurotus eryngii, disclosed by the invention, is automatic, convenient and quick, and improves the processing efficiency of the pleurotus eryngii.

Drawings

FIG. 1 is a schematic diagram of the construction of a process line according to the present invention;

FIG. 2 is a schematic structural view of the slicing apparatus according to the present invention;

FIG. 3 is a schematic view of the construction of the first guide member and the second guide member of the present invention;

FIG. 4 is a schematic structural diagram of the slitting device according to the present invention;

FIG. 5 is a schematic view of the detailed structure of the first conveying member and the multi-blade assembly of the present invention;

FIG. 6 is a schematic view of the structure of the packaging device of the present invention;

FIG. 7 is a schematic structural diagram of a stacking apparatus according to the present invention;

FIG. 8 is a schematic view of a first blocking device according to the present invention;

FIG. 9 is a schematic view of the grasping element according to the present invention;

FIG. 10 is a schematic view of the film covering device of the present invention;

FIG. 11 is a schematic view of the receiving device of the present invention;

fig. 12 is a schematic structural view of the powder coating device of the invention.

In the figure:

the slicing device comprises a slicing device 1, a conveying channel 11, a cutting knife piece 12, a first transmission belt 13, a second transmission belt 14, a first guide piece 15, a second guide piece 16, a first guide plate 17, a first vertical plate 18 and a first elastic piece 19;

the slitting device 2, the first conveying member 21, the second conveying member 22, the multi-knife assembly 23, the first conveying belt 24, the blade 25 and the second conveying belt 26;

the packaging device 3, the transporting device 31, the stacking device 32, the packaging box 33, the box conveying belt 34, the capping device 35, the funnel 36, the guiding and stacking channel 37, the first blocking device 38, the second blocking device 39, the first blocking plate 310, the first rack 311, the first gear 312, the first driving motor 313, the sealing cover 314, the grabbing component 315, the placing frame 316, the adsorption nozzle 317, the lifting cylinder 318 and the rotating motor 319;

the device comprises a film coating device 4, a granulator 41, a bearing device 42, a powder wrapping device 43, a bearing disc 44, a containing box 45, a driver 46, a through hole 47, a turnover motor 48, a lifting driving cylinder 49, a rotating motor 410, a vibration conveying belt 411 and a conveying channel 412.

Detailed Description

In order to further explain the technical solution of the present invention, the following detailed description is given by way of specific examples.

The automated processing line for pleurotus eryngii of the present invention, as shown in fig. 1-12, includes a slicing device 1 for slicing pleurotus eryngii, a strip cutting device 2 for cutting sliced pleurotus eryngii into strips located at the downstream of the slicing device 1, and a packaging device 3 for packaging strips of pleurotus eryngii located at the downstream of the strip cutting device 2. Slicing and slitting pleurotus eryngii through the cooperation of the slicing device 1 and the slitting device 2, and then packaging through the packaging device 3 to form an automatic processing production line, so that the processing efficiency is increased, and the cost is saved.

Preferably, the film covering device 4 comprises a granulator 41 for granulating pleurotus eryngii strains into granules, a receiving device 42 which is positioned at an output port of the granulator 41 and used for receiving the granules and soaking the granules in liquid, and a powder coating device 43 which is positioned at an output port of the receiving device 42 and used for coating the granules with powder. Pleurotus eryngii strains are manufactured into granules through a granulator 41 for convenient planting, and then the granules are soaked and wrapped with degradable powder to form a degradable film coating layer on the surfaces of the granules.

Preferably, the receiving device 42 includes a receiving tray 44 for receiving the particles, a holding box 45 for holding the liquid and allowing the receiving tray 44 to be soaked, and a driver 46 for driving the receiving tray 44 to move up and down, rotate and turn over. The receiving tray 44 receiving the pellets is driven by the driver 46 to be completely immersed in the containing box 45.

Preferably, the bottom and side walls of the tray 44 are provided with through holes 47 having a diameter smaller than the diameter of the pellets. The liquid can flow into the bearing disc 44 through the through holes 47 and also can flow out of the bearing disc 44, so that the particles can be soaked conveniently.

Preferably, the driver 46 includes a turnover motor 48 fixedly connected to the sidewall of the tray 44, a lifting driving cylinder 49 for driving the turnover motor 48 to ascend and descend, and a rotating motor 410 for driving the lifting driving cylinder 49 to horizontally rotate. The lifting driving cylinder 49 drives the turnover motor 48 to drive the receiving disc 44 to descend and soak in the liquid in the containing box 45, then the lifting driving cylinder 49 is driven by the rotating motor 410 to drive the turnover motor 48 to horizontally rotate and be arranged above the powder wrapping device 43, and then the turnover motor 48 drives the receiving disc 44 to turn over to pour the particles in the receiving disc 44 into the powder wrapping device 43.

Preferably, the output of the inverter motor 48 is connected to the uppermost end of the side wall of the tray 44.

Preferably, the powder coating device 43 includes a vibrating conveyor belt 410 for vibrating the coated powder at the output of the receiving device 42, and a conveying channel 412 for mounting the vibrating conveyor belt 410 and receiving the coated powder particles. The granules are subjected to vibration coating on the vibration conveying belt 410, and then fall into the groove bottom of the conveying channel 412 to wait for manual collection.

Preferably, the slicing apparatus 1 includes a conveying path 11 for conveying pleurotus eryngii, and a cutter member 12 installed at an output end of the conveying path 11. The pleurotus eryngii is transmitted through the transmission channel 11 and then is sliced by descending the cutter 12.

Preferably, the conveying path 11 comprises two first and

second belts

13, 14, which have the same conveying direction and are respectively positioned above and below the pleurotus eryngii, and two first and

second guide members

15, 16, which are positioned between the first and

second belts

13, 14 and guide the pleurotus eryngii. The first transmission belt 13 and the second transmission belt 14 are matched with each other to transmit the pleurotus eryngii, and the first guide member 15 and the second guide member 16 are matched with each other to ensure that the transmission direction of the pleurotus eryngii is stable.

Preferably, the first guide 15 and the second guide 16 are arranged axisymmetrically with respect to the first belt 13 transport direction. Ensuring more stable guiding.

Preferably, the first guide 15 includes a first guide plate 17 contacting with pleurotus eryngii, a first standing plate 18 for mounting the first guide plate 17, and a first elastic member 19 fixed between the first guide plate 17 and the first standing plate 18. Different sizes of pleurotus eryngii can be automatically adapted through the first elastic member 19.

Preferably, the structure of the second guide 16 corresponds to the structure of the first guide 15. Stably engaged with the first guide member 15.

Preferably, the slitting device 2 comprises a first conveyor 21 for conveying the sliced pleurotus eryngii, a second conveyor 22 positioned above the first conveyor 21 and engaged with the first conveyor 21, and a multi-blade assembly 23 mounted on the first conveyor 21 for slitting. The sheet-shaped pleurotus eryngii is transported by the first and

second conveyors

21 and 22, and then cut by the multi-blade assembly 23 to form a plurality of strips of pleurotus eryngii.

Preferably, the first conveying member 21 includes a plurality of first conveying belts 24 arranged side by side, and a gap is formed between adjacent first conveying belts 24; the multiple-blade assembly 23 includes a plurality of blades 25 each disposed within a gap. So that the sheet-shaped pleurotus eryngii is cut into a plurality of pieces at a time by the plurality of blades 25 while being transported.

Preferably, second transport member 22 includes a plurality of second conveyor belts 26 that are each vertically co-planar with the plurality of first conveyor belts 24. And is better fitted with the first conveying member 21.

Preferably, the packing device 3 includes a transporting device 31 at an output of the slitting device 2, a stacking device 32 installed at the output of the transporting device 31 for stacking and guiding the strip-shaped pleurotus eryngii, a packing box 33 located below the stacking device 32, a box conveying belt 34 for conveying the packing box 33, and a capping device 35 installed at one side of the box conveying belt 34 for capping the packing box 33. The cut strip-shaped pleurotus eryngii is transported to the stacking device 32 through the transporting device 31, stacked in a pile and put into the packing boxes 33, then the packing and the covering are carried out through the covering device 35, and the packing boxes 33 are transported intermittently by the box transporting belt 34.

Preferably, the stacking device 32 comprises a funnel 36 for receiving the strip-shaped pleurotus eryngii, a guide stacking channel 37 connected to the output port of the funnel 36, and two first blocking devices 38 and second blocking devices 39 for installing the guide stacking channel 37 to block; the first blocking means 38 is located above the second blocking means 39. The first blocking device 38 is opened first, then the strip-shaped pleurotus eryngii enters the guide stacking channel 37 along the funnel 36 and is placed on the second blocking device 39, when the stack is full, the second blocking device 39 is closed by the first blocking device 38, the stack-shaped pleurotus eryngii falls into the packaging box 33, and then the packaging box 33 is conveyed to the capping device 35 through the box conveying belt 34 for capping.

Preferably, the first blocking device 38 includes a first blocking plate 310 penetrating through a side wall of the guide stacking channel 37 and disposed in the guide stacking channel 37, a first rack 311 connected below the first blocking plate 310, a first gear 312 engaged with the first rack 311, and a first driving motor 313 fixedly installed on an outer wall of the guide stacking channel 37 and driving the first gear 312 to rotate. The first gear 312 is driven to rotate by the first driving motor 313, and the first blocking plate 310 is horizontally moved to block the guide stacking path 37 or not to block the guide stacking path 37 by the cooperation of the first gear 312 and the first rack 311.

Preferably, the closing means 35 comprises a sealing cover 314 covering the package 33, a grasping assembly 315 grasping the sealing cover 314 covering the package 33, and a placing frame 316 on which the sealing cover 314 has been placed. The sealing cover 314 gripping the placing frame 316 by the gripping assembly 315 is put on the packing box 33.

Preferably, the grasping assembly 315 includes a suction nozzle 317 for sucking the sealing cover 314, a lifting cylinder 318 for driving the suction nozzle 317 to move up and down, and a rotation motor 319 for driving the lifting cylinder 318 to rotate between the placing frame 316 and the packing box 33. The lifting cylinder 318 is driven by the rotating motor 319 to drive the adsorption nozzle 317 to rotate and be arranged above the placing frame 316, the lifting cylinder 318 drives the adsorption nozzle 317 to move downwards to adsorb the sealing cover 314 and then move upwards, the adsorption nozzle 317 is driven to rotate by the rotating motor 319 to be arranged above the packing box 33, and then the lifting cylinder 318 drives the adsorption nozzle 317 to move downwards to drive the sealing cover 314 to cover the packing box 33.

Preferably, the suction portion of the suction nozzle 317 is shaped to match the sealing cap 314. Preferably a suction sealing cap 314 and a covering sealing cap 314.

a. cleaning pleurotus eryngii;

b. slicing to form flaky pleurotus eryngii;

c. slicing the flaky pleurotus eryngii to form strip-shaped pleurotus eryngii;

d. and (5) boxing and packaging.

Preferably, in the step b, the slicing device 1 is used for slicing the pleurotus eryngii, the conveying channel 11 is used for conveying the pleurotus eryngii, and the cutter 12 descends to slice the pleurotus eryngii.

Preferably, in step c, the slicing device 2 is used for slicing the sliced pleurotus eryngii, the first conveying member 21 and the second conveying member 22 are matched to convey the sliced pleurotus eryngii, and the multi-blade assembly 23 is used for cutting the sliced pleurotus eryngii to form a plurality of pleurotus eryngii strips.

Preferably, in step d, the strip-shaped pleurotus eryngii is stacked and packaged by the packaging device 3, the first blocking device 38 is in an open state, the strip-shaped pleurotus eryngii enters the guide stacking channel 37 along the funnel 36 and is placed on the second blocking device 39, when the stack is full, the first blocking device 38 is closed, the second blocking device 39 is opened, the stacked strip-shaped pleurotus eryngii falls into the packaging box 33, and the packaging box conveying belt 34 conveys the packaging box 33 to the capping device 35 for capping.

The product form of the present invention is not limited to the embodiments and examples shown in the present application, and any suitable changes or modifications of the similar ideas should be made without departing from the patent scope of the present invention.

Claims

1. The utility model provides an automatic processing water line of apricot bao mushroom, includes the tectorial membrane device that carries out the tectorial membrane to the apricot bao mushroom bacterial, its characterized in that: the device also comprises a slicing device for slicing the grown pleurotus eryngii, a strip cutting device for slicing the sliced pleurotus eryngii into strips at the downstream of the slicing device, and a packaging device for packaging the strips of pleurotus eryngii at the downstream of the strip cutting device.

2. The automated processing line for pleurotus eryngii according to claim 1, which is characterized in that: the laminating device comprises a granulator for granulating pleurotus eryngii strains into granules, a receiving device which is positioned at an output port of the granulator and receives the granules and soaks the granules with liquid in the granules, and a powder wrapping device which is positioned at an output port of the receiving device and wraps the granules with powder and laminated film.

3. The automated processing line for pleurotus eryngii according to claim 2, wherein: the supporting device comprises a supporting disc for supporting particles, a containing box for containing liquid and allowing the supporting disc to soak, and a driver for driving the supporting disc to lift, rotate and overturn.

4. The automated processing line for pleurotus eryngii according to claim 3, which is characterized in that: the bottom and the side wall of the bearing plate are provided with through holes with the diameter smaller than that of the particles.

5. The automated processing line for pleurotus eryngii according to claim 4, wherein: the driver comprises a turnover motor fixedly connected with the side wall of the bearing plate, a lifting driving cylinder for driving the turnover motor to lift, and a rotating motor for driving the lifting driving cylinder to horizontally rotate.

6. The automated processing line for pleurotus eryngii according to claim 2, wherein: wrap up in whitewashed device and wrap up in the vibration transmission band of powder including being located the vibration of accepting the device delivery outlet to and be used for installing the vibration transmission band and accept and wrap up in the transmission channel of the good granule of powder tectorial membrane.

7. The automated processing line for pleurotus eryngii according to claim 1, which is characterized in that: the slicing device comprises a transmission channel for transmitting the pleurotus eryngii and a cutter piece arranged at the output end of the transmission channel.

8. The automated processing line for pleurotus eryngii according to claim 7, which is characterized in that: the transmission way comprises a first transmission belt and a second transmission belt which have the same transmission direction and are respectively positioned above and below the pleurotus eryngii, and a first guide member and a second guide member which are positioned between the first transmission belt and the second transmission belt and guide the pleurotus eryngii.

9. The automated processing line for pleurotus eryngii according to claim 8, wherein: the first guide piece and the second guide piece are arranged in an axisymmetric manner by taking the transmission direction of the first transmission belt as an axis.

10. The automated processing line for pleurotus eryngii according to claim 9, which comprises: the first guide piece comprises a first guide plate in contact with pleurotus eryngii, a first vertical plate for mounting the first guide plate, and a first elastic piece fixed between the first guide plate and the first vertical plate.