CN114516077A

CN114516077A - Adjustable agaricus bisporus slicing device

Info

Publication number: CN114516077A
Application number: CN202210181761.6A
Authority: CN
Inventors: 朱海涛; 周裔彬
Original assignee: Anhui Agricultural University AHAU
Current assignee: Anhui Agricultural University AHAU
Priority date: 2022-02-25
Filing date: 2022-02-25
Publication date: 2022-05-20

Abstract

The invention provides an adjustable agaricus bisporus slicing device, which comprises a slicing table and a slicing mechanism; a plurality of material grooves which are parallel to each other are arranged on the slicing table at intervals; the slicing mechanism comprises a mounting plate, a moving plate, a first driving mechanism and a second driving mechanism; the mounting plate is positioned above the slicing table and parallel to the slicing table, the mounting plate is driven by a first driving mechanism to be close to or far away from the slicing table, slicing assemblies are arranged at the bottom of the mounting plate and correspond to the material grooves, each slicing assembly comprises a plurality of main cutters which are arranged in parallel at intervals, and a through groove is formed in the mounting plate and positioned between any two adjacent main cutters; the movable plate is located the mounting panel top and is close to or keeps away from the mounting panel by the drive of second actuating mechanism, and the bottom of the movable plate all is installed with the regulation cutter and adjusts the cutter and can pass through logical groove with each logical groove corresponding position. The slicing thickness can be adjusted, a plurality of agaricus bisporus in the material groove can be sliced at the same time, and the slicing efficiency and the practicability are high.

Description

Adjustable agaricus bisporus slicing device

Technical Field

The invention relates to the technical field of food processing equipment, in particular to an adjustable agaricus bisporus slicing device.

Background

The agaricus bisporus is one of the most common edible strains, is easy to artificially culture, has high yield and fleshy meat, is rich in mannose, trehalose, various amino acids, mineral elements and other nutrient substances, tastes delicious and is rich in nutrition. Due to indoor planting of the agaricus bisporus, the agaricus bisporus can be harvested for multiple times every month, the yield is extremely high, the amount of the fresh edible dishes is limited, and further processing is needed to solve the planting economic benefit. At present, firstly, the agaricus bisporus is cleaned, sliced and dried to be made into mushroom slices, which are convenient to package and store; and secondly, the fresh agaricus bisporus is made into cans by the processes of cleaning, filtering, grading, slicing, canning, sterilizing and the like, so that the storage time can be prolonged without losing the delicious taste. The two processing modes of the agaricus bisporus can automatically complete the slicing operation of the agaricus bisporus by a slicing machine, the slicing devices in the market are more at present, but the slicing devices are fixed in specification, and because the agaricus bisporus is not uniform in size, the slicing device for the agaricus bisporus cannot be used for quickly meeting the slicing requirements of the agaricus bisporus with all sizes, and meanwhile, the slicing thickness cannot be flexibly adjusted according to the requirements, so that the flexible and multipurpose slicing device is very necessary to design.

Disclosure of Invention

Based on the technical problems in the background art, the invention provides an adjustable agaricus bisporus slicing device.

The invention provides an adjustable agaricus bisporus slicing device, which comprises a slicing table and a slicing mechanism, wherein the slicing table is provided with a cutting table frame; a plurality of material grooves which are parallel to each other are arranged on the slicing table at intervals; the slicing mechanism comprises a mounting plate, a moving plate, a first driving mechanism and a second driving mechanism; the mounting plate is positioned above the slicing table and parallel to the slicing table, the mounting plate is driven by a first driving mechanism to be close to or far away from the slicing table, slicing assemblies are arranged at the bottom of the mounting plate and correspond to the material grooves, each slicing assembly comprises a plurality of main cutters which are arranged in parallel at intervals, and a through groove is formed in the mounting plate and positioned between any two adjacent main cutters; the movable plate is located the mounting panel top and is close to or keeps away from the mounting panel by the drive of second actuating mechanism, and the bottom of the movable plate all is installed with the regulation cutter and adjusts the cutter and can pass through logical groove with each logical groove corresponding position.

Preferably, the slicing table is provided with two opposite mounting frames, the inner sides of the mounting frames are respectively provided with a first linear guide rail which is vertically arranged, and two ends of the mounting frames are respectively connected with the two first linear guide rails in a sliding fit manner; the first driving mechanism comprises two first air cylinders which are respectively arranged on the two mounting frames, and the two first air cylinders are respectively connected with the two ends of the mounting frame.

Preferably, two opposite vertical frames are installed at the top end of the installation plate, vertically-arranged second linear guide rails are installed on the inner sides of the vertical frames, and two ends of the moving plate are connected with the two second linear guide rails in a sliding fit mode respectively.

Preferably, one side of the moving plate, which is far away from the mounting plate, is provided with a fixing plate parallel to the moving plate, and two ends of the fixing plate are respectively connected with the two vertical frames; the second driving mechanism comprises a plurality of mounting shafts and a driving motor, the mounting shafts are rotatably mounted on the fixing plate at intervals, the driving motor is in transmission connection with one of the mounting shafts, synchronizing wheels are mounted on the mounting shafts, the synchronizing wheels are in transmission connection through synchronous belts, and cams are mounted on the mounting shafts; the bottom of the moving plate is connected with a plurality of springs which are connected with the mounting plate.

Preferably, the cam has a first position state and a second position state; when the cam is in a first position state, one end of the cam, which is close to the mounting shaft, abuts against the moving plate, the spring is in a natural state, and the cutting edges of the plurality of adjusting cutters are respectively positioned in the plurality of through grooves; when the cam is in the second position state, one end of the cam, far away from the mounting shaft, abuts against the moving plate and the spring is in a compression state, the adjusting cutters respectively penetrate through the through grooves, and the cutting edges of the adjusting cutters and the cutting edge of the main cutter are located on the same horizontal line.

Preferably, the lengths of the main cutter and the adjusting cutter are matched with the length of the material groove, and the length directions of the main cutter and the adjusting cutter are consistent with the length direction of the material groove.

Preferably, the slicing table is provided with a turning plate, a plurality of material grooves are parallelly installed on the turning plate at intervals, one end of each material groove is provided with a feed inlet, the other end of each material groove is provided with a discharge outlet, one end of the bottom of each turning plate, which is close to the discharge outlet of each material groove, is rotatably connected with the slicing table, and the slicing table is provided with a second cylinder for driving the turning plate to rotate.

Preferably, the turning plate is rotatably provided with a baffle capable of plugging a plurality of material groove discharge ports, and the turning plate is provided with a third cylinder for driving the baffle to rotate.

Preferably, the material feeding device further comprises a feeding conveying mechanism which can be in butt joint with the feeding holes of the plurality of material grooves and can convey materials into the material grooves.

Preferably, the device also comprises a discharge conveying mechanism which can be butted with the discharge ports of the plurality of material grooves.

According to the adjustable agaricus bisporus slicing device provided by the invention, agaricus bisporus to be sliced is placed in a material groove, a first driving mechanism drives a mounting plate to descend to be close to a slicing table, a plurality of main cutters of a slicing assembly slice the agaricus bisporus in the material groove, and the distance between every two adjacent main cutters is the thickness of agaricus bisporus slices; when the thickness of the agaricus bisporus slices needs to be reduced, the second driving mechanism drives the moving plate to descend to be close to the mounting plate, so that the adjusting cutter penetrates through the through groove, and the distance between the main cutter and the adjacent adjusting cutter is the thickness of the slices. The invention can not only adjust the slicing thickness, but also slice a plurality of agaricus bisporus in the material groove at the same time, has higher slicing efficiency and good practicability. Meanwhile, the agaricus bisporus feeding and slicing device is convenient to feed agaricus bisporus and discharge sliced materials by arranging the turning plate, the baffle plate, the feeding conveying mechanism and the discharging conveying mechanism.

Drawings

FIG. 1 is a first state structural diagram of an adjustable agaricus bisporus slicing device according to the present invention;

FIG. 2 is a second state structural diagram of an adjustable agaricus bisporus slicing device according to the present invention;

fig. 3 is a schematic diagram of a turning plate structure in an adjustable agaricus bisporus slicing device provided by the invention.

Detailed Description

Referring to fig. 1-3, the invention provides an adjustable agaricus bisporus slicing device, which comprises a slicing table 1 and a slicing mechanism; a plurality of material grooves 2 which are parallel to each other are arranged on the slicing table 1 at intervals, and the slicing mechanism comprises an installation plate 3, a moving plate 4, a first driving mechanism and a second driving mechanism. Wherein:

mounting panel 3 is located slicing table 1 top and is on a parallel with slicing table 1, and slicing table 1 is last to install two mutual dispositions's mounting bracket 5, and the first linear guide rail of vertical arrangement is all installed to mounting bracket 5 inboard, and 3 both ends of mounting panel are connected with two first linear guide rail sliding fit respectively. The slicing assembly is installed at the bottom of the mounting plate 3 and corresponding to the material grooves 2, the slicing assembly comprises a plurality of main cutters 6 arranged at intervals in parallel, and the mounting plate 3 is located between any two adjacent main cutters 6, and through grooves 7 are formed in the positions. The mounting plate 3 is driven closer to or farther from the slicing table 1 by a first driving mechanism.

The movable plate 4 is located the mounting panel 3 top, and two mutual dispositions's grudging post 8 are installed on 3 tops of mounting panel, and vertical second linear guide who arranges is all installed to grudging post 8 inboard, and 4 both ends of movable plate are connected with two second linear guide sliding fit respectively, and 4 bottoms of movable plate are connected with a plurality of springs 9 and a plurality of springs 9 all are connected with mounting panel 3, and 4 bottoms of movable plate and each lead to the corresponding position of groove 7 and all install and adjust cutter 10 and can pass through groove 7. The moving plate 4 is driven closer to or farther from the mounting plate 3 by a second driving mechanism.

In the embodiment, agaricus bisporus to be sliced is placed in a material groove 2, a first driving mechanism drives a mounting plate 3 to descend to be close to a slicing table 1, a plurality of main cutters 6 of a slicing assembly slice the agaricus bisporus in the material groove 2, and the distance between every two adjacent main cutters 6 is the thickness of the agaricus bisporus slices; when the thickness of the sliced agaricus bisporus needs to be reduced, the second driving mechanism drives the moving plate 4 to descend to be close to the mounting plate 3, so that the adjusting cutter 10 penetrates through the through groove 7, and the distance between the main cutter 6 and the adjacent adjusting cutter 10 is the thickness of the sliced agaricus bisporus. The embodiment can not only adjust section thickness, can also slice a plurality of bisporous mushroom in the material groove 2 simultaneously, has higher section efficiency, has fine practicality.

In this embodiment, the lengths of the main cutter 6 and the adjusting cutter 10 are matched with the length of the material groove 2, and the length directions of the main cutter 6 and the adjusting cutter 10 are consistent with the length direction of the material groove 2.

Specifically, the first driving mechanism includes two first cylinders 11, the two first cylinders 11 are respectively installed on the two mounting brackets 5, and the two first cylinders 11 are respectively connected with two ends of the mounting plate 3.

Specifically, the second drive mechanism includes a plurality of mounting shafts 12 and a drive motor. One side of the moving plate 4, which is far away from the mounting plate 3, is provided with a fixing plate 13 which is parallel to the moving plate, and two ends of the fixing plate 13 are respectively connected with the two vertical frames 8. A plurality of installation axle 12 interval rotates and installs on fixed plate 13 and driving motor is connected with one of them installation axle 12 transmission, all installs on a plurality of installation axles 12 between synchronizing wheel and a plurality of synchronizing wheel and connects through synchronous belt drive, all installs cam 14 on a plurality of installation axles 12. The cam 14 has a first position state and a second position state; when the cam 14 is in the first position state, one end of the cam 14 close to the mounting shaft 12 abuts against the moving plate 4, the spring 9 is in a natural state, and the cutting edges of the plurality of adjusting cutters 10 are respectively positioned in the plurality of through grooves 7; when the cam 14 is in the second position state, one end of the cam 14, which is far away from the mounting shaft 12, abuts against the moving plate 4, the spring 9 is in a compressed state, the adjusting cutters 10 respectively penetrate through the through grooves 7, and the cutting edges of the adjusting cutters 10 and the cutting edge of the main cutter 6 are in the same horizontal line. The motor works to drive the mounting shafts 12 to rotate, the mounting shafts 12 rotate to drive the cam 14 to rotate, and the moving plate 4 is driven to move under the action of the cam 14 and the spring 9.

Further, as shown in fig. 3, in order to facilitate the discharging of the agaricus bisporus slices, a turning plate 15 is installed on the slicing table, a plurality of material grooves 2 are installed on the turning plate 15 at intervals in parallel, a feed inlet is formed in one end of each material groove 2, a discharge outlet is formed in the other end of each material groove, one end, close to the discharge outlet of each material groove 2, of the bottom of the turning plate 15 is rotatably connected with the slicing table 1, and a second air cylinder 16 used for driving the turning plate 15 to rotate is installed on the slicing table 1. During slicing, the turning plate 15 is kept horizontal, after slicing is completed, the second air cylinder 16 works to drive the turning plate 15 to rotate, and the turning plate 15 is in a certain angle, so that the agaricus bisporus slices in the turning plate 15 are poured out.

Further, as shown in fig. 3, in order to facilitate the feeding of agaricus bisporus and the discharging of the sliced agaricus bisporus, a baffle 17 capable of plugging the discharge ports of the plurality of material tanks 2 is rotatably installed on the turning plate 15, and a third cylinder 18 for driving the baffle 17 to rotate is installed on the turning plate. The material feeding device also comprises a feeding and conveying mechanism 19 which can be butted with the feed inlets of the plurality of material grooves 2 and can convey materials into the material grooves 2. Also comprises a discharging conveying mechanism 20 which can be butted with the discharging holes of a plurality of material grooves 2. When the agaricus bisporus is fed, the baffle 17 blocks the discharge hole of the material groove 2, the second air cylinder 16 works to drive the turning plate 15 to rotate, so that the turning plate 15 forms a certain angle, the feed hole of the turning plate 15 is butted with the feed conveying mechanism 19, the agaricus bisporus is fed, the turning plate 15 forms a certain angle, so that the agaricus bisporus is fed more conveniently, and after the agaricus bisporus is fed, the second air cylinder 16 works to drive the turning plate 15 to rotate and reset, so that the turning plate 15 is horizontal; after the section is accomplished, when the section ejection of compact, third cylinder 18 drive baffle 17 rotates in order to open 2 discharge gates in material groove, and the 16 work of second cylinder drives turns over 15 rotations of board and makes and turns over 15 and be certain angles, and the section in the material groove 2 can be emptyd to discharge conveying mechanism 20 on, and discharge conveying mechanism 20 carries away the section.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. An adjustable agaricus bisporus slicing device is characterized by comprising a slicing table and a slicing mechanism; a plurality of material grooves which are parallel to each other are arranged on the slicing table at intervals; the slicing mechanism comprises an installation plate, a moving plate, a first driving mechanism and a second driving mechanism; the mounting plate is positioned above the slicing table and parallel to the slicing table, the mounting plate is driven by a first driving mechanism to be close to or far away from the slicing table, slicing assemblies are arranged at the bottom of the mounting plate and correspond to the material grooves, each slicing assembly comprises a plurality of main cutters which are arranged in parallel at intervals, and a through groove is formed in the mounting plate and positioned between any two adjacent main cutters; the movable plate is located the mounting panel top and is close to or keeps away from the mounting panel by the drive of second actuating mechanism, and the bottom of the movable plate all is installed with the regulation cutter and adjusts the cutter and can pass through logical groove with each logical groove corresponding position.

2. The adjustable agaricus bisporus slicing device according to claim 1, wherein two oppositely arranged mounting frames are mounted on the slicing table, vertically arranged first linear guide rails are mounted on the inner sides of the mounting frames, and two ends of the mounting frames are respectively connected with the two first linear guide rails in a sliding fit manner; the first driving mechanism comprises two first air cylinders which are respectively arranged on the two mounting frames, and the two first air cylinders are respectively connected with the two ends of the mounting frame.

3. The adjustable agaricus bisporus slicing device as claimed in claim 1, wherein two opposite upright frames are installed at the top end of the mounting plate, vertically arranged second linear guide rails are installed at the inner sides of the upright frames, and two ends of the moving plate are respectively connected with the two second linear guide rails in a sliding fit manner.

4. The adjustable agaricus bisporus slicing device as claimed in claim 3, wherein a fixed plate parallel to the movable plate is arranged on one side of the movable plate away from the mounting plate, and two ends of the fixed plate are respectively connected with two vertical frames; the second driving mechanism comprises a plurality of mounting shafts and a driving motor, the mounting shafts are rotatably mounted on the fixing plate at intervals, the driving motor is in transmission connection with one of the mounting shafts, synchronizing wheels are mounted on the mounting shafts, the synchronizing wheels are in transmission connection through synchronous belts, and cams are mounted on the mounting shafts; the bottom of the moving plate is connected with a plurality of springs which are connected with the mounting plate.

5. The adjustable agaricus bisporus slicing apparatus of claim 4, wherein the cam has a first position state and a second position state; when the cam is in a first position state, one end of the cam, which is close to the mounting shaft, abuts against the moving plate, the spring is in a natural state, and the cutting edges of the plurality of adjusting cutters are respectively positioned in the plurality of through grooves; when the cam is in the second position state, one end of the cam, far away from the mounting shaft, abuts against the moving plate and the spring is in a compression state, the adjusting cutters respectively penetrate through the through grooves, and the cutting edges of the adjusting cutters and the cutting edge of the main cutter are located on the same horizontal line.

6. The adjustable agaricus bisporus slicing device according to any one of claims 1 to 5, wherein the length of the main cutter and the length of the adjusting cutter are matched with the length of the material groove, and the length direction of the main cutter and the length direction of the adjusting cutter are consistent with the length direction of the material groove.

7. The adjustable agaricus bisporus slicing device according to any one of claims 1 to 5, wherein a turning plate is installed on the slicing table, a plurality of material grooves are parallelly installed on the turning plate at intervals, a feeding hole is formed in one end of each material groove, a discharging hole is formed in the other end of each material groove, one end, close to the discharging hole of each material groove, of the bottom of the turning plate is rotatably connected with the slicing table, and a second air cylinder for driving the turning plate to rotate is installed on the slicing table.

8. The adjustable agaricus bisporus slicing device according to claim 8, wherein a baffle plate capable of plugging a plurality of material groove discharge holes is rotatably installed on the turning plate, and a third cylinder for driving the baffle plate to rotate is installed on the turning plate.

9. The adjustable agaricus bisporus slicing device according to claim 8, further comprising a feeding and conveying mechanism which can be in butt joint with the feeding ports of the plurality of material grooves and can convey materials into the material grooves.

10. The adjustable agaricus bisporus slicing device according to claim 8, further comprising a discharging conveying mechanism capable of being in butt joint with the discharging ports of the plurality of material tanks.