CN219816986U - Selective peanut particle screening assembly - Google Patents

Abstract

The utility model relates to the technical field of peanut sorting, in particular to a selective peanut particle screening assembly, which comprises a first auger, wherein two ends of the first auger are respectively provided with a first feed inlet and a first discharge outlet, the lower side of the first auger, which is close to the middle part, is provided with an auxiliary outlet end, a sealing door assembly is arranged below the auxiliary outlet end, a vibrating screen assembly is arranged below the auxiliary outlet end, the vibrating screen assembly comprises a feed inlet, a stir-frying discharge port and a pressing discharge port, the feed inlet is communicated with the auxiliary outlet end, the upper side surface of the first auger is provided with an auxiliary inlet end, the position of the auxiliary inlet end is provided with a second auger, and the second auger is communicated with the pressing discharge port and the auxiliary inlet end. According to the utility model, the auxiliary outlet end and the door sealing assembly are arranged at the first auger, so that the first auger is connected with two different production processes, and different production processes can be selected in a simpler mode according to the batch quality of peanuts in the production process, thereby reducing equipment loss and production cost.

Description

Selective peanut particle screening assembly

Technical Field

The utility model relates to the technical field of peanut sorting, in particular to a selective peanut particle screening assembly.

Background

The peanut oil is squeezed by two modes, namely, the cooked peanut oil is squeezed by crushing and squeezing after the peanut is fried, and the raw peanut oil is squeezed by directly crushing and squeezing, so that the cooked peanut oil has better oil output relatively. Because the peanut kernels have different particle sizes, the condition that small particle sizes are fried and burned and large particle sizes are not cooked easily occurs in the frying process, the peanuts are usually screened by screening equipment, the large particles are cooked and squeezed, and the small particles are raw and squeezed.

However, in actual use, because of different growth quality of peanuts, not all batches of peanuts need to be screened, for example, the whole particle size of the peanuts is small, screening is time-consuming and labor-consuming, and the yield is improved less.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model aims to provide a selective peanut particle screening component which can select a production mode according to actual conditions.

The above-mentioned application purpose of the utility model is realized through the following technical scheme:

a selective peanut particle screening assembly comprising:

the two ends of the first auger are respectively provided with a first feeding port and a first discharging port, the first feeding port is connected with a feeding elevator, and the first discharging port is connected with a peanut crusher;

the lower side of the first auger, which is close to the middle part, is provided with an auxiliary outlet end, the door sealing assembly is arranged at the auxiliary outlet end, and the door sealing assembly is used for sealing the auxiliary outlet end;

the vibrating screen assembly comprises a feed inlet, a stir-frying material outlet and a pressing material outlet, wherein the feed inlet is communicated with the auxiliary outlet end, and the stir-frying material outlet is communicated with a stir-frying material lifting machine;

the second auger comprises a second feeding port and a second discharging port, the second feeding port is communicated with the pressing discharging port, and the second discharging port is communicated with the auxiliary inlet end;

the auxiliary inlet end is positioned between the auxiliary outlet end and the first discharge port.

Optionally, the door sealing assembly includes a door sealing plate detachably mounted to the secondary outlet end.

Optionally, the door sealing plate is far away from one side of the vibration screen assembly and hinged to the first auger, the first auger is hinged to a selective driving rod, and the output end of the selective driving rod is hinged to the door sealing plate.

Optionally, the door sealing plate comprises a bottom plate, the bottom plate size is greater than the vice exit end, fixedly connected with shrouding on the bottom plate, the shrouding size with vice exit end is the same, after the door sealing plate seals, the shrouding upside with the inside downside parallel and level of first auger.

Optionally, the vice exit end both sides fixedly connected with passageway board, after the door closure board was opened, the door closure board bottom surface with passageway board bottom side parallel and level.

Optionally, a blocking block is arranged on the bottom side of the channel plate, and after the door sealing plate is opened, the bottom surface of the door sealing plate is attached to the upper side of the blocking block.

Optionally, the vibration screen assembly includes the mounting bracket, install the sieve case in the mounting bracket, sieve case mid-mounting has the screen plate that is on a parallel with the bottom surface, sieve case one end upside is seted up the feed inlet, the sieve case is kept away from feed inlet one end is provided with fry material discharge gate and presses the material discharge gate, the sieve case to fry material discharge gate and press material discharge gate place end downward sloping.

Optionally, two connecting rods are hinged to two sides of the screening bin, one end of the connecting rod, which is far away from the screening bin, is hinged to the mounting frame, a driving motor is arranged at the bottom of the screening bin, and an eccentric block is mounted at the output end of the driving motor.

In summary, the present utility model includes at least one of the following beneficial technical effects:

1. by arranging the auxiliary outlet end and the door sealing assembly at the first auger, the first auger is connected with two different production processes, and different production processes can be selected in a simpler mode according to the batch quality of peanuts in the production process, so that the equipment loss and the production cost are reduced;

2. the first auger is provided with the selection driving rod and the hinge, and the opening and closing of the door sealing plate are controlled by the selection driving rod, so that the automation degree of the equipment is improved, and the door sealing assembly is convenient to control;

3. through setting up the passageway board, seal the passageway board of back and both sides after the door plant is opened forms a triangle-shaped passageway, and the peanut of being convenient for flows into shakes the sieve subassembly, reduces outside sputtering, causes extravagant possibility.

Drawings

FIG. 1 is a schematic overall structure of an embodiment of the present utility model;

FIG. 2 is a schematic overall structure of another view of an embodiment of the present utility model;

FIG. 3 is a schematic view of a door closing assembly according to an embodiment of the present utility model;

fig. 4 is an enlarged schematic view of the portion a in fig. 1.

Reference numerals: 1. a first auger; 11. a first feed inlet; 12. a first discharge port; 13. an auxiliary outlet end; 14. a secondary inlet end;

2. a door closing assembly; 21. a door sealing plate; 211. a bottom plate; 212. a sealing plate; 22. a driving rod; 23. a channel plate; 24. a blocking block;

3. a vibrating screen assembly; 301. a mounting frame; 302. a screening box; 303. a connecting rod; 304. a driving motor; 305. an eccentric block; 31. a feed inlet; 32. a stir-frying material outlet; 33. a pressing material outlet;

4. a second auger; 41. a second feed inlet; 42. and a second discharging hole.

Detailed Description

The present utility model will be described in further detail with reference to the accompanying drawings.

In order to more clearly understand the technical scheme shown in the embodiment of the utility model, the existing production process is first described.

In the existing production flow, peanuts enter an auger through a feeding lifting machine, then pass through screening equipment, are separated into two parts after screening, wherein one part enters a stir-frying lifting machine, then enters the stir-frying equipment, and the other part enters a peanut crusher, and are crushed and squeezed.

From the perspective of users, as peanuts are different in growth quality, not all batches of peanuts need to be screened, when the whole particle size of the peanuts is small, the screened large particles are less, the yield is improved less after stir-frying, and the equipment loss and the production cost are increased.

Referring to fig. 1 and 2, an embodiment of the present disclosure discloses a selective peanut particle screening assembly, which includes a first auger 1, wherein two ends of the first auger 1 are respectively a first feed port 11 and a first discharge port 12, the first feed port 11 is connected to the feed elevator, the first discharge port 12 is connected to a peanut crusher, an auxiliary outlet port 13 is provided on a lower side of the first auger 1 near a middle portion, a door sealing assembly 2 is installed below the auxiliary outlet port 13, the door sealing assembly 2 is used for sealing the auxiliary outlet port 13, a vibrating screen assembly 3 is provided below the auxiliary outlet port 13, the vibrating screen assembly 3 includes a feed port 31, a stir-frying discharge port 32 and a pressing discharge port 33, the feed port 31 is communicated with the auxiliary outlet port 13, the stir-frying discharge port 32 is communicated with the stir-frying elevator, an auxiliary inlet port 14 is provided on an upper side of the first auger 1, a second auger 4 is provided at a position of the auxiliary inlet port 14, the second auger 4 includes a second feed port 41 and a second auxiliary discharge port 42, the second feed port 41 is communicated with the pressing discharge port 33, and the second inlet port 14 is communicated with the first inlet port 14, and the second inlet port 14 is communicated with the second inlet port 14.

Specifically, a first feed inlet 11, an auxiliary outlet end 13, an auxiliary inlet end 14 and a first discharge outlet 12 are sequentially formed in the first auger 1, the vibrating screen assembly 3 is installed at the auxiliary outlet end 13, the second auger 4 is installed at the auxiliary inlet end 14, part of materials screened out by the vibrating screen assembly 3 are returned to the first auger 1 by the second auger 4, and the auxiliary outlet end 13 can be closed by the sealing door assembly 2.

Therefore, by arranging the auxiliary outlet end 13 and the door sealing assembly 2 at the first auger 1, the first auger 1 is connected with two different production processes, and different production processes can be selected in a simpler mode according to the batch quality of peanuts in the production process, so that the equipment loss and the production cost are reduced.

In some possible ways, the door sealing assembly 2 may be configured as a rectangular plate adapted to the secondary outlet end 13, two C-shaped sliding grooves are installed on two sides of the secondary outlet end 13, the door sealing assembly 2 is slidably inserted into the C-shaped sliding grooves, the secondary outlet end 13 is slidably opened or closed, the vibrating screen assembly 3 may be selected as a linear vibrating screen, a drum screen or the like, the vibrating screen assembly 3 is at least provided with a layer of screen, and peanut particles needing to be fried and directly squeezed are distinguished.

Further description will be provided below in connection with specific use cases.

When the peanut crushing machine is used, peanut enters the first auger 1 through the feeding elevator, when peanut particles are small as a whole, the auxiliary outlet end 13 is closed through the door sealing assembly 2, and the peanut directly enters the peanut crushing machine through the first auger 1; when large particles in peanut particles are more, the sealing door assembly 2 is opened, the peanut enters the vibrating screen assembly 3 from the first auger 1, the vibrating screen assembly 3 is used for screening and distinguishing the peanut particles, the large particles enter the stir-frying hoister to be fried, and the small particles directly enter the peanut crusher after flowing back to the first auger 1 through the second auger 4. By opening or closing the auxiliary outlet end 13 according to the different peanuts, the peanuts with different qualities can be selected in different production processes in a simpler manner, and the production cost is reduced.

As an embodiment of the selective peanut particle screening assembly provided herein, the door closure assembly 2 includes a door closure panel 21, the door closure panel 21 being removably mounted to the secondary outlet end 13.

In the whole, the detachable door sealing plate 21 is used for sealing the auxiliary outlet end 13, so that the opening and closing of the auxiliary outlet end 13 can be controlled conveniently.

In some possible ways, the closure panel 21 may be mounted by bolting, snap-fastening, or the like.

Further, referring to fig. 3, a door sealing plate 21 is hinged to the first auger 1 at a side far away from the vibrating screen assembly 3, the first auger 1 is hinged to a selective driving rod 22, and an output end of the selective driving rod 22 is hinged to the door sealing plate 21.

It should be appreciated that by providing the selection driving rod 22 and the hinged first auger 1, the opening and closing of the door sealing plate 21 is controlled by the selection driving rod 22, so that the automation degree of the equipment is improved, and the control of the door sealing assembly 2 is facilitated.

In some possible ways, the selective drive rod 22 may be selected from an electric push rod, a hydraulic rod, a pneumatic rod, etc., and for ease of use, the selective drive rod 22 is connected to the activation circuit of the vibrating screen assembly 3.

Further, referring to fig. 4, the door sealing plate 21 includes a bottom plate 211, the size of the bottom plate 211 is larger than that of the secondary outlet end 13, a sealing plate 212 is fixedly connected to the bottom plate 211, the size of the sealing plate 212 is the same as that of the secondary outlet end 13, and after the door sealing plate 21 is closed, the upper side surface of the sealing plate 212 is flush with the lower side surface inside the first auger 1.

It should be appreciated that the double-layer door sealing plate 21 is provided, the bottom plate 211 is used for sealing the auxiliary outlet end 13, and the sealing plate 212 is flush with the lower side surface inside the first auger 1, so that the door sealing plate 21 keeps flush with the lower side surface inside the first auger 1 after being closed, and the peanut in the first auger 1 is convenient to transport.

Further, the two sides of the auxiliary outlet end 13 are fixedly connected with channel plates 23, and after the door sealing plate 21 is opened, the bottom surface of the door sealing plate 21 is flush with the bottom side surface of the channel plate 23.

It should be appreciated that by providing the channel plate 23, the door closure plate 21 forms a triangular channel with the channel plates 23 on both sides after opening, facilitating the flow of peanut into the screen assembly 3, reducing the likelihood of outward splattering, resulting in wastage.

Further, a blocking block 24 is arranged on the bottom side of the channel plate 23, and after the door sealing plate 21 is opened, the bottom surface of the door sealing plate 21 is attached to the upper side of the blocking block 24.

It will be appreciated that by providing the blocking block 24, the door closure panel 21 is less over-opened and out of the channel panel 23.

In some possible ways, the channel plate 23 is rectangular plate-shaped and is disposed at the positions of both sides of the shutter plate 21 after opening.

As another specific embodiment of a selective peanut particle screening assembly provided in the application, please refer to fig. 1 and 2, the vibration screen assembly 3 includes a mounting frame 301, a screen box 302 is installed in the mounting frame 301, a screen plate parallel to the bottom surface is installed in the middle of the screen box 302, a feed inlet 31 is provided on the upper side of one end of the screen box 302, a stir-frying material outlet 32 and a pressing material outlet 33 are provided at one end of the screen box 302 far away from the feed inlet 31, and the screen box 302 is inclined downward toward the ends where the stir-frying material outlet 32 and the pressing material outlet 33 are located.

The vibration screen assembly 3 is composed of the screen bin 302 and the screen plate in combination with a specific use scene, is simple in structure, is in an inclined arrangement mode, and is oval particles, and separation is completed through the screen plate in the process of automatically rolling the peanuts after the inclined arrangement.

Further, two connecting rods 303 are hinged to two sides of the screening box 302, one end, away from the screening box 302, of each connecting rod 303 is hinged to the mounting frame 301, a driving motor 304 is arranged at the bottom of the screening box 302, and an eccentric block 305 is mounted at the output end of the driving motor 304.

It should be appreciated that by mounting the drive motor 304 and eccentric block 305, the drive motor 304 is caused to oscillate the sifter box 302 during rotation, facilitating peanut rolling.

In some possible ways, the mounting frame 301 is a rectangular frame, the screening box 302 is mounted in the mounting frame 301, and two ends of the connecting rod 303 are respectively hinged to the mounting frame 301 and the screening box 302, so that the screening box 302 can swing.

The embodiments of the present utility model are all preferred embodiments of the present utility model, and are not intended to limit the scope of the present utility model in this way, therefore: all equivalent changes in structure, shape and principle of the utility model should be covered in the scope of protection of the utility model.

Claims (8)

1. A selective peanut particle screening assembly, comprising:

the peanut crusher comprises a first auger (1), wherein a first feeding port (11) and a first discharging port (12) are respectively arranged at two ends of the first auger (1), the first feeding port (11) is connected with a feeding elevator, and the first discharging port (12) is connected with the peanut crusher;

the sealing door assembly (2), an auxiliary outlet end (13) is formed in the lower side, close to the middle, of the first auger (1), the sealing door assembly (2) is installed at the auxiliary outlet end (13), and the sealing door assembly (2) is used for sealing the auxiliary outlet end (13);

the vibrating screen assembly (3), the vibrating screen assembly (3) comprises a feed inlet (31), a stir-frying material outlet (32) and a pressing material outlet (33), the feed inlet (31) is communicated with the auxiliary outlet end (13), and the stir-frying material outlet (32) is communicated with a stir-frying material lifting machine;

the second auger (4), auxiliary inlet end (14) has been seted up to first auger (1) upside, second auger (4) are including second pan feeding mouth (41) and second discharge gate (42), second pan feeding mouth (41) intercommunication swage discharge gate (33), second discharge gate (42) intercommunication auxiliary inlet end (14);

wherein the auxiliary inlet end (14) is positioned between the auxiliary outlet end (13) and the first discharge port (12).

2. A selective peanut particle screening assembly as claimed in claim 1, wherein: the door sealing assembly (2) comprises a door sealing plate (21), and the door sealing plate (21) is detachably arranged at the auxiliary outlet end (13).

3. A selective peanut particle screening assembly as claimed in claim 2, wherein: the sealing door plate (21) is far away from one side of the vibrating screen assembly (3) and hinged to the first auger (1), the first auger (1) is hinged to a selective driving rod (22), and the output end of the selective driving rod (22) is hinged to the sealing door plate (21).

4. A selective peanut particle screening assembly as claimed in claim 3, wherein: the sealing plate (21) comprises a bottom plate (211), the size of the bottom plate (211) is larger than that of the auxiliary outlet end (13), a sealing plate (212) is fixedly connected to the bottom plate (211), the size of the sealing plate (212) is the same as that of the auxiliary outlet end (13), and after the sealing plate (21) is sealed, the upper side surface of the sealing plate (212) is flush with the lower side surface inside the first auger (1).

5. A selective peanut particle screening assembly as claimed in claim 4, wherein: and the two sides of the auxiliary outlet end (13) are fixedly connected with channel plates (23), and after the door sealing plate (21) is opened, the bottom surface of the door sealing plate (21) is flush with the bottom side surface of the channel plate (23).

6. A selective peanut particle screening assembly as claimed in claim 5, wherein: the bottom side of the channel plate (23) is provided with a blocking block (24), and after the door sealing plate (21) is opened, the bottom surface of the door sealing plate (21) is attached to the upper side of the blocking block (24).

7. A selective peanut particle screening assembly as claimed in claim 1, wherein: the vibrating screen assembly (3) comprises a mounting frame (301), a screen box (302) is mounted in the mounting frame (301), a screen plate parallel to the bottom surface is mounted in the middle of the screen box (302), a feeding hole (31) is formed in the upper side of one end of the screen box (302), a stir-frying material discharging hole (32) and a pressing material discharging hole (33) are formed in one end of the screen box (302), which is far away from the feeding hole (31), of the screen box (302), and the end where the stir-frying material discharging hole (32) and the pressing material discharging hole (33) are located is inclined downwards.

8. A selective peanut particle screening assembly as claimed in claim 7, wherein: two sides of the screening box (302) are hinged with two connecting rods (303), one end of each connecting rod (303) away from the screening box (302) is hinged with the mounting frame (301), a driving motor (304) is arranged at the bottom of the screening box (302), and an eccentric block (305) is mounted at the output end of the driving motor (304).