CN117281267B

CN117281267B - Batch peanut sheller

Info

Publication number: CN117281267B
Application number: CN202311585106.8A
Authority: CN
Inventors: 周建强
Original assignee: Yantai Lingyuan Peanut Machinery Co ltd
Current assignee: Yantai Lingyuan Peanut Machinery Co ltd
Priority date: 2023-11-27
Filing date: 2023-11-27
Publication date: 2024-01-26
Anticipated expiration: 2043-11-27
Also published as: CN117281267A

Abstract

The invention belongs to the technical field of agricultural machinery, and particularly discloses a batch peanut sheller which comprises a separation device, a first extrusion crushing device and a friction disintegration device. The first extrusion crushing device crushes peanut shells through mechanical extrusion; the friction disintegration device is used for extruding crushed peanut shells through mechanical friction, so that the peanut shells are in a disintegration state; the separation device separates the split peanut shells from the peanut kernels. The peanut shell is crushed by mechanical extrusion, and then crushed by mechanical friction, so that the peanut shell is in a disintegrated state, the aim is to avoid the mutual influence of the unbroken peanut, the incompletely broken peanut shell and the completely broken shell scraps, and the collision, extrusion and friction effects between the peanut shells in the traditional peanut sheller are replaced by mechanical direct extrusion and friction of the peanut shells, so that the peanut shelling efficiency is improved.

Description

Batch peanut sheller

Technical Field

The invention belongs to the technical field of agricultural machinery, and particularly relates to a batch peanut sheller.

Background

Conventional peanut shellers typically use a high-speed rotating body that breaks the peanut shell by impact, extrusion, and friction to separate the peanut kernel from the peanut shell. However, the conventional peanut sheller has problems, resulting in inefficient shelling.

The peanut crushing process is not a kick. If the peanut moisture content is too low, the peanut shell hardness is high, mechanical abrasion is easy to be serious, the peanut kernels are extremely fragile, and the integrity rate of the finally separated peanut kernels is low, so that the moisture content of the crushed peanut is not very low in general, and sometimes, in order to improve the moisture content of the dried peanut, the peanut shells and the peanut kernels need to be stored for a period of time in a water spraying and sealing way before crushing, so that the peanut shells and the peanut kernels have certain flexibility. However, the flexibility of the peanut shells means that the peanut shells, even if they have been crushed, are usually connected to each other, and are not completely separated, i.e. not completely crushed. In this state, the peanut kernel is difficult to separate from the peanut shell.

The uncrushed peanuts, the incompletely crushed peanut shells and the completely crushed shell scraps are mixed together, and the collision, extrusion and friction actions mostly occur between the peanut shells. The incompletely crushed peanut shells and the completely crushed shells are natural buffer cushions, so that the collision and extrusion actions are reduced, the friction action between the peanut shells is extremely unstable, the incompletely crushed peanut shells and the incompletely crushed peanut shells are difficult to crush, the incompletely crushed peanut shells are difficult to reach a completely crushed state by virtue of friction force, a large amount of peanut kernels cannot be separated in the half-crushed peanut shells, and the half-crushed peanut shells in turn seriously influence the shelling efficiency.

Therefore, there is a need for an improved solution to increase the efficiency of peanut shelling.

Disclosure of Invention

In view of the above-mentioned drawbacks, an object of the present invention is to provide a batch peanut sheller which can crush peanut shells by mechanical extrusion and then crush the crushed peanut shells by mechanical friction so that the peanut shells are in a disintegrated state, in order to avoid the mutual influence of the mixing of the unbroken peanut, the incompletely crushed peanut shells and the completely crushed shell chips, and to improve the peanut shelling efficiency by replacing the collision, extrusion and friction action between the peanut shells in the conventional peanut sheller with the mechanical direct extrusion and friction of the peanut shells.

In order to achieve the aim, the invention provides a batch peanut sheller which comprises a separating device, a first extrusion crushing device and a friction disintegration device. The first extrusion crushing device crushes peanut shells through mechanical extrusion; the friction disintegration device is used for extruding crushed peanut shells through mechanical friction, so that the peanut shells are in a disintegration state; the separation device separates the split peanut shells from the peanut kernels.

Further, the first extrusion crushing device comprises two first rotating rollers with opposite rotating directions, the two first rotating rollers are close to each other, the axes of the two first rotating rollers are parallel to each other and are positioned on the same horizontal plane, and a first feeding structure is arranged right above the center line of the two first rotating rollers.

Further, the first feeding structure comprises an inclined first groove body and a vibrating motor arranged on the first groove body.

Further, a second crush crushing device is also included. The second extrusion crushing device comprises two second rotating rollers with opposite rotating directions, the two second rotating rollers are close to each other, the axes of the two second rotating rollers are parallel to each other and are positioned on the same horizontal plane, and a second feeding structure is arranged right above the center line of the two second rotating rollers. The pressing space between the two second rotating rollers is smaller than the pressing space between the two first rotating rollers. The second feed structure is located directly below the first feed structure. The bottom surface of the first trough body extends over the screening holes.

Further, the friction-breaking device comprises a first static grinding body and a rotary grinding part, and a first friction-breaking space is formed between the static grinding body and the rotary grinding part.

Further, the friction disintegration device is a rotary body structure and sequentially comprises a first static grinding body, a rotary grinding part and a second static grinding body from outside to inside, a first friction disintegration space is formed between the first static grinding body and the rotary grinding part, and a second friction disintegration space is formed between the second static grinding body and the rotary grinding part. The gap of the first friction disintegrating space is larger than the gap of the second friction disintegrating space. The material of the first extrusion crushing device falls into the first friction disintegration space, and the material of the second extrusion crushing device falls into the second friction disintegration space.

Further, the surfaces of the inner side surface and the outer side surface of the rotary grinding part are provided with feeding channels, and the feeding channels extend downwards from the top of the rotary grinding part to the middle of the rotary grinding part.

Further, the lower parts of the first friction disintegrating space and the second friction disintegrating space are open structures; screening holes are uniformly distributed on the first static grinding body and the second static grinding body.

Further, the separation device comprises a separation channel which is obliquely arranged, wherein the high point of the separation channel is a peanut shell outlet, and the low point of the separation channel is a peanut kernel outlet. The device also comprises a separation fan, wherein the separation fan blows air from the middle lower part of the separation channel to the high point of the separation channel.

Further, the friction breaking device comprises an outer shell, and the friction breaking device is positioned in the outer shell. The air inlet of the separation fan is positioned in the outer shell.

Compared with the prior art, the invention has the following beneficial effects:

according to the peanut sheller, firstly, the peanut shells are crushed through mechanical extrusion, then the crushed peanut shells are in a disintegrated state through mechanical friction, so that the mutual influence of unbroken peanuts, incompletely crushed peanut shells and completely crushed shell scraps is avoided, the collision, extrusion and friction effects between the peanut shells in the traditional peanut sheller are replaced by mechanical direct extrusion and friction of the peanut shells, and the peanut shelling efficiency is improved.

According to the invention, the screening holes at the bottom of the first groove body are matched with the vibration motor, so that the peanuts with small particles fall into the second feeding structure through the screening holes while being spread, and are extruded and crushed through the two second rotating rollers, and the problem that too small peanut particles cannot be effectively extruded and crushed through the two first rotating rollers is solved. Furthermore, the invention realizes the space grinding operation with different gaps between the first friction disintegrating space and the second friction disintegrating space by only one rotary grinding part, thereby carrying out targeted friction disintegrating treatment on peanuts with different sizes. The invention can effectively dehulling the small peanut particles and avoid the unhulled small peanut from being mixed into the peanut kernel.

According to the invention, the air inlet of the separation fan is arranged in the outer shell, so that negative pressure can be formed in the outer shell, dust floating around the separation device is prevented from overflowing, meanwhile, the fan can suck away the dust and discharge the dust from the outlet of the peanut shell, and dust pollution can be effectively reduced as long as dust removal protection is performed at the outlet of the peanut shell. Air entering from the air inlet of the outer shell flows around the periphery of the friction disintegrating device, and chips on the surface of the first static grinding body can be cleaned. Further, the external air enters from the first extrusion crushing device and the second extrusion crushing device, flows through the first friction disintegration space and the second friction disintegration space of the friction disintegration device, disturbs and accelerates the discharge of peanut skin fragments, provides space for subsequent operation, enables subsequent peanuts to enter the device at a faster speed, and further improves the overall efficiency of shelling operation.

Drawings

FIG. 1 is a perspective view of a batch peanut sheller of the present invention;

FIG. 2 is an internal construction view of the batch peanut sheller of the present invention;

FIG. 3 is a perspective exploded view of the batch peanut sheller of the present invention;

FIG. 4 is a perspective exploded view of the friction disintegrating device of the present invention;

FIG. 5 is a schematic flow field diagram of a batch peanut sheller of the present invention.

In the figure: 100-first extrusion crushing device, 110-first rotary roller, 120-first feeding structure, 121-first groove body, 122-vibrating motor, 123-rotary pusher, 200-second extrusion crushing device, 210-second rotary roller, 220-second feeding structure, 221-second groove body, 300-friction disintegrating device, 310-first static grinding body, 320-rotary grinding part, 321-feeding channel, 330-second static grinding body, 400-separating device, 410-separating channel, 420-separating fan and 500-outer shell.

Detailed Description

In the description of the present embodiment, it should be noted that the azimuth or positional relationship indicated by the terms "upper", "lower", "inner", "bottom", etc. are based on the azimuth or positional relationship shown in the drawings, or the azimuth or positional relationship in which the inventive product is conventionally put in use, are merely for convenience of describing the present invention and simplifying the description, and are not indicative or implying that the apparatus or element to be referred to must have a specific azimuth, be configured and operated in a specific azimuth, and therefore should not be construed as limiting the present invention.

In the description of the present embodiment, it should also be noted that the terms "disposed," "connected," and "connected" are to be construed broadly, unless explicitly stated or limited otherwise.

For the purpose of making the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be described in further detail below with reference to the accompanying drawings.

Referring to fig. 1 to 4, the present embodiment discloses a batch peanut sheller including a first crushing device 100, a friction-disintegrating device 300, and a separating device 400. The first crushing and extruding device 100 crushes the peanut shells by mechanical extrusion; the friction-disintegrating device 300 disintegrates the crushed peanut shells by mechanical friction so that the peanut shells are in a disintegrated state; the separation device 400 separates the disintegrated peanut shells from the peanut kernels. In general, the first crushing device 100, the friction-disintegrating device 300 and the separating device 400 are arranged in sequence from top to bottom in space, so that the transfer of material between the different devices can be achieved by means of gravity. In the embodiment, firstly, the peanut shells are crushed by mechanical extrusion, and then the crushed peanut shells are in a disassembled state by mechanical friction, so that the purposes of avoiding mutual influence of the unbroken peanuts, the incompletely crushed peanut shells and the completely crushed shell scraps are achieved, and the collision, extrusion and friction effects between the peanut shells in the traditional peanut sheller are replaced by mechanical direct extrusion and friction of the peanut shells, so that the peanut shelling efficiency is improved.

As a further scheme of this embodiment: the first crushing device 100 includes two first rotating rollers 110 with opposite rotation directions, the two first rotating rollers 110 are close to each other to form a crushing space, axes are parallel to each other and are on the same horizontal plane, and a first feeding structure 120 is arranged right above the center line of the two first rotating rollers 110. Further, the first feeding structure 120 includes a sloped first tank 121 and a vibration motor 122 mounted on the first tank 121. During the use, operating personnel pours the peanut that waits to dehull into first cell body 121 through manpower or machinery, and vibrating motor 122 can make the peanut spread evenly in first cell body 121, conveniently gets into the extrusion space and extrudes.

Under this solution, the friction-breaking-up device 300 comprises a first stationary grinding body 310 and a rotary grinding portion 320, between which a first friction-breaking-up space is formed.

As a further scheme of this embodiment: a second crush device 200 is also included. The second crushing device 200 includes two second rotating rollers 210 with opposite rotation directions, the two second rotating rollers 210 are close to each other to form a crushing space, axes are parallel to each other and are on the same horizontal plane, and a second feeding structure 220 is arranged right above the center line of the two rotating rollers. The pressing space between the two second rotating rollers 210 is smaller than the pressing space between the two first rotating rollers 110. The second feeding structure 220 is located directly below the first feeding structure 120, and includes a second groove 221 disposed obliquely. The bottom surface of the first trough 121 extends over the screening openings. When the peanut extruding machine is used, the screening holes at the bottom of the first groove body 121 are matched with the vibrating motor 122, when peanuts are spread, small-particle peanuts fall into the second feeding structure 220 through the screening holes and are extruded and crushed through the two second rotating rollers 210, and the problem that too small peanut particles cannot be effectively extruded and crushed through the two first rotating rollers 110 is solved. This is also one of the advantages of this embodiment over conventional peanut shellers. Further, a rotary pusher 123 may be provided at the outlet of both the first and second feeding structures 120 and 220 for controlling the uniform speed of the peanuts into the extrusion space.

Under this technical scheme, the friction disintegrating device 300 is a rotating body structure, and sequentially comprises a first static grinding body 310, a rotary grinding part 320 and a second static grinding body 330 from outside to inside, wherein a first friction disintegrating space is formed between the first static grinding body 310 and the rotary grinding part 320, and a second friction disintegrating space is formed between the second static grinding body 330 and the rotary grinding part 320. The half-crushed peanuts from the first and second crushing devices 100 and 200 fall into the first and second friction-break spaces, respectively. By the rotation of the rotary grinding part 320, relative movement is formed between the rotary grinding part and the first static grinding body 310 and the second static grinding body 330, respectively, so that the peanut shells of the peanuts in the half-broken state in the first friction breaking space and the second friction breaking space are gradually broken by mechanical friction, and the peanut kernels can fall out of the peanut shells. Further, the gap of the first friction disintegrating space is larger than the gap of the second friction disintegrating space, so that the peanuts with different sizes from the first extrusion crushing device 100 and the second extrusion crushing device 200 are pertinently subjected to friction disintegrating treatment. By providing the flow guiding structure, the material of the first extrusion crushing device 100 falls into the first friction disintegration space, and the material of the second extrusion crushing device 200 falls into the second friction disintegration space. Further, the surfaces of the inner side surface and the outer side surface of the rotary grinding part 320 are both provided with a feeding channel 321, and the feeding channel 321 extends downwards from the top of the rotary grinding part 320 to the middle of the rotary grinding part 320, so that materials can smoothly enter the first friction disintegrating space and the second friction disintegrating space.

Further, the open structures are arranged below the first friction disintegrating space and the second friction disintegrating space, so that the disintegrated peanut shells and peanut kernels conveniently fall into the separating device 400 under the action of gravity. Further, screening holes are uniformly distributed on the first static grinding body 310 and the second static grinding body 330, so that the disintegrated peanut shells and peanut kernels can also directly fall from the screening holes on the side surfaces, and the discharging is smoother.

As a further scheme of this embodiment: the separation device 400 includes a separation channel 410 arranged obliquely, wherein the high point of the separation channel 410 is a peanut shell outlet, and the low point is a peanut kernel outlet. Also included is a separation blower 420, the separation blower 420 blowing air from a middle lower portion of the separation channel 410 toward a high point of the separation channel 410. The technical scheme is that the light peanut shells are blown upwards by conventional winnowing separation, and the heavy peanut kernels are discharged from below.

As a further scheme of this embodiment: also included is an outer housing 500, with the friction-disrupting means 300 located within the outer housing 500. The air inlet of the separation blower 420 is located in the outer case 500. Preferably, a corresponding air inlet is also provided on the outer housing 500, and is located on the opposite side of the air inlet of the separation blower 420. By adopting the technical scheme, negative pressure can be formed in the outer shell 500 to prevent dust floating around the separation device 400 from overflowing, meanwhile, the fan can suck away the dust and discharge the dust from the peanut shell outlet, and dust pollution can be effectively reduced as long as dust removal protection is carried out at the peanut shell outlet. In particular, in a peanut shelling site with a certain scale, a storage bin is often arranged at the outlet of the peanut shell, and the peanut shell and solid dust are stored in the storage bin and are transported away periodically.

In addition, referring to fig. 5, air entering from the air inlet of the outer housing 500 flows around the periphery of the friction-fit device 300, and may clean the surface of the first stationary grinding body 310 of debris. Further, the size of the air inlet on the outer casing 500 is controlled so as to provide only a part of the air inlet, and the rest of the air inlet enters from the first extrusion crushing device 100 and the second extrusion crushing device 200 and flows through the first friction disintegrating space and the second friction disintegrating space of the friction disintegrating device 300, and finally, most of the air inlet is sucked by the separating fan 420, and the rest of the air inlet is sucked by the winnowing air flow in the separating passage 410. When the high-speed airflow flows through the components, the discharge of peanut skin scraps is disturbed and accelerated, space is provided for subsequent operation, and subsequent peanuts can enter the device at a higher speed, so that the overall efficiency of the shelling operation is improved. Fig. 5 only shows part of the trend of the air flow, and in the actual situation, due to the overall size and technical parameters of the equipment, tiny in-out exists, but the effect of accelerating the discharge of the peanut skin scraps is not affected.

In the present embodiment, the first rotating roller 110, the second rotating roller 210, the rotary grinding unit 320, the separation blower 420, and the rotary pusher 123 are driven by conventional power equipment or transmission structures, and are not particularly limited.

The foregoing description of the preferred embodiments of the present invention should not be taken as limiting the invention, but rather should be understood to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims

1. A batch peanut sheller comprising a separating device (400), characterized in that: further comprising a first crush device (100) and a friction-breaking device (300); the first extrusion crushing device (100) crushes peanut shells through mechanical extrusion; the friction disintegration device (300) disintegrates the crushed peanut shells through mechanical friction; the separation device (400) separates the disintegrated peanut shells from the peanut kernels;

the first extrusion crushing device (100) comprises two first rotating rollers (110) with opposite rotating directions, the two first rotating rollers (110) are close to each other, the axes of the two first rotating rollers are parallel to each other and are positioned on the same horizontal plane, and a first feeding structure (120) is arranged right above the center line of the two first rotating rollers;

the first feeding structure (120) comprises an inclined first groove body (121) and a vibrating motor (122) arranged on the first groove body (121);

further comprising a second crushing device (200); the second extrusion crushing device (200) comprises two second rotating rollers (210) with opposite rotating directions, the two second rotating rollers (210) are close to each other, the axes of the two second rotating rollers are parallel to each other and are positioned on the same horizontal plane, and a second feeding structure (220) is arranged right above the center line of the two second rotating rollers; the extrusion space between the two second rotating rollers (210) is smaller than the extrusion space between the two first rotating rollers (110); the second feed structure (220) is located directly below the first feed structure (120); the bottom surface of the first groove body (121) is distributed over the screening holes;

the friction disintegrating device (300) is of a rotary body structure and sequentially comprises a first static grinding body (310), a rotary grinding part (320) and a second static grinding body (330) from outside to inside, wherein a first friction disintegrating space is formed between the first static grinding body (310) and the rotary grinding part (320), and a second friction disintegrating space is formed between the second static grinding body (330) and the rotary grinding part (320); the gap of the first friction disintegrating space is larger than the gap of the second friction disintegrating space; the materials of the first extrusion crushing device (100) fall into a first friction disintegration space, and the materials of the second extrusion crushing device (200) fall into a second friction disintegration space.

2. Batch peanut sheller according to claim 1, characterized in that: the surface of the inner side face and the surface of the outer side face of the rotary grinding part (320) are provided with feeding channels (321), and the feeding channels (321) extend downwards from the top of the rotary grinding part (320) to the middle of the rotary grinding part (320).

3. Batch peanut sheller according to claim 1, characterized in that: the lower parts of the first friction disintegrating space and the second friction disintegrating space are open structures; screening holes are uniformly distributed on the first static grinding body (310) and the second static grinding body (330).

4. Batch peanut sheller according to claim 1, characterized in that: the separation device (400) comprises a separation channel (410) which is obliquely arranged, wherein the high point of the separation channel (410) is a peanut shell outlet, and the low point of the separation channel is a peanut kernel outlet; also included is a separation blower (420), the separation blower (420) blowing air from a middle lower portion of the separation channel (410) to a high point of the separation channel (410).

5. The batch peanut sheller of claim 4 wherein: further comprising an outer housing (500), said friction-break device (300) being located within said outer housing (500); an air inlet of the separation fan (420) is positioned in the outer shell (500).