CN114136066A

CN114136066A - Fermented feed drying device for piglet breeding and implementation method thereof

Info

Publication number: CN114136066A
Application number: CN202111518591.8A
Authority: CN
Inventors: 李�浩; 薛兵
Original assignee: Anhui Tech Bank Bio Tech Co ltd
Current assignee: Anhui Tech Bank Bio Tech Co ltd
Priority date: 2021-12-13
Filing date: 2021-12-13
Publication date: 2022-03-04
Anticipated expiration: 2041-12-13
Also published as: CN114136066B

Abstract

The invention discloses a fermented feed drying device for piglet breeding and an implementation method thereof, and belongs to the technical field of fermented feed drying. The invention provides a fermented feed drying device for piglet breeding and an implementation method thereof.A fermented feed flowing into a feed pipe falls on a drying platform, an air pump fills air into a material stirring shell, a telescopic rod extends to a position flush with a material stirring strip, and a motor drives the telescopic rod and the material stirring strip to rotate for flatly paving the fermented feed; the heating spiral disc is used for heating the drying platform, and materials on the drying platform are dried under the condition.

Description

Fermented feed drying device for piglet breeding and implementation method thereof

Technical Field

The invention relates to the technical field of fermented feed drying, in particular to a fermented feed drying device for piglet breeding and an implementation method thereof.

Background

The piglets are the piglets just born as the name implies, the pig raising is very common in all places of China, and the piglets produced by the sows can be prepared for replacement sows after carefully caring for the growth. However, the piglets are very weak after birth, and many farmers lose their economic benefits greatly due to the fact that the piglets die. Therefore, a correct management method is needed after the piglets are born, so that the survival rate of the piglets can be effectively ensured.

The piglets need to be fed with fermented feed in the breeding process, and are generally treated by decomposing organic matters by microorganisms through fermentation, the fermentation is divided into aerobic fermentation and anaerobic fermentation, the dry anaerobic fermentation technology is generally adopted, the pollution can be reduced, the generated methane during treatment belongs to clean energy, the secondary pollution to the environment can not be caused, and the sustainable development concept of energy, environment and economy is met.

The existing fermentation device for dry anaerobic fermentation is provided with a stirring device in order to improve the contact area and fermentation efficiency of solid substances and liquid substances, and the importance of the stirring device for dry anaerobic fermentation is visible, but the existing stirring device for dry anaerobic fermentation is insufficient in technology, so that the stirring device for dry fermentation needs to coat the outer side of a container in the process of stirring, the material is prevented from spilling out in the process of stirring, extra power is needed to be provided, and the overall cost is increased.

Disclosure of Invention

The invention aims to provide a fermented feed drying device for piglet cultivation and an implementation method thereof, and aims to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a piglet is bred and uses fermented feed mummification device, including mummification case and inlet pipe, the inlet pipe is connected on one side top surface of mummification case, the internally mounted of mummification case has the tiling subassembly, the mummification subassembly, group material subassembly and unloading subassembly are installed on the tiling subassembly, the mummification subassembly sets up the below at the tiling subassembly, the fermented fodder that the inlet pipe flowed in falls into on the mummification subassembly, the tiling subassembly is used for laying flat fermented fodder after, the mummification subassembly is used for mummification fermented fodder, group material subassembly is used for the in-process of mummification to stir fermented fodder and scatters, arrange the material through the unloading subassembly after the even mummification.

Further, the flat laying assembly comprises a support, a motor, a limiting frame, a limiting ring, an outer baffle ring and a flat laying plate, wherein one end of the support is arranged on the inner wall of the drying box, the motor is arranged at the other end of the support, a rotating shaft is arranged on a shaft of the motor, external threads are processed on the outer wall of the rotating shaft, the bottom end of the rotating shaft is connected with the flat laying plate, and the rotating shaft is meshed with the limiting ring through the external threads;

the outer wall of spacing ring is connected with the one end of spacing, and the other end of spacing is fixed with the inner wall of outer fender ring, and the middle part of spacing is run through by the guide bar, and the top of guide bar is fixed with the roof of mummification case.

Further, the mummification subassembly includes mummification platform, platform support, heating spiral disk and the piece that generates heat, and the one end of platform support is fixed on the lateral wall of mummification case, and the mummification platform sets up on the platform support, and the bottom surface and the heating spiral disk of mummification platform are fixed, and the heating spiral disk is connected with the piece that generates heat to outer baffle ring descends and is connected with the outer lane contact of mummification platform.

Furthermore, the material shifting assembly comprises a material shifting strip, an air pump, a material shifting shell, a partition plate, a top plate, a telescopic rod and a sealing plate, wherein the air pump and the material shifting shell are fixed on the bottom surface of the flat bed plate, and an air outlet of the air pump is communicated with the interior of the material shifting shell;

the bottom end of the material shifting shell is fixed with material shifting strips at equal intervals, and material shifting gaps are reserved among the material shifting strips;

the partition plates are fixed in the material shifting shell at equal intervals, the top ends of the partition plates are fixed with the top plates, a containing cavity is formed between the partition plates and the top plates, one end of the telescopic rod is fixed with the sealing plate, and the other end of the telescopic rod penetrates through the material shifting shell and is positioned in the material shifting gap;

furthermore, the sealing plate is hermetically connected with the partition plate and the inner wall of the material shifting shell, a through hole is formed in the top plate, and the air pump is communicated with the accommodating cavity through the through hole;

the air pump drives air to flow into the material shifting shell, the pressure inside the material shifting shell is increased, the top plate drives the telescopic rod to descend synchronously, the telescopic rod descends to be aligned with the bottom surface of the material shifting strip, and the telescopic rod and the material shifting strip form a whole plate.

Furthermore, the whole plate formed by the material stirring strips and the telescopic rods is arranged along the radial direction of the bottom surface of the flat laying plate.

Furthermore, the blanking assembly comprises an air cylinder, a blanking plate and a conveying belt, the air cylinder is fixed on the inner wall of the drying box, one end of the blanking plate is connected with the piston end of the air cylinder, the other end of the blanking plate faces the flat bed plate, and the conveying belt is located right below the blanking plate;

the flitch constitutes 30 contained angles along the flexible direction of piston end and the radial direction of flat bed board down, and on the flitch extended to the flat bed board, the rotatory fermented fodder of flat bed board fell into on the conveyer belt along the flitch of unloading.

The invention provides another technical scheme, and an implementation method of a fermented feed drying device for piglet cultivation comprises the following steps:

s1: a shaft of the motor drives the rotating shaft to rotate, and the limiting ring moves downwards along the rotating shaft and the guide rod in the rotating process of the rotating shaft;

s2: the outer baffle ring slowly descends to the position where the outer ring edge of the drying platform is sleeved, and the outer baffle ring blocks the outer part of the flat plate;

s3: the fermented feed flows into the feeding pipe and falls on the drying platform, the air pump fills air into the material shifting shell, the telescopic rod extends to be flush with the material shifting strip, and the motor drives the telescopic rod and the material shifting strip to rotate so as to be used for flatly paving the fermented feed;

s4: the heating spiral disc is used for heating the drying platform, and the fermented feed on the drying platform is dried;

s5: the air pump pumps air into the material shifting shell, the telescopic rod retracts into the material shifting shell, the material shifting strip rotates reversely along with the motor, and the fermented feed on the flat laying plate is shifted, so that heat conduction is more uniform;

s6: during blanking, the motor rotates reversely, the outer baffle ring rises, the cylinder drives the lower material plate to extend to the drying platform, and the flat laying plate rotates to fall into the conveying belt under the guidance of the lower material plate.

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

1. according to the fermented feed drying device for piglet breeding and the implementation method thereof, the middle part of the limiting frame is penetrated by the guide rod, the limiting ring moves up and down along the guide rod through the rotation of the rotating shaft, so that the position of the outer baffle ring is adjusted, the rotating shaft is driven to rotate by the shaft of the motor, the limiting ring moves down along the rotating shaft and the guide rod in the rotating process of the rotating shaft, the outer baffle ring blocks the outer part of the flat plate, the material stirring and the material blocking are combined together, the additional power input is avoided, and the cost is reduced.

2. The invention provides a fermented feed drying device for piglet breeding and an implementation method thereof.A fermented feed flowing into a feed pipe falls on a drying platform, an air pump fills air into a material stirring shell, a telescopic rod extends to a position flush with a material stirring strip, and a motor drives the telescopic rod and the material stirring strip to rotate for flatly paving the fermented feed; the heating spiral disc is used for heating the drying platform, and materials on the drying platform are dried under the condition.

3. During blanking, the motor rotates reversely, the outer baffle ring rises, the cylinder drives the blanking plate to extend to the drying platform, and the drying platform rotates to fall into the conveying belt under the guidance of the blanking plate.

Drawings

FIG. 1 is an overall block diagram of the present invention;

FIG. 2 is a partial internal block diagram of the present invention;

FIG. 3 is a block diagram of a tiling assembly of the present invention;

FIG. 4 is a block diagram of a drying assembly of the present invention;

fig. 5 is a diagram of a material blocking state of the invention;

FIG. 6 is a block diagram of the kick-out assembly of the present invention;

fig. 7 is a structural view of a blanking assembly and a kick-off assembly of the present invention.

In the figure: 1. a drying box; 2. a tiling component; 21. a support; 22. a motor; 221. a rotating shaft; 23. a limiting frame; 231. a guide bar; 24. a limiting ring; 25. an outer retainer ring; 26. flatly paving a plate; 3. a drying assembly; 31. a drying platform; 32. a platform support; 33. heating the spiral disc; 34. a heat generating sheet; 4. a material poking component; 41. material stirring strips; 42. an air pump; 43. a material shifting shell; 44. a partition plate; 45. a top plate; 451. a through hole; 46. a telescopic rod; 47. a sealing plate; 5. a blanking assembly; 51. a cylinder; 52. a blanking plate; 53. a conveyor belt; 6. and (4) feeding a pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Please refer to fig. 1-2, a piglet is bred and uses fermented feed mummification device, including mummification case 1 and inlet pipe 6, inlet pipe 6 is connected on one side top surface of mummification case 1, the internally mounted of mummification case 1 has tiling subassembly 2, mummification subassembly 3, dial material subassembly 4 and unloading subassembly 5 and install on tiling subassembly 2, mummification subassembly 3 sets up the below at tiling subassembly 2, the fermented fodder that inlet pipe 6 flowed in falls into mummification subassembly 3, tiling subassembly 2 is used for after the tiling fermented fodder, mummification subassembly 3 is used for the mummification fermented fodder, it stirs the fermented fodder and looses to dial material subassembly 4 to be used for the in-process of mummification, arrange the material through unloading subassembly 5 after the even mummification, unloading subassembly 5 discharges the material.

Referring to fig. 3, the flat laying assembly 2 includes a support 21, a motor 22, a limiting frame 23, a limiting ring 24, an outer baffle ring 25 and a flat laying plate 26, one end of the support 21 is mounted on the inner wall of the drying box 1, the motor 22 is mounted on the other end of the support 21, the motor 22 is limited by the position of the support 21, a rotating shaft 221 is mounted on a shaft of the motor 22, the motor 22 drives the rotating shaft 221 to rotate, an external thread is processed on the outer wall of the rotating shaft 221, the bottom end of the rotating shaft 221 is connected with the flat laying plate 26, and the rotating shaft 221 is meshed with the limiting ring 24 through the external thread.

The outer wall of spacing ring 24 is connected with the one end of spacing 23, and the other end of spacing 23 is fixed with the inner wall of outer fender ring 25, and the middle part of spacing 23 is run through by guide bar 231, and the top of guide bar 231 is fixed with the roof of mummification case 1, lets spacing ring 24 reciprocate along guide bar 231 through the rotation of rotation axis 221 to the position of adjustment outer fender ring 25.

Referring to fig. 4, the drying assembly 3 includes a drying platform 31, a platform support 32, a heating spiral disc 33 and a heating plate 34, one end of the platform support 32 is fixed on the side wall of the drying box 1, the drying platform 31 is disposed on the platform support 32, the bottom surface of the drying platform 31 is fixed to the heating spiral disc 33, the heating spiral disc 33 is connected to the heating plate 34, the outer baffle ring 25 descends to be in contact with the outer ring of the drying platform 31, the heating spiral disc 33 is used for heating the drying platform 31, and the material on the drying platform 31 evaporates water in the feed at a temperature higher than 80 ℃.

Referring to fig. 5-6, the material-stirring assembly 4 includes a material-stirring bar 41, an air pump 42, a material-stirring shell 43, a partition 44, a top plate 45, an expansion rod 46 and a sealing plate 47, the air pump 42 and the material-stirring shell 43 are fixed on the bottom surface of the flat plate 26, an air outlet of the air pump 42 is communicated with the interior of the material-stirring shell 43, and the air pump 42 injects air into the material-stirring shell 43.

The bottom of the material shifting shell 43 is equidistantly fixed with material shifting strips 41, material shifting gaps are reserved between the material shifting strips 41, the material shifting strips 41 are used for shifting materials, the materials are scattered, and the heat conduction uniformity of the materials is improved.

Baffle 44 equidistant fixes in dialling the material shell 43 to the top and the roof 45 of baffle 44 are fixed, form the holding chamber between a plurality of baffles 44 and the roof 45, and the one end and the closing plate 47 of telescopic link 46 are fixed, and the other end of telescopic link 46 is worn out and is dialled the material shell 43 and be located and dial the material clearance, and telescopic link 46 can stretch out and draw back the removal in dialling the material shell 43.

The sealing plate 47 is connected with the partition plate 44 and the inner wall of the material shifting shell 43 in a sealing manner, a through hole 451 is formed in the top plate 45, and the air pump 42 is communicated with the accommodating cavity through the through hole 451.

Air pump 42 drive gas flow in dial material shell 43, dial the inside pressure increase of material shell 43, roof 45 drives telescopic link 46 and descends in step, and telescopic link 46 descends to and dials the bottom surface of stuff 41 and aligns to telescopic link 46 and dial stuff 41 and form whole board, through forming whole board with telescopic link 46 and group stuff 41, when removing, whole board can evenly spread the physics open.

The whole plate formed by the material stirring strips 41 and the telescopic rods 46 is arranged along the radial direction of the bottom surface of the flat laying plate 26, and when the telescopic rods 46 ascend, the material stirring strips 41 are used for stirring the physical materials, so that heat conduction is uniform.

Referring to fig. 7, the blanking assembly 5 includes a cylinder 51, a blanking plate 52 and a conveyor belt 53, the cylinder 51 is fixed on the inner wall of the drying box 1, one end of the blanking plate 52 is connected to the piston end of the cylinder 51, the other end of the blanking plate 52 faces the flat plate 26, and the conveyor belt 53 is located right below the blanking plate 52.

The lower material plate 52 forms an included angle of 30 degrees with the radial direction of the flat laying plate 26 along the extension direction of the piston end, the lower material plate 52 extends to the flat laying plate 26, and the rotary fermented feed of the flat laying plate 26 falls onto the conveying belt 53 along the lower material plate 52.

An implementation method of a fermented feed drying device for piglet cultivation comprises the following steps:

the method comprises the following steps: the shaft of the motor 22 drives the rotating shaft 221 to rotate, and during the rotation of the rotating shaft 221, the limiting ring 24 moves downwards along the rotating shaft 221 and the guide rod 231;

step two: the outer baffle ring 25 slowly descends to be sleeved on the edge of the outer ring of the drying platform 31, and the outer baffle ring 25 blocks the outer part of the flat plate 26;

step three: the fermented feed flowing into the feeding pipe 6 falls on the drying platform 31, the air pump 42 fills air into the material shifting shell 43, the telescopic rod 46 extends to be flush with the material shifting strip 41, and the motor 22 drives the telescopic rod 46 and the material shifting strip 41 to rotate for flatly spreading the fermented feed;

step four: the heating plate 34 generates heat to the heating spiral disc 33, the heating spiral disc 33 is used for heating the drying platform 31, and the fermented feed on the drying platform 31 is dried;

step five: the air pump 42 pumps air into the material stirring shell 43, the telescopic rod 46 retracts into the material stirring shell 43, the material stirring bar 41 rotates reversely along with the motor 22, and the fermented feed on the drying platform 31 is stirred, so that heat conduction is more uniform;

step six: during blanking, the motor 22 rotates reversely to raise the outer retainer ring 25, the air cylinder 51 drives the blanking plate 52 to extend onto the drying platform 31, and the drying platform 31 rotates under the guidance of the blanking plate 52 and falls into the conveying belt 53.

In conclusion; the invention relates to a fermented feed drying device for piglet breeding and an implementation method thereof, and the fermented feed drying device comprises a drying box 1 and a feeding pipe 6, wherein the feeding pipe 6 is connected to the top surface of one side of the drying box 1, a flat laying component 2, a drying component 3, a stirring component 4 and a blanking component 5 are arranged in the drying box 1, the stirring component 4 and the blanking component 5 are arranged on the flat laying component 2, the drying component 3 is arranged below the flat laying component 2, fermented feed flowing into the feeding pipe 6 falls onto the drying component 3, the drying component 3 is used for drying the fermented feed after the flat laying component 2 is used for laying the fermented feed, the stirring component 4 is used for stirring the fermented feed to disperse in the drying process, the fermented feed is discharged through the blanking component 5 after uniform drying, and the blanking component 5 discharges the material.

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 able to cover the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.

Claims

1. The utility model provides a piglet is bred and uses fermented fodder mummification device, a serial communication port, including mummification case (1) and inlet pipe (6), inlet pipe (6) are connected on one side top surface of mummification case (1), the internally mounted of mummification case (1) has tiling subassembly (2), mummification subassembly (3), dial material subassembly (4) and unloading subassembly (5) and install on tiling subassembly (2), mummification subassembly (3) set up the below in tiling subassembly (2), the fermented fodder that inlet pipe (6) flowed in falls into on mummification subassembly (3), after tiling subassembly (2) are used for tiling fermented fodder, mummification subassembly (3) are used for the mummification fermented fodder, stir fermented fodder scattered in-process that stirring material subassembly (4) are used for the mummification, arrange the material through unloading subassembly (5) after the even mummification.

2. The fermented feed drying device for piglet cultivation according to claim 1, wherein the spreading component (2) comprises a support (21), a motor (22), a limiting frame (23), a limiting ring (24), an outer baffle ring (25) and a spreading plate (26), one end of the support (21) is mounted on the inner wall of the drying box (1), the motor (22) is mounted on the other end of the support (21), a rotating shaft (221) is mounted on a shaft of the motor (22), an external thread is processed on the outer wall of the rotating shaft (221), the bottom end of the rotating shaft (221) is connected with the spreading plate (26), and the rotating shaft (221) is meshed with the limiting ring (24) through the external thread;

the outer wall of the limiting ring (24) is connected with one end of the limiting frame (23), the other end of the limiting frame (23) is fixed with the inner wall of the outer baffle ring (25), the middle of the limiting frame (23) is penetrated through by the guide rod (231), and the top end of the guide rod (231) is fixed with the top wall of the drying box (1).

3. The fermented feed drying device for piglet cultivation according to claim 1, wherein the drying component (3) comprises a drying platform (31), a platform support (32), a heating spiral disc (33) and a heating sheet (34), one end of the platform support (32) is fixed on the side wall of the drying box (1), the drying platform (31) is arranged on the platform support (32), the bottom surface of the drying platform (31) is fixed with the heating spiral disc (33), the heating spiral disc (33) is connected with the heating sheet (34), and the outer baffle ring (25) descends to be in contact connection with the outer ring of the drying platform (31).

4. The fermented feed drying device for piglet cultivation according to claim 1, wherein the stirring assembly (4) comprises a stirring bar (41), an air pump (42), a stirring shell (43), a partition plate (44), a top plate (45), an expansion link (46) and a sealing plate (47), the air pump (42) and the stirring shell (43) are fixed on the bottom surface of the flat bed plate (26), and an air outlet of the air pump (42) is communicated with the inside of the stirring shell (43);

the bottom end of the material shifting shell (43) is fixed with material shifting strips (41) at equal intervals, and material shifting gaps are reserved among the material shifting strips (41);

the material poking device is characterized in that the partition plates (44) are fixed in the material poking shell (43) at equal intervals, the top ends of the partition plates (44) are fixed to the top plate (45), an accommodating cavity is formed between the partition plates (44) and the top plate (45), one end of the telescopic rod (46) is fixed to the sealing plate (47), and the other end of the telescopic rod (46) penetrates through the material poking shell (43) and is located in the material poking gap.

5. The fermented feed drying device for piglet cultivation according to claim 4, wherein the sealing plate (47) is hermetically connected with the partition plate (44) and the inner wall of the material stirring shell (43), the top plate (45) is provided with a through hole (451), and the air pump (42) is communicated with the accommodating cavity through the through hole (451);

the air pump (42) drives air to flow into the material stirring shell (43), the internal pressure of the material stirring shell (43) is increased, the top plate (45) drives the telescopic rod (46) to descend synchronously, the telescopic rod (46) descends to be aligned with the bottom surface of the material stirring strip (41), and the telescopic rod (46) and the material stirring strip (41) form a whole plate.

6. The fermented feed drying device for piglet cultivation according to claim 5, wherein the stirring bar (41) and the telescopic rod (46) form a whole plate, and the whole plate is arranged along the radial direction of the bottom surface of the flat plate (26).

7. The fermented feed drying device for piglet cultivation according to claim 1, wherein the blanking assembly (5) comprises an air cylinder (51), a blanking plate (52) and a conveying belt (53), the air cylinder (51) is fixed on the inner wall of the drying box (1), one end of the blanking plate (52) is connected with the piston end of the air cylinder (51), the other end of the blanking plate (52) faces the drying platform (31), and the conveying belt (53) is located right below the blanking plate (52);

the blanking plate (52) forms an included angle of 30 degrees with the radial direction of the flat plate (26) along the extension direction of the piston end, the blanking plate (52) extends to the flat plate (26), and the flat plate (26) rotates to ferment feed and falls onto the conveying belt (53) along the blanking plate (52).

8. An implementation method of the fermented feed drying device for piglet cultivation according to any one of claims 1 to 7, comprising the following steps:

s1: the shaft of the motor (22) drives the rotating shaft (221) to rotate, and in the rotating process of the rotating shaft (221), the limiting ring (24) moves downwards along the rotating shaft (221) and the guide rod (231);

s2: the outer baffle ring (25) slowly descends to be sleeved on the edge of the outer ring of the drying platform (31), and the outer baffle ring (25) blocks the outside of the drying platform (31);

s3: fermented feed flowing into the feeding pipe (6) falls on the drying platform (31), the air pump (42) fills air into the material stirring shell (43), the telescopic rod (46) extends to be flush with the material stirring strip (41), and the motor (22) drives the telescopic rod (46) and the material stirring strip (41) to rotate for flatly paving the fermented feed;

s4: the heat generated by the heating sheet (34) is transferred to the heating spiral disc (33), the heating spiral disc (33) is used for heating the drying platform (31), and the fermented feed on the drying platform (31) is dried;

s5: the air pump (42) pumps air into the material stirring shell (43), the telescopic rod (46) retracts into the material stirring shell (43), the material stirring strip (41) rotates reversely along with the motor (22), and the fermented feed on the drying platform (31) is stirred, so that heat conduction is more uniform;

s6: when blanking, the motor (22) rotates reversely, the outer baffle ring (25) rises, the air cylinder (51) drives the blanking plate (52) to extend onto the paving plate (26), and the paving plate (26) rotates and falls into the conveying belt (53) under the guidance of the blanking plate (52).