阅读说明：本技术 一种氨基酸肥的生产装置及其生产方法 (Production device and production method of amino acid fertilizer ) 是由 韩自玺 杨睿磊 于 2021-05-15 设计创作，主要内容包括：本发明公开了一种氨基酸肥的生产装置及其生产方法,涉及新型氨基酸肥生产加工技术领域。本发明包括引导铺料结构、高效制成结构和定量存放导出配料结构,引导铺料结构的顶端滑动连接有高效制成结构,高效制成结构顶端的一侧固定连接有定量存放导出配料结构,引导铺料结构用于引导高效制成结构位移,并形成对加工好的氨基酸肥的导出。本发明通过引导铺料结构和高效制成结构的配合设计,使得装置便于完成对原料到氨基酸肥的一系列自动化的一体化装置生产,从而提高整体的加工效率及产出效率,且通过定量存放导出配料结构的设计,使得装置便于向原材料中定时定量的添加不同的配料,从而降低了人力添加控制的人力消耗,提高整体的使用便捷度。(The invention discloses a production device and a production method of an amino acid fertilizer, and relates to the technical field of production and processing of novel amino acid fertilizers. The invention comprises a guiding and paving structure, a high-efficiency manufacturing structure and a quantitative storage and lead-out batching structure, wherein the top end of the guiding and paving structure is connected with the high-efficiency manufacturing structure in a sliding manner, one side of the top end of the high-efficiency manufacturing structure is fixedly connected with the quantitative storage and lead-out batching structure, and the guiding and paving structure is used for guiding the displacement of the high-efficiency manufacturing structure and leading out processed amino acid fertilizer. According to the invention, through the matching design of the guide material laying structure and the efficient manufacturing structure, the device is convenient for completing a series of automatic integrated device production from raw materials to amino acid fertilizers, so that the integral processing efficiency and the output efficiency are improved, and through the design of the quantitative storage and guide-out batching structure, the device is convenient for adding different batching materials into the raw materials regularly and quantitatively, so that the manpower consumption of manpower addition control is reduced, and the integral use convenience is improved.)

1. The utility model provides a production facility that amino acid is fertile which characterized in that: deposit including guide stone structure (1), high-efficient make structure (2) and ration and derive batching structure (3), the top sliding connection of guide stone structure (1) has high-efficient make structure (2), one side fixedly connected with ration that structure (2) top was made to the high efficiency is deposited and is derived batching structure (3), guide stone structure (1) is used for the guide high efficiency to make structure (2) displacement to form the derivation to the fertile amino acid of processing, structure (2) are made to the high efficiency and are used for the integration to make amino acid fertilizer, it is used for the inside addition batching of structure (2) to the high efficiency of making to derive batching structure (3) is deposited to the ration to constant temperature protection batching in the short time.

2. The apparatus for producing amino acid fertilizer as claimed in claim 1, wherein: guide stone structure (1) is including carrying on locating plate (4), trackless cylinder (5) and conveyer belt (6), the equal fixedly connected with in both sides of conveyer belt (6) carries on locating plate (4), carry on one side fixedly connected with trackless cylinder (5) of locating plate (4).

3. The apparatus for producing amino acid fertilizer as claimed in claim 1, wherein: high efficiency is made structure (2) and is cut integrative structure (9) including spray drying processing structure (7), integrative jar structure of preliminary treatment fermentation reaction (8) and flattening, the bottom fixedly connected with spray drying processing structure (7) of integrative jar structure of preliminary treatment fermentation reaction (8), one side fixedly connected with of spray drying processing structure (7) flattens and cuts integrative structure (9), integrative jar structure of preliminary treatment fermentation reaction (8) are used for carrying out the base liquid that breaks, the thermal fermentation fuses and form amino acid fertilizer to raw and other materials, spray drying processing structure (7) are used for spraying the spray drying shaping after the base liquid to handling good amino acid fertilizer, flatten and cut integrative structure (9) and be used for further flattening to the base liquid of amino acid fertilizer after the drying and extrude moisture to cut apart the shaping.

4. The apparatus for producing an amino acid fertilizer as claimed in claim 3, wherein: the spray drying processing structure (7) comprises a liquid storage box (10), a first micro water pump (11), a derivation spray pipe (12), an atomization spray head (13), a heating power drying box (14), an electric heating lamp post (15), a wind power fan (16) and an extension matching arm (17), the first micro water pump (11) is fixedly connected with one end of the liquid storage box (10), the output end of the first micro water pump (11) is fixedly connected with the derivation spray pipe (12), the bottom end of the derivation spray pipe (12) is fixedly connected with a plurality of atomization spray heads (13), the heating power drying box (14) is fixedly connected with the two sides of the bottom end of the liquid storage box (10), the bottom end of the heating power drying box (14) is fixedly connected with a plurality of wind power fans (16), the inner side of the heating power drying box (14) is fixedly connected with the electric heating lamp post (15), the extension matching arm (17) is welded at the two ends of the heating power drying box (14), the extension movable arm (17) is connected with the trackless cylinder (5) in a sliding mode.

5. The apparatus for producing an amino acid fertilizer as claimed in claim 4, wherein: the flattening and cutting integrated structure (9) comprises a positioning and carrying frame (18), an extending positioning plate (19), a first motor (20), an output linkage shaft (21), a overturning driving rod (22), a rolling wheel (23), a hydraulic piston cylinder (24) and a slitting push plate (25), wherein the positioning and carrying frame (18) is fixedly connected with one end of the liquid storage tank (10), the hydraulic piston cylinder (24) is fixedly connected with one end of the positioning and carrying frame (18), the slitting push plate (25) is fixedly connected with the output end of the hydraulic piston cylinder (24), the extending positioning plate (19) is welded on one side of the positioning and carrying frame (18), the first motor (20) is fixedly connected with one side of the extending positioning plate (19) through a screw, the output linkage shaft (21) is fixedly connected with the output end of the first motor (20), the overturning driving rod (22) is sleeved on the outer sides of the two sides of the output linkage shaft (21), a rolling wheel (23) is rotatably connected between the two turning driving rods (22).

6. The apparatus for producing an amino acid fertilizer as claimed in claim 5, wherein: integrative jar structure of preliminary treatment fermentation reaction (8) is including making jar (26), inlet pipe (27), second motor (28), torque output pole (29), multifunctional support dish structure (30) and second micro water pump (31), the top of making jar (26) is through screw fixedly connected with second motor (28), the output fixedly connected with torque output pole (29) of second motor (28), the bottom fixedly connected with multifunctional support dish structure (30) of torque output pole (29), one side welding of making jar (26) has inlet pipe (27), the bottom fixedly connected with second micro water pump (31) of making jar (26).

7. The apparatus for producing an amino acid fertilizer as claimed in claim 6, wherein: multifunctional support disc structure (30) are including carrying on base plate (32), electric heat post (33), hydraulic piston cylinder (34) and cutting piece (35), carry on a plurality of electric heat posts (33) of week side fixedly connected with of base plate (32), the inboard fixedly connected with hydraulic piston cylinder (34) of carrying on base plate (32), the outside rotation of electric heat post (33) is connected with cutting piece (35), the output and the cutting piece (35) of hydraulic piston cylinder (34) are connected.

8. The apparatus for producing amino acid fertilizer as claimed in claim 1, wherein: the quantitative storage and lead-out batching structure (3) comprises an internal loading column (36), a prepared storage pipe (37), a refrigeration ring (38), a semiconductor refrigeration plate (39), a temperature conduction column (40) and a timing and quantitative lead-out structure (41), a plurality of preliminary storage pipes (37) are fixedly connected to the inner side of the built-in carrying column (36), a refrigeration ring (38) is fixedly connected with the outer side of the built-in carrying column (36), one end of the refrigerating ring (38) is fixedly connected with a semiconductor refrigerating plate (39), the refrigerating end of the semiconductor refrigerating plate (39) is fixedly connected with a temperature conducting column (40), the bottom end of the built-in carrying column (36) is fixedly connected with a timing and quantitative derivation structure (41), the inner side of the built-in carrying column (36) is fixedly connected with a timing controller, the bottom end of the preliminary storage pipe (37) is fixedly connected with a flow valve, the timing controller is electrically connected with the flow valve and the timing and quantitative derivation structure (41).

9. The apparatus for producing an amino acid fertilizer as claimed in claim 8, wherein: the timing and quantitative guide structure (41) comprises a guide pipe (42), a positioning support plate (43), a third motor (44), a driving gear (45), a driven gear disc (46) and a guide funnel (47), a positioning support plate (43) is welded at one side of the guide pipe (42), the bottom end of the positioning support plate (43) is fixedly connected with a third motor (44) through a screw, the output end of the third motor (44) is fixedly connected with a driving gear (45), the top end of the guide pipe (42) is rotationally connected with a driven gear disc (46), one side of the driven gear disc (46) is meshed with the driving gear (45), the upper surface of the driven gear disc (46) is fixedly connected with a guide funnel (47), the bottom end of the built-in carrying column (36) is rotationally connected with a driven gear disc (46), the output end of the guide pipe (42) is fixedly connected with the high-efficiency manufacturing structure (2).

10. A production method of an amino acid fertilizer production device is used for any one of the production device claims of the amino acid fertilizer, and is characterized by comprising the following steps:

the first step is as follows: raw materials are put into the pretreatment fermentation reaction integrated tank structure (8) through a feeding pipe (27), the pretreatment fermentation reaction integrated tank structure (8) is utilized to complete the treatment of the raw materials, and the raw materials are fermented to produce amino acid;

secondly, the following steps: ingredients are injected into the pretreatment fermentation reaction integrated tank structure (8) through the quantitative storage and leading-out ingredient structure (3), and the ingredients and the raw materials are fully stirred and fused by the pretreatment fermentation reaction integrated tank structure (8);

the third step: a trackless cylinder (5) is used for driving a spray drying processing structure (7) to reciprocate, so that the liquid amino acid fertilizer is superposed on the top end of a conveyor belt (6) and is heated and dried;

the fourth step: the flattening and cutting integrated structure (9) is used for synchronously rolling the fertilizer, so that the fertilizer is further discharged while being flattened, and finally, the flattening and cutting integrated structure (9) is used for cutting the fertilizer;

the fifth step: the produced fertilizer is guided out by a conveyor belt (6).

Technical Field

The invention relates to the technical field of production and processing of novel amino acid fertilizers, in particular to a production device and a production method of an amino acid fertilizer.

Background

Amino acid exists in the fertilizer as the minimum molecule of the protein, and has the characteristic of being easily absorbed by crops; the fertilizer applying device has the functions of improving disease resistance of a fertilizer applying object, improving quality of fertilizer applying crops, supplementing amino acid necessary for plants, stimulating and adjusting rapid growth of the plants, promoting robust growth of the plants, promoting absorption of nutrient substances, enhancing metabolic function of the plants, improving photosynthesis, promoting development of root systems of the plants and accelerating growth and propagation of the plants, and a corresponding device is needed for producing the amino acid.

Disclosure of Invention

The invention aims to provide a production device and a production method of an amino acid fertilizer, which aim to solve the existing problems: the existing device is limited by the structure in the using process, and the turnover processing among a plurality of devices is needed, so that the processing efficiency is poor.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a production device of amino acid fertilizer, includes that guide stone structure, high efficiency are made the structure and the ration is deposited and is derived the batching structure, the top sliding connection of guide stone structure has the high efficiency to make the structure, the high efficiency is made one side fixedly connected with ration on structure top and is deposited and derive the batching structure, guide stone structure is used for guiding the high efficiency and is made the structure displacement to form the derivation to the fertile amino acid that has processed, the high efficiency is made the structure and is used for the integration to make amino acid fertile, the ration is deposited and is derived the batching structure and is used for regularly quantitative inside to make the structure to add the batching to the high efficiency to constant temperature protection batching in the short time.

Preferably, the guiding and spreading structure comprises a carrying positioning plate, a trackless cylinder and a conveying belt, the two sides of the conveying belt are fixedly connected with the carrying positioning plate, and one side of the carrying positioning plate is fixedly connected with the trackless cylinder.

Preferably, the high efficiency is made the structure and is included spray drying processing structure, integrative jar structure of preliminary treatment fermentation reaction and flatten and cut integrative structure, the bottom fixedly connected with spray drying processing structure of integrative jar structure of preliminary treatment fermentation reaction, one side fixedly connected with of spray drying processing structure flattens and cuts integrative structure, integrative jar structure of preliminary treatment fermentation reaction is used for carrying out the base liquid that broken, thermal fermentation fused formation amino acid fertilizer to raw and other materials, spray drying processing structure is used for spraying the spray drying shaping after the base liquid to the amino acid fertilizer who handles, flatten and cut integrative structure and be used for further flattening to extrude moisture to the base liquid of the amino acid fertilizer after the drying to cut apart the shaping.

Preferably, spray drying processing structure joins in marriage the arm including holding liquid case, first miniature pump, derivation spray line, atomizing sprinkler head, heating power stoving case, electric heat lamp pole, wind-force fan and extension, the first miniature pump of one end fixedly connected with of holding liquid case, the spray line is derived to the output fixedly connected with of first miniature pump, derive a plurality of atomizing spray heads of the bottom fixedly connected with of spray line, the equal fixedly connected with heating power stoving case in both sides that holds liquid bottom of the case, a plurality of wind-force fans of the bottom fixedly connected with of heating power stoving case, the inboard fixedly connected with electric heat lamp pole of heating power stoving case, the both ends of heating power stoving case are all welded and are extended and join in marriage the arm, it joins in marriage arm and trackless cylinder sliding connection to extend.

Preferably, flatten and cut an organic whole structure and include the location and take the carrier, extend locating plate, first motor, output universal driving shaft, upset drive rod, roller wheel, hydraulic piston cylinder and cut the push pedal, the one end fixedly connected with location of holding the liquid case takes the carrier, the one end fixedly connected with hydraulic piston cylinder of location and taking the carrier, the push pedal is cut to the output fixedly connected with of hydraulic piston cylinder, the one side welding of location and taking the carrier has the extension locating plate, the first motor of screw fixedly connected with is passed through to the one side of extending the locating plate, the output fixedly connected with output universal driving shaft of first motor, the upset drive rod has been cup jointed in the outside of output universal driving shaft both sides, two it is connected with the roller wheel to rotate between the upset drive rod.

Preferably, the integrative jar structure of preliminary treatment fermentation reaction is including making jar, inlet pipe, second motor, torque delivery rod, multifunctional support dish structure and the miniature water pump of second, the top of making the jar is through screw fixedly connected with second motor, the output fixedly connected with torque delivery rod of second motor, the multifunctional support dish structure of bottom fixedly connected with of torque delivery rod, the welding of one side of making the jar has the inlet pipe, the miniature water pump of bottom fixedly connected with second of making the jar.

Preferably, the multifunctional supporting disk structure comprises a carrying base plate, electrothermal columns, a hydraulic piston cylinder and cutting pieces, wherein a plurality of electrothermal columns are fixedly connected to the peripheral side face of the carrying base plate, a hydraulic piston cylinder is fixedly connected to the inner side of the carrying base plate, the cutting pieces are rotatably connected to the outer sides of the electrothermal columns, and the output end of the hydraulic piston cylinder is connected with the cutting pieces.

Preferably, the ration is deposited and is derived batching structure includes built-in carrier post, prepares to deposit pipe, refrigeration ring, semiconductor refrigeration board, leads the temperature post and regularly derives the structure quantitatively, a plurality of preparation of inboard fixedly connected with of built-in carrier post are deposited the pipe, the outside fixedly connected with refrigeration ring of built-in carrier post, the one end fixedly connected with semiconductor refrigeration board of refrigeration ring, the refrigeration end fixedly connected with of semiconductor refrigeration board leads the temperature post, the structure is derived to the bottom fixedly connected with of built-in carrier post regularly and quantitatively, the inboard fixedly connected with timing controller of built-in carrier post, prepare the bottom fixedly connected with flow valve of depositing the pipe, timing controller and flow valve and regularly and quantitatively derive the structure and be electric connection.

Preferably, the structure is derived to timing and ration includes guiding tube, location support plate, third motor, driving gear, driven gear dish and derives the funnel, the welding of one side of guiding tube has location support plate, screw fixedly connected with third motor is passed through to location support plate's bottom, the output fixedly connected with driving gear of third motor, the top of guiding tube is rotated and is connected with the driven gear dish, one side and the driving gear meshing of driven gear dish are connected, the funnel is derived to the last fixed surface of driven gear dish, the bottom and the driven gear dish of built-in piggy-back post rotate and are connected, structure fixed connection is made with the high efficiency to the output of guiding tube.

A production method of a production device of amino acid fertilizer is used for one item of the production device of any one amino acid fertilizer, and is characterized by comprising the following steps:

the first step is as follows: the raw materials are put into the interior of the pretreatment fermentation reaction integrated tank structure through a feeding pipe, the pretreatment fermentation reaction integrated tank structure is utilized to complete the treatment of the raw materials, and the raw materials are fermented to produce amino acid;

secondly, the following steps: injecting ingredients into the pretreatment fermentation reaction integrated tank structure through a quantitative storage and leading-out ingredient structure, and fully stirring and fusing the ingredients and the raw materials by utilizing the pretreatment fermentation reaction integrated tank structure;

the third step: a trackless cylinder is used for driving a spray drying processing structure to reciprocate, so that the liquid amino acid fertilizer is superposed on the top end of the conveyor belt and is heated and dried;

the fourth step: the flattening and cutting integrated structure is used for completing synchronous rolling of the fertilizer, so that moisture is further discharged while flattening the fertilizer, and finally, the flattening and cutting integrated structure is used for completing cutting of the fertilizer;

the fifth step: the prepared fertilizer is guided out through a conveyor belt.

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

1. according to the invention, through the matching design of the material spreading structure and the high-efficiency manufacturing structure, the device is convenient for completing a series of automatic integrated device production from raw materials to amino acid fertilizer, so that the overall processing efficiency and output efficiency are improved;

2. according to the invention, through the design of the quantitative storage and leading-out batching structure, the device is convenient for adding different batching materials into raw materials in a timed and quantitative manner, so that the manpower consumption of manpower addition control is reduced, and the overall use convenience is improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic structural view of the present invention as a whole;

FIG. 2 is a schematic structural view of a paving-directing structure according to the present invention;

FIG. 3 is a schematic structural view of a high efficiency textured structure of the present invention;

FIG. 4 is a schematic partial structure view of a spray drying process structure according to the present invention;

FIG. 5 is a schematic view of a partial structure of the flattening and cutting integrated structure according to the present invention;

FIG. 6 is a partial schematic structural view of a pretreatment fermentation reaction integrated tank structure according to the present invention;

FIG. 7 is a partial schematic view of the structure of the multifunctional support tray of the present invention;

FIG. 8 is a schematic view of a partial structure of a quantitative storage and dispensing structure according to the present invention;

fig. 9 is a partial structure diagram of the timing and quantitative derivation structure according to the present invention.

In the figure: 1. a guiding placement structure; 2. the structure is manufactured efficiently; 3. quantitatively storing and guiding the batching structure; 4. carrying a positioning plate; 5. a trackless cylinder; 6. a conveyor belt; 7. spray drying the processing structure; 8. a pretreatment fermentation reaction integrated tank structure; 9. flattening and cutting the integrated structure; 10. a liquid storage tank; 11. a first micro water pump; 12. leading out the spraying pipe; 13. an atomizing spray head; 14. a thermal drying box; 15. an electric heating lamp post; 16. a wind power fan; 17. an extension fitting arm; 18. positioning the lapping frame; 19. extending the positioning plate; 20. a first motor; 21. an output linkage shaft; 22. turning over the driving rod; 23. a rolling wheel; 24. a hydraulic piston cylinder; 25. slitting the push plate; 26. making into a can; 27. a feed pipe; 28. a second motor; 29. a torque output rod; 30. a multifunctional support disk structure; 31. a second micro water pump; 32. a mounting base plate; 33. an electrothermal column; 34. a hydraulic piston cylinder; 35. cutting the slices; 36. a carrying column is arranged in the frame; 37. preparing a storage tube; 38. a refrigeration loop; 39. a semiconductor refrigeration plate; 40. a temperature conducting column; 41. a timed and quantitative derivation structure; 42. a guide tube; 43. positioning the supporting plate; 44. a third motor; 45. a driving gear; 46. a driven gear plate; 47. and (6) leading out the funnel.

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.

The first embodiment is as follows:

please refer to fig. 1:

the utility model provides a production device that amino acid is fertile, including guide stone structure 1, high efficiency is made structure 2 and the ration is deposited and is derived batching structure 3, guide stone structure 1's top sliding connection has the high efficiency to make structure 2, one side fixedly connected with ration that the high efficiency made 2 tops is deposited and is derived batching structure 3, guide stone structure 1 is used for guiding the high efficiency and is made 2 displacements of structure, and form the derivation to the amino acid fertilizer that has processed, structure 2 is made to the high efficiency and is used for the integration to make amino acid fertilizer, the ration is deposited and is derived batching structure 3 and is used for the inside addition batching of regular and quantitative structure 2 to the high efficiency, and constant temperature protection batching in the short time.

Please refer to fig. 2-3:

the guide material spreading structure 1 comprises a carrying positioning plate 4, a trackless cylinder 5 and a conveying belt 6, wherein the carrying positioning plate 4 is fixedly connected to both sides of the conveying belt 6, and the trackless cylinder 5 is fixedly connected to one side of the carrying positioning plate 4;

the efficient manufacturing structure 2 comprises a spray drying processing structure 7, a pretreatment fermentation reaction integrated tank structure 8 and a flattening and cutting integrated structure 9, the bottom end of the pretreatment fermentation reaction integrated tank structure 8 is fixedly connected with the spray drying processing structure 7, one side of the spray drying processing structure 7 is fixedly connected with the flattening and cutting integrated structure 9, the pretreatment fermentation reaction integrated tank structure 8 is used for crushing raw materials, fusing the raw materials through thermal fermentation to form base liquid of the amino acid fertilizer, the spray drying processing structure 7 is used for spraying, drying and forming the treated base liquid of the amino acid fertilizer, and the flattening and cutting integrated structure 9 is used for further flattening and extruding moisture of the dried base liquid of the amino acid fertilizer and cutting and forming the base liquid;

the position driving of the spray drying processing structure 7, the pretreatment fermentation reaction integrated tank structure 8 and the flattening and cutting integrated structure 9 is completed by utilizing the displacement of the trackless cylinder 5, and the guiding out of the finally formed fertilizer is completed by utilizing the conveying belt 6;

please refer to fig. 6-7:

the pretreatment fermentation reaction integrated tank structure 8 comprises a making tank 26, a feeding pipe 27, a second motor 28, a torque output rod 29, a multifunctional supporting disk structure 30 and a second micro water pump 31, wherein the top end of the making tank 26 is fixedly connected with the second motor 28 through a screw, the output end of the second motor 28 is fixedly connected with the torque output rod 29, the bottom end of the torque output rod 29 is fixedly connected with the multifunctional supporting disk structure 30, the feeding pipe 27 is welded on one side of the making tank 26, and the bottom end of the making tank 26 is fixedly connected with the second micro water pump 31;

the multifunctional supporting disk structure 30 comprises a carrying base plate 32, a plurality of electric heating columns 33, a hydraulic piston cylinder 34 and cutting pieces 35, wherein the peripheral side face of the carrying base plate 32 is fixedly connected with the electric heating columns 33, the inner side of the carrying base plate 32 is fixedly connected with the hydraulic piston cylinder 34, the outer side of each electric heating column 33 is rotatably connected with the cutting piece 35, and the output end of each hydraulic piston cylinder 34 is connected with the cutting piece 35;

the raw materials are guided into the manufacturing tank 26 through the feeding pipe 27, as the raw materials of the amino acid fertilizer are mostly leftovers of a marine fish processing factory and cooking serofluid, solid and liquid exist, the smaller the solid particles in the fermentation process are, the better the solid particles are, the derivation of the cutting piece 35 is completed through controlling the hydraulic piston cylinder 34, the cutting piece 35 rotates outwards through the rotation of the electrothermal column 33, the second motor 28 is utilized to complete the rotation driving of the torque output rod 29, the multifunctional supporting disk structure 30 drives the cutting piece 35 to complete the rotation, the solid is refined and crushed, the stirring is completed during the manufacturing, the ingredients and the raw materials which are injected into the manufacturing tank 26 by the quantitative storage and derivation ingredient structure 3 are stably fused, at the moment, fermentation flora is thrown into the manufacturing tank 26 through the feeding pipe 27, the electrothermal column 33 is electrified to form heating, the thermal fermentation is completed, and the fermentation efficiency is further promoted, finishing the liquid processing of the amino acid fertilizer;

please refer to fig. 4:

the spray drying processing structure 7 comprises a liquid storage tank 10, a first micro water pump 11, a leading-out spray pipe 12, an atomization spray head 13, a thermal drying tank 14, an electric heating lamp post 15, a wind power fan 16 and an extension matching arm 17, wherein one end of the liquid storage tank 10 is fixedly connected with the first micro water pump 11, the output end of the first micro water pump 11 is fixedly connected with the leading-out spray pipe 12, the bottom end of the leading-out spray pipe 12 is fixedly connected with a plurality of atomization spray heads 13, two sides of the bottom end of the liquid storage tank 10 are fixedly connected with the thermal drying tank 14, the bottom end of the thermal drying tank 14 is fixedly connected with the wind power fan 16, the inner side of the thermal drying tank 14 is fixedly connected with the electric heating lamp post 15, two ends of the thermal drying tank 14 are welded with the extension matching arm 17, and the extension matching arm 17 is connected with the trackless cylinder 5 in a sliding manner;

the liquid amino acid fertilizer is injected into the liquid storage box 10 through a second miniature water pump 31, the liquid amino acid fertilizer is guided into the guiding-out spraying pipe 12 through a first miniature water pump 11 and is sprayed on the conveying belt 6 through a plurality of atomizing spraying heads 13, at the moment, the electric heating lamp post 15 is used for electrifying and storing heat in the thermal drying box 14, the wind fan 16 is used for guiding out the stored heat in the thermal drying box 14 to form wind-heat mixed drying, the drying of the liquid amino acid fertilizer is completed, reciprocating back and forth spraying and drying are formed through the matching of the extending distribution arm 17 and the trackless cylinder 5, and multilayer overlapping is formed, so that the thickness of the fertilizer produced is ensured;

please refer to fig. 5:

the flattening and cutting integrated structure 9 comprises a positioning and lapping frame 18, an extension positioning plate 19, a first motor 20, an output linkage shaft 21, a turnover driving rod 22, a rolling wheel 23, a hydraulic piston cylinder 24 and a slitting push plate 25, one end of a liquid storage tank 10 is fixedly connected with the positioning and lapping frame 18, one end of the positioning and lapping frame 18 is fixedly connected with the hydraulic piston cylinder 24, the output end of the hydraulic piston cylinder 24 is fixedly connected with the slitting push plate 25, one side of the positioning and lapping frame 18 is welded with the extension positioning plate 19, one side of the extension positioning plate 19 is fixedly connected with the first motor 20 through a screw, the output end of the first motor 20 is fixedly connected with the output linkage shaft 21, the turnover driving rod 22 is sleeved on the outer sides of two sides of the output linkage shaft 21, and the rolling wheel 23 is rotatably connected between the two turnover driving rods 22;

in the process of processing the fertilizer, the first motor 20 is utilized to rotate the output linkage shaft 21, so that the output linkage shaft 21 drives the overturning driving rod 22 to rotate, the rolling wheel 23 and the conveyor belt 6 are in a vertical state, the fertilizer at the top end of the conveyor belt 6 is rolled, a part of liquid in the fertilizer is removed, the fertilizer is flattened, the first motor 20 is controlled to reset after flattening, the hydraulic piston cylinder 24 is controlled to extend the output end, and the slitting push plate 25 is contacted with the fertilizer to complete the division of the fertilizer;

please refer to fig. 8-9:

the quantitative storage and derivation burdening structure 3 comprises an internal carrying column 36, prepared storage pipes 37, a refrigeration ring 38, a semiconductor refrigeration plate 39, a temperature conduction column 40 and a timing and quantitative derivation structure 41, wherein the internal side of the internal carrying column 36 is fixedly connected with a plurality of prepared storage pipes 37, the external side of the internal carrying column 36 is fixedly connected with the refrigeration ring 38, one end of the refrigeration ring 38 is fixedly connected with the semiconductor refrigeration plate 39, the refrigeration end of the semiconductor refrigeration plate 39 is fixedly connected with the temperature conduction column 40, the bottom end of the internal carrying column 36 is fixedly connected with the timing and quantitative derivation structure 41, the internal side of the internal carrying column 36 is fixedly connected with a timing controller, the bottom end of the prepared storage pipes 37 is fixedly connected with a flow valve, and the timing controller, the flow valve and the timing and quantitative derivation structure 41 are electrically connected;

the timing and quantitative derivation structure 41 comprises a guide pipe 42, a positioning support plate 43, a third motor 44, a driving gear 45, a driven gear disc 46 and a derivation funnel 47, the positioning support plate 43 is welded on one side of the guide pipe 42, the bottom end of the positioning support plate 43 is fixedly connected with the third motor 44 through a screw, the output end of the third motor 44 is fixedly connected with the driving gear 45, the top end of the guide pipe 42 is rotatably connected with the driven gear disc 46, one side of the driven gear disc 46 is meshed with the driving gear 45, the upper surface of the driven gear disc 46 is fixedly connected with the derivation funnel 47, the bottom end of the built-in carrying column 36 is rotatably connected with the driven gear disc 46, and the output end of the guide pipe 42 is fixedly connected with the high-efficiency manufacturing structure 2;

the refrigeration temperature generated by electrifying the semiconductor refrigeration plate 39 is led out to the refrigeration ring 38 through the temperature guide column 40 by utilizing the matching of the semiconductor refrigeration plate 39 and the temperature guide column 40, so as to accumulate the refrigeration temperature in the refrigeration ring 38, the refrigeration temperature is led out to the prepared storage pipe 37 by utilizing the contact of the built-in carrying column 36 and the refrigeration ring 38, so as to complete the constant temperature for storing the ingredients stored in the prepared storage pipe 37, when the ingredients need to be added according to different time, the timing rotation output of the driving gear 45 is completed by controlling the third motor 44 through the timing controller, the driven gear disk 46 drives the leading-out funnel 47 to the prepared storage pipe 37 loaded with the proper ingredients under the stirring of the driving gear 45 by utilizing the meshing of the driving gear 45 and the driven gear disk 46, the flow valve at the prepared storage pipe 37 is controlled to be opened by the timing controller, so that the ingredients flow into the prepared tank 26 through the leading-out funnel 47 and the leading pipe 42, after a certain time the flow valve is controlled to close and the third motor 44 is brought to a further regulated output drive.

Example two:

the production method of the production device of the amino acid fertilizer is used in the embodiment and is characterized by comprising the following steps:

the first step is as follows: the raw material is put into the pretreatment fermentation reaction integrated tank structure 8 through a feeding pipe 27, the pretreatment fermentation reaction integrated tank structure 8 is utilized to complete the treatment of the raw material, and the raw material is fermented to produce amino acid;

secondly, the following steps: the ingredients are injected into the pretreatment fermentation reaction integrated tank structure 8 through the quantitative storage and derivation ingredient structure 3, and the ingredients and the raw materials are fully stirred and fused by the pretreatment fermentation reaction integrated tank structure 8;

the third step: a trackless cylinder 5 is used for driving a spray drying processing structure 7 to reciprocate, so that the liquid amino acid fertilizer is superposed on the top end of a conveyor belt 6 and is heated and dried;

the fourth step: the flattening and cutting integrated structure 9 is used for completing synchronous rolling of the fertilizer, so that moisture is further discharged while flattening the fertilizer, and finally the flattening and cutting integrated structure 9 is used for completing cutting of the fertilizer;

the fifth step: the produced manure is led out by means of a conveyor belt 6.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.