CN115316559B - Additive for shrimp culture pond fertilizer and water and production process thereof - Google Patents

Abstract

The invention discloses an additive for shrimp culture pond fertilizer and a production process thereof, and relates to the technical field of production of fertilizer and water additives for aquatic product culture, wherein the additive for shrimp culture pond fertilizer consists of 30-45 parts of waste white mud from alkali factories, 40-55 parts of fermented chicken manure, 10-15 parts of waste produced by fulvic acid fertilizer and 1-5 parts of inorganic nitrogen-phosphorus fertilizer, and the production process of the additive for shrimp culture pond fertilizer is realized by production equipment for the additive for shrimp culture pond fertilizer. According to the invention, in the preparation process of the additive, raw materials can be automatically screened, so that the quality of the finished additive product is prevented from being influenced by solid impurities, the manpower is saved, and the condition that tiny particles enter the air to pollute the working environment in the production process is avoided, so that the method is more suitable for industrial production.

Description

Additive for shrimp culture pond fertilizer and water and production process thereof

Technical Field

The invention relates to the technical field of production of fertilizer and water additives for aquatic product culture, in particular to an additive for fertilizer and water in a shrimp culture pond and a production process thereof.

Background

Because the ratio of the nutrient components in tap water to well water is less, if the nutrient components are directly used for cultivating aquatic products, the aquatic products are unfavorable for growth, the nutrient of the water body is increased mainly by applying a water fertilizer agent to promote the growth of the aquatic products in a pond, and the fermented chicken manure is a biological organic fertilizer produced by taking healthy and fresh chicken manure as a raw material, and can be widely used for preparing a water fertilizer additive because the water fertilizer does not pollute the water quality, can be used as fish and shrimp feed and has a water fertilizer function.

In the prior art, when fermented chicken manure is used for preparing the fertilizer water additive, the fermented chicken manure is generally directly mixed and stirred with other types of substances with fertilizer water functions, but the fermented chicken manure is dry, so that the fermented chicken manure is crushed in the stirring process, a large amount of tiny particles are generated and enter the air, and the working environment is polluted.

In addition, the fermented chicken manure usually contains a small amount of cobbles and other solid impurities in the finished product due to the omission of the raw material collecting conditions and the production conditions, and the existence of the impurities can also influence the quality of the finished product of the fertilizer water additive.

Therefore, it is necessary to invent an additive for the fertilizer and water of the shrimp culture pond and a production process thereof to solve the problems.

Disclosure of Invention

The invention aims to provide an additive for the fertilizer and the water of a shrimp culture pond and a production process thereof, so as to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: the production process of the additive for the shrimp culture pond water fertilizer comprises 30-45 parts of alkali plant waste white mud, 40-55 parts of fermented chicken manure, 10-15 parts of fulvic acid fertilizer production waste and 1-5 parts of inorganic nitrogen-phosphorus fertilizer;

the production process of the additive for the shrimp culture pond water is realized by production equipment of the additive for the shrimp culture pond water, the production equipment of the additive for the shrimp culture pond water comprises a stirring cylinder, a first driving mechanism is arranged at the bottom of the stirring cylinder and inside the stirring cylinder, a guide hopper is fixedly arranged at the top of the inner side of the stirring cylinder, and a sealing mechanism, a screening mechanism, a stirring mechanism and a second driving mechanism are sequentially arranged on the outer side of the first driving mechanism in a transmission manner from top to bottom;

the first rotary shaft in the first driving mechanism drives the first lifting sleeve plate in the sealing mechanism to lift, the first rotary shaft in the first driving mechanism drives the scraping plate in the screening mechanism to rotate, the first rotary shaft in the first driving mechanism drives the bottom plate in the stirring mechanism to rotate, the first rotary shaft in the first driving mechanism drives the second lifting sleeve plate in the second driving mechanism to lift, the driving gear in the second driving mechanism drives the lifting shaft in the stirring mechanism to rotate, and the outer annular sleeve plate in the second driving mechanism drives the lifting shaft in the stirring mechanism to lift.

Preferably, the first driving mechanism comprises a driving motor, a first rotating shaft and a second rotating shaft;

the driving motor is fixedly arranged at the bottom of the stirring cylinder, the first rotating shaft is positioned inside the stirring cylinder and is in transmission connection with the driving motor, and the second rotating shaft is connected to the top end of the first rotating shaft through the overrunning clutch.

Preferably, the sealing mechanism comprises a first lifting sleeve plate, a first spring, a mounting plate, a sealing block and a first guide rod;

the utility model discloses a guide hopper, including first lift sleeve board, first guide bar, sealing block, first spring, mounting panel, sealing block, first lift sleeve board cup joints in the second rotation axis outside to be connected with the second rotation axis transmission through the reciprocal screw thread in the second rotation axis outside, first spring, mounting panel and sealing block all slide and cup joint and set up in the second rotation axis outside, first spring one end and first lift sleeve board fixed connection and other end and mounting panel fixed connection, sealing block bonds and sets up in the mounting panel top, sealing block is located under the export of guide hopper bottom, first guide bar is provided with two, two first guide bar is fixed respectively to be set up in first lift sleeve board both sides, and all runs through guide hopper and with guide hopper sliding connection.

Preferably, the screening mechanism comprises a screen plate, a scraping plate, a rotating ring, an upper plate, a second spring and a lower plate;

the sieve is connected with the outer side of the first rotating shaft in a sliding mode, is fixedly connected with the inner wall of the stirring cylinder, the scraping plate is arranged on the first rotating shaft in a sliding and penetrating mode, the bottom of the scraping plate is attached to the top of the sieve, the rotating ring is arranged at the bottom of the sieve in a rotating and nesting mode through a bearing, two upper plates, two second springs and two lower plates are arranged on the two sides of the bottom of the sieve respectively, the two upper plates are fixedly arranged on the two sides of the bottom of the sieve respectively, the two second springs are connected with the bottom of the two upper plates respectively, the two lower plates are fixedly connected with the bottom ends of the two second springs respectively, and the two lower plates are fixedly connected with the inner wall of the stirring cylinder respectively.

Preferably, the stirring mechanism comprises a bottom plate and a plurality of stirring assemblies, wherein each stirring assembly comprises a stirring shaft, a lifting shaft, a connecting plate and a stirring column;

the bottom plate is fixedly sleeved on the outer side of the first rotating shaft and is rotationally connected with the stirring cylinder through a bearing, the stirring shaft penetrates through the bottom plate and is rotationally connected with the bottom plate through the bearing, the lifting shaft is slidably arranged on the inner side of the stirring shaft, the connecting plates and the stirring columns are all provided with a plurality of connecting plates which are uniformly and fixedly penetrated from top to bottom and are arranged on the lifting shaft, and the stirring columns are respectively and slidably sleeved on two sides of the stirring shaft and are respectively and fixedly connected with two ends of the connecting plates.

Preferably, the second driving mechanism comprises a second lifting sleeve plate, a second guide rod, an inner annular sleeve plate, an outer annular sleeve plate, a driving gear and a gear ring;

the second lift sleeve plate cup joints in the first rotation axis outside and is connected with first rotation axis transmission through the reciprocal screw thread in the first rotation axis outside, the second guide bar is provided with two, two the second guide bar slides respectively and runs through and set up in second lift sleeve plate top both sides, and all with churn inner wall fixed connection, interior annular sleeve plate is fixed cup joints in the second lift sleeve plate outside, outer annular sleeve plate passes through the bearing and rotates cup joints and set up in interior annular sleeve plate outside, outer annular sleeve plate passes through the bearing with the lift shaft bottom and rotate to be connected, drive gear is fixed cup joints and is set up in the bottom in the (mixing) shaft outside, the gear ring cup joints and sets up in outer annular sleeve plate outside, and with churn fixed connection, drive gear and gear ring meshing.

Preferably, the production process of the additive for the fertilizer and the water of the shrimp culture pond specifically comprises the following steps:

s1, adding fermented chicken manure, waste white mud of an alkali plant, waste produced by a fulvic acid fertilizer and inorganic nitrogen-phosphorus fertilizer into a guide hopper in sequence, guiding the materials by the inner wall of the guide hopper, enabling the materials to enter the stirring barrel through an opening at the bottom of the guide hopper, and then falling to the top of a sieve plate;

s2, enabling the driving motor to drive the first rotating shaft to rotate anticlockwise, enabling the second rotating shaft to rotate synchronously, driving the first lifting sleeve plate to ascend when the second rotating shaft rotates, enabling the first lifting sleeve plate to ascend and then driving the sealing block to ascend synchronously through the first spring and the mounting plate, and enabling the sealing block to seal the bottom opening of the guide hopper when the first lifting sleeve plate moves to the top end of the reciprocating thread on the outer side of the second rotating shaft;

s3, enabling the driving motor to drive the first rotating shaft to rotate clockwise, enabling the second rotating shaft not to rotate due to the limitation of the overrunning clutch, driving the second lifting sleeve plate to ascend when the first rotating shaft rotates, driving the lifting shaft to ascend through the inner annular sleeve plate and the outer annular sleeve plate when the second lifting sleeve plate ascends, pushing the rotating ring when the lifting shaft ascends, further enabling the screen plate to ascend along the first rotating shaft, enabling the screen plate to ascend to the highest position when the second lifting sleeve plate moves to the top end of the reciprocating thread on the outer side of the first rotating shaft, enabling the second lifting sleeve plate to descend under the driving of the first rotating shaft, and enabling the second spring to drag the screen plate through the upper plate, so that the screen plate descends synchronously;

s4, in the process that the second lifting sleeve plate and the second spring repeatedly drive the sieve plate to lift reciprocally, the first rotating shaft continuously drives the scraping plate to rotate, so that the materials are sieved by the sieve plate, and the sieved materials fall into the top of the bottom plate;

s5, driving the bottom plate to rotate when the first rotating shaft rotates, driving the plurality of stirring shafts to rotate by taking the first rotating shaft as an axis, and at the moment, driving the plurality of stirring columns to rotate when the stirring shafts rotate due to the action of the driving gear and the gear ring, so as to stir and mix the screened materials, wherein in the rotation process of the stirring columns, the outer annular sleeve plate drives the lifting shaft to repeatedly lift, and the lifting shaft drives the plurality of stirring columns to repeatedly lift through the connecting plate;

s6, after stirring is completed, obtaining an additive finished product for the fertilizer and the water of the shrimp culture pond, wherein the additive finished product is output through a pipeline on the right side of the stirring cylinder, sundries at the screening position are output through a pipeline on the left side of the stirring cylinder, and finally the driving motor drives the first rotating shaft to rotate anticlockwise, and then the second rotating shaft drives the sealing mechanism to reset.

The invention has the technical effects and advantages that:

according to the invention, the first driving mechanism, the sealing mechanism, the screening mechanism, the stirring mechanism and the second driving mechanism are arranged, so that the sealing mechanism and the screening mechanism are driven by the first driving mechanism, the sealing mechanism is used for plugging the guide hopper, the screening mechanism screens materials, in the screening process, the second driving mechanism drives the stirring mechanism to drive the screening mechanism to reciprocate, the screening efficiency is improved, the first driving mechanism can drive the stirring mechanism to realize mixing of the materials after screening is finished, and the second driving mechanism can drive the stirring mechanism, so that the stirring mechanism can stir the materials in all directions, and further, the stirring efficiency is improved.

Drawings

Fig. 1 is a schematic view of the overall front cross-sectional structure of the present invention.

FIG. 2 is a schematic diagram of a front cross-sectional structure of a guide hopper and a closure mechanism of the present invention.

Fig. 3 is a schematic diagram of a cross-sectional front view of a screening mechanism of the present invention.

Fig. 4 is a schematic diagram of a front cross-sectional structure of a second driving mechanism of the present invention.

Fig. 5 is a schematic diagram of a front cross-sectional structure of the stirring mechanism of the present invention.

In the figure: 1. a stirring cylinder; 2. a first driving mechanism; 21. a driving motor; 22. a first rotation shaft; 23. a second rotation shaft; 3. a guide hopper; 4. a closing mechanism; 41. a first lifting sleeve plate; 42. a first spring; 43. a mounting plate; 44. a sealing block; 45. a first guide bar; 5. a screening mechanism; 51. a sieve plate; 52. a scraper; 53. a rotating ring; 54. an upper plate; 55. a second spring; 56. a lower plate; 6. a stirring mechanism; 61. a bottom plate; 62. a stirring shaft; 63. a lifting shaft; 64. a connecting plate; 65. stirring the column; 7. a second driving mechanism; 71. a second lifting sleeve plate; 72. a second guide bar; 73. an inner annular sleeve plate; 74. an outer annular sleeve plate; 75. a drive gear; 76. a gear ring.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

The invention provides a production process of an additive for shrimp culture pond water, which is shown in figures 1-5, wherein the additive for shrimp culture pond water consists of 30-45 parts of alkali plant waste white mud, 40-55 parts of fermented chicken manure, 10-15 parts of fulvic acid fertilizer production waste and 1-5 parts of inorganic nitrogen-phosphorus fertilizer;

the production process of the additive for the shrimp culture pond water is realized by production equipment of the additive for the shrimp culture pond water, the production equipment of the additive for the shrimp culture pond water comprises a stirring cylinder 1, a first driving mechanism 2 is arranged at the bottom of the stirring cylinder 1 and inside the stirring cylinder 1, a guide hopper 3 is fixedly arranged at the top of the inner side of the stirring cylinder 1, and a sealing mechanism 4, a screening mechanism 5, a stirring mechanism 6 and a second driving mechanism 7 are sequentially arranged on the outer side of the first driving mechanism 2 in a transmission manner from top to bottom;

the second rotating shaft 23 in the first driving mechanism 2 drives the first lifting sleeve plate 41 in the closing mechanism 4 to lift, the first rotating shaft 22 in the first driving mechanism 2 drives the scraping plate 52 in the screening mechanism 5 to rotate, the first rotating shaft 22 in the first driving mechanism 2 drives the bottom plate 61 in the stirring mechanism 6 to rotate, the first rotating shaft 22 in the first driving mechanism 2 drives the second lifting sleeve plate 71 in the second driving mechanism 7 to lift, the driving gear 75 in the second driving mechanism 7 drives the lifting shaft 63 in the stirring mechanism 6 to rotate, and the outer annular sleeve plate 74 in the second driving mechanism 7 drives the lifting shaft 63 in the stirring mechanism 6 to lift.

As shown in fig. 2 and 4, the first driving mechanism 2 includes a driving motor 21, a first rotating shaft 22 and a second rotating shaft 23, wherein the driving motor 21 is fixedly disposed at the bottom of the mixing drum 1, the first rotating shaft 22 is located inside the mixing drum 1 and is in transmission connection with the driving motor 21, and the second rotating shaft 23 is connected to the top end of the first rotating shaft 22 through an overrunning clutch.

By providing the above structure, the driving motor 21 drives the first rotation shaft 22 to rotate, if the first rotation shaft 22 rotates anticlockwise, the second rotation shaft 23 rotates synchronously, and if the first rotation shaft 22 rotates clockwise, the second rotation shaft 23 does not rotate under the limitation of the overrunning clutch.

As shown in fig. 2, the closing mechanism 4 includes a first lifting sleeve plate 41, a first spring 42, a mounting plate 43, a sealing block 44 and a first guide rod 45, where the first lifting sleeve plate 41 is sleeved on the outer side of the second rotating shaft 23 and is in transmission connection with the second rotating shaft 23 through a reciprocating thread on the outer side of the second rotating shaft 23, the first spring 42, the mounting plate 43 and the sealing block 44 are all in sliding sleeved connection on the outer side of the second rotating shaft 23, one end of the first spring 42 is fixedly connected with the first lifting sleeve plate 41 and the other end of the first spring is fixedly connected with the mounting plate 43, the sealing block 44 is adhered to the top of the mounting plate 43, the sealing block 44 is located under the outlet of the bottom of the guide hopper 3, the first guide rods 45 are provided with two first guide rods 45, and the two first guide rods 45 are fixedly arranged on two sides of the first lifting sleeve plate 41 and all penetrate through the guide hopper 3 and are in sliding connection with the guide hopper 3.

Through setting up above-mentioned structure to when second rotation axis 23 drove first lift sleeve plate 41 and rise, first lift sleeve plate 41 drives sealing block 44 through first spring 42 and mounting panel 43 and rises, and then seals the opening of guide hopper 3 bottom.

As shown in fig. 3, the screening mechanism 5 includes a screen plate 51, a scraper blade 52, a rotating ring 53, an upper plate 54, a second spring 55 and a lower plate 56, where the screen plate 51 is slidably sleeved on the outer side of the first rotating shaft 22 and is fixedly connected with the inner wall of the stirring cylinder 1, the scraper blade 52 is slidably penetrating through and arranged on the first rotating shaft 22, the bottom of the scraper blade 52 is attached to the top of the screen plate 51, the rotating ring 53 is rotatably nested and arranged at the bottom of the screen plate 51 through a bearing, the upper plate 54, the second spring 55 and the lower plate 56 are both provided with two, the two upper plates 54 are respectively fixedly arranged at two sides of the bottom of the screen plate 51, the two second springs 55 are respectively connected to the bottoms of the two upper plates 54, and the two lower plates 56 are respectively fixedly connected to the bottoms of the two second springs 55 and are both fixedly connected with the inner wall of the stirring cylinder 1.

Through setting up above-mentioned structure to first rotation axis 22 drives scraper blade 52 and scrapes screen plate 51 top, and then avoids appearing the condition that the material piled up the jam, and after the swivel becket 53 drove screen plate 51 to rise simultaneously, second spring 55 can drive screen plate 51 and descend, and then makes screen plate 51 be in the state of reciprocal lift, further promotes the screening effect.

As shown in fig. 4 and 5, the stirring mechanism 6 includes a bottom plate 61 and a plurality of stirring assemblies, the stirring assemblies include a stirring shaft 62, a lifting shaft 63, a connecting plate 64 and a stirring column 65, wherein the bottom plate 61 is fixedly sleeved on the outer side of the first rotating shaft 22 and is rotationally connected with the stirring drum 1 through a bearing, the stirring shaft 62 is penetratingly arranged on the bottom plate 61 and is rotationally connected with the bottom plate 61 through the bearing, the lifting shaft 63 is slidably arranged on the inner side of the stirring shaft 62, the connecting plate 64 and the stirring column 65 are provided with a plurality of stirring assemblies, the connecting plate 64 is uniformly fixedly penetrated on the lifting shaft 63 from top to bottom, and the stirring columns 65 are slidably nested on two sides of the stirring shaft 62 and are fixedly connected with two ends of the connecting plate 64.

Through setting up above-mentioned structure to when first rotation axis 22 drove bottom plate 61 rotatory, bottom plate 61 drove a plurality of (mixing) shafts 62 and use first rotation axis 22 to rotate as the axle center, and then stir the material, when lift axle 63 goes up and down simultaneously, can drive stirring post 65 through connecting plate 64 and go up and down, and then increase the stirring area.

As shown in fig. 4, the second driving mechanism 7 includes a second lifting sleeve plate 71, a second guiding rod 72, an inner annular sleeve plate 73, an outer annular sleeve plate 74, a driving gear 75 and a gear ring 76, wherein the second lifting sleeve plate 71 is sleeved outside the first rotating shaft 22 and is in transmission connection with the first rotating shaft 22 through a reciprocating thread outside the first rotating shaft 22, the second guiding rods 72 are provided with two guiding rods, the two guiding rods 72 respectively slide through two sides arranged at the top of the second lifting sleeve plate 71 and are fixedly connected with the inner wall of the stirring drum 1, the inner annular sleeve plate 73 is fixedly sleeved outside the second lifting sleeve plate 71, the outer annular sleeve plate 74 is rotatably sleeved outside the inner annular sleeve plate 73 through a bearing, the bottom end of the outer annular sleeve plate 74 is rotatably connected with the lifting shaft 63 through the bearing, the driving gear 75 is fixedly sleeved outside the bottom of the stirring shaft 62, the gear ring 76 is arranged outside the outer annular sleeve plate 74 and is fixedly connected with the stirring drum 1, and the driving gear 75 is meshed with the gear ring 76.

By the above structure, the first rotation shaft 22 drives the second lifting sleeve plate 71 to reciprocate, the second lifting sleeve plate 71 drives the outer annular sleeve plate 74 to reciprocate through the inner annular sleeve plate 73, the outer annular sleeve plate 74 drives the lifting shaft 63 to reciprocate, and the driving gear 75 and the gear ring 76 function to rotate the stirring shaft 62 when the stirring shaft 62 rotates around the first rotation shaft 22.

Example 2

The production process of the additive for the shrimp culture pond water fertilizer specifically comprises the following steps:

s1, adding fermented chicken manure, waste white mud of an alkali plant, waste produced by a fulvic acid fertilizer and inorganic nitrogen-phosphorus fertilizer into a guide hopper 3 in sequence, guiding the materials by the inner wall of the guide hopper 3, enabling the materials to enter the stirring barrel 1 through an opening at the bottom of the guide hopper, and then falling to the top of a sieve plate 51;

s2, enabling the driving motor 21 to drive the first rotating shaft 22 to rotate anticlockwise, enabling the second rotating shaft 23 to rotate synchronously, enabling the first lifting sleeve plate 41 to ascend when the second rotating shaft 23 rotates, enabling the first lifting sleeve plate 41 to ascend and enabling the sealing block 44 to ascend synchronously through the first spring 42 and the mounting plate 43 after the first lifting sleeve plate 41 ascends, and enabling the sealing block 44 to seal the bottom opening of the guide hopper 3 when the first lifting sleeve plate 41 moves to the top end of the reciprocating thread outside the second rotating shaft 23;

s3, enabling the driving motor 21 to drive the first rotating shaft 22 to rotate clockwise, at the moment, because of the limitation of the overrunning clutch, the second rotating shaft 23 does not rotate, the second lifting sleeve plate 71 is driven to ascend when the first rotating shaft 22 rotates, the lifting shaft 63 is driven to ascend through the inner annular sleeve plate 73 and the outer annular sleeve plate 74 when the second lifting sleeve plate 71 ascends, the rotating ring 53 is pushed when the lifting shaft 63 ascends, the screen plate 51 is further ascended along the first rotating shaft 22, when the second lifting sleeve plate 71 moves to the top end of the reciprocating thread outside the first rotating shaft 22, the screen plate 51 ascends to the highest position, then the second lifting sleeve plate 71 starts to descend under the driving of the first rotating shaft 22, and the second spring 55 pulls the screen plate 51 through the upper plate 54, so that the screen plate 51 descends synchronously;

s4, in the process that the second lifting sleeve plate 71 and the second spring 55 repeatedly drive the sieve plate 51 to lift reciprocally, the first rotating shaft 22 continuously drives the scraping plate 52 to rotate, so that the materials are sieved by the sieve plate 51, and the sieved materials fall into the top of the bottom plate 61;

s5, when the first rotating shaft 22 rotates, the bottom plate 61 is driven to rotate, the bottom plate 61 drives the stirring shafts 62 to rotate by taking the first rotating shaft 22 as an axle center, at the moment, due to the action of the driving gear 75 and the gear ring 76, the stirring shafts 62 rotate, and then the stirring shafts 62 rotate to drive the stirring columns 65 to rotate, and then the sieved materials are stirred and mixed, and in the rotating process of the stirring columns 65, the outer annular sleeve plate 74 drives the lifting shafts 63 to repeatedly lift, and then the lifting shafts 63 drive the stirring columns 65 to repeatedly lift through the connecting plates 64;

s6, after stirring is completed, obtaining an additive finished product for the fertilizer and the water of the shrimp culture pond, wherein the additive finished product is output through a pipeline on the right side of the stirring cylinder 1, sundries at the screening position are output through a pipeline on the left side of the stirring cylinder 1, and finally the driving motor 21 drives the first rotating shaft 22 to rotate anticlockwise, and the second rotating shaft 23 drives the sealing mechanism 4 to reset.

Finally, it should be noted that: the foregoing description is only illustrative of the preferred embodiments of the present invention, and although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements or changes may be made without departing from the spirit and principles of the present invention.

Claims (1)

1. A production facility for shrimp culture pond fat water's additive, its characterized in that: the novel stirring device comprises a stirring barrel (1), wherein a first driving mechanism (2) is arranged at the bottom of the stirring barrel (1) and inside the stirring barrel (1), a guide hopper (3) is fixedly arranged at the top of the inner side of the stirring barrel (1), and a sealing mechanism (4), a screening mechanism (5), a stirring mechanism (6) and a second driving mechanism (7) are sequentially arranged on the outer side of the first driving mechanism (2) in a transmission manner from top to bottom;

the first rotary shaft (23) in the first driving mechanism (2) drives the first lifting sleeve plate (41) in the sealing mechanism (4) to lift, the first rotary shaft (22) in the first driving mechanism (2) drives the scraping plate (52) in the screening mechanism (5) to rotate, the first rotary shaft (22) in the first driving mechanism (2) drives the bottom plate (61) in the stirring mechanism (6) to rotate, the first rotary shaft (22) in the first driving mechanism (2) drives the second lifting sleeve plate (71) in the second driving mechanism (7) to lift, the driving gear (75) in the second driving mechanism (7) drives the lifting shaft (63) in the stirring mechanism (6) to rotate, and the outer annular sleeve plate (74) in the second driving mechanism (7) drives the lifting shaft (63) in the stirring mechanism (6) to lift;

the first driving mechanism (2) comprises a driving motor (21), a first rotating shaft (22) and a second rotating shaft (23);

the driving motor (21) is fixedly arranged at the bottom of the stirring cylinder (1), the first rotating shaft (22) is positioned in the stirring cylinder (1) and is in transmission connection with the driving motor (21), and the second rotating shaft (23) is connected to the top end of the first rotating shaft (22) through an overrunning clutch;

the sealing mechanism (4) comprises a first lifting sleeve plate (41), a first spring (42), a mounting plate (43), a sealing block (44) and a first guide rod (45);

the first lifting sleeve plate (41) is sleeved on the outer side of the second rotating shaft (23) and is in transmission connection with the second rotating shaft (23) through reciprocating threads on the outer side of the second rotating shaft (23), the first spring (42), the mounting plate (43) and the sealing block (44) are all in sliding sleeve connection on the outer side of the second rotating shaft (23), one end of the first spring (42) is fixedly connected with the first lifting sleeve plate (41) and the other end of the first spring is fixedly connected with the mounting plate (43), the sealing block (44) is adhered to the top of the mounting plate (43), the sealing block (44) is located under an outlet on the bottom of the guide hopper (3), two first guide rods (45) are arranged on two sides of the first lifting sleeve plate (41) respectively and penetrate through the guide hopper (3) and are in sliding connection with the guide hopper (3);

the screening mechanism (5) comprises a screen plate (51), a scraping plate (52), a rotating ring (53), an upper plate (54), a second spring (55) and a lower plate (56);

the sieve plate (51) is sleeved on the outer side of the first rotating shaft (22) in a sliding manner and is fixedly connected with the inner wall of the stirring cylinder (1), the scraping plate (52) is arranged on the first rotating shaft (22) in a sliding manner in a penetrating manner, the bottom of the scraping plate (52) is attached to the top of the sieve plate (51), the rotating ring (53) is arranged at the bottom of the sieve plate (51) in a rotating nested manner through a bearing, the upper plate (54), the second springs (55) and the lower plate (56) are both provided with two, the two upper plates (54) are respectively fixedly arranged on two sides of the bottom of the sieve plate (51), the two second springs (55) are respectively connected to the bottoms of the two upper plates (54), and the two lower plates (56) are respectively fixedly connected to the bottom ends of the two second springs (55) and are both fixedly connected with the inner wall of the stirring cylinder (1);

the stirring mechanism (6) comprises a bottom plate (61) and a plurality of stirring assemblies, wherein each stirring assembly comprises a stirring shaft (62), a lifting shaft (63), a connecting plate (64) and a stirring column (65);

the stirring device comprises a bottom plate (61), a stirring cylinder (1), a stirring shaft (62), a plurality of connecting plates (64) and stirring columns (65), wherein the bottom plate (61) is fixedly sleeved on the outer side of a first rotating shaft (22) and is rotationally connected with the stirring cylinder (1) through a bearing, the stirring shaft (62) is arranged on the bottom plate (61) in a penetrating manner and is rotationally connected with the bottom plate (61) through the bearing, the lifting shaft (63) is arranged on the inner side of the stirring shaft (62) in a sliding manner, the plurality of connecting plates (64) and the stirring columns (65) are uniformly and fixedly arranged on the lifting shaft (63) from top to bottom in a penetrating manner, and the plurality of stirring columns (65) are respectively arranged on two sides of the stirring shaft (62) in a sliding nesting manner and are respectively fixedly connected with two ends of the plurality of connecting plates (64);

the second driving mechanism (7) comprises a second lifting sleeve plate (71), a second guide rod (72), an inner annular sleeve plate (73), an outer annular sleeve plate (74), a driving gear (75) and a gear ring (76);

the second lifting sleeve plate (71) is sleeved on the outer side of the first rotating shaft (22) and is in transmission connection with the first rotating shaft (22) through reciprocating threads on the outer side of the first rotating shaft (22), two second guide rods (72) are arranged, the two second guide rods (72) are respectively and slidably penetrated through the two sides of the top of the second lifting sleeve plate (71) and are fixedly connected with the inner wall of the stirring cylinder (1), the inner annular sleeve plate (73) is fixedly sleeved on the outer side of the second lifting sleeve plate (71), the outer annular sleeve plate (74) is rotatably sleeved on the outer side of the inner annular sleeve plate (73) through a bearing, the outer annular sleeve plate (74) is rotatably connected with the bottom end of the lifting shaft (63) through a bearing, the driving gear (75) is fixedly sleeved on the outer bottom of the stirring shaft (62), the gear ring (76) is sleeved on the outer side of the outer annular sleeve plate (74) and is fixedly connected with the stirring cylinder (1), and the driving gear (75) is meshed with the gear ring (76);

the production process of the additive for the shrimp culture pond water fertilizer specifically comprises the following steps:

s1, adding fermented chicken manure, waste white mud of an alkali plant, waste produced by a fulvic acid fertilizer and inorganic nitrogen-phosphorus fertilizer into a guide hopper (3) in sequence, guiding the materials by the inner wall of the guide hopper (3), enabling the materials to enter the stirring barrel (1) through an opening at the bottom of the guide hopper, and then falling to the top of a sieve plate (51);

s2, enabling the driving motor (21) to drive the first rotating shaft (22) to rotate anticlockwise, enabling the second rotating shaft (23) to rotate synchronously, enabling the first lifting sleeve plate (41) to ascend when the second rotating shaft (23) rotates, enabling the first lifting sleeve plate (41) to ascend and then driving the sealing block (44) to ascend synchronously through the first spring (42) and the mounting plate (43), and enabling the sealing block (44) to seal the bottom opening of the guide hopper (3) when the first lifting sleeve plate (41) moves to the top end of the reciprocating thread outside the second rotating shaft (23);

s3, enabling the driving motor (21) to drive the first rotating shaft (22) to rotate clockwise, enabling the second rotating shaft (23) not to rotate due to the limitation of the overrunning clutch, driving the second lifting sleeve plate (71) to ascend when the first rotating shaft (22) rotates, driving the lifting shaft (63) to ascend through the inner annular sleeve plate (73) and the outer annular sleeve plate (74) when the second lifting sleeve plate (71) ascends, pushing the rotating ring (53) when the lifting shaft (63) ascends, further enabling the screen plate (51) to ascend along the first rotating shaft (22), enabling the screen plate (51) to ascend to the highest position when the second lifting sleeve plate (71) moves to the top end of the reciprocating thread outside the first rotating shaft (22), then enabling the second lifting sleeve plate (71) to descend when the first rotating shaft (22) drives, and enabling the second spring (55) to drag the screen plate (51) through the upper plate (54) to descend synchronously;

s4, in the process that the second lifting sleeve plate (71) and the second spring (55) repeatedly drive the sieve plate (51) to lift in a reciprocating manner, the first rotating shaft (22) continuously drives the scraping plate (52) to rotate, so that materials are screened by the sieve plate (51), and the screened materials fall into the top of the bottom plate (61);

s5, driving the bottom plate (61) to rotate when the first rotating shaft (22) rotates, driving the plurality of stirring shafts (62) to rotate by taking the first rotating shaft (22) as the axis, and at the moment, driving the stirring shafts (62) to rotate under the action of the driving gear (75) and the gear ring (76), driving the plurality of stirring columns (65) to rotate when the stirring shafts (62) rotate, stirring and mixing screened materials, and driving the lifting shafts (63) to repeatedly lift by the outer annular sleeve plate (74) in the rotating process of the stirring columns (65), and further driving the lifting shafts (63) to repeatedly lift by the plurality of stirring columns (65) through the connecting plate (64);

s6, after stirring is completed, obtaining an additive finished product for the fertilizer and the water of the shrimp culture pond, wherein the additive finished product is output through a pipeline on the right side of the stirring cylinder (1), sundries at the screening position are output through a pipeline on the left side of the stirring cylinder (1), and finally the driving motor (21) drives the first rotating shaft (22) to rotate anticlockwise, and the second rotating shaft (23) drives the sealing mechanism (4) to reset.