CN115141042A

CN115141042A - Organic fertilizer production process

Info

Publication number: CN115141042A
Application number: CN202210735056.6A
Authority: CN
Inventors: 王会宝
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-06-27
Filing date: 2022-06-27
Publication date: 2022-10-04

Abstract

The invention relates to the field of organic fertilizer preparation, in particular to an organic fertilizer production process, which comprises the following steps: pouring the air-dried and dried enteromorpha into a processing device for specification crushing; the enteromorpha is longitudinally and reciprocally automatically sheared in the device by the driving of variable-frequency reciprocating motion, so that the enteromorpha is sheared according to specifications; the enteromorpha sections with cut specifications fall into a prepared material adding seat through valve control; adding the mixed waste into a waste material preparation adding frame, and automatically and quantitatively adding by driving addition; through directional variable frequency driving, the enteromorpha section quantitatively falls into the waste, and the waste containing the enteromorpha section quantitatively falls into the ball forming seat; the molding processing of the waste material containing the enteromorpha section in a fixed amount is completed through the reciprocating processing in the forming ball seat; the invention has the beneficial effects that the enteromorpha prolifera causing ocean pollution is recycled and then quantitatively added into waste to form the organic fertilizer for recycling.

Description

Organic fertilizer production process

Technical Field

The invention relates to the field of organic fertilizer preparation, in particular to an organic fertilizer production process.

Background

The organic fertilizer has high content of nutrient components, and when the organic fertilizer is used for land, high-quality agricultural products can be grown by continuously supplementing the nutrition to the land; the patent number 201110376467.2 discloses a seaweed organic fertilizer, which comprises the following preparation processes: desanding the seaweed, and drying in the sun or at 50-70 ℃ to obtain dried seaweed; pulverizing dried Sargassum to obtain Sargassum powder, mixing with water, and breaking cell wall with ultrasonic wave to obtain extractive solution; filtering the leaching solution, centrifuging, decolorizing, concentrating, and drying to obtain seaweed organic fertilizer; furthermore, in order to strengthen nutrition, nutrient components such as urea, monopotassium phosphate, trace elements and the like can be added according to requirements to obtain the required seaweed organic fertilizer. Compared with the conventional extraction method, the ultrasonic extraction method has the advantages of short extraction time, high yield, avoidance of degradation under long-time high-temperature conditions and avoidance of damage of high temperature and high pressure to effective components. However, the organic fertilizer processed by the method cannot fully guarantee fermentation of recovered waste nutrients, and cannot realize efficient recovery of nutritive value.

Disclosure of Invention

The invention aims to provide an organic fertilizer production process which has the beneficial effect that enteromorpha which causes ocean pollution is recycled and then quantitatively added into waste to form an organic fertilizer for recycling.

The purpose of the invention is realized by the following technical scheme:

a production process of an organic fertilizer comprises the following steps:

step one, pouring the air-dried and dried enteromorpha into a processing device for specification crushing; the enteromorpha is longitudinally and reciprocally automatically sheared in the device by the driving of variable-frequency reciprocating motion, so that the enteromorpha is sheared according to specifications;

step two, the enteromorpha sections with the cut specifications fall into a stock preparation adding seat through valve control;

adding the mixed waste into a waste material preparation adding frame, and automatically and quantitatively adding the mixed waste through driving addition;

step four, quantitatively dropping the enteromorpha sections into the waste materials through directional variable frequency driving, and quantitatively dropping the waste materials containing the enteromorpha sections into the ball forming seat;

and step five, finishing the forming processing of the waste material containing the enteromorpha section quantitatively through the reciprocating processing in the forming ball seat.

The device comprises a waveform slope block reciprocating propulsion plate, a connecting thread plate and a variable-frequency reciprocating driver, wherein the side end of the waveform slope block reciprocating propulsion plate is fixed on the connecting thread plate, and the connecting thread plate is connected with a transmission thread cylinder of the variable-frequency reciprocating driver through thread matching to drive the waveform slope block reciprocating propulsion plate to reciprocate.

The wave-shaped slope block reciprocating propulsion plate is provided with a wave-shaped inclined slope block shape.

A falling sliding insertion valve for controlling the falling of the enteromorpha prolifera section is inserted in the waveform slope block reciprocating push plate; the wave-shaped slope block reciprocating pushing plate transversely slides in the processing rack, and a side spring locking table for sealing and preventing leakage is fixed at the side end of the processing rack; the middle end of the inner wall of the processing rack is fixed with a central slope block for preventing accumulation.

The enteromorpha polluted by green tide on the coastline is salvaged and recovered, is conveyed to a designated position to be dried in the sun and air, and is dried, the processed enteromorpha is added into the device, is cut into the section-shaped enteromorpha section with the size of the designated specification in the device through the frequency conversion reciprocating drive, falls down and is recovered; and quantitatively distributing the enteromorpha prolifera sections into corresponding quantitative waste fertilizers through stable propulsion, carrying out quantitative combined addition, continuously kneading by a spherical former to form a sphere, recovering, carrying out fermentation unified treatment, forming an organic fertilizer, effectively utilizing waste microorganisms of the enteromorpha prolifera causing sea surface pollution, and effectively relieving excessive pollution on the sea surface.

Drawings

FIG. 1 is a schematic flow diagram of the preparation of the organic fertilizer of the present invention;

FIG. 2 is a waveform ramp block reciprocation of the present invention the structure of the propulsion plate drive is shown schematically;

FIG. 3 is a schematic view of the internal structure of the processing rack of the present invention;

FIG. 4 is a schematic structural view of a side spring locking station of the present invention;

FIG. 5 is a schematic view of a driving structure of the pulley wave type moving stage of the present invention;

FIG. 6 is a schematic view of the spring shaft connection of the present invention;

FIG. 7 is a first general structural diagram of the present invention;

FIG. 8 is a second overall structural schematic of the present invention;

FIG. 9 is a schematic view of the structure of the recovery and collection of Enteromorpha segments of the present invention;

FIG. 10 is a schematic view of the structure of the metered dose of the present invention;

FIG. 11 is a schematic view of the structure of the fertilizer pushing frame of the present invention;

fig. 12 is a schematic view of the structure of the former of the present invention.

In the figure: the wave-shaped slope block is pushed into the plate 1 in a reciprocating way; connecting the thread plate 2; a variable frequency reciprocating drive 3; a drop slide insert valve 4; a processing frame 5; a central slope block 6; a side spring locking table 7; a pulley wave-shaped moving table 8; the upper sliding cutting block 9; a lower fixing base 10; a longitudinal sliding seat 11; a spring shaft 12; a downward sloping recovery slope block 13; the enteromorpha section is a loading seat 14; an enteromorpha prolifera section propulsion seat 15; a waste fertilizer presenting seat 16; a fertilizer push frame 17; a spring bottom frame 18; a variable frequency propulsion drive 19; a lower semi-arc forming base 20; a lower semi-arc sliding forming seat 21; a forming drive 22.

Detailed Description

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

As shown in the embodiments illustrated herein,

the enteromorpha polluted by green tide on the coastline is salvaged and recovered, the enteromorpha is conveyed to a designated position to be dried in the sun, air and dried, the processed enteromorpha is added into the device, the enteromorpha is cut into section-shaped enteromorpha sections with the size of a designated specification in the device through the frequency conversion reciprocating driving, and the sections fall down for recovery; and quantitatively distributing the enteromorpha prolifera segments into corresponding quantitative waste fertilizers through stable propulsion, carrying out quantitative combined addition, continuously kneading by a spherical former to form a spherical shape, recovering, fermenting and uniformly treating to form an organic fertilizer, effectively recycling waste microorganisms of the enteromorpha prolifera causing sea surface pollution, and effectively relieving excessive pollution on the sea surface.

Further optimization in conjunction with the above examples:

further, the working process of the organic fertilizer production process example shown in fig. 2, 3, 4 and 5 is as follows:

through the drive of the frequency conversion control of the frequency conversion reciprocating driver 3, a thread cylinder is connected with the thread of the bolt in a matching way, so that the bolt rotating on the connecting thread plate 2 is driven inwards or outwards, and further, the reciprocating pushing plate 1 of the wave-shaped slope block is controlled in the machining rack 5 in a transverse sliding way, so that the inwards or outwards driving is realized, and further, the reciprocating pushing plate 1 of the wave-shaped slope block is driven in the machining rack 5 in a transverse reciprocating way.

Further optimization in conjunction with the above examples:

further, the wave-shaped slope block reciprocating propulsion plate 1 is provided with a wave-shaped inclined slope block shape.

The working process of the part of the organic fertilizer production process shown in the figures 2, 3, 4 and 5 is as follows:

the upper surface of the waveform slope block reciprocating propulsion plate 1 driven by the frequency conversion reciprocating driver 3 to transversely reciprocate is in a waveform slope block shape, the upper slope is switched to appear, and further the pulley waveform moving platform 8 sliding on the waveform slope block reciprocating propulsion plate 1 is conveniently driven to transversely reciprocate and displace, so that the reciprocating automatic processing of shearing is conveniently carried out.

Further optimization in conjunction with the above examples:

a falling sliding insertion valve 4 for controlling the falling of the enteromorpha prolifera section is inserted into the waveform slope block reciprocating propulsion plate 1; the wave-shaped slope block reciprocating push plate 1 transversely slides in the processing rack 5, and a side spring locking table 7 for sealing and preventing leakage is fixed at the side end of the processing rack 5; the middle end of the inner wall of the processing frame 5 is fixed with a central slope block 6 for preventing accumulation.

the falling sliding insertion valve 4 of the waveform slope block reciprocating pushing plate 1 rotates to fall a bolt on the sliding insertion valve 4, and further through the drawing of the sliding threaded seat, a valve in the falling sliding insertion valve 4 is made to slide in fit with the waveform slope block reciprocating pushing plate 1, so that the opening is controlled to be closed, and meanwhile, through the sliding drawing of the sliding threaded seat, the interference of sliding and moving is not influenced; a plurality of side spring locking platforms 7 are fixed at the side end of the processing rack 5, and a spring top plate in each side spring locking platform 7 is attached to the waveform slope block reciprocating pushing plate 1, so that the reciprocating motion of the waveform slope block reciprocating pushing plate 1 is not influenced while the leakage is effectively prevented by blocking, and the effective blocking is realized by attaching; the middle-end central slope block 6 on the inner wall of the processing rack 5 plays a role in supporting and fixing, and meanwhile, due to the slope design of the upper surface of the processing rack, the enteromorpha is prevented from being piled.

Further optimization in conjunction with the above examples:

further, a pulley wave-shaped moving table 8 is arranged on the upper surface of the wave-shaped slope block reciprocating pushing plate 1 in a sliding mode through pulleys, an upper sliding cutting block 9 used for longitudinally sliding and shearing enteromorpha is fixed on the pulley wave-shaped moving table 8, and a lower fixed seat 10 is fixed on the side end of a central slope block 6 used for preventing accumulation on the inner wall of the processing rack 5; the lower end of the upper sliding cutting block 9 is inserted into the lower fixing seat 10 for cutting the enteromorpha.

The working process of the part according to the organic fertilizer production process example shown in fig. 5, 6, 7 and 8 is as follows:

the enteromorpha is cut in the inserting process through the clearance fit of the plurality of inserting blocks on the upper sliding cutting block 9 and the inserting groove in the lower fixing seat 10, so that the enteromorpha reaching the corresponding specification falls downwards through the inserting groove in the lower fixing seat 10, and the processing is convenient; the pulley wave-shaped moving table 8 and the upper sliding cutting block 9 are continuously driven to longitudinally reciprocate by the wave-shaped slope block reciprocating pushing plate 1, so that the upper sliding cutting block 9 is continuously and repeatedly inserted into an insertion groove in the lower fixed seat 10, the enteromorpha fallen on the lower fixed seat 10 is cut, and the automatic and repeated processing of the enteromorpha with the specified specification is further completed.

Further optimization in conjunction with the above examples:

further, the upper end of the pulley wave-shaped moving table 8 is fixed on a longitudinal sliding seat 11, the longitudinal sliding seat 11 longitudinally limits and slides in the processing rack 5, a spring shaft 12 for resetting and jacking is fixed at the upper end of the longitudinal sliding seat 11, the spring shaft 12 slides in the processing rack 5, and a spring on the spring shaft 12 is arranged between the longitudinal sliding seat 11 and the processing rack 5.

the pulley at the lower end of the pulley waveform moving platform 8 slides on the waveform slope block reciprocating pushing plate 1, the shape of the waveform slope block reciprocating pushing plate 1 is combined to constantly drive the pulley waveform moving platform 8 to longitudinally displace, and the pulley waveform moving platform 8 is constantly reset after extruding a spring on the spring shaft 12 through the spring arrangement on the spring shaft 12 and the vertical limit sliding of the vertical sliding seat 11, so that the vertical reciprocating displacement is completed, and the automatic shearing driving of the upper sliding cutting block 9 inserted into the lower fixed seat 10 is realized.

Further optimization in conjunction with the above examples:

further, a downward-inclined recycling slope block 13 for recycling the enteromorpha section, an enteromorpha section carrying seat 14 for receiving the enteromorpha section and a waste fertilizer carrying seat 16 for carrying residual fertilizer are fixed at the lower end of the processing rack 5 from top to bottom.

The working process of the part according to the organic fertilizer production process example shown in fig. 9, 10, 11 and 12 is as follows:

the enteromorpha section which finishes the designated specification through shearing falls on the lower inclined recovery slope block 13 through the control and adjustment of the falling sliding insertion valve 4, falls in the enteromorpha section loading seat 14 in an inclined mode, the quantitative clamping plate is arranged on the enteromorpha section loading seat 14, the enteromorpha section pushing seat 15 is limited in adding height when pushing the enteromorpha section to move inwards, the stable quantitative addition of the enteromorpha section is further realized, and the enteromorpha section falls into the waste fertilizer at the lower end to be the loading seat 16 through the hole at the designated position.

Further optimization in conjunction with the above examples:

further, an enteromorpha section pushing seat 15 and a fertilizer pushing frame 17 are inserted into the enteromorpha section loading seat 14 and the waste fertilizer loading seat 16 in a clearance mode respectively, and the enteromorpha section pushing seat 15 and the fertilizer pushing frame 17 are connected with a variable-frequency pushing driver 19 for driving pushing in a threaded fit mode through a connecting plate.

through adding other waste fertilizers into the fertilizer pushing frame 17 in advance, and through the stable control of the variable-frequency pushing driver 19, the enteromorpha section loading seat 14 and the fertilizer pushing frame 17 are driven to be simultaneously and inwards added through the thread matching of the thread cylinder and the bolt, the enteromorpha section loading seat 14 is the same as the enteromorpha section loading seat 14, the waste fertilizer loading seat 16 is also provided with a quantitative clamping plate for clamping the adding height, further, the added enteromorpha section falls into the waste fertilizers on the quantitative fertilizer pushing frame 17, and through the arrangement of the spring bottom frame 18 at the lower end of the fertilizer pushing frame 17, after the waste fertilizers reach the appointed position, the spring bottom frame 18 is extruded, so that the fertilizers with the enteromorpha section simultaneously and quantitatively fall into the lower semi-arc seat 20 to be pinched, and the processing and adding of the quantitative fertilizers containing the enteromorpha formed enteromorpha section are completed.

Further optimization in conjunction with the above examples:

further the lower extreme of processing frame 5 transversely pegs graft and is used for being the lower semi-arc shaping seat 20 that connects the fertilizer, and the combination slides on the lower semi-arc shaping seat 20 and is used for fashioned lower semi-arc slip shaping seat 21, and lower semi-arc slip shaping seat 21 is spacing to slide in processing frame 5, and lower semi-arc slip shaping seat 21 passes through the eccentric department of hinge bar shaping driver 22 drive carousel.

the semi-arc forming seat 20 is inserted, so that quantitative fertilizers containing enteromorpha sections respectively fall into arc-shaped wire grooves of the semi-arc forming seat 20, the lower semi-arc sliding forming seat 21 is driven by an eccentric position on a rotating disc of a forming driver 22 to complete reciprocating displacement on the semi-arc forming seat 20 and the processing rack 5, the quantitative fertilizers are continuously kneaded in a limited space, the spherical fertilizers containing enteromorpha are processed, the processing is completed, and the lower semi-arc forming seat 20 containing the spherical fertilizers containing the enteromorpha is taken out.

The fixed connection in the device can be fixed by welding, insert block combination and fixation, casting integral forming and fixation, thread fixation and the like, and the adaptive selection is carried out by combining the mounting and dismounting modes; the rotary connection can mean that the bearing is arranged on the shaft by baking, a spring retainer groove or an inter-shaft baffle is arranged on the shaft or the shaft hole, the axial fixation of the bearing is realized by clamping the elastic retainer ring in the spring retainer groove or the inter-shaft baffle, and the rotation is realized by the relative sliding of the bearing; the limit sliding is a sliding mode which limits the sliding track, the sliding direction and the position by the fit and matching sliding of a sliding block with a ball body or a bearing and the like for reducing the resistance and a sliding groove and limits the position by the limit; different connection modes are used for further distinguishing and using in combination with different using environments.

Claims

1. A production process of an organic fertilizer is characterized by comprising the following steps: the process comprises the following steps:

step one, pouring the air-dried and dried enteromorpha into a processing device for specification crushing; the enteromorpha prolifera is driven by variable frequency reciprocating motion to longitudinally reciprocate and automatically cut in the device, so that the enteromorpha prolifera is cut according to the specification;

step two, the enteromorpha sections with the cut specifications fall into a feed preparation adding seat through valve control;

2. The organic fertilizer production process according to claim 1, wherein the organic fertilizer production process comprises a wave-shaped slope block reciprocating propulsion plate (1), a connecting thread plate (2) and a variable-frequency reciprocating driver (3), the side end of the wave-shaped slope block reciprocating propulsion plate (1) is fixed on the connecting thread plate (2), and the connecting thread plate (2) drives the wave-shaped slope block reciprocating propulsion plate (1) to reciprocate through a transmission thread cylinder which is in threaded fit connection with the variable-frequency reciprocating driver (3).

3. The organic fertilizer production process according to claim 2, wherein the wave-shaped sloping block reciprocating propulsion plate (1) is provided with a wave-shaped sloping block shape.

4. The organic fertilizer production process according to claim 2, wherein a falling sliding insertion valve (4) for controlling falling of enteromorpha sections is inserted on the wave-shaped slope reciprocating pushing plate (1); the wave-shaped slope block reciprocating pushing plate (1) transversely slides in the processing rack (5), and a side spring locking table (7) for sealing and preventing leakage is fixed at the side end of the processing rack (5); the middle end of the inner wall of the processing frame (5) is fixed with a central slope block (6) for preventing accumulation.

5. The organic fertilizer production process according to claim 2, wherein the upper surface of the wave-shaped slope block reciprocating pushing plate (1) is provided with a pulley wave-shaped moving table (8) in a sliding manner through a pulley, an upper sliding cutting block (9) for longitudinally sliding and shearing enteromorpha is fixed on the pulley wave-shaped moving table (8), and a lower fixed seat (10) is fixed on the side end of the central slope block (6) for preventing accumulation on the inner wall of the processing rack (5).

6. The organic fertilizer production process according to claim 5, wherein the lower end of the upper sliding cut block (9) is inserted into the lower fixed seat (10) for shearing enteromorpha.

7. The organic fertilizer production process according to claim 5, wherein the upper end of the pulley wave-shaped moving platform (8) is fixed on a longitudinal sliding seat (11), the longitudinal sliding seat (11) longitudinally slides in the processing rack (5) in a limited manner, a spring shaft (12) for resetting and jacking is fixed at the upper end of the longitudinal sliding seat (11), the spring shaft (12) slides in the processing rack (5), and a spring on the spring shaft (12) is arranged between the longitudinal sliding seat (11) and the processing rack (5).

8. The organic fertilizer production process according to claim 4, wherein a downward-inclined recovery sloping block (13) for recovering the enteromorpha segment, an enteromorpha segment carrying seat (14) for receiving the enteromorpha segment and a waste fertilizer carrying seat (16) for carrying residual fertilizer are fixed at the lower end of the processing rack (5) from top to bottom.

9. The organic fertilizer production process according to claim 8, wherein an enteromorpha section propelling seat (15) and a fertilizer propelling frame (17) are inserted into the enteromorpha section loading seat (14) and the waste fertilizer loading seat (16) at intervals respectively, and the enteromorpha section propelling seat (15) and the fertilizer propelling frame (17) are connected with a variable-frequency propelling driver (19) for driving and propelling through a connecting plate in a threaded fit manner.

10. The organic fertilizer production process according to claim 4, wherein the lower end of the processing rack (5) is transversely inserted into a lower semi-arc forming seat (20) for receiving fertilizer, the lower semi-arc forming seat (20) is combined and slides to form a lower semi-arc sliding forming seat (21), the lower semi-arc sliding forming seat (21) slides in the processing rack (5) in a limiting mode, and the lower semi-arc sliding forming seat (21) drives the eccentric position of the rotary table through a hinge rod forming driver (22).