CN113503694B - Production, preparation and processing technology of amino acid organic fertilizer - Google Patents

Abstract

The invention relates to a production, preparation and processing process of an amino acid organic fertilizer, which uses an amino acid organic fertilizer production, preparation and processing device, wherein the amino acid organic fertilizer production, preparation and processing device comprises an installation bottom plate, supporting legs, supporting rods, a dust removal box, a feeding port, a discharging barrel, a dust removal mechanism, a drying mechanism and a blanking mechanism.

Description

Production, preparation and processing technology of amino acid organic fertilizer

Technical Field

The invention relates to the technical field of fertilizer production, in particular to a production, preparation and processing technology of an amino acid organic fertilizer.

Background

Organic fertilizer, mainly derived from plants and/or animals, is a carbonaceous material applied to soil to provide plant nutrition as its main function. Is prepared from biological substances, animal and plant wastes and plant residues, eliminates toxic and harmful substances in the biological substances, and is rich in a large amount of beneficial substances, including: various organic acids, peptides and rich nutrient elements including nitrogen, phosphorus and potassium. The amino acid organic fertilizer is a fertilizer containing amino acid substances, and the amino acid exists in the fertilizer as the minimum molecule of protein, so that the amino acid organic fertilizer has the characteristic of being easily absorbed by crops; also has the functions of improving disease resistance of the fertilization objects and improving the quality of the fertilization crops.

The fertilization time of amino acid fertilizer need carry out continuous adjustment according to the growth cycle of plant, and amino acid fertilizer is in the in-process of production preparation, often can adsorb moisture and dust in the surrounding environment because expose in the air, this can cause rotten and the loss of amino acid fertilizer fertility, consequently, in the in-process of carrying out amino acid fertilizer bagging-off operation, need in advance to pile up the amino acid fertilizer of placing and carry out the dust removal drying process, in order to keep amino acid fertilizer's self quality, however, in the in-process of carrying out amino acid fertilizer dust removal drying operation, often can have following problem:

1. traditional amino acid fertilizer is at the in-process of dry dust removal operation, be difficult to disperse the amino acid fertilizer that has bonded and peel off, also be difficult to carry out even dispersion screening with accumulational amino acid fertilizer, the effect of dropping of impurity particles such as the dust of adhesion on the amino acid fertilizer has been reduced, and be difficult to carry out synchronous collection operation to the dust that drops and the dust of suspension, the operating efficiency of amino acid fertilizer dust removal edulcoration operation and the dust removal effect of dust removal have been reduced.

2. Traditional amino acid fertilizer is at the stoving operation in-process, is difficult to provide the constant temperature stoving operation of circumference for the amino acid fertilizer, also is difficult to drive accumulational amino acid fertilizer and vibrates and overturn, has reduced the stoving effect of each floor amino acid fertilizer stoving operation, and it sweeps away to carry out secondary to the dust granule of adhesion on the amino acid fertilizer more difficult, has reduced the whole clean degree of amino acid fertilizer.

Disclosure of Invention

In order to solve the problems, the invention provides a production, preparation and processing technology of an amino acid organic fertilizer.

In order to achieve the purpose, the invention adopts the following technical scheme to realize the purpose: the utility model provides an amino acid fertilizer production preparation processingequipment, it has used an amino acid fertilizer production preparation processingequipment, this amino acid fertilizer production preparation processingequipment includes mounting plate, supporting legs, bracing piece, dust removal case, pan feeding mouth, play feed cylinder, dust removal mechanism, stoving mechanism and blanking mechanism, and concrete technology is as follows when adopting above-mentioned amino acid fertilizer production preparation processingequipment to amino acid fertilizer production preparation processing operation:

s1, blanking and conveying: firstly, manually loading the amino acid organic fertilizer to be subjected to dust removal and drying operation into a dust removal box along a feeding port, and conveying the amino acid organic fertilizer through a dust removal mechanism;

s2, vibration dust removal: in the process of the step S1, the amino acid organic fertilizer in the conveying process is driven to vibrate by the dust removal mechanism, so that dust particles adhered to the amino acid organic fertilizer fall off;

s3, rotary drying: step S2, simultaneously, drying the amino acid organic fertilizer through a drying mechanism, and performing secondary vibration dust removal on the amino acid organic fertilizer in the drying process;

s4, collecting and storing: in the process of the step S3, the blanking mechanism drives the drying mechanism to rotate obliquely, so that the amino acid organic fertilizer after drying and dust removal in the drying mechanism falls off, and then the amino acid organic fertilizer after drying and dust removal is collected and stored manually;

supporting legs are arranged at the corners around the lower end surface of the mounting bottom plate, supporting rods are uniformly arranged on the upper end surface of the mounting bottom plate, dust removing boxes are jointly arranged at the upper ends of the supporting rods, a feeding port is arranged at the upper end of each dust removing box, the discharging barrels are symmetrically arranged on the side wall of the lower end of the dust removal box in the front-back direction, the drying mechanism is jointly arranged between the discharging barrels, the dust removal mechanism is arranged in the dust removal box, and the blanking mechanism is arranged at the lower end of the dust removal box.

The drying mechanism comprises flexible pipes, drying cylinders, drying rotating shafts, positioning rods, drying rotating rings, drying blocks, drying rods, discharge ports, synchronizing wheels, synchronizing belts, positioning frames, eccentric wheels and a drying motor, the flexible pipes are arranged on the discharge cylinders, the drying cylinders are arranged on the flexible pipes, the drying rotating shafts are arranged at the end parts of the drying cylinders through bearings, the synchronizing wheels are arranged on the drying rotating shafts through splines, the synchronizing wheels at the front side and the rear side are connected through the synchronous belt in a transmission manner, the positioning frames are arranged on the side walls of the drying cylinders, the drying motor is arranged on one positioning frame through a motor base, the output shaft of the drying motor is connected with one drying rotating shaft through a coupling, the eccentric wheel is arranged on the drying rotating shaft at the same side of the drying motor through the splines, and the eccentric wheel is positioned on the inner side of the positioning frames, keep away from the stoving section of thick bamboo downside of dust removal case one end and all install the discharge gate, evenly install the multiunit locating lever along its circumference in being located the stoving pivot of stoving section of thick bamboo inboard, the stoving change of the looks isostructure is all installed jointly to the tip of the locating lever of the same group, and evenly install the stoving pole along its circumference between adjacent two sets of stoving change, the inside wall of a stoving section of thick bamboo evenly installs multiunit stoving piece along its circumference, and the stoving piece in the same group all is located between adjacent two sets of stoving change, the stoving piece that sets up through circumference can make the air of each region in the stoving section of thick bamboo be in even constant temperature state, the circumferential direction effect through the stoving pole makes the continuous upset of accumulational amino acid, inertia when rotating through the eccentric wheel can make the amino acid fertilizer in the stoving section of thick bamboo carry out synchronous reciprocating vibration, promote the stoving effect of each layer amino acid fertilizer stoving operation.

Further, the discharge gate in crisscross evenly install the screening pole from top to bottom, and evenly be provided with the brush along its circumference on the lateral wall of screening pole, the brush that sets up on the screening pole can be swept the brush clearance to amino acid fertilizer at the in-process that passes the discharge gate, promotes amino acid fertilizer's whole clean degree.

Further, dust removal mechanism include the air pump, the adsorption tube, the dust removal bottom plate, carry the pivot, the conveyer belt, conveying motor, the dust removal board, the annular chamber, dust removal pipe and hose, the dust removal bottom plate is installed to the inner wall lower extreme of dust removal case, the annular chamber is installed to the symmetry on the dust removal bottom plate, and the annular chamber is linked together with a feed cylinder, the transport pivot is installed through the bearing symmetry in the dust removal incasement and the feed cylinder, and be connected through the conveyer belt transmission between the transport pivot on the dust removal case and the feed cylinder in the feed cylinder, install conveying motor through the motor cabinet on the outer wall of dust removal case, conveying motor's output shaft is connected with the transport pivot on the dust removal case through the shaft coupling, the dust removal board is installed to the dust removal incasement, and the dust removal board is located the annular region inboard of conveyer belt, the dust removal pipe is evenly installed to the upper end of annular chamber, the adsorption tube is installed to the upper end of drying cylinder, the adsorption tube is located the top of discharge gate and the adsorption tube is linked together with the air pump, and be connected with the hose on the air pump, and the other end of hose is linked together with dust removal board and dust removal pipe respectively, the dust removal effect of hose and dust removal pipe with the dust removal pipe is collected the dust removal effect of suspension in the annular chamber through the hose and is carried out.

Further, conveyer belt outside lateral wall on evenly be provided with the striker plate, evenly be provided with the screening net on the conveyer belt, and the screening net all is located between two adjacent striker plates, evenly install the ball through normal running fit's mode on the inboard lateral wall of conveyer belt, the vibrating mass is evenly installed to the up end of dust removal board, and the ball supports and leans on the vibrating mass, the striker plate that sets up on the conveyer belt can carry out even dispersion with accumulational amino acid fertilizer, strengthens the operation effect of follow-up amino acid fertilizer dust removal edulcoration operation.

Furthermore, dust removal board, dust removal pipe and adsorption tube in all be provided with the filter pulp that is used for adsorbing the dust particulate matter, can realize carrying out automatic collection to the dust that produces in the drying process through the adsorption of filter pulp.

Further, dust removal incasement wall upper end install the direction pivot through the bearing, install the deflector through the spline in the direction pivot, the deflector slope is installed at the dust removal incasement and the lower extreme of deflector is connected through the outer wall upper end of guide spring with the annular chamber, the up end cross of deflector is provided with the multiunit guide bar, the deflector that sets up through the slope can strengthen the landing effect of amino acid fertilizer, the guide spring of setting can provide certain vibration effect for the deflector when supporting the deflector bottom, avoid the amino acid fertilizer to take place to pile up the phenomenon of jam on the deflector.

Further, blanking mechanism include the free bearing, the blanking cylinder, the fixed plate, the blanking pivot, the blanking bull stick, the telescopic link, the bearing frame, blanking spring and bearing seat, the lower extreme mid-mounting of dust removal case has the free bearing, install the blanking cylinder through normal running fit's mode on the free bearing, the fixed plate is installed to the lower extreme of dust removal case near marginal position front and back symmetry, install the blanking pivot jointly through the bearing between the fixed plate, the blanking bull stick is installed through the spline in the middle part of blanking pivot, and the rotation end of blanking bull stick is connected with the output shaft of blanking cylinder through normal running fit's mode, the telescopic link is installed through spline symmetry at the both ends of blanking pivot, the bearing frame is installed jointly to the removal end of telescopic link, the bearing frame is located the below of drying cylinder and is connected through the blanking spring between bearing frame and the drying cylinder, the bearing seat is installed to the up end face of mounting plate, and the bearing seat is located the below of bearing frame, the terminal downward sloping of drying cylinder can further strengthen the vibration effect of follow-up and down drying cylinder through the elastic support of blanking spring simultaneously.

Furthermore, the telescopic link form through the concatenation of sliding fit's mode by two sections secant planes are regular polygon's slide bar, and be connected through expanding spring between two sections slide bars, the stiff end of telescopic link is installed in the blanking pivot through the spline, the removal end of telescopic link is installed on the bearing frame through the spline.

Furthermore, the bearing frame be L shape structure, the electro-magnet is installed to the lower extreme symmetry of bearing frame, is provided with the inclined plane that highly inclines gradually downwards from the left side to the right side on the bearing seat, and is provided with the magnet hole with electro-magnet matched with on the inclined plane.

The invention has the beneficial effects that:

1. according to the invention, the sliding effect of the amino acid organic fertilizer can be enhanced through the guide plate which is obliquely arranged, the guide spring can support the bottom of the guide plate and provide a certain vibration effect for the guide plate at the same time, the phenomenon that the amino acid organic fertilizer is accumulated and blocked on the guide plate is avoided, the guide rod arranged on the guide plate enables the bonded amino acid organic fertilizer to uniformly disperse and slide through the limiting and blocking effect of the guide rod, and the operation effect of the subsequent dust removal and drying operation of the amino acid organic fertilizer is improved.

2. According to the dust removal mechanism provided by the invention, the striker plate arranged on the conveying belt can uniformly disperse the accumulated amino acid organic fertilizer, the operation effect of the subsequent amino acid organic fertilizer dust removal and impurity removal operation is enhanced, the amino acid organic fertilizer on the conveying belt can vibrate through the intermittent abutting action between the balls and the vibrating block, the arranged screening net can screen and filter the amino acid organic fertilizer in the vibrating conveying process, the dropping effect of impurity particles such as dust adhered to the amino acid organic fertilizer is enhanced, the dust suspended in the annular cavity is collected and adsorbed through the communication action of the hose and the dust removal pipe, and the operation effect of the amino acid organic fertilizer dust removal and impurity removal operation is further improved.

3. According to the drying mechanism provided by the invention, the air in each area in the drying cylinder can be in a uniform constant temperature state through the circumferentially arranged drying blocks, the accumulated amino acid organic fertilizer is continuously turned over through the circumferential rotation effect of the drying rod, the amino acid organic fertilizer in the drying cylinder can synchronously vibrate in a reciprocating manner through the inertia of the eccentric wheel during rotation, the drying effect of the drying operation of the amino acid organic fertilizer on each layer is improved, meanwhile, dust particles adhered to the amino acid organic fertilizer are subjected to secondary vibration and fall off, the hair brush arranged on the screening rod can sweep and clean the amino acid organic fertilizer in the process that the amino acid organic fertilizer passes through the discharge hole, and the overall cleaning degree of the amino acid organic fertilizer is improved.

4. According to the blanking mechanism provided by the invention, the passing speed of the amino acid organic fertilizer in the drying cylinder can be increased by enabling the tail end of the drying cylinder to incline downwards, and meanwhile, the reciprocating vibration effect of the subsequent drying cylinder can be further enhanced through the elastic support of the blanking spring, so that the operation effect of dust removal and impurity removal of the amino acid organic fertilizer is further enhanced.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a flow chart of the present invention;

FIG. 2 is a front view of the overall structure of the present invention;

FIG. 3 is a schematic cross-sectional view of the present invention;

FIG. 4 is an enlarged schematic view taken at A of FIG. 3 in accordance with the present invention;

FIG. 5 is an enlarged schematic view at B of FIG. 3 of the present invention;

FIG. 6 is an enlarged schematic view at C of FIG. 3 of the present invention;

FIG. 7 is a schematic view of a partial perspective structure of the dust removing mechanism of the present invention;

FIG. 8 is an enlarged schematic view taken at D of FIG. 7 in accordance with the present invention;

FIG. 9 is a schematic view of a partial three-dimensional structure of the blanking mechanism of the present invention;

FIG. 10 is a schematic view of a first partial perspective view of the drying mechanism of the present invention;

fig. 11 is a schematic view of a second partial perspective structure of the drying mechanism of the present invention.

In the figure: 1. mounting a bottom plate; 2. supporting legs; 3. a support bar; 4. a dust removal box; 5. a feeding port; 6. a discharging barrel; 7. a dust removal mechanism; 8. a drying mechanism; 9. a blanking mechanism; 7a, an air pump; 7b, an adsorption tube; 7c, a dust removal bottom plate; 7d, conveying rotating shafts; 7e, a conveying belt; 7f, a conveying motor; 7g, a dust removal plate; 7h, a ring cavity; 7j, a dust removal pipe; 7k, a hose; 7m, filter cotton; 7e3, a ball; 7e2, screening the net; 7e1, a striker plate; 4a12, a guide rod; 4a, a guide rotating shaft; 4a11, a guide spring; 8a, a flexible tube; 8b, drying the cylinder; 8c, drying the rotating shaft; 8d, positioning a rod; 8e, drying the rotary ring; 8f, drying the blocks; 8g, drying the rods; 8h, discharging; 8j, a synchronizing wheel; 8k, a synchronous belt; 8m, a positioning frame; 8n, an eccentric wheel; 8p, drying the motor; 9a, a hinged support; 9b, a blanking cylinder; 9c, fixing plates; 9d, blanking rotating shafts; 9e, blanking rotating rods; 9f, a telescopic rod; 9g, a bearing frame; 9h, blanking a spring; 9j, a bearing seat; 9g1, an electromagnet; 9j1, magnet hole.

Detailed Description

In order to make the technical problems, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments, it being understood that the specific embodiments described herein are only for the purpose of explaining the present invention and are not intended to limit the present invention.

Referring to fig. 1 and 2, an amino acid organic fertilizer production, preparation and processing technology uses an amino acid organic fertilizer production, preparation and processing device, and the amino acid organic fertilizer production, preparation and processing device comprises an installation bottom plate 1, supporting legs 2, a supporting rod 3, a dust removal box 4, a feeding port 5, a discharging barrel 6, a dust removal mechanism 7, a drying mechanism 8 and a blanking mechanism 9.

Referring to fig. 2, mounting plate 1 under the terminal surface corner all around all install supporting legs 2, bracing piece 3 is evenly installed to mounting plate 1's up end, dust removal case 4 is installed jointly to bracing piece 3's upper end, pan feeding mouth 5 is installed to dust removal case 4's upper end, feed cylinder 6 is installed to the front and back symmetry on the lower extreme lateral wall of dust removal case 4, install stoving mechanism 8 jointly between the feed cylinder 6, install dust removal mechanism 7 in the dust removal case 4, blanking mechanism 9 is installed to the lower extreme of dust removal case 4.

Referring to fig. 3, 5, 8 and 7, the dust removing mechanism 7 includes an air pump 7a, an adsorption pipe 7b, a dust removing bottom plate 7c, a conveying rotating shaft 7d, a conveying belt 7e, a conveying motor 7f, a dust removing plate 7g, an annular cavity 7h, a dust removing pipe 7j and a hose 7k, the dust removing bottom plate 7c is installed at the lower end of the inner wall of the dust removing box 4, the annular cavity 7h is symmetrically installed on the dust removing bottom plate 7c, the annular cavity 7h is communicated with the discharge barrel 6, conveying rotating shafts 7d are symmetrically arranged in the dust removing box 4 and the discharge barrel 6 through bearings, a conveying rotating shaft 7d on the dust removing box 4 is in transmission connection with a conveying rotating shaft 7d in the discharging barrel 6 through a conveying belt 7e, a conveying motor 7f is installed on the outer wall of the dust removing box 4 through a motor base, an output shaft of the conveying motor 7f is connected with the conveying rotating shaft 7d on the dust removing box 4 through a coupling, a dust removing plate 7g is installed in the dust removing box 4, the dust removing plate 7g is positioned at the inner side of the annular area of the conveyer belt 7e, the side wall at the outer side of the conveyer belt 7e is uniformly provided with a material baffle plate 7e1, the conveyer belt 7e is uniformly provided with a screening net 7e2, the sieving nets 7e2 are positioned between two adjacent material baffle plates 7e1, the inner side wall of the conveying belt 7e is uniformly provided with balls 7e3 in a rotating fit mode, the upper end surface of the dust removing plate 7g is uniformly provided with vibrating blocks 7g1, the ball 7e3 is abutted against the vibrating block 7g1, the upper end of the annular cavity 7h is uniformly provided with a dust removal pipe 7j, the upper end of the drying cylinder 8b is provided with an adsorption pipe 7b, the upper end of the drying cylinder 8b is provided with an air pump 7a, the adsorption pipe 7b is positioned above the discharge hole 8h and is communicated with the air pump 7a, the air pump 7a is connected with a hose 7k, and the other end of the hose 7k is respectively communicated with a dust removal plate 7g and a dust removal pipe 7j, and filter cotton 7m for adsorbing dust particles is arranged in the dust removal plate 7g, the dust removal pipe 7j and the adsorption pipe 7 b.

When the device works, the amino acid organic fertilizer to be dried and dedusted is manually filled into the dedusting box 4 along the feeding port 5, then the conveying motor 7f is started and drives the conveying rotating shaft 7d to rotate, the conveying rotating shaft 7d drives the conveying belt 7e to synchronously rotate, the conveying belt 7e drives the dropped amino acid organic fertilizer to convey and move, the baffle 7e1 arranged on the conveying belt 7e can uniformly disperse the accumulated amino acid organic fertilizer, the subsequent operation effect of dedusting and impurity removing of the amino acid organic fertilizer is enhanced, the conveying belt 7e3 is driven to synchronously move while the conveying belt 7e rotates, and the conveying belt 7e synchronously vibrates in a reciprocating manner through the intermittent abutting action between the ball 7e3 and the vibrating block 7g1 in the moving process of the ball 7e3, further drive the amino acid fertilizer in the transportation process and vibrate, the reinforcing effect that drops of impurity particles such as dust on the amino acid fertilizer, the screening net 7e2 that sets up can sieve the amino acid fertilizer among the vibratory transportation process and filter, make the dust impurity after the separation drop on the dust removal board 7g of below, further carry out the secondary through the filter pulp 7m on the dust removal board 7g and adsorb the collection to the dust particle, when conveyer belt 7e carries the amino acid fertilizer, start air pump 7a, take out the air current in with hose 7k through air pump 7a, further collect the absorption with the dust that suspends in annular chamber 7h through hose 7k and the intercommunication of dust removal pipe 7j, further promote the operation effect of amino acid fertilizer dust removal edulcoration operation.

Referring to fig. 3 and 4, the upper end of the inner wall of the dust removing box 4 is provided with a guide rotating shaft 4a through a bearing, the guide rotating shaft 4a is provided with a guide plate 4a1 through a spline, the guide plate 4a1 is obliquely arranged in the dust removing box 4, the lower end of the guide plate 4a1 is connected with the upper end of the outer wall of the annular cavity 7h through a guide spring 4a11, and the upper end face of the guide plate 4a1 is provided with a plurality of groups of guide rods 4a12 in a staggered manner.

During specific work, after the amino acid fertilizer is artificially loaded into the feeding port 5, the amino acid fertilizer slides downwards under the guide effect of gravity and the guide plate 4a1, the guide spring 4a11 that is arranged can support the bottom of the guide plate 4a1 and provide a certain vibration effect for the guide plate 4a1, the phenomenon that the amino acid fertilizer is piled up and blocked on the guide plate 4a1 is avoided, and the guide rod 4a12 arranged on the guide plate 4a1 can make the amino acid fertilizer slide on the conveying belts 7e on two sides uniformly through the self limiting blocking effect.

Referring to fig. 2, 10 and 11, the drying mechanism 8 includes a flexible tube 8a, a drying cylinder 8b, a drying rotating shaft 8c, a positioning rod 8d, a drying rotating ring 8e, a drying block 8f, a drying rod 8g, a discharging port 8h, a synchronizing wheel 8j, a synchronizing belt 8k, a positioning frame 8m, an eccentric wheel 8n and a drying motor 8p, the discharging cylinder 6 is provided with the flexible tube 8a, the flexible tube 8a is provided with the drying cylinder 8b, the end of the drying cylinder 8b is provided with the drying rotating shaft 8c through a bearing, the drying rotating shaft 8c is provided with the synchronizing wheel 8j through a spline, the synchronizing wheels 8j on the front side and the rear side are in transmission connection through the synchronizing belt 8k, the positioning frame 8m is provided on the side wall of the drying cylinder 8b, one positioning frame 8m is provided with the drying motor 8p through a motor base, and the output shaft of the drying motor 8p is connected with one drying rotating shaft 8c through a coupling, install eccentric wheel 8n through the spline on the stoving pivot 8c that is located stoving motor 8p homonymy, and eccentric wheel 8n is located the inboard of locating rack 8m, and the stoving section of thick bamboo 8b downside of keeping away from 4 one ends of dust removal case all installs discharge gate 8h, discharge gate 8h in crisscross even install screening pole 8h1 from top to bottom, and evenly be provided with brush 8h11 along its circumference on screening pole 8h 1's the lateral wall, evenly install multiunit locating lever 8d along its circumference on the stoving pivot 8c that is located stoving section of thick bamboo 8b inboard, the same stoving change 8e of structure is all installed jointly to the tip of organizing locating lever 8d, and evenly install stoving pole 8g along its circumference between the adjacent two sets of stoving change 8e, multiunit stoving piece 8f is evenly installed along its circumference to the inside wall of stoving section of thick bamboo 8b, and the stoving piece 8f in the same group all is located between the adjacent two sets of stoving change 8 e.

When the drying machine works specifically, the conveyor belt 7e conveys amino acid organic fertilizer, the drying block 8f is electrified and heated, then the drying motor 8p is started and drives one drying rotating shaft 8c to rotate, the other drying rotating shaft 8c is synchronously rotated through the transmission connection between the synchronizing wheel 8j and the synchronizing belt 8k, the drying rotating ring 8e is synchronously rotated through the transmission connection of the positioning rod 8d while the drying rotating shaft 8c rotates, the drying rod 8g is synchronously rotated through the driving of the drying rotating ring 8e, after the conveyor belt 7e drives the amino acid organic fertilizer to be conveyed to the tail end of the discharging cylinder 6, the amino acid organic fertilizer falls into the flexible pipe 8a through the gravity effect, and further slides into the drying cylinder 8b through the conveying guiding effect of the flexible pipe 8a, the drying operation is carried out on the amino acid organic fertilizer through the drying effect of the drying block 8f, the accumulated amino acid organic fertilizer is continuously overturned under the action of the circumferential rotation of the drying rod 8g, in the rotating process of the drying rotating shaft 8c, the eccentric wheel 8n is driven to synchronously rotate, the drying rotating shaft 8c is subjected to reciprocating vibration through inertia when the eccentric wheel 8n rotates, the drying cylinder 8b is further subjected to synchronous reciprocating vibration, the amino acid organic fertilizer in the drying cylinder 8b is further driven to synchronously vibrate in a reciprocating manner, the drying effect of drying operation of the amino acid organic fertilizer on each layer is improved, dust particles adhered to the amino acid organic fertilizer are subjected to secondary vibration and drop at the same time, the adsorption pipe 7b generates suction while the air pump 7a works, the dust particles remained in the drying cylinder 8b are adsorbed and collected through the adsorption force of the adsorption pipe 7b, and the dust particles synchronously slide towards one end of the discharge hole 8h in the overturning and drying operation process of the amino acid organic fertilizer, the hairbrush 8h11 arranged on the screening rod 8h1 can be brushed and cleaned in the process that the amino acid organic fertilizer passes through the discharge hole 8h, and the integral cleaning degree of the amino acid organic fertilizer is improved.

Referring to fig. 6 and 9, the blanking mechanism 9 includes a hinged support 9a, a blanking cylinder 9b, a fixing plate 9c, a blanking rotating shaft 9d, a blanking rotating rod 9e, an expansion link 9f, a bearing frame 9g, a blanking spring 9h and a bearing seat 9j, the hinged support 9a is installed in the middle of the lower end of the dust removing box 4, the blanking cylinder 9b is installed on the hinged support 9a in a rotation fit manner, the fixing plates 9c are symmetrically installed in front and back of the lower end of the dust removing box 4 near the edge position, the blanking rotating shaft 9d is installed between the fixing plates 9c through a bearing, the blanking rotating rod 9e is installed in the middle of the blanking rotating shaft 9d through a spline, the rotating end of the blanking rotating rod 9e is connected with the output shaft of the blanking cylinder 9b in a rotation fit manner, the expansion links 9f are symmetrically installed at the two ends of the blanking rotating shaft 9d through a spline, telescopic link 9f be that regular polygon's slide bar forms through sliding fit's mode concatenation by two sections section cut surfaces, and be connected through expanding spring between two sections slide bars, telescopic link 9 f's stiff end passes through the spline and installs on blanking pivot 9d, telescopic link 9 f's removal end installs bearing frame 9g through the spline jointly, bearing frame 9g is located the below of drying section of thick bamboo 8b and is connected through blanking spring 9h between bearing frame 9g and the drying section of thick bamboo 8b, bearing seat 9j is installed to the up end of mounting plate 1, and bearing seat 9j is located the below of bearing frame 9g, bearing frame 9g be L shape structure, electro-magnet 9g1 is installed to the lower extreme symmetry of bearing frame 9g, is provided with the inclined plane that highly is gradually from left to right, and is provided with on the inclined plane with electro-magnet 9g1 matched with magnet hole 9j1 on the inclined plane.

When the drying device works specifically, in the process that an amino acid organic fertilizer passes through the drying cylinder 8b, the blanking rotating rod 9e is pulled by the blanking air cylinder 9b to rotate, the blanking rotating rod 9e drives the blanking rotating shaft 9d to rotate synchronously, the symmetrically-installed telescopic rods 9f are driven by the blanking rotating shaft 9d to rotate, in the rotating process of the telescopic rods 9f, the drying cylinder 8b which is in a horizontal state previously is enabled to rotate obliquely downwards synchronously through the transmission connection of the bearing frame 9g, the arranged flexible pipe 8a can adapt to the change of the inclination angle between the tail end of the drying cylinder 8b and the discharging cylinder 6 when the drying cylinder 8b rotates, the bearing frame 9g can adapt to the change of the interval between the drying cylinder 8b and the dust removal box 4 through the self-telescopic characteristic of the telescopic rods 9f, after the bearing frame 9g moves downwards and is attached to the inclined plane on the bearing seat 9j, the electromagnet 9g1 arranged below the bearing frame 9g synchronously enters the dust removal hole 9j1, then, the electromagnet 9g1 is powered on the electromagnet 9g1 through the magnetic adsorption effect between the bearing frame 9j, the position of the drying cylinder 9g is further fixed through the reciprocating magnetic absorption effect of the drying cylinder 8b, the drying cylinder 8b can be further enhanced by the reciprocating vibration effect of the drying cylinder, and the drying cylinder 8b can be further enhanced by the reciprocating effect of the drying cylinder.

The specific process for producing, preparing and processing the amino acid organic fertilizer by adopting the amino acid organic fertilizer production, preparation and processing device is as follows:

s1, blanking and conveying: the amino acid organic fertilizer to be dried and dedusted is manually filled into the dedusting box 4 along the material inlet 5, and then the amino acid organic fertilizer slides downwards under the guide action of gravity and the guide plate 4a1, the guide spring 4a11 is arranged to support the bottom of the guide plate 4a1 and provide a certain vibration effect for the guide plate 4a1, so that the phenomenon that the amino acid organic fertilizer is accumulated and blocked on the guide plate 4a1 is avoided, and the guide rod 4a12 arranged on the guide plate 4a1 enables the amino acid organic fertilizer to uniformly slide towards the conveying belts 7e on two sides under the self limiting and blocking action;

s2, vibration dust removal: the conveying motor 7f is started and drives the conveying rotating shaft 7d to rotate, the conveying rotating shaft 7d drives the conveying belt 7e to synchronously rotate, the conveying belt 7e drives the dropped amino acid organic fertilizer to convey and move, the baffle 7e1 arranged on the conveying belt 7e can uniformly disperse the accumulated amino acid organic fertilizer, the conveying belt 7e is driven to synchronously move while the conveying belt 7e rotates, the conveying belt 7e is synchronously vibrated back and forth under the intermittent abutting action between the ball 7e3 and the vibrating block 7g1 in the moving process of the ball 7e3, the amino acid organic fertilizer in the conveying process is further driven to vibrate, the arranged sieving net 7e2 can sieve and filter the amino acid organic fertilizer in the vibrating conveying process, the separated dust impurities fall onto the dust removing plate 7g below, the dust particles are further secondarily adsorbed and collected by the filter cotton 7m on the dust removing plate 7g, the air pump 7a is started while the conveying belt 7e conveys the amino acid organic fertilizer, the air flow in the hose 7k is pumped out by the air pump 7a, and the air pump 7k is further communicated with the dust collecting pipe 7h under the dust removing action of the dust removing pipe 7k through the dust removing pipe 7 j;

s3, rotary drying: when the conveyer belt 7e conveys the amino acid organic fertilizer, the drying block 8f is electrified and heated, then the drying motor 8p is started and drives one drying rotating shaft 8c to rotate, the other drying rotating shaft 8c synchronously rotates through the transmission connection between the synchronizing wheel 8j and the synchronizing belt 8k, when the drying rotating shaft 8c rotates, the drying rotating ring 8e synchronously rotates through the transmission connection of the positioning rod 8d, the drying rod 8g is driven to synchronously rotate through the drying rotating ring 8e, when the conveyer belt 7e drives the amino acid organic fertilizer to be conveyed to the tail end of the discharging barrel 6, the amino acid organic fertilizer drops into the flexible pipe 8a through the gravity action, and further slides into the drying barrel 8b through the conveying guiding action of the flexible pipe 8a, the amino acid organic fertilizer is dried through the drying action of the drying block 8f, the accumulated amino acid organic fertilizer is continuously overturned through the circumferential rotation action of the drying rod 8g, in the process of drying rotating shaft 8c rotation, drive eccentric wheel 8n and carry out synchronous rotation, inertia when rotating through eccentric wheel 8n makes drying rotating shaft 8c carry out reciprocating vibration, further make drying cylinder 8b carry out synchronous reciprocating vibration, further drive the amino acid fertilizer in drying cylinder 8b and carry out synchronous reciprocating vibration, promote the stoving effect of each level amino acid fertilizer stoving operation, make the dust granule of adhesion on the amino acid fertilizer carry out secondary vibration and drop simultaneously, when air pump 7a carries out work, further make adsorption tube 7b produce suction, the adsorption affinity through adsorption tube 7b will remain the dust granule in drying cylinder 8b and adsorb the collection, in-process that makes amino acid fertilizer upset stoving operation slides to discharge gate 8h one end in step, set up brush 8h11 on screening pole 8h1 and can pass discharge gate 8 h's in-process to it at amino acid Brushing and cleaning are carried out, so that the overall cleaning degree of the amino acid organic fertilizer is improved;

s4, collecting and storing: in the process that the amino acid organic fertilizer passes through the drying cylinder 8b, the blanking rotating rod 9e is pulled by the blanking cylinder 9b to rotate, the blanking rotating shaft 9d is driven by the blanking rotating rod 9e to synchronously rotate, the symmetrically arranged telescopic rods 9f are driven by the blanking rotating shaft 9d to rotate, in the rotating process of the telescopic rods 9f, the drying cylinder 8b which is in the horizontal state is synchronously inclined and rotated downwards by the transmission connection of the bearing frame 9g, the arranged flexible pipe 8a can adapt to the inclination angle change between the tail end of the drying cylinder 8b and the discharging cylinder 6 when the drying cylinder 8b rotates, the bearing frame 9g can adapt to the interval change between the drying cylinder 8b and the dust removing box 4 when the drying cylinder 8b rotates by the self-telescopic characteristic of the telescopic rods 9f, and after the bearing frame 9g moves downwards and is attached to the inclined plane on the bearing seat 9j, set up in electromagnet 9g1 of bearing frame 9g below enters into magnet hole 9j1 in step, later, energize to electromagnet 9g1, the position that makes bearing frame 9g through the magnetic force adsorption between electromagnet 9g1 and the bearing seat 9j is fixed, further make the inclination of drying cylinder 8b relatively fixed, the speed of passing through of the multiplicable amino acid fertilizer of end downward sloping through making drying cylinder 8b in drying cylinder 8b, the reciprocating vibration effect of follow-up drying cylinder 8b can further be strengthened through blanking spring 9 h's elastic support simultaneously, the operation effect of further reinforcing amino acid fertilizer dust removal edulcoration, later, collect through the artifical amino acid fertilizer that drops in to discharge gate 8h and deposit.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are given by way of illustration of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides an amino acid fertilizer production preparation processingequipment, its used amino acid fertilizer production preparation processingequipment, this amino acid fertilizer production preparation processingequipment includes mounting plate (1), supporting legs (2), bracing piece (3), dust removal case (4), pan feeding mouth (5), goes out feed cylinder (6), dust removal mechanism (7), stoving mechanism (8) and blanking mechanism (9), its characterized in that: the specific process of the production, preparation and processing operation of the amino acid organic fertilizer by adopting the production, preparation and processing device of the amino acid organic fertilizer is as follows:

s1, blanking and conveying: firstly, manually loading the amino acid organic fertilizer to be subjected to dust removal and drying operation into a dust removal box (4) along a feeding port (5), and conveying the amino acid organic fertilizer through a dust removal mechanism (7);

s2, vibration dust removal: in the process of the step S1, the amino acid organic fertilizer in the conveying process is driven to vibrate by the dust removal mechanism (7), so that dust particles adhered to the amino acid organic fertilizer fall off;

s3, rotary drying: step S2, simultaneously, the amino acid organic fertilizer is dried by a drying mechanism (8), and secondary vibration dust removal is carried out on the amino acid organic fertilizer in the drying process;

s4, collecting and storing: in the process of the step S3, the blanking mechanism (9) drives the drying mechanism (8) to rotate obliquely, so that the amino acid organic fertilizer after drying and dust removal in the drying mechanism (8) falls off, and then the amino acid organic fertilizer after drying and dust removal is collected and stored manually;

supporting legs (2) are arranged at the corners of the periphery of the lower end face of the mounting base plate (1), supporting rods (3) are uniformly arranged on the upper end face of the mounting base plate (1), dust removing boxes (4) are jointly arranged at the upper ends of the supporting rods (3), a feeding opening (5) is arranged at the upper end of each dust removing box (4), discharge barrels (6) are symmetrically arranged on the side wall of the lower end of each dust removing box (4) from front to back, drying mechanisms (8) are jointly arranged between the discharge barrels (6), a dust removing mechanism (7) is arranged in each dust removing box (4), and a blanking mechanism (9) is arranged at the lower end of each dust removing box (4);

the drying mechanism (8) comprises a flexible pipe (8 a), drying cylinders (8 b), a drying rotating shaft (8 c), a positioning rod (8 d), a drying rotating ring (8 e), a drying block (8 f), a drying rod (8 g), a discharge port (8 h), a synchronizing wheel (8 j), a synchronizing belt (8 k), a positioning frame (8 m), an eccentric wheel (8 n) and a drying motor (8 p), the flexible pipe (8 a) is installed on a discharge cylinder (6), the drying cylinders (8 b) are installed on the flexible pipe (8 a), the drying rotating shaft (8 c) is installed on the end portion of each drying cylinder (8 b) through a bearing, the synchronizing wheel (8 j) is installed on each drying rotating shaft (8 c) through a spline, the synchronizing wheels (8 j) on the front side and the rear side are in transmission connection through the synchronizing belt (8 k), the positioning frame (8 m) is installed on the side wall of each drying cylinder (8 b), the drying motor (8 p) is installed on one spline positioning frame (8 m), an output shaft of the drying motor (8 p) is connected with one drying rotating shaft (8) through a shaft (8 b), the drying cylinder (8 b) and one end of the drying cylinder (8 b) is located on the same side, and the lower side of the drying motor (8 b) is located on the same side, and the drying motor (8 b) and located on the same side of the drying cylinder (8 n), and located on the drying motor (8 b) and located on the drying cylinder (8 b) and located on the same side, the same side of the drying motor (8 b), a plurality of groups of positioning rods (8 d) are uniformly arranged on a drying rotating shaft (8 c) positioned on the inner side of a drying cylinder (8 b) along the circumferential direction of the drying rotating shaft, drying rotating rings (8 e) with the same structure are commonly arranged at the end parts of the positioning rods (8 d) of the same group, drying rods (8 g) are uniformly arranged between two adjacent groups of drying rotating rings (8 e) along the circumferential direction of the drying rotating rings, a plurality of groups of drying blocks (8 f) are uniformly arranged on the inner side wall of the drying cylinder (8 b) along the circumferential direction of the drying cylinder, and the drying blocks (8 f) in the same group are positioned between two adjacent groups of drying rotating rings (8 e);

the dust removal mechanism (7) comprises an air pump (7 a), an adsorption pipe (7 b), a dust removal bottom plate (7 c), a conveying rotating shaft (7 d), a conveying belt (7 e), a conveying motor (7 f), a dust removal plate (7 g), an annular cavity (7 h), a dust removal pipe (7 j) and a hose (7 k), the dust removal bottom plate (7 c) is installed at the lower end of the inner wall of the dust removal box (4), the annular cavity (7 h) is symmetrically installed on the dust removal bottom plate (7 c), the annular cavity (7 h) is communicated with a discharge barrel (6), the conveying rotating shaft (7 d) is symmetrically installed in the dust removal box (4) and in the discharge barrel (6) through bearings, the conveying rotating shaft (7 d) on the dust removal box (4) is in transmission connection with the conveying rotating shaft (7 d) in the discharge barrel (6) through the conveying belt (7 e), the conveying motor (7 f) is installed on the outer wall of the dust removal box (4) through a motor base, the output shaft of the conveying motor (7 f) is connected with the conveying rotating shaft (7 d) on the dust removal box (4) through a coupler, the inner side of the dust removal plate (7 g) is installed in the dust removal box (4), the dust removal plate (7 j), and the drying pipe (7 b) is located in the inner side of the drying barrel (7 b) and is located in the drying pipe (7 b), an air pump (7 a) is installed at the upper end of the drying cylinder (8 b), the adsorption pipe (7 b) is located above the discharge hole (8 h), the adsorption pipe (7 b) is communicated with the air pump (7 a), a hose (7 k) is connected to the air pump (7 a), and the other end of the hose (7 k) is communicated with the dust removal plate (7 g) and the dust removal pipe (7 j) respectively;

the lateral wall of the outer side of the conveying belt (7 e) is uniformly provided with baffle plates (7 e 1), the conveying belt (7 e) is uniformly provided with a screening net (7 e 2), the screening net (7 e 2) is positioned between every two adjacent baffle plates (7 e 1), the lateral wall of the inner side of the conveying belt (7 e) is uniformly provided with balls (7 e 3) in a rotating fit mode, the upper end face of the dust removing plate (7 g) is uniformly provided with a vibrating block (7 g 1), and the balls (7 e 3) are abutted against the vibrating block (7 g 1);

and filter cotton (7 m) for adsorbing dust particles are arranged in the dust removing plate (7 g), the dust removing pipe (7 j) and the adsorption pipe (7 b).

2. The production, preparation and processing technology of the amino acid organic fertilizer as claimed in claim 1, which is characterized in that: discharge gate (8 h) in crisscross evenly install screening pole (8 h 1) from top to bottom, and screen and evenly be provided with brush (8 h 11) along its circumference on the lateral wall of screening pole (8 h 1).

3. The production, preparation and processing technology of the amino acid organic fertilizer as claimed in claim 1, which is characterized in that: dust removal case (4) inner wall upper end install direction pivot (4 a) through the bearing, install deflector (4 a 1) through the spline on direction pivot (4 a), deflector (4 a 1) slope is installed in dust removal case (4) and the lower extreme of deflector (4 a 1) is connected with the outer wall upper end of annular chamber (7 h) through guide spring (4 a 11), the up end crisscross of deflector (4 a 1) is provided with multiunit guide bar (4 a 12).

4. The production and preparation processing technology of the amino acid organic fertilizer as claimed in claim 1, characterized in that: the blanking mechanism (9) comprises a hinged support (9 a), a blanking cylinder (9 b), a fixing plate (9 c), a blanking rotating shaft (9 d), a blanking rotating rod (9 e), a telescopic rod (9 f), a bearing frame (9 g), a blanking spring (9 h) and a bearing seat (9 j), the hinged support (9 a) is installed in the middle of the lower end of the dust removal box (4), the blanking cylinder (9 b) is installed on the hinged support (9 a) in a rotating fit mode, the fixing plates (9 c) are symmetrically installed on the front and back of the lower end of the dust removal box (4) close to the edge position, the blanking rotating shaft (9 d) is installed between the fixing plates (9 c) through a bearing, and the blanking rotating rod (9 e) is installed in the middle of the blanking rotating shaft (9 d) through a spline, and the rotation end of blanking bull stick (9 e) is connected with the output shaft of blanking cylinder (9 b) through normal running fit's mode, telescopic link (9 f) are installed through the spline symmetry at the both ends of blanking pivot (9 d), bearing frame (9 g) are installed jointly to the removal end of telescopic link (9 f), bearing frame (9 g) are located the below of drying cylinder (8 b) and are connected through blanking spring (9 h) between bearing frame (9 g) and the drying cylinder (8 b), bearing seat (9 j) are installed to the up end of mounting plate (1), and bearing seat (9 j) are located the below of bearing frame (9 g).

5. The production, preparation and processing technology of the amino acid organic fertilizer as claimed in claim 4, which is characterized in that: the telescopic rod (9 f) is formed by splicing two sections of sliding rods with sections being regular polygons in a sliding fit mode, the two sections of sliding rods are connected through a telescopic spring (9 f 1), the fixed end of the telescopic rod (9 f) is installed on the blanking rotating shaft (9 d) through a spline, and the moving end of the telescopic rod (9 f) is installed on the bearing frame (9 g) through a spline.

6. The production, preparation and processing technology of the amino acid organic fertilizer as claimed in claim 4, which is characterized in that: bearing frame (9 g) be L shape structure, electro-magnet (9 g 1) are installed to the lower extreme symmetry of bearing frame (9 g), be provided with the inclined plane that highly inclines down gradually from a left side right side on bearing seat (9 j), and be provided with on the inclined plane with electro-magnet (9 g 1) matched with magnet hole (9 j 1).

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