NL2032289B1 - Conditioning device for aquatic feed production - Google Patents

Abstract

The present invention relates to the technical field of feed production, in particular to a conditioning device for aquatic feed, productiond An. output end, of a feeding device is arranged towards a top end of a rack. A stirring device is arranged in a 5 middle of the feeding device in a vertical state. A steam generation assembly is fixedly arranged on a lateral side of the top end of the rack. A water supply device is arranged on the lateral side of the rack in a vertical state and used for inputting a quantitative water source into the stirring device. A 10 discharging device is arranged on a lateral side of the stirring device and used for discharging stirred feed in the stirring device. According to the device, the feed can sufficiently absorb heat and water when uniformly stirred, and accordingly conditioning work can be better completed.

Description

P1431 /NLpd

CONDITIONING DEVICE FOR AQUATIC FEED PRODUCTION

TECHNICAL FIELD

The present invention relates to the technical field of feed production, in particular to a conditioning device for aquatic feed production.

BACKGROUND ART

In the prior art, the conditioning device is a main apparatus in the conditioning technology process and aims to carry out hy- drothermal conditioning on materials before granulation or puffing so as to make the materials sufficiently absorb heat, water and liquid, and accordingly, the materials satisfy the requirements needed by a granulation or puffing technology; but in the condi- tioning process of an existing conditioning device for aquatic feed production, most of feed and steam cannot be evenly mixed, the conditioning effect of the feed is influenced, the usage re- quirements cannot be well met, and thus, a conditioning device for aquatic feed production is required. According to the device, the feed can sufficiently absorb heat and water after uniformly stirred, and accordingly conditioning work can be better complet- ed.

SUMMARY

A technical solution is adopted by the present invention to solve the above technical problems:

A conditioning device for aquatic feed production includes: a rack; a feeding device fixedly arranged at a top end of the rack, wherein an output end of the feeding device is arranged towards the top end of the rack; a stirring device arranged in the middle of the feeding de- vice in a vertical state; a steam generation assembly fixedly installed on the rack and fixedly arranged on a lateral side of the top end of the rack;

a water supply device arranged on the lateral side of the rack in a vertical state and used for inputting a quantitative wa- ter source into the stirring device; and a discharging device arranged on a lateral side of the stir- ring device and used for discharging stirred feed in the stirring device.

Preferably, the feeding device includes: a first feeding mechanism fixedly installed on the rack and fixedly installed at the top end of the rack; a second feeding mechanism fixedly installed at the top end of the rack and surrounds the stirring device; a third feeding mechanism the same with the second feeding mechanism in structure, wherein the third feeding mechanism and the second feeding mechanism are arranged in a mirror symmetry manner; and quantitative discharging assemblies arranged at an output end of the second feeding mechanism and an output end of the third feeding mechanism in a pluggable manner.

Preferably, the first feeding mechanism includes: a first mounting frame fixedly installed on the stirring de- vice and fixedly installed at the top end of the stirring device; and a storage bin vertically arranged and fixedly arranged in the middle of the first mounting frame.

Preferably, the second feeding mechanism includes:

Preferably, the stirring device includes: a bearing frame arranged in a vertical state and arranged un- der the interior of the rack; a stirring barrel vertically arranged and fixedly arranged at a top end of a synchronous belt; a first stirring paddle rotaticnally arranged in the stirring barrel in a vertical state, wherein a lower end of the first stir- ring paddle penetrates through the bearing frame; a sealing plate covering the top of the stirring barrel, wherein a surface of the sealing plate is further provided with a plurality of rectangular through holes for feeding and water source receiving;

a servo motor arranged at a lower end of the stirring barrel in a vertical state, wherein an output shaft of the serve motor is arranged towards the stirring barrel; and the synchronous belt used for transmission connection of the output shaft of the servo motor and a lower end of the first stir- ring paddle.

Preferably, the first stirring paddle includes: a rotating shaft vertically arranged and rotationally ar- ranged in the stirring barrel; a spiral stirring blade surrounding the rotating shaft and spirally circling to a surface of the rotating shaft, wherein a surface of the spiral stirring blade is further provided with a plurality of circular through holes; a winding plate surrounding a peripheral surface of the spi- ral stirring blade, wherein the winding plate is perpendicular to an output end of the spiral stirring blade; and a stirring blade fixedly connected with the rotating shaft and installed at a lower end of the rotating shaft in a sleeving manner.

Preferably, the steam generation assembly includes: a steam generator arranged at the upper end of the rack; a spiral air outlet pipe in a spiral shape, wherein the spi- ral air outlet pipe is wound around the rotating shaft but avoids the spiral stirring blade; and an air inlet formed in the top of the rotating shaft and used for introducing steam into a pipeline;

Preferably, the water supply device includes: a supporting frame vertically arranged on the lateral side of the rack; a bearing plate fixedly connected with the supporting frame and close to a top end of the supporting frame; a water tank vertically arranged and fixedly arranged at the top end of the supporting frame; and a water pump placed at an upper end of the bearing plate.

Preferably, a third sliding groove and a fourth sliding groove are fixedly arranged on the lateral side of the stirring device in a vertical state, and a sliding plate is arranged in the middles of the third sliding groove and the fourth sliding groove in a sliding manner.

Compared with the prior art, the present invention has the beneficial effects: the present invention finishes feeding work on the feed through the feeding device, wherein the specific step includes that the worker pours the feed into the stirring device from the input end of the feeding device, and the feeding device throws needed conditioning agents with equal proportions into the stir- ring device; the present invention finishes stirring work on the feed through the stirring device and the water supply device, wherein the specific step includes that after placement is completed, the stirring device is driven to work so as to sufficiently stir the feed, steam is generated into the feed in cooperation with the steam generation assembly so that the feed stirring quality can be higher, and after the feed is evenly stirred in general, the water supply device is used for adding the water source to make the feed bonded or the water supply device is used for inputting the water source before the feed is prepared according to actual situations; and the present invention finishes discharging work on the stirred feed through the discharging device, wherein the specific step includes that after the feed is sufficiently mixed, the dis- charging device is used for discharging the feed in the stirring device 3 finally.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 and FIG.2 are two different perspectives of space dia- grams of the present invention;

FIG. 3 is a space diagram of a stirring device in a transpar- ent state of a stirring barrel of the present invention;

FIG. 4 is a space diagram of a water supply device of the present invention;

FIG. 5 is an elevation view of the stirring device of the present invention;

FIG. 6 is a space diagram of a first stirring paddle the pre-

sent invention;

FIG. 7 is a space diagram of a feeding device and the stir- ring device of the present invention;

FIG. 8 is a space diagram of a feeding device of the present 5 invention;

FIG. 9 is a space diagram of a second feeding device of the present invention; and

FIG. 10 is a space diagram of one quantitative discharging assembly of the present invention;

Marks in the drawings: 1- rack; 2-feeding device; 2a-first feeding mechanism; 2b-second feed- ing mechanism; 2c-third feeding mechanism; 2d-quantitative dis- charging assembly; 2al-first mounting frame; 2a2-storage box; 2bl- discharging box; 2b2-first mounting frame; 2b3-first arc plate; 2b4-supporting column; 2b5-sliding block; 2b6-arc sliding groove; 2b7-electric push rod; 2b8-second arc plate; 2dl-first sliding groove; 2d2-second sliding groove; 2d3-storage cup; 3-stirring device; 3a-stirring barrel; 3b-first stirring pad- dle; 3bl-rotating shaft; 3b2-spiral stirring blade; 3b3-circular through hole; 3b4-winding plate; 3b5-stirring blade; 3c-sealing plate; 3d-bearing frame; 3e-synchronous belt; 3f-servo motor; 4-steam generation assembly; 4a-steam generator; 4b-spiral air outlet pipe; 4c-air inlet; 5-water supply device; 5a-supporting frame; 5b-bearing plate;

Sc-water pump; 5d-water tank; 6-discharging device; 6a-third sliding groove; 6b-fourth sliding groove; and 6c-sliding plate.

DETAILED DESCRIPTION OF THE EMBODIMENTS

As shown in FIG. 1-FIG. 10, a conditioning device for aquatic feed production includes: a rack 1; a feeding device 2 fixedly arranged at a top end of the rack 1, wherein an output end of the feeding device 2 is arranged to- wards the top end of the rack 1; a stirring device 3 arranged in the middle of the feeding de-

vice 2 in a vertical state; a steam generation assembly 4 fixedly installed on the rack 1 and fixedly arranged on a lateral side of the top end of the rack 1; a water supply device 5 arranged on the lateral side of the rack 1 in a vertical state and used for inputting a quantitative water source into the stirring device 3; and a discharging device 6 arranged on a lateral side of the stirring device 3 and used for discharging stirred feed in the stirring device 3.

In the working state, a worker pours the feed into the stir- ring device 3 from the input end of the feeding device 2, the feeding device throws needed conditioning agents with equal pro- portions into the stirring device 3, and after placement is com- pleted, the stirring device 3 is driven to work so as to suffi- ciently stir the feed; steam is generated into the feed in cooper- ation with the steam generation assembly 4 so that the feed stir- ring quality can be higher; and after the feed is evenly stirred in general, the water supply device 5 is used for adding the water source to make the feed bonded or the water supply device 5 is used for inputting the water source before the feed is prepared according to actual situations, and after the feed is sufficiently mixed, the discharging device 6 is used for discharging the feed in the stirring device 3 finally.

As shown in FIG. 5 and FIG. 3, the feeding device 2 includes: a first feeding mechanism 2a fixedly installed on the rack 1 and fixedly installed at the top end of the rack 1; a second feeding mechanism 2b fixedly installed at the top end of the rack 1 and surrounds the stirring device 3; a third feeding mechanism 2c the same with the second feeding mechanism 2b in structure, wherein the third feeding mechanism 2c and the second feeding mechanism 2b are arranged in a mirror sym- metry manner; and quantitative discharging assemblies 2d arranged at an output end of the second feeding mechanism 2b and an output end of the third feeding mechanism 2c in a pluggable manner.

The first feeding mechanism 2a is used for feeding main dry feed into the stirring device 3, the second feeding mechanism 2b and the third feeding mechanism 2c are used for quantitatively de- livering conditioning agents needed by the feed, the quantitative discharging assemblies 2d are used for controlling the number of the conditioning agents delivered every time, and before a large number of conditioning agents need to be replaced, the quantita- tive discharging assemblies 2d can be replaced for control.

As shown in FIG. 8, the first feeding mechanism 2a includes: a first mounting frame 2al fixedly installed on the stirring device 3 and fixedly installed at the top end of the stirring de- vice 3; and a storage bin 2a2 vertically arranged and fixedly arranged in the middle of the first mounting frame 2al.

The storage bin 2a2 is used for throwing the feed, and the feed is directly poured from the input end of the storage bin 2a2 before stirring.

As shown in FIG. 9, the second feeding mechanism 2b includes: a first mounting frame 2b2 fixedly arranged on the rack 1 and fixedly arranged at the top end of the rack 1, wherein the upper end of the first mounting frame 2b2 is further fixedly provided with a first arc plate 2b3, one end of the first arc plate 2b3 is close to the stirring device 3, an end portion of one end, close to the stirring device 3, of the first arc plate 2b3 is further provided with a circular through hole, an upper end of the first arc plate 2b3 is further provided with an arc sliding groove 2b6, the arc sliding groove 2b6 is formed in the other end away from the stirring device 3, a second arc plate 2b8 is the same with the first arc plate 2b3 in structure and is arranged over the first arc plate 2b3, an end, close to the stirring device 3, of the sec- ond arc plate 2b8 is also provided with a circular through hole, the quantitative discharging assemblies 2d are arranged under the circular through holes, the other end, away from the stirring de- vice 3, of the second arc plate 2b8 is provided with vertically- arranged supporting columns 2b4, the multiple supporting columns 2b4 are arranged, lower ends of all the supporting columns 2b4 are fixedly provided with sliding blocks 2b5, the supporting columns 2b4 are in sliding connection with the arc sliding groove 2b6 through the sliding blocks 2b5, the top end of the second arc plate 2b8 is further provided with a vertically-arranged discharg- ing box 2b1, an output end of the discharging box 2b1 abuts against the surface of the top end of the second arc plate 2b8, a non-work end of an electric push rod 2b7 is hinged to the first mounting frame 2b2, and the other end of the electric push rod 2b7 is hinged to the supporting columns 2b4.

In the working state, when the conditioning agents need to be automatically and quantitatively discharged, the electric push rod 2b7 is driven to work and pushes the supporting column 2b4 hinged to the output end to drive the first arc plate 2b3 in the radian direction of the arc sliding groove 2b6 to be pushed towards the stirring device 3, so that the conditioning agents in the quanti- tative discharging assemblies 2d fall into the stirring device through the circular through hole formed in the end portion of the first arc plate 2b3, and after material falling, the electric push rod 2b7 pulls the second arc plate 2b8 back, in the pull-back pro- cess of the second arc plate 2b8, the bottom faces of the quanti- tative discharging assemblies 2d are driven to be scratched to the position under the discharging box 2bl along the upper end of the first arc plate 2b3 while the first arc plate 2b3 drives the quan- titative discharging assemblies 2d to move to the output end of the discharging box 2a so that the circular through hole formed in the end portion of the first arc plate 2b3 can be exposed to the position under the output end of the discharging box 2bl, the dis- charging box 2bl carries out automatic material falling on the in- teriors of the quantitative discharging assemblies 2d, and when the conditioning agents need to be thrown, the electric push rod 2b7 is driven to push the first arc plate 2b3.

As shown in FIG. 10, each quantitative discharging assembly includes: a first sliding groove 2dl, a second sliding groove 2d2 and a cone-barrel-shaped storage cup 2d3, wherein the second sliding groove 2d2 is fixedly arranged at the lower end of the second arc plate 2b8, the first sliding groove 2dl and the second sliding groove 2d2 are formed in the two sides of the circular through hole in the end portion of the second arc plate 2b8, one end of the storage cup 2d3 is arranged in the middles of the first slid- ing groove 2d1 and the second sliding groove 2d2 in a sliding man- ner, the other end of the storage cup 2d3 abuts against the upper end of the first arc plate 2d, different sizes of storage cups 2d3 can be automatically re- placed according to each-time feed actual situations, and when re- placement is needed, a worker only needs to hold the storage cup 2d3 by hand to directly draw the storage cup 2d3 from the middles of the first sliding groove 2d1 and the second sliding groove 2d2 and then takes a needed new storage cup 2d3 for replacement.

As shown in FIG. 5, the stirring device 3 includes: a bearing frame 3d arranged in a vertical state and arranged under the interior of the rack 1; a stirring barrel 3a vertically arranged and fixedly arranged at a top end of a synchronous belt 3e; a first stirring paddle 3b rotationally arranged in the stir- ring barrel 3a in a vertical state, wherein a lower end of the first stirring paddle 3b penetrates through the bearing frame 3d; a sealing plate 3c covering the top of the stirring barrel 3a, wherein a surface of the sealing plate 3c is further provided with a plurality of rectangular through holes for feeding and wa- ter source receiving; a servo motor 3f arranged at a lower end of the stirring bar- rel 3a in a vertical state, wherein an output shaft of the servo motor 3f is arranged towards the stirring barrel 3a; the synchronous belt 3e used for transmission connection of the output shaft of the servo motor 3f and a lower end of the first stirring paddle 3b.

In the working state, the synchronous belt 3e is used for transmission connection of the output shaft of the servo motor 3f to drive the first stirring paddle 3b to rotate in the stirring barrel 3a, and accordingly the feed in the stirring barrel 3a is evenly stirred.

As shown in FIG. 6, the first stirring paddle 3b includes: a rotating shaft 3bl vertically arranged and rotationally ar- ranged in the stirring barrel 3a; a spiral stirring blade 3b2 surrounding the rotating shaft

3bl and spirally circling to a surface of the rotating shaft 3bl, wherein a surface of the spiral stirring blade 3b2 is further pro- vided with a plurality of circular through holes 3b3; a winding plate 3b4 surrounding a peripheral surface of the spiral stirring blade 3b2, wherein the winding plate 3b4 is per- pendicular to an output end of the spiral stirring blade 3b2; and a stirring blade 3bb fixedly connected with the rotating shaft 3bl and installed at a lower end of the rotating shaft 3bl in a sleeving manner.

In the working state, the rotating shaft 3bl is driven by the synchronous belt 3e to rotate in the stirring barrel 3a, the spi- ral stirring blade 3b2 spirally conveys the feed to the top end of the rotating shaft 3bl, and when the feed is spirally conveyed, the feed penetrates through the circular through holes 3b3 to freely fall down, the feed not penetrating through the circular through holes 3b3 overflows out of the spiral stirring blade 3b2 when rotating to the top of the rotating shaft 3bl and is scat- tered towards the bottom of the stirring barrel 3a in a fountain manner, the winding plate 3b4 can better assist the spiral stir- ring blade 3b2 in feed spinning, the stirring blade 3b5 rotates together with the rotating shaft 3bl under rotation of the rotat- ing shaft 3bl so that the feed not spun up at the bottom of the stirring barrel 3a is stirred.

As shown in FIG. 3, the steam generation assembly includes: a steam generator 4a arranged at the upper end of the rack 1; a spiral air outlet pipe 4b in a spiral shape, wherein the spiral air outlet pipe 4b is wound around the rotating shaft 3bl but avoids the spiral stirring blade 3b2; and an air inlet 4c formed in the top of the rotating shaft 3bl and used for introducing steam into a pipeline;

In the working state, the steam generator 4a generates steam to convey the steam into the air inlet 4c through a hose, the steam is conveyed into the spiral air outlet pipe 4b from the air inlet 4c, and the spiral air outlet pipe 4b is used for evenly conveying the steam to the feed.

As shown in FIG. 4, the water supply device 5 includes: a supporting frame 5a vertically arranged on the lateral side of the rack 1; a bearing plate bb fixedly connected with the supporting frame 5a and close to a top end of the supporting frame 5a; a water tank 5d vertically arranged and fixedly arranged at the top end of the supporting frame 5a; and a water pump 5c placed at an upper end of the bearing plate

Sb.

In the working state, the water pump 5c is driven to suck the water source in the water tank 5d through a hose so as to quanti- tatively output the water source into the stirring device 3 so that automatic water injection work can be completed.

As shown in FIG. 5, the discharging device 6 includes: a third sliding groove 6a, a fourth sliding groove 6b and a sliding plate 6c, wherein the third sliding groove 6a and the fourth sliding groove 6b are fixedly arranged on the lateral side of the stirring device 3 in a vertical state, and the sliding plate 6c is arranged in the middles of the third sliding groove 6a and the fourth sliding groove 6b in a sliding manner.

When the stirred feed needs to be discharged, the worker man- ually pulls up an upper end of the sliding plate 6c, so that a discharging port of the stirring device 3 is opened to make the feed freely fall into a collecting box, and after discharging, the worker presses the sliding plate 6c to make the sliding plate éc reset.

A working principle of the present invention: step 1: the worker pours the feed into the stirring device 3 from the input end of the feeding device 2, and the feeding device throws needed conditioning agents with equal proportions into the stirring device 3; step 2: after placement is completed, the stirring device 3 is driven to work so as to sufficiently stir the feed, steam is generated into the feed in cooperation with the steam generation assembly 4 so that the feed stirring quality can be higher, and after the feed is evenly stirred in general, the water supply de- vice 5 is used for adding the water source to make the feed bonded or the water supply device 5 is used for inputting the water source before the feed is prepared according to actual situations;

and step 3: after the feed is sufficiently mixed, the discharging device 6 is used for discharging the feed in the stirring device 3 finally.

Claims (8)

CONCLUSIONS A conditioning device for the production of aquatic feed, comprising: a rack (1); a feeding device (2) fixedly arranged at an upper end of the rack (1), an output end of the feeding device (2) being arranged towards the upper end of the rack (1); a stirring device (3) arranged in a vertical position in the center of the feeding device (2); a steam generating assembly (4) fixedly installed on the rack (1) and fixedly mounted on a side of the upper end of the rack (1); a water supply device (5) arranged in a vertical state on the side of the rack (1) and used for introducing a quantitative water source into the stirring device (3); and a discharge device (6) arranged on a side of the stirring device (3), which is used for discharging stirred feed in the stirring device (3). A conditioning device for the production of aquatic feed according to claim 1, wherein the feeding device (2) comprises: a first feeding mechanism (2a) fixedly installed on the rack (1) and fixedly installed at the upper end of the rack ( 1); a second feeding mechanism (2b) fixedly installed at the upper end of the rack (1) and surrounding the agitator (3); a third feeding mechanism (2c) having the same structure as the second feeding mechanism (2b), wherein the third feeding mechanism (2c) and the second feeding mechanism (2b) are arranged mirror-symmetrically; and quantitative discharge assemblies (2d) arranged in a pluggable manner at an output end of the second supply mechanism anism (2b) and an output end of the third feeding mechanism (2c). A conditioning device for the production of aquatic feed according to claim 2, wherein the first feeding mechanism (2a) comprises: a first mounting frame (2a1) fixedly installed on the agitator (3) and fixedly installed at the upper end of the stirring device (3); and a storage bin (2a2) arranged vertically and fixedly located in the center of the first mounting frame (2a1). Conditioning device for the production of aquatic feed according to claim 1, wherein the stirring device (3) comprises: a support frame (3d) arranged in a vertical position and arranged under the interior of the rack (1); a stirring vessel (3a) arranged in a vertical condition and fixedly attached to an upper end of a synchronous belt (3e); a first rudder blade (3b) rotatably arranged in a vertical state in the rudder vessel (3a), a lower end of the first rudder blade (3b) penetrating the bearing frame (3d); a sealing plate (3c) covering the top of the stirring vessel (3a), a surface of the sealing plate (3c) further being provided with a plurality of rectangular through holes for supplying and receiving the water source; a servo motor (3f) arranged in a vertical state at a lower end of the stirring vessel (3a), an output shaft of the servo motor (3f) being arranged towards the stirring vessel (3a); the synchronous belt (3e) used for the transmission connection of the servo motor output shaft (3f) and a lower end of the first rudder vane (3b). The conditioning device for the production of aquatic feed according to claim 4, wherein the first stirring blade (3b) comprises: a rotating shaft (3bl) arranged vertically and rotatingly arranged in the stirring vessel (3a); a spiral rudder blade (3b2) surrounding the rotating shaft (3bl) and spirally circling to a surface of the rotating shaft {3bl), a surface of the spiral rudder blade (3b2) further being provided with a plurality of circular through holes (3b3) ; a wrapper plate (3b4) surrounding a peripheral surface of the spiral rudder blade (3b2), the wrapper plate (3b4) being perpendicular to an output end of the spiral rudder blade (3b2); and a rudder blade (3b5) fixedly connected to the rotating shaft (3bl) and installed in an enveloping manner at a lower end of the rotating shaft (3bl). A conditioning device for the production of aquatic feed according to claim 5, wherein the steam generating assembly (4) comprises: a steam generator (4a) arranged at the upper end of the rack (1); a spiral air exhaust pipe (4b) in a spiral shape, wherein the spiral air exhaust pipe (4b) is wrapped around the rotating shaft (3bl) but avoids the spiral rudder blade (3b2); and an air inlet (4c) formed in the top of the rotating shaft (3bl) and used for introducing steam into a pipeline. The conditioning device for the production of aquatic feed according to claim 1, wherein the water supply device (5) comprises: a support frame (ba) arranged vertically on the side of the rack (1); a support plate (bb) fixedly connected to the support frame (ba) and near an upper end of the support frame (5a); a water tank (5d) arranged vertically and fixedly mounted at the upper end of the support frame (5a); and a water pump (5c) located at an upper end of the bearing plate (5b). The conditioning device for the production of aquatic feed according to claim 1, wherein the discharge device (6) comprises: a third sliding groove (6a), a fourth sliding groove (6b) and a sliding plate (6c), the third sliding groove (6a) and the fourth sliding groove (6b) are fixedly attached to the side of the rudder (3) in a vertical condition, and the sliding plate (6c) is in a sliding manner in the middle of the third sliding groove (6a) and the fourth sliding groove (6b) applied.