KR20180137367A - Feedstuff supply device able to uniform mixing of additives - Google Patents

Abstract

The present invention relates to a feed supplying apparatus capable of uniformly mixing an additive. More specifically, the feed supplying apparatus capable of uniformly mixing an additive comprises: a feed supplying means to supply stored feed to each feed box through an installed supply pipe; a feed pressing means to press and crush the supplied feed and supply the crushed feed to the feed supplying means; a feed turning means to selectively turn the feed transferred by the feed supplying means to supply the feed to the feed pressing means; and an additional supplying means to uniformly supply an additional to the feed transferred by the feed supplying means. Accordingly, the additive is uniformly supplied to the feed supplied for growth of livestock such that a mixing ratio between the feed and the additive is able to be uniformly maintained, and thus the constantly mixed additive is able to be supplied to each feed box with the feed.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a feeding device capable of uniformly mixing additives,

More particularly, the present invention relates to a feeding device, and more particularly, to a feeding device which feeds a feed to each food container, which is compressed and crushed, uniformly supplies the feed to the feed material, The present invention relates to a feeding device capable of improving the efficiency and improving the growth of livestock as well as reducing the amount of feed and additives used so that the feed efficiency can be improved.

Generally, in terms of livestock breeding, there is a tendency to increase in volume in response to a competitive landscape. Massive breeding is necessarily accompanied by mechanization and automation, and an automatic feeding system is also introduced to feed livestock.

Such a conventional automatic feeding system is composed of a frame structure in which a cylinder is operated by a detection sensor to open and close the door, and a feeder that automatically feeds the feed by a detection sensor, as disclosed in Japanese Utility Model Registration No. 20-0143791 .

Here, the livestock can not digest 100% of the feed. Especially, in the case of pigs, the digestive organ is short, so 40% of the feed consumed is excreted and the amount of feed to be eaten per day is determined. 40% more.

Along with this, various additives are supplied with feed to support development of livestock and cope with various diseases.

However, the additive is fed to the fed feed and fed to the feed bottle together, but the feed rate of the additive is not constant and the mixing ratio with the feed is very low.

This problem is caused when the livestock ingest the feed, the livestock additive is consumed by only a part of the livestock, and the cost is increased due to the addition of the additive or the inoculation with the use of the injection or the like.

Accordingly, there is an urgent need to develop a technology capable of improving the digestibility of livestock and improving the mixing ratio of the feed with feed additives by uniformly adding additives.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a feed supply device for feeding feedstuffs stored in a feed pipe through a feed pipe, A feed pouring means for selectively turning the feed fed by the feed feeding means and feeding the fed feed to the feed pressurizing means, and a feeding device for uniformly feeding the feed to the feed fed by the feed feeding means The feed ratio of the feed and the additive can be maintained uniformly by feeding the additives uniformly to the feed supplied for the growth of the livestock including the feed additive for the feed, It is an object of the present invention to provide a feeding device capable of uniformly mixing feed additives The enemy.

In order to accomplish the above object, the present invention provides a method for feeding a feed to a feeder, comprising: feeding a feeder for feeding the feedstuff stored through a feed pipe to each feeder; feeding the feeder to feed the feeder to the feeder; Feed swirling means for selectively turning the feed conveyed by the feed means to supply the feed to the feed compression means and an additive feeding means for uniformly feeding the feed to the feed conveyed by the feed feeding means .

Preferably, the feeding means includes a silo for storing feed, a feed discharging portion provided at the lower end of the silo for discharging the sample uniformly, and a feeder for feeding the feed discharged from the feed discharging portion to each feed hopper A feeding disk that is rotated at an infinite orbit along one direction along the inside of the feeding pipe, a feeding disk which is provided at regular intervals in the feeding wire and is moved along the inside of the feeding pipe to feed the feed to each feeding bucket, And a supply driving unit for rotating the wire.

The feed pipe is formed with an inflow hole through which the feed compressed by the feed compressing means is introduced. The feed compressing means has a feed press-fit insertion portion formed at the upper end portion, a feed-discharge portion formed at the lower end portion, And a pair of pressing rollers rotatably connected to the squeezing space portion of the body housing so as to be rotatable in mutual contact with each other, And a crushing driving unit provided in the body housing for rotating a pair of pressing rollers of the crushing unit in mutual directions, wherein the crushing unit rotates the crushing feeder Is supplied to the feed press-feeding part of the body housing and is compressed and crushed by a pair of press rollers, And discharges the crushed feed smaller than the particles of the feed supplied by the feed supply means as it is discharged through the feed crush discharge unit.

In addition, the feed pressurized discharge unit includes a pressurized discharge hopper formed at an oblique inclination such that both sides of the pressurized discharge unit are narrowed toward the lower side, a seating plate formed at a lower end of the pressurized discharge hopper for receiving the supply pipe formed with the inflow hole, And a compressed feed outlet formed in the discharge hopper and the seating plate to supply feed compressed to the inlet of the feed pipe.

The pressing unit includes a pair of pressing rollers rotatably disposed in contact with the body housing, and a pair of pressing rollers provided at the ends of the pressing rollers. When one of the pressing rollers is rotated by the driving unit, And a helical compression groove formed along the outer periphery of at least one of the pair of compression rollers.

The feed pivoting means may include a turning pipe for feeding the feed of the feed pipe to the feed compressing means, a turning connection portion for selectively feeding the feed of the feed pipe to the turning pipe, To the feed pressurizing means.

The swivel pipe includes a first swivel pipe formed horizontally adjacent to the supply pipe, a second swivel pipe whose lower end communicates with one end of the first swivel pipe and is erected upward, And a third turning pipe provided at an inclined position so that a lower end of the feed pipe is positioned above the feed pressing means and feeding the feed conveyed along the second turning pipe to the feed pressurizing means.

The swivel connection portion may include a connection discharge hole formed at a lower portion of the supply pipe for discharging the feed conveyed along the supply pipe, a connection discharge hole formed above the one end of the first swivel pipe, And a connection opening and closing door for opening and closing the connection inflow hole. The connection opening and closing door may be formed by a plurality of openings.

And a connection driving unit for operating the connection opening / closing unit.

The swivel drive unit may further include a first swivel drive unit for feeding the feedstock fed to the first swivel pipe to the second swivel pipe and a second swivel drive unit for feeding the feedstuff fed to the second swivel pipe to the third swivel pipe And feeds to the feed compression means as the feed slid down along the third swivel pipe.

Each of the swivel drive units includes a swivel screw rotatably provided in the swivel pipe, and a swivel drive motor for rotating the swivel screw.

The additive supply means includes an additive mixer having a mixing space therein, a stationary frame for allowing the additive mixer to be rotatable, an additive mixing unit for mixing the additive mixed in the additive mixer with the feed pipe of the feeder, And an additive mixing portion for mixing the additive introduced by rotating the additive mixer in the vertical direction.

The additive mixer includes an additive mixer body having a mixing space formed therein and a lower end thereof narrowly formed toward the lower side, an additive mixing lid provided at an upper end of the additive mixer body to close the mixing space, And an additive mixing door provided on a part of the additive mixing lid to close and close the mixing space, and to close the mixing space when the liquid is closed.

Also, the additive mixing body may include an inner body forming a mixing space portion therein, an outer body spaced apart from the inner body by a predetermined distance, and an outer body formed between the inner body and the outer body, And a heat insulating layer for holding the heat insulating layer.

The insulating layer is formed by foaming urethane.

The inner surface of the mixed space portion of the additive mixing body further includes an antistatic layer to prevent the generation of static electricity.

The antistatic layer is coated with one of polyurethane (PC), polycarbonate (PC), and polypropylene (PP).

Further, the additive mixing cylinder further includes a cooling section for maintaining the temperature of the mixing space section at a low temperature.

The cooling unit may include a refrigerant pipe for surrounding the outer surface of the inner body so as to circulate the refrigerant for cooling, and a refrigerant pipe for supplying refrigerant to the refrigerant pipe, And a cooling air conditioning unit for supplying the low temperature state as the expansion process is performed.

The additive supply unit may include a rotation rod disposed in the mixing space and rotatably installed in the additive mixing lid, a supply screw unit provided at the lower end of the rotation rod and rotated in the same direction, An additive discharge portion provided at a lower end of the additive mixing body so as to contact the lower end surface of the supply screw portion and a stirring portion for stirring the additive discharge portion and the additive discharge portion for stirring the additive, And an additive driver provided in the mixing lid.

The supply screw portion may include a screw rod connected to the lower end of the rotating rod, a first screw formed along the outer periphery of the screw rod, a spiral shape along the outer periphery of the screw rod, and a lower end, A second screw formed to be positioned in a direction opposite to a lower end of the first screw and a lower end of the first screw and a lower end of the second screw so that the upper surface of the additive discharge portion is scraped to transfer the additive to the additive discharge hole Wherein the additive is transported to one side and the other side of the feed scraper by the first screw and the second screw, respectively.

The stirring vane may include a first stirring blade provided at a lower end of the rotating rod so as to correspond to an inner surface of a lower end portion of the mixing space portion and stirring an additive, and a second stirring blade provided at an intermediate portion of the rotating rod, , ≪ / RTI >

The lower end of the rotation bar further includes a dispersion guide for moving the additive in an inner side direction of the mixing space.

In addition, the dispersion guide is inclined downward toward the outer side from the central portion provided in the rotation bar.

And a vibration unit that generates vibration in the rotation bar, thereby preventing the additives from being accumulated in the first screw and the second screw.

The vibrating portion may include a vibration fixing bracket provided on the additive mixing body, a vibration striking portion provided at one end of the vibration fixing bracket so as to be rotatable and the other end striking the rotation shaft, And the other end portion of the vibration striking portion that is pressed by the vibration pressing portion rises over the other end of the swash plate, Includes the strike zone, to make it.

The striking and moving part includes a movable pupil formed so as to be orthogonal to the longitudinal direction of the swing rod, a movable attachment for moving along the movable pupil, a movable part provided rotatably in the movable attachment part for moving the other end of the vibration striking part A roller, and a movable control unit for fixing the movable mandrel to the rotation bar and adjusting the protruding length.

Further, the supply pipe is provided with a second inflow hole through which the additive is introduced by the additive supply means, and the additive discharge portion has a first additive supply passage communicating with the second inflow hole, A second discharge block having a first discharge block and a second additive supply passage communicating with the first additive supply passage and provided at a lower end of the additive mixture body so as to be positioned in the first discharge block, An additive opening and closing lever and a discharge opening and closing lever corresponding to the additive discharge hole and having an additive discharge hole for communicating the second additive supply passage and being fixed between the second discharge block and the additive mixture body, And a discharge opening / closing plate rotatably provided in the discharge block, wherein the discharge opening / closing plate is rotated using the discharge opening / closing lever, and the overlapping of the additive opening / As adjust the degree, to control the discharge rate of the additive.

And the additive discharge hole is formed only on one side of an extension line passing through the central portion of the overlay parallel to the surface, and the additive discharge hole is formed only on one side portion of the overlay, The additive discharged on one side of the supply scraper by the screw is accumulated on one side of the additive, and the additive accumulated on the other side is discharged through the additive discharge hole, and the additive is continuously discharged Discharge constantly.

The additive mixing unit may include a tubular rotation bar formed on both sides of the fixed frame so as to be rotatably installed in the fixed frame, a seaming step of vertically extending in the upright direction, A mixing block disposed between the stationary frame and the additive mixing cylinder so as to be rotatable so as to allow the tubular rotation rod to be rotatable; And a mixing driving unit for rotating at least one of the rod-guiding ball, the elevating lever for rotating the mixing block, and the barrel-rotating rod, the mixing block being rotated when the elevating lever is rotated, As the rotor rotates, the tubular bar is moved upward along the seam opening At the same time, the rotation guide rod is moved along the rod guide hole to rotate the additive mixing cylinder by the mixing drive unit in a state where the additive mixing cylinder equipped with the second discharge block is separated from the first discharge block, .

The rotation bar may include a first rotation bar having an upper end adjacent to the additive mixing lid and a lower end positioned at a lower end of the mixing space, and an upper end surrounding the upper end of the first rotation bar And a lower end portion disposed adjacent to an intermediate portion of the first rotation bar, and a rotation bearing provided between the first rotation bar and the second rotation bar and rotatable with respect to each other.

The first stirring blade is provided at a lower end of the first rotating rod, the second stirring blade is provided at a lower end of the second rotating rod, and the additive driving unit is provided with at least one of the first rotating rod and the second rotating rod .

And a mixing control unit for controlling the additive driving unit and the mixing driving unit, and when the second discharging block installed in the additive mixing cylinder is seated on the first discharging block, the mixing controller controls the additive driving unit A first mode in which the additive is discharged by rotating the first rotating rod and the first stirring blade, and a second mode in which the additive driving unit is operated when the second discharge block installed in the additive mixing cylinder is seated in the first discharge block A second mode in which the additive is mixed by rotating the second rotary bar and the second stirring vane and a second mode in which the first rotary bar and the first stirring vane are rotated to discharge the additive, A third mode in which the additive is mixed as the additive mixing cylinder is rotated up and down by operating the mixing drive unit, When the additive mixing cylinder is separated upward, the additive mixing cylinder is rotated in the vertical direction by operating the mixing drive unit, the additives are mixed, and the additive drive unit is operated, And a fourth mode in which the additives are mixed as they are rotated.

As described above, according to the feed supply apparatus capable of uniformly mixing the additives according to the present invention, the additives are uniformly supplied to the feed supplied for the growth of livestock, It is a very useful and effective invention which makes it possible to feed a constantly mixed additive with each feed can with feed.

1 is a view showing a feed device according to the present invention,
2 is a view showing the feeding means according to the present invention,
FIG. 3 is a view showing a feed pressing means according to the present invention,
FIG. 4 is a view showing a pressing part according to the present invention,
Fig. 5 is a view showing a feed pivoting means according to the present invention,
6 is a view showing an additive supply means according to the present invention,
7 is a view showing an additive supply unit according to the present invention,
8 is a view showing a supply screw portion and an additive discharge portion according to the present invention,
9 is a view showing a state in which a dispersion guide is further provided in the supply screw portion according to the present invention,
10 is a view showing a vibration part according to the present invention,
11 is a view showing an additive mixing part according to the present invention.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The following detailed description, together with the accompanying drawings, is intended to illustrate exemplary embodiments of the invention and is not intended to represent the only embodiments in which the invention may be practiced. The following detailed description includes specific details in order to provide a thorough understanding of the present invention. However, those skilled in the art will appreciate that the present invention may be practiced without these specific details.

In some instances, well-known structures and devices may be omitted or may be shown in block diagram form, centering on the core functionality of each structure and device, to avoid obscuring the concepts of the present invention.

Throughout the specification, when an element is referred to as "comprising" or " including ", it is meant that the element does not exclude other elements, do. Further, the term "part" described in the specification means a unit for processing at least one function or operation. Also, the terms " a or ", "one "," the ", and the like are synonyms in the context of describing the invention (particularly in the context of the following claims) May be used in a sense including both singular and plural, unless the context clearly dictates otherwise.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions in the embodiments of the present invention, which may vary depending on the intention of the user, the intention or the custom of the operator. Therefore, the definition should be based on the contents throughout this specification.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a view showing a feed feeding device according to the present invention, FIG. 2 is a view showing a feed feeding means according to the present invention, FIG. 3 is a view showing a feed pressing means according to the present invention, FIG. 5 is a view showing a feed pivoting means according to the present invention, FIG. 6 is a view showing an additive feeding means according to the present invention, and FIG. FIG. 8 is a view showing a feed screw part and an additive feed part according to the present invention, and FIG. 9 is a view showing a state where a feed screw part according to the present invention is further provided with a dispersion guide FIG. 10 is a view showing a vibrating part according to the present invention, and FIG. 11 is a view showing an additive mixing part according to the present invention.

As shown in the drawing, a feeder 10 capable of uniformly mixing additives is composed of a feeder 100, a feeder presser 200, a feeder pivoting device 300, and an additive feeder 400 do.

The feeding means 100 is provided to feed the stored feed through each feeding pipe 130 to each feeding barrel.

The feed compression means 200 is provided for crushing and crushing the supplied feed and then feeding it to the feed supply means 100.

The feed pivoting means 300 is provided for selectively turning the feed fed by the feed feeding means 100 and feeding it to the feed pressing means 200.

In addition, the additive feeding means 400 is provided for uniformly feeding the feed to the feed conveyed by the feed feeding means 100.

According to this feeder 10, the additive can be uniformly supplied to the feed conveyed by the feeder 100, and the mixing ratio with the feed can be improved.

When the additives are uniformly mixed with the feed and supplied to each feeder, the ingestion rate of the livestock can be improved and the growth can be improved.

2, the feed unit 100 includes a silo 110, a feed discharger 120, a feed pipe 130, a feed wire 140, a feed disk 150, (160).

The silo 110 stores feeds and the feed discharger 120 is provided at the lower end of the silo 110 to discharge the sample uniformly.

The feed pipe 130 is provided to feed the feed discharged from the feed discharger 120 to each feeder.

The supply wire 140 is rotated in an endless track in one direction along the inside of the supply pipe 130.

The feed discs 150 are provided at predetermined intervals on the feed wire 140 and are moved along the inside of the feed pipe 130 to feed the feed to each feeder.

The supply driving unit 160 is provided for rotating the supply wire 140.

Here, the supply pipe 130 is formed with an inflow hole 132 through which the feed compressed by the feed compressing means 200 flows.

As shown in FIG. 3, the feed compressing means 200 includes a body housing 210, a crimping portion 220, and a crimping driving portion 230.

The body housing 210 is formed with a feed press-fit insertion portion 214 at an upper end thereof and a feed press-fit discharge portion 216 at a lower end thereof to communicate the feed press-fit insertion portion 214 and the feed- A compression space 212 is formed in the interior of the cylinder.

The pair of pressing rollers 222 are rotatably provided in the pressing space 212 of the body housing 210 so that the pair of pressing rollers 222 are rotatable in mutual contact directions, Feeds are crushed and crushed.

The squeezing drive unit 230 is provided in the body housing 210 to rotate the pair of squeeze rollers 222 of the squeezing unit 220 in mutually opposite directions.

When the operation of the feed compression means 200 is examined, the feed pivoted by the feed pivot means 300 is fed to the feed press-fit insertion portion 214 of the body housing 210, And discharges the crushed feed smaller than the particles of the feed supplied by the feed supply means 100 as it is discharged through the feed crush discharge unit 216. [

Thus, the digestive power of the livestock fed the feed can be improved, and the feed consumption can be reduced.

To this end, the feed squeeze out portion 216 comprises a squeeze discharge hopper 2162, a seating plate 2164, and a compressed feed outlet 2166.

The pressurized discharge hopper 2162 is formed so as to be inclined so that both sides of the pressurized discharge hopper 2162 become narrower toward the center as it goes downward.

The seating plate 2164 is formed at the lower end of the pressurized discharge hopper 2162 so that the supply pipe 130 formed with the inflow hole 132 is seated.

The compressed feed outlet 2166 is formed in the compression discharge hopper 2162 and the seating plate 2164 so as to communicate with the compression space 212 and feed the compressed food into the inlet hole 132 of the supply pipe 130 .

4, the crimping portion 220 is composed of a crimping roller 222, a crimping gear 224, and a crimping groove 226. As shown in FIG.

The pair of pressing rollers 222 are rotatably provided in pairs in the body housing 210.

When one of the pressing rollers is rotated by the supply driving unit 160 as the pressing gears 224 are provided at the ends of the pressing rollers 222 and are engaged with each other, .

The pressing groove 226 is formed in a spiral shape along the outer periphery of any one of the pair of pressing rollers 222.

As shown in FIG. 5, the feed pivoting means 300 includes a swivel pipe 310, a swivel connection portion 320, and a swivel driving portion 330.

The orbiting pipe 310 is provided for feeding the feed of the feed pipe 130 to the feed compression means 200.

The swivel connection portion 320 is provided to selectively feed the feed of the feed pipe 130 to the orbiting pipe 310.

The swivel drive unit 330 is provided to feed the feed introduced into the swivel pipe 310 to the feed pressurizing means 200.

Here, the orbiting pipe 310 is composed of a first swivel pipe 312, a second swivel pipe 314, and a third swivel pipe 316.

The first turning pipe 312 is formed horizontally adjacent to the supply pipe 130 and the lower end of the second turning pipe 314 is communicated with one end of the first turning pipe 312 and is raised upward.

The third swivel pipe 316 is sloped so that the upper end thereof communicates with the upper end of the second swivel pipe 314 and the lower end of the third swivel pipe 316 is positioned above the feed pressurizing means 200 and is conveyed along the second swivel pipe 314 Feed feed means 200 to feed press means 200.

The swivel connection portion 320 includes a connection vent 322, a connection inflow hole 324, a connection frame 326, and a connection opening / closing door 328.

The connection discharge hole 322 is formed on the lower side of the supply pipe 130 so as to discharge the feed conveyed along the supply pipe 130.

The connection inflow hole 324 is formed above the one end of the first swing pipe 312 to feed the feed.

The connection frame 326 is formed therein with a connection path 327 for connecting the connection discharge hole 322 and the connection inflow hole 324.

Closing door 328 is provided for opening and closing the connection inflow hole 324 and when the connection inflow hole 324 is opened by operating the connection opening and closing door 328, The feed is introduced along the path 327.

At this time, a connection driving part 329 for operating the connection opening / closing door 328 is further included.

The connection driving unit 329 slides the connection opening / closing door 328 with a cylinder or a motor, thereby automatically opening / closing the connection inflow hole 324.

The swivel drive unit 330 includes a first swivel drive unit 332 and a second swivel drive unit 334.

The first swivel drive unit 332 is provided to feed the feedstock fed to the first swivel pipe 312 to the second swivel pipe 314.

The second swivel drive unit 334 is provided to feed the feedstock fed to the second swivel pipe 314 to the third swivel pipe 316.

The feed which has flowed into the third turning pipe 316 slips along the third turning pipe 316 and is supplied to the feed pressing means 200 as it drops.

Here, each of the swivel drive units 332 and 334 is composed of the swivel screws 3322 and 3342 and the swivel drive motors 3324 and 3344.

The orbiting screws 3322 and 3342 are rotatably provided in the corresponding swivel pipes 312 and 322 and the swivel drive motors 3324 and 3344 are provided to rotate the swivel screws 3322 and 3342.

As shown in FIG. 6, the additive supply unit 400 includes an additive mixer 410, a fixed frame 420, an additive supply unit 430, and an additive mixer 440.

The additive mixing cylinder 410 has a mixing space 411 formed therein.

Further, the stationary frame 420 is provided so that the additive mixing cylinder 410 is rotatably installed.

The additive supply unit 430 is provided to uniformly supply the mixed additive in the additive mixer 410 to the feed pipe 130 of the feeder 100.

The additive mixer 440 rotates the additive mixer 410 vertically to mix the introduced additive.

The additive mixing vessel 410 is composed of an additive mixing body 412, an additive mixing lid 414, and an additive mixing door 416.

The additive mixing body 412 has a mixing space 411 formed therein, and the lower end thereof is narrowed toward the lower side toward the center.

In addition, the additive mixing lid 414 is provided at the upper end of the additive mixing body 412 to seal the mixing space portion 411.

The additive mixing door 416 is provided in a part of the additive mixing lid 414 to open and close the mixing space part 411 and to close the mixing space part 411 when it is closed.

Here, the additive mixing body 412 is composed of the inner body 4122, the outer body 4124, and the insulating layer 4126.

The inner body 4122 forms a mixing space 411 therein and the outer body 4124 is spaced apart from the inner body 4122 by a predetermined distance.

The heat insulating layer 4126 is formed between the inner body 4122 and the outer body 4124 to maintain the temperature of the mixing space 411.

Here, the heat insulating layer 4126 is preferably formed by foaming urethane.

Further, the additive mixing body 412 further comprises an antistatic layer 4128.

The antistatic layer 4128 is formed on the inner surface of the mixing space part 411 of the additive mixing body 412 to prevent the static electricity from being generated, thereby preventing the additive from adhering to the inner surface.

The antistatic layer 4128 is preferably coated with any one of polyurethane (PC), polycarbonate (PC), and polypropylene (PP).

The additive mixing cylinder 410 further includes a cooling unit 418.

The cooling section 418 is provided to maintain the temperature of the mixing space section 411 at a low temperature.

For this purpose, the cooling unit 418 is composed of a refrigerant pipe 4182 and a cooling air conditioning unit 4184.

The refrigerant pipe 4182 is provided to surround the outer surface of the inner body 4122 so as to circulate the refrigerant for cooling.

The cooling air conditioning unit 4184 supplies the refrigerant to the refrigerant pipe 4182 and supplies the refrigerant having the increased temperature by the heat exchange with the internal body 4122 to the low temperature state as the refrigerant undergoes compression, Respectively.

Here, the cooling and air conditioning unit 4184 is the same as that used in the refrigerator or the Kimchi refrigerator.

As shown in FIG. 7, the additive supply part 430 includes a rotation rod 431, a supply screw part 432, a stirring blade 433, an additive discharge part 434, and an additive drive part 435.

The rotation rod 431 is disposed in the mixing space part 411 and is rotatably installed in the additive mixing lid 420.

Also, the supply screw portion 432 is provided at the lower end of the rotating rod 431 and rotated in the same manner.

The stirring wing 433 is provided on the rotating rod 431 and is rotated in the same manner to stir the additive in the mixing space part 411.

The additive discharge portion 434 has an additive discharge hole 4346a and is provided at the lower end of the additive mixing body 410 so as to contact the lower end surface of the supply screw portion 432. [

The additive driving unit 435 is provided in the additive mixing lid 420 to rotate the rotation rod 431.

The supply screw portion 432 is composed of a screw rod 4322 and a first screw 4324, a second screw 4326 and a supply scraper 4328 as shown in FIG.

The screw rod 4322 is connected to the lower end of the rotation rod 431 and the first screw 4324 is formed in a spiral shape along the outer periphery of the screw rod 4322.

The second screw 4326 is formed in a spiral shape along the outer periphery of the screw rod 4322 and the lower end of the second screw 4326 is positioned opposite to the lower end of the first screw 4324 with respect to the screw rod 4322.

The supply scraper 4328 is provided so as to connect the lower end of the first screw 4324 and the lower end of the second screw 4326 to scrape the upper surface of the additive discharge portion 434 to apply the additive to the additive discharge hole 434a .

Here, the supply pipe 130 is formed with a second inflow hole 134 through which the additive is introduced by the additive supply means 400.

The additive discharge portion 434 is composed of a first discharge block 4342 and a second discharge block 4344, a toppanel 4346 and a discharge opening / closing plate 4348.

The first discharge block 4342 has a first additive supply passage 4342a communicating with the second inflow hole 134 and is located in the supply pipe 130. [

The second discharge block 4344 has a second additive supply passage 4344a communicating with the first additive supply passage 4342a and is provided at the lower end of the additive mixing body 412 so as to be positioned in the first discharge block 4342 Respectively.

The topsheet 4346 has an additive dispensing hole 4346a for communicating the mixing space 411 and the second additive dispensing passage 4344a between the second dispensing block 4344 and the additive mixing body 412 .

The discharge opening and closing plate 4348 has an additive opening and closing hole 4348a and a discharge opening and closing lever 4349 corresponding to the additive discharge hole 4346a and is rotatably provided in the second discharge block 4344. [

The discharge opening / closing plate 4348 is rotated by using the discharge opening / closing lever 4349 to regulate the degree of overlap between the additive opening / closing hole 4348a and the additive discharge hole 4346a.

Here, the top surface of the soil release 4346 is installed so as to be in contact with the lower end of the supply scraper 4328.

The additive discharge hole 4346a is formed only on one side with respect to the extension line passing through the central portion of the overlay 4346 parallel to the surface.

The operation of the supply screw portion 432 and the additive discharge portion 434 will now be described in detail with reference to the operation of the supply scraper 4328 by the first screw 4324 and the second screw 4326, Lt; / RTI >

Thus, the transported additives are transported to the one side portion and the other side portion by the supply scraper 4328, respectively.

In other words, the additive accumulated on one side of the transferred additive is temporarily stored in one side of the additive, and the additive is discharged through the additive discharge hole 4346a, and the additive is continuously and constantly discharged.

9, a dispersion guide 436 for moving the additive in the direction of the inner side of the mixing space part 411 is further provided at the lower end of the rotation rod 431. As shown in FIG.

The dispersion guide 436 is formed to be inclined downward as it goes outward from the central portion provided in the rotation bar 431, and guides the additives around the rotation bar 431 to the edge and moves it downward by a proper amount.

Further, a vibration portion 450 for generating vibration in the rotation bar 431 is further constructed.

The vibrating part 450 generates vibration in the rotating rod 431 to prevent the additive from accumulating in the first screw 4324 and the second screw 4326.

The vibration unit 450 includes a vibration fixing bracket 452, a vibration striking unit 454, a vibration pressing unit 456, and a striking moving unit 458, as shown in Fig.

The vibration fixing bracket 452 is provided in the additive mixing body 410.

The vibration striking part 454 is rotatably provided at one end of the vibration fixing bracket 452, and the other end of the vibration striking part 454 strikes the rotation rod 431.

The vibration pressing portion 456 is provided to press the other end of the vibration striking portion 454 to the rotating rod 431.

The striking end portion 458 is provided on the rotating rod 431 and is rotated in the same manner. When the other end portion of the vibration striking portion 454 pressed by the vibration pushing portion 456 rides over, And is provided for hitting the rotation shaft 431.

Accordingly, the vibration unit 450 strikes the rotation bar 431 at predetermined time intervals to prevent accumulation of the additives.

And the striking moving part 458 is composed of the movable pupil 4582 and the movable attachment 4584, the movable roller 4586 and the movable adjusting part 4588. [

The movable pupil 4582 is formed to be orthogonal to the longitudinal direction of the rotating rod 431, and the movable movable rod 4584 is provided for moving along the movable pupil 4582.

Further, the movable roller 4586 is rotatably provided on the movable shaft 4584, and the other end of the vibration striking part 454 is provided for riding over.

The movable adjustment portion 4588 is provided for fixing the movable shaft 4584 to the rotation rod 431 by adjusting the projection length.

As the position of the movable roller 4586 is adjusted by the movable adjusting portion 4588, the distance between the other end of the vibration striking portion 454 and the rotating rod 431 is adjusted to adjust the magnitude of vibration.

11, the additive mixing section 440 includes a tubular rotation rod 441, a sealant protrusion 442, a rotation guide rod 443, a mixing block 444, a rod guide hole 445, (446) and a mixed driving unit (447).

The tubular swinging rods 441 are formed on both sides so that the additive mixing cylinder 410 is rotatably installed in the fixed frame 420.

In addition, the seal opening 442 is formed long in the vertical direction on the fixed frame 420 so that the barrel rotation bar 441 can be positioned and moved.

The rotation guide rod 443 is provided on the stationary frame 420 so as to be adjacent to the seal opening 442.

The mixing block 444 is provided between the stationary frame 420 and the additive mixing cylinder 410 so that the barrel rotation rod 441 is rotatably installed.

The rod guide hole 445 is formed horizontally long in the mixing block 444 so that the rotation guide rod 443 is positioned and movable.

The lifting lever 446 is provided to rotate the mixing block 444, and is formed in a 'C' shape so that both ends are fixed to the mixing block 444.

The middle portion of the lift lever 446 is positioned outside the additive mixer 410. When the additives are mixed, the additive mixer 410 is positioned at the front side or the rear side of the additive mixer 410, It is possible to secure a space that can be used.

Of course, when the additive mixing cylinder 410 is rotated, it is possible to prevent the operator from being moved into the rotating space.

The mixing drive unit 447 is provided to rotate at least one of the tubular rotation rods 441.

When the lift lever 446 is rotated, the mixing block 444 is rotated so that the barrel rotation bar 441 is moved upward along the seal opening 442.

At the same time, the rotation guide rod 443 is moved along the rod guide hole 445 to separate the additive mixing cylinder 410 equipped with the second discharge block 4344 from the first discharge block 4342.

As described above, the additives in the mixing space part 411 are mixed as the additive mixing container 410 rotates the additive mixing container 410 by the mixing driving part 447 while being spaced apart.

Here, the stirring vane 433 is composed of a first stirring vane 4332 and a second stirring vane 4334.

The first stirring blade 4332 is provided at the lower end of the rotation rod 431 so as to correspond to the inner surface of the lower end of the mixing space part 411 to stir the additives.

The second stirring blade 4334 is provided in the middle portion of the rotation rod 431 to stir the additives.

The rotation bar 431 is composed of a first rotation bar 4312, a second rotation bar 4314, and a rotation bearing 4316.

The first rotating rod 4312 has an upper end adjacent to the additive mixing lid 414 and a lower end located at the lower end of the mixing space 411.

The second rotation bar 4314 is disposed so as to surround the outside of the first rotation bar 4312. The upper end of the second rotation bar 4314 is positioned adjacent to the upper end of the first rotation bar 4312, .

The rotation bearing 4316 is provided between the first rotation bar 4312 and the second rotation bar 4314 so as to be rotatable with respect to each other.

It goes without saying that the additive is prevented from flowing between the first rotation bar 4312 and the second rotation bar 4314. [

The first stirring blade 4332 is provided at the lower end of the first rotating rod 4312 and the second stirring blade 4334 is provided at the lower end of the second rotating rod 4314.

Thus, the additive driving unit 435 rotates at least one of the first rotating rod 4312 and the second rotating rod 4314 to discharge the additive, stir the additive, or discharge and stir the additive.

To this end, a mixing control unit 450 for controlling the additive driving unit 435 and the mixing driving unit 447 is further included.

The mixing control unit 450 controls the additive driving unit 435 and the mixing driving unit 447 in the first mode, the second mode, the third mode and the fourth mode.

First, in the first mode, when the second ejection block 4344 installed in the additive mixing cylinder 410 is seated in the first ejection block 4342, the additive driving unit 435 is operated to rotate the first rotation rod 4312 The additives are discharged as the first agitating blades 4332 are rotated.

In the second mode, when the second discharge block 4344 installed in the additive mixing cylinder 410 is seated in the first discharge block 4342, the additive driving unit 435 is operated to move the second rotary bar 4314 and the second As the stirring wing 4334 is rotated, the additives are mixed and the first rotating bar 4312 and the first stirring wing 4332 are rotated to discharge the additives.

In the third mode, when the additive mixing cylinder 410 is separated upward by the lifting lever 446, the mixture driving cylinder 447 is operated to rotate the additive mixing cylinder 410 in the vertical direction, .

In the fourth mode, when the additive mixing cylinder 410 is separated upward by the lifting lever 446, the mixture driving cylinder 447 is operated to rotate the additive mixing cylinder 410 up and down, At the same time, the additives are mixed by activating the additive driving part 435 and rotating the second rotating rod 4314 and the second stirring blade 4334.

10 Feeding device 100 Feeding device
200: feed pressing means 300: feed turning means
310: turning pipe 320:
330: Swivel driving part 400: Additive supply means
410: additive mixing cylinder 420: stationary frame
430: additive supplying part 440: additive mixing part

Claims (10)

Feeding means for feeding the stored feed through each of the feed pipes to each feeder;
A feed compression means for crushing and crushing the supplied feed and then feeding the feed to the feed means;
A feed pouring means for selectively turning the feed fed by the feed feeding means and feeding the fed feed to the feed pressing means; And
And an additive supply means for uniformly supplying the additive to the feed conveyed by the feed means. The method according to claim 1,
Wherein the feed pipe is formed with an inflow hole through which the feed compressed by the feed compressing means flows,
The feed compression means comprises:
A body housing having a feed press-fit insertion portion formed at an upper end thereof, a feed press-fit / discharge portion formed at a lower end thereof, and a press-fit space portion communicating with the feed press-
A pair of pressing rollers rotatably disposed in the squeezing space portion of the body housing, the squeezing portion pressing and crushing the feed supplied from the feed pressing and feeding portion as it is rotated in a mutual tangential direction; And
And a compression drive unit provided in the body housing for rotating the pair of compression rollers of the compression unit in mutual directions,
The feed pivoted by the feed pivot means is supplied to the feed press-feeding portion of the body housing, is crushed by the pair of press rollers and crushed, and then fed through the feed press-feed discharging portion Characterized in that the feed which is crushed smaller than the particles of the feed is discharged. 2. The animal feeder according to claim 1,
A turning pipe for feeding the feed of the feed pipe to the feed pressurizing means;
A pivot connection for selectively feeding the feed of the feed pipe to the orbiting pipe; And
And a swivel driving unit for feeding the feed fed into the swivel pipe to the feed pressurizing unit. 4. The apparatus according to claim 3,
A first turning pipe formed horizontally adjacent to the supply pipe;
A second turning pipe having a lower end communicating with one end of the first turning pipe and rising upward; And
A third swiveling pipe provided at an upper end of the second swivel pipe so as to communicate with an upper end of the second swivel pipe and a lower end of the third swivel pipe so as to be positioned on the upper side of the feed compression means, And a feeder for feeding the feed to the feeder. [5] The apparatus of claim 4,
A connection discharge hole formed at a lower portion of the supply pipe for discharging the feed conveyed along the supply pipe;
A connection inflow hole formed at an upper side of one end of the first turning pipe to feed the feed;
A connecting frame in which a connecting passage for connecting the connection vent hole and the connection inflow hole is formed; And
And a connection opening / closing door for opening / closing the connection inflow hole. 6. The apparatus according to claim 5,
A first swivel driving unit for feeding the feed to the first swivel pipe to the second swivel pipe; And
And a second swivel drive unit for feeding the feedstock fed into the second swivel pipe to the third swivel pipe,
Wherein the feedstock fed into the third swivel pipe slips along the third swivel pipe and is fed to the feed pressing means. 7. The apparatus according to claim 6,
A turning screw rotatably installed in the turning pipe; And
And a swiveling drive motor for rotating the swiveling screw. 2. The food processing apparatus according to claim 1,
An additive mixing cylinder having a mixing space inside;
A fixed frame for installing the additive mixing cylinder rotatably;
An additive supply unit for uniformly supplying the additive mixed in the additive mixer to the feed pipe of the feeder; And
And an additive mixer for mixing the additive introduced by rotating the additive mixer in the up and down direction. 9. The method according to claim 8,
An additive mixing body in which a mixing space part is formed inside and a lower end part is narrowed toward the lower part;
An additive mixing cap provided at an upper end of the additive mixing body to close the mixing space; And
And an additive mixing door provided on a part of the additive mixing lid to close and close the mixing space part and to close the mixing space part when closed. 10. The process cartridge according to claim 9,
A rotating rod disposed in the mixing space and rotatably installed in the additive mixing lid;
A supply screw unit provided at a lower end of the rotating rod and rotated in the same manner;
A stirrer for stirring the additive in the mixed space portion as the stirrer is provided and rotated in the same manner;
An additive discharge portion provided at a lower end of the additive mixing body so as to contact the lower end face of the supply screw portion; And
And an additive driving part provided on the additive mixing lid to rotate the rotating rod.

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