KR101584205B1 - Fly larval rearing system - Google Patents

Abstract

The present invention relates to a fly larva rearing system and, more specifically, to a fly larva rearing system which can automatically rear fly larva. The present invention comprises: a fly living chamber where flies live; a base unit installed in the fly living chamber; a lava rearing chamber installed in the base unit; a hatching chamber installed in a side of the lava rearing chamber; and a rotation unit which is installed in the base unit, and rotates the lava rearing chamber in order.

Description

{Fly larval rearing system}

More particularly, the present invention relates to a fly larvae breeding system, and more particularly, to a caterpillar flounder breeding system in which a caterpillar is grown in stages in a plurality of divided caterpillars, The present invention relates to a larval larval rearing system for automatically feeding larvae through a repeated cycling process in which the larvae are transferred to a flounder provided in the upper part of the breeding room and then inhabited in the inbred sparrow in the breeding room.

In general, fly larvae, or maggots, are made of high protein and are used extensively as feed, or as bait for fishing.

Recently, when it is difficult to distinguish between dead and new flesh, it is used as a treatment to clean the rotten area by placing the maggots in a place that is difficult to operate or in a wound that is difficult to clean.

Thus, there were not enough facilities to mass-produce and distribute larval larvae widely used in various fields.

Therefore, in order to solve the conventional problems, Korean Patent Registration No. 10-0654253 entitled " Floc Breeding Device "has been proposed.

That is, the patent registration No. 10-0654253 discloses that the caterpillar breeding box is bound to the conveyor belt and moves one step at a time, feeding the food amount suitable for the caterpillar growth and development stage and controlling the various breeding devices It is structured so that larvae are raised by management.

However, the pre-registered patent has some disadvantages in terms of increase in food feed rate due to growth and development, disposal of feces, and so on, due to the operation of the breeding box in which the larvae grow and develop.

In other words, it is required to cope with a sudden increase in the load of the equipment due to the sudden weight due to the growth and development of the fly larvae, the stress of the larvae is increased due to the operation of the fly raising device, There is a disadvantage in that the efficiency of the operation such as transferring the larvae to the alley room by manually sorting the larvae is inferior.

Therefore, in the conventional floc breeding device described above, since the breeding box in which the fly larvae live is attached to the conveyor belt and driven, the larval production of the larvae is relatively small in comparison with the scale of the facility, There is a problem that economical efficiency and efficiency are deteriorated as a breeding facility in which a large amount of larvae must be continuously fed in the space.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a facility for providing a living environment suitable for each growing and growing step in a cover part covering a feeding room, The aim is to control the optimum habitat environment of the larvae to minimize the lower part of the larvae when raising the larvae, and to raise the larvae economically and efficiently.

In addition, a plurality of breeding rooms are divided and formed so that the larvae can be raised in stages, and a lid covering the upper part of the divided breeding room is provided with various facilities so as to provide suitable conditions for growth and development of the larvae. It is possible to economically grow the larvae by maintaining the conditions suitable for growth and development according to the first order, and to be capable of automatically feeding the larvae continuously, thereby producing a large number of larvae.

In addition, a floor net made of net is rotatably provided at the bottom of a plurality of divided breeding rooms so that when the larvae raised in the breeding room are collected, the larvae are discharged to the lower part when the bottom net is rotated, So that it can be easily recovered.

In addition, the automatic feeding of flies and caterpillars to the breeding room after the production of their own food is automated, and the automatic supply of water supplies is automatically performed, so that all the systems are automatically performed, thereby minimizing the workforce.

In addition, various organic wastes such as livestock manure, slaughterhouse, animal wastes, fish wastes, food wastes, food wastes, sewage sludge, and other organic wastes are supplied to a large number of organic matter And it is an object of the present invention to provide an animal protein larvae while preventing the environmental pollution by using the larvae as cattle feed or protein feed such as fish.

In order to accomplish the above object, the present invention provides a flieshaped flies, a base unit installed in the flieshops, an larvae kennel installed in the base unit, and an allegorical chamber arranged on the side of the larvae kennel The fly larval rearing system includes a rotation operation unit installed on the base and sequentially rotating the larva cage.

Here, the base includes an outer base member positioned on the outer side of the lower end of the larva cage, and a plurality of inner base members spaced apart from the inner side of the outer base member.

The rotary operation unit includes a rail installed on an outer base member of the base, a plurality of rollers disposed under the larval cage so as to be seated on an upper portion of the rail, And a drive motor provided with a drive gear engaged with the internal gear.

The caterpillar hatchery is characterized by comprising a caterpillar breeding part in which the caterpillar is inhabited, a cover part covering the upper part of the caterpillar breeding part, and a lower support member provided in the lower part of the caterpillar breeding part.

Here, the larvae breeding part is provided with a breeding member in which a breeding chamber is formed on the inside so as to open upwards and downwards, and a plurality of breeding chambers are arranged in the direction of the arcs.

Further, the breeding member is provided with a passage tube communicating with the feeding chamber, and an opening / closing member for controlling the passage is provided in the inside of the passage tube. The opening / closing member is disposed coaxially with the passage tube, And a cylinder for operating the flow member is provided.

In addition, a bottom net is provided in an inner lower portion of the breeding member, a pivot shaft is fixed to a lower portion of the bottom net to protrude outward of the raising member, and a tie rod is provided at one end of the pivot shaft And a binding member provided with a binding hole for binding a binding member provided on any one of the plurality of the feeding members is provided, and a rotating unit for rotating the binding member is provided, .

The lid part is divided into a plurality of sections corresponding to the caterpillars of the caterpillar breeding part, and a lid part is formed on the inner side and fixed to the base part by the support frame on the outer side part. The lid part covers the upper part of the compartment of the lid part , And the seven compartments are provided with a lid that covers the upper part.

In addition, a feeding device for feeding food to the larva cage is provided.

The food supply means includes a crushing portion for crushing the raw material, a stirring portion for stirring the raw material supplied from the crushing portion, a food storage portion for fermenting the raw material stirred in the stirring portion to produce food, And a feeding unit for feeding the food stored in the storage unit to the caterpillars.

Further, any one of the breeding members of the larva cage may be provided with a vacuum suction unit.

Here, the vacuum suction unit is provided with a suction member to communicate with the lower part of the carcass member, and a suction pipe coupled to one side of the suction member is provided. A cyclone is provided at an end of the suction pipe, A recovery box having a recovery box for storing water separated from the cyclone is provided.

In addition, a hot water tank and a cold water tank for supplying hot water or cold water to the feeding room of the larva custody are provided.

Here, the hot water tank and the cold water tank are further provided with a water replenishing tank for replenishing water.

The boiler is further provided with a boiler for heat-treating the caterpillar inhabiting any of the breeding members of the caterpillary cage.

Further, a lighting controller for controlling the lighting of the flies is provided.

The air purifier further includes an air purifier for purifying air in the flue.

According to the present invention constructed as described above, a facility for providing a living environment suitable for each growing and growing step is provided in a cover part covering a feeding room by dividing and forming a plurality of feeding rooms where the larvae live, Thereby minimizing the load of the device when raising the larval larvae, and economically and efficiently raising the larvae.

In addition, a plurality of breeding rooms are divided and formed so that the larvae can be raised in stages, and a lid covering the upper part of the divided breeding room is provided with various facilities so as to provide suitable conditions for growth and development of the larvae. It is possible to economically grow larvae by maintaining the conditions suitable for growth and development according to the first order, and it is possible to automatically feed the larvae continuously, thereby producing a large number of larvae.

In addition, a floor net made of net is rotatably provided at the bottom of a plurality of divided breeding rooms so that when the larvae raised in the breeding room are collected, the larvae are discharged to the lower part when the bottom net is rotated, Can be easily recovered.

In addition, it automatically feeds the flies and caterpillars to the breeding room after it produces its own food, and at the same time automates the supply of water, etc., so that all the systems are automatically carried out, thereby minimizing the workforce.

In addition, various organic wastes such as livestock manure, slaughterhouse, animal wastes, fish wastes, food wastes, food wastes, sewage sludge, and other organic wastes are supplied to a large number of organic matter And it is possible to prevent the environmental pollution and to feed larvae of animal protein by using the larvae as cattle feed or protein feed such as fish.

1 is a schematic view showing a fly larvae breeding system according to the present invention.
Fig. 2 is a front view showing the larvae kennel of the present invention. Fig.
Fig. 3 is a plan view showing a larvae kennel of the present invention. Fig.
Figs. 4A to 4D show the larvae growing section of the present invention. Fig.
Figure 5 shows a passage through which the larvae of the present invention migrate to the compartment.
6A to 6C are views showing the open / closed state of the lower part of the breeding member of the present invention.
7 is a view showing a rotation operation part of the present invention.
8A to 8C show food feeding means of the present invention.

Hereinafter, a fly larval feeding system according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic view showing a larval larval rearing system according to the present invention, FIG. 2 is a front view showing a larval custody of the present invention, FIG. 3 is a plan view showing a larva custody of the present invention, FIG. 5 is a view showing a passage through which the larvae of the present invention move to the alfalfa chamber, FIGS. 6A to 6C are views showing the open / closed state of the lower part of the breeding member of the present invention, FIG. 8A to FIG. 8C are diagrams showing the feeding means of the present invention. FIG.

1 to 8C, the parasite larvae feeding system 100 according to the present invention includes a flieshall 110 in which flies are inhabited, a base unit 210 installed in the flieshore 110, A caterpillar hatchery 310 installed in the base unit 210 and inhabited by crawling larvae and an allegorical chamber 810 installed on the outer side of the caterpillary caterpillars 310.

Here, although not shown in the drawing, the flue hood 110 is provided with a plurality of wires arranged in the horizontal direction at an upper end thereof. The flies are provided with a plurality of flaps for resting in the habitat, And a sensor for measuring the ventilator, the temperature, the humidity and the light intensity.

In addition, the flue hatchery 110 is provided with an air purifier 112, a lighting control unit 114 for automatically controlling the lighting lamp, and a water supply equipment 116 so as to maintain the habitat environment hygienically.

Therefore, the environment of the flounder 110 can be maintained in the best environment in which flies can live.

The base unit 210 includes an outer base member 212 formed in a circular shape and a plurality of inner base members 212 disposed to be spaced apart from each other at a predetermined interval inside the outer base member 212, (214).

The larva custody 310 includes a larval custody part 312 installed in the base part 210 and a cover part 350 covering the upper part of the larva custody part 312.

The caterpillar nursery unit 312 includes a first feeding member to an eighth feeding member 314a, 314b, 314c, 314d, 314d, 314d, ) 314e, 314f, 314g, and 314h.

That is, the larval feeding unit 312 feeds from the first feeding member to the eighth feeding member 314a, 314b, 314c, 314d, 314e ) 314f, 314g, and 314h, respectively.

Further, an air fan (not shown) is installed in each of the first to eighth lifting members 314a to 314e, 314d to 314e, 314f to 314h, And a sensor (not shown) for sensing the temperature, humidity, and illuminance of the sensors 316 and 316.

314d, 314d, 314e, 314f, 314g, and 314h are connected and fixed to the breeding chamber 316 so as to be connected to the first, second, third, and fourth feeding members 314a, 314b, 314c, And a passage pipe 320 protruding and fixed to the outside of the elevation member 314a, 314b, 314c, 314d, 314e, 314f, 314g, 314h, A connecting member 322 for opening and closing a passage of the passage pipe 320 located inside the elevating member to the eighth feeding member 314a, 314b, 314c, 314d, 314e, 314f, 314g, .

Here, it is preferable that one of the first to fourth elevation members 314a, 314b, 314c, 314d, 314e, 314f, 314g, 314h is located on the outer side of any one of the first, second, And a flow member 324 having an upper portion positioned coaxially with the passage pipe 320 is provided.

At this time, the flow member 324 is moved to the fifth rising member of the sixth lifting member 314a, 314d, 314e, 314f, 314g, and 314h from the first to eighth lifting members 314a, 314b, 314c, (Not shown) for measuring the weight of the larvae moving through the flow member 324, so that a certain amount of larvae can move to the lit room 810.

The fixing member 326 is provided on the base 210 and is fixed to the fixing member 326. The fixing member 326 is installed on the base member 210 to slide the flow member 324 in the direction of the path tube 320. [ There is provided a cylinder 328 for operating.

Accordingly, when the flow member 324 is advanced by the passage pipe 320 provided in the sixth feeding member 314f, that is, the sixth feeding member 314f in which the larvae of the fifth day are housed, The lid member 322 is inserted while pushing the lid member 322 while the lid member 320 is inserted into the lid 320 and the lid member 322 is opened. The movable member 322 is automatically returned to its original position when the predetermined amount of larvae are moved, and then the rod member 322 is moved to the alleys chamber 810 by shutting off the passage tube 320 The larvae that block the caterpillar and move to the fables (810) are brought to Paris here.

Meanwhile, the allegorization chamber 810 is mixed with the humus, the sawdust, the sand or the soil in an appropriate ratio in order to create an environment in which the larvae growing on the floor can be alienated.

A bottom net 330 of a net shape is formed below the breeding room 316 of the first to eighth breeding members 314a to 314c, 314d to 314e, 314f to 314h, And a lower portion of the bottom net 330 is provided with a pivot shaft 332 which is coupled and fixed by bolt fixing means.

At this time, both end portions of the pivot shaft 332 are protruded outward from the first to eighth lifting members 314a, 314b, 314c, 314d, 314e, 314f, 314g, And is rotatably installed by supporting means which supports both side portions.

One end of the pivot shaft 332 protruding outward from the first to eighth lifting members 314a, 314b, 314c, 314d, 314e, 314f, 314g, And a coupling hole 334 which is fixed to the coupling hole 334.

The seventh carnivorous member 314g which grows and collects the caterpillar among the first to eighth carnivorous members 314a to 314c, 314d to 314e, 314f to 314g and 314h, A binding member 336 provided at a lower end of the binding member 332 and provided with a binding hole 337 for binding the binding member 334 is provided on one side of the base member 210, And a plate 335 on which the rotation unit 338 is installed.

Therefore, the binding member 336 is rotated by the rotating unit 338 provided on the seventh feeding member 314g corresponding to the sixth day when the growth of the larvae is completed, and at the same time, The float 330 is rotated at the same angle as the float 332 rotates by 90 degrees so that the larva in the upper part of the floor net 330 is discharged downward.

314e, 314f, 314g, 314h, 314a, 314b, 314c, 314d, 314e, 314f, 314g, 314h of the eighth and tenth aspects of the present invention, A lower support member 340 is provided.

The lid part 350 is provided on the upper side of the first to fourth elevation members 314a, 314b, 314c, 314d, 314e, 314f, 314g, 314h of the larval feeding unit 312, 352a, 352d, 352e, 352f, 3524g, 352g, 352g, 352d, 352d, 352d, 352d, 352d, 352d,

At this time, the first to eighth lids 352a, 352b, 352c, 352d, 352e, 352f, 3524g, and 352h are fixed to the upper portion of the base portion 210 by the support frame 354 Respectively.

Here, a through hole 355 communicating with the division chamber is formed at each of the upper portions defined by the first to eighth covers 352a, 352b, 352c, 352d, 352e, 352f, 3524g, And a lid 356 covering the through hole 355 is provided.

At this time, the lid 356 is provided with a handle at an upper portion thereof, and the lid 356 is provided with a handle at an upper portion of the lid 356, The lid 356 is not provided in the through hole 355 of the first lid 352a located in the first livestock member 314a and only seven lids are provided to keep the lid open so that the flies can enter and scatter do.

Therefore, the flies in the flounder 110 enter the first fluttering member 314a through the through holes 355 of the first cover 352a located above the first feeding member 314a, .

Further, a carrier 358 is provided on the first to seventh lids 352a, 352b, 352c, 352d, 352e, 352f, 352g, and the carrier 356 is provided with a first lifting member A feeder 359 for feeding food to the seventh carcass members 314a, 314b, 314c, 314d, 314e, 314f, and 314g is provided, and the first to fourth carnivorous members A water supply pipe 362 provided with a shower 360 for supplying water to the breeding room 316 of the first breeding room 314a, 314b, 314c, 314d, 314e, 314f, 314g, The water supply pipe 362 installed in the member is installed to be connected to the boiler 364.

Therefore, the first to seventh lids (the first to seventh livers) 314a to 314d, 314e, 314f, 314d, 314e, 314f, 352a, 352a, 352b, 352c, 352d, 352e, 352f, 3524g) to control the best environment in which the larvae can live.

At this time, water is supplied through the boiler 364 to the shower 360 installed in the seventh care member 314g, and steam is sprayed.

An observation camera (not shown) that observes the growth state of the larvae is provided inside the first to fourth breeding members 314a, 314b, 314c, 314d, 314e, 314f, Respectively.

The larvae of the first to eighth growing members 314a, 314b, 314c, 314d, 314e, 314f, 314g and 314h of the larval custody 310 are completely grown and recovered And a vacuum absorber 410 installed at a lower portion of the seventh custody unit 314g.

The vacuum inhaler 410 is provided with a suction member 412 installed at a lower portion of the seventh carnivorous member 31g and is provided with a suction pipe 414 connected to the suction member 412, 414 are provided with a cyclone 416 separating water and caterpillar using a vortex phenomenon.

Further, a recovery box 418 is provided below the cyclone 416, and a recovery tank 420 for storing water separated by the cyclone 416 is provided.

The larvae in the breeding chamber 316 of the seventh breeding member 314g are discharged to the bottom by the rotation of the bottom net 330 and the discharged larvae are discharged through the suction member 412 and the suction pipe 414 The caterpillar and water supplied to the inside of the cyclone 416 are discharged to the inside of the cyclone 416 and discharged through the discharge port provided at the upper part by the swirling phenomenon rotating around the inner circumferential surface and stored in the recovery water tank 420 And the caterpillar is discharged to the lower part and collected in the recovery box 418. [

 The rotary operation unit 510 rotates the larvae feeding unit 312 of the larva custody 310.

Here, the rotation operation unit 510 includes a rail 512 on the outer base member 212 of the base unit 210.

Further, a plurality of rollers 514 installed at the lower portion of the larva culturing portion 312 and mounted on the upper portion of the rail 512 and rotated along the rail 512 are provided.

314d, 314d, 314f, 314g, 314h, 314a, 314b, 314c, 314d, 314d, 314g, 314h, and is formed in a ring shape, And an internal gear 516 engaged and fixed by bolt fastening means with the eighth lifting members 314a, 314b, 314c, 314d, 314e, 314f, 314g, 314h, And a drive motor 520 having a drive gear 518 engaged with the gear of the internal gear 516 is provided.

Accordingly, the internal gear 516 engaged with the driving gear 518 is rotated by the operation of the driving motor 520 to rotate the first to fourth elevating members 314a, 314b, 314c, 314d, 314e 314a, 314b, 314c, 314d, 314d, 314d, 314d, 314d, 314d, 314d, 314d, 314d, 314d, ) 314e, 314f, 314g, and 324h by one rotation every day.

In addition, a feeding device 610 for feeding food to the larva custody 310 is provided.

The food supply unit 610 includes a crushing unit 612 for crushing raw materials such as animal wastes generated from livestock manure, slaughterhouse, and various organic wastes such as animal wastes, fish wastes, food wastes, food wastes, and the like, A food storage part 630 for fermenting the raw material mixed in the agitation part 620 to produce and store food; a storage part 630 for storing the food stored in the food storage part 630, And a feeding unit 640 for supplying the fed food to the breeding ground 310.

The crushing unit 612 is provided with an inlet 614 and an outlet 615. The crushing unit 612 includes a fixed saw blade 616 inside and a rotating saw blade 618 rotated by a motor 617 provided inside, A pulverizing body 613 is provided.

Accordingly, when the motor 617 is operated after the raw material is supplied through the inlet 614, the rotary saw blade 618 is rotated and the raw material is crushed by the fixed saw blade 616 and the rotary saw blade 618, .

The stirring part 620 is provided with a stirring body 622 and a stirring shaft 624 provided with a stirring blade 625 and a stirring screw blade 626 is provided inside the stirring body 622, And a stirring motor 628 for rotating the stirring shaft 624 is provided.

The stirring shaft 624 is rotated by the operation of the stirring motor 628 and the stirring blade 625 provided in the stirring shaft 624 and the stirring blade 625 provided in the stirring shaft 624 are rotated And agitation is performed by the screw blade 626. [

The food storage part 630 is provided with a fermenting body 632 and a fermentation shaft 634 having a plurality of fermentation screw vanes 635 is provided inside the fermentation body 632, And a fermentation motor 636 for rotating the fermentation tank 634.

The fermentation shaft 634 is rotated by the operation of the fermentation motor 636 and the fermentation screw blade 635 provided on the fermentation shaft 634 is rotated by the rotation of the fermentation shaft 634, The fermentation is carried out while the raw materials are mixed, and the food is produced.

Meanwhile, the stirring body 622 and the fermenting body 632 are provided with a cover member (not shown) so as to cover the lower part and the side part, and to be spaced apart from the outer circumferential surface so as to fill the hot water therebetween.

The food supply unit 640 is connected to the fermentation body 632 of the food storage unit 630 at one side thereof and the other side thereof is installed at the larval kennel 310 to feed food And a mono pump 644 is provided at a predetermined position of the feeding pipe 642.

Therefore, the food stored in the fermentation tank 632 is supplied to the larvae hatchery 310 through the food feed pipe 642 by the operation of the mono pump 644.

In addition, hot water or cold water is supplied to the breeding room 316 of the first to seventh breeding members 314a, 314b, 314c, 314d, 314e, 314f, and 314g of the larval custody tank 310 A hot water tank 710 and a cold water tank 712 are provided.

A water replenishing tank 714 for replenishing water to the hot water tank 710 and the water tank 712 is provided.

A feeding feed conveyor 716 installed on the eighth lid 352h is provided to feed the food made of fish or internal organs into the feeding chamber 316 of the eighth feeding member 314h of the larval custody 310 do.

The operation of the thus-constructed fly larvae breeding system according to the present invention will be described below.

The parasitic larval rearing system 100 according to the present invention first adjusts the environment suitable for the flies to live in the flies 110 where the flies are inhabited.

That is, the temperature, humidity, and brightness of the flounder 110 are controlled by a boiler 364, an air blower (not shown), an air purifier 112, an illumination light controlled by the illumination control unit 114, ) Is selectively operated to create a habitat suitable for flies.

Accordingly, the interior of the flue hood 100 is operated by the illumination lamp to brighten 12 hours of 24 hours a day, the boiler 364 is operated to be heated, and the bright 12 hours is maintained at about 27 ° C to 29 ° C And the air in the flue hood 110 is cleaned and kept at a constant temperature by keeping the air in the dark for 12 hours at about 20 ° C to 22 ° C and operating the ventilator and air cleaner 112, It is possible to maintain the same temperature, humidity, and luminosity and to form and scatter.

Thus, by keeping the flounder 110 in a clean and clean state at all times, the flies can be habituated and scattered in a comfortable environment without being stressed.

Thus, when the flies of the flounder reside in the flounder 110, the flies scatter in the larvae hatchery 310.

The first cover to the cover 352a, 352b, 352c, 352d, 352e, 352f, 352g, 352h of the cover 350 covering the upper part of the larva custody 310, The upper part opens into the breeding room 316 of the first breeding member 314a through the lid having an opened upper part, that is, the first lid 352a with the opened upper part.

At this time, the concentrated feed is not fed to the second feeding member to the fourth feeding member 314b (314c) 314d and the sixth feeding member 314f, and the fifth feeding member 314e is fed with the livestock manure, Concentrated food made of various organic wastes such as food byproducts and food waste is supplied in an appropriate amount of 6 to 12 times a day according to the growth step.

Here, a place where the fly is scattered among the first to eighth growing members 314a, 314b, 314c, 314d, 314e, 314f, 314g, and 314h of the larva custody support 310, 1 raising member 314a.

At this time, through the food conveyor 716 provided on the eighth lid 352h provided on the eighth feeding member 314h so that the flies can be scattered in the feeding chamber 316 of the first feeding member 314a, The eighth feeding member 314h is converted into the first feeding member 314a so that the feeding room 316 of the first feeding member 314a is rotated, The flies come in and feed by the food provided.

When the flies are scattered in the breeding chamber 316 of the first breeding chamber 314a of the larva custody 310 at a lapse of one day, The first to eighth carnivorous members 314a, 314b, 314c, 314d, 314e, 314f, 314g, 314h are rotated by one space.

The driving motor 520 of the rotary operation unit 510 is moved to the inside of the feeding chamber 316 of the first feeding member 314a through the upper opening of the first cover 352a, The first to fourth lifting members 314a to 314d to 314d and 314d to which the internal gear 516 engaged with the driving gear 518 rotates and is fixedly coupled to the internal gear 516, 314e, 314f, 314g, and 314h are shifted one by one so that the eighth carnivorous member 314h is positioned below the first cover 352a.

In this way, the rotation operation unit 510 operates every time one day passes to rotate the larva feeding unit 312 one by one, thereby providing the optimal habitat environment for each growing stage of the larva, The caterpillar is raised in the caterpillary hatchery (310).

The first to eighth lifting members 314a to 314a provided at the lower portions of the first to eighth lid members 352a, 352b, 352c, 352d, 352e, 352f, 352g, The first to fourth lifting members to the eighth lifting members located at the lower part of the first lid 352a opened at the top in accordance with the rotation of the first lifting members 314a, 314b, 314c, 314d, 314e, 314f, 314g, 314a, 314b, 314c, 314d, 314e, 314f, 314g, and 314h are set and set from the 1st to 6th day of rearing of the spawning room and larvae.

The larvae fed from the first to eighth breeding members 314a, 314b, 314c, 314d, 314e, 314f, 314g, and 314h include first to eighth lid members When a sensor (not shown) provided in the water tank 352a, 352a, 352b, 352c, 352d, 352e, 352f, 352g, 352h measures humidity and is lower than the set humidity, the cold water tank 712 and the hot water tank The water supplied from the water heater 710 is sprayed through the shower 360 to maintain a constant humidity at all times.

The concentration of the concentrated substance stored in the fermentation matrix 632 of the food feeding means 610 through the feeder 359 mounted on the carrier 358 provided on the fifth lid 352f located above the fifth feeding member 314f The food is fed and supplied by the feeding part 640.

When the flow member 342 is moved to the sixth feeding member 314f by operating the flow member 324 installed on the outer side of the sixth feeding member 314f on the fifth day when the larvae are grown, And the separating member 322 which cuts off the passage pipe 320 is opened by the flow member 324 inserted into the passage pipe 320 inside.

The caterpillar inhabiting the breeding chamber 316 of the sixth breeding member 314f along with the light passing through the flow member 324 due to the opening of the passage pipe 320 is passed through the flow member 324, The movable member 324 is automatically returned to the original state and the separating member 322 blocks the passage tube 320. [0051] As shown in FIG.

 Accordingly, a part of the larvae in the breeding chamber 316 of the sixth breeding member 314f moves to the allegration chamber 810 through the passage pipe 320 and becomes flies.

The caterpillar moved to the alpine chamber 810 and then moved to the flounder 110 and then moved to the breeding chamber 316 of the first breeding member 314a through the opening of the first lid 352a, And it will spawn.

On the other hand, the caterpillar fully grown in the breeding chamber 316 of the seventh carcass member 314g is heated by the boiler 364 connected to the water supply pipe 362 provided in the seventh lid 352g, Hot water is sprayed through the shower 360 and heat treated.

At this time, the shower 360 coupled to the water supply pipe 362 provided in the seventh lid 352g injects the common water of about 28 ° C, the hot water of 100 ° C, and the steam of 160 ° C, .

The larvae are firstly boiled by spraying hot water through the shower 360 of the water supply pipe 362 and sprayed with steam at a high temperature of about 160 ° C in the second stage and then the rotary unit 338 is operated The rotating shaft 332 of the seventh carnivorous member 314g is rotated by 90 °, and the bottom net 330 is rotated, so that the larvae in the upper part are discharged to the lower part.

At this time, the caterpillar discharged to the lower portion of the seventh crotch member 314g is supplied to the inside of the cyclone 416 through the suction member 412 provided at the lower portion of the seventh crotch member 314g and the suction pipe 414 The water is discharged through the upper part and stored in the recovered water tank 420 by the swirling phenomenon generated by turning the inner surface of the cyclone 416 and the caterpillar supplied to the inside of the cyclone 416. The larva is discharged to the lower part, 418).

After the caterpillars raised in the seventh carnivorous member 314g are collected, the seventh carnivorous member 314g is positioned at the lower portion of the eighth lid 352h by rotating the container by the rotation operation unit 510, In this state, the food fed by the fish or the internal flies is supplied to the feeding chamber 316 of the eighth feeding member 314h through the feeding conveyor 716. [

After feeding the food to the inside of the eighth lifting member 314h, the rotatable operation unit 510 is operated to rotate the larva feeding unit 312 so that the eighth feeding member 314h is rotated by the first lid 352a, And is scattered in the breeding chamber 316 of the first breeding member 314a through the opening of the first cover 352a.

That is, in the sixth day of the seventh carnivorous member 314g, the sixth carnivorous member 314f, which is the fifth day in a state where the larvae are commercialized, is changed to the seventh carnivorous member 314g, which is the sixth day, The seventh carnivorous member 314g rotates to be converted into the eighth carnivorous member 314h so that the food of the flies is supplied to the inside and the eighth carnivorous member 314h is rotated to rotate the first carnivorous member 314a < / RTI >

In the fifth day, some larvae move to the alpine chamber (810) and move into the flies (110) by the flies, The remaining larvae produce the larvae by repeating the process of commercialization on the 6th day, so that the ecological circulation is continuous and the continuous larval rearing is accomplished.

314d, 314d, 314d, 314f, 314g, 314h, 314b, 314c, 314d, 314e, 314e, 314d, 314d, The first lid 352a and the first lid 352a are connected to the first lid 352a and the first lid 352a is opened. (316), in which the flies are scattered, and the caterpillars are raised step by step until the sixth day.

Thus, by repeating the operation of the larva custody 310, it is possible to alienate the fly and nurture the larvae and commercialize the fly.

Although the preferred embodiment of the fly larvae breeding system according to the present invention has been described above, the present invention is not limited thereto, but may be variously modified and embodied within the scope of the claims, the detailed description of the invention, and the accompanying drawings. And is also within the scope of the present invention.

100: Paris larvae Sowuk system 110: Paris habitat
112: air purifier 114:
116: water supply equipment 210: base part
212: outer base member 214: inner base member
310: Caterpillar Form Chapter 312: Caterpillar Breeding Department
314a, 314b, 314c, 314, 314e, 314f, 314g, 314h:
316: Breeding room 320: passage hall
322: Spacing member 324:
326: fixture 328: cylinder
330: bottom net 332: pivot shaft
334: Binding point 335: Plate
336: a binding member 337: a binding ball
338: Rotation unit 340: Lower support member
350:
352a, 352b, 352c, 352d, 352e, 352f, 352g, 352h:
354: passage 356: lid
358: Carrier
359: Feeding 360: Shower
362: water supply pipe 364: boiler
410: vacuum inhaler 412: suction member
414: Suction tube 416: Cyclone
418: Recovery Vix 420: Recovery tank
510: rotation operation part 512: rail
514: Roller 516: Internal gear
518: drive gear 520: drive motor
610: feeding means 612: crushing section
620: Agitator 630: Feed storage unit
640: feeding part 710: hot water tank
712: cold water tank 714: water replenishment tank
716: Feeding conveyor

Claims (17)

A flies larvae breeding system comprising a flue habitat in which flies are inhabited, a base part installed in the fly habitat, an larvae breeding ground provided in the base part, and an allegorical chamber provided on the side of the larvae breeding ground,
And a rotation operation unit installed in the base unit for sequentially rotating the larva custody,
The larval hatchery is composed of a caterpillar breeding part in which the larvae live,
A lid portion covering an upper portion of the larvae nursery;
And a lower support member provided at a lower portion of the caterpillar-
Wherein the larvae breeding part is provided with a breeding member in which a breeding chamber is formed on the inside so as to open upwards and downwards and a plurality of breeding chambers are arranged in the direction of the arcs,
The feeding member is provided with a passage pipe communicating with the feeding chamber, and a spacing member for controlling the passage is provided on the inside of the passage pipe,
And a flow member formed in a tubular shape so as to be positioned on the coarse chamber so as to be coaxial with the passage tube,
And a cylinder for operating said flow member. The method according to claim 1,
Wherein the base portion is provided with an outer base member located on the outer side of the lower end of the larva cage,
And a plurality of inner base members installed to be spaced apart from each other inside the outer base member. The method according to claim 1,
Wherein the rotation operation unit includes a rail provided on an outer base member of the base unit,
A plurality of rollers are provided at a lower portion of the caterpillary cage so as to be seated on the rail,
An internal gear connected and fixed to an inner lower end of the larva cage,
And a drive motor provided with a drive gear engaged with the internal gear. delete delete delete The method according to claim 1,
A floor net is provided in an inner lower portion of the breeding member,
And a pivot shaft coupled to the bottom of the bottom net and projecting outwardly of the raising member,
Wherein a tie rod is provided at one end of the pivot shaft,
And a binding member provided with a binding hole for binding a binding member provided in any one of the plurality of feeding members is provided and a plate provided on the base portion is provided with a rotating unit for rotating the binding member A fly larvae breeding system. The method according to claim 1,
Wherein the lid portion is divided into a plurality of portions corresponding to the caterpillars of the caterpillar breeding portion and the compartment is formed on the inner side and the lid member is fixed to the base portion by the support frame on the outer side portion,
Characterized in that the lid covering the upper part of the compartment of the lid member is provided with seven lids covering the upper part. The method according to claim 1,
And a feeding means for feeding food to the larvae cage. 10. The method of claim 9,
The food supply means includes a crushing portion for crushing the raw material,
An agitating part for agitating the raw material supplied from the crushing part,
A food storage part for fermenting the raw material stirred in the stirring part to produce food;
And a food supply unit for feeding the food stored in the food storage unit to a caterpillar breeding ground. The method according to claim 1,
Characterized in that one of the breeding members of the larval culotte is provided with a vacuum suction unit. 12. The method of claim 11,
Wherein the vacuum suction unit is provided with a suction member so as to communicate with a lower portion of the feeding member,
And a suction pipe coupled to one side of the suction member,
A cyclone is provided at an end of the suction pipe,
A recovery box is provided under the cyclone,
And a recovery tank for storing water separated from the cyclone. The method according to claim 1,
Wherein a warm water tank for supplying hot water or cold water and a cold water tank are provided in the feeding room of the larva custody cage. 14. The method of claim 13,
And a water replenishing tank for replenishing water by the hot water tank and the cold water tank. The method according to claim 1,
And a boiler for heat-treating the larvae in one of the breeding chambers of the larva cage. The method according to claim 1,
And a light conditioner for controlling the illumination of the flies. The method according to claim 1,
Further comprising an air purifier for purifying the flies of the flies.

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