KR200319123Y1 - Apparatus for breeding flies, system for breeding natural enemies of fly comprising the same, releasing container comprising the natural enemies - Google Patents

Abstract

Fly adult breeding devices, fly parasitic mass breeding systems and fly natural spinning containers are disclosed.

The fly parasitic mass breeding system according to the present invention is a fly adult breeding room (100) capable of chasing a fly eggs by breeding a housefly adult; Fly larva rearing room 200 for culturing fly larvae by administering organic waste to fly larvae; A fly larva separation chamber 300 for separating the fly larva and the degraded decomposition product; And a fly natural breeding room 400 equipped with a plurality of inoculation boxes 40 and a cradle 50 for breeding fly natural enemies using the fly larva separated from the above.

According to the present invention can be breeding a large number of flies parasitic natural species by a simple method, the fly parasitic radiation container according to the present invention has the advantage that easy storage of the fly parasitic neat, very easy to use.

Description

Apparatus for breeding flies, system for breeding natural enemies of fly comprising the same, releasing container comprising the natural enemies}

The present invention relates to a mass breeding system of fly parasites (Diptera) parasitoids, and to a fly insecticide radiation container using the fly parasite, more specifically a fly adult breeding box, a domestic species of fly parasite It relates to a system that can be bred to and a radiation container that can be easily used for flies insecticidal parasites.

In general, flies, which are a kind of insects, carry harmful elements to humans or livestock while carrying various foods and wastes by the feet with sensory functions.

Such flies not only cause an unsanitary environment on the farm, but also cause a decrease in the worker's desire to work, a decrease in productivity, and the spread of communicable diseases.

For this reason, conventional farms have been widely carried out a method for controlling flies mainly using chemical insecticides, and Korean Patent No. 83-2677 discloses trans Kris and Matemate allledolone having activity against insects of arthropods including flies. Insecticide composition based on the base of al-aledrolone esters is disclosed, and Republic of Korea Patent No. 85-1331 discloses an aerosol insecticide composition using a pyridoid-based compound that is active against arthropod insects. This effectively eradicates flies at one time, but has the side effect of causing trouble to frequently spray insecticides and environmental pollution such as destruction of ecosystems as well as poisoning of humans and livestock caused by the insecticides. In addition, the long-term use of the insecticides increases the resistance of the fly, especially for flies that are resistant to organophosphorus insecticides, which is not sufficient enough to control new high-toxic drugs, which solves the fundamental problem of fly eradication. You will not.

On the other hand, flytraps have been known as a tool to attract and capture flies, which are shaped like a glass bottle with a short neck, and the fly that is attracted inside through the neck does not come back to the neck and is captured in the bottle, but this is a large number of flies. It is difficult to effectively eradicate it.

In addition, there is a simple method of extinguishing flies using a sticky trap.However, in order to use a sticky trap, it is not only unsatisfactory in appearance by hanging it on the ceiling, but the effect of fly control is insufficient, When used, there was a problem that the range is limited by the influence of the wind.

Therefore, studies on pure biological control methods have been made instead of the above chemical methods, and natural enemies of agricultural pests, such as facility houses, have been studied and are in practical use. Parasitic nemesis among these flies is known to be effective as a biological control factor by attacking and killing the pupae of flies and spawning an average of about 100 eggs. Doing. However, there is a unique specificity between the domestic parasitic nemesis, and the introduction of foreign species may cause serious side effects such as disturbance of domestic species, so it is urgent to develop and commercialize domestic species, and use the fly pupa as the host of the fly nemesis. Therefore, there is a need for a system capable of breeding large flies and fly pupae.

Therefore, the first technical problem to be achieved by the present invention is to provide a fly larvae breeding apparatus that can obtain a large amount of fly larvae and pupa by breeding fly larvae.

The second technical problem to be achieved by the present invention is to provide a fly breeding system of fly parasitic as a domestic species that can be used in biological control methods to solve the problems of conventional chemical control methods.

The third technical problem to be achieved by the present invention is to provide a fly parasitic radiation container including the fly parasitic.

1 is a schematic diagram showing a parasitic parasitic mass breeding system according to the present invention.

Figure 2 is a perspective view of the adult fly box according to the present invention.

Figure 3 shows the appearance of a fly adult breeding box on the cradle.

Figure 4 is a perspective view of a fly larva breeding box according to the present invention.

Figure 5 shows a state loaded with a flies larva breeding box according to the present invention.

6 is a schematic view of a fly larva separation device according to the present invention.

7 is a perspective view of an inoculation box according to the present invention.

8 shows the inoculation box loaded on the holder.

9 is a schematic view of a fly parasitic spinning container according to the present invention.

<Description of the symbols for the main parts of the drawings>

5: split adult fable 6: split egg phase

7: Adult Food Feeder 8: Water Feeder

10: adult fly box 20, 120, 220: holder

30: fly larva breeding box 40: fly larva separation device

42: opening and closing part 45: secondary separator

55: light source 60: inoculation box

65: parasitic injector 80, 180, 280: air conditioner

90, 190, 290: Ventilator

100: fly larvae 200: fly larvae

300: fly larva separation room 400: fly natural enemy

The present invention to achieve the first technical problem

A detachable adult food feeder 7 and a water feeder 8 in communication with the outside via a food supply pipe 17 and a water supply pipe 18; Adult fable 5 and egg shell 6 which are detachably connected to the outside via an allegorical connector 15 and a sheller connector 16, and all surfaces except the lower surface are mesh 1 to 2 mm. Provides a fly adult breeding device (10) consisting of a net.

According to one embodiment of the present invention, the egg phase 6 is preferably provided with a protein feed medium containing 60 to 70% of moisture.

The present invention to achieve the second technical problem,

Fly adult breeding room (100) capable of breeding fly flies adult eggs;

Fly larva rearing room 200 for culturing fly larvae by administering organic waste to fly larvae;

A fly larva separation chamber 300 for separating the fly larva and the degraded decomposition product; And

Using the fly larva separated from the above provides a fly natural mass breeding system comprising a fly natural enemy breeding room 400 equipped with a plurality of inoculation boxes 60 and cradle 220 for breeding fly natural enemies.

According to one embodiment of the present invention, the fly adult breeding room 100 includes an air conditioner 80 and a ventilator 90, a detachable adult allegory 5, a detachable egg laying machine 6, adult food supply It is preferable to include a large number of fly adult box 10 and the cradle 20, including the barrel (7) and the water supply barrel (8).

In addition, the egg phase 6 is preferably provided with a protein feed medium containing 60 to 70% of moisture.

According to another embodiment of the present invention, the caterpillar breeding chamber 200 includes an air conditioner 180 and a ventilator 190, and includes a plurality of caterpillar breeding boxes 30 and a holder 120 capable of loading the same. Can be.

According to another embodiment of the present invention, the fly larva separation chamber 300 preferably includes a plurality of larva separation device 40 and the collector 35.

The larva separation device 40 is made of a transparent material, both edges are preferably dark conditions.

In addition, both edges of the caterpillar separator 40 is provided with a mesh having a mesh of 1 to 2mm in the lower portion, it is preferable to further include a secondary separator 45 is filled with sawdust inside.

According to a preferred embodiment of the present invention, the inoculation box 60 is in the form of a cuboid or disk, the lower portion is made of a transparent material, the ratio of the population of the fly natural and fly pupa is 1: 7 to 1:15 is preferred.

In addition, the fly pupae in the inoculation box 60 is preferably laid to a thickness of 1 ~ 13cm.

In addition, the light source 65 is preferably provided between the inoculation box 60 and the holder 120.

In order to achieve the third technical problem, the present invention includes a fly pupae inoculated with parasitic parasitic worms, the upper part of the container is provided with a mesh of 1 to 2 mm and a diameter of 0.5 to 1.0 mm at the bottom thereof. Provides a fly parasitic spinneret with many vents.

According to one embodiment of the present invention, a portion of the net is preferably applied to the honey stock solution.

In addition, the number of fly pupa contained in the container is preferably 9,000 ~ 13,000.

Hereinafter, a fly breeding system according to a preferred embodiment of the present invention will be described in more detail with reference to the drawings, but the present invention is not limited thereto.

First, as shown in Figure 1, the fly parasitic natural breeding system of the present invention, largely fly adult breeding room 100 and fly larva breeding room 200, fly larva separating room 300 and fly natural breeding room (400) )

The fly adult breeding room 100 according to the present invention preferably includes an air conditioner 80 and a ventilator 90 as a building provided with a door so that a person can enter and exit.

The size of the fly adult breeding room 100 of the present invention may be changed according to the required amount of fly larvae and the number of adult breeding box 10 installed therein.

According to an embodiment of the present invention can be made of a prefabricated building of 10m in width, 10m in height, 2m in height, the cradle 20 is 140cm in width, 45cm in height, 160cm in height, the bottom is provided with a wheel to move , Three-stage, it is preferable to be able to load three adult breeding boxes (10) per layer.

As shown in Figure 2, fly adult breeding box 10 according to the present invention may have a size of 40 × 40 × 40 cm. Although the material of the fly adult breeding box 10 is not particularly limited, it is preferable that the stainless steel is considered in consideration of durability, and all surfaces except the lower surface are made of a mesh of 1 to 2 mm mesh and one side is provided with a handle ( It is preferable to install 3). The bottom plate of the adult breeding box 10 is provided with an adult food supply container (7) and a water supply container (8) and they are communicated with the outside through the food supply pipe (17) and the water supply pipe (18), from time to time It is desirable to be designed to provide food and water. In addition, it is preferable that the adult allegory (5), chaerangi (6) is also detachably connected to the outside through the allegory connector (15) and the chafergi connector (16). On the other hand, it is preferable that the food supply container 7 and the water supply container 8 are separable.

According to a preferred embodiment of the present invention to put the pupa of flocked housefly per flies per adult fly breeding box 10 into the allegory (5), the weight of the 10,000 pupa was 190 ~ 195g. The flies that have become adult in the allegory period (5) undergo nutrient maturation from the feeding container (7) and undergo egg maturation and induce spawning in the egg phase (6) equipped with a medium. Sugar and whole milk powder were used for feeding adult flies, and breeding was carried out at 28 ± 1 ℃, 65% RH, 16: 8 LD, and water for adult growth was placed in a water supply container (8) every 24 hours. 500 ml was supplied. On the other hand, it is preferable to have a styrofoam plate or the like inside the water supply container 8, which is to prevent the fly adults fall into the water and die.

In the egg phase 6 used in the present invention, food waste or food waste transfer material may be used as a medium, but it is preferable to use a protein feed medium containing 60 to 70% of moisture. Food waste transfer material is fermented food waste, solids, synthetic resins, etc. are removed and evenly crushed, and then dried and mixed with ace or lime for desalting. For protein feed, calf feed, dog food, Chicken feed is not particularly limited. The medium provided inside the egg sheller 6 is a mixture of protein feed and water, so that the fly adult eggs are only scattered in the egg sheller 6. In this case, since the scattering amount varies depending on the mixing ratio of the moisture to the amount of protein feed, the amount of scattering is measured and the scattering amount is shown in Table 1 below.

Based on 100g of the medium and 10,000 adult housefly adults, it was measured 10 times.

Based on the results shown in Table 1, the water supply for the egg laying medium is preferably mixed 75 to 100ml of water per 100g of protein feed. If the moisture is insufficient, the egg is not spawned or the number of spawning is small. In the case of excess moisture, the spawning adult may fall into the medium, which is not preferable.

The egg stage (6) can be collected every day because most of the adult fly eggs spawn in 1 day, and generally, the adult fly life is 1 month. It is preferable to supply fly pupa using (5). On the other hand, the eggs were hatched in 28 ± 1 ℃, 65% RH, 16: 8 LD conditions because the incubation period was 12 hours, separated from the adult and left to develop in the egg phase for 1 day to completely hatch. In a preferred embodiment of the present invention the amount of fly larva that can be obtained per egg per 10,000 adult flies was 3g.

According to another embodiment of the present invention, the fly larva breeding chamber 200 includes an air conditioner 180 and a ventilator 190, including a plurality of larva breeding box 30 and the cradle 120 to load them. Can be done. The size of the fly larva rearing room 200 may vary depending on the amount of the fly larva required, and the number of larva rearing box 30 installed therein. According to one embodiment of the present invention, the fly larva breeding chamber 200 may be formed of a prefabricated building having a width of 10 m, a length of 10 m, and a height of 2 m. The number of the larva breeding box 30 is about 5,000 boxes, which is 4 tons per day. 1,000 boxes of organic waste can be recycled. The organic waste may be concentrated livestock waste, food waste, and the like, and it is preferable to use a pig meal having a low moisture content. On the other hand, the size of the caterpillar breeding box 30 is not particularly limited, but according to an embodiment of the present invention is an opaque box of 45 × 27 × 10 cm, as shown in Figure 4, the material is a plastic material desirable.

The organic waste is preferably crushed 5 ~ 10cm in the larval rearing box, more preferably 6 ~ 8cm. If the thickness of the medium is 5 cm or less, the organic waste throughput is reduced and the medium may be dried. If the thickness is 10 cm or more, the heat dissipation rate of the medium generated during the breeding period is lowered, thereby increasing the temperature of the lower feed layer and decreasing the medium utilization of the larva. There is a risk of death.

As shown in Figure 5, the cradle 50 is preferably 2.0m in length, 0.5m in length, 1.6m in height, it is preferable that the wheel is provided at the bottom. Larvae breeding box is suitable to load 15 rows with 8 rows.

Fly larva separation chamber 300 according to an embodiment of the present invention is a prefabricated building provided with a door so that a person can enter and exit, including a fly larva separation device 40, an air conditioner 280 and a ventilator 290 It is preferable. According to one embodiment of the present invention, the size of the fly larva separation chamber 300 is 5m wide, 5m long, 2m high, and the fly larva separating device installed in the area and the inside according to the required amount of fly larvae ( The number of 40 may vary. When the organic waste decomposition products and the reared fly larva decomposed in the fly larva rearing box 30 are transported and administered to the fly larva separation device 40, the fly larva is separated from the degradation product. The separation rate was over 95%.

The size of the caterpillar separator 40 is not limited, but considering the moving speed and separation efficiency of the fly larvae, it is preferable that the width of the larvae 70cm, 50cm long. The central portion of the separation device is made of a transparent material to maintain the bright conditions, both edges are preferably dark conditions. Because the fly larvae have negative daylight, they move out of the bright area and move to dark conditions at both edges. At this time, both edges of the caterpillar separator 40 is provided with a mesh having a mesh of 1 to 2mm in the lower portion, it is preferable to further include a secondary separator 45 filled with sawdust therein, the sawdust Is to supplement upwards. The secondary separator 45 is for removing foreign substances such as decomposition products buried in the body surface of the fly larva, fly larva has a miner (miner) characteristics to penetrate through the mesh of the secondary separator (45) Then, foreign matter is removed while passing through the area filled with sawdust, and then collected in the collector 35 through the opposite mesh. On the other hand, the secondary separator is designed so that the bottom is inclined toward the front, the front and rear opening and closing portion 42 is provided. Therefore, even when the fly larva does not pass completely through the secondary separator, the fly larva is taken out together with the sawdust by opening the opening and closing part 42, and the sawdust can be replenished again. By using the sawdust smaller than the size of the fly larvae in the secondary separator 45, the sawdust and the fly larvae can be easily separated by using a whisk in the final step. Most of the separated fly larvae are used to inoculate nemesis in the fly nemesis 400, but some of them are used to supplement the adult larvae.

Next, the isolated fly larva is transferred to the fly parasitic breeding room 400 to inoculate the fly parasitic. The fly parasitic breeding room 400 is a building provided with an entrance door for a person to enter and includes an air conditioner 380 and a ventilator 390, and a plurality of inoculation boxes 60 and cradles for breeding fly parasitic nemesis. 120 is provided. According to an embodiment of the present invention, the fly parasitic breeding room 400 may be made of a prefabricated building having a width of 10m, a length of 10m, and a height of 2m, and the number of the inoculation boxes 60 may be about 5,000 boxes. According to a preferred embodiment of the present invention, the inoculation box 60 may be in the form of a cuboid or disk, the lower portion is made of a transparent material, the ratio of the number of fly parasitic and fly pupa is 1: 7 to 1:30 is preferred. Do. The material of the inoculation box is not particularly limited, but a plastic material may be used, and when 100,000 pupa are introduced, the length may be 40cm in width and 30cm in height and 15cm in height. It is good to be. When the population ratio of fly parasitic to fly pupa in the inoculation box 60 is less than 1: 7, it is not economical and is not preferable because competition between fly parasitic itself in a narrow space is intensified. When it exceeds, since the inoculation rate is less than 70%, it is not preferable. On the other hand, the parasitic nematode can be administered in the inoculation box 60 through the parasitic nebulizer 65, and after inoculating for 10 days, the inoculation rate 80, after administering the parasitic nematode to the inoculation box 60 More than% can be secured. On the other hand, the pupae that have not been inoculated above become flies and become adult flies after about 5 days of administration to the inoculation box. Since the flies do not have protein and moisture in the inoculation box, they will soon die. The remaining rate of fly chrysalis can be over 95%.

The fly pupae in the inoculation box 60 is preferably laid to a thickness of 1 ~ 13cm, if it exceeds 13cm is not preferable because the inoculation rate is lowered. On the other hand, the cradle 220 is loaded with the inoculation box 60, for convenience of movement, 130cm wide, 45cm long, 160cm high, the bottom is equipped with wheels, a total of 10 boxes of four boxes per floor It is preferable to load thickly.

Since the fly parasitic nature is generally positive dichroic, when the light source 55 is provided between the inoculation box 60 and the cradle 120, the fly can be inoculated to the deep fly pupae, thereby increasing the inoculation rate. have. Experiments on this were carried out as follows.

300 housefly pupae within 24 hours of lysis and 30 mated flycatal females within 24 hours after allegory were placed in a glass tube with a diameter of 3cm and a height of 7.5cm and sealed with a net to prepare experimental and control groups. In the experimental section, all parts except the lower part were surrounded by aluminum foil, whereas in the control section, all parts were surrounded by aluminum foil to completely block the input of light. The two glass vials were placed in a paper box at 27 ° C., and then irradiated with 20 W halogen or the like at the bottom to allow light to flow into the lower part of the experimental sphere. The experiment was repeated three times, and the results are shown in Table 2 below.

As can be seen in Table 2, if the thickness of the fly chrysalis more than 6cm, the probability of inoculating fly chrysalis at the bottom of the fly is slightly lowered, the positive daylight characteristic of fly parasites It is possible to increase the inoculation rate using. As the thickness of the host fly pupae increases, the space efficiency can be increased.

On the other hand, in the inoculation box 60 may be directly put fly pupae, but may also be injected into the flies larvae of the seed state. In general, the time required for the allegory of fly pupae to fly adults is about 5 days, and the time required for practical inoculation in the inoculation box, because it takes 1 to 2 days for the parasitic prevalence of parasitic fly pupae. Is only 3-4 days. Therefore, when the fly larvae, not the fly pupae, are put into the host, the fly larvae may be the pupae during the time required for the parasitic naturalization to be advantageous in terms of securing an overall inoculation time. Inoculation of the parasitic nematode according to the present invention is preferably made under general insect breeding conditions using a red bulb.

Hereinafter will be described with respect to the fly parasitic can be used in the present invention.

Although many species of flies are known throughout the world, the domestic species are known as Muscidifurax raptor Girault and Sanders, Nasonia vitripennis (Walker), lattice, etc. Urolepis rufipes (Ashmead)), Pachycrepoideus vindamiae (Rondani), Spalangia endius Walker, Spalangia nigroaenea Curtis, Spalangia nigra Latrielle, etc. All of these can be used for fly control according to the present invention. Good natural conditions should be specific for the insect flies that are to be controlled, have good spawning capacity, have a long life, be resistant to pesticides and other external constraints, and harmless to humans or livestock. Hereinafter, the number of individuals produced per animal parasites per day, spawning rate, development period and survival rate will be described.

1. Production population

The production number per female of the domestic fly parasitic nemesis was measured and shown in Table 2 below.

As a result, the production population of the banyan fly gold bee was the largest, and the production population of the housefly gold bee was the smallest. However, since the number of females produced is at least 30, the ratio of fly parasitic to fly pupa is 1:30, which is sufficient. However, in order to achieve an inoculation rate of 80% or more in a short time, the amount of parasitic parasites is 1:30. It can be seen that it is appropriate to use more.

2. Period of spawning activity

The parasitic females are shown in Table 3 by measuring the maximum duration of the spawning activity during the survival period.

As can be seen from the above results, since the possible spawning period of the parasitic nematode used in the present invention is 15 days to 30 days, it can be seen that the inoculation box 60 according to the present invention may be inoculated for 10 days or more. Can be.

3. Developmental period of parasitic flies

After the fly parasitic spawning in the fly pupae, the maximum value of the time required to become an adult to adulthood is investigated and is shown in Table 4 below.

As can be seen from the above results, the development period is 20 to 30 days, which is related to the expiration date when the fly parasitic inoculation to fly pupa is used as a biological insecticide. In order to determine the approximate shelf life, the maximum life span of the fly parasitic adult was investigated and the results are shown in Table 5 below. The breeding conditions of the fly parasitic adult was 5% sugar water was supplied as food, the temperature was 26 ± 1 ℃, relative humidity 60 ± 5%.

The fly pupae inoculated for the first time in the inoculation box 60 according to the present invention becomes an allegory after about 20-30 days from the inoculation day, and the period of staying in the inoculation box 60, that is, the inoculation period 10 days, this allegory adult can survive up to 40 days, and during the life of the egg can be spawned 10 to 30 days, the effective shelf life of the biological pesticide according to the present invention is about 30 days or so.

On the other hand, in order to extend the shelf life can be extended by 30 days if the refrigerated fly chrysalis inoculated with parasitic parasitic storage of 65 ± 5% humidity, 0 ~ 4 ℃ temperature. When the refrigerating period is 30 days or less, the fable rate of the parasitic herbaceous nature was hardly changed. However, after 30 days, the fable rate gradually decreases.

In addition, by mixing and administering the fly chrysalis inoculated flies and the fly chrysalis not inoculated at an appropriate ratio in the fly parasitic spinning vessel described later, if the cycle of the first generation in the container is returned, the shelf life is further extended You can also In this case, it is desirable to keep the fly parasitic prey in the container.

In conclusion, the sperm fly beetle is preferable in terms of production population among the domestic flies, and the fly fly bee is best in terms of the period of maximum spawning activity and the maximum survival time, and in terms of developmental period until adulthood Housefly gold bees are most preferred. On the other hand, because the cheek-pattern fly gold zombie is a dominant species in the south coast and Jeju Island, it is better to use them in the region, in particular, in the case of fly gold zombie has a merit of a multi-parasitic on one fly pupa.

Hereinafter, a description will be given of the fly parasitic selection method according to the present invention.

In order to select the fly parasitic nephew according to the present invention, the cortex and the fly pupa are collected from the habitat of the outdoor fly pupa, and the natural enemy is selected in the natural selection device. The parasitic nematodes used in the present invention were collected from Gyeonggi-do, Songra-ri, Ssanghak-ri and Onseok-ri.

The natural selection device is known, it has a shape like a funnel overturned, the lower breeding conditions are dark conditions to attract the natural enemy to the light on the upper side, and the top of the natural enemy's attraction place is applied by feeding honey water. At this time, the collected natural enemies can be identified and classified through the external form of each natural enemy under the dissecting microscope to select the appropriate species.

Six to 10 fly parasitoids selected above are inoculated by injecting them into a 500 ml Erlenmeyer flask with 200 to 300 pupae. At this time, breeding conditions are raised at constant temperature and humidity breeding under the conditions of temperature 27 ℃, humidity 65%, 16: 8 (light: dark). After 10 days, flies died and parasitic pupae separated from parasites to be used in the continual breeding can be used in the inoculation box (60) according to the present invention after securing the appropriate amount of parasitic nematodes.

The parasitic nematodes, which are bred in large quantities in the fly natural breeding room 400, may be commercialized in a predetermined container. The fly parasitic spinning container according to the present invention includes a fly pupa inoculated with parasitic parasitic parasites, the upper part of the container is provided with a mesh of 1 to 2 mm and a plurality of vent holes having a diameter of 0.5 to 1.0 mm at the bottom thereof. It is characterized by being drilled. Although the material and size are not particularly limited, as illustrated in FIG. 9, the cylindrical shape is preferably cylindrical, and the number of fly pupa per container may be 9,000 to 13,000. The net is intended to be protected from external predators (rats, etc.), and since there is a mesh of 1 to 2 mm, there is no problem in escaping flies. In addition, if the parasitic fly pupae is present in the container, even if the fly adult via the allegory, it is to prevent the passage through the mesh, so as not to come out from the outside.

On the other hand, it is preferable that a portion of the honey is applied to the honey stock, which can be used as a premature flies parasitic prey in the container, even if the spinning yarn, etc., before leaving the container, By replenishing, it can also play a role in promoting spawning.

According to the present invention, the fly control method using the parasitic natural fly emits 30,000-100,000 flies parasitic per 100-150 pyeong of livestock farms. It is characterized by an allegory after a week has elapsed. If the number of flies is less than 30,000, it is not preferable because the fly control effect is not excellent. In addition, the parasitic flies attack only the fly pupae, not the fly eggs and larva larvae, since the spawning rate of the parasitic flies is 5 days after the allegory, 50% of all the population used than allegory at once Allegory first and the remaining 50% preferably after one week. The reason is that the fly pupae present in the stalk and the like are first attacked by 50%, and the fly larvae and fly larvae present in the sack and the like become fly pupae after about one week. This is to increase the Paris control efficiency by allowing them to attack them.

On the other hand, fly parasites do not attack fly adults, so the place where the fly parasites are not inhabited by fly larvae such as pigs or barns, but it is preferable that fly larvae such as livestock dressings are inhabited. It is desirable to spin when fly densities are 10 per hour in a 10 x 10 cm ² sticky trap. The reason is that when the fly adult density is lower than the above number, the fly pupal population is so small that there is little effect of using the fly parasite, and the fly chrysalis must be used after the density of the fly adult is maintained to some extent. This can be harmonized with the population of the fly parasitic nephew, because the fly parasitic nematode can breed.

In the case of controlling the fly using the fly parasitic spinning container, since the activity radius of the fly parasite in the container is around 10m, it is preferable that the installation interval of the container is a radius of 8 to 12m. Preferably, the container is installed in a place where rain is not exposed, and as soon as the fly parasite is discharged, the density of the fly begins to decrease, showing a reduction effect of more than 80% within one month. However, when the density of flies decreases, the fly parasitic nature based on it also decreases, and after the remarkable decrease of the fly parasitic nature, the density of the fly rapidly increases again, whereas the fly parasitic density cannot follow this. Therefore, it is preferable to radiate fly parasites again at one month intervals.

As described above, according to the present invention, a large number of flies parasitic natural species can be bred in a simple manner, and when the flies are controlled using them, unlike conventional chemical remedies, they are environmentally friendly, so they are not used for humans and animals. The fly control effect is very good and lasting without any damage. On the other hand, the fly parasitic radiation container according to the present invention is easy to store the fly parasitic neat, there is an advantage that the use is very simple.

Claims (14)

A separate adult food and water container communicating with the outside via a food supply and a water supply; An adult fly flock and a chafergi that are detachably connected to the outside through an allegorical connector and a chariot connector, and all surfaces except the lower surface are made of a mesh of 1 to 2 mm mesh. 2. The adult fly breeding apparatus according to claim 1, wherein the egg laying apparatus is provided with a protein feed medium containing 60 to 70% of water. Adult fly flies capable of breeding fly flies and eggs; Fly larva rearing room for cultivating fly larvae by administering organic waste to fly larvae; A fly larva separation chamber for separating the fly larvae and the degraded decomposition products; And A fly natural mass breeding system including a fly natural predator having a plurality of inoculation boxes and cradles for breeding fly natural enemies using the isolated fly larvae. According to claim 3, The adult fly breeding room includes an air conditioner and a ventilator, fly natural mass breeding system, characterized in that it comprises a plurality of adult breeding device and the cradle. According to claim 3, The caterpillar breeding room includes an air conditioner and a ventilator, a fly natural mass breeding system, characterized in that it comprises a plurality of larval breeding box and cradle. According to claim 3, The larval separation chamber is a fly natural mass breeding system, characterized in that it comprises a plurality of larval separator and collector. According to claim 6, The caterpillar separation device is made of a transparent material, both ends of the fly natural mass breeding system, characterized in that the dark condition. According to claim 6, Both edges of the caterpillar separation device is provided with a wire mesh having a mesh of 1 ~ 2mm in the lower portion, the inside of the fly natural mass breeding system further comprises a secondary separator is filled with sawdust . According to claim 3, The inoculation box is rectangular or disk-shaped, the lower part is made of a transparent material, the fly natural mass breeding system, characterized in that the population ratio of fly natural and fly pupa is 1: 7 to 1:30. The fly natural mass breeding system according to claim 3, wherein a light source is provided between the inoculation box and the holder. The fly natural mass breeding system according to claim 3, wherein the fly pupae in the inoculation box are laid with a thickness of 1 to 13 cm. A fly parachute inoculated with fly parasitic inoculation, the upper part of the container is equipped with a mesh of 1-2 mm and the lower part of the parasitic parasitic spinning vessel with a plurality of vent holes 0.5 to 1.0 mm in diameter. 13. The fly parasitic spinning container according to claim 12, wherein a part of the net is coated with a honey stock solution. 13. The fly parasitic spinning container according to claim 12, wherein the number of fly pupa contained in the container is 9,000 to 13,000.