KR100475522B1 - The rearing equipment for luciola lateralis and the rearing method - Google Patents

Abstract

The present invention relates to a breeding device and a breeding method of the firefly.

The firefly breeding device of the present invention, the container which can observe the inside; It is located in the container, and larva growth portion that allows the larvae to grow by themselves while the stones and gravel are submerged; An oxygen supply means for supplying oxygen to the water of the larva growth portion so that the larvae and the prey can live underwater; Towa forming part that the larva moves by itself to form a towa in the moist soil and the pupa; When the pupa escapes and becomes an adult, the blade of grass can be placed for spawning, and it is located in the upper part of the larva growth part. Eggs are firefly larvae scattered down through the hole to fall into the larva growth portion; is configured to include.

According to the present invention, there is provided a device capable of breeding fireflies, and the breeding of the fireflies can be carried out using this breeding device.

Description

The breeding device of the firefly and its breeding method {THE REARING EQUIPMENT FOR LUCIOLA LATERALIS AND THE REARING METHOD}

The present invention relates to a device for breeding a firefly that is very resistant to air pollution and water pollution, and a breeding method thereof.

The firefly is an insect belonging to Coleoptera, Lampyridae, which glows itself and is a rare insect that lives around a private house.

These fireflies are known to inhabit more than 200 species worldwide, but in Korea, the large brown firefly (Drilaster unicolor) with the subfamily Dirlastinae, the firefly (Luciola laterlais) of the subfamily Luciolinae, and the Lucian unmunsana (Luciola unmunsana) ), Only a few were identified: Hotaria papariensis, Northern firefly (Lampyris noctiluca), Royal firefly (Lucidina accensa), Flower firefly (Lucidina biplagiata), and late firefly (Pyrocoelia rufa).

All fireflies found in Korea are species that emit light during adulthood and are very rare species.

Fireflies are insects that live only in clean environments due to their low resistance to pollution, and are becoming extinct due to recent industrialization and urbanization.

For this reason, fireflies are important as environmental indicator organisms that can be used to measure environmental pollution.

 In particular, fireflies are not only air pollutants but also very resistant to water pollution, so they do not live in areas where water quality is not clear, and thus are important as indicator organisms for measuring water quality.

By the way, it is difficult to collect fireflies in the past, and the lifespan of the adult was short, about 10 to 23 days, which made it difficult to proceed the physiological and ecological studies of fireflies.

In addition, as a device for breeding insects, "Aetin-norin food feeding method and apparatus (Korean Patent Publication No. 2002-0067369), etc. have been devised a number of devices, but a device for cultivating and propagating firefly was not created.

Therefore, it was not possible to breed ordinary fireflies, but also fireflies, which are our native fireflies, and prevent their extinction.

The present invention is intended to solve the above problems, and more specifically, the purpose of the breeding of fireflies to prevent the extinction of fireflies, which are native fireflies.

There is also an object to provide a device capable of mass breeding fireflies.

The present invention relates to a breeding device and method of the firefly.

The apparatus of the present invention includes a scattering portion for inducing the scattering of the firefly adult to collect the eggs of the firefly, and hatch the collected eggs to obtain the firefly larvae.

In addition, the hatched small firefly larva is equipped with a larva growth part in which sand and gravel are submerged in a place where the larva can be located by itself, so that the firefly larvae escapes four times and sleeps, and is cultivated in the larval growth zone until the pupa becomes pupa.

Also, the larvae of the larvae grow in the place where the larvae can be moved by themselves, and the moss is formed in the soil forming part. do.

In addition, by maintaining the temperature of the tow forming portion at an appropriate temperature to become an adult in the pupa, this adult is induced to scatter again in the scattering portion.

Hereinafter, the technical idea of the present invention will be described in more detail with reference to experimental examples.

The inventors of the present application have observed that the habitat of the firefly in the Chungcheongbuk-do has common features.

In other words, it was found that the area of the firefly had a tributary stream, agricultural waterway, or paddy field in the valley, where the water was present, and the flow rate of these areas was relatively slow or stagnant.

This was in conflict with the claim that the firefly's habitat was around a large river or where the flow velocity was relatively high.

In addition, tributaries, agricultural water and rice paddies around the habitat were conditions under which clarified water quality could be maintained.

In fact, the water quality surrounding the firefly habitat was relatively clarified with pH 6.0-8.1.

In addition, there was no big road around the habitat of the firefly, so there was no traffic and no street lights. This was the basis for judging that the firefly's act of emitting light is for mating.

The inventors of the present application carried out various experiments as follows to observe the ecology of the firefly in more detail.

By the way, the survival time of the adults of the firefly is very short, so in order to derive the results of the experiment in a short time, a lot of experiments for the experiment had to be prepared.

For this reason, various test zones were prepared as follows.

<Test 1 to Test 10>

Experimental Method-Construct an experimental vessel for observation, and form a soil layer on the outside of the sand layer and the sand layer on the outside of the water reservoir and the water reservoir so that the inside of the experimental vessel is in an environment similar to the habitat where the firefly was collected. It was.

The water of the water storage unit was to maintain a hydrogen ion concentration (pH) of 7.1 ~ 7.7, the soil of the soil layer was used a soil with a hydrogen ion concentration (pH) of 6.3 ~ 6.5.

Also, sand, gravel, and small stones collected from the habitat's water are placed in the water reservoir, and moss, plants, grass, and small trees collected from the waterside of the habitat are located near the water. Located.

In addition, the inner temperature of the experimental vessel was maintained at 20 ~ 25 ℃ similar to the temperature of the area where the firefly was collected, and the natural light, but the illumination was installed so that the visibility can be confirmed at night.

In the water reservoir, small shellfish and beetles were collected from the waters around the habitat, and the pair of adult firefly adults collected in the experimental vessel were observed.

Results-All adults died between 13 and 20 days, but no specifics were found during the survival of the firefly, and they died at the end of their lives, given the adult survival of other test sites and the appearance of firefly in nature. Allegedly, scattering was not confirmed.

<Test Tool 11 to Test Tool 20>

Experimental Method-The illumination was to let natural light, and completely blocked the light from 20 o'clock to 06 o'clock. Other conditions were made into the same conditions as Test 1-Test 10.

Results-After 8 to 11 days, oval eggs of about 0.6 * 0.5 mm were spawned for 5 to 7 days in moss and plants around the water reservoir. In addition, after 13-20 days after the adult was added, all the adults died, and the number of laying eggs was 106-191 per female.

<Test 21-Test 30>

Experimental method-The lamp was used to emit light at the same time as the natural condition, and the light was completely blocked until 20 ~ 06. The outer part of the water reservoir forms a layer of sand, and in part, a layer of soil. Other conditions were made into the conditions similar to the test strip 1-the test strip 10.

Results-After 8-11 days spawning for 5-7 days in moss and myelin surrounding the water reservoir. In addition, after 12 to 20 days after the adult was injected, the adult died at the end of its life, and the number of laying eggs was 103 to 189 per female.

<Test 31-Test 40>

Experimental method-The lamp was radiated at the same time as the natural conditions by using a light bulb, and the light was blocked until 20 o'clock to 06 o'clock, but the light was irradiated for 20 minutes at 3 hour intervals. The other conditions were the same as those of Test 1 to Test 10.

Results-After 8-11 days spawning for 5-7 days in moss and myelin surrounding the water reservoir. In addition, 12 to 20 days after the adult was introduced, the adult died at the end of its life. The number of eggs laid was 63 to 137 per female.

<Test Zone 41 to Test Zone 50>

Experimental Method-The illumination was to let natural light, and completely blocked the light from 20 o'clock to 06 o'clock. In addition, the water of the water storage part was kept at a hydrogen ion concentration (pH) of 5.5 to 6.0, and the soil of the soil layer was a soil having a hydrogen ion concentration (pH) of 5.0 to 5.4. The other conditions were the same as those of Test 1 to Test 10.

Results-After 8 to 11 days of feeding, the eggs were spawned for 5 to 7 days in moss and plants around the water reservoir. In addition, 13 to 20 days after the adult was introduced, the adult died at the end of its life. The number of eggs spawned was 105 to 193 per female.

<Test 51-Test 60>

Experimental Method-The illumination was made to be natural light, and the light was completely blocked until 20 o'clock to 06 o'clock. As for the soil of the soil layer, soil having a hydrogen ion concentration (pH) of 5.0 to 5.4 was used. The other conditions were the same as those of Test 1 to Test 10.

Results-After 8 to 11 days, the eggs were spawned for 5 to 7 days in the moss and myelin surrounding the water reservoir. After 16 to 20 days, the adults were all dead and died. The number of eggs spawned was 102 to 190 per female.

CONCLUSIONS: There is a correlation between the scattering and the lighting of the firefly, and it is confirmed that the lighting of the firefly affects the scattering of the firefly.

In addition, it was confirmed that the difference between artificial lighting and natural lighting was not significantly different with the scattering of the firefly and that the firefly spawns in the moss or plants around the waterside when spawning.

In order to hatch the eggs of the firefly obtained through the above experiment, test spheres 11 to 60 were exposed to natural light, and placed in a place where the light was completely blocked at night, while maintaining the internal temperature of the experimental vessel at an outdoor temperature. Observed.

However, since it was possible to perform a reliable experiment without causing an artificial environmental change, the hatching quantity was measured only under the microscope for the three test pieces with the largest number of eggs in each group.

As a result, the result as shown in <Table 1> was obtained.

<Table 1> Observation of the growth of the firefly

division result June to July July to August August to October November to December January to February March to April May to June 10 days pass 20 days pass 50 days pass Elapsed 110 Days 170 days pass Elapsed 230 260 days have passed 300 days pass Test port 11 to test port 20 50-73 eggs 77-135 hatching 3 times larva found in water Larva dormant after one additional molt. Larva is dormant Larva's feeding activity resumed Towawa forms on the soil layer. 56-101 adult Test sphere 21 to test sphere 30 46 to 68 hatching 75-136 hatching 3 times larva found in water Larva dormant after one additional molt. Larva is dormant Larva's feeding activity resumed Towawa forms on the soil layer. Adults 55-143 Test sphere 31 to test sphere 40 27 to 63 hatching 45-99 hatching 3 times larva found in water Larva dormant after one additional molt. Larva is dormant Larva's feeding activity resumed Towawa forms on the soil layer. 32 to 75 adults Test port 41 to test port 50 51-81 hatching 76 to 137 hatching No larvae found No change No change No change No change No change Test block 51 to test block 60 53-80 hatch 74 to 136 hatching 3 times larva found in water Larva dormant after one additional molt. Larva is dormant Larva's feeding activity resumed Towawa forms on the soil layer. 8 to 13 adults

Conclusion-Through the above process, it can be seen that the larvae awakened from eggs laid 10 to 20 days after the adult larvae spawn, and the larvae are small enough to be identified with the naked eye, and live in water immediately. Could.

Also, the larvae of larvae live in the water and feed on shellfish such as stalks and shellfish, and grow until the end of October.Then, they molt four times in the process and then sleep in the water from November to February. Could know.

Also, it was found that the firefly larvae ended dormant around March, and when the dormant ended, they had been fed for about three months and then went up to the soil layer to form a paw and become a pupa.

In addition, it was found that the pupae period is about 30 to 40 days, and adulthood occurs in June to July when the pupa period ends.

In addition, it was found that the firefly larvae cannot survive when the pH is 6.0 or less among the physicochemical properties of the water quality of the water.

In addition, the firefly found that too low pH among the physicochemical properties of the larvae that form the paws impedes the growth of the firefly.

The inventor of the present application has produced a firefly breeding device based on the conclusion obtained through the above experiment.

The firefly breeding device of the present invention,

A container capable of observing the interior;

It is located in the container, and the larva growth portion is sand and gravel and stone submerged.

In addition, oxygen supply means for supplying oxygen to the water of the larva growth portion;

The larvae of the larvae growth part to be located by moving the larvae by themselves, moist soil formed in the soil; Has

In addition, it is located in the upper part of the larva growth part, connected to the vomit forming part, the scattering part is formed with a number of holes the size of the larvae through which the larvae waking from the egg can pass, and settle the blades of grass Has;

Hereinafter, the firefly breeding apparatus of the present invention will be described in more detail with reference to the accompanying drawings.

However, since the accompanying drawings are only examples for describing the technical idea of the present invention in more detail, the technical idea of the present invention is not limited to the accompanying drawings.

The container 10, which is a component of the present invention, enables the breeding state of the firefly to be observed, and the environment of the place where the firefly is located, that is, a condition such as temperature or lighting is formed under the condition that the firefly can be bred. To help.

Therefore, the container 10 is preferably made of a transparent material that can be observed inside.

The larva growth unit 20, which is a component of the present invention, is a part which allows the larvae to grow while living.

By the way, the firefly larva lives in water unlike the common firefly larva lives in the soil, so the larva growth part is the part where water is stored.

In addition, the larva is a nocturnal larvae, and when there is a light to hide because the larva growth unit 20 has learned that the conditions for hiding the larva should be formed.

For this purpose, there is a method of submerging the sand (21) and small pebbles (22) or stones.

When you put stones, it is desirable that some of the stones be exposed above the surface of the water and that the water depth is not too deep.

Oxygen supply means 30 of the present invention is a means for supplying oxygen to the water of the larva growth.

In other words, in order for the firefly to survive not only larvae, but also shellfish such as marshmallow or water beetle, the amount of dissolved oxygen is important, so oxygen is supplied through the oxygen supply means.

Examples of such oxygen supply means 30 are various methods.

Specifically, there is a method of supplying oxygen through a small oxygen supply unit installed in a general household fish tank.

Another method is to supply oxygen from an oxygen cylinder in which oxygen is stored.

Towa forming unit 40, which is a component of the present invention is to provide a condition that can form a towa for the larva pupae larva after a dormant period after growth.

Therefore, the soil to be formed in the towa 40 (40).

However, the experiment showed that the larvae must not be dry in order for the larvae to form a towa.

They also found that mud mixed with clay made it difficult to form towa.

Therefore, the soil settled in the soil forming unit 40 should be kept moist, and the soil is suitable for sandy soil.

In addition, because the firefly larva goes to find the place where the soil by instinct, the towa forming unit 40 must be installed in a place where the firefly larva can be moved by themselves can be formed by the firefly worms themselves. .

The scattering unit 50, which is a component of the present invention, is intended to provide a condition under which a nymph firefly adult may be spawned.

Therefore, the scattering unit 50 should be able to place the moss, plants, leaves, etc., should be located around the larva growth unit (20).

In addition, the larvae awakened from eggs scattered on moss littered with firefly larvae are very small and cannot move by their own power, so they cannot find water. Do.

In addition, the scattering unit 50 is to be connected to the vomit forming section 40 so that the adult after the pupa process can move.

In the present invention, for this purpose, the scattering unit 50 is placed on the upper part of the larval growth unit 20, and the plurality of holes larvae are formed by forming a plurality of holes 51 having a size through which the larvae awakened from eggs can pass. Fall down through the hole 51 to fall naturally into the water.

The scattering unit 50 can be separated and combined with the container 10 so that the scattering unit 50 can be used by being coupled to the container 10 only when the adult of the firefly appears.

This configuration is convenient because the firefly feeds the larvae or checks the status of the firefly, so the hand or work tool does not get caught in any part of the container.

As a result of breeding the firefly using the breeding device of the firefly configured as described above, it was possible to breed the firefly.

The breeding method was as follows.

<Breeding method>

Stage 1-Scattering Induction Stage

The firefly was collected at night in the habitat of the firefly and placed inside the container, and the leaves and moss were placed in the spawning area. The spawning was induced by maintaining the temperature at 20-25 ° C.

In addition, the container was placed in natural light and completely blocked at night.

Stage 2-Larva Collection

After spawning, the larvae hatched from the eggs of the firefly obtained through the spawning step by maintaining the temperature inside the vessel at 20-25 ° C.

Stage 3-Larva Culture

Oxygen was supplied while maintaining the hydrogen ion concentration (pH) of the larval growth portion at 7 and maintaining the water temperature at 19 ° C.

In addition, from the time the larvae hatched, the larvae continued to feed foods such as Dasslegi until they took off the slough four times and entered the dormant stage.

In addition, it was eaten by the firefly to remove the shells, such as marshmallow, so as to prevent water pollution.

Stage 4-Sleep Stage

After the firefly larvae took off the water four times, the temperature of the larval growth part was gradually lowered from 0 to -5 ° C over 2 months, and then gradually increased to 15 ° C over 2 months to maintain the water temperature from November to February.

Stage 5-Post-dormant Larva Culture

When the dormant stage of the firefly larvae is finished, the foods such as marshmallow are continuously added again, and the water temperature is maintained at 21 to 25 ° C.

Stage 6-Metamorphosis Induction Stage

When the firefly larvae deviated from the larval growth zone and formed the towada in the toe forming part, the temperature inside the container was maintained at 20 to 23 ° C. so that the firefly larvae were pupa.

Stage 7-Adult Culture Stage

The temperature inside the vessel was kept at 10-25 ° C. to allow the emergence of the adult from the pupa.

The inventors of the present application conducted an experiment using the firefly breeding apparatus of the present invention to reveal the relationship between the temperature and the hatching rate of the firefly, and the results as shown in Table 2 were obtained.

<Table 2> Egg duration and hatching rate of firefly according to temperature

Temperature (℃) Number of Disclosures () Egg period (days) Incubation rate (%) Remarks 10 70.1 Not hatched 0 Experiment with 5 test pieces for each unit. 15 185.3 43.0 61.5 20 123.2 24.5 73.9 25 139.1 15.6 71.8 30 70.9 Not hatched 0

In addition, in order to reveal the relationship between the temperature and the larva period and pupa period of the firefly, the experiment using the firefly breeding device of the present invention was obtained, as shown in <Table 3>.

<Table 3> Larvae, pupa and adult lifespan of fireflies according to temperature

Temperature (℃) Larvae (days) Chrysalis period (days) Adult lifespan (days) Remarks ♀ ♂ 10 0 0 0 0 Experiment with 5 test zones for each unit. 15 306.6 64.7 22.0 13.0 20 265.5 39.7 20.0 13.5 25 250.0 29.3 19.3 21.5 30 0 0 0 0

Through the experiment as described above it was possible to know the optimum conditions for the breeding of fireflies.

Reference numeral 15 is a lid covering the top of the container, 23 is water surface, 60 is a drain.

According to the present invention, it is possible to provide a device capable of breeding fireflies, and to proceed with more specific research on the ecology of the fireflies, and to prevent the extinction by breeding the extinct fireflies in large quantities.

In addition, it is possible to breed large numbers of fireflies so that the fireflies can be used for various experiments.

1 is a schematic view of the breeding device of the firefly of the present invention

Figure 2 is a cross-sectional view of the breeding device of the firefly of the present invention

Figure 3 is a block diagram for explaining the firefly breeding method of the present invention

<Explanation of symbols for main parts of drawing>

10. Container 15. Cover

20. Larva growth part 21. Sand

22. Gravel 23. Sleep

30. Oxygen supply means 40. Tow forming part

41. Soil 50. Scattering Area

51.Hole 60.Drain

Claims (3)

In the device which can raise a firefly, A container capable of observing the interior; A larval growth portion located in the vessel, in which sand and gravel are submerged by clarified water having a hydrogen ion concentration (ph) of 7.0 to 7.7; Oxygen supply means for supplying oxygen to the water of the larval growth portion; The larvae of the larvae of the larvae growth portion is to be moved to be located by themselves, the soil swelling forming a moist soil with a hydrogen ion concentration (ph) of 5.5 to 6.5; Located in the upper part of the larva growth portion, and connected to the vomit forming portion, the worms waking up from the egg is formed with a number of holes through which the size of the larva can pass, and settles the blades of grass It is a spawning place of the adult through the spawning larvae fall through the hole so that the falling to the larva growth portion; spawning device of the firefly configured including. The method of claim 1, The scattering unit, the breeding device of the firefly, characterized in that the separation and coupling with the container. A container capable of observing the interior; A larval growth portion located in the vessel, in which sand and gravel are submerged by clarified water having a hydrogen ion concentration (ph) of 7.0 to 7.7; Oxygen supply means for supplying oxygen to the water of the larval growth portion; The larvae of the larvae of the larvae growth portion is to be moved to be located by themselves, the soil swelling forming a moist soil with a hydrogen ion concentration (ph) of 5.5 to 6.5; Breeding of the firefly comprising a; larvae located in the upper part of the larvae growth, connected to the towado forming part, the plurality of holes formed in the size of the larva through which the larvae awakened from the egg; Place the device in the place where natural light shines, the leaves and moss in the scattering part, and put the adult firefly to keep the temperature at 20 ~ 25 ℃, at night, the spawning induction step to induce spawning by blocking the light completely ; A larvae collecting step in which the larvae are hatched from the eggs of the firefly obtained through the spawning step by maintaining the temperature inside the container even after spawning of the firefly; A larval culture step of continuously supplying oxygen while maintaining the water temperature of the larva growing part at about 19 ° C. and feeding the larvae and the like from the time when the larvae hatch to hatch until the larvae take off the slough and enter the dormant phase; If the larvae take off the larvae four times, the water temperature of the larva growth portion gradually lowered to 0 ~ 5 ℃ over two months and then dormant step to raise the image to 15 ℃ gradually over two months; When the dormant phase of the larva larvae is terminated, and then continuously feeding the food, such as marshmallow, and after the dormant larval culture stage to maintain the water temperature of 21 ~ 25 ℃; Transformation of the firefly larvae to keep the temperature inside the container at 20 to 23 ° C. at the time when the larva leaves the larvae growth zone to form a towa to the towada forming unit; Adult breeding step of maintaining the temperature inside the container to 10-25 ℃ to emerge from the pupa; method of breeding firefly