KR101315260B1 - An apparatus and methods producing chlorine dioxide gas for prevention and treatment of honey bee diseases containing sacbrood - Google Patents

Abstract

The chlorine dioxide gas disinfection device for the prevention and treatment of infectious diseases of bees, including the cystic beetle decay disease of the present invention, Chlorine dioxide gas disinfection device installed in the bee hives, the cradle; A printed circuit board installed at a side of the holder and provided with an ultraviolet LED; A power supply unit applying power to the printed circuit board; And a drug storage unit installed in a holder of a portion facing the ultraviolet LED and containing stabilized chlorine dioxide.
Accordingly, the bee viral infectious disease, a representative example of an infectious infectious disease caused by honeybee larvae and adult insects, is injected into a beehive by injecting chlorine dioxide gas, which is heavier than air generated by irradiating UV light into stabilized dichlorine. It is effective in preventing or treating cystic beetle rot (Sacbrood).

Description

Apparatus and methods producing chlorine dioxide gas for prevention and treatment of honey bee diseases containing sacbrood

The present invention relates to a chlorine dioxide gas disinfection device, and more particularly to a chlorine dioxide gas disinfection device for the prevention and treatment of infectious diseases of bees, including cystic beetle rot.

In general, bee infectious diseases can be divided into bacterial, fungal, viral and protozoan infectious diseases, depending on the pathogen.

Bacterial epidemics include American foulbrood (AFB) and European foulbrood (EFB), and fungal infectious diseases include chalkbrood, and viral infectious diseases include paralysis and cystitis. Sacbrood, etc., and protozoan infectious diseases include nosema disease.

Without preventive management of these diseases, thorough control is very important because economic losses cannot be avoided, no matter how well treated after the occurrence of the disease.

In particular, the major diseases that occur in the larvae of bees include brood, cystic beetle rot, chalk.

Buzzer disease is a generic term called buzzer disease that causes larvae to rot and kill larvae. These buzzers are divided into US buzzers and European buzzers according to pathogens. The US buzzers are the most feared bacterial diseases among the larvae, and the pathogen is a spore-forming bacterium and the causative agent is Paenibacillus larvae. The pathogen of the European buzzer is Melissococcus pluton White, which is lighter than the US buzzer.

Cystic beetle rot (sacbrood) is a viral disease, unlike the bacterial disease buzzer is a disease that is similar to buzzer in that the larvae decay in the honeycomb, but is a completely different disease.

The initial appearance of the disease is similar to the appearance of blisters, also called sacbrood (sacbrood). The diseased larvae start to fill up with fluid as if the body is blistered, and the skin starts to harden. The body gradually turns gray from white to brown to grey-brown from the head, and later turns to dark brown, leaving a dry honeycomb.

The size of the hospital virus is about 30 nanometers (nm) and stays in the body of the adult bee and multiplies, and then the virus particles enter the body of the larva. Symptoms begin on the second day of infection, and one dead larva is one of the diseases that requires alertness because it has the amount of virus that can kill as many as one million larvae. The diseased larvae can't shed their sloughs, they can't become pupa, they can't become adults, they die and rot in consumption, causing severe decay.

Not only in Korea, but also in Europe, the United States, Southeast Asia, China, and Japan, the disease is occurring everywhere, causing great damage. Since there is no cure for this disease, which is a viral disease, only preventive therapy, which is a passive method through thorough control, was the best means, and in case of infection, bees and honeycombs had to be isolated and incinerated. In order to prevent the spread of disease for healthy bees, it was sprayed with disinfectant around bee cages, beekeepers and beehives.

Such beetle rot disease is a viral disease that commonly occurs in Western bees, but in Asia, there are cystic beetle rot disease that occurs in Western bees and oriental bee rot bug disease that occurs in Asian bees. It is called sacbrood virus or thai sacbrood virus.

Recently, the Chinese sacbrood virus (CSBV) has been reported from the Asian bee (Apis cerana), which has been indigenous to the Asian continent for many years and has evolved with Asian bees. It is found with Asian honey bees in almost all Asian countries, where Pakistan, Nepal, Nepal and Asian honey bees are distributed. Cytomegalovirus rot virus caused by domestic native bee in 2010 was found to be infected by Apsi cerana among European genotype, Far Eastern Asian genotype and South Africa genotype. It was analyzed regionally (National Veterinary Research and Quarantine Service Report).

Cystic beetle rot has been reported to infect larvae through secretions from the glands of nurse bees. The disease was already prevalent in Europe and the Americas in 2007, killing 75% of all bees and causing significant damage to the beekeeping industry.In Korea, the disease began to occur in the spring of 2010 and spread throughout the country, killing more than 90%. Therefore, the damage is serious. The disease develops in the early spring, when the larvae develop. The symptoms of the disease vary depending on the degree of the condition, but are usually slightly irregular, with two or three fires spreading all over the place. If you look inside through this hole, you can see a dead larva that turns blackish brown in a fire station. Characteristically, there are no treatments and preventive drugs for infectious viral diseases of neutropenia, which is the best prevention.

Disinfectants for infectious diseases caused by viruses include chemicals such as formaldehyde, methyl bromide, and ethylene oxide, but they are environmentally harmful substances that cause the destruction of the ozone layer. Exposure to humans is fatal and even designated as a carcinogen.

Accordingly, as an alternative to the disinfectant disinfectant, chlorine dioxide, which is excellent in sterilization and sterilization of bacteria, fungi, and spores, as well as viruses, is used without any abnormality in stability.

The biochemical mode of inactivation of bacteria by chlorine dioxide has been reported to be due to disruption of protein synthesis (Benarde, MA, et al. 1967. Kinetics and Mechanism of Bacterial Disinfection by Chlorine Dioxide.Applied Microbiology. 15 (2): 257. In the case of viruses, chlorine dioxide preferentially inactivates foreign protein layers rather than nucleic acids (Noss, C., W. Dennis, and V. Olivieri. 1985. Reactivity of Chlorine Dioxide with Nucleic Acids and Proteins.In R. Jolley (ed.), Water Chlorination: Environmental Impact and Health Effects.Lewis Publishers, Chelsea, MI., .Olivieri, VP, et al. 1985.Mode of Action of Chlorine Dioxide on Selected Viruses. In R. Jolley (ed.), Water Chlorination: Environmental Impact and Health Effects.Lewis Publishers, Chelsea, MI.

 As such, chlorine dioxide which has been used for a long time with the excellent efficacy of sterilization and sterilization disinfection is exploded when the gas concentration is 10% or higher, so it is usually impossible to store or transport it. Due to difficulties in the transport and handling process, alkaline salts are reacted and stabilized. This is called stabilized chlorine dioxide.

Stabilized chlorine dioxide itself has no sterilizing and sterilizing effect, so when used as a disinfectant disinfectant, it is inconvenient to break down the stabilized structure by adding acid to generate chlorine dioxide gas, and chlorine dioxide is a yellowish green gas. Because it is easily soluble in water, chlorine dioxide in aqueous solution can oxidize and kill viruses and bacteria, but gaseous chlorine dioxide has the disadvantages of corrosion and space application when using liquid chlorine dioxide. It is known that even at lower concentrations than liquid chlorine dioxide, it has excellent sterilizing power, easy penetration, and no corrosion effect.

Recent reports on the suppression of infectivity of viruses using chlorine dioxide gas reported that 15 minutes of exposure to low concentrations of 0.03 ppm inhibited the infectivity of mice with influenza A virus (Ogata N & Shibata T. 2008 Protective effect of low). (concentration chlorine dioxide gas against influenza A virus infection.J Gen Virol.), and 0.05 ppm was able to inactivate all viruses with or without gram-positive, negative bacteria and envelopes on wet glass surfaces within 5 hours. (Morino H. et al. 2011 Effect of low-concentration chlorine dioxide gas against surface bacteria and virses on a glass surface in wet environments.Lett Appl Microbiol doi: 10.1111 / j.1472-165X). It can be seen that chlorine dioxide gas can control various microorganisms including viruses.

Thus, the use of chlorine dioxide, which has proven its ability to sterilize and sterilize bacteria, fungi and spores, as well as viruses, to improve bee-digestive disease, which is a deadly viral disease of bees Development of a chlorine gas disinfection device is required.

Disclosure of the Invention An object of the present invention is a representative case of an infectious infectious disease that occurs in larvae and adults of bees (bees), which is effective in the prevention and treatment of sacbrood, a viral infectious disease of bees that has not been treated until now. It is to provide a chlorine dioxide gas disinfection device for the prevention and treatment of infectious diseases of bees, including worm beetle rot disease configured to use chlorine gas.

A chlorine dioxide gas disinfection device for the prevention and treatment of infectious diseases of bees, including the insect worms decay disease of the present invention for achieving the above object, in the chlorine dioxide gas disinfection device installed in the bee hives, cradle; A printed circuit board installed at a side of the holder and provided with an ultraviolet LED; A power supply unit applying power to the printed circuit board; And it is installed on the cradle of the portion facing the ultraviolet LED and the drug storage unit containing the stabilized chlorine dioxide; characterized in that it comprises a.

In addition, the stabilized chlorine dioxide is characterized in that the semi-solid gel or liquid or solid.

In addition, the power supply unit is characterized by consisting of an AC to DC converter (AC to DC converter) for changing the battery or AC power to DC power to apply a DC power of 3 to 9 volts to the printed circuit board.

In addition, the printed circuit board is characterized in that the switching unit for adjusting the operating time is provided.

In the chlorine dioxide gas disinfection device is installed in the beekeeping bee according to another embodiment of the present invention, the drug storage unit is installed inside the top of the beekeeping bee and stored stabilizing chlorine dioxide; including the stabilizing chlorine dioxide is a liquid or It is formed as a solid, characterized in that to generate an chlorine dioxide gas by adding an acid to the stabilized chlorine dioxide.

A chlorine dioxide gas disinfection device installed in a beekeeping bee according to another embodiment of the present invention, the chemical storage unit is installed inside the top of the beekeeping bee and the liquid stabilized chlorine dioxide; And injection means for injecting the liquid stabilized chlorine dioxide contained in the drug storage unit, wherein the injection means is configured as an ultrasonic wave generator or a spray generator to generate chlorine dioxide gas.

According to the chlorine dioxide gas disinfection device for the prevention and treatment of infectious diseases of bees, including wormworm rot decay according to the present invention, chlorine dioxide gas that is heavier than the air generated by irradiating ultraviolet rays by UV LED to stabilized chlorine It is effective in preventing or treating sacbrood, a viral infectious disease of bees, which is a representative case of an infectious infectious disease that occurs in larvae and adults of bees by being injected into a beehive.

Accordingly, the use of chlorine dioxide gas minimizes the damage of native bees caused by major diseases such as wormworm rot disease, and effectively prevents the collective death of bees to enable the growth of strong bees.

In addition, the deodorizing action of the dilute chlorine reduces the odor caused by the death of the larvae caused by cystic beetle rot disease, thereby preventing native bees from leaving the beehive.

In addition, the economy is improved, such as labor force reduction, cost reduction, and productivity improvement due to the prevention of honey bees, such as honey farm worms and rots.

In addition, by installing the chlorine dioxide gas disinfection device of the present invention on the beehive, it is convenient to use at a low cost because it can be used indoors as well as outdoors (fields, valleys, mountains) as well as indoors (fields, valleys, mountains).

1 is a perspective view showing a general bee hives.
Figure 2 is a perspective view showing a chlorine dioxide gas disinfection device according to the present invention.
Figure 3a is a view showing the actual installation of the chlorine dioxide gas disinfection device according to the present invention.
3B is a view illustrating a state in which the ultraviolet LED of FIG. 3A is turned on and emits light.
4 is a diagram illustrating the printed circuit board of FIG. 2.
FIG. 5 is a circuit diagram illustrating a circuit configuration of the printed circuit board of FIG. 4.
Figure 6 is a graph comparing the amount of chlorine dioxide generation by time from the chlorine dioxide gas disinfection device.
7 is a graph comparing mortality of native bee groups according to whether chlorine dioxide gas is applied in native bee farms.

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

1 is a perspective view showing a bee hives in general, Figure 2 is a perspective view showing a chlorine dioxide gas disinfection device according to the present invention, Figure 3a is a view showing the actual installation state of the chlorine dioxide gas disinfection device according to the present invention 3B is a view showing a state in which the ultraviolet LED is turned on and emits light, FIG. 4 is a view showing the printed circuit board of FIG. 2, and FIG. 5 is a view showing the circuit configuration of the printed circuit board of FIG. 4. 6 is a graph comparing the amount of chlorine dioxide generation by time from the chlorine dioxide gas disinfection device, and FIG. 7 is a graph comparing mortality of native bee groups according to whether chlorine dioxide gas is applied to native bee farms.

Prior to explaining the chlorine dioxide gas disinfection device according to the present invention, it will be described first beekeeping beehive to help the understanding of the present invention.

As shown in FIG. 1, the bee hives are divided into a box 10 and a bottom plate 20 that are separated from each other.

In addition, the box 10 is made in the form of a substantially rectangular box using the material of the wood and there are a plurality of consumptions (16; growth and breeding of bees that can perform the growth and breeding of honey bees and honey storage and harvesting, etc.) And a space 11 for accommodating the beekeeping device invented to carry out honey storage and harvesting.

And, the box 10 is configured to open the upper and lower surfaces, the open upper surface of the box 10 is configured to be covered with a lid 18, the bottom plate (opened on the lower surface of the box 10) 20) is configured to be located.

On the other hand, the bee hives are classified into a single phase (in the case of a single layer) and a phase (in the case of a plurality of layers) in the lamination method of the box 10.

In addition, the box 10 and the base plate 20 has a structure in which a passage (not shown) through which a bee can enter and exit.

And, on the bee hives beekeeper is installed chlorine dioxide gas disinfection device according to the present invention to be described later.

The chlorine dioxide gas disinfection device according to the present invention will be described with reference to FIGS. 1 to 7.

As shown, the chlorine dioxide gas disinfection device (A) according to the present invention, a cradle 100 forming an appearance, and a printed circuit board installed on the side in the cradle 100, the ultraviolet LED 210 is installed ( 200, the power supply unit 300 for applying power to the printed circuit board 200 and the drug storage unit 400 is installed in the cradle 100 of the portion facing the ultraviolet LED 210 and accommodated stabilizing chlorine dioxide (400) It consists of

First, the cradle 100 is composed of a plate member 110, the receiving member 120 of the 'C' cross section is attached to the lower plate 100, the drug storage unit 400 is placed.

In addition, the ultraviolet LED 210 is a short wavelength UV, or a long wavelength UV light emitting diode that emits blue ultraviolet light is usually used, the power consumption is less than 1 watt.

In addition, the stabilized chlorine dioxide is composed of a semi-solid gel phase or a liquid or solid.

On the other hand, the power supply unit 300 is composed of an AC to DC converter (AC to DC converter) for changing the battery or AC power to DC power to apply a DC power of 3 ~ 9 volts to the printed circuit board 200.

That is, according to the present invention, a printed circuit board 200 having nine UV LEDs 210 to generate a wavelength of 254 ~ 400nm on a thin plate 110 of 24.5 x 24.5cm to be installed on the bee hive bee of the native bee ), And the power supply unit 300 and the drug storage unit 400 is mounted on the receiving member 120, and in actual use, semi-solid gel stabilization on the drug storage unit 400 of the receiving member 120. The power supply unit 300, which consists of a battery capable of supplying 9 volts of direct current with a chlorine dioxide or an alternating current, is connected to the printed circuit board 200 by a connection line to supply power.

On the other hand, the cradle 100 may be further provided with an external exposure light (not shown) that can visually check whether the power is connected.

Accordingly, by using a general battery and a battery in outdoor conditions such as valleys, mountains, and fields where electricity is not supplied due to the breeding characteristics of bees, it is possible to easily and easily treat and infect the bees infected with diseases at a very low price.

In addition, the printed circuit board 200 is provided with a switching unit 220 to adjust the operation time to adjust the operation time, turn on 1 hour, turn on 2 hours, turn on 3 hours and so on.

Accordingly, the chlorine dioxide gas generated when the ultraviolet rays from which the ultraviolet LED 210 of the printed circuit board 200 is turned on by receiving current from the power supply unit 300 are irradiated to the stabilized chlorine dioxide of the drug storage unit 400. As it spreads inside the bee hives, it treats larvae, as well as bee adults infected with B. rot, and completely degasses the inside of the bee hives.

The chlorine dioxide gas disinfection device (A) is installed on the top of the beekeeping beehive, focusing on the specific gravity of the chlorine dioxide gas being heavier than air. By fumigation of bees, adults and larvae with chlorine dioxide gas, chlorine dioxide is dissolved in water or sugar (sugar water) that is normally supplied to bees, or prevented by oral ingestion by adding chlorine dioxide liquid directly. And the therapeutic effect can be enhanced.

In addition, the use of chlorine dioxide gas minimizes the damage of native bees caused by major diseases such as cystic beetle rot disease and effectively prevents the collective death of bees to enable the growth of strong bees.

In addition, by deodorizing the action of the discrete chlorine to reduce the decay caused by the death of larvae rot caused by worms rot decay disease to prevent the native bees to give up the honeycomb and leave.

On the other hand, the economy is improved, such as labor force reduction, cost reduction, and productivity improvement due to the prevention of honey bees, such as honey farm worms and rot.

In addition, by installing the chlorine dioxide gas disinfection device (A) of the present invention on the beehive, it can be used indoors as well as outdoors (fields, valleys, mountains) as well as indoors (fields, valleys, mountains) due to the characteristics of bee breeding, and is convenient to use at low cost.

In addition, in the case of native bees, it was invented to maintain the lowest concentration (maintaining about 0.003 ppm or more), which is sensitive to changes in the environment, which shows the disinfecting effect of chlorine dioxide gas.

The concentration of chlorine dioxide gas in the chlorine dioxide gas disinfection device (A) of the present invention is measured, and the measurement conditions are as follows.

First, the measurement conditions are installed on the bee hive bee chlorine dioxide gas disinfection device (A) of the present invention, the drug storage unit 400 in the semi-solid gel phase (gel phase) anthium dioxcide gel (10,000 ~ 30,000 ppm) 200g of stabilized chlorine dioxide (stabilized chlorine dioxide) is installed and supplied with power to irradiate ultraviolet rays of 254 ~ 400 nm to generate chlorine dioxide gas, whether the generation of chlorine dioxide at the bottom of the beehive beehive Chlorine dioxide concentration was determined by a chlorine detector (GasAlert Extreme ClO ₂ , BW Technologies by Honeywell).

In addition, in order to measure the chlorine dioxide generation concentration of the chlorine dioxide gas disinfection apparatus over time, a sealed container (desiccator) made of 34 x 34 x 40 cm is installed at the top of the bee hives and the chlorine dioxide detector (GasAlert Extreme ClO ₂ , BW Technologies by Honeywell) was installed and measured for 1 hour chlorine dioxide concentration, the results are as shown in the graph of Figure 6, the red line is a large-capacity chlorine dioxide generator product-control group and the blue line is the chlorine dioxide of the present invention It is a gas generator.

At this time, in order to confirm the correct operation of the chlorine dioxide detector, a commercially available chlorine dioxide gas generator (Bactericide-mini, oxytherapy; red color of FIG. 6) is operated in a hermetic container, and then, as shown in FIG. The highest limit of 1 ppm can be confirmed.

On the other hand, in the case of the chlorine dioxide gas disinfection device (A; blue in FIG. 6) of the present invention, 0.03 at 9 minutes, 0.05 at 16 minutes, 0.08 at 27 minutes, and 0.1 ppm at 53 minutes. Chlorine dioxide gas could be detected.

Therefore, the concentration close to the lowest concentration (maintaining about 0.003 ppm or more) that exhibits the disinfecting effect of the chlorine dioxide gas is maintained.

In addition, Figure 7 is a graph showing the application and effect evaluation of the farmhouse by the mortality comparison results of the native bee group according to the application of chlorine dioxide gas in the native bee farm, the same as the chlorine dioxide gas disinfection device (A) of the present invention 200 We compared the effect of preventing or treating cystic rodent rot with chlorine dioxide-producing devices in two native bee farms whose dogs were constructed and found to have similar symptoms at the early stage of disease development by PCR method, and both native bee farms received the same pollen. The conditions of the specification were identified to be similar to the amount of salary.

In addition, the chlorine dioxide gas disinfection device (A) of the present invention is installed in only 200 beehives only in the native A bee farm (the blue line in FIG. 7), and the B native bee farm is not installed with the chlorine dioxide gas disinfection device (A). The survival rates of bees for each beehive were compared.

That is, as a result of the observation for 10 months as shown in FIG. 7, 105 out of 200 beehives survived and showed a 52.5% survival rate. In the case of B farms, only 6 out of 100 beehives survived and showed a survival rate of 0.06%. The effect by the chlorine dioxide gas was confirmed.

On the other hand, the chlorine dioxide gas disinfection device according to another embodiment of the present invention, which is installed inside the top of the beehive beehive and includes only the drug storage unit containing the stabilized chlorine dioxide, the stabilized chlorine dioxide is formed in a gel or liquid or solid In addition, an acid may be added to the stabilized chlorine dioxide to generate chlorine dioxide gas.

This can be achieved by incorporating inorganic or organic acids into stabilized chlorine dioxide or liquid chlorine dioxide or liquid chlorine dioxide, which are preserved in a semi-solid gel phase. The chemical reaction method is used to produce gasified chlorine dioxide by adding organic acid.

In addition, the chlorine dioxide gas disinfection device according to another embodiment of the present invention, is installed inside the top of the beehive beehive and spraying the liquid stabilized chlorine dioxide contained in the drug storage unit and the liquid storage chlorine dioxide containing the liquid stabilization chlorine dioxide Including a spray means for discharging, the spray means may be configured to generate a chlorine dioxide gas is composed of a known ultrasonic generator or a spray generator.

Although the preferred embodiments of the present invention have been described in detail, the technical scope of the present invention is not limited to the above-described embodiments, but should be construed according to the claims. It will be understood by those skilled in the art that many modifications and variations are possible without departing from the scope of the present invention.

A-Chlorine Dioxide Gas Sterilizer 100-Cradle
200-Printed Circuit Board 210-Ultraviolet LED
300-Power Supply 400-Pharmaceutical Storage

Claims (6)

In the chlorine dioxide gas disinfection device installed in the bee hives,
holder;
A printed circuit board installed at a side of the holder and provided with an ultraviolet LED;
A power supply unit applying power to the printed circuit board; And
Chlorine dioxide gas disinfection device for the prevention and treatment of infectious diseases of bees, including cystic beetle decay disease, characterized in that it is installed on the cradle of the portion facing the ultraviolet LED and stored stabilizing chlorine dioxide.
The method of claim 1,
The stabilizing chlorine dioxide is a chlorine dioxide gas disinfection device for the prevention and treatment of infectious diseases of bees, including cystic beetle rot disease, characterized in that the semi-solid gel or liquid or solid.
The method of claim 1,
The bee including the insect beetle decay disease, characterized in that consisting of an AC to DC converter (AC to DC converter) to change the battery or AC power to DC power to apply a DC power of 3 ~ 9 volts to the printed circuit board Chlorine dioxide gas disinfection system for the prevention and treatment of infectious diseases
The method of claim 1,
The printed circuit board is a chlorine dioxide gas disinfection device for the prevention and treatment of infectious diseases of bees, including worms rot decay disease, characterized in that the switching unit is provided for adjusting the operating time.
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