JP2005000111A - Agent-spraying apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an overall controlling apparatus having both of the attraction and the chemical control of insect pests in a form free from limitation of installation location. <P>SOLUTION: In an agent-spraying apparatus, carbon dioxide generated by a fuel cell 1 exhibits attraction effect, and effect of the overall controlling effect can be enhanced thereby. A fan enables spraying in wide range, and the insect pest controlling apparatus equipped with a stable electric source can be realized by enhancing efficiency of the fuel cell 1 which becomes the electric source of the fan by stream generated by the fan. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an autonomous drug spraying apparatus that includes an instrument for efficiently spraying a drug and a power supply thereof, and does not use an external power supply. Here, by selecting the medicine to be used, it can be used as a deodorizing device, a fragrance spraying device, and a pest control device. When used as a pest control device, a pest control device capable of performing chemical control and physical control at the same time can be realized.
[0002]
[Prior art]
Conventionally, pest control is an abbreviation for prevention and extermination of pests. Prevention refers to “control of occurrence” and “avoidance of damage”, and control means “insecticidal treatment after occurrence”. . In general, pest control methods are roughly classified into four types: chemical control, mechanical / physical control, cultivating control, and biological control (see Non-Patent Document 1). Here, chemical control is control using a chemical agent, and specifically, an insecticide is used. Insecticides have a wide variety of actions, such as digestive poisons, contact insecticides, fumigants, osmotic insecticides, adjuvants, attractants, chemical fertility agents, insecticides, and the like. The same medicine may have several actions, or a plurality of medicines may be mixed to produce several actions. During chemical control, liquid (emulsion, oil), solid (powder, granule, tablet, wettable powder) or other dosage forms are sprayed. Methods such as liquid spraying, powder spraying, granule spraying, smoke spraying, fumigation, application, pouring, dripping, dipping, and soot are used. Mosquito coils are defined as soot (see Non-Patent Document 2).
[0003]
Mechanical / physical control means capturing insects mechanically, blocking their movement, attracting / repelling, controlling / inhibiting insects by physical energy such as light, sound waves, ultrasonic waves, heat rays, high-voltage current, and radiation. It represents control methods such as controlling the behavior of pests such as confusion, depriving the reproductive ability of pests, and killing insects (see Non-Patent Document 3).
[0004]
Here, conventionally, a heating element (heater for heating) has been used to spray chemicals for pest control (see, for example, Patent Documents 1, 2, 3, and 4). In particular, it is known that blood-sucking pests such as “mosquitoes” typified by Diptera are attracted by temperature (see, for example, Non-Patent Document 4). Therefore, in order to effectively control pests such as mosquitoes, simultaneous application of a heater and a chemical agent is comprehensive control that simultaneously performs chemical control and physical control, and its effectiveness is high. However, these heating elements are mainly based on the assumption that power is supplied from a household outlet, and when installing a pest control spraying device in a house, it is subject to restrictions such as placing it near the place where the power can be taken. (For example, see Patent Documents 1, 2, and 3). Therefore, it could not be used outdoors. In order to remove the restriction on the installation location in the house, it is conceivable to use a commercially available dry battery. However, in order to give sufficient electric power to the heating element for heating, there is a problem that the use time is shortened in a dry battery. In addition, it is effective to use a fan in order to spread a medicine over a wide area in the house. However, the effect of attracting by temperature could not be expected.
[0005]
[Non-Patent Document 1]
Tetsuo Saito, Yoshiaki Matsumoto, Yoshihiro Hirashima, Eiji Kuno, Toshio Nakajima, "New Applied Entomology", Asakura Shoten, Revised Edition-8th Edition, March 10, 1991, (pages 120-121)
[0006]
[Non-Patent Document 2]
Same as above (pages 133-142)
[0007]
[Non-Patent Document 3]
Same as above (Page 153)
[0008]
[Patent Document 1]
Japanese Patent Laid-Open No. 5-194103 (page 11, FIG. 3)
[0009]
[Patent Document 2]
Japanese Patent Laid-Open No. 5-58806 (page 18, FIG. 1)
[0010]
[Patent Document 3]
JP-A-8-205744 (page 9, Fig. 3)
[0011]
[Patent Document 1]
JP-A-7-89806 (page 11, FIG. 1)
[0012]
[Non-Patent Document 4]
Toshiaki Ikeji, “Mosquito”, The University of Tokyo Press, First Edition, published February 10, 1993 (pp. 139-141)
[0013]
[Problems to be solved by the invention]
As described above, there is a problem that the spraying apparatus capable of comprehensive control that simultaneously performs chemical control and physical control is limited in installation location. On the contrary, by driving the spraying device with a portable power source, it has not been possible to provide a comprehensive control device that simultaneously combines pest attraction and chemical control.
[0014]
[Means for Solving the Problems]
Therefore, the medicine spraying device of the present invention includes a water-soluble solid or liquid medicine and a fuel cell that supplies electric power for spraying the medicine, and a medicine container for storing the medicine and a fuel for the fuel cell A package body in which the containers are arranged on the same plane is formed, and the package body can be easily detached from the main body of the medicine spraying apparatus and assembled. With such a configuration, it is possible to provide an apparatus that can perform comprehensive control that simultaneously performs chemical control and physical control, and that can be installed anywhere. Furthermore, the chemicals and fuels can be exchanged by setting the same time when the chemicals are consumed and the time when the fuels in the fuel cells are consumed, and joining the containers containing chemical control chemicals and the fuel cells. Can be done at the same time, and convenience has increased.
[0015]
In addition, a medicine spraying device according to the present invention includes a water-soluble solid or liquid medicine and a fuel cell that generates power using a fuel containing a water-soluble organic solution, and uses the power generated by the fuel cell. In addition to the spraying of chemicals, combustion gas was released from the fuel cell during power generation. Furthermore, the combustion gas has a pest control function that attracts pests. In particular, the carbon dioxide gas emitted from the fuel cell exhibits an attractive effect, and the overall control effect can be enhanced.
[0016]
In addition, a medicine spraying device according to the present invention includes a water-soluble solid or liquid medicine and a fuel cell that generates power using a fuel containing a water-soluble organic solution, and uses the power generated by the fuel cell. The chemical was sprayed by heating, and the ascending airflow at the time of heating had a pest attracting function. Alternatively, a medicine spraying device according to the present invention includes a water-soluble solid or liquid medicine, a fan for spraying the medicine, and a fuel cell for supplying electric power for driving the fan, and a fuel. The medicine is dispersed by the electric power generated by the battery, and the fan has the function of promoting the evaporation of moisture from the cathode of the fuel cell. With such a configuration, when a medicine is sprayed over a wide range, the fan is sprayed, and the air current generated by the fan increases the efficiency of the fuel cell serving as the power source, and the pest has the effect of stabilizing the power source. A control device can be provided.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
The medicine spraying device of the present invention will be described with reference to the drawings. In FIG. 1, the conceptual diagram of the chemical | medical agent spraying system using the heater of this invention is shown. The fuel cell unit 1 generates power using the fuel supplied from the fuel container unit 2. The electric power obtained by the power generation is supplied to the heater unit 4 used for spraying the medicine. On the other hand, the chemical | medical agent 3 is supplied to the heater part 4 from the chemical | medical solution tank part, and when this chemical | medical agent is heated by the heater part 4, a chemical | medical agent is vaporized and spread | diffused. The voltage required for the heater unit 4 can be obtained by connecting fuel cells in series. It is also possible to obtain a necessary voltage via a booster circuit.
[0018]
The conceptual diagram of the chemical | medical agent spraying system using the fan of this invention is shown in FIG. As in the case of FIG. 1, fuel is supplied from the fuel container part 2 to the fuel cell part 1 to generate power. The electric power obtained by the power generation is supplied to the fan 5 used for spraying the medicine. On the other hand, the chemical | medical agent 3 is supplied to the fan part from the chemical | medical solution tank part, and volatilization and spreading | diffusion of a chemical | medical agent are accelerated | stimulated with the wind force of a fan. Furthermore, evaporation of moisture generated in the fuel cell unit 1 is also promoted by the air flow generated by the fan. Here, the fuel container 2 for driving the fuel cell unit 1 and the medicine container 3 are physically connected, and the fuel can be exchanged and the medicine can be exchanged at the same time.
[0019]
FIG. 3 shows a cross-sectional view of a medicine spraying device using the heater of the present invention. The fuel cell unit 1 shown in FIG. 1 includes a cathode (positive electrode) 11 and an anode (negative electrode) 12 sandwiching a solid polymer membrane (PEM) 10. The solid polymer membrane 10 is made of a polymer material having ion selectivity, and glass for the purpose of promoting the passage of ions therein, promoting the stabilization of the membrane structure, reducing the influence of crossover, etc. Inorganic and metal oxides can be added. Specifically, engineering plastics such as DuPont Nafion (trademark) and PEEK can be used for the solid polymer film. The cathode 11 is composed of a carbon-based material and a catalyst, and a material having a binder function can be added as necessary. The catalyst can generate an oxidant from atmospheric oxygen. As the catalyst used for the cathode 11, platinum, an alloy of a platinum group element, a transition metal oxide, an organic substance having a catalytic function, or the like can be used. In particular, when platinum or a platinum-based alloy is used, high efficiency can be achieved by high dispersion in the carbon material. In addition, when using manganese dioxide or other transition metals or their composite oxides as a catalyst, an oxide powder and an electronic conduction assistant such as carbon black or carbon nanotube are mixed with a binder such as polytetrafluoroethylene to form an electrode. Can be used as The anode 12 can carry a catalyst on a carbon-based material, oxidize the fuel, and generate electrons. Electrons generated at the anode 12 are sent to the heater unit 41 through the anode wiring 14. The cathode wiring 13 connects the cathode 11 of the fuel cell and the heater unit 41, and supplies electrons necessary for the catalytic reaction at the cathode 11. Here, a booster circuit or other control circuit may be interposed in the middle of the cathode wiring 13 or the anode wiring 14. As the catalyst used for the anode, platinum, an alloy of a platinum group element, a transition metal oxide, an organic substance having a catalytic function, or the like can be used. In particular, when platinum or a platinum-based alloy is used, high efficiency can be achieved by high dispersion in the carbon material. In particular, when platinum is used as a catalyst, poisoning can be suppressed by using an alloy such as ruthenium. In addition, when using manganese dioxide or other transition metals or their composite oxides as a catalyst, an oxide powder and an electronic conduction assistant such as carbon black or carbon nanotube are mixed with a binder such as polytetrafluoroethylene to form an electrode. Can be used as The fuel 21 is a hydrogen source and may be used as long as it has an ability to generate hydrogen via a catalyst, and it can contain an organic substance having a water-soluble polarity. As the organic substance having polarity, aliphatic hydrocarbons having a straight chain or a side chain capable of exhibiting a hydrogen bond can be used. For example, (1) methanol, ethanol, 2-methylpropanol (IPA), butanol, or other alcohols, (2) ethylene glycol, propylene glycol, or other glycols, (3) dimethyl ketone, methyl- Ketones such as ethyl ketone and (4) acetone and various ethers can be used. The water-soluble organic substance used as the fuel 21 can be used in a mixed state with water. For example, in the case of methanol as the fuel 21, it can be mixed and adjusted in advance with water at a molar ratio of 1: 1. The fuel container 22 and the chemical liquid container 32 may be physically connected. When the fuel container 22 and the chemical liquid container 32 are physically connected, there is a convenience that these can be exchanged at the same time. The material of the chemical liquid container 22 and the fuel container 32 is not particularly limited, but a plastic that is insoluble in the fuel or hardly swells in the fuel can be used. In particular, considering processability, it is excellent to use various thermoplastic plastics, and these plastics can be molded by blow molding, injection molding or other molding methods. For example, polystyrene or polyolefin can be used. Further, the inner surface or the outer surface of the fuel container 22 can be coated with a metal such as aluminum or an inorganic substance such as silicon oxide. In particular, by performing vacuum deposition of silicon oxide, it is possible to prevent deterioration due to volatilization of the fuel 21 and the chemical agent 31 when not in use and the influence of oxygen in the atmosphere and light. As a method for sending the fuel 21 to the anode 12 of the fuel cell, although not shown in the drawing, a pump for sending liquid can be used. As a method for sending the fuel 21 to the anode 12 of the fuel cell, capillary action or osmotic pressure can be used. As illustrated, the fuel impregnation rod 24 can be illustrated. In order to close the gap between the fuel-impregnated rod 24 and the chemical liquid container 22, a fuel plug 23 may be arranged. The fuel plug 23 has a hole penetrating the fuel impregnating rod 24 and can be attached to the fuel container 22 by press fitting, caulking, screwing, or other sealing methods. Further, the void portion of the fuel container 22 that is not filled with the fuel 21 can be filled with nitrogen or other gas, and the liquid level of the chemical solution 21 can be pressurized by the pressure to promote the liquid feeding of the fuel 21. It is also possible to send the fuel 21 to the anode 12 of the fuel cell by its own weight.
[0020]
In this case, the fuel-impregnated rod 24 has a function of controlling the flow rate when the fuel is fed. A fuel volatilization prevention cover 25 may be disposed around the fuel impregnation rod 24 to prevent the fuel from volatilizing and the loss of pressure before the fuel is fed from the fuel impregnation rod 24 to the fuel cell anode 12. it can.
[0021]
The heating element 41 for heating the chemical liquid can indirectly or directly heat the chemical liquid. Electric power required for the heating element is generated by the fuel cell. The voltage required for the heating element 41 may be obtained by providing fuel cells in series. Further, a necessary voltage can be set between the heating element 41 and the fuel cell via a booster circuit, and other control circuits and the like can be incorporated. The control circuit also includes a switch such as bimetal and a variable resistor. In addition, a light emitting diode or the like indicating the operation of the fuel cell or the heating unit 41 may be attached. The heating element 41 used in the present invention can be heated from room temperature to 200 ° C., and can be used below the temperature at which the chemical solution reaches the boiling point.
[0022]
A fragrance, a deodorant, a pest control drug, or the like can be used as the drug. Conventionally known various drugs can be used as the chemical solution. For example, one or more agents such as digestive poisons, contact insecticides, fumigants, penetrating insecticides, adjuvants, attractants, chemical fertility agents, and insecticides may be used. Organic phosphorus, carbamates such as carbaryl, synthetic pyrethroids such as permethrin, chloronicotyl, neonicotinoids, and the like can be used. Specifically, fenitrothion (trademark: sumithion), dichlorvos (trademark: DDVP), permethrin (trademark: exmine), phthalthrin (trademark: neopinamine), pyriproxyfen, phenothrin (trademark: Smithlin), piperonyl butoxide, Propetanfos, d-T80 Resmethrin, Chlorpyrifosmethyl, Trichlorfone (Trademark: Dipterex), Dichlorvos, dd-T80 Praretrin, Imiprothrin, d-T80 Phthasulin, Fipronil, Etofenprox (Trademark: Lenatop), Pyridafenthion, Aresulin (Trademark) : Pinamine), fenthion (trademark: Vitex), sinepiline, paradichlorobenzene, trichloroethylene, pyridafenthione, diazinon, methoxadiazone, Toprene, Vaporthrin, Pyrethroid-like, IGR, Butoxide, Octachlorodiprovir ether, Cresol, Propoxl, Hydramethylnon (Trademark: Maxforce), Dipterex, Imidacloprid, N-alkylamide, Diflubenzuron, Terpene oil Chrysanthemum extract (trademark: pyrethrin) and silafluophene (trademark: silonene) can be used. Moreover, attractants, such as lactic acid, an amino acid, urea, and ammonia, can be added.
[0023]
The chemical solution container 32 can be manufactured by using the same material as that of the fuel container 22 described above and using the same processing method. The chemical solution plug 33 and the chemical solution impregnation rod 34 are the same as the above-described fuel plug 23 and fuel impregnation rod 24. In particular, the chemical liquid impregnated rod 34 is preferably made of a heat resistant material because it is not adversely affected by the heat from the heating unit 41.
[0024]
The outer container (housing) 42 is desirably made of a material that is not easily affected by heat from the heating element. A heat insulating material may be interposed between the outer container 42 and the heating element 41. The outer container 42 may be provided with a lid 44 for the fuel and chemical solution storage unit, and has a function of fixing the chemical solution container 32 and the fuel container 22 or a function of assisting it. In order to replenish oxygen consumed by the fuel cell, an air intake 44 is provided in the outer container 42 or the lid 44 of the fuel and chemical solution storage unit. Here, for convenience, the air intake port is disposed in the lid 44 of the fuel and chemical solution storage unit, but is not limited thereto.
[0025]
Next, FIG. 4 shows a cross-sectional view of a medicine spraying device using the fan of the present invention. Here, solid polymer membrane (PEM) 10, cathode (positive electrode) 11, anode (negative electrode) 12, anode wiring 14, cathode wiring 15, fuel 21, fuel container 22, fuel plug 23, fuel impregnation rod 24, fuel Volatilization prevention cover 25, chemical solution 31, chemical solution container 32, chemical solution plug 33, chemical solution impregnation rod 34, chemical solution dispersion promoting material 35, chemical solution heating element 41, exterior container (housing) 42, fuel and chemical solution storage unit lid 43 and the air intake 44 can use the same structure as FIG. The electric power obtained by the fuel cell is used for the operation of the fan 51. At this time, in order to efficiently diffuse the chemical solution, the chemical solution dispersion promoting material 35 can be connected to the chemical solution impregnated rod 34 and arranged. As the chemical solution spreading material 35, a spongy material having a high specific area without being dissolved by the chemical solution can be used. Volatilization and diffusion of the chemical solution carried to the surface of the chemical solution application promoting material 35 are promoted by the air flow generated by the fan 51. Further, since the gas in the outer container (housing) 42 is discharged by the fan 51, the inner pressure of the outer container becomes negative. In order to compensate for this, an air flow is generated from the air intake 52 toward the fuel cell cathode 11. The fan also has a function of discharging carbon dioxide gas generated at the fuel cell cathode 12.
[0026]
【Example】
Examples of the present invention are described in detail below.
(Example 1)
In this embodiment, the pest control apparatus having the configuration shown in FIG. 3 is illustrated. As the solid polymer membrane (PEM) 10, a Nafion (trademark) film (model 117) manufactured by DuPont was cut into a length of 30 mm and a width of 40 mm. The cathode (positive electrode) 11 is a carbon paper (trademark) manufactured by Toray Industries, Inc. (model TGP-H) in which carbon fine powder supporting 50 wt% platinum is dispersed in a Nafion solution and applied so that the platinum weight is 2 mg / cm ^2. −060, thickness 190 μm) was used. It was cut into 25 mm length and 30 mm width and used as an electrode. The anode (negative electrode) 12 was prepared using an alloy catalyst prepared so that platinum and ruthenium had an atomic ratio of 1: 1, and was prepared and formed in the same manner as the cathode. The anode wiring and the cathode wiring were each connected by spot welding after processing a plate made of SUS304 having a rust-proofed surface used as a current collector into a lattice shape. The current collector plate was subjected to rust prevention treatment using a commercially available conductive epoxy resin. Twelve fuel cell units described above were used in series. Here, a commercially available red light emitting diode is interposed between the anode 12 and the heating element 41 in series. The heating element 41 is a silicon rubber heater rated at 6V5W (power density 0.8 w / cm ² ). The heating element 41 was a 25 mm × 25 mm square plate shape, but was processed into a cylindrical shape and used. The fuel 21 was a mixture of about 20 ml of methanol and about 18 ml of water. The fuel container 22 has a cylindrical shape having a bottom surface having a diameter of about 50 mm and a height of about 50 mm, and an opening having a diameter of about 20 mm is provided in the upper part. The material used was polyethylene terephthalate. A fiber impregnated rod 24 was formed by bundling glass fibers and processing into a cylindrical shape having a diameter of 6 mm and a length of 60 mm. As the fuel volatilization prevention cover 25, a heat shrinkable tube made of polyamide was used. For the fuel plug 23, silicon rubber processed into a donut shape having a thickness of about 3 mm, an outer diameter of about 20 mm, and an inner diameter of about 6 mm was used. As the chemical solution 31, 40 ml of a solution containing a commercially available pyrethroid type insecticide was used. The chemical solution container 32, the chemical solution plug 33, and the chemical solution impregnation rod 34 were produced in the same manner as the fuel container 22, the fuel plug 23, and the fuel impregnation rod 24 described above. An acrylic plate having a thickness of 5 mm was used for the outer container (housing) 42 and the lid 43 of the fuel and chemical solution storage unit. The outer container (housing) 42 was used by pasting an acrylic plate and processing it to a size of 21 cm × 30 cm × 10 cm. As the air intake 44, 60 holes having a diameter of 8 mm were formed in the acrylic plate.
[0027]
In this example, it was possible to take out a voltage of 0.5 V from the fuel cell with a single cell, and it was possible to heat the heater at this voltage and spray the chemical solution.
[0028]
(Example 2)
In the present embodiment, as the chemical solution spreading facilitating material 35, a glass fiber punched out to a diameter of 30 mm and sandwiched between Teflon supports is used. As the fan 51, a commercially available Mabuchi Motor (model: RF-500TB) motor was used, and a commercially available axial fan (trademark: SPRON) was used for connection. Two fuel cells were produced in the same manner as in Example 1, and two fuel cells were connected in series. An acrylic plate having a thickness of 5 mm was used for the outer container (housing) 42 and the lid 43 of the fuel and chemical solution storage unit. The exterior container (housing) 42 was used by pasting an acrylic plate and processing it to a size of 10 cm × 15 cm × 10 cm. The air intake 44 was formed by making four holes with a diameter of 8 mm in the acrylic plate. The air intake 52 was formed by comb-like slit processing on the acrylic plate. Other than that was produced similarly to Example 1.
[0029]
In this example, the fan was driven by the power source of the fuel cell, the fuel cell could operate stably, and the chemical solution could be dispersed.
The product of the above-described embodiment was installed and operated in a general house in Chiba Prefecture. I chose a warm day in March and started running for 6 hours from noon. Despite the winter season, two flying insects could be confirmed, and the flying insects were extinct and could be controlled. This is considered to be a synergistic effect of the attracting effect and controlling of the present invention.
[0030]
【The invention's effect】
According to the configuration of the present invention, the use of the independent power source can release the restriction on the installation place of the pest control apparatus. In addition, the combined use of the fuel cell enabled the carbon dioxide attracting effect and the chemical control to be carried out at the same time, and the pest control effect was enhanced. Furthermore, the attraction by heat generated from the heater and the attraction by carbon dioxide gas generated from the fuel cell showed a synergistic effect, and the effect of pest control by chemical control was further enhanced.
[0031]
In addition, since the moisture generated at the cathode of the fuel cell was diffused and removed by the fan used for spraying the medicine, it was possible to maintain a certain output, and the effect of pest control by chemical control was further maintained.
[0032]
In addition, the chemical and fuel can be exchanged at the same time by connecting the container containing the chemical control chemical and the container containing the fuel for the fuel cell by setting the same consumption time of the chemical and the consumption of the fuel cell. It has become possible to improve convenience.
[Brief description of the drawings]
FIG. 1 is a conceptual diagram of a medicine spraying system using a heater of the present invention.
FIG. 2 is a conceptual diagram of a medicine spraying system using the fan of the present invention.
FIG. 3 is a cross-sectional view of a medicine spraying device using the heater of the present invention.
FIG. 4 is a sectional view of a medicine spraying device using the fan of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Fuel cell part 2 Fuel container part 3 Chemical solution tank part 4 Heater part 5 Fan 10 Solid polymer film (PEM)
11 Cathode (positive electrode)
12 Anode (negative electrode)
13 Cathode wiring 14 Anode wiring 21 Fuel 22 Fuel container 23 Fuel plug 24 Fuel impregnation rod 25 Fuel volatilization prevention cover

Claims (5)

A drug spraying device comprising a water-soluble solid or liquid drug and a fuel cell that supplies power for spraying the drug, the drug container storing the drug and the fuel container of the fuel cell A drug spraying device, wherein a package body arranged on the same plane is formed, and the package body can be easily detached from the body of the drug spraying device and incorporated. A drug spraying device comprising a water-soluble solid or liquid drug and a fuel cell that generates power using a fuel containing a water-soluble organic solution, wherein the drug is sprayed by electric power generated by the fuel cell. In addition, the chemical spraying device is characterized in that combustion gas is released from the fuel cell during power generation. The chemical spraying device according to claim 2, wherein the combustion gas has a pest control function for attracting pests. A drug spraying device comprising a water-soluble solid or liquid drug and a fuel cell that generates power using a fuel containing a water-soluble organic solution, wherein the drug is heated by the power generated by the fuel cell. A drug spraying device characterized in that, while being sprayed, the ascending airflow at the time of heating has a pest attracting function. A drug spraying device comprising a water-soluble solid or liquid drug, a fan for spraying the drug, and a fuel cell for supplying electric power for driving the fan, wherein the fuel cell generates power. The drug spraying apparatus is characterized in that the drug is sprayed by the electric power to be applied and the fan has a function of promoting evaporation of moisture from the cathode of the fuel cell.

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