JP2016220629A - Portable type insect attraction capture device and portable electrostatic field screen generator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a portable type insect attraction capture device which is light, can be easily carried, compact sized, can be driven by applying low voltage and needs no ground structure.SOLUTION: A plurality of dielectric coated bodies 11 are arranged in line at a regular interval along a polyvinyl chloride (PVC) cylindrical body 10 and are coated with a cylindrical metallic net 12, the dielectric coated body and the metallic net covering the same are connected to a DC voltage source (dry battery ) 16 built in a handle 15, and the electrostatic field is formed between different positive/negative charges of the dielectric coated body and the metallic net. The interval of the dielectric coated body and the metallic net is fixed by installing a spacer and non-grounding circuit structure is provided.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a portable pest attracting and capturing device that can be carried for capturing pests by applying the principle of an electrostatic field screen (electrostatic field curtain) formed by generating an electrostatic field.

  In general, hydroponic cultivation of tomatoes is often carried out in the greenhouse year-round, but tomatoes are frequently damaged from pathogen infection and / or pest attack. Infection with pest-derived viruses can cause serious damage to tomatoes, especially tomato yellow leaf curl virus (TYLCV) carried by whiteflies presents the most serious threat at high temperatures. In addition, occurrence of cucumber mosaic virus (CMV) carried by peach aphid and tomato yellow dwarf virus (TSWV) carried by citrus blue thrips may be confirmed. In addition, it is known that migrove fly that lives and proliferates in a sponge-like algal flora soaked in a hydroponic culture solution can transmit rhizobacterial pathogens such as wilt fungus and root rot wilt fungus. Greenhouse tomatoes are also threatened by conidial spores such as powdery mildew fungus, gray mold fungus, and mold fungus floating in the air. In fact, especially greenhouse tomatoes have been suffering from powdery mildew throughout the year. The constant infestation of these pathogen-transmitting pests and conidia requires effective protection measures to treat a wide range of pests and pathogens that invade the greenhouse.

In order to solve this problem, the present inventors have developed an electrostatic field screen technology. An electrostatic field screen is a device that applies a DC high voltage to a metal conductor, generates static electricity on the surface of the insulator covering the electrodes, and traps charged insects, dust, etc. with the insulator by means of static electricity. . FIG. 13 is a diagram for briefly explaining the structure of the electrostatic field screen generating device 00. As shown in FIG. 13, the electrostatic field screen generating device 00 applies a positive potential to an electrode group 01 in which a dielectric coating covered with a dielectric made of an insulating resin is arranged in parallel at intervals of several mm to several cm. It comprises a positive potential applying device 03, a negative potential applying device 04 for applying a negative potential, and a ground electrode 02. Here, the electrode group 01 is referred to as an “electrostatic catcher”.
The earth electrode 02 plays a role of preventing contact of the human body with the electrostatic catcher 01, protecting the electrode, and restricting (repelling action) pest adhesion, and an electrostatic field is generated between the dielectric coverings of the electrostatic catcher 01. To do. Insects, dust, and the like that have entered the electrostatic catcher 01 are charged, and are attracted and captured by the electrostatic catcher 01 by a strong Coulomb force.

In addition, although this inventor has proposed the above invention about an electrostatic field screen generator, it can classify | categorize roughly into two.
The first is when the electrostatic catcher is monopolar. In the case of a single electrode, an electrostatic catcher and a ground electrode are indispensable in the prior art, and there is a configuration example in which an electrostatic catcher and one ground electrode, or an electrostatic catcher and two ground electrodes are arranged on both sides thereof. there were.
The second is the case where the electrostatic catcher is bipolar. In the case of two poles, the positive electrode and the negative electrode are alternately arranged. In this case, the ground electrode is not particularly required for the electric field configuration. However, in order to ensure safety, it is desirable to arrange the ground electrode on one side or two sides (on both sides) for further controlling the attachment of insects or the like to the electrostatic catcher portion.

  The present invention is based on the use of a single-charged dipolar (SD) screen having a bipolar electrostatic catcher. The inventors of the present application proved that the pests repelled the pest by attaching an SD screen to the window of the greenhouse in order to avoid the electrostatic field. In fact, the SD screen was able to catch and repel pests. Also in this experiment, we designed a greenhouse assessment method to confirm the repelling function of the SD screen attached to the window. That is, for the spread of biotype-Q whiteflies carrying tomato yellow leaf curl virus (TYLCV), this evaluation method was used to show the appearance of typical symptoms of tomato yellow leaf curl virus (TYLCV) in greenhouse tomatoes. It is effective to monitor. Through this evaluation method, it is clear that the SD screen attached to the window eliminates external whitefly that enters the greenhouse through the window. However, even if the protection is effective, it has been found to be incomplete due to the lack of protection at the house entrance. That is, the pests enter from the entrance door when the worker enters and exits.

  For such pests that enter from the entrance door when workers enter and exit, conventionally, measures such as applying or spraying medicinal chemicals such as insecticides, insecticides, fungicides, and fungicides are generally performed. I came. However, in recent years, due to the heightened safety awareness, the use of pesticides on agricultural crops and pesticide-free cultivation have become popular, and there is a demand for measures against diseases and pests that are effective without using pesticides or with small amounts. . Moreover, since drugs such as insecticide sprays can be absorbed by the human body, there is no denying the danger of chemical damage. In addition, dust collectors such as small vacuum cleaners may inhale not only pests but also the leaves of plants depending on the suction force, branch leaves may break due to the discharged wind, and temperature rise in the greenhouse due to hot air may also occur. I'm worried. Further, when manufacturing the apparatus, there is a limit to downsizing in consideration of the space of the recovery tank and the like.

  On the other hand, there is a strong demand for tick countermeasures at home. There are many types of ticks, but most of the ticks in the house are dust mites or leopard mites, and even dead ticks and dead bodies can cause allergies. The body length is as small as 0.2 to 0.5 mm, and it is milky white, so it can hardly be seen with the naked eye. It is said that 70 to 80% of people with allergic asthma and atopic symptoms are caused by mite house dust, and these mite allergy countermeasures are very important. However, although the basic measure is to remove mites and their allergens, there is no effective measure for removing mites because they can hardly be seen with the naked eye.

  Therefore, in view of the above problems, the present invention applies the principle of an electrostatic field screen and can be captured by holding it over a pest or the like that has entered a greenhouse or a household, and is small in size, driven at a low voltage, It is an object of the present invention to provide a portable pest attracting and capturing device that is portable without requiring an earth structure.

  In order to achieve the above object, a portable pest attracting and capturing device of the present invention comprises a dielectric coating in which at least a part of a negative electrode conductor formed by connecting to a negative electrode terminal is covered with an insulator, and the dielectric coating A conductor which is arranged so as to face the body while maintaining a predetermined distance and is charged by receiving an electric field from the dielectric coating; a voltage source; and a negative voltage applying means for applying a negative potential to the negative terminal. A groundless conductor provided with a support for supporting the dielectric covering, the conductor, the voltage source, and the negative voltage applying means; and a connecting line for connecting the conductor and the high potential side terminal of the negative voltage applying means. The structure includes a pest trapping part that captures a pest using a continuous electric field formed by a potential difference generated between the structure and the conductor and the dielectric covering.

  As a variation, the support is a rod-shaped body, the dielectric coating is formed on the outer periphery of the support, the conductor is formed at a predetermined interval on the outer periphery of the dielectric coating, and the whole is a rod-shaped body. The pests are a plurality of holes or grooves through which the pests pass through the pests, and the pests that have passed through the plows are formed between the conductors and the dielectric cover. There is a rod-shaped portable pest attracting and capturing device that is captured by the pest capturing unit.

  Further, as another variation, the support is a plate-like body, the dielectric coating is formed on the surface of the support, the conductor is formed on the surface of the dielectric coating with a predetermined interval, The pest has a plate-like body as a whole, and the conductor has a large number of holes or grooves through which the pest passes, and the pest that has passed through the passage has the conductor and the dielectric covering. There is a flat-type portable pest attracting and capturing device that is captured by the pest capturing unit formed between the two.

  It is preferable that a predetermined interval is maintained by disposing an insulating spacer in the gap between the dielectric coating and the conductor.

  Furthermore, it is convenient for use outdoors or at home if it is provided with a groundless structure provided with a connection line for connecting the low potential side terminal and the high potential side terminal of the negative voltage application means from the conductor. This is because the electrons pumped out of the conductor by applying a negative voltage to the dielectric coating of the negative voltage application means are moved to the negative voltage application means side through the connection line of the earthless structure, and the electrons are applied with the negative voltage. The structure is applied to the dielectric coating to which a negative voltage is applied, and electron transfer through the ground is unnecessary.

  The conductor is preferably net-like, but it is sufficient that a plurality of desired holes and grooves are formed. Therefore, a metal plate is formed by punching holes with a punching die or laser processing, or a hole is formed in a conductive sheet obtained by printing conductive ink or conductive paste on paper or resin material. You can do it. With such a method, weight reduction and cost reduction can be achieved.

According to the portable pest attracting and capturing apparatus of the present invention, it is possible to capture by applying the principle of an electrostatic field screen and holding it over a pest that has entered a greenhouse or a household. Since the grounding wires from both the voltage source and the net are removed, there is an effect that it is lightweight and portable. By simply sliding the portable pest attracting and capturing device along the leaves, the pests on the leaves are attracted to the portable pest attracting and capturing device, so that the operator can easily operate and the operation burden can be reduced. is there. As a result, there is an effect that the insect pests entering from the entrance can be captured and the appearance and the spread of viral diseases of plants in the house can be minimized. In fact, the inventors of the present application show that the direct capture method is effective in collecting whiteflies that enter the house because most of the whiteflies are stationary on the backside of the tomato leaves. Are expected.
Furthermore, although the electrostatic field screen device is required to be ventilated in a greenhouse or a container, the portable pest attracting and capturing device of the present invention does not require the air permeability, so that the structure can be simplified and the cost can be reduced. it can.

It is a disassembled perspective view which shows simply the external appearance structure of the portable pest attracting and capturing apparatus 1 of the present invention. It is a perspective view which shows the external appearance structure after the assembly of the portable pest attracting and capturing apparatus 1 of the present invention. FIG. 3 is an AA end view of FIG. 2. It is a figure which shows simply the basic composition including the electric circuit of the portable pest attracting and capturing apparatus 1 of the present invention. It is a figure which shows simply the usage method of the portable pest attracting and capturing apparatus 1 of this invention. It is a figure which shows a mode that a pest attracts and captures to the said apparatus in use of the portable pest attracting and capturing apparatus 1 of this invention. It is a perspective view which shows the external appearance structure after the assembly of the portable pest attracting and capturing apparatus 2 of the present invention. It is a disassembled perspective view which shows simply the external appearance structure of the portable pest attracting and capturing apparatus 2 of the present invention. It is a figure which shows simply the basic composition including the electric circuit of the portable pest attracting and capturing apparatus 2 of the present invention. It is a figure which shows simply the usage method of the portable pest attracting and capturing apparatus 2 of this invention. It is a figure which shows a mode that a pest attracts and captures to the said apparatus in use of the portable pest attracting and capturing apparatus 2 of this invention. It is a figure explaining simply formation of an electrostatic field and a static electric field of an electrostatic field screen generator by a publicly known technique. It is a figure explaining simply the structure of electrostatic field screen generator 00.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In each figure, the same number is attached | subjected to the same part, and the overlapping description is abbreviate | omitted. It should also be noted that the drawings may be exaggerated to understand the present invention and are not necessarily shown to scale. It should be noted that the technical scope of the present invention is not limited to the specific applications, shapes and dimensions shown in the following embodiments. Hereinafter, embodiments of the electrostatic field screen generator of the present invention will be described with reference to the drawings.

  The present invention has been further improved by using the principle of an electrostatic field screen generating device, which was previously developed by the inventor of the present application, particularly called SD-screen (single-applying / bipolar electrostatic field screen). . Before describing the embodiment, the principle of the SD-screen shown in the known art (Japanese Patent No. 5252449) will be described with reference to FIG. The covering body 01 is produced by passing the iron bar 01a through the soft vinyl chloride 01b. On one side of the covering 1 is a stainless steel ground net (ground electrode) 02. The distance between the covering body 01 and the earth net 02 (earth electrode) is 3 mm, and the layers are arranged in parallel. First, when a voltage is applied to the covering 01, an electrostatic field is formed around each covering. The earth net 02 (earth electrode) is inserted into this electrostatic field. Then, for example, when a negative voltage is applied to the covering 01, the side of the earth net 02 (ground electrode) facing the covering is positively polarized. That is, by inserting the earth net 02 (ground electrode) into the electrostatic field, a pair of positive and negative electrodes is created in the electrostatic field space, and an electric field (hereinafter referred to as “static electric field”) is formed inside the electrostatic field. is there. In this static electric field, a force that always pushes the movable charge from the negative electrode (covering body 01) to the positive electrode (earth net 02) works, and when an insect or the like enters, the electric charge of the insect or the like is pushed out, and the pushed electric charge Is absorbed by the earth net 02 (earth electrode). Then, the principle is that insects and the like that have been deprived of charge are positively charged and strongly attracted and captured by the negative pole (cover 01). It will be understood that the portable pest attracting and capturing devices 1 and 2 of the present invention have been proposed for the purpose of reducing the weight and cost by utilizing the above-described principle.

The portable pest attracting and capturing apparatus 1 according to the first embodiment has a stick-shaped appearance. Hereinafter, description will be given based on the drawings. FIG. 1 is an exploded perspective view simply showing the external configuration of the portable pest attracting and capturing apparatus 1 of the present invention, and FIG. 2 is a perspective view showing the external configuration after assembly. The portable pest attracting and capturing apparatus 1 generally includes a cylindrical body 10 and a plurality of dielectric covering bodies 11a, 11b, 11c arranged in parallel at a constant interval in the length direction of the outer ring of the cylindrical body 10. 11d, 11e, 11f, 11g, 11h and a plurality of dielectric coatings 11a, 11b, 11c, 11d, 11e, 11f, 11g, 11h are coated on the outer ring so as to face each other while maintaining a predetermined distance. It comprises a net-like conductor 12, a voltage source 16, and a handle 15 incorporating the voltage source 16.
The tubular body 10 is a portion that becomes the core of the portable pest attracting and capturing apparatus 1.
The dielectric covering 11 is formed by connecting at least part of the surface of the negative electrode conductor formed by connecting to the negative terminal with an insulator, and the adjacent dielectric coverings 11 are connected to each other.
The conductor 12 is charged by receiving an electric field from the dielectric coating 11. The conductor 12 covers the outer ring so as to face the plurality of dielectric covering bodies 11 while maintaining a predetermined distance 13. In order to maintain the predetermined interval, the spacers 14 may be arranged at the predetermined interval 13.
The handle 15 has a built-in voltage source 16 and a negative voltage applying means 17 for applying a negative potential to the negative terminal, and a potential difference between the opposing positive potential conductor 12 and the negative potential dielectric cover 11 is generated. Create a continuous electric field.

  In order to make the dielectric covering 11, an iron conductor (length 50 cm, diameter 2 mm) is inserted into a polyvinyl chloride tube (thickness 1 mm). In addition, it is not limited to this, The dielectric coating body 11 is good to coat | cover an insulator, for example, polyethylene, vinyl chloride, an acryl, nylon, or polystyrene, to iron, copper, aluminum, or stainless steel as a base | substrate. The insulator preferably has a volume resistance value of 1.0 × 10 9 to 10Ω, but in order to obtain a desired volume resistance value, the addition amount of the antistatic agent applied in or on the insulator is adjusted. It is good to control. As the antistatic agent, a surfactant is mainly used. For example, a nonionic surfactant ether type polyoxyethylene alkyl ether or polyoxyethylene alkylphenyl ether can be used. A plasticizer may be used instead of the antistatic agent. A plasticizer is a compound synthesized from an acid and an alcohol, which is generally used for the purpose of giving flexibility to an insulator mainly made of vinyl chloride. Since the surface resistance value of the plasticizer is lower than the surface resistance value of vinyl chloride alone, the surface resistance value as soft vinyl chloride can be lowered by adding a plasticizer to vinyl chloride. In other words, the plasticizer has an antistatic effect in addition to its original purpose of providing flexibility, so the surface resistance value of the insulator can be set to a desired value by controlling the amount of plasticizer added. Can do it. When the insulator is vinyl chloride, for example, phthalate bisphthalate or diisononyl phthalate can be used as the plasticizer.

  Please refer to FIG. FIG. 3 is an AA end view of FIG. In Example 1, eight dielectric coverings 11a, 11b, 11c, 11d, 11e, 11f, 11g, and 11h are cylindrically formed outside a cylindrical body 10 (diameter 3 cm) made of hard polyvinyl chloride. The double-sided adhesive tape wound along the body 10 is arranged at a constant interval. Note that a desired number of dielectric coatings 11 can be adopted. The separation distance 13 between the dielectric covering 11 and the net-like conductor 12 is preferably fixed at 3 mm by placing a spacer 14 (silicone piece having the same thickness as the gap). The separation distance 13 can be arbitrarily determined. However, by reducing the separation distance 13, the electric field strength of the static electric field is increased, and a structural current can be generated in a low voltage range. It should be noted that the tips of the dielectric covering 11 and the net-like conductor 12 may be sealed with silicone sealing caps 18 and 19.

  Please refer to FIG. FIG. 4 is a diagram simply showing a basic configuration including an electric circuit of the portable pest attracting and capturing apparatus 1 of the present invention. In FIG. 4, only members necessary for understanding the present invention are shown to facilitate understanding of the internal structure, and some other members may not be shown. The dielectric coverings 11 a, 11 b, 11 c, 11 d, 11 e, 11 f, 11 g, 11 h are connected to each other and connected to the negative electrode, and the mesh conductor 12 is connected to the positive electrode of the DC voltage source 16 built in the handle 15. Is done. The voltage source 16 is built in the handle 15 and operates with two 1.5V alkaline batteries connected in series. In order to make the insulating cover dielectric, the dielectric cover 11 is negatively charged, the facing side of the facing conductor 12 is positively charged, and the outer surface of the insulating tube is negatively charged. As a result of electrostatic induction, the surface of the dielectric coating 11 that is negatively charged polarizes the conductor 12 in order to be positively charged on the side surface of the dielectric coating 11. That is, an electric field is formed between different positive and negative charges of the dielectric covering 11 and the conductor 12.

  In Example 1, the dielectric coating 11 is negatively charged at 0.5 to 10 kV. In order to measure mechanical discharge (generation of current from the dielectric coating 11 to the conductor 12), the galvanometer G may be mounted on the electric circuit between the conductor 12 and the voltage source 15. The voltage is changed to examine the range of voltages that cause a mechanical discharge. Apparently, the rated current due to mechanical discharge occurs at 5.7 kV or higher, and increases when voltage is applied beyond that. From these results, the inventors used a voltage of 0.5-5.6 kV to determine the range that produced a force strong enough to capture all the pests. As a result, the pests in the electric field are attracted to the vicinity of the dielectric covering 11 of the portable pest attracting and capturing apparatus 1. The earthless structure will be described in the second embodiment.

  Here, the dielectric coating 11 is a negative dielectric coating as a negative electrode, but a configuration in which the polarity is reversed and a positive induction coating is also possible. Since the principle is the same except that the polarity is changed, the description of the configuration having the opposite polarity is omitted.

前述したとおり、携帯型害虫誘引捕捉装置１がすべての検定用害虫を捕捉できる電圧帯を決定するために、携帯型害虫誘引捕捉装置１に対して０．５〜５．６ｋＶの電圧を印加して実験をおこなった。これら害虫の成虫は、害虫吸引装置でポット耕のトマト（生育１ヶ月）の背軸表面に放たれたものである。
図５を参照する。図５は、本発明の携帯型害虫誘引捕捉装置１の使用方法を簡単に示す図である。図５に示すように、携帯型害虫誘引捕捉装置１をトマトの葉に沿って優しくスライドさせて行くことにより放逐された害虫の捕捉を試みる。ここでは、１０匹から７匹の成虫を用いた。害虫の種ごと及び電圧のきざみごとに試した。
図６を参照する。図６は、本発明の携帯型害虫誘引捕捉装置１の使用において、害虫が当該装置に誘引捕捉される様子を示す図である。誘電被覆体１１を通電すると、その周囲に静電場が形成される。図６においては、図に向かって導電体１２の孔と誘電被覆体１１との間に静的電場が形成される。図５に示したように携帯型害虫誘引捕捉装置１をトマトの葉に沿って優しくスライドさせることにより、導電体１２に触れた害虫は静電場及び静的電場に誘引され、導体１２又は誘電被覆体１１に捕捉される。
より体長の大きな害虫を捕捉するためには、より強力に誘電被覆体１１を帯電させる必要があるが、誘電被覆体１１に印加される電圧を高くすることで捕捉力はより強くなる。同時に、似たような体長の三種の害虫（コナジラミ、ミカンキイロアザミウマ、モモアカアブラムシ）の間での捕捉率に大きな違いはなかった。１．５ｋＶ以上の電圧は、害虫の体長や種類と関係なく、誘電被覆体１１がすべての成虫を捕捉する強さとして十分である。また、現場での実証を通じて、風速７ｍ/ｓであっても害虫を捕捉するために十分な強さであることが分かった。これらの結果、１．５ｋＶ以上で印加された携帯型害虫誘引捕捉装置１であれば、実際のハウス内での環境において上述したすべての害虫を駆除することができたことを示している。
しかしながら、比較的低い電圧を印加した場合は、発生する静電力は害虫、例えば、脚をばたばたさせたり、体をくねらせたりするような虫を捕捉するには不十分であった。これらの害虫は誘電被覆体１１から逃れるか、さもなければ、送風装置によって誘電被覆体１１から吹き飛ばされた。これらの観察をもとに、以降の実験（ここでは示さない。）では、より確実に害虫を捕捉するために携帯型害虫誘引捕捉装置１に対して１．５ｋＶの電圧を印加することとする。 In Example 1, the inventors examined the ability to capture adult insects of different lengths that were expelled into the greenhouse. The insect pests used for the test were whitefly, citrus thrips, peach aphid, and swordfly. Table 1 shows the percentage of pests captured by the portable pest attracting and capturing device 1 at different positive and negative voltages (0.5 to 5.6 kV) in percentage. In order to confirm the pest trapping performance of the portable pest attracting and trapping device 1, the inventors of the present application installed a blower (maximum wind speed of 7 m / s with respect to the dielectric coating 11) in the greenhouse and carried the portable pest for 10 minutes. The pests captured by the attracting and capturing device 1 were blown. The experiment was repeated 5 times and the data are present according to standard deviation. In addition, the important difference (a, b, c) between data was analyzed using the Tukey method.

As described above, a voltage of 0.5 to 5.6 kV is applied to the portable pest attracting and capturing apparatus 1 in order to determine a voltage band in which the portable pest attracting and capturing apparatus 1 can capture all pests for testing. The experiment was conducted. These adult pests were released on the spine surface of pot-cultivated tomatoes (1 month of growth) with a pest suction device.
Please refer to FIG. FIG. 5 is a diagram simply showing how to use the portable pest attracting and capturing apparatus 1 of the present invention. As shown in FIG. 5, the portable insect pest attracting and capturing device 1 is tried to capture the displaced insect by gently sliding it along the tomato leaf. Here, 10 to 7 adults were used. Each pest species and voltage step was tested.
Please refer to FIG. FIG. 6 is a diagram illustrating a state in which a pest is attracted and captured by the device when the portable pest attracting and capturing device 1 of the present invention is used. When the dielectric coating 11 is energized, an electrostatic field is formed around it. In FIG. 6, a static electric field is formed between the hole of the conductor 12 and the dielectric coating 11 toward the figure. As shown in FIG. 5, the portable insect pest attracting and capturing apparatus 1 is gently slid along the tomato leaf, so that the insects touching the conductor 12 are attracted to the electrostatic and static electric fields, and the conductor 12 or the dielectric coating. Captured by the body 11.
In order to capture a pest having a larger body length, it is necessary to more strongly charge the dielectric covering 11, but the capturing power becomes stronger by increasing the voltage applied to the dielectric covering 11. At the same time, there was no significant difference in the capture rate among three pests of similar length (whiteflies, citrus thrips, peach aphids). A voltage of 1.5 kV or more is sufficient as the strength with which the dielectric cover 11 captures all adult insects regardless of the length and type of the pests. Moreover, through field demonstrations, it was found that the wind speed was 7 m / s and it was strong enough to catch pests. As a result, the portable pest attracting and capturing apparatus 1 applied at 1.5 kV or higher has been able to exterminate all the above-mentioned pests in an actual house environment.
However, when a relatively low voltage is applied, the electrostatic force generated is insufficient to capture pests, such as insects that flutter their legs or twist their bodies. These pests escaped from the dielectric coating 11 or were blown away from the dielectric coating 11 by a blower. Based on these observations, in a subsequent experiment (not shown here), a voltage of 1.5 kV is applied to the portable pest attracting and capturing device 1 in order to capture the pests more reliably. .

  In a conventional SD screen, the dielectric covering comprises a metal net grounded on both sides, and the high voltage generated through the cockcroft circuit of the voltage source is used to form positive and negative electrodes. The dielectric coating is negatively charged by the addition of electrons lifted from the ground, while the metal net is positively charged by pushing electrons (free electrons) in the metal to the ground. Inventors have confirmed in a recent study that a configuration in which a voltage is applied between the two in order to carry the electrons of the metal net to the dielectric coating is effective. In this configuration, the dielectric coating and the metal net have opposite polarities and an electric field is formed between them.

  The most important point of the portable insect pest attracting and capturing apparatus 1 improved from the conventional SD screen is that the grounding wires from both the voltage source 15 and the net-like conductor 12 are removed, thereby realizing a portable apparatus. That is. The current flowing in the dielectric cover 11 depends on the voltage applied to the electrodes, the distance between the electrodes, and the insulation resistance of the insulator covering the dielectric cover 11. The current from the insulated conductor depends on the insulation resistance at a predetermined voltage that determines the dielectric constant level of the insulator. The current is inversely proportional to the distance.

The portable pest attracting and capturing apparatus 2 according to the second embodiment has a so-called iron-shaped appearance. Hereinafter, description will be given based on the drawings. FIG. 2 is a perspective view showing an external configuration after assembly of the portable pest attracting and capturing apparatus 2 which is a modification of the first embodiment, and FIG. 2 is an exploded perspective view simply showing the external configuration. The portable pest attracting and capturing apparatus 2 generally faces the main body 20, a single dielectric cover 21 disposed inside the bottom of the main body 20, and maintains a predetermined distance from the dielectric cover 21. And a voltage source 25, and a handle 24. The main body 20 is an exterior part of the portable pest attracting and capturing device 2, and is a storage body containing a dielectric covering 21, a conductor 22, and a voltage source 25, and includes a handle 24.
The dielectric covering 21 is a flat plate having a desired shape, and at least a part of the surface of the negative electrode conductor formed by connecting to the negative electrode terminal is covered with an insulator.
The conductor 22 is charged by receiving an electric field from the dielectric coating 21.
Further, the spacers 23 may be arranged at the predetermined intervals in order to maintain the predetermined intervals.
In addition, a negative voltage applying means for applying a negative potential to the negative electrode terminal is provided, and a continuous electric field is formed between the opposing positive potential conductor and the negative potential dielectric coating by the potential difference, and the conductor and the negative electrode are negative. It is characterized by comprising an earthless structure provided with a connection line for connecting the high potential side terminal of the voltage applying means.

  The dielectric cover 21 has a steel plate coated with polyvinyl chloride. In addition, it is not limited to this, The dielectric coating body 11 is good to coat | cover an insulator, for example, polyethylene, vinyl chloride, an acryl, nylon, or polystyrene, to iron, copper, aluminum, or stainless steel as a base | substrate. Hereinafter, since it is the same as the description described in Example 1, it abbreviate | omits.

Please refer to FIG. FIG. 9 is a diagram simply showing a basic configuration including an electric circuit of the portable pest attracting and capturing apparatus 2 of the present invention. In this example, the output terminal of the DC booster 27 is a negative voltage, and a negative voltage is applied to the dielectric coating 21 to charge the dielectric coating 21 to a negative potential.
The conductor 22 is a conductor that draws up electric charges, and is a kind of earth-equivalent member. By using the conductor 22, electrons can be supplied to the negative voltage application device 27 side through the grounding-ungrounded circuit 60. The negative voltage application device 27 can perform a charge discharging action. In other words, the electrostatic catcher itself is a single electrode having only a negative electrode, but the entire device has a balanced charge.
Electrons pumped out from the conductor 22 are moved to the negative voltage application device 27 side via a connection line 61 of a grounding-ungrounded circuit 60 (shown by a dotted line). That is, the electrons pumped out of the conductor 22 without being passed through the ground are transferred to the dielectric coating 21 side via the negative voltage applying device 27 side and applied, so that the electron movement through the ground electrode is performed. It becomes unnecessary.

Please refer to FIG. FIG. 10 is a diagram simply showing how to use the portable pest attracting and capturing apparatus 2 of the present invention. Moreover, FIG. 11 is a figure which shows a mode that a pest attracts and captures to the said apparatus in use of the portable pest attracting and capturing apparatus 2 of this invention. As shown in FIG. 10, in order to capture the pests that have been expelled, the portable pest attracting and capturing device 2 is gently slid along the tomato leaves as if ironing.
Please refer to FIG. When the dielectric coating 21 is energized, an electrostatic field is formed around it. In FIG. 11, a static electric field is formed between the hole of the conductor 22 and the dielectric cover 21 toward the figure, and the portable pest attracting and capturing device 2 is gently slid along the tomato leaf, Pests that have touched the conductor 22 are attracted to the electrostatic and static electric fields and are captured by the conductor 22 or the dielectric coating 21.

  While the embodiments of the portable pest attracting and capturing apparatus of the present invention have been described above, it will be understood that various modifications can be made without departing from the technical scope of the present invention.

  The present invention can be used as a portable insect pest attracting and capturing device in a greenhouse of a university or public institution, or an agricultural greenhouse, and it can also attract insects such as mites or mold spores in a futon of a general household. Can do.

1 2 Portable Pest Attracting and Capturing Device 10 Tubular Body 11 21 Dielectric Cover 12 22 Conductor 13 23 Spatial Gap 14 24 Spacer 15 25 Handle 16 26 Voltage Source 17 27 Voltage Application Device 18 19 Seal Cap 20 Main Body 28 Seal Frame 60 Grounding-free circuit

Claims (6)

A dielectric covering in which at least part of the surface of the negative electrode conductor formed by connecting to the negative electrode terminal is coated with an insulator;
A conductor that is arranged to be opposed to the dielectric coating while maintaining a predetermined interval, and is charged by receiving an electric field from the dielectric coating;
A voltage source;
Negative voltage applying means for applying a negative potential to the negative terminal;
A support for supporting the dielectric covering, the conductor, the voltage source, and the negative voltage applying means;
An earthless structure provided with a connection line for connecting the conductor and the high potential side terminal of the negative voltage application means;
A portable pest attracting and capturing device including a pest capturing unit that captures a pest using a continuous electric field formed by a potential difference generated between the conductor and the dielectric covering. The support is a rod-shaped body, the dielectric coating is formed on the outer periphery of the support, the conductor is formed at a predetermined interval on the outer periphery of the dielectric coating, and the whole has a rod shape,
The conductor includes a pest passage portion that is a large number of holes or grooves through which the pest passes, and the pest that has passed through the passage portion is formed between the conductor and the dielectric coating. The portable pest attracting and capturing device according to claim 1, wherein the portable pest attracting and capturing device is captured by a pest capturing unit. The support is a plate-like body, the dielectric covering is formed on the surface of the support, the conductor is formed on the surface of the dielectric covering at a predetermined interval, and the whole forms a plate-like body. ,
The conductor includes a pest passage portion that is a large number of holes or grooves through which the pest passes, and the pest that has passed through the passage portion is formed between the conductor and the dielectric coating. The portable pest attracting and capturing device according to claim 1, wherein the portable pest attracting and capturing device is captured by a pest capturing unit.   4. The device according to claim 1, wherein the predetermined distance is maintained by disposing an insulating spacer in a gap between the dielectric coating and the conductor. 5. Portable pest attracting and capturing device.   Electrons pumped out of the conductor by applying a negative voltage to the dielectric coating of the negative voltage application means are moved to the negative voltage application means side via the connection line of the earthless structure, and the electrons are moved to the negative voltage application means side. The portable insect pest attracting trap according to any one of claims 1 to 4, wherein a negative voltage is applied to the dielectric coating body to which the negative voltage is applied. apparatus. A dielectric covering in which at least part of the surface of the negative electrode conductor formed by connecting to the negative electrode terminal is coated with an insulator;
A conductor that is arranged to be opposed to the dielectric coating while maintaining a predetermined interval, and is charged by receiving an electric field from the dielectric coating;
A voltage source;
Negative voltage applying means for applying a negative potential to the negative terminal;
A support for supporting the dielectric covering, the conductor, the voltage source, and the negative voltage applying means;
An earthless structure provided with a connection line for connecting the conductor and the high potential side terminal of the negative voltage application means;
A portable electrostatic field screen generator for providing a continuous electric field formed by a potential difference generated between the conductor and the dielectric covering, facing each other.

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