KR20200073426A - Insect suction device for testing tiny harmful insects - Google Patents

Abstract

The present invention provides an insect suction device for bioassay of tiny harmful insects, including: a petri dish having a receiving portion in which an internal space capable of receiving tiny harmful insects is formed and a cap portion coupled to the receiving portion; an inlet pipe for insect suction which is connected to one side of the petri dish to communicate with the receiving portion and is extended by a predetermined length to be exposed to the outside; an air transfer pipe which is connected to the other side of the petri dish to communicate with the receiving portion, and is extended to a suction apparatus providing air suction power; and a cut-off filter disposed in the cap portion to prevent tiny harmful insects from leaking into the air transfer pipe.

Description

Micro pest pest tester for bioassay {INSECT SUCTION DEVICE FOR TESTING TINY HARMFUL INSECTS}

The present invention relates to a micropest bioassist, a micropest bioassay that can more conveniently perform bioassays for medicinal effects by collecting pests of very small size, such as thrips, in a petri dish. It is about the flag.

Due to micro pests such as thrips, the damage to crops such as cucumber, eggplant, and pumpkin is serious, and countermeasures are required. Most farm households use common insecticides to control thrips, but the choice of insecticides is not wide due to rapid resistance. In this regard, bio-assays for controlling thrips have been conducted by test institutes such as national research institutes and universities, but it is difficult to search for various drugs due to the large amount of test time required for each drug.

Conventional thrips bioassays were conducted by sweeping the thrush on the petri dish using brushes, pins, etc. after brushing the target pests on the damaged plants.

However, in the process of controlling thrips with a very small body size, a large number of natural deaths occur, and there is a problem that a lot of manpower and work time must be input. In addition, it is impossible to accurately determine the medicinal effect of pesticides due to the occurrence of a large number of natural deaths, and there is a limitation in which medicinal efficacy can be tested for living organisms only indoors.

In relation to the insect repeller, Patent Document 1 discloses an insect repeller that uses UV LEDs to attract insects and sucks and traps the attracted insects with a fan. Patent Literature 2 discloses a worm trap that consists of a body through which a through hole is formed in a circular shape at the top and bottom, and a trapping network that is screwed with the body to capture worms by inhaling and trapping worms by inhalation of air. .

More specifically, Patent Document 1 is a body, a suction unit provided on one surface of the body, a fan installed behind the suction unit, and at least provided on the body around the fan to irradiate ultraviolet rays toward the front The above UV LED, the discharge unit for discharging air sucked from the suction unit but discharging air in a direction different from the air suction direction of the suction unit, a duct that is an air flow path from the suction unit to the discharge unit, and the suction unit A first streamlined inner surface which is provided on the inner wall side facing the direction in which the duct extends and guides the air sucked from the suction part in the direction of the duct, and the insect trap installed on the discharge part and through which air passes and sucks in with the air. Proposing an insecticide containing a.

Patent document 2 is located at the bottom of the main body to attract insects, a bulb, a rotation filter to suck the insects attracted through the bulb, a motor located inside the bottom of the main body to move the suction fan, and suction It consists of a blocking filter unit that prevents worms from coming out, and the rotation filter is hinged so that both sides can be opened and closed based on the center of the body through-hole, and the blocking filter unit is a primary blocking filter with a narrow inlet through which the worm enters. It is composed of a car blocking filter, and a lampshade intake shade is installed around the bulb at the bottom of the main body so that insects can be attracted and sucked in. The body is installed inside the house and a catch net is installed outside the house or an open catch It is possible to radiate insects by installing a net, and the filter is detachably installed on the main body to replace the filter when the insect is inhaled and full, and the insect's carcass collects on the filter and does not scatter to prevent hygiene use. Proposal is proposed.

However, conventional insecticides have a large volume of devices, which is inconvenient to carry and handle, and it is difficult to delicately capture micro-pests such as thrips, and also has a disadvantage in that it is impossible to perform bioassay in the field immediately after the insects are captured. Countermeasures are required.

Patent Literature 1: Korean Patent Publication No. 2017-0095142 Patent Literature 2: Korean Patent Publication No. 2013-0115963

The present invention was devised in consideration of the technical background as described above, and it is possible to reduce the size and weight, and to efficiently collect micro-pests such as thrips, and at the same time capture it and put it directly in a petri dish. It is an object of the present invention to provide a micro-pest biopsy insulator that can be conveniently carried out.

Another object of the present invention is to provide a microscopic insecticidal biopest absorber of light and small size that is easy to carry and handle, and easy to assemble and separate.

In order to achieve the above object, the present invention is a petri dish having a receiving portion having an inner space capable of accommodating micro-pests and a cap portion coupled to the receiving portion; A suction inlet pipe connected to one side of the petri dish, communicating with the receiving portion, extending to a predetermined length, and exposed to the outside; An air moving pipe connected to the other side of the petri dish and communicating with the receiving portion and extending into a suction mechanism providing air suction force; And a blocking filter disposed on the cap portion to prevent micro-pests from flowing into the air moving tube.

The cap portion is fitted to the upper portion of the receiving portion to cap the receiving portion, and the upper portion of the cap portion is formed with a smaller diameter than the diameter of the cap portion to have a step difference and to provide an upper chamber communicating with the cap portion, It is preferable that the inlet pipe is connected to the upper surface of the cap portion, and the air moving pipe is connected to the side surface of the upper chamber.

It is preferable that the blocking filter is disposed in a communication portion between the cap portion and the upper chamber.

The micro-pest bioassay absorber according to the present invention may further include an air vent provided on an upper surface of the upper chamber.

Micropest bioassay intake according to the present invention has the following effects.

First, it is possible to easily collect micro-pests such as thrips with air inhalation power, and immediately capture them in a petri dish at the same time as capture, so that bioassays can be quickly and accurately performed on the pesticidal efficacy at the capture site.

Second, since the device can be constructed using a petri dish and manufactured in a compact and light weight, it is convenient to carry and handle.

Third, it is possible to shorten the working time during the bioassay and to increase the work efficiency because a large number of work personnel is not required.

Fourth, it is possible to reduce the bioassay time, so it is possible to select an effective agent by conducting a bioassay of various pesticides in a short time.

Fifth, it is possible to accurately capture the thrips to be used for the test object, so it is possible to accurately select individuals and reduce the occurrence of natural death.

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical idea of the present invention together with the detailed description of the invention described below, and thus the present invention is described in such drawings. It is not limited to interpretation.
1 is a perspective view showing the appearance of a micro-pest biopsy absorber according to a preferred embodiment of the present invention.
FIG. 2 is a partially exploded perspective view of FIG. 1.
Figure 3 is a cross-sectional view showing an example of the use of a micro-pest biopsy tester according to a preferred embodiment of the present invention.
4 is a table comparing the results of the thrips collecting operation using the micro-pest bioassist according to the present invention and the results of the thrips collecting operation using the conventional method.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, the terms or words used in the present specification and claims should not be construed as being limited to ordinary or lexical meanings, and the inventor appropriately explains the concept of terms in order to explain his or her invention in the best way. Based on the principle that it can be defined, it should be interpreted as meanings and concepts consistent with the technical spirit of the present invention. Therefore, the configuration shown in the embodiments and drawings described in this specification is only one of the most preferred embodiments of the present invention and does not represent all of the technical spirit of the present invention, and thus can replace them at the time of application. It should be understood that there may be equivalents and variations.

1 is a perspective view showing the appearance of a micro-pest bioassist for a pest test according to a preferred embodiment of the present invention, and FIG. 2 is a partially exploded perspective view of FIG. 1.

Referring to Figures 1 and 2, the micro-pest biopsy inhaler according to a preferred embodiment of the present invention is a Petri dish (Petri dish) 10 and Petri dish (Petri dish) having an internal space to accommodate the micro-pest It includes a suction inlet pipe 12 connected to one side of 10), an air moving pipe 16 connected to the other side of the petri dish 10, and a blocking filter 14 disposed inside the petri dish 10.

The petri dish 10 is a transparent container having an inner space for accommodating very small insects of several millimeters (mm) in size, such as micro pests, especially thrips, and having a round side and a flat bottom. The petri dish 10 includes a receiving portion 10a having a space to accommodate micro-pests located at the bottom and a cap portion 10b coupled to the upper portion of the receiving portion 10a.

The cap portion 10b of the petri dish 10 is fitted to the upper portion of the receiving portion 10a and caps the receiving portion 10a to prevent the collected micro-pests from flowing out. The side surface of the cap portion 10b is fitted to overlap the side surface of the receiving portion 10a. The diameter of the cap portion 10b may be designed, for example, around 55 mm.

The upper portion of the cap portion 10b is formed with a smaller diameter (for example, 34 mm) than the diameter of the cap portion 10b to provide a stepped upper chamber 13. Between the cap portion 10b and the upper chamber 13, holes through which air can pass are formed, so that they can communicate with each other. The upper chamber 13 provides a supplementary space for the introduction and intake of air to the petri dish 10 efficiently.

The suction pipe 12 is connected to the upper surface of the cap portion 10b to communicate with the receiving portion 10a, and the air moving pipe 16 is connected to the side surface of the upper chamber 13 and the upper chamber 13 and the receiving portion It is in communication with (10a). The suction pipe 12 is extended to a predetermined length and exposed to the outside. Therefore, the user closes the nozzle 12a of the intake pipe 12 for absorption to the micro-pest to be collected in a state where the front part of the intake pipe 12 for absorption is held by hand, so that the micro-pest to be collected is sucked intake pipe ( 12) You can do the collection work in such a way that it is sucked inside.

The air moving pipe 16 is connected to the other side of the petri dish 10 and communicates with the receiving portion 10a and extends to an inhalation mechanism (17 in FIG. 4) providing air suction power. The air moving tube 16 may be formed of, for example, a transparent tube having a diameter of about 7 mm.

As the suction mechanism 17, a device for generating air suction force, such as a rubber pump, is employed. Alternatively, a device with a suction fan that rotates by a predetermined power may be employed as the suction mechanism 17.

The blocking filter 14 is disposed on the cap portion 10b to prevent micro-pests from flowing into the air moving tube 16. The blocking filter 14 is preferably composed of a mesh formed with holes through which micro-pests cannot pass, such as thrips, and is preferably disposed in a communication portion between the cap part 10b and the upper chamber 13. It is preferable that the cut-off filter 14 is disposed at the center of the upper chamber 13 and the diameter is designed to be, for example, about 15 mm.

On the upper surface of the upper chamber 13, an air vent 15 having a vent hole is provided eccentrically. The air vent 15 exerts air to the outside during the inhalation operation of the intake mechanism 17 to facilitate the operation of the intake mechanism and further enhance the pest suction power. The air vent 15 is provided with a ventilation hole having a diameter of about 7 mm, for example, similar to the air moving tube 16. It is preferable that the ventilation hole provided in the air vent 15 is located at a point deviated by a predetermined distance from the center of the upper chamber 13. Specifically, the air vent 15 is preferably disposed at a point farther than the diameter of the blocking filter 14 so that the air that has passed through the blocking filter 14 can be efficiently escaped to the air moving tube 16.

Figure 3 is a cross-sectional view showing an example of the use of the micro-pest biopsy tester according to a preferred embodiment of the present invention.

In the use of the present invention, the operator collects the nozzle 12a of the intake pipe 12 for absorption by approaching the micro-pest, which is parasitic on the damaged plant, while holding the front part of the intake pipe 12 for absorption by hand. After inhaling the target micro-pest into the intake pipe 12 for sucking, or after shaking off the target pest from the damaged plant, the nozzle 12a of the intake pipe 12 for suction is brought close to the target micro-pest to be collected. The work may be performed by inhaling it into the inlet pipe 12.

As shown in FIG. 3, when the inhalation mechanism 17 performs an inhalation operation, air is instantaneously introduced through the intake pipe 12 for absorption, and micro-pests, such as thrips, which are collected, are sucked together with the air, and the petri dish (10) is introduced into the receiving portion (10a).

The air sucked together with the micro-pest moves to the upper portion of the cap portion 10b, passes through the blocking filter 14, and then passes through the upper chamber 13 and exits through the air moving pipe 16 to the suction mechanism 17. The micro-pest does not pass through the cap portion 10b by the blocking filter 14 and is contained in the inner space of the receiving portion 10a. Through this process, the micro-pest contained in the petri dish 10 can be directly used for bioassay work on the efficacy of the pesticide.

Figure 4 is a table comparing the results of collecting thrips using a conventional method of sweeping the target micro-pests into a petri dish using a brush and collecting thrips using a micropest bioassist according to the present invention. In the table, n. represents the number of attempts at the insecticidal. The number of attempts at insect respiration was defined as one when 20 thrips were collected.

As shown in FIG. 4, when the micropest bioassay absorber according to the present invention is used, it can be seen that the collection time can be significantly reduced and the live insect rate and collection accuracy of the thrips can be significantly improved.

As described above, the present invention can efficiently collect micro-pests such as thrips, and at the same time capture the micro-pests directly in the petri dish 10, and can conveniently perform bioassays for pesticidal efficacy. It has a remarkable effect.

In addition, it is possible to accurately verify the efficacy of thrips, and it is possible to conduct various drug tests by shortening the bioassay time and selecting an effective drug. The present invention can be used for collection and testing of various micro-pests (mite, powdery, etc.) in addition to thrips.

Although the present invention has been described above by way of limited examples and drawings, the present invention is not limited by this, and will be described below by the person skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the equal scope of the claims.

10: receiving portion 11: cap portion
12: intake pipe for intake 13: upper chamber
14: cut-off filter 15: air vent
16: Air moving tube 17: Intake mechanism

Claims (4)

A petri dish having an accommodating portion having an internal space capable of accommodating micro-pests and a cap portion coupled to the accommodating portion;
A suction inlet pipe connected to one side of the petri dish, communicating with the receiving portion, extending to a predetermined length, and exposed to the outside;
An air moving pipe connected to the other side of the petri dish and communicating with the receiving portion and extending into a suction mechanism providing air suction force; And
Included in the cap portion, a filter for preventing the micro-pest from flowing out of the air moving tube; micro pest biosensor containing. According to claim 1,
The cap portion is fitted to the upper portion of the receiving portion to cap the receiving portion,
The upper portion of the cap portion is formed with a smaller diameter than the diameter of the cap portion to have a step difference and an upper chamber communicating with the cap portion,
The intake pipe for inhalation is connected to the upper surface of the cap portion, and the air moving pipe is a micro-pest biopsy inhaler, characterized in that connected to the side of the upper chamber. According to claim 2,
A filter for micro-pest bioassay characterized in that the blocking filter is disposed in a communication portion between the cap part and the upper chamber. According to claim 3,
An air vent provided on the upper surface of the upper chamber; micro-pest bioassist, characterized in that it further comprises.

Images