KR100654216B1 - Device and method for counting noxious insect using flame sensor - Google Patents

Abstract

A device and a method for counting killed flying insects using a flame sensor are provided to automatically and correctly count the number of the killed flying insects in an electric insecticidal lamp by detecting a flame generated when the flying insect is killed by an electric shock. An electric insecticidal unit(210) kills the contacted flying insects by the electric shock. A flame detector(220) detects the flame generated at the surface of the electric insecticidal unit by the electric shock. A counter(230) counts a detection frequency by linking with flame detection of the flame detector. The flame detector includes the flame sensor detecting the flame of a set frequency band and a block film receiving the flame of the set frequency band while blocking light inputted from the outside.

Description

Insect insect counting device and insect counting method using flame detection sensor {DEVICE AND METHOD FOR COUNTING NOXIOUS INSECT USING FLAME SENSOR}

1 is a view for explaining the main configuration of the lightning pesticide.

Figure 2 is a block diagram showing a pesticide counting device of a fly pest using a flame sensor according to an embodiment of the present invention.

3 is a block diagram showing the configuration of the flame detection means according to the present invention.

FIG. 4 is a flowchart illustrating a pesticide counting method of a fly pest using a flame sensor according to an embodiment of the present invention.

5 is a view showing an example of an experiment for counting the number of detection by the flame detection according to an embodiment of the present invention.

6 is a view showing an example of an experiment to count the number of insect pests by flame detection after installing the pesticide counting device in an external place, according to an embodiment of the present invention.

7 is a detailed view of each component included in the insecticide counting apparatus of the present invention.

8 is an example of a block diagram for the components constituting the insecticide counting apparatus of the present invention.

<Explanation of symbols for the main parts of the drawings>

200: insecticide counting device

210: Lightning Insecticide

220: flame detection means

230: count means

240: information generating means

The present invention relates to an insect pest counting device and insect pest counting method using a flame detection sensor that automatically counts the number of insect pests attracted by lightning insects and finishes their lives, and displays them in real time on a display tool.

Particularly, the present invention provides an insect pest counting device using a flame detection sensor that accurately counts the number of digits of a flying insect pest that is electrocuted by detecting a flame generated during the electric shock in an electric insect pest that electrocuts an approaching pest. Pesticide counting method.

Gluboard-type insect pests were able to monitor the status of fly pests by checking the pests captured by the glue board with the naked eye and counting the number of pests and the number of pests.

However, it is not possible to know exactly how many insect pests have been invaded and killed by the lightning insects currently being used. However, monitoring is the only way that the control manager visually checks the dead bodies of pests killed by electric shock.

Moreover, in the conventional monitoring method, it is very difficult for the control manager to grasp the number when the dead bodies are scattered by the wind and the surrounding environment.

That is, the existing electric insect pests do not have a counter that can count the number of insect pests that have been insecticide, so it is difficult to know exactly how many insect pests are being introduced into the installation area, so it is difficult to solve the fundamental problem of the insect pests.

Therefore, it is expected that this problem can be easily solved by developing and installing a counter machine that can accurately count the number of pests that are pesticides for active management of insect pests in areas where lightning pests are installed.

Therefore, in the present invention, the control manager solves the problem of the conventional method of manually counting insect pests insects through the naked eye, insect pest counting device and insect counting method of insect pests using a flame detection sensor capable of automatic counting through the counter I would like to propose.

The present invention has been made to solve the above problems, by automatically counting the number of fly pests electrocuted by identifying the sparks generated during the electric shock of the fly pests by counting the number of fly pests manually by the conventional control manager It is an object of the present invention to provide an insect pest counting device and insect pest counting method of a fly insect using a flame sensor that can solve the inconvenience that was inevitable.

In addition, the present invention by using the flame detection sensor using a flame detection sensor that accurately counts the number of flying pests electrocuted by detecting only the flame generated by the electric shock of the flying pests while excluding UV light that attracts the flying pests It is an object of the present invention to provide a pesticide counting device and a pesticide counting method.

In addition, the present invention enables the control manager to accurately and quickly determine the current status of the insect pests in each region where the lightning pests are installed and operated, and also to identify the inflow path of the insect pests early to improve the efficiency of the control work. It is an object of the present invention to provide a pesticide counting device and insecticide counting method of fly insect pests using a flame detection sensor.

Insect pest counting device using a flame detection sensor for achieving the above object is, electric insecticide means for electric shock to the adventitious pest contact, flame detection for detecting the flame generated on the surface of the electric insecticide means by the electric shock Means; and counting means for counting the number of times of detection in association with said flame detection in said flame detection means.

In addition, as a method of the present invention for achieving the above object, the insect pest counting method using a flame detection sensor, the electric insecticide contacting the electric insect pest in contact with the electric insecticide means of the insect counting device, and the insecticide counting device Detecting a flame generated on the surface of the electric shock insecticide means by the electric shock in the flame detection means, and counting the detection frequency in association with the flame detection in the flame detection means in the counting means of the insecticide counting device; Characterized in that it comprises a step.

Hereinafter, a pesticide counting device and insecticide counting method of a fly insect pest using a flame sensor according to the present invention will be described with reference to the accompanying drawings.

1 is a view for explaining the main configuration of the lightning pesticide.

Lightning insects, commonly referred to as manned insects, are insect repellent equipment that emits long-wave UV rays that are preferred by fly insects (beetles) and attracts them to the surrounding area by attracting them.

First, the electric insecticide is a device that emits ultraviolet rays in the wavelength band that can attract the insect pests provided with the UV light emitter (100). That is, the UV light emitter 100 emits light having a peak wavelength of 352 nm, for example, known to be favored by the fly pest, and serves to attract the fly pest to the vicinity of the UV light emitter 100.

The grid network 110 is a device for installing a grid of the network structure surrounding the UV light emitter 100 at a certain distance, and electric shock electric shock to fly insects in contact with the network by blurring the high-voltage electricity to the surface of the network. That is, the grid network 110 serves to cause electrocution by high-voltage electricity applied to the network in the course of passing through the narrow hole of the net insect attracted to the UV light emitter 100 toward the UV light emitter 100. At this time, the grid network 110 may generate a flame discharge toward the fly pest approaching the network using the high-pressure discharge principle to electrocut the fly pest. Accordingly, the grid network 110 may induce electrocution not only for the fly pests in direct contact with the network but also for the fly pests in proximity to the grid network 110.

Pedestal 120 serves to collect the flying pests falling by electrocution by the electric shock. Pedestal 120 is designed to be separated from the UV light emitter 100 or grid network 110, for example, the control manager can easily clean the flying pests collected in the pedestal 120.

In other words, the electric insecticide is a discharge facility that attracts the insect pests to the UV ray to approach the high-voltage electricity flowing network, and eradicate the insect pests by using the high-voltage electricity.

The insecticide counting apparatus of the present invention accurately counts the number of non-flying insects electrocuted by such lightning insects using flames generated from lightning insects during electric shock, and thus accurately collects information on the current status of fly insect pests in the place where the lightning insects are installed. Be sure to

Figure 2 is a block diagram showing a pesticide counting device of a fly pest using a flame sensor according to an embodiment of the present invention.

The insecticide counting apparatus 200 of the present invention may include an electric insecticide means 210, a flame detection means 220, and a counting means 230.

First, the electric insecticidal means 210 electrocuts the insect pests, and is a device for electric shock using the high-voltage electricity to fly insects in close proximity or direct contact with the surface. In other words, the lightning insect killing means 210 emits light in the UV wavelength band as a attracting medium for flying insects, and serves to eradicate the flying insects attracted by the UV rays using the high-pressure discharge principle.

In the present specification, the above-described electric shock insect insect utilizing the UV ray as a attracting medium as the electric shock insecticide 210 is described. However, to illustrate the lightning insect pests as the lightning insect insect means 210 is for convenience of explanation of the present invention, in addition to the lightning insect insects by using a variety of inducing media such as CO ₂ gas emitted by the photocatalytic action of the high-pressure electric insect Various insecticides attracted to the flowing grid can be exemplified by the electric insecticide means (210).

Flame detection means 220 detects the flame generated on the surface of the lightning pest control means 210 by the electric shock of the fly pest. That is, the flame detection means 220 serves to recognize a flame of a specific wavelength band generated when the fly pest is electrocuted by the high-pressure discharge principle.

3 is a block diagram showing the configuration of the flame detection means according to the present invention.

As shown in FIG. 3, the flame detecting means 300 may include a flame sensor 310 and a blocking film part 320.

First, in order to detect the flame according to the electric shock of the fly pest, the flame detection means 300 may include a flame sensor 310 for identifying and detecting only the flame of a specific wavelength range. Flame sensor 310 is a sensor device that can detect the flame of the average wavelength of the spark generated by the electric shock, for example, 200nm wavelength, the spark is generated on the surface of the electric insecticide means 210 according to the electric shock of the flying pest It identifies and generates a predetermined signal.

In this embodiment, it is illustrated that the FLAME SENSOR "UV TRON R2868" manufactured by HAMAMATSU, Japan, is used as the flame sensor 310. The "UV TRON R2868" is an ultraviolet detector using a photoelectric effect of metal and is a sensor developed for flame detection, fire monitoring, and the like. The "UV TRON R2868" has a sensitivity in a wide band of 185 nm to 260 nm, and can accurately and quickly detect a flame (ultraviolet radiation) in the 200 nm band generated from the electric insecticide means 210.

Further, as the driving circuit for the "UV TRON R2868", this embodiment illustrates the use of the DRIVING CIRCUIT "C3704" of HAMAMATSU, Japan. The "C3704" is a driving circuit for operating the "UV TRON R2868". For example, by applying a low voltage DC 6V to 30V to the "UV TRON R2868", the "UV TRON R2868" is operated as a sensor optimized for flame detection. do.

In the present specification, as a flame sensor and a circuit for driving the same, the "UV TRON R2868" and "C3704" of HAMAMATSU Co., Ltd. have been described by way of example. It will be apparent to those skilled in the art that the present invention does not depart from the spirit of the invention.

In addition, the flame detection means 300 may further include a blocking film unit 320 to block the inflow of light from the outside, to separate and enter the flame of the set wavelength band. That is, the blocking film unit 320 blocks UV rays emitted from the electric insecticide means 210 into the flame sensor 310, and identifies and detects only the flame of the set wavelength band generated by the electric shock of the flying insect pest. Play a role. The blocking film part 320 is to prevent the flame detection means 300 makes a meaningless detection reaction by the UV rays emitted from the lightning pesticide means 210 to attract the fly pests. The wavelength band blocked by the blocking film part 320 may be flexibly set by the operator of the present system in consideration of the system environment. In the present exemplary embodiment, the blocking film part 320 may have blocking wavelength information of 380 nm band, and block UV rays, which are emitted light while maintaining the wavelength of 380 nm according to the blocking wavelength information.

By the blocking film unit 320, the flame detection means 300 can accurately identify only the flame detection due to the fly insect electric shock, without reacting to the UV light which is a attracting medium.

2 again, the counting means 230 counts the number of times of detection in association with the flame detection in the flame detection means 220. That is, the counting means 230 checks the signal generated by the flame detecting means 220 that detects the flame generated by the electric shock of the fly pest, and according to the confirmation of the signal to determine the magnitude (value) of the detection frequency For example, it serves to increase by '1'. The number of detections counted by the counting means 230 may be defined as the number of flame occurrences within a certain error range, that is, the number of electric shocks of a flying pest.

In counting the number of detections, the counting means 230 may accumulate and record the number of detections counted during a period set in a predetermined recording tool (for example, a memory (reference numeral 235 in FIG. 2)). After the elapse of time, the memory 235 is reset to accumulate the number of detections during the new period and prepare for writing. For example, the counting unit 230 may accumulate and record the number of detections counted for one week in the memory 235 provided in correspondence with the lightning insect pest A in connection with the lightning insecticide A and the like installed in the area A. Accordingly, the insecticide counting apparatus 200 of the present invention may create an environment in which the insecticide counting information for one week is generated by the information generating means 240 described later. In addition, the counting unit 230 may reset the number of detections accumulated and recorded in the memory 235 to '0' at a time point of one week elapsed, and prepare for accumulating and recording the number of detections to be generated during the next one week. .

Therefore, according to the present invention, by identifying the flame generated during the electric shock of the insect pests and automatically counts the number of insect pests electrocuted by eliminating the inconvenience of having to count the number of insect pests manually by the conventional control manager can do.

In addition, according to the present invention, by providing a blocking film portion 320 for distinguishing and identifying only the flame generated by the electric shock of the insect pests while excluding the UV light to attract the insect pests, the number of the insect pests electrocuted less To count correctly.

In addition, the insecticide counting apparatus 200 of the present invention can easily determine the current status of the insect pests or the inflow path of the insect pests at the location where the electric insecticide means (electric insecticide, etc.) is installed by generating the insecticide coefficient information. To this end, the insecticide counting apparatus 200 may further include information generating means 240, and the information generating means 240 generates insecticidal coefficient information on the electric shock insect pests using the counted detection frequency. Do it. The insecticide coefficient information may include, for example, information about the number of detections (the number of electrocution pests that have been electrocuted) counted for a period of time set in a specific region, so that the present invention accurately monitors the status of the insect pests and induces efficient control operations. Can be faithfully implemented.

In addition, the information generating means 240 may visualize and display the generated insecticide coefficient information through a display tool (eg, FND: Flexible Numeric Display). In the display of the pesticide coefficient information, the information generating means 240 1) read the accumulated detection frequency from the memory 235 at each set time interval to generate the pesticide coefficient information and display the generated pesticide coefficient information through the display tool 2) The insecticide coefficient information may be generated in real time as the number of detections increases in the memory 235, and may be visualized through a display tool.

In particular, when a plurality of lightning insect killing means 210 are installed in different positions, the information generating means 240 may generate the insecticide information including information on the number of detections counted for each period set by the lightning insect killing means. . Accordingly, according to the present invention, the control managers can accurately and quickly determine the current status of the insect pests in each region where the lightning pests are installed and operated, and also to prevent the influx path of the insect pests to be identified early. Work efficiency can be aimed at.

Hereinafter, the workflow of the insecticide counting apparatus 200 according to the embodiment of the present invention will be described in detail.

FIG. 4 is a flowchart illustrating a pesticide counting method of a fly pest using a flame sensor according to an embodiment of the present invention.

The insecticide counting method of the present invention is performed by the insecticide counting device 200 described above.

First, the insecticide counting device 200 electrocuts the insect pests that are contacted by the electric insecticide means 210 (S410). This step (S410) is a process of attracting the fly pests by using UV rays like the fly pests, electrocution of the attracted fly pests by the high-pressure discharge principle. As described above, the electric insecticidal means 210 may be implemented as an electric insecticide that emits UV rays having a peak wavelength of 352 nm, which is most preferred by the insect pests, as a attracting medium for the insect pests.

In addition, the insecticide counting device 200 detects the flame generated on the surface of the electric insecticide means by the electric shock in the flame detection means 220 (S420). This step (S420) is a process of identifying the flame generated on the surface of the electric shock pesticide means 210 by the high-pressure discharge when the fly pest is electric shock, for example, a flame sensor for detecting ultraviolet light in the wavelength range of 185nm ~ 260nm ( In 310, the flame of the 200 nm wavelength band may be identified and detected.

In particular, the insecticide counting device 200 in this step (S420) may be installed in front of the flame sensor 310, blocking film portion 320 to block the inflow of light from the outside, but to separate and enter the flame of the set wavelength band. In addition, only the flame of a specific wavelength introduced by the blocking film part 320 installed may be detected. The installation of the blocking film part 320 is to prevent the flame sensor 310 from performing a sensing operation in response to UV rays emitted from the electric insecticide means 210 to the attracting medium, and the blocking film part 320 is While maintaining the blocking wavelength information of the 380nm wavelength band, UV rays, that is, attracted light, of the similar wavelength band are prevented from entering the flame detection means 220. That is, the insecticide counting device 200 in this step (S420) allows only the flame (light) generated in the process of electric shock to fly pests to the flame detection means 220.

According to the function of the blocking film portion 320, the insecticide counting method of the present invention, it is possible to accurately identify the generation of sparks due to the electric shock of the fly pests without interference of other UV light.

Next, the insecticide counting device 200 counts the number of times of detection in association with the flame detection by the flame detection means 220 in the counting means 230 (S430). This step (S430) is a process of increasing the number of detection by a predetermined value (for example, 1) according to a predetermined signal generated according to the detection of the flame, the control manager is electrocuted by electric shock insects through an increased detection frequency Make sure you know the number of pests.

In addition, the insecticide counting device 200 generates insecticide coefficient information on the electric insect fly insect pests using the counted detection frequency (S440). This step (S440) is a process of generating statistical information on the insect pests electrocuted by the lightning pests during the set period, for example, insect pests such as individual lightning insects by using the number of detections accumulated in the plurality of lightning insects during the same period Coefficient information can be generated. Accordingly, the insecticide counting device 200 in this step (S440) can provide the current management information on the pest management in different areas as the pesticide control information to the control manager, the control manager to install the lightning pests, etc. It allows for more accurate monitoring of the pest status in the area where it is operated.

In addition, the insecticide counting device 200 in this step (S440) can be displayed in real time by visualizing the generated pesticide coefficient information through a predetermined display tool, the control manager to check the current state and path of influx of insect pests Make it early.

5 is a view showing an example of an experiment for counting the number of detection by the flame detection according to an embodiment of the present invention.

In FIG. 5, for simplicity of experiments, instead of the actual insect pests, an experiment in which the experimenter touches a grid net such as an electric insecticide with an artificial object, induces a flame, and detects the induced flame in a flame sensor.

Figure 5 is a photograph of the preliminary experimental process for the verification of the pesticide counting device, the applicant is installed on the front of the flame sensor (flame sensor) lightning pesticide to determine whether the count of the number of detection when the flame is possible The experiment was conducted.

In the above experiment, the flame sensor was installed in front of the lightning insect lamp, so that the number of detections could be counted by the counter by checking the pulses during and after the flame. In addition, in this experiment, the front surface of the sensor was covered with a UV blocking film (blocking film portion) of the 380nm band to solve the problem that the counter is malfunctioned by attracting light.

Reference numeral 501 denotes the use of 'R2826' and 'C3704' of Hamamatsu, Japan, as the flame detection sensor and driving circuit used in this experiment. As described above, the flame sensor 'R2826' detects an ultraviolet ray in the wavelength range of 185nm to 260nm, and detects a flame generated by an electric insecticide.

Reference numeral 502 exemplifies a specific embodiment of the pesticide counting apparatus of the present invention. That is, the insecticide counting device for the lab test set up for this experiment is composed of an electric insecticide lamp, a counter (counting means), and a flame sensor.

Reference numeral 503 is taken to install the UV blocking film in front of the flame detection sensor in order to block UV rays for attracting insect pests radiated from the lightning pest. The left outer shield film has the blocking wavelength information of 380nm band, and prevents the detection error of the flame detection sensor by preventing UV insect attracting insects from entering the flame detection sensor.

Reference numeral 504 illustrates the use of a photocoupler to switch the voltage level between the driving circuit 'C3704' and the counter.

Reference numeral 505 denotes photographing the wooden chopsticks wetted with water to a grid net such as an electric insecticide to artificially make a flame. Upon contact with the wooden chopsticks to the grid net, a flame is generated on the surface (grid net) such as an electric insecticide, and the flame sensor detects the spark.

Reference numeral 506 is taken by the counter to detect only the flame of the specific wavelength band through the UV blocking film, photographed that the number of detection is counted. Reference numeral 506 illustrates that the number of times the wooden chopsticks are repeatedly contacted during a predetermined period of time is visualized and displayed on the display tool FND.

6 is a view showing an example of an experiment to count the number of insect pests by flame detection after installing the pesticide counting device in an external place, according to an embodiment of the present invention.

Figure 6 illustrates a field test process for the pesticide counting device of the present invention.

In this field test, it was confirmed whether the insecticide counting apparatus of the present invention normally performs counts on very small pests such as moths and humpbacks. That is, in the present experiment, unlike a pest that is relatively large in size and has a large amount of moisture, such as a fly, and a large amount of flame is easy to detect, and a small body is small in moisture, the size of the flame when the electric shock is expected to be small, It was confirmed whether the pesticide counting device could sense it.

Reference numeral 601 is a picture taken of the base station simple septic tank used as a field test site.

Reference numeral 602 denotes a photograph of a state in which the insecticide counter of the present invention is installed and fixed in the septic tank.

Reference numeral 603 is a picture of the field test performed for about 1 hour.

Reference numeral 604 is a picture taken to electrocution of the insect pests as the insects come in contact with the lightning pests.

Reference numeral 605 is a picture of the collection of the flying insect pest electrocuted in contact with the lightning pest, etc. for 1 hour of the test time. In reference numeral 605, it can be seen that the humpback fly and the moth fly, which are relatively small in size, are collected from the flying insect pests.

Reference numeral 606 is a magnified image of a large flies having a body size of 1 to 2 mm and collected by electrocution.

By this field test, the insecticide counting device of the present invention confirmed that the flame detection and counting of the detection frequency were successfully performed even for a small fly insect.

However, when a plurality of adventitious pests are electrocuted at the same time, the insecticide counting device of the present invention generates some errors in recognizing this as a single count, but the error rate is measured to be less than 5%, so that the total adventitious pest count is large. There will be no effect.

7 is a detailed view of each component included in the insecticide counting apparatus of the present invention.

First, reference numeral 701 and 702 are photographs of a Hamamatsu driving circuit C3704 capable of sensing a 2 nm wavelength band and a UV TRON R2826 mounted on the driving circuit C3704. . The driving circuit C3704 having the UV TRON (R2826) mounted thereon is installed on the front of the lightning insect lamp and detects the flame generated by the fly insect pest.

Reference numeral 703 is provided in front of the UV TRON (R2826) to prevent the UV TRON (R2826) mounted in the driving circuit (C3704) to detect the attraction of the lightning insect, etc., not the spark caused by the lightning insect. A picture taken of a sunscreen film. By this UV blocking film, the UV TRON (R2826) does not detect the UV light of the attraction light having a wavelength of 380nm, it is possible to prevent the counting of the number of detection in the counter.

Reference numeral 704 denotes a photograph of a counter that counts the number of detections. The UV TRON (R2826) is to detect the flame generated from the lightning pest with the contact of the insect pests, the counter counts the number of detection according to the detection of UV TRON (R2826) of the insect pests electrocuted by the lightning pest Count the numbers. As shown by reference numeral 704, the UV TRON (R2826) excludes UV rays such as attracting lights and detects only the flame 17 times, so that the counter counts the number of detections to 17 and the display FND visualizes and displays the number of detections 17. Doing.

8 is an example of a block diagram for the components constituting the insecticide counting apparatus of the present invention.

First, the driving circuit may include a pulse generator (PG) 801 and a boosting transformer (BT) 802. The PG 801 is an apparatus for generating an electrical signal (waveform), and may generate various types of electrical signals (square wave, triangular wave, sine wave, etc.) in addition to the AC and DC electric signals. The BT 802 is an apparatus for outputting an input signal as an output signal boosted to a predetermined size.

Reference numeral 803 denotes a UV-T, and the UV-T 803 may illustrate a UV TRON (R2826) used as a flame detection sensor in the present invention. The UV-T 803 may be mounted in a driving circuit to be optimally operated as a flame detection sensor.

Reference numeral 804 denotes an analog signal processing block A. The A 804 performs predetermined signal processing on an analog signal output from the UV-T 803.

Reference numeral 805 shows a photo coupler (signal level change, PG), and the PG 805 combines a light emitting element and a light receiving element to transmit a signal to a medium.

Reference numeral 806 denotes a buffer block B, which serves to temporarily wait for a signal output from the PG 805 for the next processing.

The signal waiting for the B 806 is received by the uP (microprocessor) 807 via the digital BUS after a predetermined delay time elapses. The uP 807 may record the received signal in the memory (M, 808) or accumulate and display the number of detections in the display (D, 809).

Therefore, according to the present invention, by identifying the flame generated during the electric shock of the insect pests and automatically counts the number of insect pests electrocuted by eliminating the inconvenience of having to count the number of insect pests manually by the conventional control manager can do.

In addition, according to the present invention, it is possible to accurately count the number of fly pests electrocuted by eliminating the UV light that attracts fly pests, and having a blocking film portion for distinguishing and identifying only the sparks generated by the electric shock of the fly pests. To help.

Embodiments of the invention include a computer readable medium containing program instructions for performing various computer-implemented operations. The computer readable medium may include program instructions, local data files, local data structures, or the like, alone or in combination. The media may be those specially designed and constructed for the purposes of the present invention, or they may be of the kind well-known and available to those having skill in the computer software arts. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tape, optical recording media such as CD-ROMs, DVDs, magnetic-optical media such as floppy disks, and ROM, RAM, flash memory, and the like. Hardware devices specifically configured to store and execute the same program instructions are included. The medium may be a transmission medium such as an optical or metal wire, a waveguide, or the like including a carrier wave for transmitting a signal specifying a program command, a local data structure, or the like. Examples of program instructions include not only machine code generated by a compiler, but also high-level language code that can be executed by a computer using an interpreter or the like.

While specific embodiments of the present invention have been described so far, various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the claims below, but also by those equivalent to the claims.

As can be seen from the above description, according to the present invention, by identifying the flame generated during the electric shock of the insect pests to automatically count the number of insect pests electrocuted by the conventional control manager to manually count the number of insect pests It is possible to provide an insect pest counting device and insect pest counting method of a fly pest using a flame sensor that can solve the inconvenience that was inevitable.

In addition, according to the present invention, by using only a flame detection sensor that accurately counts the number of non-airborne pests electrocuted by distinguishing and detecting only the flame generated by the electric shock of the non-existent pests while excluding the UV light that attracts them It is possible to provide an insect pest counting device and insect pest counting method of the insect pests.

In addition, according to the present invention, the control managers can accurately and quickly determine the current status of the insect pests in each region where the lightning pests are installed and operated, and also to prevent the influx path of the insect pests to be identified early, the control work It is possible to provide an insect pest counting device and insect pest counting method of a fly insect pest using a flame detection sensor which aims to improve the efficiency of the present invention.

In addition, according to the present invention, by implementing the counting equipment by utilizing the existing electric pesticides as it is easy to apply the field and insect pest counting device and insect counting method of insect pests using a flame detection sensor that can reduce the cost burden due to development Can provide.

Claims (10)

Insecticide counting device, Electric insecticidal means for electric shock of the adventitious pest contacted; Flame detection means for detecting a flame generated on the surface of the electric shock insecticide means by the electric shock; And Counting means for counting the number of detections in association with the flame detection in the flame detection means Insect pest counting device of the insect pests using a flame detection sensor comprising a. The method of claim 1, The flame detection means, Flame sensor identifies and detects flames at set wavelengths Insect pest counting device of the insect pests using a flame detection sensor comprising a. The method of claim 2, The flame detection means, Blocking film portion to block the inflow of light from the outside, but to separate and enter the flame of the set wavelength band Insect pest counting device of the insect pests using a flame detection sensor comprising a. The method of claim 3, The blocking film unit insect pest counting device of the insect pest using the flame detection sensor, characterized in that it comprises the blocking wavelength information of 380nm band. The method of claim 1, The electric insecticide means for insect pest counting apparatus using a flame detection sensor, characterized in that for emitting the light in the UV wavelength band to the attracting medium for the insect pests. The method of claim 1, The electric insecticide means of insect pest counting apparatus using a flame detection sensor, characterized in that the electric shock to the electric insect pest using the high-pressure discharge principle. The method of claim 1, And information generating means for generating insecticidal coefficient information for the electric shocked insect pest using the counted detection frequency, The information generating means is insecticide counting device of the insect pests using a flame detection sensor, characterized in that for displaying the insecticide coefficient information by visualizing the display tool. In the insecticide counting method by an insecticide counting device, Electric shock of the adventitious pest contacted by the electric insecticide means of the insecticide counting device; Detecting a flame generated on the surface of the electric insecticide means by the electric shock in the flame detection means of the insecticide counting device; And And counting the number of times of detection in association with the flame detection by the flame detection means in the counting means of the insecticide counting device. The method of claim 8, The step of detecting the flame, Blocking the inflow of light from the outside but providing a blocking film unit for separating and entering the flame of the set wavelength band; And Detecting a flame introduced by the blocking film part Insect pest counting method of the insect pests using a flame detection sensor comprising a. A computer-readable recording medium having recorded thereon a program for executing the method of claim 8 or 9.

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