KR100688247B1 - Device and method for counting noxious insect using current sensor - Google Patents

Abstract

A device and a method for counting flying noxious insects using a current sensor are provided to solve inconvenience of manual counting by automatically counting the killed flying noxious insects with the current sensor for detecting current or voltage changes generated when the flying noxious insects are killed in the insecticidal lamp. The insecticidal map(210) electrifies the contacted flying noxious insects, and the sensor(220) detects a signal change generated in the insecticidal lamp by electric shock. A counter(230) counts detections by linking with the signal change of the sensor. An information generator(240) generates killed insect counting information for the electrified flying noxious insects by using a counted detection value and displays the generated killed insect counting information through a display tool. The sensor identifies a kind of the contacted flying noxious insects according to a level of the detected signal change. The killed insect counting number includes the information for the detection value counted by each kind of the identified flying noxious insects.

Description

TECHNICAL FIELD [0001] The present invention relates to a pest insect counting apparatus and a pest insect counting method using a current sensor,

Fig. 1 is a view for explaining a main structure of a bug insect lamp.

2 is a block diagram showing an insect-counting apparatus for insect pests using a current sensor according to an embodiment of the present invention.

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

4 is a flowchart illustrating a method of insect counting using a current sensor according to an embodiment of the present invention.

5 is a flowchart illustrating an example of detecting a signal change according to the present invention.

6 is a diagram illustrating an example of an experiment for counting the number of times of detection by signal change detection according to an embodiment of the present invention.

7 is a diagram illustrating an example of an experiment for counting the number of times of detection by signal change detection according to another embodiment of the present invention.

8 is a diagram showing an example of an experiment for setting the counting delay time for the insect counting apparatus of the present invention.

Fig. 9 is a detailed view of each component included in the insecticide counting apparatus of the present invention.

10 is an example of a block diagram for a component constituting the insect control apparatus of the present invention.

Fig. 11 is a photograph of an example in which a change in current caused by an electric insect pest or the like is measured during an electric shock of a pest insect.

Description of the Related Art

200: Insect counter

210: Lightning insecticide

220: sensor means

230: Counting means

240: Information generating means

The present invention relates to a pest insect counting apparatus and a pest insect counting method using a current sensor that automatically counts the number of pest insects that are attracted to a live insecticide and finishes its life and display it on a display tool in real time.

In particular, the present invention relates to an insect pest insect pest insect pest insect pest insect pest insect pest insect pest insect pest insect pest insect pest insect pest insect pest insect pest insect pest insect pest insect pest And a method of insecticidal counting.

The glue board type insect pests were able to monitor the status of insect pests by checking the insects trapped in the glue board with the naked eye and counting the number of insects and confirming the type and number of insects.

However, it is not known exactly how many insect pests have been invaded by insecticides currently being used. However, the extent to which the control manager has visually confirmed the dead body of a pest killed by an electric shock is all that is monitored.

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

That is, since there is no counter for counting the number of insect pest insects in the existing insect pest, it is difficult to solve the fundamental problem of insect insect pest, since it is not known exactly how many insect pest is introduced into the installation area.

Therefore, in order to actively control the insect pests in the area where the insect pest is installed, it is expected that the problem can be solved easily by developing and installing a counter which can accurately count the insect pest count.

Accordingly, the present invention solves the problems of the conventional method of manually counting insect pest insects through the naked eye, and provides a pest insect counting apparatus and insecticidal counting method of a pest insect using a current sensor capable of automatic counting by a counter I would like to propose.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a method and apparatus for automatically detecting a current change or voltage change, Insect counting apparatus and insecticidal counting method using a current sensor capable of solving the inconvenience that it is necessary to count the number of insecticides.

Further, the present invention provides a pest insect counting apparatus and insecticidal counting method of a pest insect using a current sensor capable of counting the number of pest insects to be electrified by the pest insect species by identifying the kind of pest insect that electrifies from the converted current value .

In addition, the present invention enables the control manager to accurately and promptly grasp the status of pest insects in each region where the pest insecticide is installed and operated, and to identify the inflow path of the pest insect early, And to provide a method for insecticide counting and insecticidal counting of insect insect pests using a current sensor.

In order to achieve the above-mentioned object, a pest insect counting apparatus using a current sensor is provided with a pest insecting means for electric shock of a pest insect coming into contact with the pest, and a pest inspecting means for detecting a signal change generated in the electric pest insecting means And a counting means for counting the number of times of detection in conjunction with the signal change detection in the sensor means.

According to another aspect of the present invention, there is provided a method for insect counting of insect pests using a current sensor, comprising the steps of: electrifying insect pests contacted by the insect pest counting means of the insect pest counting apparatus; Detecting a change in the signal generated in the lightning pest control means by the electric shock in the sensor means and counting the number of senses in response to the signal change detection in the sensor means in the counting means of the insect counter .

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

Fig. 1 is a view for explaining a main structure of a bug insect lamp.

The lightning insecticide, commonly referred to as an insect insecticide, is an insect repellent device that emits UV rays of long wavelengths favored by insect pests (fly insects) and attracts insect pests to the periphery of the insect and then electrifies them with high pressure.

First, a bug insecticide is a device that emits ultraviolet rays of a wavelength range capable of attracting insect pests by having a UV light emitter 100. That is, the UV light emitter 100 radiates light having a peak wavelength of, for example, 352 nm, which is known to be preferred by the pest insect, to attract the pest insect around the UV light emitter 100.

The grid network 110 is a device for installing a grid of a network structure that surrounds the UV light emitters 100 at a certain distance and for electrically discharging the insect pests that are in contact with the network by blurring the high voltage electricity with the network surface. In other words, the grid network 110 plays a role of attracting the UV rays and causing the insect pests directed to the UV emitters 100 to be electrified by the high voltage electric power applied to the network in the process of passing through the narrow holes of the network. At this time, the grid network 110 may generate a spark discharge toward an insect pest approaching the network by using a high-voltage discharge principle to electrify the insect pest. Accordingly, the grid network 110 can induce electrotransmission even for insect pests that are in direct contact with the network, as well as insect pests that are close to the grid network 110.

The pedestal 120 serves to collect the insect pests that fall by electrification by the electric power. The pedestal 120 is designed to be separable from the UV emitter 100 or the grid network 110, for example, to allow the pollution control manager to easily clean the pests collected on the pedestal 120.

That is, the lightning insecticide is a discharge device for attracting the insect pests to the UV line to approach the network through which high-voltage electricity flows, and to eradicate the insect pests using the high-voltage electricity.

The insect-counting apparatus of the present invention counts the number of insect pests that are electrified by such insect pest by using the change of current or voltage caused by electric insect pest during electric shock, Ensure that information is accurately aggregated.

2 is a block diagram showing an insect-counting apparatus for insect pests using a current sensor according to an embodiment of the present invention.

The insecticide counting apparatus 200 of the present invention may include the lightning insecting means 210, the sensor means 220, and the counting means 230.

First, the lightning insecting means 210 is an apparatus for electrifying an insect pest, and electrically discharging the insect pest which is in proximity to or directly in contact with the surface of the grid net by means of high-voltage electricity. That is, the lightning insecting unit 210 emits light in the UV wavelength band to the attracting medium for the pest insect, and eradicates the pest insect attracted by the UV rays using the high-voltage discharge principle.

In the present specification, the above-described electric insecticide lamp using UV rays as the attracting medium is described as an example of the electric insecticide means 210. It should be noted that the lightning insecticidal means 210 is exemplified by the lightning insecticide means 210 for explaining the present invention. In addition to the lightning insecticide, the insecticidal means 210 may utilize various attracting media such as CO2 gas emitted by the photocatalytic action, It is needless to say that various insecticidal lamps attracted to the flowing grid can be exemplified as the lightning insecticide means 210.

The sensor means (220) is a device for detecting a signal change occurring in the electric killer means (210) by the electric shock of the pest insect. That is, when the insect pest is electrified by the high-voltage discharge principle, the sensor means 220 changes the magnitude of the electric current flowing in the grid network 110 of the electric insecticidal means 210 or the mode in which the magnitude of the voltage changes It plays a role of recognizing. High voltage electricity of, for example, 3 KW flows in the grid network 110, and the resistance size of the grid network 110 as a whole is changed (when the insect pest is connected to the grid network 110) The voltage or current flowing in the grid network 110 also temporarily fluctuates.

That is, the sensor means 220 senses a change in the voltage or a change in the electric current in the electric killer means 210, and recognizes the point of time when the insect pest is electrocuted when the change is detected.

For example, assuming that the current flowing through the grid network 110 is normally 2.3 to 2.5 A, the sensor means 220 recognizes the magnitude 3.0 A of the changed current due to the electric shock of the pest insect, 210 may be contacted with the insect pests to sense that they are electrocuted.

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

3, the sensor unit 300 may include a current transformer (CT) 310, a current-voltage conversion circuit 320, and a voltage analyzer 330.

The sensor means 300 in Fig. 3 exemplifies the monitoring of the change in current flowing in the lightning insecting means 210 (the grid network 110 of the lightning insecting means 210) as a signal change to be sensed.

First, the sensor means 300 may include an ultra-precise current transformer 310 for measuring the current during the electric shock of the pest insect through an electrode connected to the electric pest inserting means 210 and for changing the current. The electric insecticide 210 is supplied with high-voltage electricity for electrically discharging insect pests, and the electric current according to the high-voltage electric current continuously flows at a constant magnitude. The ultra-precise current transformer 310 is connected to the light insecticide means 210 is temporarily changed in magnitude, and the current at that point is measured.

In the measurement of the current, the ultra-precise current transformer 310 can accurately measure the changed current at the time when the insect pest is electrically charged by using the electrode electrically connected to the electric fungicide 210.

Thereafter, the ultra-precise current transformer 310 converts the measured current into a current of a predetermined magnitude proportional to the current. The ultra-precise current transformer 310 may be, for example, a clamp meter.

In addition, the sensor means 300 may include a current to voltage converter (CVC) 320 for converting the changed current into a voltage. That is, the current-voltage conversion circuit 320 serves to convert a fine current value into a voltage value, the input of the circuit being a current, and the output being a voltage.

The use of this current-to-voltage conversion circuit 320 is intended to convert the current into a voltage value and to use it to infer the current value if it is not easy to measure a significantly small current or a fairly large current.

In addition, the sensor means 300 may include a voltage analyzer 330 for analyzing the converted voltage to monitor a change in current. That is, the voltage analyzer 330 can recognize the degree of change (current value) of the measured current using the converted voltage value.

The degree of change in the perceived current may be used to infer the type of spawning insect pests. For example, when the degree of change in the perceived current is relatively large, the sensor means 300 can infer that the change in current is caused by electric shock due to a large flies that are large in size. On the other hand, when the degree of change in the perceived current is relatively small, the sensor means 300 can deduce that the change of the current is caused by the electric discharge of the 'moth flies or flies', which are small in size, by the electric insecticide.

That is, the sensor means 300 not only recognizes that the pest insect is electric shocked by the electric insecticide lamp by sensing the current change in the electric insecticidal means 210, but also recognizes the kind of insect pest electric shocked by the electric insecticidal lamp approximately It can be recognized.

Referring again to FIG. 2, the counting means 230 counts the number of times of detection in conjunction with sensing of a signal change in the sensor means 220. That is, the counting means 230 confirms a signal generated by the sensor means 220 that senses a change in current or a voltage generated due to the electric shock of the pest insect, And increases the size (numerical value) by, for example, '1'. The number of sensed times counted by the counting means 230 can be defined as the number of signal changes occurring within a certain error range, that is, the number of times that the pest insects are electrically charged.

In the counting of the number of times of detection, the counting means 230 may accumulate and record the number of sensed counts for a predetermined period of time in a predetermined recording tool (for example, memory (reference numeral 235 in FIG. 2) The memory 235 is reset to prepare for accumulation and recording of the number of senses for a new period. For example, in relation to the lightning insecticide B installed in the area B of the promenade, the counting means 230 may accumulate and record the number of sensed times for one day (one day) in the memory 235 provided corresponding to the lightning insecticide B . Accordingly, the insect counting apparatus 200 of the present invention can create an environment in which the insecticide counting information for the first day is generated by the information generating means 240 described later. In addition, the counting means 230 can reset the number of sensed cumulative and recorded senses to '0' in the memory 235 at the time when one day has elapsed, and prepare for accumulation and recording of the sensed number to be generated in the next one day .

Therefore, according to the present invention, the number of insect pests that can be electrified by sensing a current change or a voltage change in the insect pest or the like when the insect pest is electrically charged is automatically counted to manually count the number of insect pests by the conventional control manager It is possible to solve the inconvenience that was not present.

Further, according to the present invention, an environment is provided for counting the number of insect pests that are electrified for each pests type by identifying the kind of pests that are electrocuted from the converted current value.

In addition, the insecticidal counting apparatus 200 of the present invention can generate insecticide counting information to easily identify the state of insect pests at the location where the insect pest insect (light insect pest insect) is installed and the infestation path of insect insect pest. For this purpose, the insect counting apparatus 200 may further include an information generating unit 240, and the information generating unit 240 generates insect counting information on the charged insect pests using the counted number of sensed senses . The insecticide counting information may include, for example, information on the number of sensed counts (the number of insect pests that have been electrocuted) for a predetermined period of time in a specific area, thereby accurately monitoring the status of insect pests and inducing efficient control work. Can be faithfully fulfilled.

Particularly, in the present invention, the information generating unit 240 identifies the kind of the pest insect to be contacted to the lightning insecting unit 210 according to the magnitude of the signal change (the estimated current value) sensed by the sensor unit 220 , And the insecticide counting information may be generated by using the information on the counted number of times of insect pest counting. For example, the insecticide counting information generated by the information generating means 240 may include information corresponding to the number of sensed senses recorded by each size of the insect pests (large, medium, and small).

The information generation means 240 may visualize the generated insecticidal coefficient information through a display tool (e.g., FND: Flexible Numeric Display). In the display of the insecticide counting information, the information generating means 240 reads 1) the cumulative number of sensations from the memory 235 at predetermined time intervals, generates insecticide count information, and displays the generated insecticide count information through a display tool Or 2) generate insecticide count information in real time as the number of senses increases in the memory 235, and visualize the insecticide count information through a display tool.

In particular, when a plurality of lightning insecticidal means 210 are installed at different locations, the information generation means 240 may generate the insecticidal information including information on the number of sensed counts during a predetermined period for each lightning pest control means . Accordingly, according to the present invention, it is possible to allow the control manager to accurately and quickly grasp the status of pest insects in each region where the pest insect lamp is installed and operated, and to identify the inflow path of the pest insect early, The efficiency of the operation can be improved.

Hereinafter, the operation flow of the insect counting apparatus 200 according to the embodiment of the present invention will be described in detail.

4 is a flowchart illustrating a method of insect counting using a current sensor according to an embodiment of the present invention.

The insect counting method of the present invention is performed by the insect counting apparatus 200 described above.

First, the insecticidal counting device 200 charges the insect pest contacted by the lightning insecting means 210 (S410). This step S410 is a process for attracting the pest insect using the UV rays preferred by the pest insect and electrostatically attracting the attracted insect pest by the high voltage discharge principle. The lightning pest control unit 210 may be implemented as a lightning pest that emits UV rays of the peak wavelength of 352 nm, which is preferred by the pest insect, to the attracting medium for the pest.

In addition, the insect counting apparatus 200 senses a signal change generated in the lightning insecting means 210 by the sensor means 220 (S420). The step S420 is a process of identifying a change of a current flowing in the grid network 110 or a change of a voltage of the lightning pest control means 210 at the time when the pest insect is electrically charged.

For example, assuming that the current flowing through the grid network 110 is normally 2.3 to 2.5 A, the insect counting apparatus 200 senses that the magnitude of the current changes to 3.0 A due to the electric shock of the insect pest .

5 is a flowchart illustrating an example of detecting a signal change according to the present invention.

FIG. 5 illustrates a process of monitoring a change in current as an embodiment of detecting a signal change according to the present invention.

The insect counting apparatus 200 measures the electric current at the time of electric shock of the insect pest through an electrode connected to the electric insect pest 210, and changes the electric current (S510). In the lightning insecticide means 210, high-voltage electricity flows for electrically discharging insect pests, and a current according to the high-voltage electricity flow continuously flows at a constant magnitude. In this step S510, 210 is temporarily changed in size, and the current is measured at that time. In the measurement of the electric current, the insect counting apparatus 200 can accurately measure the changed electric current at the time when the insect pest is electrically charged by using the electrode electrically connected to the electric insecticide means 210. Thereafter, the insect counting apparatus 200 changes the measured current to a current of a predetermined magnitude proportional to the current.

In addition, the insect counting apparatus 200 converts the changed current into a voltage (S520). In this step S520, a fine current value is converted into a voltage value by using the current-voltage conversion circuit 320, and the voltage conversion process is performed by using the input of the circuit as a current and the output as a voltage. This step S520 is a process for converting the current into a voltage value and inferring the current value by using the current when the current is considerably small, or when the current is considerably large or when it is not easy to measure the current.

Next, the insect counting apparatus 200 analyzes the converted voltage to monitor a change in current (S530). In this step S530, the voltage value converted by the voltage analyzer 330 may be used to recognize the degree of change (current value) of the measured current.

In particular, in this step S530, the insect counting apparatus 200 can infer and identify the kind of insect pests that are electrified in the electric fence insecting unit 210 based on the degree of change of the perceived current. For example, the insect-counting apparatus 200 can be interpreted as a change in the perceived current due to the large-sized 'fly' sensed by a pest insecticide when the perceived current change is relatively large. On the other hand, the insect-counting apparatus 200 can deduce that the change of the current is caused by the electric shock of the small moth flies or hippopotamuses when the change of the perceived current is relatively small.

That is, the insect counting apparatus 200 not only recognizes that the insect pest is electrically charged by the electric insecticide lamp by sensing the current change in the electric insecticide means 210, but also recognizes the kind of insect insect pest electric shocked by the electric insecticide lamp .

Referring again to FIG. 4, the insect counting apparatus 200 counts the number of times of sensing in conjunction with sensing of a signal change in the sensor means 220 in the counting means 230 (S430). In this step S430, the detection number is increased by a predetermined value (for example, 1) according to a predetermined signal generated according to the detection of a signal change. The number of insect pests can be grasped.

In addition, the insect counting apparatus 200 generates insecticide count information on the charged insect insect using the counted number of sensed senses (S440). This step S440 is a process of generating statistical information on insect pests that are electrified by a pest insect light for a set period of time. For example, by inserting insect pests Coefficient information can be generated. Accordingly, the insecticidal counting apparatus 200 in this step S440 can provide status information on the pest insects in different regions to the control administrator as the above-mentioned insecticide count information, This will enable more accurate monitoring of the pest status of the pest control area in operation.

The insecticide counting apparatus 200 in this step S440 can display the generated insecticide count information by visualizing it with a predetermined display tool and display it in real time so that the pollution control manager can display the insect pest count information and route Be able to grasp early.

6 is a diagram illustrating an example of an experiment for counting the number of times of detection by signal change detection according to an embodiment of the present invention.

FIG. 6 is a photograph of an experiment process of measuring the change of the insecticidal current by connecting a superconducting current transformer (CT) to a primary insecticide primary (220V) and a secondary (3,800V).

Reference numeral 601 denotes a test fly taken as an insect pest used in the present experiment.

Reference numeral 602 is a photograph of an experimental mosquito net used in this experiment, in which the insect pest is forced to fly within a certain spatial range.

Reference numeral 603 denotes a photographed lightning insect lamp (product of Inchec Co., Ltd.) used in the present experiment.

Reference numeral 604 is a photograph of a current transformer (CT) and a current-to-voltage converter circuit used in the present experiment.

Reference numeral 605 denotes a voltage change measurement tool using an oscilloscope and a multimeter.

Reference numeral 606 is a photograph showing a state in which a moving picture of measurement data counted by the insect counter device of the present invention is photographed.

Experiments using these experimental tools may require sensitivity enhancement processing to increase the detection success rate because the measured current change is weak. In addition, the insect counting apparatus can easily pic-up the primary current change by the experimental environment using the above-described experimental apparatus.

7 is a diagram illustrating an example of an experiment for counting the number of times of detection by signal change detection according to another embodiment of the present invention.

FIG. 7 is a photograph of a counter board production and a lab test process, illustrating the progress of the production and testing of a processor board capable of counting the primary side current change detection.

Reference numeral 701 is a photograph taken to increase the resistance value by adjusting the number of turns for sensitivity increase in the experimental environment of FIG. 6 described above. In this experiment, the number of turns is adjusted to 5 turns to adjust the resistance value from 150 ohms to 470 ohms.

Reference numeral 702 denotes an experiment preparation process for counting test.

Reference numeral 703 is a photograph of counting the number of electric insecticides (number of senses) of the insect pest which detects the contact of the insect pest and the change of the electric current due to the contact, connecting a counter to the electric insecticidal lamp.

Reference numerals 704 and 705 are photographs showing the increase in the number of electric insecticides of the counter by recognizing the insect pest contact to the electric insecticidal lamp according to the detection of the electric current change.

Reference numeral 706 is a photograph of the last counted number of electric insect killings. In this experiment, it was confirmed that the detection success rate was about 85% by counting the number of times '11 times' sensed by the current change in the actual electrocuted 13 animals.

According to this experiment, the lap test using flies showed about 80% detection success rate.

8 is a diagram showing an example of an experiment for setting the counting delay time for the insect counting apparatus of the present invention.

FIG. 8 is a photograph in which the counting test is performed by setting the counting delay time of the counter to 1 second (the counter response speed is 1 second) while carrying out the lap test by mounting the counter on the side of the electric insecticide.

Reference numeral 801 denotes an entire image of the insecticidal lamp for testing completed.

Reference numeral 802 denotes a front view of the assembled test insecticide.

Reference numeral 803 denotes a side view of the assembled test insecticide.

Reference numeral 804 is a photographed image showing that the insect pest is electrocuted to the insect pest as the insect pest is contacted through the test progress.

Reference numeral 805 denotes a photographed photographed insect pest collected during the test time in contact with the pest insect light. At 805, a total of 18 insect pests that were electrocuted during the test time can be confirmed.

At 806, the number of sensed counts of the counter by the electric current of the electric killer means 210 is measured for 18 actual pests. In the figure 806, when the delay time is set to 1 second, two insects are counted, and the total number of senses is visualized and displayed in the display tool (FND) with '38 times'. Therefore, it can be seen from this experiment that delay time adjustment or adjustment of the counter display value is necessary.

FIG. 9 is a detailed view of each component included in the insect counter device of the present invention. FIG.

First, reference numeral 901 denotes a photodiode for measuring a secondary power line inside a bombardment lamp with a clamp meter. Clamp meter is a device that can measure the current without breaking the wire. It is a device that measures the current by inducing the magnetic field generated from the wire.

Reference numeral 902 denotes a current value measured by a clamp meter with respect to the secondary side power supply line. And reference numeral 902 indicates that the current value 2.3 A at the normal time is measured. As described above, the value of the current flowing through the electric insecticide lamp is normally measured at 2.3 to 2.5 A, and the insect pest is measured at 3.0 A when the electric insulator is charged.

Reference numeral 903 denotes a current transformer of the present invention having the same function as the clamp meter. The ultra-precise current transformer senses the current value of the instant insecticide lamp, which changes as the insect pest is fired, and counts the number of insect pest insects (the number of senses) counted by a predetermined counter.

Reference numeral 904 is a photograph of FND as a display tool for visualizing and displaying the number of insect pests counted by the counter.

10 is an example of a block diagram for a component constituting the insect control apparatus of the present invention.

Reference numeral 1001 denotes a current transformer (CT), which is a device that acquires a small current proportional to a large current. That is, the CT 1001 is a device that draws the classified current signal through the current shunt (CS, reference numeral 1002) and into the analog signal processing block (A, 1003).

Reference numeral 1003 denotes an analog signal processing block (A), and the A 1002 performs predetermined signal processing on the inputted analog signal.

Reference numeral 1004 denotes an analog electronic filter (F). The F 1004 filters the signal processed analog signal and extracts only a necessary part of the signal.

Reference numeral 1005 denotes sample and hold (S & H). The S & H 1005 maintains an input voltage or output voltage to an analog-to- / D < / RTI >

Reference numeral 1006 denotes an analog-to-digital converter (A / D), and the A / D 1006 converts a filtered analog signal into a digital signal

The digital signal converted by the A / D 1006 is received by a microprocessor (1007) via a digital BUS. The uP 1007 can record the received signal in the memory (M, reference numeral 1008) or cumulatively display it as the number of times of detection in the display (D, 1009).

Fig. 11 is a photograph showing an example in which a change in current caused by an electric insect pest during electric shock of an insect pest is measured.

FIG. 11 illustrates a current sensor that senses a current flowing through a bug insect lamp and displays it on an oscilloscope.

As shown in Fig. 11, the current sensor measures a current of 2.3 to 2.5 A normally due to the current flowing through the insecticide lamp.

If the insect pest is contacted with the electric insecticide lamp and the insect pest is electrified by the electric insecticide, the current value flowing through the insecticidal insecticide temporarily changes. This can be seen in the right picture of FIG.

That is, the insect-counting apparatus of the present invention can detect the current change in the electric insect pest and the like according to the electric shock of the pest insect, and count the number of insect pest insect insect number.

Therefore, according to the present invention, it is possible to solve the inconvenience of manually counting the number of insect pests by the conventional control manager by automatically counting the number of insect pests that are electrified by the current change occurring when the insect pest is electrically charged can do.

Further, according to the present invention, an environment is provided for counting the number of insect pests that are electrified for each pests type by identifying the kind of pests that are electrocuted from the converted current value.

Embodiments of the present invention include computer readable media including program instructions for performing various computer implemented operations. The computer-readable medium may include program instructions, local data files, local data structures, etc., alone or in combination. Such media may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape, optical recording media such as CD-ROMs and DVDs, magneto-optical media such as floppy disks, and ROMs, And hardware devices specifically configured to store and execute the same program instructions. The medium may be a transmission medium such as optical or metal lines, waveguides, etc., including a carrier wave for transmitting a signal specifying a program command, a local data structure, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims and the claims.

As can be seen from the above description, according to the present invention, by automatically counting the number of insect pests that electrify by identifying a current change or voltage change that occurs when an insect pest is electrically charged, It is possible to provide a pest insect counting apparatus and a pest insect counting method of a pest insect using a current sensor capable of solving the inconvenience that can not be counted.

In addition, according to the present invention, by inserting the type of insect pests to be electrified from the converted current value, it is possible to count the number of insect pests that are electrified by the insect pest type, Can be provided.

In addition, according to the present invention, it is possible to allow the control manager to accurately and promptly grasp the status of pest insects in each region where the pest insect lamp is installed and operated, and to identify the inflow path of pest insect early, It is possible to provide a pest insect counting apparatus and a pest insect counting method of a pest insect by using a current sensor for improving efficiency.

Claims (10)

In the insect counting device, Electric insect repellent means for electric shocking the flying insect which is contacted; A sensor means for detecting a signal change generated in the electric firing device by the electric shock; Counting means for counting the number of times of detection in conjunction with the signal change detection by the sensor means; And And information generating means for generating insecticide count information for the electrified insect pests using the counted number of sensed times and visualizing and displaying the generated insecticide count information through a display tool, Wherein the sensor means identifies the kind of the insect pest contacting the electric fungicide means according to the magnitude of the sensed signal change, Wherein the insecticide counting information includes information on the number of sensed counts for each of the identified insect pest species. The method according to claim 1, Wherein the sensor means monitors a change in current flowing in the electric fence insecting means as the signal change. 3. The method of claim 2, The sensor means An ultrasound defibrillator (CT) for measuring the current at the time of electric shock of the pest insect through an electrode connected to the lightning pest control means and changing the current; A current-voltage conversion circuit (CVC) for converting the converted current into a voltage; And A voltage analyzer for analyzing the converted voltage and monitoring the change of the current; Wherein the insect-counting device is a pest insect-counting device using a current sensor. delete delete The method according to claim 1, Wherein the lightning pest control means emits light in the UV wavelength band to the attracting medium for the pest insect. The method according to claim 1, Wherein the electric insect repellent means electrically charges the contact insect pests using a high voltage discharge principle. In the insect counting method by the insect counting apparatus, A step of electrically discharging a flying insect which is contacted by the insecticidal means of the insecticidal counting device; Detecting a change in a signal generated in the lightning pest control means by the electric shock in the sensor means of the insect counting device; Counting the number of times of detection in conjunction with sensing of the signal change in the sensor means in the counting means of the insect counting device; And Generating insecticide count information for the charged insect pests by using the counted number of times of sensing in the information generating means of the insect counter, and visualizing and displaying the generated insecticide count information through a display tool , Wherein the sensor means identifies the kind of the insect pest contacting the electric fungicide means according to the magnitude of the sensed signal change, The step of visualizing and displaying the insecticidal coefficient information through a display tool, Displaying insecticide count information including information on the number of sensed counts for each type of the identified insect pest Wherein the insect counting method comprises the steps of: 9. The method of claim 8, The step of detecting a signal change comprises: Measuring an electric current at the time of electric shock of the insect pest through an electrode connected to the electric insecticide means, Converting the converted current into a voltage; And Monitoring the change of the current by analyzing the converted voltage Wherein the insect counting method comprises the steps of: A computer-readable recording medium recording a program for executing the method of claim 8 or 9.

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