KR20060118805A - The mosquito extirpation system which uses a multiplex frequency - Google Patents

Abstract

A mosquito extirpation system using method for exchanging and outputting multiple frequency is provided to generate the frequency in a multi-stepped shape and convert the generated frequency to an optic signal so as to generate the electronic waves of a desired multi-frequency and effectively extirpate mosquito. The mosquito extirpation system using method for exchanging and outputting multiple frequency comprises: a pulse generator(10), generating a square pulse wave at a determined time interval; a step-wave generator(20), inputted with the generated square pulse wave and outputting 16 step waves with 16 stepwise increasing voltages; a light emitting diode(40), emitting the light with a brightness corresponding to the step wave voltage; an adder(30), increasing the voltage by a necessary degree for the light emitting diode to generate an optic signal; a light-resistance converter(50), convert the light generated by the light emitting diode(40) to a resistance value; a frequency converter(60); and a sound generator(70).

Description

Mosquito extirpation system which uses a multiplex frequency}

1 is a block diagram showing the configuration of a mosquito repellent apparatus using the present invention multi-frequency switching output method.

2 and 3 is a circuit diagram showing a detailed configuration embodiment in the present invention.

4 is an output waveform diagram of a pulse generator in the present invention.

5 is an output waveform diagram of a stepped wave generator in the present invention.

6 is an output waveform diagram of an adder in the present invention.

7 is an output waveform diagram of a frequency converter in the present invention.

8 is a circuit diagram showing the configuration of the indoor mosquito control device in the present invention.

The present invention relates to a mosquito repellent apparatus using a multi-frequency switching output method to alternately generate various types of electromagnetic waves from the sound wave to the ultrasonic region to combat various kinds of mosquitoes.

Mosquitoes are insects that ingest the blood of humans or animals to ingest nutrients. In some cases, mosquitoes can be very dangerous.

As a result, people are introducing various products such as mosquito nets as well as passive methods such as mosquito nets to combat mosquitoes, but they do not show many effects and may have an adverse effect on the human body.

In recent years, a technology for preventing the access of mosquitoes while harmless to the human body using electromagnetic waves has been developed and commercialized.

In general, it is known that female mosquitoes suck blood for the purpose of nutrient intake during the spawning season.

The female mosquitoes that keep their semen in one mating time have the property of avoiding male mosquitoes that run into barracks because they no longer need mating.

Through various studies, cancer mosquitoes hate the sound of dragonflies, winged wings of males, and metallic bouncing sounds, and developed a mosquito repellent device using its sound. (Note: The range of sound waves arising from the movement of the wing of a male mosquito is usually 400㎐-20㎑)

Most of the mosquito repellent devices use ultrasonic waves in a frequency band that humans do not recognize, and ultrasonic waves of 25,000 kHz to 60,000 kHz of ultrasonic waves recognized by humans.

However, these mosquito repellent devices are composed of an oscillation circuit for emitting electromagnetic waves having a single frequency or at most 5 to 7 frequency bands, and the reliability of the effect is insufficient, especially in places of indoor or outdoor use. As a result, the efficiency is poor.

In the present invention, a mosquito repellent device that alternately generates an electromagnetic wave having multiple frequency bands is to be constructed, generating a frequency in the form of a multi-step staircase, converting the generated frequency into an optical signal, and converting the generated frequency into an optical signal. It is to provide an effective mosquito repellent device by being able to generate a plurality of electromagnetic waves of the desired frequency from the ultrasound to the ultrasound.

In addition, the present invention is to maximize the efficiency by alternately generating the electromagnetic waves of sound waves and ultrasonic waves through the speaker.

In addition, to provide a suitable mosquito control device according to the location (indoor / outdoor) used.

The present invention provides a pulse generating means for generating a square pulse wave at a predetermined time interval, stepped wave generating means for generating a predetermined set stepped rising voltage in accordance with a pulse generated from the pulse generating means, and a stepped wave generating means. An adder for increasing the step voltage value to an operating voltage necessary for converting the optical signal; an optical signal converting means for generating an optical signal having a brightness according to the increased step voltage value through the adder; Light / resist conversion means for converting light into a predetermined resistance value, frequency conversion means for outputting a predetermined frequency according to the resistance value converted through the light / resistance conversion means, and a frequency output from the frequency conversion means. And sound generating means for outputting sound to generate electromagnetic waves for mosquito repelling. All.

Referring to the embodiment shown in the accompanying drawings of the present invention having such a feature will be described in detail the configuration and operation process as follows.

Pulse generator 10 for generating square pulse waves at predetermined time intervals, and stepped wave generator 20 for outputting 16 stepped waves having 16 stepped rising voltages by receiving pulse waves generated from the pulse generator. ), An adder 30 for increasing the voltage required to generate an optical signal of the light generator 40, and light generation indicating the brightness of light according to the stepped wave voltage by receiving 16 stepped wave voltages from the adder 30. The unit 40, the light / resistance converter 50 for converting light generated by the light generator 40 into a resistance value, and the frequency conversion for generating a frequency according to the resistance value set by the light / resistance converter 50. And a sound generator 70 for outputting a sound corresponding to a frequency output from the frequency converter 60 to generate an electromagnetic wave having a frequency of 16 steps.

2 and 3 illustrate an embodiment of a circuit configuration of the mosquito repellent device using the multi-frequency of the present invention.

 The pulse generator 10 includes a timer IC 10A that generates a pulse to the output Q according to a period set by the resistors R1 and R2 and the capacitor C1.

The timer IC 10A is configured of NE555, and the period T obtained by the resistors R1 and R2 and the capacitor C can be expressed by Equation 1 below.

T = 0.693C (R1 + R2) [sec]

This period is set to the minimum time interval required for mosquitoes to detect, and at least 3 seconds to 6 seconds.

The stepped wave generator 20 is configured to generate a stepped wave having 16 steps using the pulse generated from the pulse generator 10 as an input pulse.

The stepped wave generator 20 includes a counter IC 20A for outputting a stepped wave that is increased in accordance with a predetermined voltage whenever the pulse output from the pulse generator 10 changes.

The counter IC 20A is configured such that a stepped wave having a total of 16 steps is generated by dividing up to 3.4V up to 16 times each time a pulse is input and repeating again when it comes down to OV again.

The adder 30 includes operational amplifiers 30A, 30B, and 30C for amplifying the stepped waves output from the stepped wave generator 20.

The operational amplifiers 30A, 30B, and 30C are composed of LM324 ICs.

By using the operational amplifiers (30A, 30B, 30C) to increase the step voltage value of 16 stages, amplifies the output of 0.294V ~ 3.41V from the step wave to 1.34V ~ 4.48V,

The adder 30 increases the voltage value of the first step by the minimum voltage at which the light generator 40 can operate.

The light generator 40 operates by using the emitter voltages of the transistors Q1 and Q1 operated as the base input using the 16 stepped wave voltages amplified from the adder 30 as the base inputs, and thus the light emitting diodes (LED1 and LED2). Is a transistor (Q2) for controlling the operation.

In this way, the transistors Q1 and Q2 are configured as a Darlington connection, and the light emitting diodes LED1 and LED2 are configured such that the intensity of light gradually changes according to the 16 stepped wave voltages.

At this time, the light emitting diodes (LED1, LED2) controlled according to the flash is composed of a high-brightness LED having a wide width.

The photo / resistance converter 50 is composed of a photo resistor CdS cell whose resistance value changes depending on the amount of light.

The frequency converter 60 amplifies the frequency output by the timer IC 60A and the timer IC 60A to change the resistance value changed by the photo / resistive converter 50 into a frequency. It comprises a 60B.

 The timer IC 60A is composed of a general timer IC NE555 for pulse output.

At this time, the frequency range generated by the frequency converter 60 is in the range of about 100 Hz to about 30 Hz.

The sound generator 70 is configured as a speaker driving circuit for generating sound according to the frequency output from the frequency converter 60 in this way,

Transistors Q3, Q4 and Q5 for multi-stage amplification of the frequency inputted from the frequency converter 60, and a speaker 70A for negatively outputting the frequencies amplified by the transistors Q3, Q4 and Q5. It is configured by.

Amplification circuits Q3, Q4, and Q5 are configured by three-stage Darlington connection considering current amplification (in some cases, two stages of Q3 and Q4). It is configured to increase the reach of electromagnetic waves.

And a constant voltage unit 80 for stabilizing the operating power of each unit in order to prevent the operating power from becoming unstable due to the change in load.

The constant voltage unit 80 is composed of a constant voltage IC 80A.

Unexplained R3 to R25 are resistors, and C2 to C10 are capacitors, which are passive elements required to design the circuitry of each part.

The mosquito repellent apparatus using the multi-frequency according to the present invention generates 16 step wave voltages, generates light that varies with the light intensity according to the generated voltage, and converts the generated light back into a predetermined frequency to multi-frequency. It characterized in that to generate an electromagnetic wave having a description of the operation process as follows.

In the timer IC 10A of the pulse generator 10, a period set by the resistors R1 and R2 and the capacitor C1, that is, at intervals of about 3 seconds to 6 seconds suitable for detecting a mosquito, is shown in FIG. It generates continuous square wave pulses such as

4 shows a square wave pulse output from the pulse generator 10.

The pulse generated in this way acts as an input pulse of the counter IC 20A of the stepped wave generator 20, and as shown in FIG. 5 having 16 rising voltages for such an input pulse in the counter IC 20A. , 16 staircase waves are output.

5 is a view showing a waveform of the step wave output from the step wave generation unit 20.

As described above, the stepped wave output through the counter IC 20A of the stepped wave generator 20 is input to the adder 30, and the voltage of the stepped wave having 16 steps is increased by the adder 30.

6 is a diagram showing waveforms output from the adder 30.

The stepped wave voltage raised by the adder 30 by a predetermined voltage is input to the light generator 40 to generate light.

The stepped wave voltage output from the adder 30 is inputted to the base of the transistor Q1, whereby the transistor Q1 is operated, and the two-stage amplification operation is performed by the transistor Q2 connected to the transistor Q1. At the same time, the light emitting diodes LED1 and LED2 are driven to generate light. Here, the reason why the transistors Q1 and Q2 are connected to Darlington is to amplify a large current to maximize the width of the light emitting diodes LED1 and LED2 to improve the frequency sensitivity.

At this time, since the light intensity generated by the light emitting diodes (LED1, LED2) is changed according to the input stepped wave, as shown in Figure 6 gradually becomes brighter according to the input stepped wave voltage, reverts to the original voltage, and the process of brightening again Will be repeated.

When the light is generated from the light emitting diodes (LED1, LED2) in this way, the light / resistance converter 50 sets the resistance value that changes according to the amount of light.

As described above, the photo / resistance converter 50 is composed of a light quantity sensor CdS cell, and the resistance value of the CdS cell changes according to the amount of light received.

The generated light is received at opposing positions of the light emitting diodes LED1 and LED2 to set a resistance value according to the amount of light.

In the CdS cell, the resistance value decreases as the amount of light increases, and the resistance value increases as the amount of light decreases.

Accordingly, the frequency converter 60 may convert and output a resistance value continuously changing according to the amount of light in the light / resistance converter 50 into a frequency.

7 shows a waveform output from the frequency converter 60.

The timer IC 60A constituted by the frequency generating means of the frequency converter 60 generates a frequency according to the resistance value of the CdS cell, amplifies it through the operational amplifier 60B, and outputs the frequency to the sound generator 70. .

The sound generator 70 includes a speaker 70A as a circuit for generating a predetermined sound according to the input frequency.

As described above, the voltage having the frequency output from the frequency converter 60 is amplified by three stages through the transistors Q3, Q4, and Q5 to generate sound having a frequency of 16 steps through the speaker 70A.

Therefore, it is to generate the electromagnetic wave of 16 multi-frequency, the electromagnetic wave from the sound wave to the ultrasonic region is generated.

8 illustrates a circuit configuration configured for indoor use in the embodiment of the present invention.

The embodiment of the present invention described above is similar to the embodiment shown in FIG. 3 for outdoor use, and includes a light generator 40 ', a light / resistance converter 50, a frequency converter 60', and a sound generator 70 '. ), Including

When the indoor configuration is used, the amplification process of the frequency generated by the frequency converter 60 'is not performed, that is, the operational amplifier 60B is not configured.

In addition, in the sound generator 70 ', the variable resistor VR1 is configured to adjust the three-stage amplification factor, so that the volume of the speaker 70A is adjusted.

According to this, low frequency (low frequency) can also be generated.

Thus, it is possible to configure a mosquito repellent device suitable for indoor / outdoor.

As described above, the present invention has an operation process of generating step waves with multiple voltages, photoelectric conversion, resistance conversion, frequency conversion, and electromagnetic wave generation, and generates 16 multiple frequency electromagnetic waves, thereby covering sound waves and ultrasonic waves. The alternating electromagnetic waves are effective in combating various mosquitoes.

Designed for indoor and outdoor use, high efficiency.

In addition, since high-brightness LEDs are used, effects that can be used even as indoor auxiliary light can be obtained.

Claims (11)

Pulse generating means for generating a square pulse wave at a predetermined time interval, stepped wave generating means for receiving a pulse wave generated from the pulse generating part and outputting a predetermined number of stepped waves having a stepped rising voltage, An adder for increasing the voltage required to generate an optical signal, light generating means for generating an optical signal having a brightness of light according to the stepped wave voltage by receiving a stepped wave voltage having an increased voltage value input from the adder; The light / resistance conversion means for converting the light generated by the resistance to the resistance value, the frequency conversion means for generating a frequency according to the resistance value set from the light / resistance conversion means, and outputs the sound according to the frequency output from the frequency conversion means Multi-frequency switching output method characterized in that it comprises a sound generating means for generating an electromagnetic wave having a frequency of multiple stages Mosquito control device. 2. The apparatus of claim 1, wherein the pulse generating means comprises a timer IC having a pulse generating period set in consideration of a necessary time detected by the mosquito. The mosquito control device using a multi-frequency switching output method according to claim 1, wherein the stepped wave is generated by 16 steps. The apparatus of claim 1, wherein the adder comprises operational amplifiers 30A, 30B, and 30C for amplifying the stepped waves output from the stepped wave generating means. . The mosquito using a multi-frequency switching output method according to claim 1, wherein the light generating means comprises high brightness light emitting diodes (LED1, LED2) such that the intensity of light gradually changes according to the stepped wave voltage in step 16. Eradication device. The device of claim 1, wherein the light / resistance converting means comprises a CdS cell whose resistance value is changed according to the amount of light. The apparatus of claim 1, wherein the frequency range generated by the frequency converting means is set within a range of 100 Hz to 30 Hz. The apparatus of claim 1, wherein the sound generating means comprises a speaker driving circuit for generating sound according to the frequency output from the frequency converting means. The amplifying circuit (Q3, Q4, Q5) according to claim 1, comprising transistors (Q3, Q4, Q5) for multistage amplification of the frequency inputted from the frequency converting means. It is configured to include, and the mosquito control device using a multi-frequency switching output method characterized in that the output of the speaker is set to the maximum to increase the reach of the electromagnetic wave. 10. The mosquito control device using a multi-frequency switching output method according to claim 1 or 9, comprising a loudness adjusting means for adjusting the loudness generated by adjusting the current amplification factor. The mosquito control device using a multiple frequency switching output method according to claim 1, further comprising a constant voltage supply means for stabilizing the operating power of each part in order to prevent the operating power from becoming unstable due to a change in load. .

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