KR100985802B1 - Circuit for anti-insect device - Google Patents

Abstract

The present invention relates to a circuit for insect repellent, and the technical problem to be solved is to provide a insect repellent circuit at the same time to insect trapping insects. To this end, after attracting an insect with an ultraviolet lamp, a circuit for a insect repeller comprising a heater electrically connected to an anode terminal and a ground terminal of DC voltage and supplied with electric power to repel the attracted insect, Negative element disposed; A switching element electrically connected to the large current path of the heater; And a voltage comparator having a reference voltage terminal to which a reference voltage is input, a comparison voltage terminal electrically connected to the sub-characteristic element, and an output terminal electrically connected to the switching element. The voltage comparator outputs a signal to the output terminal when the comparison voltage does not exceed the reference voltage, and maintains the switching element turned on to supply current to the heater. When the reference voltage is exceeded outputs a signal to the output terminal to turn off the switching element so that the current supplied to the heater is disconnected, so that the heater is periodically heated within a predetermined temperature range Start the circuit.

Insect Repellent, Insect Extract, Heater, Ultraviolet Lamp, Negative Element

Description

CIRCUIT FOR ANTI-INSECT DEVICE}

The present invention relates to a circuit for insect repellents, and more particularly, to a circuit for insect repellents that attracts insects with a heater after attracting insects with an ultraviolet lamp.

In the summer seasons, insects such as mosquitoes, moths and flies are increasing, and these insects are active in the evenings. Therefore, restaurants and events are provided with insect repellent insects such as flies and mosquitoes.

These insect repellents are mainly used to attract insects using a UV lamp and then to heat them with a high temperature heater. After the insects are caught, the insects accumulate in the inner case of the insect repeller.

However, when the insects are not cleared after a certain time, the insects will be decayed, and the decaying smell will cause a decay smell. This causes odors around the insect repellents installed in food and event venues.

In addition, after cleaning the inside of the insect repeller, the insects to remove the insects caused by the gathering of other insects around the insects to create a dirty environment.

The technical problem of the present invention is to provide a insect repellent circuit at the same time to insect trapping insects are prevented.

The insect repeller circuit of the present invention for achieving the above technical fruit is a heater that is electrically connected to the anode and the ground terminal of the DC voltage and supplied with electric power to attract the insect to the ultraviolet lamp, and to attract the attracted insect. In the circuit for the insect repellent including,

A sub-element disposed around the heater; A switching element electrically connected to the large current path of the heater; And a voltage comparator having a reference voltage terminal to which a reference voltage is input, a comparison voltage terminal electrically connected to the sub-characteristic element, and an output terminal electrically connected to the switching element. It is formed to include more

The voltage comparator outputs a signal to the output terminal when the comparison voltage does not exceed the reference voltage, and maintains the switching element turned on to supply current to the heater, and when the comparison voltage exceeds the reference voltage. By outputting a signal to the output terminal to turn off the switching element so that the current supplied to the heater is disconnected, it characterized in that the heater is periodically heated within a certain temperature range.

Here, the switching element is formed of an incremental MOSFET having a gate terminal electrically connected to the output terminal, a drain terminal electrically connected to the heater, and a source terminal electrically connected to the ground terminal. A positive pole of direct current voltage can be applied. In this case, the increased MOSFET may be formed in an N-channel type.

In addition, the heater may be maintained in the heating temperature range of 100 ℃ to 160 ℃ by the turn on and turn off operation of the switching element.

In addition, the circuit for the repeller includes a first resistor electrically connected between the reference voltage terminal and the positive terminal of the DC voltage; A second resistor electrically connected between the comparison voltage terminal and the positive terminal of the DC voltage; A third resistor electrically connected between the first resistor and a ground terminal of the DC voltage; And a fourth resistor electrically connected between the second resistor and the ground terminal of the DC voltage. The negative electrode may be electrically connected between the fourth resistor and the ground terminal of the DC voltage.

The present invention traps the insects attracted by the ultraviolet lamp with a heater, and by drying the internal essence of the insect by maintaining the temperature of the heater at an appropriate temperature, there is an effect of preventing the decay of the insect.

The above effects have been briefly described so as not to obscure the gist of the present invention and will be described in more detail in the following detailed description.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, the same reference numerals are used for the same components, and overlapping descriptions of the same components will not be described. In addition, components of equivalent or similar concepts will be described using the same names.

Hereinafter will be described the configuration, coupling relationship and role of the insect recharger circuit according to an embodiment of the present invention.

Referring to FIG. 1, FIG. 1 is a block diagram of a circuit for a repeller according to an embodiment of the present invention.

As shown in FIG. 1, the repeller circuit 100 according to an embodiment of the present invention includes an ultraviolet lamp 110, a heater 120, a sub-characteristic element 130, a switching element 140, and a voltage comparator. 150 is formed. In addition, the repeller circuit 100 may further include a light emitting diode 160. In addition, the repeller circuit 100 may further include a first resistor 171, a second resistor 172, a third resistor 173, and a fourth resistor 174. The insect repeller circuit 100 according to the present embodiment is driven by receiving a DC power of approximately + 24V, and is shown as + 24V in the portion applied to the positive pole of the DC power in the drawing, and the ground terminal of the DC power is common to the ground symbol. Is applied.

The ultraviolet lamp 110 is disposed around the heater 120. The ultraviolet lamp 110 receives the power to generate ultraviolet rays to attract insects.

One end of the heater 120 is electrically connected to the positive end of the DC power supply, and the other end is electrically connected to the switching element 140. The heater 120 is electrically connected to the ground terminal when the switching element 140 is turned on to receive DC power and is heated by DC power. The heater 120 is heated when the switching element 140 is turned on to release heat, the released heat serves to trap insects. In addition, the heater 120 serves to dry the inner essence of the body of the insect so that insects do not decay and cause rotting odor after trapping the insect.

One end of the negative temperature coefficient (NTC) 130 is electrically connected to the positive terminal of the DC power supply and the comparison voltage terminal 152 of the voltage comparator 150, and the other end is electrically connected to the ground terminal. . The sub-element 130 is disposed around the heater 120 to change the internal resistance according to the temperature of the heater 120. The change in the internal resistance of the sub-element 130 is changed such that the internal resistance value approaches 0 ohm as the temperature of the heater 120 increases, so that the voltage value applied to the comparison voltage terminal 152 is applied to the reference voltage terminal 151. It serves to lower than the applied voltage value.

The switching element 140 may be formed of a junction transistor (BJT) or a field effect transistor (FET). The switching element in this embodiment will be described as an incremental MOSFET having a gate end G, a source end S, and a drain end D. FIG. Here, the gate terminal G is electrically connected to the output terminal 153 of the voltage comparator 150. In addition, the source terminal S is electrically connected to the ground terminal of the DC voltage. In addition, the drain terminal D is electrically connected to one end of the heater 120. The switching element 140 is set to a driving voltage of approximately + 24V between the source terminal S and the drain terminal D to allow current to flow from the drain terminal D to the source terminal S. FIG. The switching element 140 is turned on when a signal is input to the gate terminal (G) to heat the heater 120 by flowing a current to the heater 120, and cut off the current flowing to the heater 120 when turned off It serves to prevent heating of the heater 120.

Here, the positive terminal of the DC voltage is electrically connected to the gate terminal G of the switching element 140 so that approximately +24 V is applied. That is, since the voltage difference between the source terminal S and the source terminal S is approximately + 24V, and the voltage of the anode is applied, the gate terminal G is turned on when the power of the entire blower circuit 100 is applied, and thus the heater 120 is turned on. By heating the heater 120 serves to continuously supply the current to prevent the decay of the insect by drying the essence of the insect body attracted by the ultraviolet lamp 110. In this case, the switching element 140 is preferably formed in the N-channel type of the increased MOSFET in order to maintain the turn-on operation immediately after the DC power is applied to the entire blower circuit 100, the turn-on operation. .

The voltage comparator 150 includes a reference voltage terminal 151, a comparison voltage terminal 152, and an output terminal 153. The reference voltage terminal 151 is electrically connected to the positive terminal of the DC power supply so that the reference voltage is applied. In addition, the first resistor 171 and the third resistor 173 are electrically connected to the reference voltage terminal 151. The comparison voltage terminal 152 is electrically connected to the positive terminal of the DC power supply. In addition, the comparison voltage terminal 152 is electrically connected to the second resistor 172 and the fourth resistor 174, and is also electrically connected to the negative characteristic element 130 through the fourth resistor 174. The output terminal 153 is electrically connected to the gate terminal G of the switching element 140 and electrically connected to the positive terminal of the DC voltage.

Here, when the comparison voltage does not exceed the reference voltage, the voltage comparator 150 outputs +24 V to the output terminal 153 to turn on the switching element 140 to continuously supply current to the heater 120. Keep it. In addition, when the comparison voltage exceeds the reference voltage, the voltage comparator 150 outputs a voltage of the output terminal 153 to -24V to turn off the switching element 140 to disconnect the current supplied to the heater 120. Maintain the state. Therefore, the voltage comparator 150 maintains the heater 120 at an appropriate temperature by repeating the turn-on and turn-off operations of the switching element 140. In this case, the heater 120 maintains the temperature of approximately 140 ℃ to trap the insects, and to dry the inner essence of the entrapped insect body to prevent the insects from rotting. In most insects, after about one minute at about 75 ℃, the fluid inside the body dries out to die.

In addition, the repeller circuit 100 may further include a first resistor 171, a second resistor 172, a third resistor 173, and a fourth resistor 174. The first resistor 171 is electrically connected between the reference voltage terminal 151 and the positive terminal of the DC voltage. The second resistor 172 is electrically connected between the comparison voltage terminal 152 and the positive terminal of the DC voltage. The third resistor 173 is electrically connected between the first resistor 171 and the ground terminal of the DC voltage. The fourth resistor 174 is electrically connected between the second resistor 172 and the ground terminal of the DC voltage. In this case, the negative characteristic element 130 is electrically connected between the fourth resistor 174 and the ground terminal. Here, the first resistor 171 and the second resistor 172 are formed with the same resistance value. In addition, the third resistor 173 and the fourth resistor 174 have approximately the same resistance value. The first resistor 171, the second resistor 172, the third resistor 173, and the fourth resistor 174 may be configured in plural to match a relative set value of the reference voltage and the comparison voltage. . When the temperature of the heater 120 is less than about 140 ° C., the negative characteristic element 130 connected to these resistors has an internal resistance value so that the comparison voltage does not exceed the reference voltage. Near zero (0) Ohm so that the comparison voltage exceeds the reference voltage serves to change the voltage value output to the output terminal 153 of the voltage comparator 150. Here, another resistor may be further connected to the output terminal 153 of the voltage comparator 150 in order to adjust a set voltage applied to the gate terminal G. FIG.

On the other hand, the repeller circuit 100 is further formed by including a light emitting diode (160). The light emitting diode 160 has an anode end electrically connected to the gate end G. Here, the anode end is electrically connected to the anode end of the DC voltage. In addition, the cathode terminal of the light emitting diode 160 is electrically connected to the ground terminal of the DC voltage. The light emitting diode 160 emits light when the switching element 140 is turned on, and the light for turning off the switching element 140 is turned off to visually turn on and turn off the switching element 140. As shown, it serves to visually check whether the heater 120 is heated. Therefore, a user using the insect repeller circuit 100 can know whether the heater 120 is normally operated through the light emitting diode 160.

Hereinafter, the operation and effects of the operation of the insect repeller circuit 100 according to an embodiment of the present invention will be described.

First, when the power is applied to the ultraviolet lamp 110 to drive, the insect is attracted by the ultraviolet lamp 110. At this time, when a DC power of approximately + 24V is applied to the circuit 100 for the insect repeller, the output terminal 153 of the voltage comparator 150 outputs a voltage of + 24V to the gate terminal G of the switching element 140. The switching element 140 is turned on. Thus, the heater 120 is heated, and the heated heater 120 starts to insect and dry the internal essence of the insect body after insect insects are finished. In this case, the voltage comparator 150 maintains the turn-on state of the switching element 140 because the comparison voltage does not exceed the reference voltage, and the heater 120 is continuously heated. Then, in the sub-element 130 disposed around the heater 120, the internal resistance is continuously lowered by the heat of the heater 120, the sub-element 130 is disposed around the sub-element 130 Of the voltage comparator 150 based on the resistance values of the first resistor 171, the second resistor 172, the third resistor 173, and the fourth resistor 174 and the resistance change of the negative characteristic element 130. The comparison voltage is set to exceed the reference voltage. Then, the voltage comparator 150 outputs a voltage of -24 V at the output terminal 153, and a reference potential of approximately 0 V is formed at the gate terminal G of the switching element 140. Then, the switching element 140 is turned off, and the current flowing to the heater 120 is cut off. Therefore, the heater 120 stops heating because no current is supplied, and the temperature is gradually dropped while maintaining the temperature around 140 ° C. In this case, as the temperature of the heater 120 decreases, the resistance of the negative characteristic element 130 gradually increases, and the resistance values of the negative characteristic element 130 are the first resistance 171 and the second resistance 172. When the comparison voltage is lowered below the reference voltage according to the resistance setting value of the third resistor 173 and the fourth resistor 174, a voltage of approximately +24 V is output to the output terminal 153 of the voltage comparator 150 for switching. The device 140 is turned on. Therefore, the heater 120 is supplied with a current by the turn-on operation of the switching element 140, and is heated again until it reaches 140 ℃. Thereafter, the sub-element 130 continuously changes the resistance value to repeat the turn-on operation and the turn-off operation of the switching element 140 to maintain the temperature of the heater 120 at about 140 ° C. Although the temperature of the heater 120 is illustrated as 140 ° C. in the present embodiment, the temperature of the heater 120 may be formed at 100 ° C. to 160 ° C. in order to trap insects and to prevent rot. Here, if the temperature of the heater 120 is less than 100 ℃ insect insects are not easily made to escape insects, if larger than 160 ℃ insect insects are easily made, but the likelihood of fire or burns due to high heat Since it may cause human damage, the temperature of the heater 120 is preferably formed to 100 ℃ to 160 ℃.

As described above, the insect repeller circuit 100 according to an embodiment of the present invention can repel insects such as flies and mosquitoes by heating the heater 120, and at the same time as to trap insects, heater 120 The temperature of the insect is maintained at an appropriate temperature to dry the internal fluid of the insect body to prevent the decay of the insects to be trapped. In addition, the heater 120 maintains the heating temperature at an appropriate temperature to prevent overheating of the heater.

1 is a block diagram of a circuit for a repeller according to an embodiment of the present invention.

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

110; Lamp 120; heater

130; Negative element 140; Switching element

150; Voltage comparator 160; Light emitting diode

171; First resistance 172; 2nd resistance

173; Third resistor 174; Fourth resistance

Claims (5)

In the insect repeller circuit comprising a heater that is heated and supplied with electric power to the anode and the ground terminal of the DC voltage in order to attract the insect attracted by the ultraviolet lamp, A sub-element disposed around the heater; A switching element electrically connected to the large current path of the heater; And A voltage comparator having a reference voltage terminal to which a reference voltage is input, a comparison voltage terminal electrically connected to the sub-characteristic element, and an output terminal electrically connected to the switching element; It is formed to include more The voltage comparator outputs a signal to the output terminal when the comparison voltage does not exceed the reference voltage, and maintains the switching element turned on to supply current to the heater, and when the comparison voltage exceeds the reference voltage. And a signal output to the output terminal to turn off the switching element so that the current supplied to the heater is disconnected so that the heater is periodically heated within a predetermined temperature range. The method of claim 1, The switching element is formed of an incremental MOSFET having a gate terminal electrically connected to the output terminal, a drain terminal electrically connected to the heater, and a source terminal electrically connected to the ground terminal. The gate terminal is a circuit for a repeller, characterized in that the anode of the DC voltage is applied. The method of claim 2, The increasing MOSFET is formed of an N-channel circuit for the insect repeller circuit. The method of claim 1, The heater circuit of the repeller, characterized in that the heating temperature is maintained within the range of 100 ℃ to 160 ℃ by the turn on and turn off operation of the switching element. The method of claim 1, A first resistor electrically connected between the reference voltage terminal and the positive terminal of the DC voltage; A second resistor electrically connected between the comparison voltage terminal and the positive terminal of the DC voltage; A third resistor electrically connected between the first resistor and a ground terminal of the DC voltage; And A fourth resistor electrically connected between the second resistor and a ground terminal of the DC voltage; It is formed to include more And the negative characteristic element is electrically connected between the fourth resistor and a ground terminal of a DC voltage.

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