KR19990040672A - Automatic control method of inverter stand with pest control function - Google Patents

Abstract

The present invention relates to a method for automatically controlling an inverter stand having a pest control function, and in view of the fact that the conventional inverter stand adjusts only the illuminance of the lamp L by the amount of light reflected from the floor, the present invention provides a main power supply. When supplied, check the key input to turn on the lamp (L), when the lamp is turned on by the initial oscillation frequency (A), the lamp (L) is lit, the ambient light sensor (800) detects the ambient light and Therefore, the oscillation frequency (B) corresponding to the ambient illuminance is read out from the data storage unit 700 and set to contrast the oscillation frequency (A) (B). The process of adjusting the illuminance of the lamp L by increasing or decreasing the oscillation frequency of the frequency converter 400 according to the difference value, and generating ultrasonic waves in various frequency ranges in conjunction with the increase or decrease of the oscillation frequency A or B. By performing The oscillation frequency of the frequency converter is increased or decreased to correspond to the ambient illuminance detected by the lamp to adjust the illuminance of the lamp and generate ultrasonic waves in various frequency ranges in conjunction with the oscillation frequency. It can be.

Description

Automatic control method of inverter stand with pest control function.

The present invention relates to an automatic control method of an inverter stand having a pest control function, and more particularly, to adjust the illuminance of the lamp to correspond to the brightness of the surroundings detected by the illuminance sensor while simultaneously interlocking with the pests such as mosquitoes. The present invention relates to an automatic control method of an inverter stand having a pest control function to variably radiate ultrasonic waves.

1 and 2, a general inverter stand includes a bridge diode, a zener diode, a capacitor, and the like, and provides a constant voltage unit 101 for supplying a constant voltage to a set. And a key input unit 102 including keys for setting the operation mode of the set, including a touch sensor installed on a support of the inverter stand, and installed at an end of the lamp shade 110 having an illumination sensor. And the frequency sensing data for adjusting the illuminance of the lamp L by the illuminance detecting unit 109 for detecting illuminance (light quantity) on the bottom surface and the output of the illuminance detecting unit 109 and a key input. It consists of a microprocessor 103, an oscillation IC and a plurality of capacitors and resistors for converting the oscillation frequency thereof, and receives a ramp configuration by receiving the frequency conversion data output from the microprocessor 103. The frequency converter 104 oscillates the oscillation frequencies of the different bands supplied to the unit 104, and the field effect transistor which is switched by receiving the oscillation frequency oscillated by the frequency converter 104 and the lamp in conjunction with the ramp. And a lamp driver 105 having a transformer or the like for adjusting the level of the operating power supplied to (L), and a display unit 106 for displaying the operating state of the set.

When the main power is supplied by the operation of the touch sensor of the key input unit 102, the inverter stand oscillates by determining the time constant of the frequency converter 104 having a capacitor and a resistance by the frequency conversion data output from the microprocessor 103. The IC uses an oscillation frequency of approximately 50 KHz to 90 KHz and applies it to the primary side of the transformer of the lamp driver 105. Then, the plurality of field effect transistors are alternately operated by the voltage generated on the secondary side of the transformer to adjust the operating power supplied to the lamp L. At this time, the lighting of the lamp L is performed while the power supplied from the constant voltage unit 101 is discharged through the transformer formed in the front of the lamp L and the self resistance of the lamp and a loop formed by the plurality of field effect transistors.

Subsequently, when the illuminance of the bottom surface L sensed by the illuminance sensor 109 and the illuminance of the lamp L are converted, the visibility of the frequency converter 104 is adjusted to adjust the brightness of the light generated by the lamp L. FIG. The number is converted so that the oscillation IC oscillates the corresponding oscillation frequency. Then, the discharge amount of the lamp driver 105 is adjusted to adjust the illuminance of the lamp (L). Here, as the oscillation frequency supplied from the frequency converter 104 to the lamp driver 105 increases, the current supplied to the lamp L decreases, so that the light of the lamp L becomes weak.

Since most of the inverter stands are turned on in a dark space or at night, the lighting switch, that is, the key is composed of a touch sensor so that the lamp of the inverter stand can be smoothly lit. The touch sensor is activated when the human body approaches or touches while the main power is input. The current operating state of the inverter stand is then switched. That is, when the touch sensor is operated by the human body while the lamp L of the inverter stand is turned off, the lamp L is turned on, whereas when the touch sensor is operated by the human body while the lamp L of the inverter stand is lit, the lamp ( Turn off L). In addition, the microprocessor 103 may drive a buzzer (generally using a piezo buzzer) that is not shown when the touch sensor is operated or a key is pressed to check the operation state of the touch sensor or another key input. Output buzzer sound. Accordingly, the operation state of the touch sensor or the key input state of the key input unit 102 can be checked.

Since the inverter stand is installed so that the illuminance detecting part faces downward, the illuminance of the lamp L is adjusted only by the amount of light reflected on the bottom surface. In other words, in addition to the defects that do not adequately cope with the brightness of the surrounding, there is a defect that does not inhibit the gathering of pests such as mosquitoes into the lamp.

The present invention has been devised to solve such a defect, install an illumination sensor to detect the brightness of the lamp shade above, and adjusts the brightness of the lamp corresponding to the ambient brightness detected by the illumination sensor and linked to it It is an object of the present invention to provide an automatic control method of the inverter stand having a pest control function that can generate the ultrasonic variable variably to combat pests.

The present invention for achieving this object is the first step of confirming the key input for turning on the lamp when the main power is supplied, and the second step of turning on the lamp by the initial oscillation frequency (A) at the time of illumination, illuminance detection means The third step of detecting the ambient illumination by reading the oscillation frequency (B) corresponding to the ambient illumination from the data storage means and setting it; and the fourth step of comparing the oscillation frequency (A) (B); The fifth step of adjusting the illuminance of the lamp by increasing or decreasing the oscillation frequency of the frequency conversion means in accordance with the difference value of the oscillation frequency (A) (B), and continuously in conjunction with the increase and decrease of the oscillation frequency (A) (B) A sixth step of generating an ultrasonic wave having a frequency is performed.

1 is a block diagram showing the configuration of a typical inverter stand,

2 is a perspective view of a typical inverter stand,

3 is a block diagram showing the configuration of an inverter stand according to the present invention;

4 is a perspective view of an inverter stand according to the present invention;

5 is a table showing a change state of the oscillation frequency according to the ambient brightness in the present invention,

6 is a flowchart illustrating an operating state of the inverter stand according to the present invention.

Explanation of symbols on the main parts of the drawings

100: constant voltage unit 200: key input unit

300: microprocessor 400: frequency converter

500: lamp driving unit 600: display unit

700: data storage 800: illuminance sensor

900: ultrasonic generator

3 and 4, the configuration according to the embodiment of the present invention, a key input unit consisting of a variety of keys, including a constant voltage unit 100 for supplying a constant voltage to the set, and a touch sensor for setting the operation mode of the set 200, the upper portion of the lampshade is installed upward and the illumination sensor (800) for detecting the ambient light, and the inverter while adjusting the oscillation frequency of the frequency converter 400 according to the key input and ambient light A microprocessor 300 for controlling the overall operation of the stand, a frequency converter 400 for oscillating an oscillation frequency supplied to the lamp driver 400 by receiving the frequency conversion data output from the microprocessor 300; Lamp driving unit 500 for adjusting the operating power supplied to the lamp (L) by receiving the oscillation frequency output from the frequency converter 400, and the oscillation frequency and the corresponding to the ambient illuminance Consists in the processor 300 to process various kinds of data is the data storage unit 700 which stores a display unit 600 for displaying an operating state of the inverter type of fluorescent lamp, including the microprocessor 300.

6 is a flowchart illustrating an operating state of the inverter stand according to the present invention, in which a first step of confirming a key input for lighting a lamp L when the main power is supplied, and at the initial oscillation frequency A when the lamp is turned on. A second step of turning on the lamp L, a third step of detecting the ambient light by the illumination sensor 800, and an oscillation frequency B corresponding to the ambient light. The oscillation frequency of the frequency converter 400 according to the third step of reading from and setting it, the fourth step comparing the oscillation frequency (A) (B), and the difference value of the oscillation frequency (A) (B). The fifth step of adjusting the illuminance of the lamp L by increasing and decreasing and the sixth step of generating ultrasonic waves at a continuous frequency in association with the change of the oscillation frequency (A) (B) are performed.

Here, the oscillation frequency (A) is set to the oscillation frequency oscillated by the frequency converter 400 before the illuminance sensor 800 detects the ambient illumination while the lamp (L) is lit, the data storage unit 700 The oscillation frequency is set to gradually increase as the input voltage increases, and if the oscillation frequency (A) is higher than the oscillation frequency (B), the oscillation frequency of the frequency converter 400 is reduced, and the oscillation frequency ( If B) and the oscillation frequency (A) are the same, the oscillation frequency is maintained as it is, while if the oscillation frequency (A) is lower than the oscillation frequency (B), the oscillation frequency of the frequency converter 400 is increased and the lamp driver 500 )

5 is a table showing the oscillation frequency for turning on the lamp of the inverter stand according to the present invention, the brightness of the surroundings (inversely proportional to the input voltage detected and input by the illuminance sensor 800) As it becomes brighter, the oscillation frequency for driving the lamp gradually decreases.

When the main power is input (S1) while maintaining the standby state, the microprocessor 300 of the inverter stand configured as described above checks the input of a key (touch sensor) for turning on the lamp L (S2). As a result, if the touch sensor is not operated, the standby state is maintained, but when the touch sensor is operated, frequency conversion data is generated and applied to the frequency converter 400. As a result, an oscillation frequency of 70 KHz oscillated by the frequency converter 400 is applied to the lamp driver 500 so that the lamp L is turned on with brightness corresponding to the oscillation frequency A of 70 KHz (S3).

After the first lighting, the microprocessor 300 checks whether the illuminance data detected by the illuminance sensor 800 is normally input (S4). In other words, the illuminance detection sensor 800 operates normally to check whether illuminance data is input. As a result, if the illuminance detection sensor 800 does not operate normally (that is, a state in which illuminance data is not input), the display unit 600 is driven to output a message indicating that the illuminance detection sensor 800 is in an abnormal state (S5). When the illuminance data is normally input, the ambient brightness is sensed according to the input voltage level of the illuminance data (S6).

The oscillation frequency corresponding to the input voltage is read from the data storage unit 700 (S7) and the oscillation frequency B is set (S8). That is, as shown in FIG. 5, the oscillation frequency is gradually decreased to correspond to the input voltage which decreases as the ambient light becomes bright (for example, as shown in FIG. 5, 90KHz at 5V, 86KHz to 0 at 4.5V, 54kHz at 5V and 50KHz at 0V).

Subsequently, the microprocessor 300 obtains a difference value by comparing the oscillation frequency A and the oscillation frequency B (S9). As a result, when the oscillation frequency B corresponding to the ambient brightness detected by the illumination sensor 800 is larger than the oscillation frequency A oscillating on the frequency converter 400 (a case where the ambient brightness becomes dark) 5), the oscillation frequency oscillated in the frequency converter 400 is reduced (S10) and output to the lamp driver 500, and the oscillation frequency (oscillated in the conventional frequency converter 400 is shown in FIG. When A) and the oscillation frequency B corresponding to the ambient brightness detected by the illuminance sensor 800 are the same (the case where the ambient brightness is the same), the oscillation frequency oscillating on the frequency converter 400 is present. Oscillation frequency corresponding to the ambient brightness detected by the illuminance sensor 800 rather than the oscillation frequency A oscillating to the frequency converter 400 while being outputted to the lamp driver 500 by maintaining the low temperature (S11). When (B) is small (the surrounding brightness becomes brighter) Be) has an oscillation frequency of the oscillation to the frequency converter 400 as shown in Figure 5, increasing (S12) to output to a lamp driver 500 controls the lighting of the lamp (L).

Here, the oscillation frequency output from the data storage unit 700 to the lamp driver 500 is also applied in parallel to the ultrasonic generator 900 under the control of the micro process 300. Ultrasonic wave is generated in association with the increase and decrease of the step (S13).

Here, after the lamp L is adjusted to correspond to the ambient brightness after the initial lighting state, the oscillation frequency oscillated by the frequency converter 400 before the illumination data is sensed by the illumination sensor 800 may be used. Set to the oscillation frequency (A). Accordingly, the microprocessor 300 generates the brightness of the lamp L in the oscillation frequency A previously oscillated by the frequency converter 400 and the oscillation frequency B corresponding to the ambient brightness detected by the illuminance sensor 800. Can be adjusted according to the difference value.

The microprocessor 300 for controlling this operation continues until the light is turned off by checking the operation state of the touch sensor (S14), and outputs the frequency converter 400 when the touch sensor for turning off the lamp L is operated. The lamp L is turned off while blocking the frequency conversion data.

The present invention adjusts the frequency of the lamp corresponding to the ambient brightness detected by the illumination sensor by adjusting the brightness of the lamp corresponding to the ambient brightness detected by the illumination sensor to detect the brightness of the upper is installed upward on the lamp shade The intensity of the lamp can be adjusted by increasing or decreasing the negative oscillation frequency, and the ultrasonic waves generated in conjunction with the radiation are radiated at a variable continuous frequency, and thus, even pests that are resistant to the ultrasonic waves of a specific frequency can be eliminated.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be defined only by the appended claims.

Claims (4)

A first step of confirming a key input for lighting the lamp L when the main power is supplied; A second step of lighting the lamp L by the initial oscillation frequency A when it is turned on; A third step of sensing ambient illumination by the illumination detection sensor 800 and reading the oscillation frequency B corresponding to the ambient illumination from the data storage 700 and setting it; A fourth step of preparing for oscillation frequency (A) (B); A fifth step of adjusting the illuminance of the lamp L by increasing or decreasing the oscillation frequency of the frequency converter 400 according to the difference value of the oscillation frequency (A) (B); And a sixth step of generating an ultrasonic wave having a continuous frequency in association with the change of the oscillation frequency (A) (B). 2. The automatic control of an inverter stand having a pest control function according to claim 1, wherein the data storage unit 700 has an oscillation frequency which is gradually increased as the voltage level input from the illuminance data increases. Way. According to claim 1, If the oscillation frequency (A) is higher than the oscillation frequency (B) in the fifth step, the oscillation frequency of the frequency converter 400 is reduced, the oscillation frequency (B) and the oscillation frequency (A) If the same, the oscillation frequency is maintained as it is, while if the oscillation frequency (A) is lower than the oscillation frequency (B) is characterized in that to increase the oscillation frequency of the frequency converter 400 to supply to the lamp driver 500 Automatic control method of inverter stand with pest control function. According to claim 1, wherein the ultrasonic wave generated in the sixth step is applied to the same signal as the oscillation frequency applied to the lamp is operated in conjunction with the brightness of the lamp automatic control of the inverter stand with a pest control function Way.