KR100190968B1 - Illuminance Inverter for Time Zone of Inverter Stand and its Method - Google Patents

Abstract

The present invention provides a constant voltage unit 100 for supplying a constant voltage to the set, a key input unit 200 composed of various keys including a touch sensor for setting the operation mode of the set, and controls the overall operation of the set based on key input. A frequency converter 400 for converting the oscillation frequency supplied to the lamp driver 400 by receiving the microprocessor 300, the frequency conversion data output from the microprocessor 300, and the frequency converter 400. In the inverter having a driving unit 500 for adjusting the level of the operating power supplied to the lamp (L) by receiving the oscillation frequency output from the display, and the display unit 600 for displaying the operating state of the set, the microprocessor The clock oscillator 800 is configured to supply the clock data providing the current time to the 300, and frequency conversion data corresponding to each time zone is stored. The data storage unit 700 is connected to the microprocessor 300, and the microprocessor 300 recognizes the current time by the clock data supplied from the clock oscillator 800 and converts the frequency conversion data corresponding to the current time. By reading from the data storage unit 700 and outputting to the frequency converter 400 to adjust the operating power of the lamp (L), it is possible to adjust the illuminance of the lamp (L) according to each time period.

Description

Illuminance conversion device according to time zone of the inverter stand and its method.

The present invention relates to an inverter stand, and more particularly, to a time zone illumination converter and method of the inverter stand to adjust the illumination of the lamp by varying the oscillation frequency of the frequency converter according to the time zone.

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 frequency conversion for adjusting the illuminance of the lamp by receiving a key input. It is composed of a microprocessor 103 for outputting data, a plurality of capacitors and resistors for converting the oscillation IC and its oscillation frequency, and receiving the frequency conversion data output from the microprocessor 103 to the lamp driver 104. The frequency converter 104 converts the supplied oscillation frequency and the oscillation frequency output from the frequency converter 104 to perform a switching operation. Is composed of a lamp driver 105 having a field effect transistor, a transformer for controlling the level of the operating power supplied to the lamp L in association with the field effect transistor, a display unit 106 for displaying the operating state of the set, and the like. have.

When the main power is supplied by the touch sensor of the key input unit 102, the inverter determines the time constant of the frequency converter 104 having a capacitor and a resistance by frequency conversion data output from the microprocessor 103. The IC oscillates an oscillation frequency of approximately 50 KHz to 90 KHz and applies it to the transformer primary side 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 lamp detected by the illuminance detector 109 is converted, the oscillation IC may convert the time constant of the frequency converter 104 to adjust the brightness of the light generated by the lamp L. To oscillate the 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 switch, so that the lamp of the inverter stand can be smoothly lit. The touch sensor is activated when the human body touches while the main power is being 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 of the inverter stand is turned off, the lamp is turned on, whereas when the touch switch is operated by the human body while the lamp of the inverter stand is turned on, the lamp is turned off. In addition, the microprocessor 103 may drive a buzzer (generally using a piezo buzzer) not shown when the touch switch is operated or when a key is pressed to check the operation state of the touch switch or other key input. Output buzzer sound. Accordingly, the operation state of the touch switch or the key input state of the key input unit 102 can be checked.

However, the inverter stand regulates the illuminance by adjusting the operating power supplied to the lamp according to the illuminance of the lamp, but for this purpose, a separate illuminance sensor must be installed and the user cannot set the illuminance desired by the user. There is a case.

An object of the present invention is to provide a time-division illuminance conversion device and a method of the inverter stand that can recognize the current time by the clock data and adjust the illuminance of the lamp according to the current time. .

The present invention for achieving the above object is the first step of determining whether there is a key input when the main power is supplied, and if there is a key input to supply the frequency conversion data to the frequency conversion means to oscillate the oscillation frequency, and A second step of confirming whether clock data is supplied from the clock oscillation means while supplying the driving power to the lamp by supplying the lamp driving means; and when the clock data is input, the current time is recognized by the clock data and corresponding frequency conversion data The third step of reading from the data storage means, the fourth step of setting the oscillation frequency (A) by the read out frequency conversion data, and the set oscillation frequency (A) and the initial frequency of the oscillation frequency (I) The fifth step of preparing for the relationship between the large and small, and the roughness of the lamp by converting the oscillation frequency of the frequency conversion means according to the prepared result and supplying it to the lamp driving means Characterized in that it is made to perform the sixth step of adjusting.

That is, the present invention is to control the overall operation of the set on the basis of the key input means composed of a variety of keys, including a constant voltage means for supplying a constant voltage to the set, a touch switch for setting the operation mode of the set A control unit, a frequency conversion unit configured to convert the oscillation frequency supplied to the lamp driving unit by receiving the frequency conversion data outputted from the control unit, and an oscillation frequency output from the frequency conversion unit and supplied to the lamp An inverter having lamp driving means adapted to adjust a level of an operating power supply and display means adapted to display an operating state of a set, the inverter comprising: clock oscillating means adapted to supply clock data providing a current time to the control means; It is composed of frequency conversion corresponding to each time zone The data storage means having the data stored therein is connected to the control means. The control means recognizes the current time by the clock data supplied from the clock oscillation means and reads the frequency conversion data corresponding to the current time from the data storage means. Output to the frequency conversion means is characterized in that it is configured to adjust the driving frequency of the lamp.

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 flowchart showing an operating state of the present invention;

5 is a diagram showing the oscillation frequency of the time-based frequency converter 400 according to an embodiment of 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 unit 800: clock oscillation unit

As shown in FIG. 3, the present invention is based on a key input unit 200 composed of various keys including a constant voltage unit 100 for supplying a constant voltage to a set, a touch switch for setting an operation mode of the set, and a key input. A microprocessor 300 for controlling the overall operation of the set, a frequency converter 400 for converting the oscillation frequency supplied to the lamp driver 400 by receiving the frequency conversion data output from the microprocessor 300, Inverter having a ramp driver 500 for adjusting the operating frequency supplied to the lamp L by receiving the oscillation frequency output from the frequency converter 400, and a display unit 600 for displaying the operation state of the set In this case, a clock oscillator 800 for supplying clock data for providing a current time to the microprocessor 300 is configured, and a frequency conversion day corresponding to each time zone is provided. Is stored in the data storage unit 700 is connected to the microprocessor 300, the microprocessor 300 recognizes the current time by the clock data supplied from the clock oscillator 800 and corresponds to the current time The frequency conversion data is read from the data storage unit 700 and output to the frequency converter 400 to adjust the operating frequency of the lamp L.

4 is a flowchart illustrating an operating state of the present invention, in which a first step of determining whether there is a key input when the main power is supplied, and supplying frequency conversion data to the frequency converter 400 when the key input is applied to generate an oscillation frequency. Oscillation, and supplying it to the lamp driver 500 to supply an operating frequency to the lamp L while checking whether the clock data is supplied from the clock oscillator 800, and when the clock data is input, by the clock data. A third step of recognizing the current time and reading corresponding frequency conversion data from the data storage unit 700; a fourth step of setting the oscillation frequency A by the read frequency conversion data; and the set oscillation. The fifth step of preparing the magnitude relationship between the frequency (A) and the oscillation frequency (I) at the initial lighting, and converts the oscillation frequency of the frequency converter 400 according to the prepared result to supply to the lamp driver 500 A sixth step of adjusting the roughness of the profile (L) is showing a carrying.

In this case, when the clock data is not input, the display unit 600 is driven to output an error message. If the set oscillation frequency A and the initial lighting oscillation frequency I are the same, the oscillation frequency currently oscillated is maintained, and When the oscillation frequency (I) is large when turned on, the oscillation frequency is decreased, and when the set oscillation frequency (A) is large, the oscillation frequency is increased.

5 is a diagram showing an example of the oscillation frequency of the frequency converter 400 according to each time zone for explaining an embodiment of the present invention, the oscillation frequency (A) during the bright day around Is set high and the oscillation frequency (A) is set low at dark night.

When the inverter stand having the above configuration is supplied with the main power of the inverter stand (S1), the inverter stand checks the operation state of the keypad or the touch switch of the key input unit 200 to determine whether there is a key input (S2). When the mode for turning on the lamp L is set by manipulation of the touch switch or key input of the key input unit 200, frequency conversion data is output to the frequency converter 400, and then the frequency converter 400 is performed. The oscillation frequency supplied by the oscillator is supplied to the lamp driver 500 to adjust the operating frequency supplied to the lamp L (S3), and determine whether the clock data is supplied from the clock oscillator 800 (S4). As a result, when the clock data is not supplied, the display unit 600 is driven to inform that the clock unit of the current inverter stand is in an error state (S5). When clock data is applied from the clock oscillator 800, the microprocessor 300 receives the clock data output from the clock oscillator 800 to recognize the current time, and converts the corresponding frequency conversion data into the data storage 700. Read from (S6) to set the oscillation frequency (A) (S7). That is, the frequency conversion data supplied to the frequency converter 400 is adjusted to adjust the oscillation frequency oscillated by the frequency converter 400 according to the current time detected by the clock data as shown in FIG. 5. The microprocessor 300 setting the oscillation frequency of the frequency converter 400 determines whether the oscillation frequency I output from the current frequency converter 400 is greater than the oscillation frequency A set according to the current time. (S8). As a result, when it is determined that the oscillation frequency I output from the current frequency converter 400 is greater than the oscillation frequency A set according to the current time, the oscillation frequency oscillated by the frequency converter 400 is reduced. The frequency converter 400 outputs the frequency conversion data to the frequency converter 400 and, conversely, it is determined that the oscillation frequency I output from the current frequency converter 400 is smaller than the oscillation frequency A set according to the current time. In this case, the frequency conversion data is output to the frequency converter 400 so that the oscillation frequency oscillated by the frequency converter 400 is output (S8). Of course, the microprocessor 300 converts the frequency conversion data supplied to the frequency converter 400 so as to oscillate the oscillation frequency in accordance with the time zone, but to prevent the illumination of the lamp (L) to suddenly change the frequency converter The oscillation frequency of 400 is gradually converted. Finally, even while converting the oscillation frequency of the frequency converter 400 according to the time zone, the microprocessor 300 checks the key input of the key input unit 200 or the operation state of the touch switch (S11) to turn the lamp L on. When the mode for extinguishing is set, the oscillation of the frequency converter 400 is stopped so that the operating frequency supplied to the lamp L can be cut off. Accordingly, the illuminance of the lamp (L) can be adjusted according to the time zone.

This operation is performed only in the automatic operation mode of the inverter stand, and in another embodiment of the present invention, when the operating mode of the inverter stand is set to the manual mode, the operating power supplied to the lamp L is manually adjusted so that the lamp ( The illuminance of L) can be adjusted manually.

The present invention sets the oscillation frequency of the frequency converter according to the time zone, and then controls the driving of the frequency converter to oscillate the oscillation frequency corresponding to the current time read by the clock data applied by the clock oscillator, thereby specifying a time zone required by the user. The level of illumination can be maintained.

In other words, the oscillation frequency of the frequency converter is set high during the bright day, while the oscillation frequency of the frequency converter is set low during the dark night, but the user sets the oscillation frequency of the frequency converter corresponding to the set time. By doing so, the illumination of the lamp in the time zone can be adjusted according to the needs of the user.

Claims (5)

A constant voltage unit 100 for supplying a constant voltage to the set, a key input unit 200 including various keys including a touch sensor for setting an operation mode of the set, and a microprocessor for controlling the overall operation of the set based on key input ( 300 and a frequency converter 400 for converting the oscillation frequency supplied to the lamp driver 400 by receiving the frequency conversion data output from the microprocessor 300, and outputted from the frequency converter 400. In the inverter having a lamp driver 500 for controlling the level of the operating power supplied to the lamp (L) by receiving the oscillation frequency, and the display unit 600 for displaying the operating state of the set, A clock oscillator 800 for supplying clock data for providing a current time to the microprocessor 300 is configured; A data storage unit 700 in which frequency conversion data corresponding to each time slot is stored is connected to the microprocessor 300; The microprocessor 300 recognizes the current time by the clock data supplied from the clock oscillator 800, and reads out the frequency conversion data corresponding to the current time from the data storage 700 and outputs it to the frequency converter 400. Illuminance converter for each time zone of the inverter stand, characterized in that configured to adjust the operating power of the lamp (L). According to claim 1, wherein the microprocessor 300 is configured to recognize the current time by the clock data only in the automatic mode and to read the frequency conversion data corresponding to this to adjust the conversion of the oscillation frequency of the frequency converter 400 Illuminance converter for each time zone of the inverter stand characterized in that. Determining whether there is a key input when the main power is supplied; When there is a key input, the frequency conversion data is supplied to the frequency converter 400 to oscillate the oscillation frequency, and the lamp driver 500 supplies the operating power to the lamp L while the clock oscillator 800 receives the clock data. A second step of confirming whether is supplied; A third step of recognizing the current time by the clock data when the clock data is input and reading the corresponding frequency conversion data from the data storage 700; A fourth step of setting the oscillation frequency (A) by the read frequency converted data; A fifth step of preparing a magnitude relationship between the set oscillation frequency A and the oscillation frequency I at initial lighting; According to the result of the preparation, the oscillation frequency of the frequency converter 400 is converted and supplied to the lamp driver 500 to perform the sixth step of adjusting the illuminance of the lamp L according to time zones of the inverter stand. Illumination conversion method. 4. The method of claim 3, wherein when the clock data is not input in step 2, the display unit 600 drives the display unit 600 to output an error message. The oscillation frequency of the present invention is maintained if the oscillation frequency (A) and the initial lighting oscillation frequency (I) set in step 6 are the same, and the oscillation frequency is decreased if the oscillation frequency (I) is large during the initial lighting. And, when the set oscillation frequency (A) is large, increase the oscillation frequency.