KR100267240B1 - Method and Apparatus for setting of second grid voltage in CRT - Google Patents

Abstract

PURPOSE: A method and an apparatus for setting up the second grid voltage of a cathode ray tube are provided to control a luminance, a color, and a focus of a screen by adding a resistor divider to the circuit. CONSTITUTION: An operating voltage of 110-220 volts is boosted to 24-28k volts by a flyback transformer. The boosted voltage is supplied to an anode stage of a cathode ray tube. A resistor divider(4) with an arbitrary resistance is connected with a divided voltage terminal according to a standard of the cathode ray tube loaded in a monitor. The standard voltage is supplied to the second grid stage. Accordingly, a value of luminance is fixed. The luminance value and a color of a video signal is controlled automatically by a micro computer installed in a monitor.

Description

Method and apparatus for setting second grid voltage of cathode ray tube {Method and Apparatus for setting of second grid voltage in CRT}

The present invention relates to a method and apparatus for setting a second grid voltage of a cathode ray tube (CRT: Cathode Ray-Tube, CDT: color display tube), and more particularly, to set a voltage supplied to a second grid terminal of the cathode ray tube. To this end, by installing a voltage divider having a resistance value standardized according to the specification of the cathode ray tube, a second variable cathode of the cathode ray tube is removed from a separate variable resistance adjustment process for adjusting the brightness and color of the monitor in the production process of the monitor. A grid voltage setting method and apparatus therefor.

In general, a cathode ray tube is a representative image forming apparatus of a display device such as a monitor, and the like, focuses and accelerates electrons emitted from cathodes (first to third grids) enclosed in the tube to generate an electron beam, and generates an electric field or A device in which the scanning direction of the electron beam is controlled by the action of a magnetic field. In order to focus and accelerate the electron beam, a voltage boosted to a different value is applied to the first to third grids sealed in the tube according to the specification of the cathode ray tube, and a commercial voltage (100 volts or 220 volts) for domestic use is applied. The booster is used to generate the high pressure supplied to each grid.

In a typical case, a flyback transformer is used as a booster for boosting the voltage supplied to the cathode ray tube. FIG. 1 is a circuit diagram of a high voltage generation using a flyback transformer to generate a high pressure supplied to a general cathode ray tube. Here, since the high voltage generation circuit diagram using the flyback transformer shown in FIG. 1 is a known high voltage generation circuit employed in a conventional television or monitor, a detailed description thereof will be omitted, and only essential components of the present invention will be described. do.

As shown in FIG. 1, the commercial voltage of 110 volts (V) or 220 volts (V) is boosted from 25 kilovolts to 28 kilovolts by the flyback transformer 1, followed by a cathode ray. It is supplied to the anode terminal (high pressure application terminal) of the tube.

The high voltage is divided by 420 volts (V) to 730 volts (V) by the variable resistor 2 and then supplied to the second grid terminal. Here, the second grid voltage is a voltage that determines the cut-off voltage, the focus characteristic, and the drive gain, and the luminance of the cathode ray tube as the voltage supplied to the second grid terminal varies. In other words, the value of the back-balance (White-Balance) and its color change.

In a typical case, the second grid voltage is determined according to the specification of the cathode ray tube, and as shown in FIG. 2 in the process of manufacturing the monitor, the second resistor according to the specification of the cathode ray tube is mounted by mounting the variable resistance control switch 3. Grid voltage can be adjusted. That is, by operating the variable resistance control switch 3 shown in FIG. 2, the voltage value divided by the variable resistor 2 is varied, and this variable voltage is supplied to the second grid, resulting in the brightness of the monitor. Values and colors are variable.

In the process of adjusting the brightness, color, and focus of the screen using a conventional high voltage generating circuit having the above-described configuration, after adjusting the high pressure (approximately 27 kilovolts) supplied to the anode terminal of the cathode ray tube By adjusting the variable resistance control switch (3), the brightness value of the screen is adjusted. Thereafter, the brightness and the color of the video signal are adjusted through a microcomputer (not shown), and finally, the focus is adjusted by using the variable resistor for focus adjustment shown in FIG.

On the other hand, as described above, in the general cathode ray tube, the second grid voltage is set in advance according to each specification. Therefore, during the manufacturing process, the operator can adjust the second grid voltage by adjusting the variable resistor in accordance with this rule, thereby adjusting the second grid voltage conforming to the corresponding specification.

By the way, when manufacturing the conventional monitor as described above, the following problems occur.

(1) Since the process of operating the variable resistor is added to adjust the brightness and color, a separate operator is required to operate the variable resistor, so that the production efficiency is reduced and unmanned operation is impossible.

(2) 150 volts (V) to 1500 volts in which the adjusting range of the variable resistor for varying the second grid voltage is larger than the range (420 volts (V) to 730 volts (V)) according to the adjustment specification of the second grid voltage. Since it is (V), it is not easy to adjust the second grid voltage when the amount of displacement of the adjustment voltage value is very large when operating the variable resistor.

(3) When adjusting the brightness of the monitor by adjusting the second grid voltage, deviation occurs according to each specification of the cathode ray tube, thereby degrading quality and reliability. Here, if the second grid voltage is higher than the standard voltage value according to the specification, the moire characteristic is lowered. If the second grid voltage is lower than the standard voltage value according to the specification, the focus characteristic is lowered.

Accordingly, the present invention is to solve the above-mentioned problems, an object of the present invention is to remove the variable resistor for adjusting the second grid voltage, the voltage divider having a fixed resistance value according to the specifications standardized for each cathode ray tube The present invention provides a method for setting a second grid voltage of a cathode ray tube by removing the variable resistance adjusting step.

In addition, another object of the present invention is to install a voltage divider having a fixed resistance value according to the specification standardized for each cathode ray tube to supply a standardized divided voltage, so that a stable luminance characteristic of the cathode ray tube can be obtained A second grid voltage setting method is provided.

Further, another object of the present invention is to provide a second grid voltage setting device of a cathode ray tube for achieving the above objects.

1 is a high pressure generating circuit diagram using a flyback transformer to generate a high pressure supplied to a typical cathode ray tube,

2 is a mounting state diagram of the variable resistor shown in FIG. 1;

3 is a high-voltage circuit using a flyback transformer according to the present invention,

4 is a mounting state diagram of the voltage divider shown in FIG. 3.

<Description of the code used in the main part of the drawing>

1: Flyback Transformer

4: voltage divider 5: voltage divider connection terminal

A feature of the present invention for achieving the above object is a method for setting a voltage supplied to a second grid terminal sealed to a cathode ray tube from a high pressure boosted by a flyback transformer; The second grid voltage setting method of the cathode ray tube is to divide the high pressure output from the flyback transformer with a voltage divider having a resistance value specified according to the specification of the cathode ray tube to supply to the second grid terminal.

On the other hand, another feature of the present invention described above, in the apparatus for setting the voltage supplied to the second grid terminal of the cathode ray tube from the high voltage boosted by the flyback transformer: after the high pressure output from the flyback transformer is divided And a second grid voltage setting device of the cathode ray tube including a voltage divider having a fixed resistance value mounted between the flyback transformer and the second grid terminal to be supplied to the second grid terminal.

In another aspect of the present invention described above, the voltage divider preferably has a resistance value set in accordance with the specification of the cathode ray tube.

In addition, the cathode ray tube is preferably installed on the back of the monitor, it is preferable to further include a voltage dividing resistance connecting terminal so that the voltage dividing resistor can be mounted.

Hereinafter, a method for setting a second grid voltage of a cathode ray tube according to the present invention and a preferred embodiment thereof will be described in detail with reference to the accompanying drawings.

3 is a circuit diagram of a high voltage generation using a flyback transformer according to the present invention, and FIG. 4 is a state diagram of the voltage-dividing resistor shown in FIG. 3. In FIGS. 3 and 4, the same reference numerals as used in FIGS. 1 and 2 denote the same components, and thus a separate description thereof will be omitted and only essential components of the present invention will be described.

Referring to FIG. 3, in the high voltage generation circuit of the present invention, the variable resistance of the high voltage generation circuit shown in FIG. 1 is removed, and the divided value resistor 4 having a fixed resistance value according to the specification of the cathode ray tube at the position where the variable resistance is mounted ) Is mounted. That is, 110 volts (V) or 220 volts (V) of domestic commercial voltage is boosted from 25 kilovolts to 28 kilovolts by the flyback transformer (1), and then the anode terminal of the cathode ray tube ( High voltage is applied to a voltage of a predetermined level within the range of voltages (420 volts (V) to 730 volts (V)) specified according to the specifications of the cathode ray tube by the voltage dividing resistor (4). After the partial pressure is supplied to the second grid terminal.

In addition, the voltage dividing resistance connecting terminal 5 is provided so that the voltage dividing resistor 4 of the present invention can be mounted on the rear surface of the monitor shown in FIG. 4, that is, the position where the conventional variable resistance control switch is mounted.

At this time, since the standardized voltage level according to each specification of the cathode ray tube is already determined according to the internationalized standard, this standard data can be programmed during the manufacturing process of the monitor. Thus, by programming the above-described standard data into an automated process device, commonly referred to as a 'robot', the operator does not need to artificially adjust the voltage supplied to the second grid.

Looking at the process of adjusting the brightness, color and focus of the screen using the high-voltage generating circuit of the present invention having the configuration as described above are as follows.

The domestic commercial voltage of 110 volts (V) or 220 volts (V) is boosted to 24 kV to 28 kV by the flyback transformer 1 and then supplied to the anode terminal of the cathode ray tube.

Here, by connecting the voltage divider 4 having an arbitrary resistance value to the voltage dividing resistor connecting terminal 5 in accordance with the specification of the cathode ray tube mounted on the monitor, the normalized voltage dividing voltage is supplied to the second grid terminal. This means that the luminance value of the screen is fixed, and automatically adjusts the luminance value and color of the video signal through a microcomputer (not shown) installed in the monitor.

Here, the method of connecting the voltage dividing resistor 4 is preferably to be collectively mounted by the aforementioned automated process equipment. For this purpose, the voltage dividing resistor connecting terminal 5 is formed outside the apparatus, and the voltage dividing resistor is used. By fitting (4) to the voltage dividing resistor connecting terminal 5, the voltage level supplied to the second grid can be determined, thereby providing the most convenient and stable automated process.

As a result, according to the second grid voltage setting method and apparatus of the cathode ray tube according to the present invention has the following advantages.

(1) By removing the variable resistor for adjusting the second grid voltage and installing a voltage divider having a fixed resistance value according to the specification of the cathode ray tube, an additional process and an operator for adjusting the variable resistor are unnecessary, so that an unattended Justification is possible.

(2) Since the second grid voltage in the cathode ray tube belonging to the specification of the same standard is always constant, the performance of the product can be stabilized and the reliability can be improved.

(3) The production cost of the product can be reduced by eliminating the variable resistor of high cost and using the resistor of low cost.

(4) By mounting the voltage-dividing resistor connection terminal on which the voltage-dividing resistor is mounted, the back of the monitor facilitates the mounting process of the voltage-dividing resistor.

Claims (2)

A method for setting a voltage supplied from a high voltage boosted by a flyback transformer to a second grid terminal sealed in a cathode ray tube; The voltage divider suitable for the specification of the cathode ray tube is connected to the voltage divider connecting terminal formed on the back of the monitor on which the cathode ray tube is mounted by connecting a voltage divider resistor having a resistance value standardized according to the specification of the cathode ray tube. The second grid voltage setting method of the cathode ray tube to be supplied to. In the apparatus for setting the voltage supplied to the second grid terminal of the cathode ray tube from the high voltage boosted by the flyback transformer: Fixed between the flyback transformer and the second grid terminal to be supplied to the second grid terminal after the high pressure output from the flyback transformer is divided, the resistance value is set according to the specification of the cathode ray tube A voltage divider resistor having a resistance value; The voltage dividing resistor is connected to the voltage dividing resistance connecting terminal provided on the rear of the monitor on which the cathode ray tube is mounted, so that the voltage dividing resistor conforming to the specification of the cathode ray tube is supplied to the second grid terminal. 2 Grid voltage setting device.

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