KR100316477B1 - Fly back transformer - Google Patents

Abstract

The present invention relates to a flyback transformer that can reduce the size of the focus unit and improve the reliability by insulating the focus voltage output unit with an epoxy resin. The present invention relates to a transformer that is boosted on the secondary side by applying a predetermined input current to the primary coil. A third coil is wound to draw the screen voltage, a high voltage rectifying diode is connected to the secondary high voltage terminal of the transformer, the high voltage rectifying diode is connected to a high voltage output terminal, and also a bleed resistance, and the bleed resistance is variable. A ground is connected through a resistor, and a flyback transformer is formed by connecting an intermediate tap of the bleed resistor to a focus voltage output terminal.

Description

Flyback Transformers {FLY BACK TRANSFORMER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flyback transformer for supplying a high voltage to a television or a monitor. More particularly, the present invention relates to a flyback transformer capable of reducing the size and reducing the cost by simplifying the configuration of the focus unit.

In general, a flyback transformer (FLY BACK TRANSFORMER) is a device that is mounted inside a television or monitor to rectify the voltage to DC high voltage by doubling the pulse voltage used in the horizontal output circuit by several times, basically shown in the circuit diagram of FIG. As described above, the primary winding L1 receiving the sawtooth wave voltage output from the horizontal output circuit 20 and the secondary winding L2 boosting and rectifying the voltage induced from the primary winding L1 to a predetermined high voltage. ) And a rectifying diode (D) for rectifying the high-voltage direct current voltage output by the secondary winding (L2) and outputting it to the high-voltage output terminal (Hv).

At this time, a focus voltage for adjusting the focus of the water pipe is required. The focus voltage is about 22 to 32% of the anode voltage Hv output from the flyback transformer. Accordingly, a focus unit 30 having a variable voltage VR1 for adjusting the focus voltage and a variable resistor VR2 for adjusting the screen voltage in series is connected to a high voltage output terminal Hv of the flyback transformer through a bleed resistor B / R. Then, the focus voltage and the screen voltage are drawn out from the middle taps of the variable resistors VR1 and VR2, respectively. Therefore, the voltage of about 37% of the high voltage is applied to the focus unit by the bleed resistor B / R, and the voltage is adjusted to the variable resistors VR1 and VR2 and drawn out to the focus voltage and the screen voltage. .

The actual structure of the flyback transformer having such a circuit configuration is made as shown in Figure 1a, the high-pressure bobbin (1) and the low-pressure bobbin (2) is installed on the side of the case 10 of the flyback transformer focus pack ( 11, a focus and screen shaft volume 9 for adjusting the focus voltage and the screen voltage and a slider 8 connected thereto are installed, and the contact and contact of the slider 8 are shown in FIG. 1A. A substrate 7 having a circuit pattern formed thereon is positioned on the rear surface of the focus pack 10, and a breather resistor 13 and a high voltage diode 3 are formed on the pattern on the substrate 7 and the terminals of the high voltage bobbin 2. After the connection, the focus and the screen cable 12 is constructed so that it is molded and molded as the epoxy soft resin 4. Here, reference numeral 5 in the drawing denotes a speed-up capacitor, and 6 is a ferrite core.

In other words, as the contact portion changes as the slider 8 moves, the resistance value changes to change the focus voltage.

However, the high voltage outputted through the high voltage rectifying diode D after being induced into the secondary winding L2 is dropped through the bleed resistor, so that a high voltage of a predetermined level (for example, about 10 kV or more) is applied to the input of the focus unit. Since it is necessary to secure the insulation force, and in particular, only the focus unit part cannot be insulated with epoxy, so the size of the printed circuit board of the focus unit becomes large and the design of the pattern becomes important to secure the insulation force spatially.

In addition, there is a problem that appears in the most vulnerable part of the flyback transformer during bad conditions such as decompression test during the reliability test.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described conventional problems, and an object thereof is to provide a flyback transformer capable of reducing the size of the focus unit and improving the reliability by allowing the focus voltage output unit to be insulated with epoxy resin.

1 is a cross-sectional view showing the structure of a typical flyback transformer.

Figure 2 is a circuit diagram showing the configuration of a conventional flyback transformer.

3 is a circuit diagram showing the configuration of a flyback transformer according to the present invention.

4A is a schematic structural diagram showing an actual configuration of a conventional focus unit, and FIG. 4B is a schematic diagram showing a portion changed according to the present invention.

* Description of the symbols for the main parts of the drawings *

1: high pressure bobbin 2: low pressure bobbin

3: high pressure rectifier diode 4: epoxy resin

5 speed up capacitor 6 ferrite core

7: printed circuit board 8: slider

9: shaft volume 10: case

13: bleed resistance

As a construction means for achieving the object of the present invention described above, the flyback transformer according to the present invention is provided with a tertiary coil to draw a screen voltage to the transformer to receive a predetermined input current as the primary coil and boosted on the secondary side The high voltage rectifying diode is connected to the secondary high voltage terminal of the transformer, the high voltage rectifying diode is connected to the high voltage output terminal, and also connected to a bleed resistor, and the bleed resistance is grounded through a variable resistor. The middle tap is connected to the focus voltage output terminal.

Hereinafter, with reference to the accompanying drawings will be described the configuration and operation of the present invention.

3 is a circuit diagram of the configuration of the flyback transformer according to the present invention, and the primary winding forming the low-voltage bobbin of the flyback transformer at the output terminal of the horizontal output circuit 20 for outputting the sawtooth current by operating in accordance with the horizontal output pulse. (L1) is connected, and the high voltage terminal of the secondary winding (L2) where the voltage is induced from the primary winding (L1) is connected to the high voltage output terminal (Hv) through the high voltage rectifying diode (D), and the high voltage rectifying diode An anode of (D) is connected to a bleed resistor (B / R), and the other end of the bleed resistor (B / R) is grounded through a variable resistor (VR31), and an intermediate tap of the bleed resistor (B / R) is connected. It is connected to a focus voltage output terminal Vf, and a tertiary winding L3 for inducing a screen voltage G2 is provided in a low voltage bobbin wound around the primary winding L1.

As described above, in the flyback transformer according to the present invention, instead of outputting the focus voltage output from a separate focus unit as in the related art, a voltage is drawn from the middle tap of the bleed resistor and output as a focus voltage. The adjustment of the focus voltage is implemented by connecting a variable resistor in series with the bleed resistor and adjusting the resistance value of the variable resistor. The operation thereof will be described in more detail as follows.

That is, when the horizontal output circuit 20 operates to flow the sawtooth current to the primary winding L1 of the flyback transformer, the sawtooth current is boosted and caught on the secondary winding L2 of the flyback transformer, which is a high voltage rectification. The pulsating component is smoothed by the diode D and then output to the high voltage output terminal Hv.

At this time, the high voltage outputted to the high voltage output terminal Hv is divided by the resistance ratio between the bleed resistor B / R and the variable resistor VR31 connected in series.

At this time, by adjusting the variable resistance (VR31), it is possible to change the total resistance value of the high voltage applied. In addition, since the middle tap of the bleed resistor B / R is connected to the focus voltage output terminal Vf, the upper and lower resistance values of the breather resistor B / R are referred to as R1 and R2 based on the middle tap, respectively. At this time, if the resistance value of the variable resistor VR31 is adjusted to 0, the total resistance value becomes minimum, and at this time, the output focus voltage Vf is To be the minimum.

On the contrary, when the variable resistor VR31 is adjusted to have a maximum resistance value, and the resistance value at this time is R3, the focus voltage Vf is To the maximum.

At this time, the screen voltage (G2) is drawn from the tertiary winding (L3) provided in the low-pressure bobbin of the flyback transformer, and adjusted to use in the set.

The actual implementation of the illustrated focus unit circuit is as shown in FIG. 4, where FIG. 4A is a schematic perspective view showing a conventional focus unit, and FIG. 4B is a schematic perspective view of an improved focus voltage output portion according to the present invention.

As shown in the drawing, a conventional focus unit is provided with a bleed resistor 41 having one end connected to a high voltage output terminal Hv, and a printed circuit printed with a resistor pattern having the other end of the bleed resistor 41 and two variable parts. The input end of the substrate 42 is connected. In this case, in the resistor pattern on the printed circuit board 42, the variable part is in contact with the slider 8 shown in FIG. 1A, and the slider 8 must be rotated by the shaft volume 9 on the upper side thereof. Since it cannot be charged with (4), it is necessary to secure a predetermined space for insulation to the focus output unit. In addition, since the resistor pattern including the two variable parts is to be printed, the size of the printed circuit board 42 is very large.

On the contrary, in the focus unit according to the present invention, as shown in FIG. 4B, the bleed resistor 41 'is connected to the high voltage output terminal Hv, and the middle tap of the bleed resistor 41' is the focus voltage output terminal Vf. The other end of the bleed resistor 41 'is connected to a substrate 42' on which a variable resistance pattern is printed. At this time, the size of the bleed resistor 41 'is the same as the conventional one, and the substrate 42' is smaller than the conventional substrate 42 because only one variable resistance pattern can be printed. In addition, since the focus output terminal Vf connected to the middle tab of the bleed resistor 41 'can be insulated by impregnation with an epoxy resin 4 or the like, it is advantageous for securing an insulation separation distance and improving reliability.

At this time, the screen voltage is drawn through the third auxiliary coil (L3) wound on the flyback transformer to adjust the outside of the flyback transformer from the outside, thereby reducing the size of the focus unit.

The flyback transformer implemented as described above can impregnate the output terminal of the focus voltage with epoxy, thereby increasing the insulation effect, and as a result, has an excellent effect of increasing the reliability of the test unit, and the voltage adjusting shaft of the focus unit. By eliminating the configuration of volume and slade, there is an excellent effect of simplifying the set process and improving productivity.

In addition, by drawing the focus voltage directly under the bleed reduction, there is no need for parts such as shaft volume or slide, thereby reducing the cost.

Claims (2)

Winding the tertiary coil to draw the screen voltage to the low voltage bobbin of the flyback transformer which is boosted by the secondary winding coil by receiving a predetermined input current through the primary winding coil, and the high voltage end of the secondary winding coil of the flyback transformer. A high voltage rectifier diode, a high voltage rectifier diode connected to a high voltage output terminal, a high voltage rectifier diode connected to a bleed resistor, the bleed resistor is grounded through a variable resistor, and an intermediate tap of the bleed resistor is connected to a focus voltage output terminal. Flyback transformer, characterized in that the configuration by connecting. The flyback transformer according to claim 1, wherein the focus voltage of the flyback transformer is adjusted by changing a resistance value of the variable resistor.