KR100435161B1 - Transformer for LCD inverter being in structure raising high inside voltage - Google Patents

Abstract

The present invention relates to a transformer for LCD inverters, and the transformer for LCD inverters having a withstand voltage rising structure according to the present invention includes a first winding unit having a plurality of partition / slit layer structures and a second winding unit for winding a high voltage line. The first winding and the second winding which are formed at the lower end of both ends of the winding part and the winding part, and are wound on the bobbin, the first winding part, and the second winding part, respectively, which are formed of a supporting plate supporting the winding part and having lead wire connecting pins. An LCD inverter transformer consisting of a winding, an insulator and a core that covers the upper end of the bobbin and covers the support plate, and the bobbin has a secondary lead line separated from the second winding at the bottom of the last partition wall where the secondary lead line of the second winding is drawn out. To protrude the support jaw so that it can pivot with the connecting pin of the support plate, and the insulator is a plate material, which surrounds the side of the winding part of the perforated bobbin A wall is formed at both ends of the upper through part, and an inner wall is formed adjacent to the second winding from the supporting jaw to the supporting plate to which the drawing line of the second winding is connected, and an outer wall is formed at the end of the supporting plate parallel to the inner wall to insert the drawing line. Characterized in that.

According to the present invention, it is possible to prevent the winding portion from being contaminated with foreign matters (salin, moisture, grease, etc.) to lower the withstand voltage, thereby improving the assembling process, and the second lead wire of the second winding for pin connection It can protect, and can insulate the breakdown voltage to be applicable to a large screen LCD in a small size.

Description

Transformer for LCD inverter being in structure raising high inside voltage}

The present invention relates to a transformer for LCD inverter having a voltage withstand voltage rising structure. More specifically, the film-type insulator of a conventional LCD inverter transformer has an inner and outer wall structure formed on the bottom to protect the secondary lead wire of the second winding. The present invention relates to a transformer for an LCD inverter that can increase the withstand voltage by replacing a plate cap that blocks electric field interference between wires.

Unlike plasma display panels (PDPs) and field emission displays (FEDs), liquid crystal displays (LCDs) are non-light-emitting (light-receiving elements) and thus cannot be used in the absence of light. In order to compensate for these disadvantages, a backlight for uniformly irradiating the display surface of the LCD is used. In general, the backlight has a basic structure of a light source, a light guide plate, a diffusion plate, and a prism sheet.

Cold Cathode Flourescent Lamps (CCFLs) are the most commonly used backlights. Cold Cathode Fluorescent Lamps, which are used as light sources, consume less power and provide bright white light. It has such characteristics as to evenly irradiate.

An LCD inverter is used to turn on the above-mentioned cold cathode fluorescent lamp and adjust its brightness. In the case of a large-screen LCD, recently, since the length of the cold cathode fluorescent lamp is increased, the starting voltage is increased while the LCD is thin. Since the diameter of the cold cathode fluorescent lamp decreases, the starting voltage also increases.

Therefore, as the starting voltage of the cold cathode fluorescent lamp increases, the withstand voltage (insulation voltage between the primary winding and the secondary winding) of the transformer used in the LCD inverter circuit must be higher.

1 shows a basic circuit of an LCD inverter used to light a cold cathode fluorescent lamp.

According to FIG. 1, the control circuit turns on / off the switch S1 by using current sensing (a voltage applied to the sensing resistor Rs is compared with a reference voltage and the current flowing through the lamp is fed back when the two voltages do not match) and a dimming signal. The controlled voltage Vd thereby controls the brightness of the lamp by varying the lamp current.

After the lamp is turned on, in order to maintain the lighting state and to adjust the brightness, an AC voltage must be applied to both ends of the lamp. For this purpose, a rotor circuit using the autogenous oscillation of the switches S2, S3 and transformer T1 is configured.

2 is an exploded view of a conventional transformer for LCD inverter.

According to Figure 2, the transformer used in the conventional LCD inverter circuit is a bobbin 100 having a winding portion 120 and the support plate 110, the first winding 126 and the second winding wound on the bobbin 100 128, an insulator 200 and a core 300 penetrating the upper end of the bobbin 100 to be covered on the support plate 110, and the winding part 120 includes a plurality of partition walls / slit layers for winding a high voltage line. It consists of a first winding portion 122 having a structure and a second winding portion 124 for winding a low voltage line, the support plate 110 is formed at both ends of the lower end of the winding portion 120 to support the winding portion 120 And a leader line connecting pin 112.

Here, the insulator 200 forms a film wall 210 on both sides of the upper through portion so as to insulate the first winding 126 and the second winding 128 wound on the bobbin 100 from both sides, and the first winding portion. Reference numeral 122 defines a plurality of support jaws 122a by protruding the lower end of the partition wall to support the secondary leader line 126a through which the high voltage current is generated and guided to the support plate 110.

3 is a perspective view of the upper side coupling of a conventional transformer for LCD inverter.

According to FIG. 3, a film-type insulator 200 made of a synthetic resin penetrates through the bobbin 100 wound around the first winding 126 and the second winding 128, and is placed on the support plate 110, and on the insulator 200. Again, the cores 300 are fitted to both ends of the bobbin 100, respectively, and are coupled through the internal passages of the bobbin 100. The upper end protruding to the outside of the bonded bobbin 100 is wax-impregnated, and the core 300 is externally taped.

Therefore, the insulator 200 can insulate the input terminal of the low-voltage first winding 126 and the output terminal of the high-voltage second winding 128.

4 is a bottom side coupling diagram of a conventional transformer for LCD inverter.

However, the insulator 200 is currently made of a film of a material such as PC (PolyCarbonate) or PETP (PolyEthylene TerePhthalate), and in this case, its insulation is remarkably lowered to increase the insulation voltage of the LCD inverter for controlling cold cathode fluorescent lamps having high starting voltage. Sufficient space must be secured between the high and low voltage stages. Therefore, the problem that the volume of the transformer becomes large occurs.

In addition, as shown in FIG. 4, since the insulator 200 does not protect the secondary leader line 126a of the second winding 128 on the bottom side, the secondary leader line (only in the assembly process of the transformer and the wax impregnation process (only) (126a) is only supported by the supporting jaw 122a of the second winding part 124, and may come into contact with the manufacturer's hand or equipment to get foreign substances such as oil or damage by short circuit with other transformers. Is exposed to. That is, if the sophisticated second winding 128 and the lead wire 126a are sparked and burned by high voltage without being able to withstand the withstand voltage, the withstand voltage of the transformer may be decreased.

In addition, since the secondary leader line 126a illustrated in FIG. 4 is not blocked by the insulator 200 withstand voltage interference with the second winding 128 in the inner direction and withstand voltage interference with the core 300 in the outer direction. This results in a significant decrease in the withstand voltage.

Accordingly, in order to apply a high voltage necessary for starting an LCD inverter used for controlling a cold cathode fluorescent lamp, it is necessary to develop a transformer having a structure in which its volume is reduced while increasing the withstand voltage.

The present invention has been made in order to meet the requirements as described above, the film-type insulator of the existing transformer for LCD inverters, the inner and outer wall structure on the bottom to protect the secondary lead wire of the second winding and electric field interference between the wires It is an object of the present invention to provide a transformer for an LCD inverter that can increase the withstand voltage by replacing the cap with a plate cap.

1 shows a basic circuit of an LCD inverter used to light a cold cathode fluorescent lamp.

2 is an exploded view of a conventional transformer for LCD inverter.

3 is a perspective view of the upper side coupling of a conventional transformer for LCD inverter.

4 is a bottom side coupling diagram of a conventional transformer for LCD inverter.

5 is a combined exploded view of a transformer for LCD inverters having a withstand voltage rising structure according to the present invention.

6 is a perspective view of the upper side coupling of the transformer for LCD inverter having the withstand voltage rising structure according to the present invention.

Fig. 7 is a perspective view when the cap of the LCD inverter transformer having the withstand voltage rising structure according to the present invention is viewed from the bottom face side.

8 is a bottom side coupling diagram of a transformer for LCD inverters having a withstand voltage rising structure according to the present invention.

<Explanation of symbols for main parts of drawing>

500: bobbin 510: support plate

512: lead wire connecting pin 520: winding

522: first winding portion 522a: support jaw

524: Second winding unit 526: First winding

526a: secondary lead line 528: secondary line 2

600: cap 610: top sidewall

620: bottom outer wall 700: core

710: core through part

In order to achieve the above object, the transformer for LCD inverter having the withstand voltage rising structure according to the present invention is composed of a first winding portion having a plurality of partition wall / slit layer structure and a second winding portion winding a low voltage line to wind the high voltage line. The first winding, the first winding, the second winding, and the bobbin respectively formed on the bobbin, the first winding portion, and the second winding portion, which are formed at the lower end of the winding portion and both ends of the winding portion to support the winding portion, and have a lead connecting pin. An LCD inverter transformer comprising an insulator and a core covering an upper part of a support plate, and a bobbin has a secondary outgoing line spaced apart from a second winding at a lower end of the last partition wall where the secondary outgoing line of the second winding is drawn out. The supporting jaw protrudes so that it can pivot with a connecting pin, and the insulator is a plate-shaped material. It is formed at both ends and forms an inner wall adjacent to the second winding from the support jaw to the support plate to which the lead wire of the second winding is connected at the bottom, and forms an outer wall at the end of the support plate parallel to the inner wall to insert the lead wire. .

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the transformer for LCD inverter having a voltage withstand structure according to the present invention.

5 is a combined exploded view of a transformer for LCD inverters having a withstand voltage rising structure according to the present invention.

Referring to FIG. 5, a transformer for an LCD inverter (hereinafter, referred to as a “transformer according to the present invention”) having a withstand voltage rising structure according to a preferred embodiment of the present invention may include a first winding portion 522 and a second winding portion ( It comprises a bobbin 500, a first winding 526, a second winding 528, an insulator 600, and a core 700 including a winding portion 522 and a support plate 510 having a 524. do.

The bobbin 500 has a structure (for example, a structure such as failure) that forms a passage inside the winding part 522 to which the coil (that is, the winding) is wound so that the core 700 can be penetrated and inserted.

The first winding part 522 has a plurality of partition / slit layer structures for winding the high voltage cable, and the first winding 526 is wound around the slit layer a predetermined number of times and passes through the groove 524a of the partition wall to the next slit layer. Take a cold way. The coil is not separated from the winding process by the partition groove 524a of the first winding part 522. The second winding part 524 winds the low voltage line.

Here, the bobbin 500 is connected to the support plate 510 by separating the secondary leader line 526a from the second winding 528 at the lower end of the last partition wall through which the secondary leader line 526a of the second winding 528 is drawn out. The support jaw 522a protrudes so that the pin 512 can pivot. That is, like the conventional transformer according to FIG. 2, only the last partition wall in which the partition walls are separated from the first winding part 522 does not have all the support jaws 522a to form the support jaws 522a. Therefore, a space is secured between the secondary leader line 526a and the partition walls.

The support plate 510 is formed at the lower ends of both ends of the winding part 522 to support the winding part 522 and includes a leader line connecting pin 512.

The first winding 526 is a coil wound around the first winding portion 522 to generate a high voltage (about 2000V). Since the diameter thereof is usually only 0.04 mm, the first winding 526 is easily burned or physically damaged by the spark. Therefore, the first winding 526 should be protected by the partition / slit layer structure of the first winding portion 522.

The second winding 528 is a coil in which a low voltage (approximately 5V) current flows around the second winding portion 524 and its thickness is significantly thicker (about 0.5 mm) than the first winding 526.

The insulator 600 penetrates the upper end of the bobbin 500 to cover the support plate 510 to insulate the primary current and the secondary current. The insulator 600 has a predetermined thickness instead of the aforementioned film-like material. (Hereinafter, the insulator is referred to as a "cap"). Cap 600 is preferably made of Liquid Crystal Polyester (LCP).

The cap 600 forms sidewalls 610 that surround side surfaces of the winding part 522 of the penetrated bobbin 500 at both ends of the upper through portion.

The core 700 is generally set in two sets of the same shape and inserted into both ends of the inner passage of the bobbin 500, and are coupled to each other. The core 700 is formed of a metal material and forms the core through part 710 to be inserted into and fixed to the inner passage of the bobbin 500.

6 is a perspective view of the upper side coupling of the transformer for LCD inverter having the withstand voltage rising structure according to the present invention.

Referring to FIG. 6, the cap 600 penetrates the winding part 522 and is covered by the support plate 510 to be coupled to the bobbin 500, and the core 700 is inserted / coupled at both ends on the cap 600. The transformer according to the present invention thus bonded is wax impregnated and taped as described above.

Fig. 7 is a perspective view when the cap 600 of the transformer for LCD inverter having the withstand voltage rising structure according to the present invention is viewed from the bottom face side.

According to FIG. 7, the bottom of the cap 600 of the transformer according to the present invention is formed from the support jaw 522a of the bobbin 500 to the support plate 510 to which the lead wire 526a of the second winding 528 is connected. An inner wall 630 is formed adjacent to the two windings 528. That is, the bottom inner wall 630 of the cap 600 is inserted into the space between the shortly formed bobbin bulkhead and the secondary lead-out line 526a, thus blocking the electric field interference between the secondary lead-out line 526a and the first winding line 526. do.

In addition, the cap 600 forms an outer wall 620 at the end of the support plate 510 in parallel with the inner wall 630 to insert the secondary leader line 526a, and the secondary leader line 526a has a bottom inner wall 630. The groove 514 is sandwiched between the bottom outer wall 620 and connected to the support plate 510, and the support plate 510 is protected / leaded so that each lead wire 526a is connected to the connection pin 512 on the bottom. ) To form a plurality.

Accordingly, the bottom outer wall 620 allows the secondary lead wire 526a connected to the connecting pin 512 to be insulated from the core 700.

8 is a bottom side coupling diagram of a transformer for LCD inverters having a withstand voltage rising structure according to the present invention.

Due to the structure of the cap 600 described above, the secondary lead wire 526a is physically protected and insulated from each part to increase the withstand voltage.

The present invention has been described above with reference to the preferred embodiments, which are merely examples and are not intended to limit the present invention, and those skilled in the art to which the present invention pertains do not depart from the essential characteristics of the present invention. It will be appreciated that various modifications and applications are not possible that are not illustrated above. For example, each component specifically shown in the embodiment of the present invention can be modified. And differences relating to such modifications and applications will have to be construed as being included in the scope of the invention defined in the appended claims.

According to the present invention, it is possible to prevent the winding portion from being contaminated with foreign matters (salin, moisture, grease, etc.) to lower the withstand voltage, thereby improving the assembling process, and the secondary lead wire of the second winding for pin connection may be improved. It can protect, and can insulate the breakdown voltage to be applicable to a large screen LCD in a small size.

Claims (1)

In order to wind the high voltage cable, a winding part including a first winding part having a plurality of partition / slit layer structures and a second winding part for winding a low voltage wire and a lower end of both ends of the winding part are formed to support the winding part and connect the lead wire connecting pin. LCD inverter composed of a bobbin composed of a supporting plate provided therein, a first winding and a second winding wound around the first winding portion and a second winding portion, respectively, and an insulator and a core penetrating the upper end of the bobbin to cover the supporting plate. In the transformer for The bobbin protrudes the supporting jaw so that the secondary lead-out line is spaced apart from the second winding line at the lower end of the last partition wall through which the secondary lead-out line of the second winding line is drawn out so that the secondary lead line can turn with the connecting pin of the support plate. The insulator is a plate-shaped material, and forms sidewalls surrounding both sides of the winding part of the perforated bobbin at both ends of the upper surface through, and is adjacent to the second winding from the supporting jaw to the supporting plate to which the lead wire of the second winding is connected. And an outer wall formed at an end of the support plate in parallel with the inner wall to insert the lead wire.