KR20080004868A - Transformer and back light assembly having the same - Google Patents

Abstract

A transformer and a back light assembly having the same are provided to increase a surface distance by forming a first arch preventing unit made of an insulating material between an output terminal and an external core. A transformer(100) includes a core unit(200), a first transformer unit(300), a second transformer(400), and an insulating member(500). The core unit is made of a material having a magnetic property. The core unit is made of a ferrite material capable of efficiently boosting a voltage in comparison with a capacitance. The core unit may be made of silicon steel. The first transformer unit includes a first coil(310) and an input terminal(320). The first coil is wound to a first section. The input terminal extends to a first direction(a) from the first coil. A first voltage is inputted into the input terminal. Therefore, magnetic flux is formed in the core unit by the first voltage. The first voltage represents a low voltage having a low potential difference. The second transformer unit includes a second coil(410) and an output terminal(420). The second coil is wound to a second section. The output terminal extends to a second direction(b) from the second coil.

Description

TRANSFORMER AND BACK LIGHT ASSEMBLY HAVING THE SAME}

1 is a perspective view showing a transformer according to an embodiment of the present invention.

FIG. 2 is a perspective view illustrating the core unit and the insulating member in detail by disassembling the transformer illustrated in FIG. 1.

3 is a cross-sectional view taken along the line II ′ of FIG. 1.

4 is a cross-sectional view of a transformer according to another embodiment of the present invention.

5 is an exploded perspective view illustrating a backlight assembly according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

100, 150: transformer 200: core unit

210: inner core 220: outer core

300: first transformer 310: first coil

320: input terminal 400: second transformer

410: second coil 420: output terminal

500, 550: insulation member 510: body portion

520, 560: first arc protection unit 530, 570: second arc protection unit

600: storage container 700: lamp

800: power supply board 900: lamp socket unit

1000: Backlight Assembly

The present invention relates to a transformer and a backlight assembly having the same, and more particularly, to a transformer capable of preventing arcing and a backlight assembly having the same.

BACKGROUND ART A liquid crystal display generally includes a liquid crystal display panel for displaying an image and a backlight assembly for supplying light to the liquid crystal display panel.

The backlight assembly uses various kinds of light sources to generate light. For example, a backlight assembly used in a large liquid crystal display such as a TV generates light using lamps arranged in parallel with each other on the same plane. Here, the lamp may be made of a cold cathode fluorescent lamp (CCFL) that generates light through plasma discharge by a high voltage. In this case, the backlight assembly includes a separate transformer to generate a high voltage for driving the lamp.

The transformer boosts low voltage to high voltage through the core and the primary and secondary coils wound around the core. That is, the secondary coil is wound around the core at a turns ratio several ten times higher than the primary coil, and then a low voltage is applied to the primary coil, thereby outputting a high voltage boosted to the secondary coil. This high voltage is output to the outside by an output terminal formed at the end of the secondary coil.

However, since the output terminal is substantially disposed very close to the core, there is a problem that an arc can be generated between the output terminal and the core.

Accordingly, the present invention has been made in view of such a problem, and the present invention provides a transformer and a backlight assembly having the same that form a separate structure between the output terminal and the core to prevent generation of an arc.

The transformer according to an aspect of the present invention described above includes a core unit, a first transformer part, a second transformer part, and an insulating member. The first transformer unit has a first coil wound around the core unit and an input terminal extending from the first coil to receive a first voltage. The second transformer unit has a second coil wound around the core unit and an output terminal extending from the second coil and outputting a second voltage boosted from the first voltage. The insulation member may be coupled to the core unit to protect the first and second transformer parts, and a first arc prevention part extending from one end of the body part to increase a creepage distance between the core unit and the output terminal. Have

The core unit includes an elongated inner core and an outer core surrounding both ends of the inner core. Here, the first arc protection part is formed between the outer core and the output terminal.

In addition, the winding ratio of the second coil is characterized in that higher than the winding ratio of the first coil.

The first arc protection portion covers the side of the outer core. Alternatively, the first arc protection part may cover the upper portion of the output terminal.

On the other hand, the insulating member may further include a second arc preventing portion extending from the other end of the body portion to increase the creepage distance between the core unit and the input terminal.

According to an aspect of the present invention, a backlight assembly includes an accommodating container, a light generating unit accommodated in the accommodating container to generate light, and a power supply substrate disposed under the accommodating container to apply a driving voltage to the light generating unit. And a first transformer unit disposed on the power supply substrate to generate the driving voltage, and having a core unit, a first coil wound around the core unit, and an input terminal extending from the first coil to receive a first voltage. And a second transformer unit having a second coil wound around the core unit and an output terminal extending from the second coil and outputting a second voltage boosted from the first voltage, and coupled to the core unit. A body portion that protects the second transformer portion and a first portion extending from one end of the body portion to increase the creepage distance between the core unit and the output terminal; It includes a transformer having an insulating member having a check protection.

According to such a transformer and a backlight assembly having the same, a first arc prevention part made of an insulating material is formed between an output terminal to which a high voltage is output and an outer core disposed adjacent thereto, thereby increasing the creepage distance between the output terminal and the outer core. Arcs that can be generated due to high voltages can be prevented.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view illustrating a transformer according to an embodiment of the present invention, FIG. 2 is a perspective view illustrating the core unit and the insulating member in detail by disassembling the transformer shown in FIG. 1, and FIG. It is a cross-sectional view taken along the line.

1 and 2, a transformer 100 according to an embodiment of the present invention may include a core unit 200, a first transformer unit 300, a second transformer unit 400, and an insulating member 500. Include.

The core unit 200 itself is made of a material having magnetic properties. For example, the core unit 200 is made of a ferrite material that can boost the voltage more efficiently than the capacity. Alternatively, the core unit 200 may be made of silicon steel that is easy to process and repair.

The core unit 200 includes an inner core 210 that is formed to be thin and long, and an outer core 220 that surrounds both ends of the inner core 210. That is, the outer core 220 has a U-shape in which two of the outer cores 220 face each other, corresponding to both ends of the inner core 210. This is to facilitate the operation of winding the first coil 310 of the first transformer unit 300 and the second coil 410 of the second transformer unit 400 to the inner core 210 to be described below. to be. Alternatively, the outer core 220 may be integrally formed. On the other hand, the inner core 210 may also have a structure in which the center is separated from the body.

The first transformer part 300 includes a first coil 310 wound around a first end of the inner core 210 and an input terminal 320 extending in a first direction a from the first coil 310. . The first transformer 300 has a structure in which an electrothermal coating is wound around a metal wire made of copper (Cu) having excellent electrical conductivity.

This is to prevent a short circuit from occurring in the first coil 310 of the first transformer unit 300. If a short circuit occurs in the first coil 310, more current flows than the current that the first transformer 300 can accommodate and eventually burn out, resulting in a fire. In addition, a separate insulator may be further disposed between the inner core 210 and the first coil 310 to additionally insulate the inner core 210 and the first transformer 300.

  The first voltage is input to the input terminal 320. As a result, magnetic flux is formed in the core unit 200 by the first voltage. The first voltage typically means a low voltage having a low potential difference. For example, the first voltage may be formed in the range of 5V to 200V.

The second transformer 400 is a second coil 410 wound on a second end opposite to the first end of the inner core 210 and a second coil opposite to the first direction a from the second coil 410. An output terminal 420 extending in the direction b.

The second transformer 400 has the same structure as the first transformer 300. The second coil 410 is substantially formed adjacent to the first coil 310. In addition, a separate insulator may be further disposed between the inner core 210 and the second coil 410.

The output terminal 420 is disposed adjacent to the outer core 220. This is because the transformer 100 in the present invention is attached to a substantially flat power supply substrate. Accordingly, the input terminal 320 is also disposed adjacent to the outer core 220.

In the second coil 410, a second voltage is generated by the magnetic flux formed in the core unit 200 according to the first voltage. The second voltage is applied to the outside through the output terminal 420. The second voltage has a potential difference that is relatively much higher than the first voltage. For example, the second voltage is formed in the range of 800-1700V.

That is, the first voltage input to the input terminal 320 is changed to a second voltage having a potential difference several tens of times high through the first coil 310 and the second coil 410. To this end, the second coil 410 has a winding ratio relatively higher than that of the first coil 310.

Here, the winding ratio and the boost ratio are substantially directly proportional to each other. For example, when the relative winding ratio of the first coil 310 and the second coil 410 is 1: 4, the step-up ratio of the first voltage and the second voltage is also 1: 4.

As a result, an arc may be generated between the output terminal 420 and the external core 220 due to the boosted second voltage. This is because, as mentioned above, the output terminal 420 and the outer core 220 are arranged very close to each other, and excessive current flows in the output terminal 420 due to the second voltage.

This arc can be easily solved by increasing the creepage distance, which is the length of the electric line of force between the output terminal 420 and the outer core 220, by sufficiently separating the distance between the output terminal 420 and the outer core 220. . However, since the miniaturization is indispensable for the transformer 100 of the present invention to be applied to a liquid crystal display device displaying an image using liquid crystal, the above-described method is not suitable.

Accordingly, the present invention proposes a method of disposing an insulating member 500 having a separate structure that prevents an arc from occurring between the output terminal 420 and the outer core 220.

The insulating member 500 is coupled to the core unit 200 to protect the first and second coils 310 and 410, and a first body formed between the output terminal 420 and the outer core 220. Arc protection unit 520 is included.

The insulating member 500 is made of, for example, a resin material having excellent electrical insulation. The insulating member 500 typically uses the term bobbin in the transformer 100.

Body portion 510 is the transformer 100 of the present invention is substantially attached to a separate power supply substrate 800, accordingly, the core unit 200, the first transformer 300 and the second transformer ( It serves to insulate 400 from the power supply substrate 800.

The first arc protection part 520 is formed while covering the side of the core unit 200 corresponding to the second direction b. The first arc protection part 520 forms a long electric line between the output terminal 420 and the outer core 220 to increase the creepage distance.

Accordingly, the first arc protection unit 520 may prevent the instantaneous current generated at the second voltage without flowing through the second core of the output terminal 420 into the external core 220.

The length of the electric force line between the output terminal 420 and the outer core 220, that is, the creepage distance of the first arc prevention part 520 is changed according to the height h1. In general, the height h1 of the first arc protection part 520 is preferably equal to or higher than the thickness of the outer core 220. This is to prevent the excessive current of the output terminal 420 which prioritizes the linear direction by causing the electric force lines to be bypassed in an arc shape rather than a straight line. In contrast, the height h1 of the first arc protection part 520 may be variously formed according to the magnitude of the second voltage.

According to the thickness t1, the first arc protection part 520 may pass or block an excessive current caused by the second voltage of the output terminal 420 through the first arc protection part 520. That is, when the thickness t1 is equal to or less than the reference value, the first arc preventing part 520 may pass through the excess current, thereby substantially failing to perform an insulating role.

The reference of the thickness t1 depends on the second voltage of the output terminal 420, and the larger the potential difference of the second voltage is, the thicker the reference of the thickness t1 is. In addition, since the thickness t1 substantially affects the planar area of the transformer 100, the first arc prevention part 520 is most preferably formed to a reference thickness.

The first arc preventing part 520 is formed by changing a metal mold for manufacturing the insulating member 500. In contrast, the first arc prevention part 520 may be manufactured separately from the body part 510 and bonded to the body part 510 by an adhesive member.

As such, the insulating member 500 forms a separate first arc preventing part 520 between the output terminal 420 and the outer core 220 to adjust the creepage distance between the output terminal 420 and the outer core 220. By increasing, the excessive current generated by the second voltage can be prevented from generating an arc that is instantaneously applied to the outer core 220.

Meanwhile, the insulating member 500 extends from the body portion 510 to the first transformer 300 and the core unit 200, that is, between the input terminal 320 and the external core 220, so that the insulating member 500 is external to the input terminal 320. A second arc protection unit 530 may be further included to prevent arcs that may be generated between the cores 220. At this time, since the arc is prevented by the second arc protection unit 530 is the same as in the first arc protection unit 520, redundant description will be omitted.

However, the height h2 and the thickness t2 of the second arc protection part 530 are substantially lower than the second voltage of the output terminal 420, because the first voltage of the input terminal 320 is substantially lower than the first h2. It may be formed lower or thinner than the height h1 and the thickness t1 of the arc prevention part 520. In addition, when it is determined that the arc is not generated between the input terminal 320 and the external core 220 because the first voltage is too low, the second arc protection part 530 may be removed.

In addition, the insulating member 500 may further include a guide portion 540 extending from the body portion 510 between the inner core 210 and the outer core 220 to guide the coupling with the core unit 200. . In addition, the guide part 540 may serve to partially block electric force lines generated between the inner core 210 and the outer core 220.

4 is a cross-sectional view of a transformer according to another embodiment of the present invention.

In the present embodiment, except for the shape of the first and second arc protection portion of the insulating member has the same configuration as in Figs. 1 to 3, the same reference numerals are used, and overlapping detailed description thereof will be omitted. .

4, the first arc protection part 560 of the insulating member 550 of the transformer 150 according to another embodiment of the present invention is formed while covering the upper portion of the output terminal 420.

The length of the electric force line between the output terminal 420 and the outer core 220, that is, the creepage distance of the first arc prevention part 560 is changed according to the length L1. In general, the first arc protection part 560 has a length L1 that can cover the entire output terminal 420. This is to prevent the excessive current of the output terminal 420 in which the above-mentioned electric force lines are bypassed and give priority to the linear direction. In contrast, the length L1 of the first arc protection part 560 may be variously formed according to the magnitude of the second voltage.

Thus, the insulating member 550 is formed while covering the upper portion of the output terminal 420, the first arc protection portion 560, the excessive current due to the second voltage as shown in Figures 1 to 3 instantaneously the external core Can prevent the arc applied to

In addition, the second arc protection part 570 of the insulating member 550 may be formed while covering the upper portion of the input terminal 320 between the input terminal 320 and the external core 220. Since the first voltage is substantially low, the length L2 of the second arc protection part 570 may be shorter than the length L1 of the first arc protection part 560. In addition, when it is determined that the first voltage of the input terminal 320 is very low and there is no possibility that an arc is generated between the input terminal 320 and the external core 220, the second arc protection part 570 may be removed. It may be.

5 is an exploded perspective view illustrating a backlight assembly according to an embodiment of the present invention.

In the present embodiment, since the transformer is the same as the structure shown in Figures 1 to 4, the same reference numerals are used, and overlapping detailed description thereof will be omitted.

Referring to FIG. 5, the backlight assembly 1000 according to an embodiment of the present invention includes a storage container 600, lamps 700, a power supply substrate 800, and a transformer 100.

The storage container 600 includes a bottom portion 610 and four side portions 620 extending vertically from the bottom portion 610 to form a storage space therein. The lamps 700 may include a plurality of lamps arranged in parallel with each other in the storage container 600.

The lamp 700 has a power supply lead 710 to which a driving voltage generated from the transformer 100, that is, a second voltage is applied, is formed at one end thereof, and at the other end thereof, a storage container 600 and Connected ground lead 720 is formed. These lamps 700 are Cold Cathode Fluorescent Light (CCFL) with electrodes formed therein.

The power supply substrate 800 is disposed under the storage container 600 to apply a driving voltage to the lamps 700. To this end, the backlight assembly 1000 may further include a lamp socket unit 900 connecting the power supply board 800 to the power lead wire 710 of the lamp 700.

The transformer 100 is disposed on the power supply substrate 800 to generate the driving voltage. Here, the driving voltage means the second voltage mentioned in FIGS. 1 to 4. In addition, the output terminal 420 and the input terminal 320 of the transformer 100 are electrically connected to the power supply substrate 800 by a soldering method.

Meanwhile, the backlight assembly 1000 is disposed below the lamps 700 to reflect light emitted downward from the lamps 700, and is disposed on the lamps 700. The light emitting device may further include a diffusion plate 960 for diffusing light emitted from the light source and an optical sheet 970 disposed on the diffusion plate 960 to improve characteristics of light emitted from the diffusion plate 960.

According to such a transformer and a backlight assembly having the same, a first arc prevention part made of an insulating material is formed between an output terminal to which a high voltage is output and an outer core disposed adjacent thereto to increase the creepage distance, thereby increasing the creepage distance. The generated excessive current can be prevented from instantaneously being applied to the outer core.

In addition, it is possible to prevent the arc in advance by preventing the arc.

Although the detailed description of the present invention has been described with reference to the preferred embodiments of the present invention, those skilled in the art or those skilled in the art will have the idea of the present invention described in the claims to be described later. It will be understood that various modifications and variations can be made in the present invention without departing from the scope of the present invention.

Claims (8)

A core unit; A first transformer unit having a first coil wound around the core unit and an input terminal extending from the first coil to receive a first voltage; A second transformer unit having a second coil wound around the core unit and an output terminal extending from the second coil and outputting a second voltage boosted from the first voltage; And An insulating member having a body portion coupled to the core unit to protect the first and second transformer parts and a first arc preventing portion extending from one end of the body portion to increase a creepage distance between the core unit and the output terminal; Including transformer. The method of claim 1, wherein the core unit Elongated inner core; And And an outer core surrounding both ends of the inner core. The transformer of claim 2, wherein the first arc protection part is formed between the outer core and the output terminal. The transformer of claim 3, wherein a winding ratio of the second coil is higher than a winding ratio of the first coil. 5. The transformer of claim 4, wherein the first arc protection portion covers a side of the outer core. 5. The transformer of claim 4, wherein the first arc protection part covers an upper portion of the output terminal. 3. The transformer of claim 2, wherein the insulation member further comprises a second arc protection portion extending from the other end of the body portion to increase the creepage distance between the core unit and the input terminal. A storage container; A light generating unit accommodated in the storage container to generate light; A power supply substrate disposed under the storage container to apply a driving voltage to the light generating unit; And A first transformer unit disposed on the power supply substrate to generate the driving voltage, the first transformer unit having a core unit, a first coil wound around the core unit, and an input terminal extending from the first coil to receive a first voltage; A second transformer unit having a second coil wound around a core unit and an output terminal extending from the second coil and outputting a second voltage boosted from the first voltage, and coupled to the core unit to the first and second units; And a transformer having a body portion protecting the transformer and an insulating member having a first arc prevention portion extending from one end of the body portion to increase the creepage distance between the core unit and the output terminal.

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