KR20080003965A - A transformer having a closed magnetic flux path - Google Patents

Abstract

A transformer having a closed flux path is provided to drive one first winding normally even when other first windings are damaged. At least one bobbin(21) comprises at least two first coil frames(211) and at least one second coil frame(212). At least one first wining comprises at least two first coils which are wounded at the first coil frames respectively. At least one second winding comprises a plurality of second coils which are wounded at the second coil frames. At least two magnetic cores(22,23) pass the inside of the bobbin to form a closed flux path.

Description

Transformer with closed magnetic flux path {A TRANSFORMER HAVING A CLOSED MAGNETIC FLUX PATH}

1 is a schematic diagram of a magnetic flux path of a prior art transformer.

2 is a schematic diagram of a first embodiment of the present invention.

3 is a schematic diagram of the lung flux path of the present invention.

4 is a schematic diagram of two coils wound in parallel and a closed magnetic flux path of the present invention.

5 is a schematic diagram of a second embodiment of the present invention.

6 is a schematic diagram of a third embodiment of the present invention.

7 is a schematic diagram of a fourth embodiment of the present invention.

8 is a schematic diagram of a transformer having a plurality of drives and a plurality of outputs of the present invention.

The present invention relates to a transformer having a closed magnetic flux path. In particular, the present invention relates to a transformer having a closed magnetic flux path used to drive a plurality of CCFLs.

As LCD devices (such as LCD monitors or LCD TVs) grow in size, LCD devices require more CCLF to make light emission from the LCD devices brighter and more uniform.

As shown in FIG. 1, when the prior art transformer 1 provides a plurality of output drive signals, two first windings 11 and two second windings 12 are connected to a single magnetic flux path 13. Is located symmetrically). Each first winding 11 has a set of pins 111 and each second winding 12 has a different set of pins 121. Each of the two first windings 11 is connected with a drive (not shown in the figure) via pins 111. Similarly, each of the two second windings 12 is connected with a CCFL (not shown in the figure) via pins 121. Thus, the transformer provides two sets of output signals. However, when one of the first windings 11 is damaged or corroded, the magnetic flux induced by the magnetic flux path 13 becomes so small that it affects the signal output from the two second windings 12. Therefore, the power supplied to the CCFL is inappropriate, and the brightness of the CCFL is affected.

One particular aspect of the present invention is to provide a transformer having a closed magnetic flux path. The transformer is connected with a plurality of drives to provide a plurality of output signals. The flux paths are independent of each other. When one of the first windings is damaged, the output signal is not affected.

The transformer with a closed magnetic flux path has at least one bobbin, at least one first winding, at least one second winding and at least two magnetic cores. The bobbin has at least two first coil frames and at least one second coil frame. The first winding has at least two first coils wound on the first coil frame of the bobbin. The second winding has a plurality of second coils wound on the second coil frame of the bobbin. Two magnetic cores pass through the bobbin to form at least two independent closed magnetic flux paths. Therefore, even if one first coil of the closed magnetic flux path is damaged, the magnetic flux on the other closed magnetic flux path does not change, so that the output of the second coil becomes stable.

To better understand the invention, reference is made to the following detailed description, which describes examples and examples of the present invention. Such descriptions are intended to illustrate the invention and are not intended to limit the scope of the claims.

The drawings included herein are provided to better understand the invention.

See FIG. 2. The transformer with a closed magnetic flux path has a bobbin 21, an E-type magnetic core 22 and an I-type magnetic core 23. The type I magnetic core 23 penetrates inside the bobbin 21. The E type magnetic core 22 is joined with the I type magnetic core 23 to form a magnetic flux path 24 having an angular B shape (as shown in FIG. 3). The bobbin 21 has four first coil frames 211 and two second coil frames 212. A separating-board 213 is positioned at the center of the bobbin 21 to separate the first coil frame 211 from the second coil frame 212. The first coil frame 211 is located symmetrically with the second coil frame 212. Two adjacent first coil frames 211 are located near the separator plate 213. The second coil frames are separately installed on two sides of the bobbin 21 and are adjacent to the first coil frame 211. There are a plurality of first fins 214 and second fins 215 in the bobbin 21. The first fin 214 is adjacent to the first coil frame 211 and the second fin 215 is adjacent to the second coil frame 212. The first coil frame 211 is wound around the first winding 25 and the second coil frame 212 is wound around the second winding 26 (as shown in FIG. 3). The first pin 214 is connected with a driver (not shown in the figure), and the second pin 215 is connected with a CCFL (not shown in the figure).

See FIG. 3. The bobbin 21 (as shown in FIG. 2) has two first windings so as to have a first winding 25 and a second winding 26 in which two sides of the magnetic flux path 24 are symmetrically disposed. 25 and two second windings 26. The first winding 25 has two first coils 251 and a compensating coil 252. Thus, the two windings 25 are individually connected to the Royer drive (not shown in the drawing) via the first pin 214, and the two second windings 26 are connected to the second pin ( 215 is individually connected to the CCFL. When power is input to the first winding 25 through the lower drive, the magnetic flux path 24 forms a closed magnetic flux path, creating a magnetic flow due to the current flow through the first winding 25. . The two second windings 26 generate a current for driving the CCFL to emit light in response to magnetic flow. The compensating coil 252 makes the current generated in the second winding 26 more stable. When one rotor drive connected to one first winding 25 in one of the closed magnetic flux paths 241 is damaged, the other closed magnetic flux path 241 is independent of the two closed magnetic flux paths 241. Therefore, it is not damaged or affected. Thus, the intact closed magnetic flux path 241 enables the CCFL to emit light stably.

See FIG. 4. The first winding 25 has two first coils 251 and a drive (not shown) through the first pin 214 using a two wound wires method. Connected. The drive is full-bridge, half-bridge, or push-pull. The four first pins 214 of the first coil 251 are individually connected to the current output terminal MOSFETs of the driver and other MOSFETs. The two input pins 214 of the first coil 251 are electrically connected to the current input terminal MOSFETs of the push-pull driver. The two output pins 214 of the first coil 251 are electrically connected to other MOSFETs of the push-pull driver. In this way, the intact closed magnetic flux path 241 can operate normally, and the two-wound wire method reduces the collection effect of the first coil 251 and the temperature of the first coil 251. To protect the first winding 25.

See FIG. 5. In this embodiment, the transformer with the closed magnetic flux path 2 has a bobbin 21, a pseudo E type magnetic core 22 ′ and a type I magnetic core 23. The pseudo E-shaped magnetic core 22 'has a U-shaped portion 221'. Two parallel l-shaped portions 222 'extend upward from the center of the bottom of the U-shaped portion 221'. The type I magnetic core 23 penetrates inside the bobbin 21. The pseudo E-shaped magnetic core 22 'is joined with the I-type magnetic core 23 to form a magnetic flux path 24 having a lattice shape. Thus, two independent closed flux paths are obtained.

See FIG. 6. In this embodiment, the transformer with the closed magnetic flux path 2 has a bobbin 21, two E-type magnetic cores 22 and two I-type magnetic cores 23. The two I-type magnetic cores 23 are arranged in parallel at the center of the bobbin 21, perpendicular to the bobbin 21, and are straddled with the bobbin 21. The central portions of the two E-type magnetic cores 22 plug into the bobbin 21 from two ends of the bobbin 21. Two sides of the E-type magnetic core 22 are joined to the I-type magnetic core 23 separately. Thus, two independent closed flux paths are obtained.

See FIG. 7 and FIG. 8. The transformer with the closed magnetic flux path 2 provides a plurality of outputs. In this embodiment, the transformer with the closed magnetic flux path 2 has two bobbins 21, four F-type magnetic cores 27 and two I-type magnetic cores 23. The two bobbins 21 are identical to each other. The two I-type magnetic cores 23 are arranged in parallel in the center of the bobbin 21, perpendicular to the bobbin 21, and straddling the bobbin 21. The F-type magnetic cores 27 are individually plugged into the bobbin 21 and are adjacent to each other. The F type magnetic core 27 is individually bonded to two I type magnetic cores 23. The magnetic flux path 24 forms two independent closed magnetic flux paths 241, as shown in FIG. 8. Each of the closed magnetic flux paths 241 has two first windings 25 and two second windings 26, with multiple inputs and multiple outputs. Each of the closed magnetic flux paths 241 is independent of each other, so that a single closed magnetic flux path 241 can be stably output.

The transformer with the closed magnetic flux path 2 avoids the problem that the output of every second winding is affected when a single first winding is damaged. The two-wound wire method reduces the collection effect and temperature to protect the first winding. In addition, co-locating the various magnetic cores has the effect of forming multiple magnetic flux paths with multiple inputs and multiple outputs.

The foregoing description merely illustrates certain embodiments and examples of the invention. Accordingly, the present invention should cover various modifications and variations made to the structure and operation of the invention described herein as long as it is within the scope of the invention as defined in the following appended claims.

As described above, according to the present invention, even when one of the first windings is damaged, it is possible to obtain a transformer in which the other first winding still operates normally and is not affected.

Claims (7)

A transformer with a closed magnetic flux path, the transformer comprising: At least one bobbin having at least two first coil frames and at least one second coil frame; At least one first winding having at least two first coils wound separately on the two first coil frames; At least one second winding having a plurality of second coils wound on the second coil frame; And At least two magnetic cores penetrating the interior of the bobbin to form a closed magnetic flux path. The method according to claim 1, The bobbin has a plurality of first and second pins, the first winding connecting with a drive through the first pin. The method according to claim 2, And the first winding is connected to the drive part by a two wound wires method. The method according to claim 2, The driving unit is a full bridge driving unit, a half bridge driving unit, a push-pull driving unit, or a lower driver. The method according to claim 1, The magnetic core comprises at least one type I magnetic core and at least one type E magnetic core, the type I magnetic core joining the type E magnetic core. The method according to claim 1, The magnetic core comprises a pseudo-E magnetic core and a type I magnetic core, the type I magnetic core joining the type E magnetic core. The method according to claim 1, The magnetic core comprises four F-type magnetic cores and two I-type magnetic cores, wherein the I-type magnetic core is bonded to the F-type magnetic core.

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