KR200355756Y1 - Transformer structure - Google Patents

Abstract

The transformer structure has a low-voltage bobbin, two high-voltage bobbins, and two iron cores. The low voltage coil is wound around the low voltage bobbin. Two high voltage coils are wound around a high voltage bobbin, respectively. The high voltage coil and the low voltage coil form a gap therebetween. Each iron core has an inner protruding strip. Since the inner protruding strips of the iron core are respectively inserted in the interval opposite the gaps, the circuit components of the low voltage coil and the external power supply do not burn due to the short circuit of the high voltage coil. Since the low voltage coil is connected to two high voltage coils, the current flowing through the light source of the backlight module is much more balanced, and the elements of the transformer and the backlight module are simplified to reduce costs.

Description

Transformer structure {TRANSFORMER STRUCTURE}

The present invention relates to a transformer structure, in particular a transformer structure for driving a light source of a backlight module.

With advances in optoelectronic technology, manufacturers are devoted to developing large liquid crystal display panels to provide better liquid crystal display devices to consumers. In addition to the liquid crystal display panel, a backlight module is required in the liquid crystal display device to provide a light source for the liquid crystal display panel. The backlight module includes a Cold Cathode Fluorescent Lamp (CCFL) and a transformer. Sufficient transformers are needed to drive the CCFLs for large liquid crystal display panels.

Referring to FIG. 1, a prior art transformer includes a low voltage bobbin 4, a high voltage bobbin 5 and two iron cores 6. The low voltage coil 45 and the high voltage coil 55 are wound around the low voltage bobbin 4 and the high voltage bobbin 5, respectively. The two iron cores 6 are two C-shaped iron cores 6. Two ends of each iron core 6 are respectively inserted into and positioned in the low voltage bobbin 4 and the high voltage bobbin 5.

The low voltage coil 45 is connected to a circuit component of the external power supply. The high voltage coil 55 is connected to the CCFL. When the power supply is on, the low voltage coil 45 generates magnetic flux at two iron cores 6 of the same magnetic circuit. The magnetic flux is coupled with the high voltage coil 55 to generate an induced voltage driving the CCFL for emitting light. Since the low voltage coil 45 and the high voltage coil 55 use the same magnetic circuit, mutual inductance increases. When the transformer drives the CCFLs, a very large load current is generated on the high voltage coil 55. The load current induces a very large counter magnetomotive force that affects the power conversion of the low voltage coil 45 to generate high heat in the low voltage coil 45. If the high voltage coil 55 is shorted, the circuit components of the low voltage coil 45 and the external power supply will burn due to the counter magnetizing force induced by the short circuit current. In addition, when the transformer is connected with many CCFL pieces, in order to balance the current flowing through the CCFL, a ballast component is required to be connected between the transformer and the CCFL, thereby increasing the cost. If one transformer is used to drive only one CCFL, the cost is still high.

Thus, as mentioned above, conventional transformer structures still have a number of problems that must be improved. The present invention aims to solve the problems of the prior art.

Therefore, the main object of the present invention is to provide a transformer structure which can prevent the circuit components of the low voltage coil and the external power supply connected to the low voltage coil from being burned due to the short circuit of the high voltage coil.

Another object of the present invention is to provide a transformer structure that can balance the current flowing through each light source of the backlight module connected to the high voltage coil.

Another object of the present invention is to provide a transformer structure that can reduce the cost of the transformer and the backlight module.

According to the present invention, the object of the present invention is achieved through a transformer structure having a low voltage bobbin, two high voltage bobbins, and two iron cores. The low voltage bobbin has a first body, a first side wall, and a second side wall. The first side wall and the second side wall each connect two ends of the first body. The low voltage bobbin has a first hollow portion, a first body, and a second side wall passing through the first side wall. The low voltage coil is wound around the first body. Each high voltage bobbin has a second body, a third sidewall, and a fourth sidewall. The third side wall and the fourth side wall each connect two ends of the second body. Each high voltage bobbin has a second hollow portion, a second body, and a fourth side wall penetrating the third side wall. Two high voltage coils are wound around the second body, respectively. The low voltage coils around the first body of the high voltage coil and the low voltage bobbin form a gap therebetween. Each iron core has a base, an outer protruding strip, an inner protruding strip, and two outer protruding posts. The outer protruding strip, the inner protruding strip, and the two outer protruding posts of each of the two iron cores extend in the same direction from the base. The inner protruding strip is disposed between the outer protruding strip and the two outer protruding posts. The outer protruding strip of the iron core is inserted into the first hollow part through the first side wall and the second side wall of the low voltage bobbin, respectively, and is located in the first hollow part. The inner protruding strips of the iron core are each inserted in the direction opposite to the gap. An outer protruding post of one of the iron cores is respectively inserted into the second hollow part through the third sidewall of the high voltage bobbin, and is respectively positioned in the second hollow part. Another outer protruding post of the iron core is respectively inserted into the second hollow part through the fourth sidewall of the high voltage bobbin, and is respectively positioned in the second hollow part.

Since the inner protruding strips of the iron core are inserted in the gaps in the opposite direction to the gaps, the circuit components of the external power supply connected with the low voltage coils and the low voltage coils are not burned due to the short circuit of the high voltage coils. The low voltage coils around the low voltage bobbin each combine with two high voltage coils around the two high voltage bobbins, so that the current flowing through each of the light sources of the backlight module connecting with the high voltage coils is much more balanced, and the elements of the transformer and backlight module Simplifies the cost.

In order to provide a better understanding of the subject innovation, the following specification describes examples and examples of the subject innovation. Accordingly, examples of more important features of the present invention have been summarized somewhat broadly so that the description can provide a better understanding and can be highly appreciated for the contribution of the prior art. Of course, there are additional features of the present invention that can be described below to form the subject of utility model claims.

1 is a top plan view of a prior art transformer structure.

2 is an exploded perspective view of a low-voltage bobbin and a high-voltage bobbin of the present invention.

3 is an assembly view of a low voltage bobbin and a high voltage bobbin of the present invention.

4 is another assembly diagram of the low voltage bobbin and the high voltage bobbin of the present invention.

5 is a top plan view of the low voltage bobbin and the high voltage bobbin of the present invention.

6 is an exploded perspective view of the transformer structure of the present invention.

7 is an assembly view of the transformer structure of the present invention.

8 is a side elevation view of a transformer structure of the present invention.

9 is an exploded perspective view of another transformer structure of the present invention.

<Explanation of symbols for main parts of drawing>

1: low voltage bobbin 2: high voltage bobbin

3: iron core 10: first body

11: first sidewall 12: second sidewall

13 first hollow portion 14 low voltage pin

15: low voltage coil 20: second body

21: third sidewall 22: fourth sidewall

23: hollow part 24: high voltage pin

25: high voltage coil 26: guiding groove

27: interval 30: donation

31: outer protrusion strip 32: inner protrusion strip

33: outer protruding post 121: first positioning post

122: second positioning post 123: first cavity

124: first projection 201: insulating wall

202, slot 221, third positioning post

222: fourth positioning post 223: second projection

224: second cavity

2 to 8, the present invention provides a transformer structure. The transformer structure has a low voltage bobbin 1, two high voltage bobbins 2, and two iron cores 3.

The low voltage bobbin 1 has a first body 10, a first side wall 11, and a second side wall 12. The first side wall 11 and the second side wall 12 respectively connect two ends of the first body 10. The low voltage bobbin 1 has a first hollow portion 13, a first body 10, and a second side wall 12 penetrating the first side wall 11. The low voltage bobbin 1 has a low voltage pin 14 disposed on the second side wall 12. The quantity of low voltage pins 14 may be even or odd. The low voltage coil 15 is wound around the first body 10. When the number of low voltage pins 14 is even, the two ends of the low voltage coil 15 can each be wound rapidly on the low voltage pins 14 in an automatic manner. The low voltage coil 15 is connected to a circuit component of the external power supply.

Each high voltage bobbin 2 has a second body 20, a third side wall 21, and a fourth side wall 22. The third side wall 21 and the fourth side wall 22 are connected to two ends of the second body 20, respectively. Each high voltage bobbin 2 has a second hollow portion 23, a second body 20, and a fourth side wall 22 penetrating the third side wall 21. The second body 20 has a plurality of insulating walls 201. Each of the insulating walls 201, one of the insulating walls 201 and the third sidewalls 21, and the other of the insulating walls 201 and the fourth sidewalls 22 respectively form a slot 202 therebetween. . The high voltage bobbin 2 has a high voltage pin 24 disposed on the fourth side wall 22, and the fourth side wall 22 forms a guiding groove 26. Each high voltage pin 24 has a winding 241 and a solder 242. Two high voltage coils 25 are respectively wound in slots 202 around the second body 20. Two ends of each high voltage coil 25 are respectively housed in the guiding grooves 26 and wound around the windings 241, respectively. The low voltage coil 15 around the first body 10 of the high voltage coil 25 and the low voltage bobbin 1 forms a gap 27 therebetween. The high voltage coil 25 connects to a light source of a backlight module such as a cold cathode fluorescent lamp (CCFL).

Each iron core 3 has a base 30, an outer protruding strip 31, an inner protruding strip 32, and two outer protruding posts 33. The outer protruding strip 31, the inner protruding strip 32, and the outer protruding post 33 of each iron core 3 are cubes and extend in the same direction from the base 30. The inner protruding strip 32 is disposed between the outer protruding strip 31 and the two outer protruding posts 33. The outer protruding strip 31 of the iron core 3 is inserted into the first hollow part 13 through the first side wall 11 and the second side wall 12 of the low voltage bobbin 1, respectively, so that the first hollow part ( 13). The inner protruding strips 32 of the iron core 3 are each inserted in the direction opposite to the gap 27 and positioned at the gap 27. The outer protruding posts 33 of one of the iron cores 3 are respectively inserted into the second hollow portions 23 through the third sidewalls 21 of the high voltage bobbin 2 and are respectively positioned in the second hollow portions 23. do. An outer protruding post 33 of another one of the iron cores 3 is respectively inserted into the second hollow portion 23 through the fourth side wall 22 of the high voltage bobbin 2, so that each of the second hollow portions 23 is provided. Is located in. The iron core 3 can be fixed with an adhesive.

In this embodiment, the low voltage bobbin 1 and each high voltage bobbin 2 form a positioning structure therebetween. The positioning structure includes a first positioning post 121, a second positioning post 122, a third positioning post 221, and a fourth positioning post 222. The first positioning post 121 and the second positioning post 122 extend in parallel from the two ends of the second sidewall 12 of the low voltage bobbin 1, respectively. The first positioning post 121 has a first cavity 123. The second positioning post 122 has a first protrusion 124. The third positioning post 221 and the fourth positioning post 222 extend in parallel from the two ends of the fourth side wall 22 of the high voltage bobbin 2, respectively. The third positioning post 221 has a second protrusion 223. The fourth positioning post 222 has a second cavity 224. The second projection 223 of one of the high voltage bobbins 2 engages with the first cavity 123 of the first positioning post 121, and the second cavity 224 of the other of the high voltage bobbins 2 Coupling with the first projection 124 of the second positioning post 122. This makes the coupling between the low voltage bobbin 1 and the high voltage bobbin 2 simple and reliable.

When the power supply is turned on, the low voltage coil 15 generates magnetic flux in the outer protruding strip 31 of the two iron cores 3. The magnetic flux flows through the inner protruding strip 32 and the outer protruding strip 33 respectively along the magnetic circuit of the iron core 3 and then returns to the outer protruding strip 31. The magnetic flux is coupled to the high voltage coil 25 to generate an induced voltage that drives the CCFL for emitting light. Since the low voltage coil 15 connects the two high voltage coils 25, the load currents flowing through the CCFLs, respectively, are much more balanced. On the other hand, the load current generates a counter magnetic flux on the outer protruding post 33. The counter magnetic flux flows through the inner protruding strip 32 and then returns to the outer protruding post 33 due to the magnetic flux of the outer protruding strip 31. The counter magnetic flux does not generate counter magnetic force on the outer protruding strip 31 which affects the power conversion of the low voltage coil 15. In addition, the temperature of the low voltage coil 15 does not easily rise due to better heat dissipation of the two iron cores 3. When the high voltage coil 25 is short-circuited so that a very large short circuit current occurs, the circuit components of the low voltage coil 15 and the external power supply are not burned due to the counter magnetizing force induced by the short circuit current. .

Referring to FIG. 9, the transformer structure of the present invention further includes at least one high voltage bobbin 2, each of which has two iron cores 3 further having another outer protruding post 33. The outer protruding posts 33 of one of the iron cores 3 are respectively inserted into the second hollow portions 23 through the third sidewalls 21 of the high voltage bobbin 2 and are respectively positioned in the second hollow portions 23. do. The outer protruding posts 33 of the other iron cores 3 are respectively inserted into the second hollow portions 23 through the fourth side walls 22 of the high voltage bobbin 2 and are respectively positioned in the second hollow portions 23. . Thereby, the quantity of the high voltage bobbin 2 and the quantity of the outer protruding post 33 of the iron core 3 may be increased to obtain the above result.

As mentioned above, the transformer structure of the present invention has the following advantages.

(1) The circuit components of the external power supply connected to the low voltage coil and the low voltage coil, since the inner protruding strips of the two iron cores are inserted in the gap and inserted in the direction opposite to the gap, and the two iron cores have better heat dissipation. It does not burn due to the short circuit of the high voltage coil.

(2) Since the low voltage coils around the low voltage bobbins connect the two high voltage coils around the two high voltage bobbins, the current flowing through each of the light sources of the backlight module connecting with the high voltage coils becomes even more balanced.

(3) Each high voltage bobbin has the same structure, the two iron cores are symmetrical, and no ballast component is required, which simplifies the elements of the transformer and the backlight module, thereby reducing the cost.

It will be apparent to those skilled in the art that the foregoing description is only illustrative of specific embodiments and examples of the present invention. Therefore, the present invention will encompass various modifications and variations of the structure and operation described herein that are within the scope of the present invention as defined in the following Utility Model claims.

According to the present invention, the circuit components of the low voltage coil and the external power supply connected to the low voltage coil can be prevented from burning due to a short circuit of the high voltage coil, and the current flowing through each light source of the backlight module connected to the high voltage coil. A transformer structure is provided which can balance the voltage and reduce the cost of the transformer and the backlight module.

Claims (10)

As a low-voltage bobbin, The low voltage bobbin has a first body, a first side wall, and a second side wall, wherein the first side wall and the second side wall connect two ends of the first body, respectively, and the low voltage bobbin connects the first side wall. A low voltage bobbin having a penetrating first hollow portion, said first body, and said second side wall, wherein a low voltage coil is wound around said first body, As two high-voltage bobbins, Each of the high voltage bobbins has a second body, a third side wall, and a fourth side wall, wherein the third side wall and the fourth side wall respectively connect two ends of the second body, and each of the high voltage bobbins is A second hollow portion penetrating a third sidewall, the second body, and the fourth sidewall, and two high voltage coils are wound around the second body, respectively, and the first body of the high voltage coil and the low voltage bobbin The perimeter low voltage coil has two high voltage bobbins that form a gap therebetween, and As two iron cores, Each iron core has a base, an outer protruding strip, an inner protruding strip, and two outer protruding posts, and the outer protruding strip, the inner protruding strip, and two outer protruding posts of each of the two respective iron cores form the base. Extending in the same direction from the inner protruding strip, the inner protruding strip disposed between the outer protruding strip and the two outer protruding posts, wherein the outer protruding strip of the iron core is formed through the first side wall and the second side wall of the low voltage bobbin, respectively. 1 is inserted into the hollow portion, and is located in the first hollow portion, the inner protruding strips of the iron core are respectively inserted in the gaps in opposite directions to the gap, and the outer protruding posts of one of the iron cores are formed of the high voltage bobbin. Respectively inserted into the second hollow part through the third side wall, each of which is located in the second hollow part, another outer stone of the iron core The post is inserted into each of the second hollow portion through a fourth side wall of the high voltage bobbin, each of the two iron cores that are positioned in the second hollow portion Transformer structure comprising a. The method of claim 1, The low voltage bobbin has a low voltage pin disposed on the second side wall, the transformer structure, characterized in that the number of the low voltage bobbin is even, The method of claim 1, The low voltage bobbin and the respective high voltage bobbin form a positioning structure therebetween. The method of claim 3, The positioning structure includes a first positioning post, a second positioning post, a third positioning post, and a fourth positioning post, wherein the first positioning post and the second positioning post comprise the low voltage bobbin. Respectively extending in parallel from two ends of the second sidewalls of the first positioning post, the first positioning post having a first cavity, the second positioning post having a first protrusion, the third positioning post and the first Four positioning posts respectively extend in parallel from two ends of the fourth sidewall of the high voltage bobbin, the third positioning post has a second projection, the fourth positioning post has a second cavity, and The second projection of one of the high voltage bobbins is coupled with the first cavity of the first positioning post, and the second cavity of the other of the high voltage bobbins is formed of the first cavity of the second positioning post. Transformer structure characterized in that combined with one projection. The method of claim 1, And the high voltage bobbin has a high voltage pin disposed on the fourth sidewall. The method of claim 5, Each of said high voltage pins comprises a winding and a soldering portion. The method of claim 5, And the fourth sidewall of the high voltage bobbin forms a guiding groove. The method of claim 1, The second body of the high voltage bobbin is provided with a plurality of insulating walls, each of the insulating wall, one of the insulating wall and the third side wall, and the other of the insulating wall and the fourth side wall are respectively slots therebetween. And a high voltage coil is wound in the slot. The method of claim 1, The outer protruding strip, the inner protruding strip, and the outer protruding post of each iron core are cubes. The method of claim 1, Further comprising at least another high voltage bobbin, each of the two iron cores further having another outer protruding post, wherein an outer protruding post of one of the iron cores is second through a third sidewall of the respective high voltage bobbin Inserted into the hollow portion, respectively positioned in the second hollow portion, wherein the outer protruding posts of the other iron cores are respectively inserted into the second hollow portion through the fourth sidewalls of the high voltage bobbin, respectively positioned in the second hollow portion Transformer structure.