The present invention relates to a transformer, and more particularly to a transformer having leakage inductance.
A transformer has become an essential electronic component for voltage regulation into required voltages for various kinds of electric appliances. Referring to
Since the leakage inductance of the transformer has an influence on the electric conversion efficiency of a power converter, it is very important to control leakage inductance. Related technologies were developed to increase coupling coefficient and reduce leakage inductance of the transformer so as to reduce power loss upon voltage regulation. In the transformer of
In the new-generation electric products (e.g. LCD televisions), a backlight module is a crucial component for driving the light source because the LCD panel fails to illuminate by itself. Generally, the backlight module comprises a plurality of discharge lamps and a power supply system for driving these lamps. The discharge lamps are for example cold cathode fluorescent lamps (CCFLs). These discharge lamps are driven by an inverter circuit of the power supply system. As the size of the LCD panel is gradually increased, the length and the number of the lamps included in the LCD panel are increased and thus a higher driving voltage is required. As a consequence, the transformer of the inverter circuit is usually a high-voltage transformer with leakage inductance. For electrical safety, the primary winding coil and the secondary winding coil of such a transformer are separated by a partition element of the bobbin. Generally, the current generated from the power supply system will pass through a LC resonant circuit composed of an inductor L and a capacitor C, wherein the inductor L is inherent in the primary winding coil of the transformer. At the same time, the current with a near half-sine waveform will pass through a power MOSFET (Metal Oxide Semiconductor Field Effect Transistor) switch. When the current is zero, the power MOSFET switch is conducted. After a half-sine wave is past and the current returns zero, the switch is shut off. As known, this soft switch of the resonant circuit may reduce damage possibility of the switch, minimize noise and enhance performance.
Referring to
For winding the primary winding coil 24 on the first bobbin piece 22, a first terminal of the primary winding coil 24 is firstly soldered on a pin 28a under the first base 26a. The primary winding coil 24 is then successively wound around the first bobbin piece 22 in the direction distant from the first side plate 26. Afterward, a second terminal of the primary winding coil 24 is returned to be soldered onto another pin 28b under the first base 26a. For winding the secondary winding coil 25 on the second bobbin piece 23, a first terminal of the secondary winding coil 25 is firstly soldered on a pin 29a under the second base 27a. The secondary winding coil 25 is then successively wound around the winding sections 23b of the second bobbin piece 23 in the direction distant from the second side plate 27. Afterward, a second terminal of the secondary winding coil 25 is returned to be soldered onto another pin 29b under the second base 27a. Moreover, due to the partition plate 23a of the second bobbin piece 23, the primary winding coil 24 is separated from the secondary winding coil 25, thereby maintaining an electrical safety distance and increasing leakage inductance of the transformer 2.
The winding structure of the transformer 2, however, still has some drawbacks. For example, the primary winding coil 24 and the secondary winding coil 25 are subject to electromagnetic induction in the main magnetic circuit. Since the transformer 2 has no branch magnetic circuit, the coupling effect is good but the leakage inductance is insufficient and fails to be adjusted. In other words, the transformer 2 is not suitable to be used in the resonant circuit. Moreover, the electromagnetic induction of the transformer 2 readily generates electromagnetic interference. The electromagnetic interference adversely affects neighboring electronic components or circuitry of the circuit board.
Therefore, there is a need of providing a transformer having leakage inductance so as to obviate the drawbacks encountered from the prior art.
It is an object of the present invention to provide a transformer having adjustable leakage inductance and reduced electromagnetic interference.
In accordance with an aspect of the present invention, there is provided a transformer having leakage inductance. The transformer includes a bobbin assembly, a primary winding coil, a first secondary winding coil, a second secondary winding coil, and a magnetic core assembly. The bobbin assembly includes a primary winding part, a first secondary winding part, a second secondary winding part and a channel. A first opening is formed in a bottom surface of the bobbin assembly and communicates with the channel. The primary winding coil is wound around the primary winding part. The first secondary winding coil is wound around the first secondary winding part. The second secondary winding coil is wound around the second secondary winding part. The magnetic core assembly is partially embedded into the channel of the bobbin assembly, and includes a first magnetic part and a second magnetic part. The second magnetic part includes a first extension post, and the first extension post is inserted into the first opening of the bobbin assembly.
In accordance with another aspect of the present invention, there is provided a transformer having leakage inductance. The transformer includes a bobbin assembly, a first primary winding coil, a second primary winding coil, a first secondary winding coil, a second secondary winding coil, and a magnetic core assembly. The bobbin assembly includes a first primary winding part, a second primary winding part, a first secondary winding part, a second secondary winding part and a channel. A first opening is formed in a bottom surface of the bobbin assembly and communicates with the channel. The first primary winding coil is wound around the first primary winding part. The second primary winding coil is wound around the second primary winding part. The first secondary winding coil is wound around the first secondary winding part. The second secondary winding coil is wound around the second secondary winding part. The magnetic core assembly is partially embedded into the channel of the bobbin assembly, and includes a first magnetic part and a second magnetic part. The second magnetic part includes a first extension post, and the first extension post is inserted into the first opening of the bobbin assembly.
The above contents of the present invention will become more readily apparent to those ordinarily skilled in the art after reviewing the following detailed description and accompanying drawings, in which:
The present invention will now be described more specifically with reference to the following embodiments. It is to be noted that the following descriptions of preferred embodiments of this invention are presented herein for purpose of illustration and description only. It is not intended to be exhaustive or to be limited to the precise form disclosed.
In this embodiment, the primary winding part 36, the first secondary winding part 37 and the second secondary winding part 38 of the bobbin assembly 31 are made of insulating material and integrally formed into a one-piece structure. The primary winding part 36 is arranged at the middle section of the bobbin assembly 31. The primary winding part 36 includes one or more partition plates 361, wherein multiple winding sections 362 are defined by the one or more partition plates 361. Every partition plate 361 has one or more notches 363. The primary winding coil 32 is successively wound around the winding sections 362 through the one or more notches 363.
The first secondary winding part 37 and the second secondary winding part 38 are disposed at two opposite sides of the bobbin assembly 31. In other words, the first secondary winding part 37 and the second secondary winding part 38 are disposed on bilateral sides of the primary winding part 36. The first secondary winding part 37 is separated from the primary winding part 36 by a first separation plate 313. The second secondary winding part 38 is separated from the primary winding part 36 by a second separation plate 314. Due to the first separation plate 313 and the second separation plate 314, the electrical safety distance between the primary winding coil 32 and the first secondary winding coil 33 and the electrical safety distance between the primary winding coil 32 and the second secondary winding coil 34 are maintained. In addition, the first secondary winding part 37 and the second secondary winding part 38 have a first side plate 315 and a second side plate 316, respectively. The first secondary winding part 37 includes one or more partition plates 371, wherein multiple winding sections 372 are defined by the one or more partition plates 371. The second secondary winding part 38 includes one or more partition plates 381, wherein multiple winding sections 382 are defined by the one or more partition plates 381. According to voltage dividing principle, the numbers of the winding sections 372 and 382 may be varied depending on the voltage magnitude. Every partition plate 371 has one or more notches 373. The first secondary winding coil 33 is successively wound around the winding sections 372 through the one or more notches 373. Every partition plate 381 has one or more notches 383. The second secondary winding coil 34 is successively wound around the winding sections 382 through the one or more notches 383.
In this embodiment, the first opening 312 is extended from the bottom surface 311 of the bobbin assembly 31 to the inner portion of the first separation plate 313 and communicates with the channel 39. Moreover, a second opening 319 is extended from the bottom surface 311 of the bobbin assembly 31 to the inner portion of the second separation plate 314 and communicates with the channel 39. The bobbin assembly 31 further comprises a first slot 317 and a second slot 318. The first slot 317 is extended from the bottom surface 311 of the bobbin assembly 31 to the inner portion of the first side plate 315 and communicates with a first end of the channel 39. The second slot 318 is extended from the bottom surface 311 of the bobbin assembly 31 to the inner portion of the second side plate 316 and communicates with a second end of the channel 39.
In this embodiment, the first separation plate 313 includes one or more bobbin bases (313a, 313b), the second separation plate 314 includes one or more bobbin bases (314a, 314b), the first side plate 315 includes one or more bobbin bases (315a, 315b), the second side plate 316 includes one or more bobbin bases (316a, 316b), and the partition plate 361 includes one or more bobbin bases (361a). Several pins 310 (e.g. L-shaped pins) are protruded from the bobbin bases 313a, 313b, 314a, 314b, 315a, 315b, 316a, 316b, 361a of the bobbin assembly 31. The pins 310 are inserted into corresponding conductive holes of a circuit board (not shown). In this embodiment, each pin 310 includes a first connecting part 310a and a second connecting part 310b, which are perpendicular to each other. In other words, the first connecting part 310a and the second connecting part 310b are respectively protruded from two adjacent surfaces of a corresponding bobbin base. The primary winding coil 32, the first secondary winding coil 33 and the second secondary winding coil 34 are connected to corresponding first connecting parts 310a of the pins 310. The second connecting parts 310b of the pins 310 are inserted into corresponding conductive holes of a circuit board (not shown). The first connecting parts 310a and the second connecting parts 310b of the pins 310 are made of conductive material such as copper or aluminum. The first connecting parts 310a and the second connecting parts 310b are integrally formed such that the pins 310 are L-shaped.
In this embodiment, the first magnetic part 351 of the magnetic core assembly 35 is a slab-type core magnetic part. The first magnetic part 351 is accommodated with the channel 39. The second magnetic part 352 of the magnetic core assembly 35 includes a slab portion 352b, a first lateral post 352c, a second lateral post 352d, the first extension post 352a and a second extension post 352e. The first lateral post 352c and the second lateral post 352d are perpendicularly protruded from a first end and a second end of the slab portion 352b, respectively. The first extension post 352a and the second extension post 352e are also perpendicularly protruded from the slab portion 352b. The first extension post 352a and the second extension post 352e are arranged between the first lateral post 352c and the second lateral post 352d. In some embodiments, the first extension post 352a and the second extension post 352e have a first width W1, respectively, and the first lateral post 352c and the second lateral post 352d have a second width W2, respectively, wherein the second width W2 is wider than the first width W1, and the first extension post 352a, the second extension post 352e, the first lateral post 352c, and the second lateral post 352d have the same length, the cross-section area of each of the first lateral post 352c and the second lateral post 352d is greater than the cross-section area of each of the first extension post 352a and the second extension post 352e. The first lateral post 352c is inserted into the first slot 317 of the bobbin assembly 31 and contacted with a first end 351a of the first magnetic part 351. The second lateral post 352d is inserted into the second slot 318 of the bobbin assembly 31 and contacted with a second end 351b of the first magnetic part 351. The first extension post 352a is inserted into the first opening 312 of the bobbin assembly 31 and spaced from the first magnetic part 351 by a gap. The second extension post 352e is inserted into the second opening 319 of the bobbin assembly 31 and spaced from the first magnetic part 351 by a gap.
When a voltage is applied to the primary winding coil 32, a current is inputted into the primary winding coil 32 such that electromagnetic induction is rendered on the primary winding coil 32. Meanwhile, an induction voltage and an induction current are respectively generated in the first secondary winding coil 33 and second secondary winding coil 34. As such, a main magnetic circuit generated by the primary winding coil 32, the first secondary winding coil 33 and second secondary winding coil 34 run through the first magnetic part 351 and the second magnetic part 352. That is, the magnetic line of force successively passes through the first lateral post 352c, the slab portion 352b, the second lateral post 352d and the first magnetic part 351 and then returns back to the second magnetic part 352. The first extension post 352a is arranged between the primary winding coil 32 and the first secondary winding coil 33. The second extension post 352e is arranged between the primary winding coil 32 and the second secondary winding coil 34. Since the first extension post 352a and the second extension post 352e are respectively inserted into the first opening 312 and the second opening 319 and separated from the first magnetic part 351 by a gap, a branch magnetic circuit is defined by the first extension post 352a and the second extension post 352e. Due to the main magnetic circuit and the branch magnetic circuit, the leakage inductance of the transformer 3 is increased and adjustable. As a consequence, the transformer of the present invention can be applied to any resonant circuit. Since the second magnetic part 352 is disposed on the bottom surface 311 of the bobbin assembly 31 and arranged between the bobbin assembly 31 and the circuit board 4, the electromagnetic interference generated by the transformer 3 has reduced influence on neighboring electronic components or circuitry of the circuit board 4.
For protecting the first secondary winding part 37 and the second secondary winding part 38, the transformer 3 further comprises one or more insulating covers.
After the bobbin assembly 31 is sheathed by the first insulating cover 51 and the second insulating cover 52, the first magnetic part 351 of the magnetic core assembly 35 is accommodated within the channel 39 and the second magnetic part 352 is disposed on the bottom surface 311 of the bobbin assembly 31. The slab portion 352b of the second magnetic part 352 is arranged between the bottom surface 311 of the bobbin assembly 31 and the circuit board 4. The first lateral post 352c is inserted into the first slot 317 of the bobbin assembly 31 and contacted with the first end 351a of the first magnetic part 351. The second lateral post 352d is inserted into the second slot 318 of the bobbin assembly 31 and contacted with the second end 351b of the first magnetic part 351. The first extension post 352a is inserted into the first opening 312 of the bobbin assembly 31 and spaced from the first magnetic part 351 by a gap. The second extension post 352e is inserted into the second opening 319 of the bobbin assembly 31 and spaced from the first magnetic part 351 by a gap. The first insulating cover 51 is arranged between the first secondary winding coil 33 and the second magnetic part 352 so as to maintain an electrical safety distance between the first secondary winding coil 33 and the second magnetic part 352. Similarly, the second insulating cover 52 is arranged between the second secondary winding coil 34 and the second magnetic part 352 so as to maintain an electrical safety distance between the second secondary winding coil 34 and the second magnetic part 352.
In this embodiment, the first primary winding part 66a, the second primary winding part 66b, the first secondary winding part 67 and the second secondary winding part 68 of the bobbin assembly 61 are made of insulating material and integrally formed into a one-piece structure. The first primary winding part 66a and the second primary winding part 66b are arranged at the middle section of the bobbin assembly 61. The first primary winding part 66a and the second primary winding part 66b are separated from each other by a partition plate 661.
The first secondary winding part 67 and the second secondary winding part 68 are disposed at two opposite sides of the bobbin assembly 61. In other words, the first secondary winding part 67 and the second secondary winding part 68 are disposed on bilateral sides of the first primary winding part 66a and the second primary winding part 66b. The first secondary winding part 67 is separated from the first primary winding part 66a by a first separation plate 613. The second secondary winding part 68 is separated from the second primary winding part 66b by a second separation plate 614. Due to the first separation plate 613 and the second separation plate 614, the electrical safety distance between the first primary winding coil 62a and the first secondary winding coil 63 and the electrical safety distance between the second primary winding coil 62b and the second secondary winding coil 64 are maintained. In addition, the first secondary winding part 67 and the second secondary winding part 68 have a first side plate 615 and a second side plate 616, respectively. The first secondary winding part 67 includes one or more partition plates 671, wherein multiple winding sections 672 are defined by the one or more partition plates 671. The second secondary winding part 68 includes one or more partition plates 681, wherein multiple winding sections 682 are defined by the one or more partition plates 681. According to voltage dividing principle, the numbers of the winding sections 672 and 682 may be varied depending on the voltage magnitude. Every partition plate 671 has one or more notches 673. The first secondary winding coil 63 is successively wound around the winding sections 672 through the one or more notches 673. Every partition plate 681 has one or more notches 683. The second secondary winding coil 64 is successively wound around the winding sections 382 through the one or more notches 683. In some embodiments, a rib 613c is formed on the first separation plate 613 for increasing the creepage distance between the first primary winding coil 62a and the first secondary winding coil 63. Similarly, a rib 614c is formed on the second separation plate 614 for increasing the creepage distance between the second primary winding coil 62b and the second secondary winding coil 64. Similarly, a rib 661b is formed on the partition plate 661 for increasing the creepage distance between the first primary winding coil 62a and the second primary winding coil 62b.
In this embodiment, the first opening 612 is extended from the bottom surface 611 of the bobbin assembly 61 to the inner portion of the first separation plate 613 and communicates with the channel 69. Moreover, a second opening 619 is extended from the bottom surface 611 of the bobbin assembly 61 to the inner portion of the second separation plate 614 and communicates with the channel 69. The bobbin assembly 61 further comprises a first slot 617 and a second slot 618. The first slot 617 is extended from the bottom surface 611 of the bobbin assembly 61 to the inner portion of the first side plate 615 and communicates with a first end of the channel 69. The second slot 618 is extended from the bottom surface 611 of the bobbin assembly 61 to the inner portion of the second side plate 616 and communicates with a second end of the channel 69.
In this embodiment, the first separation plate 613 includes one or more bobbin bases (613a, 613b), the second separation plate 614 includes one or more bobbin bases (614a, 614b), the first side plate 615 includes one or more bobbin bases (615a, 615b), the second side plate 616 includes one or more bobbin bases (616a, 616b), and the partition plate 661 includes one or more bobbin bases (661a). Several pins 610 (e.g. L-shaped pins) are protruded from the bobbin bases 613a, 613b, 614a, 614b, 615a, 615b, 616a, 616b, 661a of the bobbin assembly 61. The pins 610 are inserted into corresponding conductive holes of a circuit board (not shown). In this embodiment, each pin 610 includes a first connecting part 610a and a second connecting part 610b, which are perpendicular to each other. In other words, the first connecting part 610a and the second connecting part 610b are respectively protruded from two adjacent surfaces of a corresponding bobbin base. The first primary winding coil 62a, the second primary winding coil 62b, the first secondary winding coil 63 and the second secondary winding coil 64 are connected to corresponding first connecting parts 610a of the pins 610. The second connecting parts 610b of the pins 610 are inserted into corresponding conductive holes of a circuit board (not shown). The first connecting parts 610a and the second connecting parts 610b of the pins 610 are made of conductive material such as copper or aluminum. The first connecting parts 610a and the second connecting parts 610b are integrally formed such that the pins 610 are L-shaped.
In this embodiment, the first magnetic part 651 of the magnetic core assembly 65 is a slab-type core magnetic part. The first magnetic part 651 is accommodated with the channel 69. The second magnetic part 652 of the magnetic core assembly 65 includes a slab portion 652b, a first lateral post 652c, a second lateral post 652d, the first extension post 652a and a second extension post 652e. The first lateral post 652c and the second lateral post 652d are perpendicularly protruded from a first end and a second end of the slab portion 652b, respectively. The first extension post 652a and the second extension post 652e are also perpendicularly protruded from the slab portion 652b. The first extension post 652a and the second extension post 652e are arranged between the first lateral post 652c and the second lateral post 652d. In some embodiments, the first extension post 652a and the second extension post 652e have a first width W1, respectively, and the first lateral post 652c and the second lateral post 652d have a second width W2, respectively, wherein the second width W2 is wider than the first width W1, and the first extension post 652a, the second extension post 652e, the first lateral post 652c, and the second lateral post 652d have the same length, the cross-section area of each of the first lateral post 652c and the second lateral post 652d is greater than the cross-section area of each of the first extension post 652a and the second extension post 652e. The first lateral post 652c is inserted into the first slot 617 of the bobbin assembly 61 and contacted with a first end 651a of the first magnetic part 651. The second lateral post 652d is inserted into the second slot 618 of the bobbin assembly 631 and contacted with a second end 651b of the first magnetic part 651. The first extension post 652a is inserted into the first opening 612 of the bobbin assembly 61 and spaced from the first magnetic part 651 by a gap. The second extension post 652e is inserted into the second opening 619 of the bobbin assembly 361 and spaced from the first magnetic part 651 by a gap.
In some embodiments, a first concave part 615c and a second concave part 616c are respectively formed on the first side plate 615 and the second side plate 616. After the first magnetic part 651 and the second magnetic part 652 of the magnetic core assembly 65 are combined with the bobbin assembly 61, the first concave part 615c and the second concave part 616c are clamped by a clamping element (not shown) so as to fix the magnetic core assembly 65 on the bobbin assembly 61. Alternatively, the magnetic core assembly 65 is fixed on the bobbin assembly 61 by adhesive or an insulating tape.
From the above embodiment, the extension post of the second magnetic part is inserted into the opening of the bobbin assembly, arranged between the primary winding coil and the secondary winding coil, and separated from the first magnetic part by a gap, so that a branch magnetic circuit is defined by the extension post. The branch magnetic circuit could increase or adjust the leakage inductance of the transformer in order to be applied to various resonant circuits. Moreover, since the second magnetic part is arranged between the bottom surface of the bobbin assembly and the circuit board, the electromagnetic interference generated by the transformer has reduced influence on neighboring electronic components or circuitry of the circuit board.
While the invention has been described in terms of what is presently considered to be the most practical and preferred embodiments, it is to be understood that the invention needs not be limited to the disclosed embodiment. On the contrary, it is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims which are to be accorded with the broadest interpretation so as to encompass all such modifications and similar structures.
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98110941 A | Apr 2009 | TW | national |
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20100253458 A1 | Oct 2010 | US |