Method for making magnetics assembly including transformer

Abstract

A method for making a magnetic assembly comprises the following steps: twisting a first to eighth magnetic wires to form a bundle of wires having a first end and an opposite second end; providing a magnetic core; winding the bundle of magnetic wires around the magnetic core; sorting the first end and the second end of the bundle of wires to form individual first ends and individual second ends of the first to eighth wires; picking out the second ends of the first wire and the second wire, and the first ends of the third wire and the fourth wire to form a center tap of a primary coil of a transformer; and picking out the second ends of the fifth wire and the sixth wire, and the first ends of the seventh wire and the eighth wire to form a center tap of a secondary coil of the transformer.

Claims

1. An magnetic assembly comprising: a printed circuit board forming opposite input pad region and output pad region and a core mounting region therebetween in a first direction, each of said input pad region and said output pad region including a plurality of conductive pads along a second direction perpendicular to said first direction; a toroidal core mounted upon the core mounting region; four pairs of wires wound upon the toroidal core and categorized with a positive input, a negative input, a positive output, and a negative output, each of the four pairs at least being twisted alone; the pair of the positive input and the pair of the negative input having corresponding first input ends respectively soldered to the corresponding conductive pads on the input pad region, approaching the core around position while winding thereon in opposite clockwise and counterclockwise directions with regard to a cross-section of said toroidal core, respectively, and gradually leaving away from each other along a surface path of said core in opposite clockwise and counterclockwise directions with regard to an elevational view of said toroidal core viewed along an axial direction, and finally reunited together and twisted together before corresponding second input ends of said pair of positive input and that of negative input being soldered to the corresponding conductive pad; similarly the pair of positive output and the pair of negative output having corresponding first output ends respectively soldered upon the corresponding conductive pads on the output region, approaching the core around another position while winding thereon in opposite clockwise and counterclockwise directions with regard to said cross-section of said toroidal core, respectively, and gradually leaving away from each other along said surface path of said core in opposite clockwise and counterclockwise directions with regard to the elevational view of said toroidal core viewed along the axial direction, and finally reunited together and twisted together before corresponding second output ends of said pair of positive output and that of negative output being soldered to the corresponding conductive pad; wherein the two pairs rotating in the same clockwise direction are further twisted together and the other two pairs rotating in the same counterclockwise direction are further twisted together.

2. The magnetic assembly as claimed in claim 1, wherein the conductive pad on which the first input ends are soldered, is located on the input pad region, while the conductive pad on which the second out put ends are soldered, is located on the output pad region.

3. The magnetic assembly as claimed in claim 2, wherein the first output ends and the second output ends are intercrossed before soldered upon the corresponding conductive pads, respectively.

4. The magnetic assembly as claimed in claim 1, wherein the two pairs rotating in the same clockwise direction are twisted simultaneously, and the two pairs rotating in a same counterclockwise direction are twisted simultaneously.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a top view of a magnetics assembly according to an embodiment of present invention;

(2) FIG. 2 is a top view of a transformer to be mounted on and a PCB shown in FIG. 1;

(3) FIG. 3 is a circuitry of a transformer mounted on and the PCB shown in FIG. 1;

(4) FIG. 4 is a bundle of wires having eight magnetic wires twisted together;

(5) FIG. 5 is a 2XN type RJ 45 connector using the magnetics assembly shown in FIG. 1;

(6) FIG. 6 is an exploded view of the connector shown in FIG. 5;

(7) FIG. 7 is a perspective view of a contact module shown in FIG. 5 and having the magnetics assembly shown in FIG. 1; and

(8) FIG. 8 is a circuitry of one port of the connector shown in FIG. 5.

DETAILED DESCRIPTION OF THE INVENTION

(9) Reference will now be made to the drawing figures to describe the present invention in detail.

(10) Referring to FIGS. 1-4, a magnetics assembly 100 according to an embodiment of present invention is shown. The magnetics assembly 100 comprises a printed circuit board (PCB) 200 and four transformers 1 mounted thereon. Each transformer 1 comprises a magnetic core 2 and a bundle of wires 3 winding around the magnetic core 2. The magnetic core 2 is shaped as a toroidal shaft extending along a circle locus around a central axial, the toroidal shaft defining a central opening 22, a top and a bottom faces perpendicular to the central axial. The bundle of wires 3 includes a first to eighth wires. The first and second wires are coated with red patent leather, the third and fourth wires are coated with blue patent leather, the fifth and sixth wires are coated with green patent leather, and the seventh and eighth wires are coated with glod patent leather.

(11) The bundle of wires 3 has a central portion with the first to eighth wires twisted together, a first end and an opposite second end. The central portion winds around the magnetic core 2 in one direction through the central opening 22 and around the toroidal shaft some times. The first end of the bundle of wires 3 extends out from central opening 22 through the top face and each wire has a corresponding first end therein. The second end of the bundle of wires 3 extends out from the central opening 22 of the magnetic core 2 through the bottom face, and each wire has a corresponding second end therein. The second ends of the first wire and the second wire, and the first ends of the third wire and the fourth wire are sorted out and twisted to form a central tap 36. The first ends of the first wire and the second wire are sorted out and twisted to form an input 33 of a primary coil of the transformer 1. The second ends of the third wire and the fourth wire are sorted out and twisted to form an output 34 of the primary coil of the transformer 1. The second ends of the fifth wire and the sixth wire, and the first ends of the seventh wire and the eighth wire are sorted out twisted to form a central tap 35. The first ends of the fifth wire and the sixth wire are sorted out and twisted to form an input 31 of a secondary coil of the transformer 1. The second ends of the seventh wire and the eighth wire are sorted out and twisted to form an output 32 of the secondary coil of the transformer 1.

(12) Since the first end of the bundle of wires 3 extends from the top face of the magnetic core 2 and the second end of the bundle of wires 3 extends from the bottom face of the magnetic core 2, it is quite clear that to sort out the red wire ends (first ends of the first and second wires) extending from the top face of the magnetic core 2 to form the input of primary coil, sort out the red wire ends extending from the bottom face of the magnetic core 2 and the blue wire ends extending from the top face of the magnetic core 2 to form the central tap of the primary coil, and sort out the blue wire ends extending from the bottom face of the magnetic core 2 to form the output of the primary coil. It is the same way to sort out the input, the output and the central tap of the secondary coil. In order to more accurately position a length of the coils winding around the core 2, the first end and the second end of the bundle of wires 3 could be first intercrossed, and then sorted out to form the inputs 31, 33, the outputs 32, 34 and the central taps 35, 36. However, this will make it quite troublesome to distinguish which ends of the wires should be the central taps 35, 36 or the inputs 31, 32 or the outputs 33, 34.

(13) The PCB 200 has a plurality of conductive pads 41-43, 51-53 arrayed in first row 4 and a second row 5. The input 33, the output 34 and the central tap 36 of the primary coil are soldered onto corresponding conductive pads 51, 52, 53 in the second row 5. The input 31, the output 32 and the central tap 35 of the secondary coil being soldered onto corresponding conductive pads 41, 42, 43 in the first row 4. It is clearly shown in FIG. 2 that the central tap 36 is soldered onto the conductive pad 53, and the central tap 35 of the secondary coil before the central tap 35 is soldered onto the conductive pad 43. Furthermore, the central tap 36 of the primary coil and the central tap 35 of the secondary coil are intercrossed at a place 365 so that they are positioned mutually before being soldered onto the conductive pads 51-53, 41-43 of the PCB 200.

(14) Through the forementioned connection between the inputs 31, 33, outputs 32, 34, and central taps 35, 36 of the primary coil and the secondary coil, the transformer 1 has two duplicated litz wires to carry each circuit of the primary coil or the secondary coil (clearly shown in FIG. 3). It could be understandable that if necessary, three or more duplicated litz wires could be used to carry each circuit of the transformer 1. Additionally, it is a significant advantage that the circuits of the transformer 1 are duplicated litz wires and all the litz wires are wound around the magnetic core in one time and then sorted out to form the central taps 35, 36, the inputs 31, 32 and the outputs 33, 34.

(15) Referring to FIGS. 5-8, a 2XN type RJ 45 connector 40 having eight magnetic assemblies 100 is shown. The magnetics assembly 100 further comprises four common mode chokes 56 (shown in FIG. 7) mounted on a side of the PCB 200 opposite to the transformers 1. The four common mode chokes 56 are mounted onto the PCB 200 through surface mounted technology and are respectively connected to corresponding transformers 1 by the PCB 200 (shown in FIG. 8). The stacked RJ45 connector 40 has two rows of mating ports 402, 404 stacked vertically. The connector 40 comprises a housing 46 and four contact modules 44 received in the housing 46. Each of the contact modules 44 has two magnetic assemblies 100 and two rows of mating contacts 442, 444 electrically connected to the two magnetic assemblies 100, respectively. The two rows of mating contacts 442, 444 respectively extend into each mating ports for making connection with a RJ 45 plug (not shown) inserted therein.

(16) The contact module 44 further comprise a center frame 48 supporting the two magnetic assemblies 100 and the mating contacts 442, 444. The frame 48 defines two cavities 480, 482 oppositely opened to receive the transformers 1 disposed on inner sides of the two PCBs 200.

(17) A method for making the magnetics assembly 100 comprises the following steps: (1) providing a first to eighth magnetic wires; (2) twisting the first to eighth magnetic wires to form a bundle of wire 3 having a first end and an opposite second end; (3) providing a magnetic core 2 shaped as a toroidal shaft extending along a circle locus around a central axial, the toroidal shaft defining a central opening 22, a top and a bottom faces perpendicular to the central axial; (4) winding the magnetic wires around the magnetic core 2 in one direction with the first end extending out from the central opening 22 through the top face of the magnetic core 2 and the second end extending out from the central opening 22 through the bottom face of the magnetic core 2; (5) untwisting the first end and the second end of the bundle of wires to form individual first ends and individual second ends of the first to eighth wires; (6) twisting the second ends of the first wire and the second wire, and the first ends of the third wire and the fourth wire to form the central tap 36 of a primary coil of the transformer 1, twisting the first ends of the first wire and the second wire to form the input 33 of the primary coil, twisting the second ends of the third wire and the fourth wire to form the output 34 of the primary coil; (7) twisting the second ends of the fifth wire and the sixth wire, and the first ends of the seventh wire and the eighth wire to form the central tap 35 of the secondary coil of the transformer 1, twisting the first ends of the fifth wire and the sixth wire to form the input 31 of the secondary coil, twisting the second ends of the seventh wire and the eighth wire to form the output 32 of the secondary coil; (8) intercrossing the central taps 35, 36 of the primary coil and the secondary coil to result a primary position mutually; (9) providing a printed circuit board 200 having an upper row and a lower row of conductive pads 51-53, 41-43, and soldering the inputs 31, 33, the outputs 32, 34 and the central tap 35, 36 onto respective conductive pads 41-43, 51-53 through thermal welding after step (8); and (10) providing four surface-mounted-type common mode chokes (CMCs) 56 and soldering the CMCs 56 onto a side of the PCB 200 opposite to the transformer 1 after step (9).

(18) The disclosure is illustrative only, changes may be made in detail, especially in matter of shape, size, and arrangement of parts within the principles of the invention.