1. Field of the Invention
The present invention relates to a coil device preferably used for a resonance transformer and the like.
2. Description of the Related Art
Coil devices are used in various electrical products for various uses. For instance, in a lighting circuit for a backlight of liquid crystal display, a leakage transformer, which is as a resonance transformer for driving a display device with higher voltages, is generally used.
For a leakage transformer, as shown in the following Reference 1 for instance, a horizontal-type coil device, to which a scroll axis of coil is arranged parallel to a mounting substrate surface of the coil device, is known. Such horizontal-type coil device has a problem that a leakage flux toward upward and downward directions with respect to the mounting substrate surface is large.
In order to make the leakage flux small, it is considered that top and bottom of the horizontal-type coil device is covered with aluminum board or aluminum foil. However, with this, heat dissipation may be deteriorated.
Further, for other leakage transformers, as shown in the following Reference 2 for instance, a vertical-type coil device, to which a scroll axis of coil is arranged perpendicular to a mounting substrate surface of the coil device, is known. With its configuration, it enables to make the leakage flux toward upward and downward directions with respect to the mounting substrate surface small.
However, for conventional coil devices, a primary coil and a secondary coil are composed of wires wound by normal regular winding. Particularly, for the secondary coil which produces a high voltage, there is a problem with voltage withstandability since the start of winding wire for a first layer and the end of winding wire for a second layer closely contact with each other, and the voltage differences between them get larger. Further, for the regular winding, it is a way to wind one wire in a spiral way for a first layer and then to wind back on the first layer from end to start of the first layer for a second layer. For the subsequent layers, the same process is applied.
Further, as the frequency of voltage applied to a coil device gets higher, there is a problem with the current flow since wires, which are adjacent to each other, exert effects on each other. Furthermore, for the coil devices used for a leakage transformer, it is important to stabilize leakage characteristics. However, for the conventional coil devices wherein wires are wound in regular winding, there is a problem with the stability of leakage characteristics.
The present invention has been made by considering the above circumstances, and a purpose of the present invention is to provide a coil device which is excellent in voltage withstandability and high frequency characteristics, and also excellent in stability of leakage characteristics.
In order to achieve the above purpose, a coil device according to the present invention comprises:
a first bobbin provided with a first winding part at an outer circumference to which a first wire composing either a primary coil or a secondary coil is wound; and
a second bobbin mounted on the outer circumference of said first bobbin and provided with a second winding part at an outer circumference to which a second wire composing the other one of said primary coil or said secondary coil is wound, wherein
a plurality of partition walls, separating portions of the wire which are adjacent to each other along the scroll axis of said first wire or said second wire, are formed on at least one of said first winding part or said second winding part along said scroll axis at predetermined intervals,
a section width of each section, which is along said scroll axis, separated by said partition walls is determined so that only one said wire can pass through,
a height of said partition walls is determined so that one or more of said wires can pass through, and
at least one connecting groove, connecting the sections which are adjacent to each other, is formed on each partition wall.
For coil devices according to the present invention, when winding the wire in two layers or more around the winding part on which partition walls are formed, winding the wire in two layers or more in one section and then winding the wire in two layers or more in next section, and subsequently winding the wire in two layers or more by moving the wire to the next sections through the connecting grooves. Thus, the voltage differences among portions of the wire overlapping each other in each section are small. Further, portions of the wire which are adjacent to each other in a direction of the scroll axis are insulated by partition walls, and that result in improvement of voltage withstandability and also improvement of high frequency characteristics.
Furthermore, in each section, the wire is wound so that only a single cross-section of the wire exists along the direction of scroll axis. Therefore, it becomes easier to prevent fluctuations of the winding number of the wire per layer, and that results in stability of leakage characteristics. Specifically, it becomes easy to strictly control the coupling coefficient K between a primary coil and a secondary coil. Further, the coil device of the present invention can be favorably used as a leakage transformer.
Further, the coil device of the present invention can be used as a vertical-type coil device wherein a scroll axis of coil is arranged perpendicular to a mounting substrate surface of the coil device. Therefore, it is easy to cool a core which is inserted into a hollow portion of first bobbin.
Preferably, the first wire arranged at an inner circumference side composes said secondary coil which produces a high voltage compared with said primary coil, and a plurality of partition walls are formed along said scroll axis on said first winding part.
In this case, by arranging the secondary coil which produces a high voltage at an inner circumference of the primary coil which produces a relatively low voltage, it becomes easy to insulate. Further, in this case, for said second winding part, second wires may be wound in regular winding. This is because the second wire composes a primary coil and relatively low voltage is applied.
It is preferable that said second bobbin can be divided at a dividing line which is parallel to said scroll axis. With this configuration, it becomes easy to arrange second bobbin at the outer circumference of first bobbin.
A first overall width of said first winding part which is in a direction of said scroll axis may be different from a second overall width of said second winding part which is in a direction of said scroll axis. By making the first overall width different from the second overall width, it enables to adjust a leakage characteristic. Further, even if equalizing the overall width of the first winding part and the second winding part, by making the number of winding layer of the first winding part and the second winding part different, it enables to adjust a leakage characteristic.
It is preferable that said connecting grooves, which are respectively formed on said partition walls, are arranged so that they enable to communicate linearly along the direction of said scroll axis. Further, it is preferable that two or more of said connecting grooves are respectively formed on each of partition walls. Any one of connecting grooves can be used as a passage for the wire movement among sections, and the other one of connecting grooves can be used as a passage that enables the start end of winding wire or final end of winding wire to lead to the terminal which is formed on one end of the scroll axis. If the passage for leading is linear, it enables to connect the end of the wire to the terminal by the most direct way.
At least one of said partition walls may be contacted with the inner surface of said second bobbin so as to align a position of said first winding part and said second winding part approximately concentrically. In this case, there is no need to apply extra members to align the positions of the first bobbin and the second bobbin.
The followings are the explanation of the present invention based on embodiments shown in FIGS.
As shown in
The core 12 of the coil device 10 forms a magnetic path where magnetic flux generated from coil, which is described later, passes. It is formed by assembling a pair of cores 12, 12 which are separately formed. These cores 12 have a symmetrical shape, and they are attached to each other, sandwiching the second bobbin 50 and the first bobbin 40 from upward and downward directions (Z-axis direction in
As shown in
Further, in Figures, Z-axis shows a height direction of the coil device 10, and it enables low height profile of the coil device as the height of Z-axis direction of the coil device 10 becomes lower. Furthermore, Y-axis and Z-axis are perpendicular to each other and also perpendicular to Z-axis. In this embodiment, as shown in
First bobbin 40 comprises an approximately rectangular planar first bobbin plate 42. A bottom side of first bobbin plate 42 is a mounting surface (mounting substrate surface) of the coil device. On an approximately intermediate position of the first bobbin plate 42, as shown in
On the upper side of the Z-axis direction of the first hollow cylinder 44, the first bobbin upper collar part 48 is integrally formed projecting, along the plane of the Y-X axis, from the first hollow cylinder 44 in a radial direction. At the four corners of the first bobbin upper collar part 48, a terminal block 49 is integrally formed, and each pair of first terminals 70 and 72 can be removably attached.
These terminals 70 and 72 are composed of, for instance, metal terminals. As will hereinafter be described, on the first terminal 70, a lead part 22a (refer to
As shown in
It is preferable that first bobbin plate 42, first hollow cylinder 44, first bobbin upper collar part 48, terminal block 49 and partition walls 46 of first bobbin 40 are integrally formed by an injection molding and the like.
A first through hole 44a, penetrating in the Z-axis direction, is formed inside the first hollow cylinder 44 of the first bobbin plate 42. Middle legs 14 of core 12 enter into the first through hole 44a from upward and downward of the Z-axis directions, and tip ends of middle legs 14 contact with each other at an approximately intermediate position of the Z-axis direction of the through hole 44a.
As shown in
Second bobbin 50 comprises a second hollow cylinder 54 which covers the inner coil 20 from outside. Further, on the outer circumference of the second hollow cylinder 54, a second bobbin lower collar part 52 and a second bobbin upper collar part 58 are formed, along the circumferential direction, in the Z-axis direction at predetermined intervals. The lower collar part 52 and the upper collar part 58 are provided parallel to the plane of the X-Y axis, extending parallel to the mounting surface.
The second winding part 55 is located between the lower collar part 52 and the upper collar part 58. As shown in
In the present embodiment, by changing a forming position and a forming interval of the upper collar part 52 and the lower collar part 58 which are formed on the outer circumference of the second hollow cylinder 54 of second bobbin 50, it enables to shorten the second overall width L2 of the second winding part 55 in a direction of scroll axis compared with the first overall width L1 of the first winding part 45 in a direction of scroll axis, as shown in
As shown in
As shown in
Second bobbin 50, which is divisible into two parts, comprising collar parts 52, 58 and second hollow cylinder 54 is integrally formed by an injection molding and the like. Further, cover member 60 can also be formed by an injection molding and the like.
As shown in
It is preferable that a height h1 of each partition wall 46 is higher than m×d1, if the total number that the wire will be wound for each section 47 is represented by “m”. With that, as shown in
Note that it is not necessary to contact the tops of all partition walls 46 with the inner surface of the second bobbin 50. The height of any one of partition walls, preferably two or more of the partition walls separating in a direction of the scroll axis may be set higher than the other partition walls to align the position, so that only those tops of partition walls contact with the inner surface of second bobbin 50. Alternatively, the positions of the first bobbin 40 and the second bobbin 50 may be aligned by members other than partition walls 46.
In such case, as shown with a dashed line in
The first wire 22 may be composed of a single wire, or may be composed of a strand wire. Further, it is preferable that the first wire 22 is composed of an insulating coating conductive wire. Although the outer diameter d1 of the wire 22 is not particularly limited, for instance, φ1.0 to φ3.0 mm is preferable when applying high current. For the second wire 32, it may be the same with the first wire 22. However, it may also be different from the first wire 22.
In this embodiment, high current is applied to the first wire 22 to compose a secondary coil of transformer. Therefore, the wire diameter of the first wire 22 is made larger compared with the second wire 32. However, the wire diameter is not particularly limited. It may be the same with the second wire 32, or conversely, it may also be different from the second wire 32. Further, for the materials of the first wire 22 and the second wire 32, they may be the same with each other, or they may also be different from each other.
In the present embodiments as shown in
On the other hand, as previously mentioned, in the second bobbin 50, the second wire 32 (321 to 32n) compositing the outer coil 30 which serves as a primary coil is wound by regular winding around the second winding part 55. For the regular winding, it is a way to wind the wire for a first layer and then subsequently wind the wire for a second layer. With this, the wire 321 which is the start end of winding wire for a first layer and the wire 32n which is the final end of winding wire overlap. In the present embodiment, the outer coil 30 composes a primary coil of transformer. Therefore, the outer coil has a low voltage compared with the inner coil 20 which serves as a secondary coil, and there are no problems with the regular winding.
As shown in
Coil device 10 according to the present embodiment is produced by assembling each part shown in
Next, the first wire 22 is wound around the outer circumference of first hollow cylinder 44 of first bobbin 40 to form the inner coil 20. Although the first wire 22 used to form the inner coil 20 is not particularly limited, litz wire and the like are preferably used. Further, a lead part 22a which is a terminal portion of the first wire 22 when forming the inner coil 20 is tangled with a part of the first terminal 70 and soldered to connect.
Next, the second bobbin 50 is mounted on the first bobbin 40 wherein the inner coil 20 is formed. At the outer circumference of the second hollow cylinder 54 of the second bobbin 50, the second wire 32 composing the outer coil 30 is wound.
After that, a cover 60 is attached to both sides of the Y-axis direction of the second bobbin 50, and then core 12 is mounted from upward and downward directions of the Z-axis direction. Specifically, tip ends of middle legs 14, 14 and tip ends of side legs 16, 16 of core 12 are connected together. Further, there may be a gap between tip ends of middle legs 14, 14.
As for a material of core 12, although soft magnetic materials such as metal, ferrite and the like are exemplified, it is not particularly limited. The core 12 is fixed to the second bobbin 50 and the first bobbin 40 by applying a bonding adhesive or by winding its outer circumference with a tape-shaped member 80. Further, after the series of assembling process, varnish impregnation may be performed to coil device 10. With these processes, coil device 10 according to the present embodiment can be produced.
Coil device 10 is a vertical type, wherein the Z-axis direction (flux flowing direction) of middle legs 14 is vertical to the mounting surface. For the vertical type of coil device 10, base portions 13, 13 of core 12 are placed upward and downward directions of the Z-axis of coils 20, 30, and that these base portions 13, 13 suppress leakage flux toward upward and downward directions. Therefore, leakage flux of coil device 10 upward and downward directions can be suppressed effectively, compared to a horizontal type wherein upward and downward directions of coil are hardly shielded by core.
Therefore, the coil device 10 can prevent occurrence of eddy currents on surrounding constructional materials and the like, without implementing aluminum shield and the like. Further, the coil device 10 can decrease occurrence of heat and noise associated with the occurrence of eddy current.
Further, the coil device does not require a shield to shield leakage flux, and therefore it can obtain a favorable heat dissipation characteristic. Furthermore, the coil device 10 provides short length middle leg 14 and side legs 16, 16 of core 12, and that enables to prevent damages of core 12 caused by external impact and the like.
Further, for a tape-shaped member 80, it is preferable that it is composed of materials excellent in pyroconductivity, and more preferably excellent in insulation characteristics. Specifically, for a tape-shaped member 80, it is composed of, for instance, metals such as aluminium, copper and stainless, or alloys thereof, or resin materials excellent in pyroconductivity such as PPS resin.
Further, in the present embodiment, the combination of the first bobbin 40 and the second bobbin 50 is covered from the outside by respective base portions 13, 13 and side legs 16, 16 of core 12. With this structure, it enables to prevent leakage flux. The X-axis direction width of base portions 12, 12 and side legs 16, 16 may be the same or different, with respect to the X-axis direction length of middle legs 14, 14 of core 12. However, by making them approximately the same, it enables easily to adjust leakage characteristics.
For the coil device 10 according to the present embodiment, as shown in
Further, in each section 47, the wire 22 is wound so that only a single wire 221 to 22n exists along the direction of the scroll axis. With this, it becomes easier to prevent fluctuations of the winding number of the wire 22 per layer, and that results in stability of leakage characteristics. Specifically, it becomes easy to strictly control the coupling coefficient K between the outer coil 30 composing a primary coil and the inner coil 20 composing a secondary coil. With that, the coil device 10 of the present embodiment can be favorably used as a leakage transformer.
Further, the coil device 10 of the present embodiment can be used as a vertical-type coil device, to which a scroll axis of coil is arranged perpendicular to a mounting substrate surface of the coil device. Therefore, it is easy to cool a core 12 which is inserted into a hollow portion of the first bobbin 40.
Furthermore, in the present embodiment, the first wire 20 arranged at the inner circumference composes a secondary coil (inner coil 20) which produces a high voltage, compared with the primary coil of the transformer. With this, it becomes easy to insulate by arranging the secondary coil (inner coil 20) which produces a high voltage at the inner side of the primary coil (outer coil 30) which produces a relatively low voltage. Further, for the second winding part 55, the second wire 32 is wound by normal regular winding. However, there are no problems with that since the second wire 32 composes the outer coil 30 which serves as a primary coil to which a relatively low voltage is applied.
Moreover, in the present embodiment, as shown in
In addition, in the present embodiment, as shown in
Further, in the present invention, although connecting grooves 46a respectively formed on the partition walls 46 are not necessarily arranged linearly along the direction of the scroll axis, it is preferable that they are arranged to communicate linearly as shown in
For the coil device 10a according to the second embodiment shown in
In this coil device 10a, one or more of partition walls 56 are formed in the middle of the second bobbin in a direction of the scroll axis, and they divide the second winding part 55 into two or more sections 57 along the direction of the scroll axis. In each section 57, the second wires 321 to 32k and 32k+1 to 32n are wound by regular winding. On each of the partition walls 56, connecting grooves 56a are formed one or more in the circumferential direction. The connecting grooves 56a function similarly with the connecting grooves 46a.
In the coil device 10a of this embodiment, it enables to separately arrange the outer coil 30 which composes a primary coil. Further, the primary coil which is separately arranged for each section 57 may be an independent separated coil respectively composed of different wires.
In the first embodiment, as shown in
With this, the effects of heat dissipation from coils 20 and 30 can be expected. The reason is that the heat transfer characteristics of not only coil 20 but also of coil 30 are improved by providing heat dissipation parts at the lower end of the coil device 10b. Further, in the embodiment shown in
Further, as with the coil device 10c shown in
For the coil device 10d shown in
Further, in the above-mentioned embodiment, it is not necessary to align the positions of the outer coil 30 and the inner coil 20 concentrically, and it may be displaced in order to adjust the leakage characteristics.
Number | Date | Country | Kind |
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2012-130695 | Jun 2012 | JP | national |
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