1. Field of the Invention
The present invention relates to transformer coils, and particularly relates to transformer coils including at least two windings wrapped around a coil shaft.
2. Description of the Related Art
The transformer coil disclosed in Japanese Unexamined Patent Application Publication No. 8-162336, for example, is known as a conventional transformer coil. FIG. 8 is a plan view of a transformer coil 500 disclosed in Japanese Unexamined Patent Application Publication No. 8-162336.
The transformer coil 500 includes a coil bobbin 502, a pin terminal 510, and a winding 520. The coil bobbin 502 is configured of a core 504, an upper flange 506, and a lower flange 508. The core 504 extends in a vertical direction. The upper flange 506 is connected to an upper end of the core 504. The lower flange 508 is connected to a lower end of the core 504.
In addition, a groove 512 that extends in the vertical direction is provided in a side surface of the lower flange 508. The pin terminal 510 protrudes downward from a bottom surface of the lower flange 508.
The winding 520 is wrapped around the core 504. Furthermore, the winding 520 is guided by the groove 512 and is drawn out from the bottom surface of the lower flange 508. Both ends of the winding 520 are wrapped around the pin terminal 510.
In the transformer coil 500 disclosed in Japanese Unexamined Patent Application Publication No. 8-162336, the winding 520 is covered by an insulative material. Accordingly, to connect the winding 520 and the pin terminal 510, the winding 520 is wrapped around the pin terminal 510 and is dipped in a solder liquid. At this time, the liquid surface of the solder liquid is located at a base of the pin terminal 510 (that is, at a location L0). The covering of the winding 520 is thus melted by heat from the solder liquid. As a result, the winding 520 and the pin terminal 510 are connected by the solder.
Incidentally, the solder liquid wets upward along the winding 520. There is thus a risk that the cover of the winding 520 located within the groove 512 will also be melted. Accordingly, in the transformer coil 500 disclosed in Japanese Unexamined Patent Application Publication No. 8-162336, a width of an upper portion of the groove 512 is smaller than a width of a lower portion of the groove 512. The solder liquid is suppressed from wetting upward within the groove 512 as a result.
However, with the transformer coil 500 disclosed in Japanese Unexamined Patent Application Publication No. 8-162336, there is a risk that the cover of the winding 520 located within the groove 512 will melt due to heat transmitted from the solder liquid to the winding 520.
Accordingly, preferred embodiments of the present invention provide a transformer coil capable of preventing a cover of a winding from melting in portion other than a portion that is wrapped around a terminal.
A transformer coil according to an aspect of various preferred embodiments of the present invention includes a bobbin including a core portion that extends in a predetermined direction, a flange portion that is provided at an end of the core portion on one side of the predetermined direction and extends from the core portion in a perpendicular or substantially perpendicular direction that is perpendicular or substantially perpendicular to the predetermined direction, and a projecting portion that projects toward the one side in the predetermined direction from a first surface on one side of the flange portion in the predetermined direction; two first terminals that project from the first surface of the flange portion toward the one side in the predetermined direction; and a first winding that is wrapped around the core portion and whose both ends are respectively wrapped around the two first terminals; wherein both ends of the first winding are respectively soldered to the two first terminals at a region between an end portion of the projecting portion on the one side in the predetermined direction and the first surface of the flange portion.
According to various preferred embodiments of the present invention, the covering of portions of a winding other than a portion wrapped around a terminal is prevented from melting.
The above and other elements, features, steps, characteristics and advantages of the present invention will become more apparent from the following detailed description of the preferred embodiments with reference to the attached drawings.
Hereinafter, transformer coils according to various preferred embodiments of the present invention will be described with reference to the drawings.
Hereinafter, the configuration of transformer coils according to preferred embodiments will be described with reference to the drawings.
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Here, a surface of the flange portion 24 on the positive direction side of the z-axis direction is called a surface S3. A surface of the side surface portion 24a on the negative direction side of the z-axis direction is called a surface S1. A surface of the side surface portion 24b on the negative direction side of the z-axis direction is called a surface S2. A surface of the side surface portion 24a on the negative direction side of the y-axis direction is called a side surface S4. A surface of the side surface portion 24b on the positive direction side of the y-axis direction is called a side surface S5.
Grooves 26a-26d that connect the surface S1 and the surface S3 are provided in the side surface S4 of the side surface portion 24a. The grooves 26a-26d extend in the z-axis direction, and are arranged in that order from the negative direction side toward the positive direction side of the x-axis direction. Grooves 28a-28d that connect the surface S2 and the surface S3 are provided in the side surface S5 of the side surface portion 24b. The grooves 28a-28d extend in the z-axis direction, and are arranged in that order from the negative direction side toward the positive direction side of the x-axis direction.
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The pin terminals 40a-40e are metal pins that extend from the surface S1 of the side surface portion 24a toward the negative direction side of the z-axis direction. The pin terminal 40a is provided farther toward the negative direction side of the x-axis direction than the groove 26a. The pin terminal 40b is provided between the groove 26a and the groove 26b. The pin terminal 40c is provided between the groove 26b and the groove 26c. The pin terminal 40d is provided between the groove 26c and the groove 26d. The pin terminal 40e is provided farther toward the positive direction side of the x-axis direction than the groove 26d. The pin terminals 40a-40e are preferably configured integrally with the bobbin 12 through resin molding, or are inserted into the bobbin 12 later.
The pin terminals 42a-42e are metal pins that extend from the surface S2 of the side surface portion 24b toward the negative direction side of the z-axis direction. The pin terminal 42a is provided farther toward the negative direction side of the x-axis direction than the groove 28a. The pin terminal 42b is provided between the groove 28a and the groove 28b. The pin terminal 42c is provided between the groove 28b and the groove 28c. The pin terminal 42d is provided between the groove 28c and the groove 28d. The pin terminal 42e is provided farther toward the positive direction side of the x-axis direction than the groove 28d. The pin terminals 42a-42e are preferably configured integrally with the bobbin 12 through resin molding, or are inserted into the bobbin 12 later.
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A conducting wire such as a polyurethane enameled wire, abbreviated as UEW, is used as the winding 17, for example. In other words, the surface of the winding 17 is covered with an insulative material. Although not shown in the drawings, an insulative tape is wrapped around the core portion 20 around which the winding 17 is wrapped.
Both ends of the winding 17 as described thus far are soldered to the pin terminals 42c and 42d, respectively. The soldering is performed preferably by dipping the pin terminals 42c and 42d around which the winding 17 is wrapped into a solder liquid. In
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A three-layer insulated wire, for example, is preferably used as the winding 16. In a three-layer insulated wire, a conductor is covered by three layers of an insulative film. As such, the winding 16 is better insulated than the winding 17. A diameter of the winding 16 is greater than a diameter of the winding 17. Although not shown in the drawings, an insulative tape is wrapped around the core portion 20 around which the winding 16 is wrapped.
A pitch between the portions of the winding 16 that are wrapped around the pin terminals 40b and 40c is equal or substantially equal to a pitch between the portions of the winding 17 that are wrapped around the pin terminals 42c and 42d. However, as mentioned earlier, the diameter of the winding 16 is greater than the diameter of the winding 17. Accordingly, the size of a gap in the z-axis direction between adjacent portions of the winding 16 at the pin terminals 40b and 40c is smaller than the size of a gap in the z-axis direction between adjacent portions of the winding 17 at the pin terminals 42c and 42d.
Both ends of the winding 16 as described thus far are soldered to the pin terminals 40b and 40c, respectively. The soldering is performed preferably by dipping the pin terminals 40b and 40c around which the winding 16 is wrapped into a solder liquid. In
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The core 14 is attached to the bobbin 12 by the core portion 14b being inserted into the hole H from the positive direction side of the z-axis direction. Likewise, the core 15 is attached to the bobbin 12 by the core portion 15b being inserted into the hole H from the negative direction side of the z-axis direction. As a result, a tip portion of the outer peripheral portion 14a and a tip portion of the outer peripheral portion 15a are joined, a tip portion of the outer peripheral portion 14c and a tip portion of the outer peripheral portion 15c are joined, and a tip portion of the core portion 14b and a tip portion of the core portion 15b are joined. The outer peripheral portions 14a, 14c, 14d, 15a, 15c, and 15d encircle the periphery of the coils of the windings 16 and 17. The core portions 14b and 15b pass through each coil interior of the windings 16 and 17.
The transformer coil 10 according to the present preferred embodiment prevents the covering of the portions of the windings 16 and 17 aside from the portions wrapped around the pin terminals 40b, 40c, 42c, and 42d from melting. More specifically, according to the transformer coil 500 disclosed in Japanese Unexamined Patent Application Publication No. 8-162336, when the pin terminal 510 is dipped into the solder liquid, the liquid surface of the solder liquid is located at the base of the pin terminal 510 (that is, the location L0). In this case, there is thus a risk that the cover of the winding 520 located within the groove 512 will be melted by heat transmitted from the solder liquid.
On the other hand, according to the transformer coil 10, the pin terminals 40b and 40c are dipped so that the liquid surface of the solder liquid is at the location L2 that is between the location L1 and the location L3. The location L2 is located farther toward the positive direction side of the z-axis direction than end portions, on the negative direction side of the z-axis direction, of the portions of the winding 16 that are wrapped around the pin terminals 40b and 40c. Accordingly, the portions of the winding 16 that are wrapped around the pin terminals 40b and 40c are also partially dipped in the solder liquid. The covering of the portions of the winding 16 dipped in the solder liquid is thus melted by heat from the solder liquid. Furthermore, the covering of a portion of the winding 16 farther toward the positive direction side of the z-axis direction than the location L2 is melted due to the solder liquid wetting upward along the winding 16 and heat from the solder liquid being transmitted to the winding 16 and the pin terminals 40b and 40c. As a result, the bare wire of the winding 16 and the pin terminals 40b and 40c are connected by the solder. Accordingly, both ends of the winding 16 are soldered to the pin terminals 40b and 40c, respectively, in a region between the end portion of the projecting portion 30 on the negative direction of the z-axis direction (the location L1) and the surface S1 of the side surface portion 24A (the location L3).
However, the location L2 of the liquid surface of the solder liquid is distanced from the location L3 of the surface S1, and thus the covering at a portion of the winding 16 near the location L3 is not melted. Accordingly, the covering of the portions of the winding 16 aside from the portions wrapped around the pin terminals 40b and 40c (for example, the portions located in the grooves 26b and 26c) is prevented from melting. Note that the covering of the portions of the winding 17 aside from the portions wrapper around the pin terminals 42c and 42d (for example, the portions located in the grooves 28b and 28c) are also prevented from melting for the same reasons.
Here, according to the IEC 950 standard, there must not be equal to or more than 6.4 mm of bare wire between the primary winding and a soldered area of the secondary winding in a transformer coil. According to the IEC 65 standard, there must not be equal to or more than 6.0 mm of bare wire, and according to the UL standard, there must not be equal to or more than 3.2 mm of bare wire. Accordingly, with the transformer coil 500 disclosed in Japanese Unexamined Patent Application Publication No. 8-162336, it has been necessary to, for example, increase the vertical thickness of the lower flange 508 of the coil bobbin 502 and increase the distance from the primary winding to the soldered area of the secondary winding in cases where the covering of the winding 520 located within the groove 512 will also melt. This increases the height of the transformer coil 500.
Accordingly, the transformer coil 10 prevents the covering of the portions of the windings 16 and 17 aside from the portions wrapper around the pin terminals 40b, 40c, 42c, and 42d from melting. As a result, the distance from the winding 17 to the soldered portion of the winding 16 (the portion where the cover has melted) is prevented from decreasing. As a result, it is not necessary to increase the height of the flange portion 24 in the z-axis direction. The transformer coil 10 has a lower profile as a result.
Furthermore, with the transformer coil 10, both ends of the winding 16 are preferably soldered to the pin terminals 40b and 40c at the same time as both ends of the winding 17 are soldered to the pin terminals 42c and 42d. More specifically, as shown in
Hereinafter, a transformer coil according to a first variation of a preferred embodiment of the present invention will be described with reference to the drawings.
The transformer coil 10a differs from the transformer coil 10 in terms of the shapes of the pin terminals 40a-40e. More specifically, in the transformer coil 10a, the pin terminals 40a-40e have a base portion A1, which has a diameter R1 and makes contact with the surface S1, and a tip portion A2, which has a diameter R2 that is smaller than the diameter R1 and is provided farther on the negative direction side of the z-axis direction than the base portion A1. The winding 16 is wrapped around both the base portion A1 and the tip portion A2.
In the transformer coil 10a configured as described above, the base portion A1 is wider than the diameter of the tip portion A2. Accordingly, the length of the winding 16 wrapped around the pin terminals 40b and 40c in the transformer coil 10a is greater than the length of the winding 16 wrapped around the pin terminals 40b and 40c in the transformer coil 10, even in the case where there is the same number of turns. Accordingly, heat from the solder liquid is transmitted through the transformer coil 10a toward the positive direction side in the z-axis direction slower in the transformer coil 10a than in the transformer coil 10. Accordingly, the covering of the winding 16 melts less easily in the transformer coil 10a than in the transformer coil 10.
Note that the pin terminals 42a-42e may also have the same shapes as the pin terminals 40a-40e. Furthermore, rather than widening the base portions A1 of the pin terminals 40a-40e and 42a-42e themselves, the base portions A1 of the pin terminals 40a-40e and 42a-42e may be widened using projections from the bobbin 12 or the like.
Hereinafter, a transformer coil according to a second variation of a preferred embodiment of the present invention will be described with reference to the drawings.
The transformer coil 10b differs from the transformer coil 10 in terms of the location of the surface S2 of the side surface portion 24b on the negative direction side of the z-axis direction. More specifically, in the transformer coil 10b, the surface S2 is located farther toward the negative direction side of the z-axis direction than the surface S1.
In the case where a conducting wire such as a polyurethane enameled wire, abbreviated as UEW, is used as the winding 17, it does not matter whether or not the covering of the portions located within the grooves 28b and 28c melts. Accordingly, the surface S2 may be located farther toward the negative direction side of the z-axis direction than the surface S1. As a result, the number of times the winding 17 is wrapped around the pin terminals 42c and 42d is reduced. In other words, the number of turns in the winding 17 around the pin terminals 42c and 42d is smaller than the number of turns in the winding 16 around the pin terminals 40b and 40c (is different, in other words). As a result, the process for wrapping the winding 17 around the pin terminals 42c and 42d is simplified. In addition, the number of turns is smaller, and thus the length of the winding 17 is reduced. Furthermore, an unnecessary inductance component is prevented from arising in the winding 17.
The transformer coil according to the present invention is not limited to the transformer coils 10, 10a, and 10b, and can be modified without departing from the essential spirit thereof.
Note that the winding 16 may be the primary winding and the winding 17 may be the secondary winding.
Various preferred embodiments of the present invention and variations thereof are useful in transformer coils, and are particularly useful to prevent a covering of portions of a winding aside from portions wrapper around a terminal from melting.
While preferred embodiments of the present invention have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing from the scope and spirit of the present invention. The scope of the present invention, therefore, is to be determined solely by the following claims.
Number | Date | Country | Kind |
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2012-171208 | Aug 2012 | JP | national |
Number | Date | Country | |
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Parent | PCT/JP2013/069868 | Jul 2013 | US |
Child | 14607169 | US |