TRANSFORMER

TECHNICAL FIELD

The present disclosure relates to a transformer.

BACKGROUND

There is a known transformer in which a primary coil and a secondary coil included therein are both stacked. For example, JP 2015-192082A discloses a thin transformer in which a primary coil and a secondary coil are disposed in the same plane. In this thin transformer, a plurality of planar coils are arranged one on top of one another.

However, with the configuration described in JP 2015-192082A, the primary coil and the secondary coil are provided in the same plane, and therefore the same plane in which these coils are disposed requires a wide area. On the other hand, simply stacking the primary coil and the secondary coil is likely to result in a significant leakage flux in their respective end portions. When a leakage flux is increased, the leakage inductance is increased.

Therefore, it is an object of the present disclosure to provide a transformer including stacked primary and secondary coils with a reduced leakage inductance, in which the leakage inductance is reduced.

SUMMARY

A transformer according to the present disclosure includes a primary winding and a secondary winding that are insulated from each other, the secondary winding including a first coil and a second coil that are conductively connected to each other, the primary winding including a third coil, and all of the first coil, the second coil, and the third coil at least partially encircling one axis extending along a first direction.

The first coil, the second coil, and the third coil are stacked in the first direction. The first coil includes a first end and a second end. The second coil includes a third end and a fourth end. The secondary winding further includes a first conductor and a second conductor.

The first conductor is sandwiched between the first end and the third end in the first direction so as to be conductively connected to the first end and the third end. The second conductor is sandwiched between the second end and the fourth end in the first direction so as to be conductively connected to the second end and the fourth end. A second direction is orthogonal to the first direction.

The first end and the second end are arranged adjacent to, but not in contact with, each other in the second direction. The third end and the fourth end are arranged adjacent to, but not in contact with, each other in the second direction. The first conductor and the second conductor are arranged adjacent to, but not in contact with, each other in the second direction.

A first position is different from at least one of a second position and a third position. The first position is a position in the second direction of a boundary between the first conductor and the second conductor. The second position is a position in the second direction of a boundary between the first end and the second end. The third position is a position in the second direction of a boundary between the third end and the fourth end.

ADVANTAGEOUS EFFECTS OF INVENTION

The transformer according to the present disclosure includes stacked primary and secondary coils, in which the leakage inductance is reduced.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a plan view illustratively depicting the configuration of a transformer according to Embodiment 1.

FIG. 2 is a perspective view illustratively depicting the configuration of the transformer according to Embodiment 1.

FIG. 3 is a perspective view illustratively depicting the configuration of a core.

FIG. 4 is an exploded perspective view illustratively depicting a primary winding and a secondary winding.

FIG. 5 is a side view illustratively depicting the configuration of the transformer according to Embodiment 1.

FIG. 6 is a cross-sectional view illustratively depicting the configuration of the secondary winding.

FIG. 7 is a circuit diagram illustratively depicting a converter in which the transformer according to Embodiment 1 is used.

FIG. 8 is a plan view illustratively depicting the configuration of a transformer according to Embodiment 2.

FIG. 9 is an exploded perspective view illustratively depicting a primary winding and a secondary winding.

FIG. 10 is a cross-sectional view illustratively depicting the configuration of the secondary winding.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

First, aspects of the present disclosure will be listed and described.

The present disclosure is as follows.

A transformer includes a primary winding and a secondary winding that are insulated from each other, the secondary winding including a first coil and a second coil that are conductively connected to each other, the primary winding including a third coil. All of the first coil, the second coil, and the third coil at least partially encircle one axis extending along a first direction.

Due to the first position being different from at least one of the second position and the third position, the action of increasing the magnetic resistance to the leakage flux occurs, resulting in a reduction in the leakage flux, and hence the leakage inductance.

It is preferable that the secondary winding further includes a third conductor, the first coil further includes a fifth end, the second coil further includes a sixth end, the fifth end and the second end are arranged adjacent to, but not in contact with, each other in the second direction, the sixth end and the fourth end are arranged adjacent to, but not in contact with, each other in the second direction, the third conductor is sandwiched between the fifth end and the sixth end in the first direction so as to be conductively connected to the fifth end and the sixth end, the third conductor and the second conductor are arranged adjacent to, but not in contact with, each other in the second direction, a fourth position is different from at least one of the first position and the second position, and the fourth position is a position in the second direction of a boundary between the third conductor and the second conductor. The reason being that the fifth end and the sixth end are center taps of the secondary winding.

It is preferable that the third coil is sandwiched between the first coil and the second coil in the first direction, and the third coil, the first conductor, and the second conductor are located aligned in the first direction. The reason being that this reduces the leakage flux.

Specific examples of the transformer according to the present disclosure will be described below with reference to the drawings. It should be noted that the present disclosure is not limited to these examples, but is defined by the claims, and is intended to include all modifications which fall within the scope of the claims and the meaning and scope of equivalents thereof.

Embodiment 1

In the following, a transformer according to Embodiment 1 will be described. FIG. 1 is a plan view illustratively depicting the configuration of a transformer 100 according to Embodiment 1. The transformer 100 includes a core 5.

FIG. 2 is a perspective view illustratively depicting the configuration of the transformer 100. However, to facilitate viewing, FIG. 2 only depicts a portion located on the core 5 side relative to a position indicated by the line CC in FIG. 1.

FIG. 3 is a perspective view illustratively depicting the configuration of the core 5. The core 5 is a so-called EI core. The core 5 includes an I-core 51 and an E-core 52. The E-core 52 includes three legs 501, 502, and 503. The legs 501, 502, and 503 are arranged along a second direction X. The leg 502 is located between the legs 501 and 503. The second direction X is orthogonal to a first direction Z.

The transformer 100 includes a primary winding 1 and a secondary winding 2. The primary winding 1 includes third coils 11, 12, 13, and 14. The secondary winding 2 includes a first coil 21 and a second coil 22. The first coil 21, the second coil 22, and the third coils 11, 12, 13, and 14 are stacked in the first direction Z. The number of layers in which the third coils of the primary winding 1 are stacked is not limited to four.

All of the first coil 21, the second coil 22, and the third coils 11, 12, 13, and 14 at least partially encircle an axis J. The axis J is a virtual axis passing through the leg 502 along the first direction Z, and is indicated by the dot-dash line in all of the drawings.

The first coil 21 includes an encircling portion 210, and ends 21a and 21c. The encircling portion 210 encircles the leg 502, and hence the axis J. The ends 21a and 21c extend continuously from the encircling portion 210, and are arranged adjacent to, but not in contact with, each other in the second direction X. Hereinafter, being arranged in this manner is expressed as being “adjacent to each other in a non-contact manner”. A boundary 21ac is a boundary between the ends 21a and 21c in the second direction X.

The second coil 22 includes an encircling portion 220, and ends 22b and 22c. The encircling portion 220 encircles the leg 502, and hence the axis J. The ends 22b and 21c extend continuously from the encircling portion 220, and are adjacent to each other in a non-contact manner in the second direction X. A boundary 22bc is a boundary between the ends 22b and 22c in the second direction X.

In Embodiment 1 and Embodiment 2, which will be described below, a third direction Y is introduced that is orthogonal to both the first direction Z and the second direction X. The encircling portion 210 is located on the third direction Y side relative to the ends 21a and 21c. The encircling portion 220 is located on the third direction Y side relative to the ends 22a and 22c.

The first coil 21 encircles the leg 502 once, excluding the boundary 21ac.

The second coil 22 encircles the leg 502 once, excluding the boundary 22bc. The third coils 11, 12, 13, and 14 encircle the leg 502 a plurality of times.

FIG. 4 is an exploded perspective view illustratively depicting the primary winding 1 and the secondary winding 2 in the first direction Z. In FIG. 4, the core 5 is omitted. Also in FIG. 4, the region located on the core 5 side relative to the position indicated by the line CC is shown, as in the case of FIG. 2.

In the first direction Z, the second coil 22, the third coils 14, 13, 12, 11, and the first coil 21 are stacked in this order.

The third coil 11 includes ends 11d and 11e. The third coil 12 includes ends 12d and 12e. The third coil 13 includes ends 13d and 13e. The third coil 14 includes ends 14d and 14e.

In the primary winding 1, the third coils 11, 12, 13, and 14 are connected in series in this order. The end 11e is connected to the end 12e by a conductor 112. The conductor 112 is sandwiched between the ends 11e and 12e in the first direction Z so as to be conductively connected to the ends 11e and 12e. The end 12d is connected to the end 13e by a conductor 123. The conductor 123 is sandwiched between the ends 12d and 13e in the first direction Z so as to be conductively connected to the ends 12d and 13e. The end 13d is connected to the end 14e by a conductor 134. The conductor 134 is sandwiched between the ends 13d and 14e in the first direction Z so as to be conductively connected to the ends 13d and 14e. The ends 11d and 14d function as opposite ends of the primary winding 1. The ends 11d and 14d are located on the third direction Y side relative to the third coils 12 and 13.

FIG. 5 is a side view illustratively depicting the configuration of the transformer 100. FIG. 5 shows a side as viewed from a direction opposite to the third direction Y. The hatching of the conductors 112, 123, and 134 is provided for the sake of convenience in order to improve viewability, rather than to indicate a cross section.

The first coil 21 and the second coil 22, and the third coils 11, 12, 13, and 14 can each be realized in the form of a conductive pattern in a printed circuit board 60 in which a plurality of insulating layers are stacked. The conductive pattern is provided on a boundary or a surface of a stacked insulating layer. Each of the conductors 112, 123, and 134 can be realized by a via hole that provides conductive connection in the corresponding insulating layer in the thickness direction. In FIGS. 1, 2, and 4, the insulating layers are omitted. By only depicting the contour of the printed circuit board 60 with a dot-dash line in FIG. 5, the viewability of the conductors 112, 123, and 134 is enhanced.

The secondary winding 2 includes conductor groups 211, 212, 213, and 214. The conductor group 211 includes conductors 211a, 211b, and 211c. The conductor group 212 includes conductors 212a, 212b, and 212c. The conductor group 213 includes conductors 213a, 213b, and 213c. The conductor group 214 includes conductors 214a, 214b, and 214c.

FIG. 6 is a cross-sectional view illustratively depicting the configuration of the secondary winding 2. FIG. 6 shows a cross section seen at a position indicated by the line DD shown in FIG. 1 as viewed along the third direction Y.

The end 21a and the end 21c are arranged in a non-contact manner across the boundary 21ac along the second direction X. The conductor 211a and the conductor 211c are arranged in a non-contact manner across a boundary 211ac along the second direction X. The conductor 212a and the conductor 212c are arranged in a non-contact manner across a boundary 212ac along the second direction X. The conductor 213a and the conductor 213c are arranged in a non-contact manner across a boundary 213ac along the second direction X. The conductor 214a and the conductor 214c are arranged in a non-contact manner across a boundary 214ac along the second direction X. The end 22a and the end 22c are arranged in a non-contact manner across a boundary 22ac along the second direction X.

The end 21c and the end 21b are arranged in a non-contact manner across a boundary 21bc along the second direction X. The conductor 211c and the conductor 211b are arranged in a non-contact manner across a boundary 211bc along the second direction X. The conductor 212c and the conductor 212b are arranged in a non-contact manner across a boundary 212bc along the second direction X. The conductor 213c and the conductor 213b are arranged in a non-contact manner across a boundary 213bc along the second direction X. The conductor 214c and the conductor 214b are arranged in a non-contact manner across a boundary 214bc along the second direction X. The end 22c and the end 22b are arranged in a non-contact manner across the boundary 22bc along the second direction X.

In FIGS. 2 and 4, some or all of the reference numerals of the above-described boundaries are omitted in order to avoid complication of the illustration.

A conductor 611a is sandwiched between the end 21a and the conductor 211a in the first direction Z so as to be conductively connected to the end 21a and the conductor 211a. The conductor 611a can be realized by a via hole formed in the insulating layer sandwiched between the end 21a and the conductor 211a.

A conductor 612a is sandwiched between the conductor 211a and the conductor 212a in the first direction Z so as to be conductively connected to the conductor 211a and the conductor 212a. The conductor 612a can be realized by a via hole formed in the insulating layer sandwiched between the conductor 211a and the conductor 212a.

A conductor 623a is sandwiched between the conductor 212a and the conductor 213a in the first direction Z so as to be conductively connected to the conductor 212a and the conductor 213a. The conductor 623a can be realized by a via hole formed in the insulating layer sandwiched between the conductor 212a and the conductor 213a.

A conductor 634a is sandwiched between the conductor 213a and the conductor 214a in the first direction Z so as to be conductively connected to the conductor 213a and the conductor 214a. The conductor 634a can be realized by a via hole formed in the insulating layer sandwiched between the conductor 213a and the conductor 214a.

A conductor 642a is sandwiched between the conductor 214a and the end 22a in the first direction Z so as to be conductively connected to the conductor 214a and the end 22a. The conductor 642a can be realized by a via hole formed in the insulating layer sandwiched between the conductor 214a and the end 22a.

A conductor 611b is sandwiched between the end 21b and the conductor 211b in the first direction Z so as to be conductively connected to the end 21b and the conductor 211b. The conductor 611b can be realized by a via hole formed in the insulating layer sandwiched between the end 21b and the conductor 211b.

A conductor 612b is sandwiched between the conductor 211b and the conductor 212b in the first direction Z so as to be conductively connected to the conductor 211b and the conductor 212b. The conductor 612b can be realized by a via hole formed in the insulating layer sandwiched between the conductor 211b and the conductor 212b.

A conductor 623b is sandwiched between the conductor 212b and the conductor 213b in the first direction Z so as to be conductively connected to the conductor 212b and the conductor 213b. The conductor 623b can be realized by a via hole formed in the insulating layer sandwiched between the conductor 212b and the conductor 213b.

A conductor 634b is sandwiched between the conductor 213b and the conductor 214b in the first direction Z so as to be conductively connected to the conductor 213b and the conductor 214b. The conductor 634b can be realized by a via hole formed in the insulating layer sandwiched between the conductor 213b and the conductor 214b.

A conductor 642b is sandwiched between the conductor 214b and the end 22b in the first direction Z so as to be conductively connected to the conductor 214b and the end 22b. The conductor 642b can be realized by a via hole formed in the insulating layer sandwiched between the conductor 214b and the end 22b.

A conductor 611c is sandwiched between the end 21c and the conductor 211c in the first direction Z so as to be conductively connected to the end 21c and the conductor 211c. The conductor 611c can be realized by a via hole formed in the insulating layer sandwiched between the end 21c and the conductor 211c.

A conductor 612c is sandwiched between the conductor 211c and the conductor 212c in the first direction Z so as to be conductively connected to the conductor 211c and the conductor 212c. The conductor 612c can be realized by a via hole formed in the insulating layer sandwiched between the conductor 211c and the conductor 212c.

A conductor 623c is sandwiched between the conductor 212c and the conductor 213c in the first direction Z so as to be conductively connected to the conductor 212c and the conductor 213c. The conductor 623c can be realized by a via hole formed in the insulating layer sandwiched between the conductor 212c and the conductor 213c.

A conductor 634c is sandwiched between the conductor 213c and the conductor 214c in the first direction Z so as to be conductively connected to the conductor 213c and the conductor 214c. The conductor 634c can be realized by a via hole formed in the insulating layer sandwiched between the conductor 213c and the conductor 214c.

A conductor 642c is sandwiched between the conductor 214c and the end 22c in the first direction Z so as to be conductively connected to the conductor 214c and the end 22c. The conductor 642c can be realized by a via hole formed in the insulating layer sandwiched between the conductor 214c and the end 22c.

With such conductive connection, both the end 21a and the end 22a function as one end of the secondary winding 2, both the end 21b and the end 22b function as the other end of the secondary winding 2, and both the end 21c and the end 22c function as a center tap of the secondary winding 2.

As compared with a configuration in which the primary coil and the secondary coil are provided in the same plane, such as the configuration disclosed in JP 2015-192082A, the area extending in the second direction X and the third direction Y of the transformer 100 can be reduced because the primary winding 1 and the secondary winding 2 are stacked in the first direction Z. This is advantageous in reducing the size of the transformer.

Upon applying a voltage to the ends 11d and 14d of the primary winding 1, a current flows through the primary winding 1, and a magnetic flux is generated from the current. This magnetic flux has a component constituting a so-called leakage flux, which is not interlinked with the secondary winding 2.

A first component of the leakage flux is a magnetic flux that passes between the first coil 21 and the third coil 11 in the first direction Z, and between the second coil 22 and the third coil 14 in the first direction Z, and that is not interlinked with either of the first coil 21 and the second coil 22.

A second component of the leakage flux is a magnetic flux that passes through the boundaries 21ac, 211ac, 212ac, 213ac, 214ac, and 22ac in this order, or in the reverse order.

A third component of the leakage flux is a magnetic flux that passes through the boundaries 21bc, 211bc, 212bc, 213bc, 214bc, and 22bc in this order, or in the reverse order.

The second component of the leakage flux moves back and forth in a region surrounded by a closed circuit obtained as a result of the ends 21a and 22c of the secondary winding 2 being connected to each other outside the transformer 100 via a load or directly. The third component of the leakage flux moves back and forth in a region surrounded by a closed circuit obtained as a result of the ends 21b and 22c of the secondary winding 2 being connected to each other outside the transformer 100 via a load or directly.

Accordingly, in view of reducing the second component of the leakage flux in order to reduce the leakage flux, it is desirable to increase the magnetic resistance to the second component in a path extending from the boundary 21ac to the boundary 22ac via the boundaries 211ac, 212ac, 213ac, and 214ac. In view of reducing the third component of the leakage flux in order to reduce the leakage flux, it is also desirable to increase the magnetic resistance to the third component in a path extending from the boundary 21bc to the boundary 22bc via the boundaries 211bc, 212bc, 213bc, and 214bc.

In the second direction X, the boundaries 21ac, 211ac, 212ac, 213ac, 214ac, and 22ac are at positions x2, x1, x3, x1, x3, and x2, respectively. Also, the positions x1, x2, and x3 are all different from one another. Accordingly, the second component of the leakage flux generally flows in the first direction Z or a direction opposite thereto, but flows in a serpentine manner along the second direction X. Such a serpentine magnetic path increases the magnetic resistance to the second component of the leakage flux.

In the second direction X, the boundaries 21bc, 211bc, 212bc, 213bc, 214bc, and 22bc are at positions x5, x4, x6, x4, x6, and x5, respectively. Also, the positions x4, x5, and x6 are all different from one another. Accordingly, the third component of the leakage flux generally flows in the first direction Z or a direction opposite thereto, but flows in a serpentine manner along the second direction X. Such a serpentine magnetic path increases the magnetic resistance to the third component of the leakage flux.

The example shown in FIG. 6 illustrates a case where the positions in the second direction X of the boundaries adjacent to each other in the first direction Z are necessarily different from each other. In this case, as compared with a case where the positions in the second direction X of the boundaries adjacent to each other in the first direction Z are all the same, the leakage flux is reduced by about 20 to 30 percent (provided that the ends 21a and 21c are shorted, and the end 21b is open).

The positional relationship between the conductors illustrated in FIG. 6 is desirable in view of increasing the magnetic resistance; however, such a positional relationship is not necessarily required.

When any two of the positions in the second direction X of the boundaries 21ac, 211ac, 212ac, 213ac, 214ac, and 22ac are different from each other, the magnetic path is longer than that in the case where any two of the positions are not different from each other (i.e., none of the positions are different from one another), resulting in an increase in the magnetic resistance to the second component of the leakage flux. For example, the boundaries 212ac and 214ac may be at the position x1. Although the boundaries 21ac and 22ac are both located at the position x2 in FIG. 6, the boundaries 21ac and 22ac may be at positions different from each other in the second direction X.

When any two of the positions in the second direction X of the boundaries 21bc, 211bc, 212bc, 213bc, 214bc, and 22bc are different from each other, the magnetic path is longer than that in the case where any two of the positions are not different from each other (i.e., none of the positions are different from one another), resulting in an increase in the magnetic resistance to the third component of the leakage flux. For example, the boundaries 212bc and 214bc may be at the position x4. Although the boundaries 21bc and 22bc are both located at the position x5 in FIG. 6, the boundaries 21bc and 22bc may be at positions different from each other in the second direction X.

The foregoing can be expressed as follows. First, in a configuration in view of reducing the second component of the leakage flux:

(ia) the first position is different from at least one of the second position and the third position;

(iia) the first position is any one of:

the position x1 in the second direction X of the boundary 211ac between the conductor 211a and the conductor 211c;

the position x3 in the second direction X of the boundary 212ac between the conductor 212a and the conductor 212c;

the position x1 in the second direction X of the boundary 213ac between the conductor 213a and the conductor 213c; and

the position x3 in the second direction X of the boundary 214ac between the conductor 214a and the conductor 214c;

(iiia) the second position is

the position x2 in the second direction X of the boundary 21ac between the end 21a and the end 21c; and

(iva) the third position is

the position x2 in the second direction X of the boundary 22ac between the end 22a and the end 22c.

Also in a configuration in view of reducing the third component of the leakage flux, as in the case of (ia) to (iva) above:

(ib) the first position is different from at least one of the second position and the third position;

(iib) the first position is any one of:

the position x4 in the second direction X of the boundary 211bc between the conductor 211b and the conductor 211c;

the position x6 in the second direction X of the boundary 212bc between the conductor 212b and the conductor 212c;

the position x4 in the second direction X of the boundary 213bc between the conductor 213b and the conductor 213c; and

the position x6 in the second direction X of the boundary 214bc between the conductor 214b and the conductor 214c;

(iiib) the second position is the position x5 in the second direction X of the boundary 21bc between the end 21b and the end 21c; and

(ivb) the third position is the position x5 in the second direction X of the boundary 22bc between the end 22b and the end 22c.

Example of Application to Full-Bridge DC/DC Converter

FIG. 7 is a circuit diagram illustratively depicting a converter 200 in which the transformer 100 is used. The converter 200 is a full-bridge DC/DC converter. The transformer 100 is used as a transformer T in the converter 200.

The ends 11d and 14d of the transformer 100 function as primary-side terminals of the transformer T. The ends 21a, 21b, and 21c of the transformer 100 function as secondary-side terminals of the transformer T. The end 21c functions as a center tap of the transformer T. An inductor La having one end connected to the end 11d inside the transformer T equivalently indicates the leakage inductance of the transformer T on the primary side.

On the primary side of the transformer T, switching elements Q1, Q2, Q3, and Q4 and diodes D1 and D2 are provided between power lines H1 and L1. The power line H1 has a higher potential than the power line L1.

The switching elements Q1 and Q2 are connected in series between the power lines H1 and L1. The switching elements Q3 and Q4 are connected in series between the power lines H1 and L1.

The diodes D1 and D2 are connected in series between the power lines H1 and L1. The anode of the diode D1 and the cathode of the diode D2 are connected to the end 11d. The cathode of the diode D1 is connected to the power line H1. The anode of the diode D2 is connected to the power line L1.

The end 11d is connected, via an inductor Lb, to a connection point P1 at which the switching elements Q1 and Q2 are connected to each other. The end 14d is connected to a connection point P2 at which the switching elements Q3 and Q4 are connected to each other.

Switching elements Q101 and Q102, an inductor Lc, and a capacitor Cd are provided on the secondary side of the transformer T. The capacitor Cd is provided between power lines H2 and L2. The power line H2 has a higher potential than the power line L2. The power line L2 is grounded, for example.

One end of the switching element Q101 is connected to the end 21b, and the other end thereof is connected to the power line L2. One end of the switching element Q102 is connected to the end 21a, and the other end thereof is connected to the power line L2. One end of the inductor Lc is connected to the end 21c, and the other end thereof is connected to the power line H2.

All of the switching elements Q1, Q2, Q3, Q4, Q101, and Q102 are realized by a field-effect transistor, for example.

Since the operations of the converter 200 having the above-described configuration, including, for example, the timing at which the switching elements Q1, Q2, Q3, Q4, Q101, and Q102 are switched, are known, descriptions of the operations are omitted in the present embodiment. A description will be given of an advantage of using the transformer 100 in the transformer T to reduce the leakage inductance of the primary side.

The inductor Lb has the function of reducing the surge voltage on the secondary side of the converter 200. Energy is regenerated to the power lines H1 and L1 via the diodes D1 and D2.

The larger the ratio of the inductance of the inductor Lb to the inductance (the leakage inductance on the primary side of the transformer T) of the inductor La, the greater the effect of reducing the surge voltage on the secondary side is. Since the sum of the inductance of the inductor Lb and the inductance of the inductor La affects the resonant period of so-called soft switching, it is not desirable to increase the inductance of the inductor Lb without limitation. Therefore, it is desirable that the inductance of the inductor La is small.

The transformer 100 has the above-described features (i) to (iv), and the leakage inductance on the primary side thereof is reduced. Accordingly, the transformer 100 is suitably applied to a full-bridge DC/DC converter, such as the converter 200 in which the inductor Lb is used.

Embodiment 2

A transformer according to Embodiment 2 will be described. Note that the same constituent elements as those described in Embodiment 1 are denoted by the same reference numerals in the description of Embodiment 2, and the description thereof has been omitted.

FIG. 8 is a plan view illustratively depicting the configuration of a transformer 101 according to Embodiment 2. The transformer 101 includes a core 5. The same configuration as that of the core 5 of the transformer 100 can be used for the core 5.

FIG. 9 is an exploded perspective view illustratively depicting a primary winding 1 and a secondary winding 2 in a first direction Z. The core 5 is omitted in FIG. 9. FIG. 9 shows a region located on the core 5 side relative to a position indicated by the line EE in FIG. 8.

The transformer 101 includes a primary winding 1 and a secondary winding 2. The primary winding 1 includes third coils 11, 12, 13, and 14. The secondary winding 2 includes a first coil 21 and a second coil 22. In the first direction Z, the second coil 22, the third coils 14, 13, 12, and 11, and the first coil 21 are stacked in this order.

All of the first coil 21, the second coil 22, and the third coils 11, 12, 13, and 14 at least partially encircle an axis J. As an example of the configuration of the third coils 11, 12, 13, and 14 of the transformer 101, the configuration of the third coils 11, 12, 13, and 14 illustrated in the transformer 100 is used. The number of layers in which the coils of the primary winding 1 are stacked is not limited to four.

The first coil 21 includes an encircling portion 210, and ends 21a and 21b. The encircling portion 210 encircles the axis J. As the encircling portion 210 of the transformer 101, the encircling portion 210 of the transformer 100 is used, for example. The ends 21a and 21b extend continuously from the encircling portion 210, and are adjacent to each other in a non-contact manner in the second direction X. A boundary 21ab is a boundary between the ends 21a and 21b in the second direction X.

The second coil 22 includes an encircling portion 220, and ends 22a and 22b. The encircling portion 220 encircles the axis J. As the encircling portion 220 of the transformer 101, the encircling portion 220 of the transformer 100 is used, for example. The ends 22a and 22b extend continuously from the encircling portion 210, and are adjacent to each other in a non-contact manner in the second direction X. A boundary 22ab is a boundary between the ends 22a and 22b in the second direction X.

The encircling portion 210 is located on the third direction Y side relative to the ends 21a and 21b. The encircling portion 220 is located on the third direction Y side relative to the ends 22a and 22b.

The first coil 21 encircles the axis J once, excluding the boundary 21ab. The second coil 22 encircles the axis J once, excluding the boundary 22ab.

The first coil 21, the second coil 22, and the third coils 11, 12, 13, and 14 can each be realized in the form of a conductive pattern in a printed circuit board 60 in which a plurality of insulating layers are stacked. The conductive pattern is provided on a boundary or surface of a stacked insulating layer. Each of the conductors 112, 123, and 134 can be realized by a via hole that provides conductive connection in the corresponding insulating layer in the thickness direction. The insulating layers are omitted in FIGS. 8 and 9.

The secondary winding 2 includes conductor groups 211, 212, 213, and 214. The conductor group 211 includes conductors 211a and 211b. The conductor group 212 includes conductors 212a and 212b. The conductor group 213 includes conductors 213a and 213b. The conductor group 214 includes conductors 214a and 214b.

FIG. 10 is a cross-sectional view illustratively depicting the configuration of the secondary winding 2. FIG. 10 shows a cross section seen at a position indicated by the line FF shown in FIG. 8 as viewed along the third direction Y.

The end 21a and the end 21b are arranged in a non-contact manner across the boundary 21ab along the second direction X. The conductor 211a and the conductor 211b are arranged in a non-contact manner across a boundary 211ab along the second direction X. The conductor 212a and the conductor 212b are arranged in a non-contact manner across a boundary 212ab along the second direction X. The conductor 213a and the conductor 213b are arranged in a non-contact manner across a boundary 213ab along the second direction X. The conductor 214a and the conductor 214b are arranged in a non-contact manner across a boundary 214ab along the second direction X. The end 22a and the end 22b are arranged in a non-contact manner across the boundary 22ab along the second direction X.

In FIGS. 8 and 9, some or all of the reference numerals of the above-described boundaries are omitted in order to avoid complication of the illustration.

The conductors 611a, 612a, 623a, 634a, 642a, 611b, 612b, 623b, 634b, and 642b are configured and arranged in the same manner as the transformer 100. The transformer 101 does not include the ends 21c and 22c included in the transformer 100. Accordingly, the conductors 611c, 612c, 623c, 634c, and 642c are not provided in the transformer 101.

With such conductive connection, both the end 21a and the end 22a function as one end of the secondary winding 2, and both the end 21b and the end 22b function as the other end of the secondary winding 2.

Also in the transformer 101, the magnetic flux generated upon application of a voltage to the ends 11d and 14d of the primary winding 1 includes a component constituting a leakage flux.

A second component of the leakage flux is a magnetic flux that passes through the boundaries 21ab, 211ab, 212ab, 213ab, 214ab, and 22ab in this order, or in the reverse order.

Accordingly, in view of reducing the second component of the leakage flux in order to reduce the leakage flux, it is desirable to increase the magnetic resistance in a path extending from the boundary 21ab to the boundary 22ab via the boundaries 211ab, 212ab, 213ab, and 214ab.

In the second direction X, the boundaries 21ab, 211ab, 212ab, 213ab, 214ab, and 22ab are at positions x8, x7, x9, x7, x9, and x8, respectively. Also, the positions x7, x8, and x9 are all different from one another. Accordingly, the second component of the leakage flux generally flows in the first direction Z or a direction opposite thereto, but flows in a serpentine manner along the second direction X. Such a serpentine magnetic path increases the magnetic resistance to the second component of the leakage flux.

The example shown in FIG. 10 illustrates a case where the positions in the second direction X of the boundaries adjacent to each other in the first direction Z are necessarily different from each other. The positional relationship between the conductors illustrated in FIG. 10 is desirable in view of increasing the magnetic resistance; however, such a positional relationship is not necessarily required.

When any two of the positions in the second direction X of the boundaries 21ab, 211ab, 212ab, 213ab, 214ab, and 22ab are different from each other, the magnetic path is longer than that in the case where any two positions are not different from each other (i.e., none of the positions are different from one another), resulting in an increase in the magnetic resistance to the second component of the leakage flux. For example, the boundaries 212ab and 214ab may be at the position x7. Although the boundaries 21ab and 22ab are both located at the position x8 in

FIG. 10, the boundaries 21ab and 22ab may be at positions different from each other in the second direction X.

The foregoing can be generally expressed as follows.

(i) the first position is different from at least one of the second position and the third position;

(ii) the first position is any one of:

the position x7 in the second direction X of the boundary 211ab between the conductor 211a and the conductor 211b;

the position x9 in the second direction X of the boundary 212ab between the conductor 212a and the conductor 212b;

the position x7 in the second direction X of the boundary 213ab between the conductor 213a and the conductor 213b; and

the position x9 in the second direction X of the boundary 214ab between the conductor 214a and the conductor 214b;

(iii) the second position is the position x8 in the second direction X of the boundary 21ab between the end 21a and the end 21b; and

(iv) the third position is the position x8 in the second direction X of the boundary 22ab between the end 22a and the end 22b.

APPENDIX

Not all of the third coils 11, 12, 13, and 14 necessarily need to be sandwiched between the first coil 21 and the second coil 22 in the first direction Z. Any of the third coils 11, 12, 13, and 14 may be sandwiched between the first coil 21 and the second coil 22, or none of them need to be sandwiched between the first coil 21 and the second coil 22.

In view of reducing the first component of the leakage flux, in a preferred example of the arrangement, all of the third coils 11, 12, 13, and 14 are sandwiched between the first coil 21 and the second coil 22 in the first direction Z.

When the primary winding 1 and the secondary winding 2 are realized in the printed circuit board 60, it is desirable that the first coil 21 is not sandwiched between any of the second coil 22 and the third coils 11, 12, 13, and 14. The reason being that the ends 21a, 21b, and 21c are likely to be connected to an external device of the transformer 100. Alternatively, it is desirable that the second coil 22 is not sandwiched between any of the first coil 21 and thew third coils 11, 12, 13, and 14. The reason being that the ends 22a, 22b, and 22c are likely to be connected to an external device of the transformer 100.

It should be appreciated that the configurations described in the embodiments and modifications above may be combined as appropriate as long as there are no mutual inconsistencies.

TRANSFORMER

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