DE202020102991U1 - Common mode choke coil - Google Patents

Abstract

A common mode choke coil that has the following features:
a core including a winding core portion, a first flange portion provided in an axial direction of the winding core portion on a first end side, and a second flange portion provided in the axial direction of the winding core portion on a second end side opposite to the first end side;
a first wire, a second wire, a third wire and a fourth wire, each of which is helically wound around the winding core portion;
a first connection electrode and a third connection electrode provided on the first flange portion; and
a second connection electrode and a fourth connection electrode which are provided on the second flange section,
wherein each of the end portions of the first wire and the second wire on the first end side is connected to the first connection electrode, each of the end sections of the first wire and the second wire on the second end side is connected to the second connection electrode,
each of the end portions of the third wire and the fourth wire on the first end side is connected to the third connection electrode, each of the end portions of the third wire and the fourth wire on the second end side is connected to the fourth connection electrode,
at least part of the first wire is wound around the winding core section to form a first layer,
at least part of the third wire is wound to form a second layer located on an outer peripheral side of the first layer in a recess formed between adjacent turns of the first wire,
at least a portion of the fourth wire is wound to form a third layer located on an outer peripheral side of the second layer in a recess formed between adjacent turns of the third wire, and
at least a portion of the second wire is wound to form a fourth layer located on an outer peripheral side of the third layer in a recess formed between adjacent turns of the fourth wire.

Description

background

Technical field

This disclosure relates to a common mode choke coil and, more particularly, to a wire winding type common mode choke coil having a structure in which a plurality of wires are wound around a winding core portion provided on a core.

Background technique

With reference to 9 and 10th becomes a widely used version of a common mode choke coil 31 described.

As in 9 is illustrated includes the common mode choke coil 31 a core 32 and a first wire 33 and a second wire 34 , which each form inductors. The common mode choke coil 31 can be a top plate 45 include.

The core 32 comprises a winding core section 35 , a first flange section 36 that is in an axial direction on one side of a first end 38 of the winding core section 35 is provided, and a second flange portion 37 that is on one side of a second end 39 opposite the first end side 38 is provided.

The first flange section 36 is with a first connection electrode 41 and a third connection electrode 43 provided, and the second flange portion 37 is with a second connection electrode 42 and a fourth connection electrode 44 Mistake. As from the position of the connection electrodes 41 to 44 can be seen is the common mode choke coil 31 in a position in which the mounting surface, which is to face the side of the mounting substrate, in 9 is directed upwards.

Each of the first wire 33 and the second wire 34 is parallel from the first end side 38 to the side of the second end 39 helically around the winding core section 35 wrapped. The end sections of the first wire 33 are with the first connection electrode 41 or the second connection electrode 42 connected, and the end portions of the second wire 34 are with the third connection electrode 43 or the fourth connection electrode 44 connected.

The common mode choke coil 31 with the embodiment described above is with an in 10th illustrated equivalent circuit provided. In 10th are elements that the in 9 illustrated correspond, identified by the same reference numerals.

As in 10th is illustrated includes the common mode choke coil 31 a first inductor 46 through the first wire 33 is formed with the first connection electrode 41 and the second connection electrode 42 is connected, and a second inductor 47 through the second wire 34 is formed with the third connection electrode 43 and the fourth connection electrode 44 connected is.

Although in 9 not clearly illustrated is the first wire 33 around a peripheral surface of the winding core portion 35 wound to form a first layer and the second wire 34 is wound to form a second layer located on an outer peripheral side of the first layer while a portion thereof is fitted in a recess formed between adjacent turns of the first wire 33 is formed. This is the first inductor 46 and the second inductor 47 magnetically coupled to each other.

With the common mode choke coil described above 31 As the signal frequency input therein increases, mode conversion characteristics may deteriorate. The mode conversion characteristics indicate a ratio of an output common mode noise to an input differential signal component, wherein the common mode noise is converted from the input differential signal component. For example, Japanese Unexamined Patent Application Publication No. 2014-120730 describes a disturbance in the equilibrium of the stray capacitance (distributed capacitance) that occurs between different windings of the first wire 33 and the second wire 34 is described as a cause of the problem.

Therefore, as in 11 is illustrated in a common mode choke coil 31a described in Japanese Unexamined Patent Application Publication No. 2014-120730, a following winding mode of the wires 33 and 34 accepted.

In 11 is the cross section of the first wire 33 hatched to distinguish it from the second wire 34 to clarify. In addition, each of the first wire is in the cross section 33 and the second wire 34 , in the 11 are illustrated, the number of windings "1" to "12" are given. The numbers are from the first end side 38 counted out where the first flange section is 36 of the winding core section 35 located.

In 11 are under the sections of the first wire 33 and the second wire 34 that around the winding core section 35 are wound, portions that are on a front of the winding core portion 35 are shown, illustrated schematically with solid lines, or sections through the winding core section 35 are hidden, are shown schematically with broken lines. In 11 with the wires 33 and 34 are not all sections that are on the front of the winding core section 35 located, and not all sections through the winding core section 35 are covered, illustrated.

1. (1) Eine erste Wickelregion A, in der der erste Draht 33 näher an der Seite des ersten Endes 38 positioniert ist als der zweite Draht 34, während dieselben mit jeweils denselben Windungszahlen des ersten Drahts 33 und des zweiten Drahts aneinander angrenzen.
2. (2) Eine zweite Wickelregion B, in der der erste Draht 33 näher an der Seite des zweiten Endes 39 positioniert ist als der zweite Draht 34, während dieselben mit jeweils denselben Windungszahlen des ersten Drahts 33 und des zweiten Drahts 34 aneinander angrenzen.
3. (3) Eine Wechselregion C, die sich zwischen der ersten Wickelregion A und der zweiten Wickelregion B befindet, in der die Windungen des ersten Drahts 33 und die Windungen des zweiten Drahts 34 in ihrer Positionsbeziehung einen Wechsel erfahren, indem der erste Draht 33 und der zweite Draht 34 gekreuzt werden. Die erste Wickelregion A, die Wechselregion C und die zweite Wickelregion B sind in dieser Reihenfolge entlang der Axialrichtung des Wickelkernabschnitts 35 angeordnet.

With reference to 11 are the regions of the first wire 33 and the second wire 34 classified as follows based on the winding conditions.

1. (1) A first winding region A in which the first wire 33 closer to the side of the first end 38 is positioned as the second wire 34 while the same with the same number of turns of the first wire 33 and the second wire adjoin each other.
2. (2) A second winding region B in which the first wire 33 closer to the side of the second end 39 is positioned as the second wire 34 while the same with the same number of turns of the first wire 33 and the second wire 34 adjoin each other.
3. (3) A change region C, which is located between the first winding region A and the second winding region B, in which the turns of the first wire 33 and the turns of the second wire 34 undergo a change in their positional relationship by the first wire 33 and the second wire 34 to be crossed. The first winding region A, the changing region C and the second winding region B are in this order along the axial direction of the winding core section 35 arranged.

In one technique described in Japanese Unexamined Patent Application Publication No. 2014-120730, in order to solve the problem of deterioration of the mode conversion characteristics, the winding structure of the first wire 33 and the second wire 34 in the first winding region A and the winding structure of the first wire 33 and the second wire 34 in the second winding region B is designed symmetrically with respect to a center line CL in the changing region C, so that parts of a stray capacitance (distributed capacitance) between different turns of the first wire 33 and the second wire 34 is generated, balanced.

In other words, the number of turns of each of the first wire 33 and the second wire 34 in the first winding region A and the number of turns of each of the first wires 33 and the second wire 34 aligned in the second winding region B.

Thus, given the capacitance between different turns, both for the first wire 33 as well as for the second wire 34 is generated uniformly, an imbalance between the impedances of the first wire 33 and the second wire 34 can be suppressed, thereby improving the mode conversion characteristics and realizing a common mode choke coil with high quality.

Brief description

However, according to the technique described in Japanese Unexamined Patent Application Publication No. 2014-120730, there is room for improvement in mode conversion characteristics. For example, because of the common mode choke coil 31a electrical circuit formed is divided into a first half and a second half with respect to a forward direction of a signal, the deviation of the stray capacitance between different turns in a macroscopic view, that is, in the entire turns, suppressed. However, the stray capacitance between different turns is generated in a local view, that is, for example, if only a first half or a second half is examined. As a result, as in 4th that will be described later, the inventor of the present embodiment discovers that the mode conversion characteristics gradually deteriorate in a high frequency range.

It is therefore the object of the present disclosure to provide a common mode choke coil which is able to significantly improve the degree of freedom in generating stray capacitance between different turns, including an embodiment which reduces a local variation in stray capacitance between the different turns and which Mode conversion characteristics can improve.

A common mode choke coil according to an aspect of the present disclosure includes a core that includes a winding core portion, a first flange portion that is provided in an axial direction of the winding core portion on a first end side, and a second flange portion that faces in the axial direction of the winding core portion on a second end side the first end side is provided, a first wire, a second wire, a third wire and a fourth wire, each of which is helically wound around the winding core section, a first Connection electrode and a third connection electrode, which are provided on the first flange section, and a second connection electrode and a fourth connection electrode, which are provided on the second flange section.

Each of the end portions of the first wire and the second wire on the first end side is connected to the first terminal electrode, each of the end portions of the first wire and the second wire on the second end side is connected to the second terminal electrode, each of the end portions of the third wire and the fourth wire on the first end side is connected to the third connection electrode, and each of the end portions of the third wire and fourth wire on the second end side is connected to the fourth connection electrode.

At least a part of the first wire is wound around the winding core portion to form a first layer, at least a part of the third wire is wound to form a second layer, which is located on an outer peripheral side of the first layer in a recess between is formed adjacent turns of the first wire, at least a part of the fourth wire is wound to form a third layer, which is located on an outer peripheral side of the second layer in a recess formed between adjacent turns of the third wire, and at least one Part of the second wire is wound to form a fourth layer, which is located on an outer peripheral side of the third layer in a recess formed between adjacent turns of the fourth wire.

A common mode choke coil according to another aspect of the present disclosure includes a core that includes a winding core portion, a first flange portion that is provided in an axial direction of the winding core portion on a first end side, and a second flange portion that is in the axial direction of the winding core portion on a second end side is provided opposite to the first end side, a first wire, a second wire and a third wire, each of which is helically wound around the winding core section, a first connection electrode and a third connection electrode provided on the first flange section, and a second connection electrode and one fourth connection electrode provided on the second flange portion.

Each of the end portions of the first wire and the second wire on the first end side is connected to the first terminal electrode, each of the end portions of the first wire and the second wire on the second end side is connected to the second terminal electrode, an end portion of the third wire on the first End side is connected to the third connection electrode and an end portion of the third wire on the second end side is connected to the fourth connection electrode.

At least a part of the first wire is wound around the winding core portion to form a first layer, at least a part of the third wire is wound to form a second layer, which is located on an outer peripheral side of the first layer in a recess between is formed adjacent turns of the first wire, and at least a part of the second wire is wound to form a third layer, which is located on an outer peripheral side of the second layer in a recess formed between adjacent turns of the third wire.

In one technique described in Japanese Unexamined Patent Application Publication No. 2014-120730, a first winding region and a second winding region where the positional relationship between two wires of a pair are opposite to each other are arranged in an axial direction of a winding core portion. Here, in brief, in the aspect described above, a region corresponding to the first winding region and a region corresponding to the second winding region are stacked in a direction perpendicular to the axial direction of the winding core portion.

Other features, elements, characteristics, and advantages of the present disclosure will become more apparent from the following detailed description with reference to the accompanying drawings.

Figure list

• 1 is a plan view showing a common mode choke coil 1 illustrated according to a first embodiment, viewed from one side of a mounting surface;
• 2nd Fig. 12 is a sectional view schematically showing a winding state of first to fourth wires in the common mode choke coil 1 illustrated in 1 is illustrated;
• 3rd FIG. 10 is an enlarged sectional view of a part of first to fourth wires to describe stray capacitance C1 and C2 used in the first to fourth wires shown in FIG 2nd are illustrated;
• 4th FIG. 12 is a diagram illustrating frequency characteristics of mode conversion characteristics of common mode choke coils, and (A) illustrates characteristics of a common mode choke coil that a “ Layer winding ”called the two-layer winding described in Japanese Unexamined Patent Application Publication No. 2014-120730 as a comparative example, (B) illustrates characteristics of a common mode choke coil according to the first embodiment described in Japanese Unexamined Patent Application Publication No. 2014-120730 as another comparative example, and (C) illustrates characteristics of a common mode choke coil as an example according to the present disclosure;
• 5 12 is a sectional view schematically showing a winding state of the first to fourth wires in a common mode choke coil 1a as a modification example of the common mode choke coil 1 illustrated in 2nd is illustrated;
• 6 is a plan view showing a common mode choke coil 1b illustrated according to a second embodiment, viewed from one side of a fastening surface;
• 7 Fig. 12 is a sectional view schematically showing a winding state of the first to third wires in the common mode choke coil 1b illustrated in 6 is illustrated;
• 8th FIG. 10 is an enlarged sectional view of a part of the first to third wires to illustrate the dimensional relationship between a central wiring and an insulating coating layer of the first to third wires shown in FIG 7 are illustrated;
• 9 Fig. 3 is a perspective view showing the common mode choke coil 31 illustrated in a position with a mounting surface facing upward;
• 10th is an equivalent circuit diagram of the common mode choke coil 31 , in the 9 is illustrated; and
• 11 Fig. 12 is a sectional view schematically showing a winding state of the first and second wires 33 and 34 in the common mode choke coil 31a illustrated in Japanese Unexamined Patent Application Publication No. 2014-120730.

Detailed description

1 illustrates a common mode choke coil 1 according to a first embodiment. In the 1 illustrated common mode choke coil 1 includes a core 2nd , four wires, that is, a first wire 11 , a second wire 12th , a third wire 13 and a fourth wire 14 to form inductors. 2nd Fig. 12 is a schematic sectional view showing a winding state of the first wire 11 , the second wire 12th , the third wire 13 and the fourth wire 14 in the in 1 illustrated common mode choke coil 1 illustrated. In 2nd are clearly between the first wire 11 and the second wire 12th as well as the third wire 13 and the fourth wire 14 to distinguish cross sections of the first wire 11 and the second wire 12th illustrated with a white interior and cross sections of the third wire 13 and the fourth wire 14 are hatched.

The core 2nd is made of a non-conductive material, in particular aluminum as a dielectric, Ni-Zn-based ferrite as a magnetic material, a resin or the like. The core 2nd has an essentially rectangular cross section. The wires 11 to 14 are made, for example, of copper coated with an insulator and have a substantially circular cross-section and substantially the same outside diameter. It should be noted that the material and the shape of the core 2nd and the material, shape and outer diameter of the wires 11 to 14 is not limited to those exemplified herein.

The core 2nd comprises a winding core section 3rd , a first flange section 6 which is in an axial direction of the winding core portion 3rd on one side of a first end 4th is provided, and a second flange portion 7 that is on one side of a second end 5 opposite the first end side 4th is provided. The first wire 11 , the second wire 12th , the third wire 13 and the fourth wire 14 are parallel to each other with substantially the same number of turns from the first end side 4th to the side of the second end 5 helically around the winding core section 3rd wrapped. The reason why "essentially the same number of turns" is used is that the position of a winding start point or a winding end point of the respective wires 11 to 14 on the winding core section 3rd can be slightly shifted from each other.

The first flange section 6 is with a first connection electrode 21 and a third connection electrode 23 provided, and the second flange portion 7 is with a second connection electrode 22 and a fourth connection electrode 24th Mistake. The connection electrodes 21 to 24th are produced, for example, by firing a conductive paste, by plating a conductive metal, by gluing a metal plate with an adhesive, or the like. The common mode choke seen from the mounting surface side 1 is in 1 illustrated. In 2nd are the connection electrodes 21 to 24th not illustrated.

The end sections of the first wire 11 and the second wire 12th on the first end side 4th are both with the first Connection electrode 21 connected, and the end portions of the first wire 11 and the second wire 12th on the side of the second end 5 are both with the second connection electrode 22 connected. The end sections of the third wire 13 and the fourth wire 14 on the first end side 4th are both with the third connection electrode 23 connected, and the end portions of the third wire 13 and the fourth wire 14 on the side of the second end 5 are both with the fourth connection electrode 24th connected. For the connections mentioned above, for example, thermocompression bonding or laser welding is selected.

The common mode choke coil 1 may comprise an upper plate, that of the upper plate 45 corresponds to that in the in 9 illustrated common mode choke coil 31 is included. Similar to the core 2nd For example, the upper plate is made of aluminum as a non-magnetic material, Ni-Zn-based ferrite as a magnetic material, a resin, or the like. If the core 2nd and the top plate is made of a magnetic material and the top plate is arranged around the first flange portion 6 and the second flange portion 7 to connect form the core 2nd and the top plate together form a closed magnetic circuit.

Referring mainly to 2nd is the first wire 11 around the winding core section 3rd wrapped to form a first layer. The third wire 13 is wound to form a second layer located on an outer peripheral side of the first layer, while a portion thereof, more specifically, a portion in the cross-sectional plane thereof, is fitted in a recess between adjacent turns of the first wire 11 is formed. Next is the fourth wire 14 wound to form a third layer located on an outer peripheral side of the second layer, while a portion thereof, more specifically, a portion in the cross-sectional plane thereof, is fitted in a recess between adjacent turns of the third wire 13 is formed. At the end is the second wire 12th wound to form a fourth layer located on an outer peripheral side of the third layer, while a portion thereof, more specifically, a portion in the cross-sectional plane thereof, is fitted in a recess between adjacent turns of the fourth wire 14 is formed.

In 2nd are the number of turns "1" to "20" from one side of the first end 4th of the winding core section 3rd counted out in each cross section of the first wire 11 , the second wire 12th , the third wire 13 and the fourth wire 14 specified. The number of turns is in those described later 5 and 7 also indicated in the cross section of the wire.

If the number of turns described above is considered closely, the first wire point 11 , which forms the first layer, and the third wire 13 , which forms the second layer, a section in which the first wire 11 closer to the side of the second end 5 of the winding core section 3rd is positioned as the third wire 13 while the same with the same number of turns, from the side of the first end 4th of the winding core section 3rd counted out, adjoin each other. That is, if n is a natural number from 2 to 20, there is an nth turn of the third wire 13 next to an (n-1) th turn of the first wire 11 .

Furthermore, the second wire 12th , which forms the fourth layer, and the fourth wire 14 , which forms the third layer, a section in which the second wire 12th closer to the side of the first end 4th of the winding core section 3rd is positioned as the fourth wire 14 , they have the same number of turns, from the first end side 4th of the winding core section 3rd counted out, adjoin each other. That is, if n is a natural number from 1 to 19, the nth turn of the fourth wire is 14 next to the (n + 1) th turn of the second wire 12th .

Therefore, as in 3rd is illustrated between the first wire 11 and the third wire 13 creates a stray capacitance C1 between different turns and between the second wire 12th and the fourth wire 14 a stray capacitance C2 is generated between different turns, the first wire 11 with the first connection electrode 21 and the second connection electrode 22 is connected, the third wire 13 with the third connection electrode 23 and the fourth connection electrode 24th is connected, the second wire 12th with the first connection electrode 21 and the second connection electrode 22 is connected and the fourth wire 14 with the third connection electrode 23 and the fourth connection electrode 24th connected is. Because the first wire 11 and the second wire 12th are connected to the same connection electrode at each end and the third wire 13 and the fourth wire 14 are connected to the same connection electrodes at each end, are the first wire 11 and the second wire 12th electrically connected in parallel and the third wire 13 and the fourth wire 14 are electrically connected in parallel to form the same signal line in a differential signal circuit.

Regarding the turn between the first wire 11 and the third wire 13 and the turn displacement between the second wire 12th and the fourth wire 14 which generate the stray capacitance C1 and C2 cause are the displacement direction of the first wire 11 to the third wire 13 and the direction of displacement of the second wire 12th to the fourth wire 14 opposite to each other. In other words, as in 3rd the nth turn of the third wire is illustrated 13 on the upper left side of the nth turn of the first wire 11 positioned, and the nth turn of the fourth wire 14 is on the lower right side of the nth turn of the second wire 12th positioned. That is, the stray capacitance C1 between different turns becomes between the nth turn of the third wire 13 and the (n-1) th turn of the first wire 11 is generated, and the stray capacitance C2 between different turns becomes between the nth turn of the fourth wire 14 and the (n + 1) th turn of the second wire 12th generated.

As a result, the stray capacitance C1 between the first layer and the second layer and the stray capacitance C2 between the third layer and the fourth layer are generated in a direction opposite to each other. Thus, the stray capacitance becomes C1 and the stray capacitance C2 generated in an opposite direction to each other using two wires (first wire 11 and second wire 12th , third wire 13 and fourth wire 14 ) which are electrically connected in parallel as opposed to a technique described in Japanese Unexamined Patent Application Publication No. 2014-120730, where each wire is divided into a first half and a second half. That is, with respect to an nth turn of a signal line, the stray capacitance C1 and C2 can be generated for both an (n-1) th turn and an (n + 1) th turn of the other signal line. That is why the common mode choke coil 1 the deviation of the stray capacitance is reduced not only in a macroscopic view, that is to say in an entire signal line, but also in a local region, in particular in each winding unit. Therefore, the mode conversion characteristics can be improved up to a high frequency range.

The frequency characteristics of the mode conversion characteristics of the common mode choke coils obtained by simulation are shown in FIG 4th illustrated. In 4th (A) illustrates the characteristics of a common mode choke coil adopting the two-layer winding called “layer winding” described in Japanese Unexamined Patent Application Publication No. 2014-120730 as a comparative example, (B) illustrates the characteristics of the common mode choke coil according to the first embodiment shown in FIG Japanese Unexamined Patent Application Publication No. 2014-120730 is described as another comparative example, and (C) illustrates the characteristics of the common mode choke coil which is an example according to the present disclosure. The characteristics described above are obtained for common mode chokes, for which the number of wire turns 10th is.

As in 4th is illustrated, compared to the mode conversion characteristics (A) of the common mode choke coil adopting the two-layer winding called "layer winding" described in Japanese Unexamined Patent Application Publication No. 2014-120730, the mode conversion characteristics (B) of the common mode choke coil according to the first embodiment, described in Japanese Unexamined Patent Application Publication No. 2014-120730, and improves the mode conversion characteristics (C) of the common mode choke coil as an example according to the present disclosure. Further, the mode conversion characteristics (C) of the common mode choke coil as an example according to the present disclosure are improved by about 20 dB over the mode conversion characteristics (B) of the common mode choke coil according to the first embodiment described in Japanese Unexamined Patent Application Publication No. 2014-120730.

Among the improvement effects described above, the improvement effect in a high frequency range results from the reduction of the local deviation of the stray capacitance between the different turns described above, and the improvement effect in a low frequency range results from the reduction of an inductance difference between different signal lines.

In the common mode choke coil, which takes over the "layer winding" called double layer winding, which in the Japanese Unexamined Patent Application Publication No. 2014-120730 is described, and in the common mode choke coil according to the first embodiment, which in the Japanese Unexamined Patent Application Publication No. 2014-120730 a first wire always forms a first layer and a second wire always forms a second layer. In this case, since the winding diameter of a wire in the second layer is larger, differences between the first wire and the second wire are generated in a length of the wire line and in a distance of the wire from the core, thereby causing a slight inductance difference. On the other hand, the differences in the length of the wire line and the distance of the wire from the core in the common mode choke coil 1 as an example, according to the present disclosure, reduced on average since a signal line from the first wire 11 and the second wire 12th is formed, that is, an innermost first layer and an outermost fourth layer, and the other signal line from the third wire 13 and the fourth wire 14 is formed, that is, an intermediate second layer and third layer, whereby the inductance difference is reduced. Thus, with the common mode choke coil 1 as an example according to the present disclosure, the mode conversion characteristics in a low frequency range are also improved.

As with the common mode choke coil 1 both the third wire 13 as well as the fourth wire 14 , which form the intermediate second and third layers, at each end with the third connection electrode 23 and the fourth connection electrode 24th connected, it is not necessary to take a closer look at the stray capacity (distributed capacity). However, applies if turns with the same number of turns of the respective third wire 13 and the fourth wire 14 are far apart, the difference in electrical potential between the third wire 13 and the fourth wire 14 may not be ignored and a stray capacity problem may arise. To avoid the problem, point out in the 2nd illustrated embodiment of the third wire 13 and the fourth wire 14 a section where the third wire 13 closer to the side of the first end 4th is positioned as the fourth wire 14 while the same with the same number of turns, from the side of the first end 4th counted out, adjoin each other. The positional relationship can be reversed, as in 5 is illustrated below.

A modification example of the in 2nd illustrated common mode choke coil 1 is in 5 illustrated. 5 is a diagram that 2nd corresponds. In 5 are elements that the in 2nd illustrated correspond, marked with the same reference symbols, and a repeated description is omitted.

At one in 5 illustrated common mode choke coil 1a are winding modes of the wires 11 to 14 by those in 2nd illustrated common mode choke coil 1 different. In the winding modes of the in 2nd illustrated wires 11 to 14 are a first turn 13-1 of the third wire 13 , a twentieth turn 14-20 of the fourth wire 14 and a first turn 12-1 of the second wire 12th not firmly fixed, since the winding core section or wire for stable carrying of the same is not available. Regarding the first turn described above 13-1 of the third wire 13 , the twentieth turn 14-20 of the fourth wire 14 and the first turn 12-1 of the second wire 12th therefore, it is difficult to perform winding in a stable state and to keep the wound position.

In contrast, the winding modes in 5 illustrated wires 11 to 14 the first turn 13-1 of the third wire 13 on the winding core section 3rd on the first end side 4th a first turn 11-1 of the first wire 11 positioned. It is also the twentieth turn 14-20 of the fourth wire 14 fitted into a recess between a nineteenth turn 13-19 and a twentieth turn 13-20 of the third wire 13 is formed. Therefore, the wound position for all turns of all wires 11 to 14 be kept stable.

Although the first turn 12-1 of the second wire 12th is illustrated as not firmly fixed, the first turn 12-1 of the second wire 12th between a first turn 14-1 of the fourth wire 14 and the first flange portion 6 be fitted. Because the first turn 14-1 of the fourth wire 14 is fitted into a recess between the first turn 11-1 of the first wire 11 and the first turn 13-1 of the third wire 13 is formed, the position can be maintained stably.

The in 5 The illustrated winding mode is very likely to be used in a practical winding operation.

At the in 5 illustrated embodiment have the third wire 13 and the fourth wire 14 a section where the third wire 13 closer to the side of the second end 5 is positioned as the fourth wire 14 while the same with the same number of turns, from the side of the first end 4th counted out, adjoin each other. This positional relationship is opposite to that in 2nd illustrated positional relationship between the third wire 13 and the fourth wire 14 . However, it is needless to say that the same effect as that 2nd illustrated example also in the in 5 illustrated embodiment is maintained.

At the in 2nd illustrated common mode choke coil 1 and the in 5 illustrated common mode choke coil 1a are the first line 11 , the second wire 12th , the third wire 13 and the fourth wire 14 all substantially circular in cross-section and have essentially the same outside diameter. In this way, the winding state of a wire on the upper layer side can be stabilized with respect to a wire on the lower layer side, that is, the winding state of the third wire 13 as a wire on the upper layer side with respect to the first wire 11 as a wire on the side of the lower layer, the fourth wire 14 as a wire on the upper layer side with respect to the third wire 13 as a wire on the side of the bottom layer and the second wire 12th as a wire on the side of the top Layer on the fourth wire 14 as a wire on the bottom layer side.

It is also in the 2nd illustrated common mode choke coil 1 and the in 5 illustrated common mode choke coil 1a it is not necessary to provide a region where a plurality of wires intersect, for example, the change region C of the common mode choke coil 31a , in the 11 is illustrated. That is why it is opposite the in 11 illustrated common mode choke coil 31a in the case of common mode chokes 1 and 1a easier to manufacture the same, and the possibility of wire quality deterioration with such damage to the insulating coating layer 18th (In reference to 8th ) in the wires 11 to 14 can be further reduced.

Next is a common mode choke coil 1b according to a second embodiment with reference to 6 to 8th described. 6 corresponds 1 , and 7 corresponds 2nd . In 6 to 8th become elements that the in 1 and 2nd illustrated correspond, marked with the same reference symbols, and a repeated description is omitted.

The common mode choke coil 1b is provided with three wires as a feature. In short, there is a feature of the common mode choke coil 1b according to the second embodiment in that the reels of the third wire 13 and the fourth wire 14 for the common mode choke coil 1 according to the first embodiment described above, only by the third wire 13 be achieved. Therefore, according to the second embodiment, it is possible to further simplify the wire winding process compared to the first embodiment.

The common mode choke coil 1b encompasses the core 2nd , three wires, that is the first wire 11 , the second wire 12th and the third wire 13 . In 7 are clearly between the first wire 11 and the second wire 12th and the third wire 13 to distinguish cross sections of the first wire 11 and the second wire 12th illustrated with a white interior, and a cross section of the third wire 13 is hatched.

Similar to the core 2nd of the first embodiment has the core 2nd the winding core section 3rd , the first flange section 6 which is in an axial direction of the winding core portion 3rd on the first end side 4th is provided, and the second flange portion 7 on that on the side of the second end 5 opposite the first end side 4th is provided. The first wire 11 , the second wire 12th and the third wire 13 are parallel to each other with substantially the same number of turns from the first end side 4th to the side of the second end 5 helically around the winding core section 3rd wrapped.

As in the case of the core 2nd in the first embodiment are the first connection electrode 21 and the third connection electrode 23 on the first flange section 6 provided, and the second connection electrode 22 and the fourth connection electrode 24th are on the second flange section 7 intended. In 7 are the connection electrodes 21 to 24th not illustrated.

The end sections of the first wire 11 and the second wire 12th on the first end side 4th are both with the first connection electrode 21 connected, and the end portions of the first wire 11 and the second wire 12th on the side of the second end 5 are both with the second connection electrode 22 connected. The end section of the third wire 13 on the first end side 4th is with the third connection electrode 23 connected, and the end portion of the third wire 13 on the side of the second end 5 is with the fourth connection electrode 24th connected.

With the common mode choke coil 1b can be a top plate that the in 9 illustrated top plate 45 corresponds, also be provided.

As in 7 is illustrated is the first wire 11 around the winding core section 3rd wrapped to form a first layer. The third wire 13 is wound to form a second layer located on an outer peripheral side of the first layer, while a portion thereof, more specifically, a portion in the cross-sectional plane thereof, is fitted in a recess between adjacent turns of the first wire 11 is formed. Next is the second wire 12th wound to form a third layer located on an outer peripheral side of the second layer, while a portion thereof, more specifically, a portion in the cross-sectional plane thereof, is fitted in a recess between adjacent turns of the third wire 13 is formed.

Regarding the first wire 11 which forms the first layer and the third wire 13 that forms the second layer is the first wire 11 closer to the side of the second end 5 of the winding core section 3rd positioned as the third wire 13 while the same with the same number of turns, from the side of the first end 4th of the winding core section 3rd counted out, adjoin each other.

Also, regarding the second wire 12th which forms the third layer and the third wire 13 , which forms the second layer, the second wire 12th closer to the side of the first end 4th of the winding core section 3rd positioned as the third wire 13 while the same with the same number of turns, from the side of the first end 4th of the winding core section 3rd counted out, adjoin each other. It should be noted that the first turn 12-1 of the second wire 12th on the first end side 4th the first turn 11-1 of the first wire 11 is positioned and on the winding core section 3rd is positioned. Such a winding mode is very likely to be used in a practical winding operation that is similar to that in 5 illustrated winding mode is similar.

With the common mode choke coil 1b According to the second exemplary embodiment, the stray capacitance between the first layer and the second layer and the stray capacitance between the second layer and the third layer are generated in mutually opposite directions. Similar to the case of the first embodiment described above, the two types of stray capacitance in opposite directions are generated using two wires (first wire 11 and second wire 12th ) that are electrically connected in parallel. That is, with respect to an nth turn of one signal line, the stray capacitance C1 and C2 can be generated both for an (n-1) th turn and for an (n + 1) th turn of the other signal line. That is why the common mode choke coil 1 b not only reduces the deviation of the stray capacitance in a macroscopic view, that is to say in an entire signal line, but also in a local region, in particular in each winding unit. Thus, the mode conversion characteristics can be improved up to a high frequency range.

The common mode choke coil 1b according to the second embodiment comprises a first inductor through the first wire 11 and the second wire 12th is formed, the respective ends of which are connected to the first connection electrode 21 and the second connection electrode 22 connected and a second inductor through the third wire 13 is formed, the ends of which are connected to the third connection electrode 23 and the fourth connection electrode 24th are connected. In the case described above, where the first wire 11 , the second wire 12th and the third wire 13 made of wires with the same specification, a difference is generated between the DC resistance of the first inductor and the DC resistance of the second inductor.

The mode conversion characteristics of the common mode choke 1b can be further improved with suitable measures regarding the difference in direct current resistance described above. In the second embodiment, the following embodiment is preferably adopted as a measure.

As in 8th each includes the first wire 11 , the second wire 12th and the third wire 13 a central conductor track 17th , which is made of a conductor such as copper, with a substantially circular cross section and the insulating coating layer 18th with an electrical insulating property that the peripheral surface of the central conductor 17th covered. Here is the diameter of the central trace 17th of the third wire 3rd set so that it is approximately √-2 times the diameter of the central trace 17th each of the first wire 11 and the second wire 12th is, that is, about 1.3 times or more and about 1.5 times or less.

By adopting the structure as described above, the sum of the cross-sectional area of the central interconnect can 17th of the first wire 11 and the central conductor track 17th of the second wire 12th the same or substantially the same as the cross-sectional area of the central conductor track 17th of the third wire 3rd fail. Thus, the difference in DC resistance between the first inductor through the first wire 11 and the second wire 12th is formed, and the second inductor through the third wire 13 is formed to be zero or essentially zero.

With the common mode choke coil 1b are the first line 11 , the second wire 12th and the third wire 13 all substantially circular in cross-section and have essentially the same outside diameter. Similar to the case of the first embodiment, the above-described condition contributes to stabilizing the winding state of a wire on the upper layer side with respect to a wire on the lower layer side, that is, each of the winding state of the third wire 13 as a wire on the upper layer side with respect to the first wire 11 as a wire on the side of the lower layer and the second wire 12th as a wire on the upper layer side with respect to the third wire 13 as a wire on the bottom layer side.

It is also, similar to the case of the in 2nd illustrated common mode choke coil 1 and the in 5 illustrated common mode choke coil 1a , in the case of the common mode choke coil 1b it is not necessary to provide a section in which a plurality of wires intersect, for example the change region C of the in 11 illustrated common mode choke coil 31a . That is why it is in the case of the common mode choke coil 1b easier to manufacture the same, and the possibility of deterioration in wire quality with, for example damage to the insulating coating layer 18th in the wires 11 to 13 can compared to the case of in 11 illustrated common mode choke coil 31a can be further reduced.

As described above, the in 2nd illustrated common mode choke coil 1 and the in 5 illustrated common mode choke coil 1a regarding the first wire 11 and the third wire 13 the first wire 11 closer to the side of the second end 5 positioned as the third wire 13 while the same with the same number of turns, from the side of the first end 4th counted out, adjoin each other, and with respect to the second wire 12th and the fourth wire 14 , the second wire 12th closer to the side of the first end 4th is positioned as the fourth wire 14 while the same with the same number of turns, from the side of the first end 4th counted out, adjoin each other.

At the in 7 illustrated common mode choke coil 1b is regarding the first wire 11 and the third wire 13 the first wire 11 closer to the side of the second end 5 positioned as the third wire 13 while the same with the same number of turns, from the side of the first end 4th counted out, adjoin each other, and with respect to the second wire 12th and the third wire 13 is the second wire 12th closer to the side of the first end 4th positioned as the third wire 13 while the same with the same number of turns, from the side of the first end 4th counted out, adjoin each other.

That is, any of the common mode chokes 1 , 1a and 1b are two regions in which positional relationships with respect to two wires of a pair forming adjacent layers are opposed to each other are stacked in a direction perpendicular to an axial direction of the winding core portion. Therefore, compared to the technology used in the Japanese Unexamined Patent Application Publication No. 2014-120730 , the degree of unevenness of the distributed capacity is reduced, and the mode conversion characteristics are improved up to a higher frequency range.

In addition, each of the common mode chokes 1 , 1a and 1b adopted a structure in which one wire is shifted one turn from the other wire with respect to two wires of a pair which form adjacent layers while being adjacent to each other with the same number of turns. In this way, if a structure is used in which only one turn is shifted, the stray capacitance generated between the two wires described above can be minimized.

In the present disclosure, with respect to two wires of a pair that form the adjacent layers, there is no limitation to an embodiment in which wires with the same number of turns are shifted by one turn, and an embodiment in which wires with the same number of turns are shifted by two or more turns are shifted can be used. Regarding common mode chokes 1 and 1a can change the amount of turn between the first wire 11 and the third wire 13 and the amount of turn shift between the second wire 12th and the fourth wire 14 differ from each other. Similarly, with respect to the common mode choke coil 1b the amount of turn between the first wire 11 and the third wire 13 and the amount of turn shift between the second wire 12th and the third wire 13 differ from each other.

While this disclosure is described with reference to the exemplary embodiments illustrated in the figures, it is to be understood that various modifications are possible within the scope of the present disclosure.

For example, the number of turns of a wire provided in a common mode choke coil can be increased or decreased as desired.

In addition, the counting direction of the number of turns used in the description of the embodiment can be reversed.

Furthermore, a portion of a plurality of wires included in a common mode choke may have an overlap portion or a twist winding portion in which wires are twisted together.

The illustrated embodiments are exemplary, and partial replacement or combination of implementations between different embodiments is possible.

According to the aspect described above, with respect to certain turns in the first inductor or the second inductor formed by the four wires or the three wires, since stray capacitance can be generated between different turns in a plurality of positions, the degree of freedom in Generating a stray capacitance between different turns can be significantly improved.

While some embodiments of the disclosure 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 revelation. The scope of protection of the disclosure is therefore to be determined solely by the following claims for protection.

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• JP 2014120730 [0044, 0073]

Claims (12)

A common mode choke coil that has the following features: a core including a winding core portion, a first flange portion provided in an axial direction of the winding core portion on a first end side, and a second flange portion provided in the axial direction of the winding core portion on a second end side opposite to the first end side; a first wire, a second wire, a third wire and a fourth wire, each of which is helically wound around the winding core portion; a first connection electrode and a third connection electrode provided on the first flange portion; and a second connection electrode and a fourth connection electrode, which are provided on the second flange section, wherein each of the end portions of the first wire and the second wire on the first end side is connected to the first connection electrode, each of the end sections of the first wire and the second wire on the second end side is connected to the second connection electrode, each of the end portions of the third wire and the fourth wire on the first end side is connected to the third connection electrode, each of the end sections of the third wire and the fourth wire on the second end side is connected to the fourth connection electrode, at least part of the first wire is wound around the winding core section to form a first layer, at least part of the third wire is wound to form a second layer located on an outer peripheral side of the first layer in a recess formed between adjacent turns of the first wire, at least a portion of the fourth wire is wound to form a third layer located on an outer peripheral side of the second layer in a recess formed between adjacent turns of the third wire, and at least a part of the second wire is wound to form a fourth layer, which is located on an outer peripheral side of the third layer in a recess formed between adjacent turns of the fourth wire. The common mode choke coil according to Claim 1 , wherein the first wire, the second wire, the third wire and the fourth wire are wound with a substantially identical number of turns around the winding core section. The common mode choke coil according to Claim 1 or 2nd , wherein the first wire and the third wire have a portion in which the first wire is positioned closer to the second end side than the third wire, while adjoining each other with identical numbers of turns counting from the first end side, and the second Wire and the fourth wire have a portion in which the second wire is positioned closer to the first end side than the fourth wire, while the same adjoin each other with identical numbers of turns, counted from the first end side. The common mode choke coil according to Claim 3 , wherein the third wire and the fourth wire have a portion in which the third wire is positioned closer to the first end side than the fourth wire, while adjoining each other with identical numbers of turns, counting from the first end side. The common mode choke coil according to Claim 3 , wherein the third wire and the fourth wire have a portion in which the third wire is positioned closer to the second end side than the fourth wire, while adjoining each other with identical numbers of turns, counting from the first end side. The common mode choke coil according to one of the Claims 1 to 5 , wherein the first wire, the second wire, the third wire and the fourth wire have a substantially circular cross section and have a substantially identical outer diameter. The common mode choke coil according to Claim 6 , wherein each of the first wire, the second wire, the third wire, and the fourth wire includes a central conductive line made of a conductor having a substantially circular cross section and an insulating coating layer having an electrical insulating property that includes a peripheral surface of the central conductive line covered, the central trace of each of the first wire, the second wire, the third wire and the fourth wire has a substantially identical diameter, and the insulating coating layer of each of the first wire, the second wire, the third wire and the fourth wire is substantially identical Has thickness. A common mode choke coil having a core including a winding core portion, a first flange portion provided in an axial direction of the winding core portion on a first end side, and a second flange portion extending in the axial direction of the Winding core portion is provided on a second end side opposite the first end side; a first wire, a second wire, and a third wire, each of which is helically wound around the winding core portion; a first connection electrode and a third connection electrode provided on the first flange portion; and a second terminal electrode and a fourth terminal electrode provided on the second flange portion, each of the end portions of the first wire and the second wire on the first end side being connected to the first terminal electrode, each of the end portions of the first wire and the second wire the second end side is connected to the second connection electrode, an end section of the third wire on the first end side is connected to the third connection electrode and an end section of the third wire on the second end side is connected to the fourth connection electrode, at least part of the first wire around the Winding core portion is wound to form a first layer, at least part of the third wire is wound to form a second layer located on an outer peripheral side of the first layer in a recess formed between adjacent turns of the first wire, and at least a part of the second wire is wound to form a third layer, which is located on an outer peripheral side of the second layer in a recess formed between adjacent turns of the third wire. The common mode choke coil according to Claim 8 , wherein the first wire, the second wire and the third wire are wound with an essentially identical number of turns around the winding core section. The common mode choke coil according to Claim 8 or 9 , wherein the first wire and the third wire have a portion in which the first wire is positioned closer to the second end side than the third wire, while adjoining each other with identical numbers of turns counting from the first end side, and the second Wire and the third wire have a section in which the second wire is positioned closer to the first end side than the third wire, while the same adjoin each other with identical numbers of turns, counted from the first end side. The common mode choke coil according to one of the Claims 8 to 10th , wherein the first wire, the second wire and the third wire have a substantially circular cross-section and have a substantially identical outer diameter. The common mode choke coil according to one of the Claims 8 to 11 , wherein each of the first wire, the second wire, and the third wire includes a central conductive line made of a conductor having a substantially circular cross section and an insulating coating layer having an electrical insulating property covering a peripheral surface of the central conductive line, and one The diameter of the central conductor of the third wire is 1.3 times or more or 1.5 times or less of a diameter of the central conductor of each of the first wire and the second wire.

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