JP4209851B2 - Common mode choke coil - Google Patents

Description

  The present invention relates to a common mode choke coil.

As this type of common mode choke coil, a laminated body in which a plurality of insulators are laminated, at least three coils that are located in the laminated body and are magnetically coupled to each other, and formed in the laminated body, A device having at least six terminal electrodes electrically connected to the end portion is known (see, for example, Patent Documents 1 and 2). In the common mode choke coils described in Patent Documents 1 and 2, at least three coils are arranged in the stacking direction of the stacked body.
JP 2004-165448 A Japanese Patent No. 3166702

  In the common mode choke coils described in Patent Documents 1 and 2, since at least three coils are juxtaposed in the stacking direction of the laminate, the distance between the coils is constant between the input end and the output end of the coil. Not change. Further, the coil conductors forming each coil are not opposed to each other. For this reason, it is difficult to design the line capacitance between the coil conductors to a desired value, and it is difficult to adjust the characteristic impedance.

  An object of the present invention is to provide a common mode choke coil in which variation in characteristic impedance is small and characteristic impedance can be easily adjusted.

  A common mode choke coil according to the present invention is formed in a laminate in which a plurality of insulators are laminated, at least three coils that are located in the laminate and magnetically coupled to each other, and each of the coils. At least six terminal electrodes electrically connected to the ends, and each coil includes a first lead conductor connected to a corresponding terminal electrode among the at least six terminal electrodes, and a first A coil conductor located on the same layer as the lead conductor and connected to the first lead conductor, and located on a different layer from the first lead conductor and connected to a corresponding terminal electrode among at least six terminal electrodes And a second lead conductor, and the first lead conductor, the coil conductor, and the second lead conductor are electrically connected, and at least One of the first lead conductor and the coil conductor coil has is characterized in that it is arranged in order along the stacking direction so as to be adjacent in the stacking direction of the plurality of insulators.

  In the common mode choke coil according to the present invention, in particular, the first lead conductor and coil conductor of each coil are sequentially arranged along the stacking direction so as to be adjacent to each other in the stacking direction of the plurality of insulators. For this reason, it will be suppressed that the space | interval in the said lamination direction of the coil conductor of each coil changes. As a result, the line capacitance between the coil conductors can be designed to a desired value, and the characteristic impedance can be adjusted.

  Each coil further includes a new coil conductor located in a different layer from the first lead conductor, and the first lead conductor, the coil conductor, the second lead conductor, and the new coil conductor are electrically connected to each other. It is preferable that the new coil conductors configured by being connected and included in at least three coils are juxtaposed in order along the stacking direction so as to be adjacent to each other in the stacking direction of the plurality of insulators. In this case, since the new coil conductors of the coils are also arranged in order along the lamination direction so as to be adjacent to each other in the lamination direction of the plurality of insulators, the new coil conductors of the coils in the lamination direction are arranged. It will be suppressed that a space | interval also changes. As a result, the line capacitance between the coil conductors can be designed to a desired value, and the characteristic impedance can be adjusted.

  The coil conductor and the second lead conductor are electrically connected through the through-hole conductor, and the line length of each coil is set to a desired value by adjusting the position of the through-hole conductor. It is preferable. In this case, the impedance of each coil is finely adjusted, and impedance adjustment can be easily performed.

  The plurality of insulators may be magnetic materials. In this case, the common mode noise can be effectively removed in a frequency band of approximately 1.0 MHz to 1.0 GHz.

  The multilayer body includes a pair of end faces facing each other in the stacking direction of the plurality of insulators, and of the plurality of insulators, adjacent to one end face of the multilayer body among the first lead conductors of each coil. The insulator located between the first lead conductor and the second lead conductor adjacent to the other end face of the multilayer body among the second lead conductors of each coil is a non-magnetic material, and the remaining insulators are A magnetic material is preferred. In this case, the differential mode impedance is reduced, and a common mode choke coil capable of handling a high frequency band can be obtained.

  The stacked body includes a portion positioned so as to surround at least three coils, and a portion positioned so as to sandwich the portion in the stacking direction of the plurality of insulators, and among the plurality of insulators, at least It is preferable that the insulator included in the portion positioned so as to surround the three coils is a non-magnetic body, and the remaining insulator is a magnetic body. In this case, the differential mode impedance is further reduced, and a common mode choke coil that can cope with a higher frequency band can be obtained.

  The at least three coils include a ground line dedicated coil and a pair of signal line dedicated coils. The first lead conductor and the coil conductor of the ground line dedicated coil are the first of the signal line dedicated coils. Preferably, it is located between the first lead conductor and coil conductor of the other signal line dedicated coil and the other lead conductor and coil conductor. In this case, the gap between the coil conductor of the ground line dedicated coil and the coil conductor of one signal line dedicated coil in the stacking direction, and the coil conductor of the ground line dedicated coil and the coil conductor of the other signal line dedicated coil It will be suppressed that the space | interval in the said lamination direction changes. As a result, the line capacitance between the coil conductors can be designed to a desired value, and the characteristic impedance can be adjusted.

  Further, since the coil conductors of the pair of signal line dedicated coils are arranged across the coil conductor of the ground line dedicated coil, the distributed capacity in the coil conductors of the pair of signal line dedicated coils can be kept low. As a result, the filter effect in the high frequency band is improved.

  Each coil further includes a new coil conductor located on a different layer from the first lead conductor, and the new coil conductor included in the ground line dedicated coil is a new coil conductor included in one of the signal line dedicated coils. The coil conductor is preferably located between the coil conductor and a new coil conductor of the other signal line dedicated coil. In this case, the gap between the new coil conductor of the ground line dedicated coil and the new coil conductor of one signal line dedicated coil in the stacking direction, and the new coil conductor of the ground line dedicated coil and the other signal line dedicated It will be suppressed that the space | interval in the said lamination direction with the new coil conductor of a coil changes. As a result, the line capacitance between the coil conductors can be designed to a desired value, and the characteristic impedance can be adjusted.

  In addition, since the new coil conductor of the pair of signal line dedicated coils is disposed across the new coil conductor of the ground line dedicated coil, the distributed capacity of the pair of signal line dedicated coils in the new coil conductor can be kept low. It will be. As a result, the filter effect in the high frequency band is improved.

  According to the present invention, it is possible to provide a common mode choke coil in which variation in characteristic impedance is small and characteristic impedance can be easily adjusted.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description, the same reference numerals are used for the same elements or elements having the same function, and redundant description is omitted. In the description, the terms “upper” and “lower” may be used, which correspond to the vertical direction of each figure.

(First embodiment)
FIG. 1 is a perspective view showing a common mode choke coil according to the first embodiment. FIG. 2 is a schematic diagram for explaining a cross-sectional configuration of the common mode choke coil according to the first embodiment. FIG. 3 is an exploded view showing the common mode choke coil according to the first embodiment.

  The common mode choke coil CC1 according to the first embodiment, as shown in FIGS. 1 to 3, is a stacked type common mode choke coil, and is a rectangular parallelepiped element 1 and first and second signals. Line-dedicated coils 21, 31, a ground line-dedicated coil 41, and terminal electrodes 3 to 8 formed on the side surface of the element body 1 are provided. The first and second signal line dedicated coils 21 and 31 and the ground line dedicated coil 41 are located in the element body 1. The first signal line dedicated coil 21, the second signal line dedicated coil 31, and the ground line dedicated coil 41 are magnetically coupled to each other.

  As shown in FIG. 3, the element body 1 is a laminated body formed by laminating a plurality of (in this embodiment, five layers) insulators 11 to 15. The actual common mode choke coil CC1 is integrated to such an extent that the boundary between the insulators 11 to 15 cannot be visually recognized. The insulators 11 to 15 are configured by firing a magnetic green sheet.

  The first signal line dedicated coil 21 includes a first lead conductor 22, a coil conductor 23, and a second lead conductor 24. The first lead conductor 22 and the coil conductor 23 are located on the insulator 11 and are integrally formed continuously. Thereby, the 1st lead conductor 22 and the coil conductor 23 will be located in the same layer. One end of the first lead conductor 22 is drawn to the side surface of the element body 1 and exposed on the side surface, and is electrically connected to the corresponding terminal electrode 3. The coil conductor 23 has a spiral shape, and its outer end is continuous with the other end of the first lead conductor 22.

  A through-hole conductor 51 a that penetrates the insulator 12 in the thickness direction is formed at a position corresponding to the inner end of the coil conductor 23 in the insulator 12. The through-hole conductor 51a is electrically connected to the inner end of the coil conductor 23 in a state where the insulators 11 and 12 are laminated. On the insulator 12, a land-like inner conductor 61a is located so as to correspond to the through-hole conductor 51a. The inner conductor 61a is electrically connected to the through-hole conductor 51a. The internal conductor 61a functions as a through-hole connection conductor.

  A through-hole conductor 51 b that penetrates the insulator 13 in the thickness direction is formed at a position corresponding to the inner conductor 61 a in the insulator 13. The through-hole conductor 51b is electrically connected to the internal conductor 61a in a state where the insulators 12 and 13 are laminated. On the insulator 13, a land-like inner conductor 61b is positioned so as to correspond to the through-hole conductor 51b. The inner conductor 61b is electrically connected to the through-hole conductor 51b. The internal conductor 61b functions as a through-hole connection conductor.

  A through-hole conductor 51c penetrating the insulator 14 in the thickness direction is formed at a position corresponding to the inner conductor 61b in the insulator 14. The through-hole conductor 51c is electrically connected to the internal conductor 61b in a state where the insulators 13 and 14 are laminated.

  The second lead conductor 24 is located on the insulator 14. As a result, the first lead conductor 22 and the coil conductor 23 and the second lead conductor 24 are located in different layers. One end of the second lead conductor 24 is drawn to the side surface of the element body 1 and exposed on the side surface, and is electrically connected to the corresponding terminal electrode 6. The other end of the second lead conductor 24 extends to a position where the through-hole conductor 51c is formed, and the second lead conductor 24 is electrically connected to the through-hole conductor 51c.

  As described above, the coil conductor 23 and the second lead conductor 24 are electrically connected through the through-hole conductors 51a to 51c and the internal conductors 61a and 61b. As a result, the first lead conductor 22, the coil conductor 23, and the second lead conductor 24 are electrically connected to each other to constitute the first signal line dedicated coil 21.

  The ground line dedicated coil 41 includes a first lead conductor 42, a coil conductor 43, and a second lead conductor 44. The first lead conductor 42 and the coil conductor 43 are located on the insulator 12 and are integrally formed continuously. As a result, the first lead conductor 42 and the coil conductor 43 are located in the same layer. One end of the first lead conductor 42 is drawn to the side surface of the element body 1 and exposed on the side surface, and is electrically connected to the corresponding terminal electrode 4. The coil conductor 43 has a spiral shape, and the outer end is continuous with the other end of the first lead conductor 42.

  A through-hole conductor 52 a that penetrates the insulator 13 in the thickness direction is formed at a position corresponding to the inner end of the coil conductor 43 in the insulator 13. The through-hole conductor 52a is electrically connected to the inner end of the coil conductor 43 in a state where the insulators 12 and 13 are laminated. On the insulator 13, a land-like inner conductor 62a is positioned so as to correspond to the through-hole conductor 52a. The inner conductor 62a is electrically connected to the through-hole conductor 52a. The internal conductor 62a functions as a through-hole connection conductor.

  A through-hole conductor 52b penetrating the insulator 14 in the thickness direction is formed at a position corresponding to the inner conductor 62a in the insulator 14. The through-hole conductor 52b is electrically connected to the internal conductor 62a in a state where the insulators 13 and 14 are laminated.

  The second lead conductor 44 is located on the insulator 14. As a result, the first lead conductor 42 and the coil conductor 43 and the second lead conductor 44 are located in different layers. One end of the second lead conductor 44 is drawn to the side surface of the element body 1 and exposed on the side surface, and is electrically connected to the corresponding terminal electrode 7. The other end of the second lead conductor 44 extends to a position where the through-hole conductor 52b is formed, and the second lead conductor 44 is electrically connected to the through-hole conductor 52b.

  As described above, the coil conductor 43 and the second lead conductor 44 are electrically connected through the through-hole conductors 52a and 52b and the internal conductor 62a. As a result, the first lead conductor 42, the coil conductor 43, and the second lead conductor 44 are electrically connected to each other to form the ground line dedicated coil 41.

  The second signal line dedicated coil 31 includes a first lead conductor 32, a coil conductor 33, and a second lead conductor 34. The first lead conductor 32 and the coil conductor 33 are located on the insulator 13 and are integrally formed continuously. Thereby, the 1st lead conductor 32 and the coil conductor 33 will be located in the same layer. One end of the first lead conductor 32 is drawn to the side surface of the element body 1 and exposed on the side surface, and is electrically connected to the corresponding terminal electrode 5. The coil conductor 33 has a spiral shape, and the outer end is continuous with the other end of the first lead conductor 32.

  A through-hole conductor 53 a that penetrates the insulator 14 in the thickness direction is formed at a position corresponding to the inner end of the coil conductor 33 in the insulator 14. The through-hole conductor 53a is electrically connected to the inner end of the coil conductor 33 in a state where the insulators 13 and 14 are laminated.

  The second lead conductor 34 is located on the insulator 14. As a result, the first lead conductor 32 and the coil conductor 33 and the second lead conductor 34 are located in different layers. One end of the second lead conductor 34 is drawn to the side surface of the element body 1 and exposed on the side surface, and is electrically connected to the corresponding terminal electrode 8. The other end of the second lead conductor 34 extends to a position where the through-hole conductor 53a is formed, and the second lead conductor 34 is electrically connected to the through-hole conductor 53a.

  As described above, the coil conductor 33 and the second lead conductor 34 are electrically connected through the through-hole conductor 53a. As a result, the first lead conductor 32, the coil conductor 33, and the second lead conductor 34 are electrically connected to each other to constitute the second signal line dedicated coil 31.

  The coil conductors 23, 33, and 43 are mostly viewed from the direction in which the insulators 11 to 14 are laminated (hereinafter simply referred to as “lamination direction”) in the spiral portions of the coil conductors 23, 33, and 43. It extends to overlap each other. The first lead conductor 22 and the coil conductor 23, and the first lead conductor 42 and the coil conductor 43 are arranged with an interval corresponding to the thickness of the insulator 12 when viewed in the stacking direction. . The first lead conductor 42 and the coil conductor 43 and the first lead conductor 32 and the coil conductor 33 are arranged with an interval corresponding to the thickness of the insulator 13 when viewed in the stacking direction. . Any interval described above is set to a length that allows the first and second signal line dedicated coils 21 and 31 and the ground line dedicated coil 41 to be magnetically coupled.

  In the common mode choke coil CC1, as described above, the first lead conductor 22 and the coil conductor 23 are located on the insulator 11, the first lead conductor 42 and the coil conductor 43 are located on the insulator 12, The first lead conductor 32 and the coil conductor 33 are located on the insulator 13. Therefore, the first lead conductor 22 and the coil conductor 23, the first lead conductor 42 and the coil conductor 43, and the first lead conductor 32 and the coil conductor 33 are adjacent to each other in the stacking direction in the stacking direction. Will be arranged in order.

  The insulator 15 is located on the insulator 14 and functions as a base layer for protecting the second lead conductors 24, 34, and 44. The insulator 15 is also for adjusting the element body 1 to a predetermined thickness, and the number of insulators 15 is not limited to one layer. Further, an insulator may be positioned under the insulator 11 in order to adjust the element body 1 to a predetermined thickness dimension.

  Next, a method for manufacturing the common mode choke coil CC1 will be described.

  First, magnetic green sheets that constitute the insulators 11 to 15 are prepared. Next, through holes are formed by laser processing or the like at predetermined positions of the magnetic green sheets that constitute the insulators 12 to 14, that is, positions where the through hole conductors 51a to 53a are to be formed.

  Next, conductor patterns corresponding to the respective conductors 22 to 24, 32 to 34, 42 to 44, and 61a to 62a are formed on the respective magnetic green sheets constituting the insulators 11 to 14. Each conductor pattern is formed, for example, by screen-printing a conductor paste (conductor material) mainly composed of silver or nickel and then drying. Each through hole is filled with a conductor paste when each conductor pattern is formed.

  The magnetic green sheet is a slurry made of, for example, ferrite (for example, Ni—Cu—Zn based ferrite, Ni—Cu—Zn—Mg based ferrite, Cu—Zn based ferrite, or Ni—Cu based ferrite) powder. Can be used which is formed by coating the film by a doctor blade method. The thickness of the magnetic green sheet is, for example, about 20 μm.

  Next, the green sheets are sequentially laminated and pressure-bonded, cut into chips, and then fired at a predetermined temperature (for example, 800 to 900 degrees). As a result, the element body 1 is formed. The element body 1 has, for example, a length in the longitudinal direction after firing of 2.0 mm, a width of 1.25 mm, and a height of 0.8 mm. The width of each conductor 22 to 24, 32 to 34, 42 to 44 after firing is set to about 50 μm, for example. The thickness of each of the conductors 22 to 24 and 32 to 34 after firing is set to about 14 μm, for example. The pattern interval of each coil conductor 23, 33, 43 is set to about 60 μm, for example.

  Next, terminal electrodes 3 to 8 are formed on the element body 1. As a result, the common mode choke coil CC1 is formed. The terminal electrodes 3 to 8 are baked at a predetermined temperature (for example, about 700 ° C.) after transferring an electrode paste mainly composed of silver, nickel or copper to the outer surface of the element body 1 obtained as described above. It is formed by applying electroplating. For electroplating, Cu / Ni / Sn, Ni / Sn, Ni / Au, Ni / Pd / Au, Ni / Pd / Ag, Ni / Ag, or the like can be used. The characteristic impedance of the common mode choke coil CC1 can be set to 100Ω, for example.

  As described above, in the present embodiment, the first lead conductor 22 and the coil conductor 23 of the first signal line dedicated coil 21, the first lead conductor 42 and the coil conductor 43 of the ground line dedicated coil 41, The first lead conductor 32 and the coil conductor 33 of the second signal line dedicated coil 31 are sequentially arranged along the stacking direction so as to be adjacent to each other in the stacking direction. For this reason, it is suppressed that the space | interval in the lamination direction of the coil conductors 23, 43, and 33 of each coil 21, 41, and 31 changes. As a result, the line capacitance between the coil conductors 23, 43 and 33 can be designed to a desired value, and the characteristic impedance of the common mode choke coil CC1 can be adjusted.

  In the present embodiment, the coil conductor 23 of the first signal line dedicated coil 21 and the coil conductor 33 of the second signal line dedicated coil 31 are arranged with the coil conductor 43 of the ground line dedicated coil 41 interposed therebetween. Therefore, the distributed capacity in the coil conductors 23 and 33 of the first and second signal line dedicated coils 21 and 31 is kept low. As a result, in the common mode choke coil CC1, the filter effect in the high frequency band is improved.

  Moreover, in this embodiment, each insulator 11-15 is a magnetic body. As a result, the common mode choke coil CC1 can effectively remove common mode noise in a frequency band of approximately 1.0 MHz to 1.0 GHz.

In the present embodiment, the insulators 12 to 14 may be nonmagnetic materials. In this case, a non-magnetic green sheet is used as the green sheet that constitutes the insulators 12 to 14. As the non-magnetic green sheet, for example, a slurry obtained by applying a slurry using a mixed powder of Fe ₂ O ₃ , ZnO and CuO as a raw material on a film by a doctor blade method can be used. The thickness of the nonmagnetic green sheet can be set to about 18 μm, for example.

  By making the insulators 12 to 14 nonmagnetic, the element body 1 including a pair of end faces opposed to each other in the stacking direction is the first lead conductor of each of the coils 21, 31, and 41 among the insulators 11 to 15. Among the second lead conductors 24, 34, 44 of the coils 21, 31, 41 from the first lead conductor 22 adjacent to one end face of the element body 1, of the elements 22, 32, 42, the other of the element body 1. The insulators 12 to 14 positioned between the second lead conductors 24, 34, and 44 adjacent to the end face are nonmagnetic, and the remaining insulators 11 and 15 are magnetic. As a result, the differential mode impedance is reduced, and the common mode choke coil CC1 capable of handling a high frequency band can be obtained.

  In the present embodiment, the insulators 11 to 15 may be non-magnetic materials, and the insulators 11 to 15 may be further sandwiched between the magnetic materials 16 (see FIG. 4). In this case, the insulators 11 to 15 included in the portion located so as to surround each of the coils 21, 31 and 41 in the element body 1 are non-magnetic materials and are positioned so as to sandwich the insulators 11 to 15 in the stacking direction. The insulator included in the portion is the magnetic body 16. That is, the conductors 22, 23, 24 of the first signal line dedicated coil 21, the conductors 32, 33, 34 of the second signal line dedicated coil 31, and the conductors 42, 43, 44 of the ground line dedicated coil 41 are non- It will be in contact with the magnetic material. As a result, the impedance of the differential mode is further reduced, and the common mode choke coil CC1 that can cope with a higher frequency band can be obtained.

  In the present embodiment, the coil conductors 23, 33, 43 and the second lead conductors 24, 34, 44 are electrically connected through corresponding through-hole conductors 51a to 53a. As shown, the line lengths of the coils 21, 31, 41 can be set to desired values by adjusting the positions of the through-hole conductors 51a-53a. In this case, the characteristic impedance of each coil 21, 31, 41 is finely adjusted, and the characteristic impedance can be easily adjusted.

(Second Embodiment)
FIG. 7 is a schematic diagram for explaining a cross-sectional configuration of the common mode choke coil according to the second embodiment. FIG. 8 is an exploded configuration diagram of the common mode choke coil according to the second embodiment.

  The common mode choke coil CC2 according to the second embodiment is a stacked type common mode choke coil, like the common mode choke coil CC2 according to the first embodiment, as shown in FIGS. The rectangular parallelepiped element body 1, the first and second signal line dedicated coils 21 and 31, the ground line dedicated coil 41, and the terminal electrodes 3 to 8 formed on the side surfaces of the element body 1 are provided. .

  As shown in FIG. 8, the element body 1 is a stacked body formed by stacking a plurality of (in this embodiment, 10 layers) insulators 71 to 80. The actual common mode choke coil CC2 is integrated so that the boundary between the insulators 71 to 80 cannot be visually recognized. The insulators 71 to 80 are configured by firing a magnetic green sheet.

  The first signal line dedicated coil 21 includes a first lead conductor 22, coil conductors 23 a to 23 c, and a second lead conductor 24. The second signal line dedicated coil 31 includes a first lead conductor 32, coil conductors 33 a to 33 c, and a second lead conductor 34. The ground line dedicated coil 41 includes a first lead conductor 42, coil conductors 43 a to 43 c, and a second lead conductor 44.

  The first lead conductor 22 and the coil conductor 23a are located on the insulator 71 and are integrally formed continuously. Thereby, the 1st lead conductor 22 and the coil conductor 23a will be located in the same layer. One end of the coil conductor 23 a is continuous with the other end of the first lead conductor 22.

  A through-hole conductor 81 a that penetrates the insulator 72 in the thickness direction is formed at a position corresponding to the other end of the coil conductor 23 a in the insulator 72. The through-hole conductor 81a is electrically connected to the other end of the coil conductor 23a in a state where the insulators 71 and 72 are laminated. On the insulator 72, a land-like inner conductor 91a is located so as to correspond to the through-hole conductor 81a. The internal conductor 91a is electrically connected to the through-hole conductor 81a. The internal conductor 91a functions as a through-hole connection conductor.

  A through-hole conductor 81 b penetrating the insulator 73 in the thickness direction is formed at a position corresponding to the inner conductor 91 a in the insulator 73. The through-hole conductor 81b is electrically connected to the internal conductor 91a in a state where the insulators 72 and 73 are laminated. On the insulator 73, a land-like inner conductor 91b is positioned so as to correspond to the through-hole conductor 81b. The internal conductor 91b is electrically connected to the through-hole conductor 81b. The internal conductor 91b functions as a through-hole connection conductor.

  A through-hole conductor 81c penetrating the insulator 74 in the thickness direction is formed at a position corresponding to the inner conductor 91b in the insulator 74. The through-hole conductor 81c is electrically connected to the internal conductor 91b in a state where the insulators 73 and 74 are laminated.

  The coil conductor 23 b is located on the insulator 74. Thus, the first lead conductor 22, the coil conductor 23a, and the coil conductor 23b are located in different layers. One end of the coil conductor 23b extends to a position where the through-hole conductor 81c is formed, and the coil conductor 23b is electrically connected to the through-hole conductor 81c.

  A through-hole conductor 82a penetrating the insulator 75 in the thickness direction is formed at a position corresponding to the other end of the coil conductor 23b in the insulator 75. The through-hole conductor 82a is electrically connected to the other end of the coil conductor 23b in a state where the insulators 74 and 75 are laminated. On the insulator 75, a land-like inner conductor 92a is positioned so as to correspond to the through-hole conductor 82a. The inner conductor 92a is electrically connected to the through-hole conductor 82a. The internal conductor 92a functions as a through-hole connection conductor.

  A through-hole conductor 82b penetrating the insulator 76 in the thickness direction is formed at a position corresponding to the inner conductor 92a in the insulator 76. The through-hole conductor 82b is electrically connected to the internal conductor 92a in a state where the insulators 75 and 76 are laminated. On the insulator 76, a land-like inner conductor 92b is positioned so as to correspond to the through-hole conductor 82b. The inner conductor 92b is electrically connected to the through-hole conductor 82b. The internal conductor 92b functions as a through-hole connection conductor.

  A through-hole conductor 82c penetrating the insulator 77 in the thickness direction is formed at a position corresponding to the inner conductor 92b in the insulator 77. The through-hole conductor 82c is electrically connected to the internal conductor 92b in a state where the insulators 76 and 77 are laminated.

  The coil conductor 23c and the second lead conductor 24 are located on the insulator 77 and are integrally formed continuously. As a result, the first lead conductor 22 and the coil conductor 23a, and the coil conductor 23c and the second lead conductor 24 are located in different layers. One end of the coil conductor 23c extends to a position where the through-hole conductor 82c is formed, and the coil conductor 23c is electrically connected to the through-hole conductor 82c. The other end of the coil conductor 23 c is continuous with the other end of the second lead conductor 24.

  As described above, the coil conductor 23a and the coil conductor 23c are electrically connected through the through-hole conductors 81a to 81c and 82a to 82c and the internal conductors 91a, 91b, 92a, and 92b. Accordingly, the first lead conductor 22, the coil conductors 23a to 23c, and the second lead conductor 24 are electrically connected to each other, thereby constituting the first signal line dedicated coil 21.

  The first lead conductor 42 and the coil conductor 43a are located on the insulator 72 and are integrally formed continuously. Thereby, the 1st lead conductor 42 and the coil conductor 43a will be located in the same layer. One end of the coil conductor 43 a is continuous with the other end of the first lead conductor 42.

  A through-hole conductor 83a penetrating the insulator 73 in the thickness direction is formed at a position corresponding to the other end of the coil conductor 43a in the insulator 73. The through-hole conductor 83a is electrically connected to the other end of the coil conductor 43a in a state where the insulators 72 and 73 are laminated. On the insulator 73, a land-like inner conductor 93a is positioned so as to correspond to the through-hole conductor 83a. The inner conductor 93a is electrically connected to the through-hole conductor 83a. The internal conductor 93a functions as a through-hole connection conductor.

  A through-hole conductor 83b penetrating the insulator 74 in the thickness direction is formed at a position corresponding to the inner conductor 93a in the insulator 74. The through-hole conductor 83b is electrically connected to the internal conductor 93a in a state where the insulators 73 and 74 are laminated. On the insulator 74, a land-like inner conductor 93b is positioned so as to correspond to the through-hole conductor 83b. The inner conductor 93b is electrically connected to the through-hole conductor 83b. The internal conductor 93b functions as a through-hole connection conductor.

  A through-hole conductor 83c that penetrates the insulator 75 in the thickness direction is formed at a position corresponding to the inner conductor 93b in the insulator 75. The through-hole conductor 83c is electrically connected to the internal conductor 93b in a state where the insulators 74 and 75 are laminated.

  The coil conductor 43b is located on the insulator 75. Thus, the first lead conductor 42, the coil conductor 43a, and the coil conductor 43b are located in different layers. One end of the coil conductor 43b extends to a position where the through-hole conductor 83c is formed, and the coil conductor 43b is electrically connected to the through-hole conductor 83c.

  A through-hole conductor 84a penetrating the insulator 76 in the thickness direction is formed at a position corresponding to the other end of the coil conductor 43b in the insulator 76. The through-hole conductor 84a is electrically connected to the other end of the coil conductor 43b in a state where the insulators 75 and 76 are laminated. On the insulator 76, a land-like inner conductor 94a is positioned so as to correspond to the through-hole conductor 84a. The inner conductor 94a is electrically connected to the through-hole conductor 84a. The internal conductor 94a functions as a through-hole connection conductor.

  A through-hole conductor 84b penetrating the insulator 77 in the thickness direction is formed at a position corresponding to the inner conductor 94a in the insulator 77. The through-hole conductor 84b is electrically connected to the internal conductor 94a in a state where the insulators 76 and 77 are laminated. On the insulator 77, a land-like inner conductor 94b is positioned so as to correspond to the through-hole conductor 84b. The inner conductor 94b is electrically connected to the through-hole conductor 84b. The internal conductor 94b functions as a through-hole connection conductor.

  A through-hole conductor 84c penetrating the insulator 78 in the thickness direction is formed at a position corresponding to the inner conductor 94b in the insulator 78. The through-hole conductor 84c is electrically connected to the internal conductor 94b in a state where the insulators 77 and 78 are laminated.

  The coil conductor 43c and the second lead conductor 44 are located on the insulator 78 and are integrally formed continuously. As a result, the first lead conductor 42 and the coil conductor 43a, and the coil conductor 43c and the second lead conductor 44 are located in different layers. One end of the coil conductor 43c extends to a position where the through-hole conductor 84c is formed, and the coil conductor 43c is electrically connected to the through-hole conductor 84c. The other end of the coil conductor 43 c is continuous with the other end of the second lead conductor 44.

  As described above, the coil conductor 43a and the coil conductor 43c are electrically connected through the through-hole conductors 83a to 83c and 84a to 84c and the internal conductors 93a, 93b, 94a, and 94b. Accordingly, the first lead conductor 42, the coil conductors 43a to 43c, and the second lead conductor 44 are electrically connected to each other, thereby constituting the ground line dedicated coil 41.

  The first lead conductor 32 and the coil conductor 33a are located on the insulator 73 and are integrally formed continuously. Thereby, the 1st lead conductor 32 and the coil conductor 33a will be located in the same layer. One end of the coil conductor 33 a is continuous with the other end of the first lead conductor 32.

  A through-hole conductor 85 a that penetrates the insulator 74 in the thickness direction is formed at a position corresponding to the other end of the coil conductor 33 a in the insulator 74. The through-hole conductor 85a is electrically connected to the other end of the coil conductor 33a in a state where the insulators 73 and 74 are laminated. On the insulator 74, a land-like inner conductor 95a is located so as to correspond to the through-hole conductor 85a. The inner conductor 95a is electrically connected to the through-hole conductor 85a. The inner conductor 95a functions as a through-hole connection conductor.

  A through-hole conductor 85 b that penetrates the insulator 75 in the thickness direction is formed at a position corresponding to the inner conductor 95 a in the insulator 75. The through-hole conductor 85b is electrically connected to the inner conductor 95a in a state where the insulators 74 and 75 are laminated. On the insulator 75, a land-like inner conductor 95b is positioned so as to correspond to the through-hole conductor 85b. The inner conductor 95b is electrically connected to the through-hole conductor 85b. The inner conductor 95b functions as a through-hole connection conductor.

  A through-hole conductor 85c penetrating the insulator 76 in the thickness direction is formed at a position corresponding to the inner conductor 95b in the insulator 76. The through-hole conductor 85c is electrically connected to the internal conductor 95b in a state where the insulators 75 and 76 are laminated.

  The coil conductor 33 b is located on the insulator 76. Thus, the first lead conductor 32, the coil conductor 33a, and the coil conductor 33b are located in different layers. One end of the coil conductor 33b extends to a position where the through-hole conductor 85c is formed, and the coil conductor 33b is electrically connected to the through-hole conductor 85c.

  A through-hole conductor 86a that penetrates the insulator 77 in the thickness direction is formed at a position corresponding to the other end of the coil conductor 33b in the insulator 77. The through-hole conductor 86a is electrically connected to the other end of the coil conductor 33b in a state where the insulators 76 and 77 are laminated. On the insulator 77, a land-like inner conductor 96a is located so as to correspond to the through-hole conductor 86a. The inner conductor 96a is electrically connected to the through-hole conductor 86a. The inner conductor 96a functions as a through-hole connection conductor.

  A through-hole conductor 86b penetrating the insulator 78 in the thickness direction is formed at a position corresponding to the inner conductor 96a in the insulator 78. The through-hole conductor 86b is electrically connected to the internal conductor 96a in a state where the insulators 77 and 78 are laminated. On the insulator 78, a land-like inner conductor 96b is located so as to correspond to the through-hole conductor 86b. The inner conductor 96b is electrically connected to the through-hole conductor 86b. The internal conductor 96b functions as a through-hole connection conductor.

  A through-hole conductor 86c that penetrates the insulator 79 in the thickness direction is formed at a position corresponding to the inner conductor 96b in the insulator 79. The through-hole conductor 86c is electrically connected to the internal conductor 96b in a state where the insulators 78 and 79 are laminated.

  The coil conductor 33c and the second lead conductor 34 are located on the insulator 79 and are integrally formed continuously. As a result, the first lead conductor 32 and the coil conductor 33a, and the coil conductor 33c and the second lead conductor 34 are located in different layers. One end of the coil conductor 33c extends to a position where the through-hole conductor 86c is formed, and the coil conductor 33c is electrically connected to the through-hole conductor 86c. The other end of the coil conductor 33 c is continuous with the other end of the second lead conductor 34.

  As described above, the coil conductor 33a and the coil conductor 33c are electrically connected through the through-hole conductors 85a to 85c and 86a to 86c and the internal conductors 95a, 95b, 96a, and 96b. Thus, the first lead conductor 32, the coil conductors 33a to 33c, and the second lead conductor 34 are electrically connected to each other, thereby constituting the second signal line dedicated coil 31.

  The coil conductors 23a to 23c, 33a to 33c, and 43a to 43c are configured so that most of the coil conductors 23a to 23c, 33a to 33c, and 43a to 43c are stacked in the direction in which the insulators 71 to 79 are stacked (hereinafter simply referred to as “stacking”). It is extended so that it may mutually overlap seeing from a direction. The coil conductors 23a to 23c and the coil conductors 43a to 43c are arranged with an interval corresponding to the thickness of the insulators 72, 75, and 78 positioned therebetween when viewed in the stacking direction. The coil conductors 43a to 43c and the coil conductors 33a to 33c are arranged with an interval corresponding to the thickness of the insulators 73, 76, and 79 positioned therebetween when viewed in the stacking direction. Any interval described above is set to a length that allows the first and second signal line dedicated coils 21 and 31 and the ground line dedicated coil 41 to be magnetically coupled.

  In the common mode choke coil CC2, as described above, the first lead conductor 22 and the coil conductor 23a are located on the insulator 71, and the first lead conductor 42 and the coil conductor 43a are located on the insulator 72. The first lead conductor 32 and the coil conductor 33 a are located on the insulator 73. Therefore, the first lead conductor 22 and the coil conductor 23a, the first lead conductor 42 and the coil conductor 43a, and the first lead conductor 32 and the coil conductor 33a are adjacent to each other in the stacking direction in the stacking direction. Will be arranged in order.

  The coil conductor 23 b is located on the insulator 74, the coil conductor 43 b is located on the insulator 75, and the coil conductor 33 b is located on the insulator 76. Therefore, the coil conductor 23b, the coil conductor 43b, and the coil conductor 33b are sequentially arranged along the stacking direction so as to be adjacent to each other in the stacking direction. The coil conductor 23 c is located on the insulator 77, the coil conductor 43 c is located on the insulator 78, and the coil conductor 33 c is located on the insulator 79. Therefore, the coil conductor 23c, the coil conductor 43c, and the coil conductor 33c are sequentially arranged along the stacking direction so as to be adjacent to each other in the stacking direction.

  The insulator 80 is located on the insulator 79 and functions as a base layer for protecting the coil conductor 33 c and the second lead conductor 34. The insulator 80 is also for adjusting the element body 1 to a predetermined thickness dimension, and the number of the insulators 80 is not limited to one layer. Further, an insulator may be disposed under the insulator 71 in order to adjust the element body 1 to a predetermined thickness dimension.

  As described above, in the present embodiment, as in the first embodiment, the first lead conductor 22 and the coil conductor 23a of the first signal line dedicated coil 21 and the first lead of the ground line dedicated coil 41 are provided. The conductor 42 and the coil conductor 43a, and the first lead conductor 32 and the coil conductor 33a of the second signal line dedicated coil 31 are sequentially arranged along the stacking direction so as to be adjacent to each other in the stacking direction. Further, the coil conductor 23b, the coil conductor 43b, and the coil conductor 33b are sequentially arranged along the lamination direction so as to be adjacent to each other in the lamination direction, and the coil conductor 23c, the coil conductor 43c, and the coil conductor 33c are adjacent to each other in the lamination direction. Thus, they will be arranged in order along the stacking direction. For this reason, it will be suppressed that the space | interval in the lamination direction of the coil conductors 23a-23c, 43-43c, 33-33c of each coil 21,41,31 changes. As a result, the line capacitance between the coil conductors 23a-23c, 43-43c, 33a-33c can be designed to a desired value, and the characteristic impedance of the common mode choke coil CC2 can be adjusted.

  In the present embodiment, the coil conductors 23a to 23c of the first signal line dedicated coil 21 and the coil conductor 33a of the second signal line dedicated coil 31 are sandwiched between the coil conductors 43 to 43c of the ground line dedicated coil 41. ˜33c are arranged, the distributed capacity in each of the coil conductors 23a-23c, 33a-33c of the first and second signal line dedicated coils 21, 31 is kept low. As a result, in the common mode choke coil CC2, the filter effect in the high frequency band is improved.

  Moreover, in this embodiment, each insulator 71-80 is a magnetic body. As a result, the common mode choke coil CC2 can effectively remove common mode noise in a frequency band of approximately 1.0 MHz to 1.0 GHz.

  In the present embodiment, the insulators 72 to 79 may be nonmagnetic materials. In this case, the element body 1 including a pair of end faces opposed to each other in the stacking direction is the insulator body 1 to 80 of the first lead conductors 22, 32, and 42 of the coils 21, 31, and 41. From the first lead conductor 22 adjacent to one end face to the second lead conductor 34 adjacent to the other end face of the element body 1 out of the second lead conductors 24, 34, 44 of the coils 21, 31, 41. The insulators 72 to 79 positioned between the two are nonmagnetic materials, and the remaining insulators 11 and 15 are magnetic materials. As a result, the differential mode impedance is reduced, and the common mode choke coil CC2 capable of handling a high frequency band can be obtained.

  In the present embodiment, the insulators 71 to 80 may be nonmagnetic materials, and the insulators 71 to 80 may be further sandwiched between magnetic materials. In this case, the insulators 71 to 80 included in the portion positioned so as to surround the coils 21, 31, and 41 in the element body 1 are nonmagnetic, and are positioned so as to sandwich the insulators 71 to 80 in the stacking direction. The insulator contained in the portion is a magnetic material. That is, the respective conductors 22, 23a to 23c, 24 of the first signal line dedicated coil 21, the second signal line dedicated coil 31, the respective conductors 32, 33a to 33c, 34, and the ground line dedicated coil 41, the respective conductors 42, 43a to 43c and 44 will be in contact with a non-magnetic material. As a result, the differential mode impedance is further reduced, and the common mode choke coil CC2 that can cope with a higher frequency band can be obtained.

  Also in the present embodiment, by adjusting the positions of the through-hole conductors 81a to 81c, 82a to 82c, 83a to 83c, 84a to 84c, 85a to 85c, 86a to 86c, the coils 21, 31, 41 can be adjusted. The line length may be set to a desired value. As a result, the characteristic impedance of each of the coils 21, 31, 41 is finely adjusted, and the characteristic impedance can be easily adjusted.

  The common mode choke coils CC1 and CC2 according to the present embodiment can be matched with the characteristic impedance of the interface standard adopting the TMDS (Transition Minimized Differential Signaling) transmission method.

  The preferred embodiments of the present invention have been described above, but the present invention is not necessarily limited to these embodiments. For example, the present invention can also be applied to a common mode choke coil array having a plurality of first signal line dedicated coils 21, a ground line dedicated coil 41, and a second signal line dedicated coil 31.

It is a perspective view which shows the common mode choke coil which concerns on 1st Embodiment. It is a schematic diagram for demonstrating the cross-sectional structure of the common mode choke coil which concerns on 1st Embodiment. It is the block diagram which decomposed | disassembled and showed the common mode choke coil which concerns on 1st Embodiment. It is the block diagram which decomposed | disassembled and showed the modification of the common mode choke coil which concerns on 1st Embodiment. It is the block diagram which decomposed | disassembled and showed the modification of the common mode choke coil which concerns on 1st Embodiment. It is the block diagram which decomposed | disassembled and showed the modification of the common mode choke coil which concerns on 1st Embodiment. It is a schematic diagram for demonstrating the cross-sectional structure of the common mode choke coil which concerns on 2nd Embodiment. It is the block diagram which decomposed | disassembled and showed the common mode choke coil which concerns on 2nd Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Elementary body, 3-8 ... Terminal electrode, 11-15, 71-80 ... Insulator, 16 ... Magnetic body, 21 ... First signal line coil, 22, 32, 42 ... First lead conductor, 23, 23a-23c, 33, 33a-33c, 43, 43a-43c ... coil conductor, 24, 34, 44 ... second lead conductor, 31 ... second signal line dedicated coil, 41 ... ground line dedicated coil, 51a to 51c, 52a, 52b, 53a, 81a to 81c, 82a to 82c, 83a to 83c, 84a to 84c, 85a to 85c, 86a to 86c ... through-hole conductors, 61a, 61b, 62a, 91a, 91b, 92a, 92b, 93a, 93b, 94a, 94b, 95a, 95b, 96a, 96b ... internal conductors, CC1, CC2 ... common mode choke coils.

Claims (5)

A laminate in which a plurality of insulators are laminated;
Three coils located in the laminate and magnetically coupled to each other;
6 terminal electrodes formed in the laminate and electrically connected to respective ends of the coils, and
Each coil is
A first lead conductor connected to a corresponding terminal electrode among the six terminal electrodes;
A first coil conductor located in the same layer as the first lead conductor and connected to the first lead conductor;
A second coil conductor located in a different layer from the first lead conductor;
A second lead conductor located on a different layer from the first lead conductor and connected to a corresponding terminal electrode among the six terminal electrodes, and
The first lead conductor, the first and second coil conductors, and the second lead conductor are electrically connected, and
The first lead conductor and the first coil conductor of the three coils are sequentially arranged along the stacking direction so as to be adjacent to each other in the stacking direction of the plurality of insulators ,
The second coil conductors of the three coils correspond to the order of arrangement of the first lead conductors and the first coil conductors, and are adjacent to each other in the stacking direction of the plurality of insulators along the stacking direction. Arranged in order,
The three coils include a ground line dedicated coil and a pair of signal line dedicated coils,
The first lead conductor and the first coil conductor included in the ground line dedicated coil include the first lead conductor and the first coil conductor included in one signal line dedicated coil, and the other signal line dedicated coil. Located between the first lead conductor and the first coil conductor,
The second coil conductor of the ground line dedicated coil is located between the second coil conductor of one signal line dedicated coil and the second coil conductor of the other signal line dedicated coil. A common mode choke coil. The first coil conductor and the second coil conductor are electrically connected through a through-hole conductor,
The common mode choke coil according to claim 1, wherein the line length of each coil is set to a desired value by adjusting the position of the through-hole conductor. Common mode choke coil according to claim 1 or 2, wherein the plurality of insulators are magnetic. The stacked body includes a pair of end faces facing in the stacking direction of the plurality of insulators,
Of the plurality of insulators, among the first lead conductors of the coils, the multilayer of the second lead conductors of the coils from the first lead conductor adjacent to one end surface of the multilayer body. 3. The insulator located between the other end surface of the body and the second lead conductor adjacent to the other end surface is a non-magnetic body, and the remaining insulator is a magnetic body. Common mode choke coil as described. The stacked body includes a portion positioned so as to surround the at least three coils, and a portion positioned so as to sandwich the portion in the stacking direction of the plurality of insulators,
2. The insulator included in the portion positioned so as to surround the at least three coils among the plurality of insulators is a non-magnetic body, and the remaining insulators are magnetic bodies. Or the common mode choke coil of Claim 2.

Images