JP2007281379A - Laminated inductor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a structure, suitable especially for a power inductor, in which high inductance is obtained by increasing the number of turns, lowering of a Q value and increase of loss are prevented, and the height is lowered. <P>SOLUTION: A laminated inductor 10 has a structure wherein a magnetic layer having electric insulation property and an internal conductor layer are alternately laminated, and a coil pattern of the internal conductor layer is connected in order, thereby a coil which rounds while superimposing in a laminating direction in an electric insulator is formed, and both ends of the coil are lead out from an outer surface of a laminate to be connected to an external electrode 14. A coil pattern 20 of the internal conductor layer has an 8-shaped form, and two inner magnetic channels by the 8-shaped coil pattern is so made as to have cumulative connection, and further all or a part of an outer region of the coil formed by the coil pattern in the laminate is made a nonmagnetic substance to decrease a magnetic flux passing through the outer region of the coil. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an inductor having a multilayer structure, and more particularly, to a multilayer inductor in which a high inductance can be obtained even when the number of layers is small by forming a winding pattern of an inner conductor layer into a figure 8 shape. It is. This multilayer inductor is particularly suitable for power inductors for mobile applications.

  In the past, power inductors used in power circuits such as DC-DC converters were generally configured by winding a coil around a magnetic core. However, in recent years, there has been a demand for smaller and thinner power circuit components. Along with this, chip components with a laminated structure have been developed and put into practical use. Such a power inductor having a laminated structure is often used as a power source for mobile portable devices, and is the largest component among DC-DC converter components although it is small. Up to now, chips with a height of about 1 mm have been frequently used. Recently, however, there is an increasing demand for further reduction in height, such as 0.8 mm or 0.5 mm.

  Multilayer inductors have an electrical insulating magnetic layer and an inner conductor layer that are alternately stacked, and the winding patterns of the inner conductor layer are connected in sequence, so that they spiral around the electrical insulator in the stacking direction. In this structure, both ends of the coil are drawn out to the outer surface of the multilayer chip and connected to the external electrodes. That is, the coil is embedded in the laminated body made of a magnetic material. Here, the magnetic layer and the inner conductor layer are formed and stacked by using, for example, a screen printing technique.

  Conventional multilayer inductors generally form a coil by laminating and sequentially connecting internal conductor layers having a winding pattern of less than one turn per layer (for example, 1/2 turn or 3/4 turn). (For example, refer to Patent Document 1). However, in such a configuration, since it is difficult to increase the number of turns (the number of internal conductor layers) with a low-profile structure, it is difficult to obtain a high inductance.

  By the way, white LEDs are frequently used in liquid crystal backlights of small mobile devices such as mobile phones. A boost converter power supply for LED lighting of this type of liquid crystal backlight is characterized by a high voltage (about 15 V) and a small current (about 20 mA), and a high-inductance power inductor is required. Since it is difficult to obtain a high inductance for such applications, the conventional multilayer inductor as described above is not suitable.

As a technique for obtaining a multilayer inductor having a high inductance with a small number of layers, a configuration has been proposed in which two coils are arranged in parallel in a multilayer chip so that currents flow in opposite directions to each other. (See Patent Document 2). However, in this winding configuration, there is a problem that the Q value decreases and the loss increases.
Japanese Patent Publication No. 6-56812 JP-A-9-63848

  The problem to be solved by the present invention is that a high inductance can be obtained by increasing the number of turns, and further, a reduction in Q value and an increase in loss can be prevented, and a low profile can be achieved. Is to realize.

  The present invention relates to a coil in which magnetic layers and internal conductor layers having electrical insulation properties are alternately laminated, and the winding patterns of the internal conductor layers are sequentially connected so as to circulate while overlapping in the lamination direction in the electrical insulator. In the multilayer inductor having a structure in which both ends of the coil are respectively drawn out to the outer surface of the multilayer body and connected to the external electrode, the winding pattern of the inner conductor layer forms an 8-shape. The two inner magnetic paths by the coil-shaped winding pattern are in a harmonized connection, and all or part of the outer region of the coil formed by the winding pattern in the laminate is made nonmagnetic, and the outside of the coil The multilayer inductor is characterized in that the magnetic flux passing through the region is reduced.

  Further, according to the present invention, magnetic layers and internal conductor layers having electrical insulating properties are alternately laminated, and the winding patterns of the internal conductor layers are sequentially connected to circulate while overlapping in the lamination direction in the electrical insulator. In a multilayer inductor having a structure in which a coil is formed and both ends of the coil are respectively drawn to the outer surface of the multilayer body and connected to an external electrode, the inner conductor layer has a plurality of 8-shaped winding patterns juxtaposed. In this structure, magnetic regions and nonmagnetic regions are selectively formed at the beginning and end of the stacking direction so that the inner magnetic path formed by these eight-shaped winding patterns is in a harmonized connection. The laminated inductor is characterized in that all or part of the outer area of the coil formed by the winding pattern in the laminated body is made of a non-magnetic material so as to reduce the magnetic flux passing through the outer area of the coil. It is.

  Here, all or part of the outer part of the 8-shaped winding pattern of all the inner conductor layers, and all or part of the outer part between the overlapping winding patterns are made nonmagnetic. The structure which does is preferable. By expanding a part of the width of the winding pattern to the outside until reaching the outer surface of the laminated body, the outside of the coil can be made nonmagnetic, and the magnetic flux passing outside the winding pattern can be blocked.

  A space between adjacent patterns in the center of the 8-shaped winding pattern is preferably a non-magnetic material, but may be a magnetic material.

  A gap structure in which the entire surface perpendicular to the stacking direction in the stacked body is made of a nonmagnetic layer is preferably formed in the stacked body. This gap structure contributes to the improvement of the DC superposition characteristics, and may be a single layer, but it is preferable to arrange a plurality of layers symmetrically with respect to the center in the stacking direction.

  This multilayer inductor is particularly suitable for a power inductor for mobile use used in a power supply circuit such as a DC-DC converter.

  The multilayer inductor according to the present invention has a structure in which eight-shaped winding patterns are laminated, so that a large number of turns can be realized with a small number of laminations, and thus the inductance can be increased while being low profile. In addition, since the number of internal conductor layers is small, the magnetic layer can be thickened outside the ends of the coil (upper and lower parts in the stacking direction), and magnetic saturation of the magnetic material hardly occurs despite the low profile, thus improving the DC superposition characteristics. be able to. Furthermore, in the present invention, all or a part of the outer region of the coil formed by the 8-shaped winding pattern is made of a non-magnetic material, so that the magnetic flux passing through the outer region of the winding pattern can be reduced. . The magnetic field generated outside the winding pattern cancels a part of the originally required magnetic field. However, in the present invention, since this outer magnetic path is cut off, the Q value is prevented from lowering. And increase in loss can be suppressed.

  In addition, the multilayer inductor according to the present invention has a structure in which a plurality of 8-shaped winding patterns are juxtaposed and laminated so that the magnetic paths of these 8-shaped winding patterns are in a Japanese-style connection. With the number of layers, a larger number of turns can be realized, and a very high inductance can be obtained. Also in this case, the direct current superimposition characteristics can be improved, the Q value can be prevented from being lowered, and the increase in loss can be suppressed.

  Furthermore, in the present invention, when the space between the winding patterns of the inner conductor layer is made non-magnetic, it is possible to prevent the generation of a minute magnetic path (minor loop) surrounding the winding pattern and reduce the AC loss on the low bias side. This means that the loss due to standby current can be reduced, and the effect is great in terms of power saving especially in mobile applications. Further, by providing a gap structure in the stacked body, it is possible to improve the direct current superposition characteristics.

  One embodiment of a multilayer inductor according to the present invention is shown in FIG. In FIG. 1, A shows the plane of the inner conductor layer, B shows the plane of the magnetic layer, C shows the appearance, and D shows the longitudinal section. In the figure, the hatched lines are conductors (winding patterns), the portions marked with dots represent nonmagnetic materials, and the white portions not marked with dots represent magnetic materials.

  As shown in FIG. 1C, the multilayer inductor 10 is a surface-mounted chip component having a substantially rectangular parallelepiped shape. Two coils are embedded side by side inside the multilayer chip 12 that is mostly made of a magnetic material, and two inner magnetic paths by both coils are in a Japanese-style connection, and one end of each coil is connected to the multilayer chip. The structure is electrically connected to external electrodes 14 formed at both ends of the surface.

  In the coil inside the multilayer chip, a plurality of inner conductor layers are provided with an 8-shaped winding pattern, and an inner magnetic path formed by the 8-shaped winding pattern is in a Japanese-style connection. The entire outer region of the coil formed by the U-shaped winding pattern is made of a non-magnetic material to block the outer magnetic flux of the winding pattern.

  In the embodiment of FIG. 1, six internal conductor layers (first to sixth layers) shown in A are laminated in that order. The second to fifth layers all have a complete 8-shaped winding pattern 20. Each of the 8-shaped winding patterns passes near the chip outline, does not intersect at the center, and one is continuous but the other is interrupted, resulting in two turns per layer. The first layer and the sixth layer are layers in which the end of the coil is formed, and one side (the right half in the first layer and the left half in the sixth layer) is one turn, but the opposite of them The terminal side is 3/4 turn. The coil terminal portion 21 has a wide pattern that reaches the outline (outer surface) of the chip for connection to the external electrode.

  Such a winding pattern is wound in a rectangular shape while being bent at a right angle, and is formed by screen printing using a conductive paste. Here, the interrupted position in the center of the winding pattern is slightly shifted in each inner conductor layer, and the upper and lower layers are successively made continuous using a technique such as a via hole. A total of about 11.5 turns of coil is formed by these six layers. If a four-layer structure is used, a coil having about 7.5 turns can be obtained.

  In the second to fifth layers, the inner side of the winding pattern is of course the magnetic region 24, but in this embodiment, the outer side of the winding pattern is a nonmagnetic region 26. Similarly, in the first layer and the sixth layer, the outside of the winding pattern is a nonmagnetic region 26. However, since the half turn of the coil terminal is a pattern that reaches a wide chip outline, this also serves as a nonmagnetic region.

  A magnetic layer is interposed between the inner conductor layers. In this embodiment, as shown in FIG. 1B, this magnetic layer also has a magnetic region 24 corresponding to the inner side of the winding pattern and a nonmagnetic region 26 on the outer side.

  With such a laminated structure, the longitudinal section is as shown in FIG. That is, all the outside of the coil becomes the nonmagnetic region 26, and the inside of the coil becomes the magnetic region 24. That is, all of the outer portions of the 8-shaped winding pattern 20 of all the inner conductor layers, and between the overlapping winding patterns and all of the outer portions thereof become the nonmagnetic region 26. When one external electrode is energized to the other external electrode, the reverse current flows in each loop part in the 8-shaped winding pattern of one layer, and the same direction in the loop part of each layer that is superimposed on top and bottom Current can flow. By making the inner magnetic paths of the left and right coils in this way, the magnetic flux flows in the opposite direction inside both the coils as indicated by arrows. Here, when the inner magnetic paths of the left and right coils are connected in a Japanese-style manner, the outside of the coils is an unnecessary part as an original magnetic path. By making the entire outer portion the nonmagnetic region 26, the magnetic flux passing through the outside can be reduced. The magnetic field generated outside the winding pattern (the magnetic field as indicated by the dotted arrow in D of FIG. 1) cancels a part of the magnetic field inside the coil that is originally required. Therefore, only the magnetic field inside the coil can be used effectively, the Q value can be prevented from decreasing, and the increase in loss can be suppressed.

  FIG. 2 shows another embodiment. A represents a winding pattern in the inner conductor layer of the coil terminal portion, and B represents a longitudinal section of the multilayer chip. As in FIG. 1, the winding pattern of the coil terminal portion 21 is widened toward the outside over approximately ½ turn (L-shaped portion) and is shaped to reach the outer surface of the multilayer chip. Since the winding pattern is a conductor (non-magnetic material), when the upper and lower coil terminal portions are formed in such a shape, as shown in B, the non-magnetic material (coil) is not required even if the non-magnetic material is not printed. The terminal portion) surrounds the outside of the coil, and even if the whole is the magnetic region 24, the outer magnetic flux of the winding pattern 20 can be blocked by the coil terminal portion, although not as much as in the example of FIG. A certain degree of Q value reduction (increased loss) prevention effect can be obtained.

  In the present invention, all or part of the outer portion of the 8-shaped winding pattern of all the inner conductor layers, and all or part of the outer winding portion between the overlapping winding patterns are non-magnetic. What is necessary is just to set it as an area | region, and an internal structure can be changed suitably. An example is shown in FIG.

  3A is an example in which all of the outer portions of the 8-shaped winding pattern 20 of all the inner conductor layers are nonmagnetic regions 26, and FIG. 3B is an overlapping winding pattern. This is an example in which the nonmagnetic region 26 is formed between and between the outer portions.

  3C and 3D, as in FIG. 1, all of the outer portions of the 8-shaped winding pattern 20 of all the inner conductor layers, and between the overlapping winding patterns and all of the outer portions thereof. In addition to the non-magnetic region 26, the non-magnetic region 26 is also formed between adjacent patterns in the center of the 8-shaped winding pattern 20. In D, the non-magnetic region 26 is also formed between the overlapping winding patterns.

  E and F in FIG. 3 are the same as those in FIG. 1 except for all the outer portions of the 8-shaped winding pattern 20 of all the inner conductor layers, and between the overlapping winding patterns and all of the outer portions. This is an example in which the gap structure 28 is formed in the multilayer chip, which is made of the nonmagnetic region 26 and the entire surface perpendicular to the stacking direction in the multilayer body is made of a nonmagnetic layer. In E, the single gap structure 28 is provided at the center in the stacking direction, and in F, the gap structure 28 is arranged in two layers symmetrically with respect to the center in the stacking direction.

  As in the example shown in FIG. 1 or FIG. 3, it is possible to prevent the occurrence of a minute magnetic path (minor loop) surrounding the winding pattern 20 by the nonmagnetic region 26, and to reduce the AC loss on the low bias side. This means that the loss due to the standby current can be reduced, and can greatly contribute to power saving particularly in mobile applications. Further, as shown in FIGS. 3E and 3F, the gap structure 28 provided in the multilayer chip functions to adjust the inductance value, thereby improving the DC superposition characteristics.

  The magnetic part can be formed by printing a magnetic ferrite paste, and the non-magnetic part can be formed by printing a non-magnetic ferrite paste having a relative permeability of about 1. This type of multilayer inductor may be manufactured by a conventional method such as printing and laminating a large number of patterns vertically and horizontally, cutting, firing, forming and baking external electrodes.

  FIG. 4 is an explanatory view showing still another embodiment of the multilayer inductor according to the present invention. Here, in the figure, the hatched lines are conductors (winding patterns), the portions with dots are non-magnetic materials, and the white portions without dots are magnetic materials.

  In this example, the inner conductor layer is a structure in which two eight-shaped winding patterns 20 are juxtaposed, so that the inner magnetic path by the eight-shaped winding patterns 20 is in a Japanese-style connection. The magnetic region 24 and the non-magnetic region 26 are selectively formed at the beginning and end of the stacking direction, and all of the outer region of the coil formed by each of the eight-shaped winding patterns 20, or A part is made into the nonmagnetic area | region 26, and it comprises so that the magnetic flux which passes the outer side of the winding pattern 20 may be interrupted | blocked.

  Here, only one inner conductor layer (B in FIG. 4) is drawn, but a plurality of layers are laminated as in FIG. By connecting two sets of eight-shaped winding patterns in the upper and lower layers one after another, a total of four coils are juxtaposed, and two sets of eight characters arranged side by side on the top layer (or bottom layer) Are connected to the external electrode as a coil end of each of two sets of the eight-shaped winding patterns juxtaposed on the lowermost layer (or the uppermost layer). A magnetic region 24 that bisects the long side of the chip is provided at the top of the coil as shown in A, and a short side of the chip is bisected at the bottom of the coil as shown in C. A magnetic region 24 is provided to restrict the coil inner magnetic path. That is, these magnetic regions 24 form a magnetic path in the short side direction at the upper part of the coil and in the long side direction at the lower part of the coil. The magnetic layer provided between the inner conductor layers has a magnetic region that divides the long side of the chip into two as shown in A.

  When the layers are laminated in this manner, the winding patterns are sequentially connected, and one external electrode is energized to the other external electrode, the inside of the four coils inside the multilayer chip 12 as indicated by an arrow in FIG. The magnetic flux passes continuously in order. Since a coil having about 4 turns per inner conductor layer is formed, a high inductance can be obtained even if the number of laminated layers is small.

  In this embodiment, two 8-shaped winding patterns are juxtaposed per layer, but a larger number of 8-shaped winding patterns can be arranged. Also in this case, the magnetic region and the non-magnetic region are selectively formed at the beginning and end portions in the stacking direction so that the inner magnetic path by each 8-shaped winding pattern is in a Japanese-style connection.

BRIEF DESCRIPTION OF THE DRAWINGS Explanatory drawing which shows one Example of the multilayer inductor which concerns on this invention. The longitudinal cross-sectional view of the modification. Explanatory drawing which shows the other Example of the multilayer inductor which concerns on this invention. Explanatory drawing which shows the further another Example of the multilayer inductor which concerns on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Multilayer inductor 12 Laminated body chip 14 External electrode 20 Winding pattern 24 Magnetic area | region 26 Nonmagnetic area | region

Claims (6)

  Magnetic layers and internal conductor layers having electrical insulation are alternately laminated, and by sequentially connecting the winding patterns of the internal conductor layers, a coil is formed that circulates while overlapping in the lamination direction in the electrical insulator, In the multilayer inductor having a structure in which both ends of the coil are respectively drawn out to the outer surface of the multilayer body and connected to an external electrode, the winding pattern of the inner conductor layer forms an 8-shaped winding, and the 8-shaped winding Magnetic flux that passes through the outer region of the coil by making the two inner magnetic paths by the pattern to be in a joint connection and making all or part of the outer region of the coil formed by the winding pattern in the laminate nonmagnetic. A multilayer inductor characterized in that the number of inductors is reduced.   Magnetic layers and internal conductor layers having electrical insulation are alternately laminated, and by sequentially connecting the winding patterns of the internal conductor layers, a coil is formed that circulates while overlapping in the lamination direction in the electrical insulator, In the multilayer inductor having a structure in which both ends of the coil are respectively drawn to the outer surface of the multilayer body and connected to the external electrode, the inner conductor layer has a structure in which a plurality of 8-shaped winding patterns are juxtaposed. A magnetic region and a non-magnetic region are selectively formed at the beginning and end of the stacking direction so that the inner magnetic path formed by the 8-shaped winding pattern is in a summing connection. A multilayer inductor characterized in that all or part of an outer region of a coil formed by a line pattern is made of a non-magnetic material so as to reduce a magnetic flux passing through the outer region of the coil.   All or part of the outer part of the 8-shaped winding pattern of all the inner conductor layers, and all or part of the outer part between the overlapping winding patterns and the outer part thereof are non-magnetic. Item 3. The laminated inductor according to Item 1 or 2.   3. A part of the width of the winding pattern is extended outward until it reaches the outer surface of the laminate, thereby making the outside of the coil non-magnetic and blocking the magnetic flux passing outside the winding pattern. The multilayer inductor described.   The multilayer inductor according to any one of claims 1 to 4, wherein a magnetic material is used between adjacent patterns in the center of the figure 8 winding pattern. 6. The gap structure in which a whole surface perpendicular to the stacking direction in the stack is formed of a nonmagnetic layer is formed in the stack, and the gap structure is arranged symmetrically with respect to the center in the stacking direction. The multilayer inductor described in 1.

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