This invention relates to a coil component and the fabrication method thereof. In particular, this invention relates to the coil component which is used as a reactor in a high-power system such as an energy control of a battery mounted on an electrically-powered car or a hybrid car including an electromotor and an internal-combustion engine.
In an electrically-powered car or a hybrid car, the coil component is driven at frequencies within the audibility range of the human ear. Specifically, the normal driving frequency of the coil component in the electrically-powered car or the hybrid car belongs to a frequency range of from several kilohertz to several tens kilohertz.
The driving frequency of the audibility range has a possibility of undesired vibration which is caused by mutual forces of attraction between coil wires or between a coil and a magnetic core. The undesired vibration makes an audible noise or whine. In addition, if the coil component has an air-gap, the coil component further has a possibility of undesired vibration caused by mutual forces of attraction between portions of the core which is provided with the air-gap. Note here that, according to the conventional techniques, there is no magnetic core structure which does not become saturated even upon a DC bias of 200A or more without air-gaps. In other words, at least one air-gap is an absolute necessity for a superior DC bias characteristic over 200A or more.
A known coil component is disclosed in JP-A 2001-185421. The disclosed coil component is used for a low-power and high-frequency system. The disclosed coil component comprises a coil and first and second magnetic core members. The first magnetic core member includes magnetic metal powder of 50-70%, by volume, and thermosettable resin of 50-30%, by volume. The second magnetic core member is a dust core made of sintered ferrite body or magnetic metal powder. The first and the second magnetic core members are magnetically connected in series. The coil is embedded in the first magnetic core member.
One of the purposes of JP-A 2001-185421 is to provide a magnetic component such as an inductor, a choke coil and a transformer, which can suppress noise occurrence when the magnetic component is driven.
However, note here that the actual target frequency of JP-A 2001-185421 seems to belong to a range of from several hundreds of kilohertz to several megahertz as disclosed in paragraph [0006] of JP-A 2001-185421. The target frequency of JP-A 2001-185421 far exceeds the audible frequencies. It should be also known that the high-frequency vibration of the coil component at its air-gap does not make an audible noise or whine. Therefore, it is reasonable to assume that JP-A 2001-185421 directs its attention to another noise occurrence mechanism which is quite different from the present invention.
In addition, the target of JP-A 2001-185421 is a downsized coil component for low-power system. As a matter of course, the structure of the coil component disclosed in JP-A 2001-185421 is weak in the properties of withstand voltage and resistance to undesired pulses such as surge currents.
Thus, it is conceivable that the coil component of JP-A 2001-185421 is not suitable for the high-power and low-frequency system.
It is an object of the present invention to provide a coil component which has a property of high withstand voltage and another property of resistance to undesired pulses and can suppress the whine of the coil component driven even at the audible frequency, and to provide a fabrication method thereof.
According to an aspect of the present invention, a coil component comprises: a coil-containing insulator enclosure obtainable by enclosing a coil, except for end portions of the coil, with an insulator which comprises at least first resin; and a magnetic core made of a mixture of a second resin and powder, which comprises at least magnetic powder, wherein at least one part of the coil-containing insulator enclosure is embedded in the magnetic core.
An appreciation of the objectives of the present invention and a more complete understanding of its structure and a fabrication method thereof may be had by studying the following description of the preferred embodiment and by referring to the accompanying drawings.
With reference to FIGS. 1 to 10, a coil component 100 according to a first embodiment of the present invention comprises a coil-containing insulator enclosure 60 and a magnetic core 80. In this embodiment, the coil-containing insulator enclosure 60 is completely embedded in the magnetic core 80.
As shown in FIGS. 4 to 6, the coil-containing insulator enclosure 60 has a structure obtainable by enclosing a coil 30 with an insulator 50, except for end portions 12, 22 of the coil 30.
As seen from
By using the coil 30, the coil-containing insulator enclosure 60 is obtained in accordance with a manufacturing process as illustrated in
On the bottom portion, first insulator spacers 46 are disposed. The first insulator spacers 46 are made of the same material as the insulator 50, the material being explained in detail afterwards. Each of the first insulator spacers 46 has almost the same thickness as that of the insulator 50 of the coil-containing insulator enclosure 60 in the axial direction of the coil 30. The thickness of the insulator 50 of the coil-containing insulator enclosure 60 in the axial direction of the coil 30 is shown with a reference “t2” in
After the first insulator spacers 46 are disposed on the bottom portion of the temporal container 40, the coil 30 is mounted on the first insulator spacers 46 to position the coil 30 within the temporal container 40 in its vertical direction in consideration of the thickness t2 of the insulator 50. As apparently understood from the above description and the drawing, the first insulator spacers 46 serve to position the coil 30 only in the vertical direction, i.e. the axial direction of the coil 30.
To position the coil 30 within the horizontal direction of the coil-containing insulator enclosure 60, second insulator spacers 48 are inserted between the radially-peripheral part of the coil 30 and the inner side surface of the temporal container 40. Each of the second insulator spacers 48 has almost the same thickness as that of the insulator 50 of the coil-containing insulator enclosure 60 in the radial direction of the coil 30. The thickness of the insulator 50 of the coil-containing insulator enclosure 60 in the radial direction of the coil 30 is shown with a reference “t1” in
After the coil 30 is horizontally and vertically positioned within the temporal container 40 by the use of the first and the second insulator spacers 46, 48, the material of the insulator 50 is filled between the coil 30 and the temporal container 40.
In this embodiment, the insulator 50 is made of epoxy resin. Hereinafter, the resin of the insulator 50 is referred to as “first resin”.
In this embodiment, the epoxy resin is required to be liquid which has a small coefficient of viscosity. Therefore, the mutual solubility of resin and additives, hardenings or catalysts and the lifetime of the resin, in particular, are important items to be considered in deciding the actual epoxy resin. Based on the considerations, it is preferable that the base compound is selected from the group of bisphenol A epoxy resin, bisphenol F epoxy resin, polyfunctional epoxy resin and so on, while the hardener or curing agent is selected from the group of aromatic polyamine system, carboxylic anhydride system, initiative hardener system and so on. In this embodiment, bisphenol A epoxy resin is selected as a base compound of the first resin, and low-viscosity solventless aromatic amine liquid is selected as a hardener for the first resin.
The first resin may be another thermosettable resin such as silicone resin. Also, the resin may be another curable or hardenable resin such as light-curable or photo-settable resin, ultraviolet curable resin, chemical-reaction curable resin, or the like.
When the first resin of the insulator 50 is cast in the temporal container 40 and then is hardened, the coil-containing insulator enclosure 60 is obtained as shown in FIGS. 4 to 6.
As seen from FIGS. 4 to 6, the coil-containing insulator enclosure 60 comprises two hollow portions 62, 64, which correspond two hollow portions 32, 34 of the coil 30, respectively. The insulator 50 of the coil-containing insulator enclosure 60 has a thickness t3 in the Y-direction, which is a direction perpendicular to the arrangement direction of the coil members 10, 20. The insulator 50 of the coil-containing insulator enclosure 60 has a thickness t4 in the X-direction, which is the arrangement direction of the coil members 10, 20.
The thus obtained coil-containing insulator enclosure 60 is positioned and arranged within a case 70 as illustrated in
The positioning members are spacers made of the same material as that of the magnetic core 80. Because the magnetic core 80 is made of a mixture of resin and magnetic powder as described in detail afterwards, the spacers are referred to as mixture spacers, hereinafter. Furthermore, the resin included in the mixture is referred to as a second resin in distinction from the first resin of the insulator 50. In this embodiment, the second resin is however the same resin as the first resin in material. If the second resin is the same resin as the first resin, the coil-containing insulator enclosure 60 and the magnetic core 80 can be easily and suitably formed in a single object when the coil-containing insulator enclosure 60 is embedded in the magnetic core 80.
With reference to
After the coil-containing insulator enclosure 60 is horizontally and vertically positioned in the case 70 by the use of the first to the third mixture spacers 72, 74, 76, the mixture of the second resin 82 and the magnetic powder 84 is cast in the case 70 to be filled between the case 70 and the coil-containing insulator enclosure 60 as illustrated in FIGS. 8 to 10. After that, the second resin 82 is hardened so that the magnetic core 80 of the present embodiment can be obtained.
As apparently from the above description, the magnetic core 80 of the embodiment is a casting, which is obtainable by casting the mixture into a predetermined shaped container for molding. In consideration of the size of the high-power coil component, it is preferable that the mixture 20 is composed of the materials which are capable of casting without any solvents.
In this embodiment, the casting process is basically carried out without pressure or with reduction of pressure. Once the casting process is finished, the casting may be subjected to some pressure for the purpose of increasing the density of the magnetic core according to the present embodiment. There is no limitation on the mold shape, and the magnetic core 80 of the mixture can be formed in any shapes.
The magnetic powder 84 is soft magnetic metal powder, especially, Fe base powder in this embodiment. Specifically, the Fe base powder is powder selected from the group comprising Fe—Si system powder, Fe—Si—Al system powder, Fe—Ni system powder and Fe system amorphous powder. In case of Fe—Si system powder, an average content of Si is preferably in a range of from 0.0 percent, by weight, to 11.0 percents, by weight, both inclusive. In case of Fe—Si—Al system powder, an average content of Si is preferably in a range of from 0.0 percent, by weight, to 11.0 percents, by weight, both inclusive; while another average content of Al is preferably in a range of from 0.0 percent, by weight, to 7.0 percents, by weight, both inclusive. In case of Fe—Ni system powder, an average content of Ni is in a range of from 30.0 percents, by weight, to 85.0 percents, by weight, both inclusive.
In this embodiment, the magnetic powder 84 is substantially spherical powder, which can be obtained by, e.g., gas atomization. The spherical or the almost spherical powder is suitable for increasing its filling factor or filling ratio in the mixture of the magnetic powder 84 and the second resin 82. In this embodiment, it is recommended that the spherical or the almost spherical powder has an average diameter of 500 μm or less as the most normal diameter in its particle size distribution. The magnetic powder 84 may be non-spherical powder such as powder obtained by another intentional gas atomization or indefinitely-shaped powder obtained by water atomization, when its anisotropy is used. If the magnetic powder 84 of non-spherical powder or indefinitely-shaped powder is used, the mixture of the magnetic powder 84 and the second resin 82 is subjected to an anisotropic alignment under the predetermined magnetic field before the mixture becomes completely hardened.
In consideration of fluidity of the mixture of the second resin 82 and the magnetic powder 84, the mixing ratio of the second resin 82 in the mixture is in a range of from 20 percents, by volume, to 90 percents, by volume, both inclusive. Preferably, the mixing ratio is in a range of from 40 percents, by volume, to 70 percents, by volume, both inclusive.
The magnetic core 80 has an elastic modulus of 3000 MPa or more. The second resin 82 is selected such that, in case of the magnetic core 80 has the foregoing elastic modulus of 3000 MPa or more under a specific condition, the second resin 82 has an elastic modulus of 100 MPa or more if only the second resin 82 is hardened in accordance with the specific condition. The value of the elastic modulus of the magnetic core 80 or the hardened second resin 82 is measured in accordance with a standard of measurement called JIS K6911 (Testing methods for thermosetting plastics).
In this embodiment, the magnetic core 80 has the elastic modulus of 15000 MPa. The second resin 82 is selected such that the hardened second resin 82 has 1500 MPa if only the second resin 82 is hardened under the same condition where the mixture is hardened to have the elastic modulus of 15000 MPa. When the magnetic core 80 has the elastic modulus of 15000 MPa or more, its thermal conductivity drastically becomes better. Specifically the thermal conductivity becomes 2 [WK−μm−1]. Therefore, it is preferable that the magnetic core 80 has the elastic modulus of 15000 MPa or more.
The above-mentioned magnetic core 80 can be modified as far as the magnetic core 80 has relative permeability of 10 or more at a magnetic field of 1000*103/4π[A/m]. For example, each of particles of the magnetic powder 84 may be provided with a high permeability thin layer, such as a Fe—Ni base thin layer. The high permeability thin layer is formed on a surface of each particle of the magnetic powder 84. Also, each of particles of the magnetic powder 84 may be coated with at least one insulator layer in advance of the mixing of the magnetic powder 84 and the second resin 82. In case of the magnetic powder particle with the high permeability thin layer, the insulator layer is formed on the high permeability thin layer. The mixture of the second resin 82 and the magnetic powder 84 may further include non-magnetic filler such as filler selected from the group comprising glass fiber, granular resin, and inorganic material base powder, which includes silica powder, alumina powder, titanium oxide powder, silica glass powder, zirconium powder, calcium carbonate powder and aluminum hydroxide powder. Also, the mixture of the second resin 82 and the magnetic powder 84 may include a small amount of permanent magnetic powder.
The insulator 50 may include non-magnetic filler. The non-magnetic filler included in the insulator 50 is selected such that at least one of an elastic modulus and a linear expansion coefficient of the mixture hardened corresponds to that of the hardened insulator 50. The non-magnetic filler may be filler selected from the group comprising glass fiber, granular resin, and inorganic material base powder, which includes silica powder, alumina powder, titanium oxide powder, silica glass powder, zirconium powder, calcium carbonate powder and aluminum hydroxide powder.
It is preferable that the non-magnetic filler added to the insulator 50 is substantially spherical powder. It is also preferable that the spherical or the almost spherical non-magnetic powder has an average diameter of 500 μm or less as the most normal diameter in its particle size distribution.
In consideration of fluidity of the insulator 50 before the insulator 50 is hardened, the mixing ratio of the first resin in the insulator 50 is 30 percents, by volume, or more. Preferably, if the high magnetic reluctance of the insulator 50 is used as described later, the ratio of the first resin is in a range of from 30 percents, by volume, to 50 percents, by volume, both inclusive. In other words, it is preferable that the content of the non-magnetic filler in the insulator 50 is 50 percents, by volume, or more.
In order to ensure better insulation effect, it is preferable that each of the thicknesses t1, t2 and t4 shown in
The case 70 of this embodiment is made of aluminum alloy. The case 70 may be made of other metal or alloy such as Fe—Ni alloy. In case of the metal case 70, it is preferable that an insulator film is formed on an inner surface of the metal case 70 before the mixture of the second resin 82 and the magnetic powder 84 is cast in the metal case 70. Furthermore, the case may be a ceramic case such as an alumina mold.
In this embodiment, the magnetic core 80 and the coil-containing insulator enclosure 60 are fixed to the case 70. However, the present invention is not limited thereto. For example, in the manufacturing process of the coil component 100 of the present invention, the case 70 may be formed of fluorocarbon polymers sheets, and the mixture may be cast in the case made of fluorocarbon polymers sheets. When the fluorocarbon polymers sheets are removed from the hardened mixture, the coil component without the case can be obtained and can be freely arranged within an existing case.
Next explanation will be made about a coil component according to a second embodiment of the present invention, with reference to FIGS. 11 to 15. The coil component of the present embodiment has a structure similar to that of the coil component 100 of the first embodiment.
As seen from
In other words, two high magnetic reluctance regions 56, 58 are added to the coil-containing insulator enclosure 60 of the first embodiment in the Y-direction, as illustrated in
According to the present embodiment, the high magnetic reluctance region 54(56, 58) can be easily obtained by selecting the shape of the temporal container 41 as shown in
Next explanation will be made about a coil component 110 of a third embodiment of the present invention, with reference to FIGS. 16 to 18. The coil component 110 of the present embodiment has a structure where high magnetic reluctance members 90 are added to the coil component 100 of the first embodiment, wherein the high magnetic reluctance members 90 each has a magnetic reluctance higher than the magnetic core 80 made of the mixture and are inserted into the magnetic path formed in the coil component 100.
In this embodiment, each of the high magnetic reluctance members 90 is made of the same material as the insulator 50 and constitutes a high magnetic reluctance region which has relative permeability of 20 or less within the magnetic core 80 made of the mixture. The high magnetic reluctance member 90 may be made of another material comprising the same resin as the first resin. Also, the high magnetic reluctance member 90 may be made of another material comprising the same resin as the first resin and other non-magnetic filler which is not used in the insulator 50. In addition, the high magnetic reluctance member 90 may be made of another material comprising the same resin as the first resin and magnetic powder as far as the high magnetic reluctance member 90 has the magnetic reluctance higher than the magnetic core.
As shown in
Each of the high magnetic reluctance members 90 may be positioned by forming the high magnetic reluctance members 90 in advance and by putting each of the high magnetic reluctance members 90 at the predetermined positions on the mixture when the mixture reaches the suitable level during the casting process of the mixture.
As shown in
The above-mentioned embodiments can be modified as followings.
As shown in
As shown in
An example of the specific magnetic core member 210 is a dust core made of powder selected from the group comprising Fe system amorphous powder, Fe—Si system powder, Fe—Si—Al system powder and Fe—Ni system powder, or a laminated core made of Fe base thin sheets.
The coil 30 illustrated in
In the above-mentioned embodiments, the positioning processes of the coil 30 and the coil-containing insulator enclosure 60, 61 use the insulator spacers 46, 48 and the mixture spacers 72, 74, 76, respectively. However, if the coil 30 has high stiffness, the coil 30 and the coil-containing insulator enclosure 60, 61 can be positioned, without using the insulator spacers 46, 48 and the mixture spacers 72, 74, 76, but by holding only the end portions 12, 22 of the coil 30. The coil 30 and the coil-containing insulator enclosure 60, 61 may be hanged and positioned by the use of fluorocarbon polymer fibers.
The preferred embodiments of the present invention will be better understood by those skilled in the art by reference to the above description and figures. The description and preferred embodiments of this invention illustrated in the figures are not to intend to be exhaustive or to limit the invention to the precise form disclosed. They are chosen to describe or to best explain the principles of the invention and its applicable and practical use to thereby enable others skilled in the art to best utilize the invention.
While there has been described what is believed to be the preferred embodiment of the invention, those skilled in the art will recognize that other and further modifications may be made thereto without departing from the sprit of the invention, and it is intended to claim all such embodiments that fall within the true scope of the invention.
Number | Date | Country | Kind |
---|---|---|---|
2003-168055 | Jun 2003 | JP | national |
2003-172313 | Jun 2003 | JP | national |
2003-185303 | Jun 2003 | JP | national |
2003-206300 | Aug 2003 | JP | national |
2003-323673 | Sep 2003 | JP | national |
2003-360606 | Oct 2003 | JP | national |
2003-399664 | Nov 2003 | JP | national |
2004-033576 | Feb 2004 | JP | national |
2004-063989 | Mar 2004 | JP | national |
2004-146858 | May 2004 | JP | national |