Patent Grant
9589716
This application relates in subject matter to U.S. patent application Ser. No. 11/519,349 filed Sep. 12, 2006 and now issued U.S. Pat. No. 7,791,445, and U.S. patent application Ser. No. 12/181,436 Filed Jul. 9, 2008 and now issued U.S. Pat. No. 8,378,777, the complete disclosures of which are hereby incorporated by reference in their entirety.
The field of the invention relates generally to the construction and fabrication of miniaturized magnetic components for circuit board applications, and more specifically to the construction and fabrication of miniaturized magnetic components such as power inductors and transformers.
Recent trends to produce increasingly powerful, yet smaller electronic devices have led to numerous challenges to the electronics industry. Electronic devices such as smart phones, personal digital assistant (PDA) devices, entertainment devices, and portable computer devices, to name a few, are now widely owned and operated by a large, and growing, population of users. Such devices include an impressive, and rapidly expanding, array of features allowing such devices to interconnect with a plurality of communication networks, including but not limited to the Internet, as well as other electronic devices. Rapid information exchange using wireless communication platforms is possible using such devices, and such devices have become very convenient and popular to business and personal users alike.
For surface mount component manufacturers for circuit board applications required by such electronic devices, the challenge has been to provide increasingly miniaturized components so as to minimize the area occupied on a circuit board by the component (sometimes referred to as the component “footprint”) and also its height measured in a direction parallel to a plane of the circuit board (sometimes referred to as the component “profile”). By decreasing the footprint and profile, the size of the circuit board assemblies for electronic devices can be reduced and/or the component density on the circuit board(s) can be increased, which allows for reductions in size of the electronic device itself or increased capabilities of a device with comparable size. Miniaturizing electronic components in a cost effective manner has introduced a number of practical challenges to electronic component manufacturers in a highly competitive marketplace. Because of the high volume of components needed for electronic devices in great demand, cost reduction in fabricating components has been of great practical interest to electronic component manufacturers.
In order to meet increasing demand for electronic devices, especially hand held devices, each generation of electronic devices need to be not only smaller, but offer increased functional features and capabilities. As a result, the electronic devices must be increasingly powerful devices. For some types of components, such as magnetic components that provide energy storage and regulation capabilities, meeting increased power demands while continuing to reduce the size of components that are already quite small, has proven challenging.
Non-limiting and non-exhaustive embodiments are described with reference to the following Figures, wherein like reference numerals refer to like parts throughout the various drawings unless otherwise specified.
While conventional miniaturized magnetic components such as inductors and transformers have perhaps have been produced economically using known techniques, they have not met the performance requirements of higher powered devices. Likewise, constructions that are more capable of meeting higher performance requirements have not yet proven to be economically produced. Cost and/or performance issues of known magnetic component constructions for higher powered electronic devices have yet to be overcome in the art.
Historically, magnetic components such as inductors or transformers were assembled with separately fabricated magnetic core pieces that are assembled around a wire coil and physically gapped with respect to one another. Numerous problems exist when trying to miniaturize such components. In particular, achieving tightly controlled physical gaps in increasingly miniaturized components has proven difficult and expensive. An inability to control the physical gap creating also tends to create undesirability variability and reliability issues for miniaturized components.
To avoid difficulties with physically gapped core constructions for magnetic components, magnetic powder materials have been combined with binder materials to produce so-called distributed gap materials. Such material may be moldable into a desired shape and avoids any need for assembly of discrete core structures with physical gaps. Further, such material may be molded, in a semi-solid slurry form or as a granular insulated dry powder, directly around pre-fabricated coil structures to form a single piece core structure containing a coil. Mixing and preparing the magnetic powder and binder materials in a controlled and reliable manner, as well as controlling the molding steps, can be difficult, however, leading to increased costs of manufacturing magnetic components. This is perhaps more so for power inductors operating at comparatively higher current levels than conventional components. Increased performance requirements may require coil different coil configurations, different formulations of the moldable magnetic powder slurry or dry granular materials and/or tighter process controls in fabricating the components, any of which may increase the difficulty and cost of manufacturing such components.
Another known technique for producing miniaturized magnetic components is to form the components from thin layers of material to form a chip-type component. In conventional components of this type, dielectric layers of material, such as ceramic green sheet materials, have been used to form magnetic components. Conductive coil elements are typically formed or patterned on one or more of the dielectric layers and the coil elements are enclosed or embedded within the dielectric layers when assembled and formed. While very small components can be manufactured using such dielectric materials, they tend to provide limited performance capabilities. Processing the green sheets can further be intensive and relatively expensive for mass produced components. The ceramic sheets also have relatively poor heat transfer characteristics for higher current applications demanded by power inductors.
It has also been proposed to construct magnetic components from composite magnetic sheet materials arranged in layers. In components of this type, the layers are not only dielectric but also magnetic. That is, the sheet materials used as the layers exhibit a relative magnetic permeability μr of greater than 1.0 and are generally considered to be magnetically responsive materials. Such magnetically responsive sheet materials may include soft magnetic particles dispersed in a binder material, and are provided as freestanding thin layers or films that may be assembled in solid form, as opposed to semi-solid or liquid materials that are deposited on and supported by a substrate material, as the components are fabricated. As such, and unlike other composite magnetic materials known in the art, such freestanding thin layers or films are capable of being laminated.
Examples of laminated components utilizing composite magnetic sheet materials are disclosed in U.S. Published Patent Application No. 2010/0026443 A1. Such constructions can be beneficial in that the composite magnetic sheet materials can be prefabricated, and the layers can be pressure laminated around a conductive coil, which in turn may be pre-fabricated independently from any of the composite magnetic sheet materials. Lamination of the layers may be accomplished at relatively low cost and with less difficulty compared to other processes. Such constructions have nonetheless proven susceptible to performance limitations in certain aspects, and have not yet completely met the needs of higher powered, yet smaller sized, electronic devices. This is believed to be due to limitations in the composite magnetic sheet materials presently available.
Existing composite magnetic sheet materials have primarily been developed for electromagnetic shielding purposes, and have been utilized to construct magnetic components with this in mind. One such example of a component including composite magnetic sheets is described in KOKAI (Japanese Unexamined Patent Publication) No. 10-106839 entitled “Multilayer High-frequency Inductor”. This reference teaches flat and/or acicular soft magnetic powder material that are intrinsically conductive materials, being kneaded into an insulating organic binder such that the soft magnetic powder is dispersed in the organic binder and formed into material layers that can be stacked to construct an inductor. The flat and/or acicular soft magnetic powder material is specifically compared and contrasted with nearly spherical magnetic powder materials. This reference teaches that a desirable magnetic anisotropy occurs if the soft magnetic powder is formed in at least one of the shapes of the soft magnetic powder of flat and acicular, in the high-frequency range, the magnetic permeability of the inductor, based on the magnetic resonance, increases. The reference concludes that the flat and/or acicular soft magnetic powder material is superior to spherical powder material for electromagnetic shielding, and when used to form a multilayer high-frequency inductor, separately provided shielding features can be eliminated and the size of the inductor component may be further reduced.
Published European Patent Application No. EP 0 785 557 A1 also discloses composite magnetic material sheets for electromagnetic shielding purposes. This reference, teaches two types of soft, flat magnetic particles and organic binder used to fabricate composite magnetic sheet materials having anisotropic properties. EP 0 785 557 A1 further discloses that polymer binders may be used to form the magnetic sheets, where the magnetic powder fills more than 90 weight percent of the completed solid sheet.
WO 2009/113775 discloses composite magnetic sheet materials utilized to construct a multilayer power inductor. This reference teaches sheets charged with soft magnetic metal powders wherein the soft magnetic powders are anisotropic and are arranged in parallel or perpendicular to the surface of the sheet. Surfaces of the sheets are patterned with circuit paths that are electrically connected by vias to define a conductive coil. Center areas of the sheets may have isotropic properties if desired, while the remaining areas of the sheets remain anisotropic. A fill factor for the magnetic powder sheet materials disclosed is about 80% or less by weight. Power inductor constructions of this type have proven to be limited in their performance capabilities for higher powered devices. Specifically, the direct current capacity of such constructions is below that required by newer electronic devices and applications.
A published paper entitled “Permeability and electromagnetic-interference characteristics of Fe—Si—Al alloy flakes-polymer composite”, J. Appl. Phys. 85, 4636 (1999) is further believed to represent the state of the art of magnetic composite sheet materials. In this paper, noise suppression effects of an Fe—Si—Al alloy flakes-polymer composite are studied, and the properties of different types of sheets including anisotropic magnetic powders are compared. The paper concludes that magnetic permeability (μ max) of composite sheets made of Fe—Si—Al flakes (which has anisotropic properties) is superior to sheets made from atomized magnetic powder materials, and a much higher magnetic permeability is possible with the composite sheets made of Fe—Si—Al flakes.
Perhaps unexpectedly so, existing magnetic composite sheet materials, which have been refined considerably to provide desirable magnetic properties, are not effective to provide necessary performance capabilities for miniaturized components operable at increased current levels demanded by new electronic devices. To provide lower cost, yet high performance, laminated and miniaturized magnetic components such as power inductors and transformers operable at higher current levels, other types of magnetic composite sheet materials are needed.
Exemplary embodiments of inventive magnetic component constructions are described below utilizing enhanced magnetic composite sheet materials offering improved performance for higher current and power applications that is difficult, if not impossible, to achieve, using known magnetic composite sheet materials. Magnetic components such as power inductor and transformer components may be fabricated with reduced cost compared to other known power inductor constructions. Manufacturing methodology and steps associated with the devices described are in part apparent and in part specifically described below but are believed to be well within the purview of those in the art without further explanation.
The coil 102 is fabricated from a flexible wire conductor according to known techniques and includes a first end or lead 110, a second lead 112 (best seen in
As those in the art will appreciate, an inductance value of the winding portion 114 depends primarily upon the number of turns of the wire, the specific material of the wire used to fabricate the coil 102, and the cross sectional area of the wire used to fabricate the coil 102. As such, inductance ratings of the magnetic component 100 may be varied considerably for different applications by varying the number of coil turns, the arrangement of the turns, and the cross sectional area of the coil turns. The tightly wound coil 102 as shown includes a relatively high number of turns in a compact configuration relative to conventional coils for used for miniaturized components. The inductance value of the component 100 can be therefore be increased considerably relative to other known miniaturized magnetic component constructions.
Optionally, and as shown in
While the component 100 depicted is a power inductor component including one coil 102, it is contemplated that more than one coil 102 may likewise be provided. In a multiple coil embodiment, the coils may be connected in series or in parallel in an electrical circuit. Separate coils may likewise be arranged to form a transformer component instead of an inductor.
The magnetic composite sheets 104 and 106 are provided as a freestanding, solid sheet layers and may therefore be assembled rather easily, as contrasted with slurry or semi-solid materials, and liquid materials known in the art that are deposited on and supported by a substrate material for manufacturing purposes. The magnetic composite sheets 104 and 106 are flexible and amenable to lamination processes as described below.
Despite the accepted understanding of those in the art that shape anisotropy of magnetic powder particles is desirable in composite magnetic sheet constructions, Applicants believe that such shape anisotropy may actually be counterproductive for constructing magnetic components, including but not necessarily limited to higher current, miniaturized power inductors. That is, and perhaps unexpectedly so, the magnetic performance of certain magnetic components, of which the component 100 is one example, may actually be improved by utilizing magnetic composite sheets 104, 106 having no shape anisotropy, among other properties discussed below.
As those in the art will appreciate, shape anisotropy refers to the shape of the magnetic powder particles used to form the magnetic composite sheets 104 and 106. Highly symmetrical magnetic powder particles are considered to have no shape anisotropy, such that a given magnetic field magnetizes the powder particles to the same extent in all directions. Square particles and spherical particles are examples of particles having no shape anisotropy, although other symmetrical shapes are possible. While the size of the magnetic particles themselves may vary somewhat, a uniform shape of the particles in the magnetic composite sheets 104, 106 will provide no shape anisotropy. Alternatively stated, while the actual dimensions of the magnetic particles may not be equal, the aspect ratio (the ratio of a longest dimension to the shortest dimension in a three dimensional coordinate system) of the particles is generally uniform in the magnetic composite sheets 104, 106. It is possible that two or more different shapes of particles may have the same aspect ratio and provide no shape anisotropy in the magnetic composite sheets 104, 106 even if used in combination, but magnetic particles of different shapes having different aspect ratios, and perhaps even randomly distributed shapes and aspect ratios, would not provide magnetic composite sheets having no shape anisotropy.
As discussed above, and unlike the magnetic composite sheets 104 and 106, existing magnetic composite sheet materials are typically formulated and refined to provide a predetermined degree of shape anisotropy (i.e. having magnetic particles with elongated, highly asymmetrical shapes and large aspect ratios). Shape anisotropy is believed to attenuate, rather than improve, magnetic performance from a power magnetics perspective, and has until now presented practical performance limitations of magnetic components constructed from conventional, shape anisotropic magnetic composite sheets.
It should be recognized that while no shape anisotropy is believed to be beneficial in the magnetic composite sheets 104, 106, other forms of anisotropy exist and may be present in the magnetic composite sheets 104, 106 in further and/or alternative embodiments. For example, magnetocrystalline anisotropy may occur even in particles having no shape anisotropy. As another example, stress anisotropy may also exist to some extent. That is, while the magnetic composite sheets 104, 106 have no shape anisotropy, they may be anisotropic in another manner. Shape anisotropy, however, tends to be the dominant form of anisotropy when the magnetic powder particle sizes are small.
In various embodiments, soft magnetic powder particles used to make the magnetic composite sheets 104, 106 may include Ferrite particles, Iron (Fe) particles, Sendust (Fe—Si—Al) particles, MPP (Ni—Mo—Fe) particles, HighFlux (Ni—Fe) particles, Megaflux (Fe—Si Alloy) particles, iron-based amorphous powder particles, cobalt-based amorphous powder particles, and other suitable materials known in the art. Combinations of such magnetic powder particle materials may also be utilized if desired. The magnetic powder particles may be obtained using known methods and techniques. Optionally, the magnetic powder particles may be coated with an insulating material.
After being formed, the magnetic powder particles may be mixed and combined with a binder material. The binder material may be a polymer based resin having desirable heat flow characteristics in the layered construction of the component 100 for higher current, higher power use of the component 100. The resin may further be thermoplastic or thermoset in nature, either of which facilitates lamination of the sheet layers 104, 106 with heat and pressure. Solvents and the like may optionally be added to facilitate the composite material processing. The composite powder particle and resin material may be formed and solidified into a definite shape and form, such as the substantially planar and flexible thin sheets 104, 106 as shown. Specific methodology and techniques for making the magnetic sheets 104, 106 are known and not separately described herein. Much of the methodology and techniques for manufacturing existing composite magnetic sheets still applies, with the exception of the shape anisotropy as discussed above and some of the particulars in composition briefly explained below.
Various formulations of the magnetic composite materials used to form the sheets 104, 106 are possible to achieve varying levels of magnetic performance of the component 100 in use. In general, however, in a power inductor application, the magnetic performance of the material is generally proportional to the flux density saturation point (Bsat) of the magnetic particles used, the permeability (μ) of the magnetic particles, the loading (% by weight) of the magnetic particles in the composite, and the bulk density of the completed composite after being pressed around the coil as explained below. That is, by increasing the magnetic saturation point, the permeability, the loading and the bulk density a higher inductance will be realized and performance will be improved.
On the other hand, the magnetic performance of the component is inversely proportional to the amount of binder material used in the composite. Thus, as the loading of the composite of material with the binder material is increased, the inductance value of the end component tends to decrease, as well as the overall magnetic performance of the component. Each of Bsat and μ are material properties associated with the magnetic particles and may vary among different types of particles, while the loading of the magnetic particles and the loading of the binder may be varied among different formulations of the composite.
For inductor components, the considerations above can be utilized to strategically select materials and composite formulations to achieve specific objectives. As one example, metal powder materials may be preferred over ferrite materials for use as the magnetic powder materials in higher power indicator applications because metal powders, such as Fe—Si particles have a higher Bsat value. The Bsat value refers the maximum flux density B in a magnetic material attainable by an application of an external magnetic field intensity H. A magnetization curve, sometimes referred to as a B-H curve wherein a flux density B is plotted against a range of magnetic field intensity H may reveal the Bsat value for any given material. The initial part of the B-H curve defines the permeability or propensity of the material of the core 20 to become magnetized. Bsat refers to the point in the B-H curve where a maximum state of magnetization or flux of the material is established, such that the magnetic flux stays more or less constant even if the magnetic field intensity continues to increase. In other words, the point where the B-H curve reaches and maintains a minimum slope represents the flux density saturation point (Bsat).
Additionally, metal powder particles, such as Fe—Si particles have a relatively high level of permeability, whereas ferrite materials such as FeNi (permalloy) have a relatively low permeability. Generally speaking, a higher permeability slope in the B-H curve of the metal particles used, the greater the ability of the composite material to store magnetic flux and energy at a specified current level, which induces the magnetic field generating the flux.
In exemplary embodiments, the magnetic powder particles comprise at least 90% by weight percent of the composite. Additionally, the composite sheets 104, 106 may have a density of at least 3.3 grams per cubic centimeter, and an effective magnetic permeability of at least 10. The composite material is formed into the sheets 104, 106 so as not to create any physical voids or gaps in the sheets. As such, the sheets 104, 106 have distributed gap properties that avoid any need to create a physical gap in the component construction. The magnetic composite sheets 104, 106 when fully formed have insulating, dielectric, and magnetic properties. For the context of this discussion, the term “insulator” refers to a low degree of electrical conduction, and hence the sheets 104, 106 will not conduct electrical current in use. The term “dielectric” refers to a high polarizability (i.e., electric susceptibility) of the composite material in an applied electric field. The term “magnetic” refers to the degree of magnetization that the composite obtains in response to an applied magnetic field (i.e., magnetic permeability). Using such composite sheets 104 and 106, a power inductor having a large inductance value as well as a relatively large direct current capacity is possible for use in higher powered electronic devices of a smaller size.
As previously mentioned, the magnetic composite sheets 104 and 106 are freestanding, flexible solid at room temperature, and definite in shape, as opposed to semi-solid and liquid materials known in the art having no definite shape. Accordingly, the magnetic composite sheets 104 and 106 may be manipulated, handled and assembled with definite shape to form magnetic components without having to use support substrates, deposition techniques and the like that semi-solid or liquid composite materials entail in other known magnetic component constructions. More specifically, and as shown in
Two sheets 104, 106 are shown in the illustrative embodiment of
The magnetic core piece 108 is separately provided from the first and second composite sheets 104, 106. The magnetic core piece 108 may include a first portion 118 of a first dimension and a second portion 120 having a second dimension. In the example shown, the first portion 118 is generally annular or disk-shaped and has a first radius R1 (
The coil winding portion 114 seats or rests upon the first portion 118 of the magnetic piece. The radius R1 of the first portion 118 in the example embodiment shown is relatively large so that the outer periphery of the first portion 118 is extends nearly completely between the opposed end edges of the sheets 104, 106 as best seen in
The second portion 120 having the lesser radius R2, in contrast with the first portion 118, is not coextensive with the upper sheet 104 and a smaller contact area is provided. The plurality of turns in the coil winding portion 114 extend about the second portion 120 of the core piece 108, and the second portion 120 extends above the coil 102 for a short distance in a direction parallel to the axis 122 (
The core piece 108 may be fabricated from ferrite, any of the magnetic powder particles disclosed above, or other appropriate magnetic material known in the art. The core piece 108 provides structural support to the coil 102 during lamination processes, assists in locating the coil 102 relative to the composite sheets 104, 106 and provides additional magnetic performance of the completed component 100, especially when the core piece 108 has a greater magnetic permeability than the composite sheets 104, 106. In such an embodiment, the higher direct current capacity of the coil 102 may therefore be coupled with the core piece 108 having a greater magnetic permeability for even greater inductance.
Once the coil 102, the sheets 104 and 106, and the core piece 108 are assembled as shown in
As the sheets 104 and 106 deform and define the core structure 124 under compressive force, the thickness of the respective sheets 104 and 106 are changed in a non-uniform manner in the plane of each sheet, and also with respect to one another. That is, the sheets 104 and 106 are not necessarily deformed to the same extent in different areas of the sheet or in relation to one another. The sheets 104 and 106 meet one another and bond to one another in some areas of the component 100 (e.g., at the between the edge of the coil 102 and outer edges of the sheets 104 and 106) and the sheets 104 meet the outer surfaces of the coil 102 and core piece 108 and bond to them in other areas. Because of the geometry of the coil 102 and core piece 108 in a direction parallel to the axis 122 (
While the sheets 104 and 106 bond to one another where they meet as the core structure 124 is defined, the sheets 104 and 106 do not intermingle but rather remain as bonded layers in the construction. That is, while the bond line between the sheets 104 and 106 may be complex because of the geometries involved in laminating the sheets to the three dimensional coil 102 and core piece 108, the bond line still exists. In contrast, and for clarity, a construction wherein such corresponding layers did intermingle and mix to effectively become indistinguishable from one another would not form a laminate and would not constitute a lamination process for the purposes of the present invention. Specifically, layers that become fluidized and intermingled would not be laminated in the context of the present invention.
The assembled coil 102, sheets 104 and 106, and core piece 108 may be placed in a mold and laminated inside the mold to preserve the shape of the laminated component as seen in
As shown in
While the terminal tabs 115 and 116 are used to form the exemplary surface mount terminations 126 shown, surface mount terminations may alternatively be formed in another manner. For example, when the coil leads 110 and 112 are extended to the side edges 125 and 127 as shown in
A study of
The core piece 201, like the core piece 108, is separately provided from the first and second magnetic composite sheets 104, 106. The magnetic core piece 201 may include a first portion 202 of a first dimension, a second portion 204 (
The third portion 206 extends above the second portion 204, is generally annular or disk-shaped and has a third radius R3 (
The coil winding portion 114 seats or rests upon the first portion 202 of the magnetic piece. The radius R1 of the first portion 202 in the example embodiment shown is relatively large so that the outer periphery of the first portion 202 extends nearly completely between the opposed end edges of the sheets 104, 106 as best seen in
The second and third portions 204 and 206 having the lesser radiuses R2 and R3, in contrast with the first portion 118, are not coextensive with the upper sheet 104 and a smaller contact area is provided. The plurality of turns in the coil winding portion 114 extend about the second portion 204 of the core piece 201. The coil 102 may be directly formed on and wound around the drum core 201 such that the winding portion 114 is wound on the second portion 204. The winding 102 may be prefabricated on the drum core 201 and provided as a subassembly for manufacturing the component 200.
The core piece 201 may be fabricated from ferrite, any of the magnetic powder particles disclosed above, or other appropriate magnetic material known in the art. The core piece 201 provides structural support to the coil 102 during lamination processes, assists in locating the coil 102 relative to the composite sheets 104, 106 and provides additional magnetic performance of the completed component 200, especially when the core piece 201 has a greater magnetic permeability than the composite sheets 104, 106. In such an embodiment, the higher direct current capacity of the coil 102 may therefore be coupled with the core piece 201 having a greater magnetic permeability for even greater inductance.
Except for the core piece 201 used in lieu of the core piece 108, the manufacture of the component 200 is substantially the same as described above, with similar benefits and advantages.
The component 300 is otherwise similar in all aspects to the component 100 previously described. Like reference characters are therefore utilized for corresponding features in the embodiments 100 and 300. The reader is referred to the discussion above for the features of the component 300 that overlap with the features of the component 100.
By virtue of the dielectric, magnetic, and polymeric properties of the sheets 104 and 106 as described, miniaturized, low profile magnetic components such as power inductors may be provided with large inductance values as well as large direct current capacity that have heretofore been very difficult to manufacture in an economical manner, if at all. Similar benefits may accrue to other types of miniaturized magnetic components such as transformers.
The benefits and advantages of the invention are now believed to be amply disclosed in relation to the exemplary embodiments described.
A magnetic component has been disclosed including: at least one conductive wire coil including a first lead, a second lead, and a plurality of turns between the first and second lead; and at least one insulating, dielectric, and magnetic sheet comprising a composite mixture of soft magnetic powder particles with no shape anisotropy and a binder material, the composite being provided as a freestanding, solid sheet layer; wherein the at least one insulating, dielectric, and magnetic sheets is laminated to the coil, thereby defining a monolithic core structure embedding the at least one coil.
Optionally, the binder material may be one of a thermoplastic or thermoset resin. The resin may be polymer based. The at least one insulating, dielectric, and magnetic sheet may be laminated to the coil with at least one of heat and pressure. The magnetic powder particles may comprise at least 90 percent by weight of the mixture in the at least one insulating, dielectric, and magnetic sheet. An effective magnetic permeability of the at least one insulating, dielectric, and magnetic sheet may be at least 10. A density of the at least one insulating, dielectric, and magnetic sheet may be at least 3.3 grams per cubic centimeter. Terminal tabs may be coupled to each of the first and second leads. Surface mount terminations coupled to the respective first and second leads.
A magnetic core piece may be separately provided from the at least one sheet, with the plurality of turns extending about the magnetic core piece, and the at least one sheet being laminated to the coil and the magnetic core piece. The magnetic core piece may include a first portion having a first radius and a second portion having a second radius different from the first radius, with the second portion extending from the first portion and the plurality of turns extending about the second portion. The separately fabricated core piece may be a drum core, and the wire coil may be wound around the drum core.
The component may be a power inductor. The at least one insulating, dielectric, and magnetic sheet may include a first sheet and a second sheet, with each of the first and second sheets comprising a composite mixture of soft magnetic powder particles with no shape anisotropy and a binder material, the composite being provided as a freestanding, solid sheet layer; wherein the at least one coil is interposed between the first and second sheet, and wherein the first and second sheets are laminated to the coil and to one another to embed the at least one coil in a monolithic core structure.
Another embodiment of a magnetic component is also disclosed including: first and second insulating, dielectric, and magnetic sheets; at least one conductive wire coil including a first lead, a second lead, and a plurality of turns between the first and second lead; wherein the at least one conductive coil is interposed between the first and second insulating, dielectric, and magnetic sheets; wherein the first and second insulating, dielectric, and magnetic sheets are laminated to the coil to embed the coil therebetween and define a monolithic core structure without creating a physical gap; and the first and second insulating, dielectric, and magnetic sheets each comprising: a composite sheet including soft magnetic powder particles with no shape anisotropy and a polymer binder consisting of thermoplastic or thermoset resin which can be laminated with heat and pressure; the composite being provided as a freestanding, solid sheet layer; wherein a density of the composite is at least 3.3 grams per cubic centimeter; wherein the magnetic powder particles comprise at least 90% by weight percent of the composite; and wherein the effective magnetic permeability of the composite is at least 10.
The magnetic component may further include a magnetic core piece separately provided from the first and second sheets, with the plurality of turns extending about the magnetic core piece, and the first and second sheets being laminated to the coil and the separately fabricated core piece to form a monolithic core structure. The separately fabricated core piece may include a first portion having a first radius and a second portion having a second radius different from the first radius, with the second portion extending from the first portion and the plurality of turns extending about the second portion. The magnetic core piece may be a drum core, and the wire coil may be wound around the drum core. The magnetic component may further include surface mount terminations, and the component may be a power inductor.
An embodiment of a magnetic component is additional disclosed including: first and second insulating, dielectric, and magnetic sheet each comprising a composite being provided as a freestanding, solid sheet layer; at least one conductive wire coil including a first lead, a second lead, and a plurality of turns between the first and second lead; a magnetic core piece separately provided from the first and second insulating, dielectric and magnetic sheets; the plurality of turns extending about the magnetic core piece; wherein the at least one conductive coil and the magnetic core piece is interposed between the first and second insulating, dielectric, and magnetic sheets; wherein the first and second insulating, dielectric, and magnetic sheets are laminated to the coil and the magnetic core piece to embed the coil and the magnetic core piece and define a monolithic core structure without creating a physical gap; and surface mount terminations connected to the first and second coil leads.
The magnetic core piece may include a first portion having a first radius and a second portion having a second radius different from the first radius, with the second portion extending from the first portion and the plurality of turns extending about the second portion. The separately fabricated core piece may be a drum core, and the wire coil may be wound around the drum core. The composite may comprise: soft magnetic powder particles with no shape anisotropy; and a polymer binder consisting of thermoplastic or thermoset resin which can be laminated with heat and pressure; wherein a density of the composite is at least 3.3 grams per cubic centimeter; wherein the magnetic powder particles comprise at least 90% by weight of the composite; and wherein the effective magnetic permeability of the composite is at least 10. The component may be a power inductor.
A method of fabricating a magnetic component including a wire coil and at least one insulating, dielectric and magnetic sheet is also disclosed. The method includes: assembling at least one wire coil with the at least one insulating, dielectric and magnetic sheet layer; the at least one sheet comprising a composite provided as a freestanding, solid sheet layer, the composite including soft magnetic powder particles with no shape anisotropy; and laminating the at least one insulating, dielectric, and magnetic sheet to the at least one wire coil, thereby forming a monolithic core structure embedding the coil therein without a physical gap.
Optionally, assembling at least one wire coil with the at least one sheet may include: interposing at least one wire coil with first and second insulating, dielectric, and magnetic sheets each being a composite provided as a freestanding, solid sheet layer, the composite in each sheet including soft magnetic powder particles with no shape anisotropy; and laminating the first and second insulating, dielectric, and magnetic sheets to the at least one wire coil, thereby forming a monolithic core structure embedding the coil therein without a physical gap. The method may also include providing surface mount terminations connected to the first and second leads. The coil may include at least one conductive wire coil including a first lead, a second lead, and a plurality of turns between the first and second lead; and the component may further include a magnetic core piece separately provided from the at least one insulating, dielectric, and magnetic sheet, the method further comprising: extending the plurality of turns around a portion of the magnetic core piece; and laminating the at least one insulating, dielectric, and magnetic sheet to the coil and the magnetic core piece. Extending the plurality of turns around a portion of the magnetic core piece may include winding the coil around a drum core.
A product may be formed by the method, and the product may be a power inductor. The composite may further include: a polymer binder consisting of thermoplastic or thermoset resin which can be laminated with heat and pressure; wherein a density of the composite is at least 3.3 grams per cubic centimeter; wherein the magnetic powder particles comprise at least 90% by weight of the composite; and wherein the effective magnetic permeability of the composite is at least 10.
An embodiment of a magnetic component is also disclosed including: at least one conductive wire coil including a first lead, a second lead, and a plurality of turns between the first and second lead; and a magnetic composite material defining a monolithic core structure embedding the at least one coil without creating a physical gap; wherein the magnetic composite material includes metal powder particles with no shape anisotropy and a binder; wherein a density of the composite is at least 3.3 grams per cubic centimeter; wherein the metal powder particles comprise at least 90% by weight percent of the composite; and wherein the effective magnetic permeability of the composite is at least 10.
The monolithic core structure may be formed from at least one insulating, dielectric, and magnetic sheet laminated to the at least one coil. The at least one sheet may include first and second sheets, and the conductive coil is interposed between the first and second insulating, dielectric, and magnetic sheets.
This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.
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