Patent Application
20240128012
The field of the invention relates generally to surface mount electromagnetic component assemblies and methods of manufacturing the same, and more specifically to high current bottom sunken surface mount components and methods of manufacturing the same.
Electromagnetic inductor components are known that utilize electric current and magnetic fields to provide a desired effect in an electrical circuit. Current flow through a conductor in the inductor component generates a magnetic field that can be concentrated in a magnetic core. The magnetic field can, in turn, store energy and release energy, cancel undesirable signal components and noise in power lines and signal lines of electrical and electronic devices, or otherwise filter a signal to provide a desired output.
Increased power density in circuit board applications has resulted in a further demand for inductor solutions to provide power supplies in reduced package sizes with desired performance. Conventional surface mount inductor solutions, however, are disadvantaged in some aspects and improvements are accordingly desired.
An inductor assembly for a circuit board, the inductor assembly may comprise a magnetic core structure, a first conductive winding, and a second conductive winding. The magnetic core structure may comprise first and second magnetic core pieces, wherein each of the first and second magnetic core pieces may comprise a top side, a bottom side, a vertical front side, and a vertical rear side comprising a first vertical slot and a second vertical slot extending in spaced apart relation from the first vertical slot. The magnetic core structure may comprise a third magnetic core piece interposed between the vertical rear sides of the first magnetic core piece and the second magnetic core piece. The third magnetic core piece may comprise opposing top and bottom sides and opposing vertical sides, wherein a combination of each of the first and second magnetic core pieces and the third magnetic core piece defines coil slots. In some embodiments, the first conductive winding may be assembled to the first magnetic core piece and the third magnetic core piece, and a second conductive winding may be assembled to the second magnetic core piece and the third magnetic core piece, each of the first and second conductive windings comprises a top section and first and second leg sections each extending perpendicular to the top section.
In some embodiments, each of the first and second leg sections of each of the first and second conductive windings may comprise a surface mount termination located at a bottom section of that leg section, wherein when the first, second, and third magnetic core pieces may be combined with the first and second conductive windings to form the inductor assembly, the surface mount terminations of the first and second leg sections protrude downward relative to the bottom sides of the first, second, and third magnetic core pieces to from a space between the inductor assembly and the circuit board.
In some embodiments, the first conductive winding may be molded to the first magnetic core piece and the third magnetic core piece, and the second conductive winding may be molded to the second magnetic core piece and the third magnetic core piece.
In some embodiments, the first and second magnetic core pieces may be formed and arranged as mirror images of one another. In some embodiments, the third magnetic core piece may be differently shaped from the first and second magnetic core pieces. In some embodiments, each of the opposing vertical sides may comprise a third vertical slot and a fourth vertical slot, wherein the first and second vertical slots on the vertical rear side of each of the first and second magnetic core pieces align with the third and fourth vertical slots on each of the opposing sides of the third magnetic core piece respectively. In some embodiments, the combination of each of the first and second magnetic core pieces and the third magnetic core piece may further define a recessed top surface
In some embodiments, the first and second leg sections each may extend perpendicular to the top section at each opposing end edge of the top section, wherein the top sections of each respective first and second conductive windings may be respectively received in the recessed top surface of the magnetic core structure, wherein the first and second legs sections of each respective first and second conductive windings may be respectively received in the coil slots of the magnetic core structure. In some embodiments, the surface mount termination may be configured to increase a width of a bottom end of each of the conductive windings.
In some embodiments, the first vertical slot and the second vertical slot may be parallel and may be spaced from side edges of the first and second magnet core pieces that interconnect the vertical front side and the vertical rear side. In some embodiments, the first and second conductive windings may be U-shaped coils. In some embodiments, the each of the first, the second, and the third core pieces may define half of the full slot. In some embodiments, the bottom sides of the first, the second and the third magnetic core pieces may be flat and may extend coplanar to one another in a spaced apart and may be parallel to the plane of the circuit board.
In some embodiments, the vertical rear side of each of the first and the second magnetic core pieces may be gapped from each of the opposing vertical sides of the third magnetic core piece. In some embodiments, the top section of each of the conductive windings comprises an extension may extend to the vertical front side of each of the first and the second magnetic core pieces.
In some embodiments, the surface mount termination may comprise a lateral section extending perpendicularly to the leg section, and a terminal section that extends perpendicularly to the lateral section and to the circuit board. The terminal section may further comprise a terminal extension extending toward the vertical front side but not reaching the vertical front side of each of the first and second magnetic core pieces.
In some embodiments, the first, second, or third magnetic core pieces may comprise one or more cutouts on a surface to define an inductance profile of that magnetic core piece, each of the one or more cutouts may define a first cross-sectional area different from a second cross sectional area of another portion of the surface without the cutout.
In some embodiments, the one or more cutouts comprise one or more exterior grooves extending vertically in a spaced apart on the vertical front side from the top side to the bottom side of each of the magnetic core pieces. In some embodiments, the one or more cutouts may comprise an interior groove may extend horizontally across the vertical rear side between side edges of each of the magnetic core pieces. In some embodiments, the one or more cutouts may comprise a depressed planar surface extending vertically across the vertical rear side between the vertical slots of each of the magnetic core pieces from the top side to the bottom side. In some embodiments, the depressed planar surface may extend in a recessed manner on the vertical rear side of each of the magnetic core pieces. In some embodiments, the depressed planar surface may have a cutout depth less than a slot depth of the first vertical slot and the second vertical slot.
Non-limiting and non-exhaustive embodiments are described with reference to the following FIGs, wherein like reference numerals refer to like parts throughout the various drawings unless otherwise specified.
State of the art telecommunications and computing (e.g., data center, cloud) applications require ever more powerful and high-performance power supplies. In the case of medium and low power supplies (below 40 amps), a single-phase power supply architecture is adequate. However, with the latest processors, field programmable gate arrays (FPGAs), application specific integrated circuits (ASICs), and cloud computing systems, higher levels of power and greater performance are in demand. New power supply modules for high-current computing applications such as servers and the like are therefore needed.
In order to achieve new and higher thresholds of power delivery, multiphase power supply architectures are desired. Multiphase power supplies can be designed to be much more efficient than single-phase supplies at higher power levels, and the architecture also allows for more operational flexibility. Such flexibility could also include turning off some of the phases when they aren't needed to deliver the required power, and redundancy if failures occur in certain portions of the power supply system. Multiphase power supplies, however, require much more complex design strategies. Importantly, the increased complexity falls largely on the magnetic components of the power supplies. Innovative integrated inductor design is needed for both non-coupled and coupled inductors to address these challenges and enable a new standard in high-performance power supplies for modern use cases.
For surface mount inductor component manufacturers, the challenge has been to provide inductor components so as to minimize the area occupied on a circuit board by the inductor component (sometimes referred to as the component “footprint”) and/or to minimize the component height measured in a direction perpendicular to a plane of the circuit board (sometimes referred to as the component “profile”). By decreasing the footprint and profile of inductor components, 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 a comparable size. Miniaturizing electronic components in a cost-effective manner has, however, introduced a number of practical challenges to electronic component manufacturers in a highly competitive marketplace. Because of the high volume of inductor components needed for electronic devices in great demand, cost reduction in fabricating inductor components, without sacrificing performance has been of great practical interest to electronic component manufacturers.
In general, each generation of electronic devices needs 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 electromagnetic inductor components that, among other things, may provide energy storage and regulation capabilities, meeting increased power demands while continuing to reduce the size of inductor components that are already quite small, has proven challenging as a general proposition, and especially challenging for certain applications.
Multiple phase paralleled buck converters are widely utilized in power supply applications to manage higher current applications and provide enhanced capabilities and functions. A multiphase buck converter can more efficiently handle higher power than a single-phase buck converter of equivalent power output specification, imposing new demands for integrated multi-phase non-coupled and coupled inductors for power supply converter applications in telecommunications and computing applications due to their space saving advantages on a circuit board.
In some cases, the integrated multi-phase inductor components desirably operate with low inductance and high inductance for fast load transient response, high DC bias current resistance, and high efficiency individually. With continuous inductor size reduction, it is more and more challenging to achieve both high initial inductance and high DC bias current resistance together with conventional single step inductance drop characteristics.
Swing-type inductor components are known that are self-adjustable to achieve optimal trade-off between transient performance, DC bias current resistance and efficiency in power converter applications. Unlike other types of inductor components wherein the inductance of the component is generally fixed or constant despite the current load, swing-type inductor operate with an inductance that varies with the current load. Specifically, the swing-type inductor component may include a core that can be operated almost at magnetic saturation under certain current loads. The inductance of a swing core is at its maximum for a range of relatively small currents, and the inductance changes or swings to a lower value for another range of relatively higher currents. Swing-type inductors and their multiple step inductance rolloff characteristics can avoid the limitations of other types of inductor components in power converter applications, but are difficult to economically manufacture in desired footprints while still delivering desired performance. Improvements in swing-type inductor components are accordingly desired.
In certain installations, so-called bottom sunken surface mount inductor components are desired in which room is provided beneath the inductor component to accommodate a mounting of a separately provided component on a circuit board with the inductor component extending over the top of the separately provided component in a vertically stacked arrangement. Meeting such desires in higher current circuitry presents further challenges in the design of the inductor component to achieve the desired performance in the desired package size with acceptable performance. Improvements are accordingly desired.
Exemplary embodiments of integrated bottom sunken surface mount inductor components are described hereinbelow that may more capably perform in higher current, higher power circuitry than conventional inductor components now in use. Integrated multi-phase inductor component assemblies are further manufacturable at relatively low cost and with simplified fabrication processes and techniques. Further miniaturization of the exemplary embodiments of integrated multi-phase inductor is also facilitated to provide surface mount inductor components with smaller package size, yet improved capabilities in high current applications. Bottom sunken features are economically provided, and swing inductor functionality is also realized, with relatively simply shaped core pieces and coils that facilitate economic al manufacturing. Method aspects may be in part explicitly discussed and in part apparent from the following description.
Referring to
In a contemplated embodiment, the inductor component 100 may be connected through the circuit board 110 to one of the phases of the multiphase buck converter. Additional inductor components 100 may be provided as discrete components from the inductor component 100 on the board 110 and may respectively connect to the other phases of the multiphase buck converter, with each inductor component 100 on the circuit board 110 being independently operable from the other inductor components 100. As multiphase power supply architecture and multiphase buck converters are known and within the purview of those in the art, further description thereof is omitted herein. The multiphase buck converter power supply application is, however, described for the sake of illustration rather than limitation, and other power supply applications are possible whether or not they relate to power supplies including buck converters.
The magnetic core pieces 104a, 104b may be similarly sized and shaped core pieces having a front side 120 and a rear side 122. The front side 120 may be flat and smooth while the rear side 122 maybe formed with spaced apart, generally parallel and vertically extending coil slots 124a, 124b. The coil slots 124a, 124b may be spaced from the respective side edges of the core pieces 104a, 104b that interconnect the front and rear sides 120, 122 as shown.
The magnetic core piece 106, unlike the core pieces 104a and 104b, may comprise opposing sides 126a, 126b that each include a pair of spaced apart, generally parallel and vertically extending coil slots 128a, 128b. As such, the core piece 106 may comprise four coil slots while the core pieces 104a, 104b may comprise two coil slots piece. The coil slots 128a, 128b in magnetic core piece 106 are also spaced from the respective side edges of the core piece 106 that interconnect the opposing sides 126a, 126b as shown.
During assembly of the magnetic core structure 102, the magnetic core pieces 104, 106 may be inverted relative to one another with the core piece 106 in between. That is, the core pieces 104a, 104b may be rotated 180° relative to one another such that the coil slots 124a, 124b on the rear side 122 in each core piece 104a, 104b may align with and face the respective coil slots 128a, 128b in each side of the core piece 106. As shown in
In some embodiments, the core pieces 104a, 104b, and 106 may share a height dimension measured in the direction perpendicular to the plane of the circuit board 110 (i.e., in the vertical direction shown in
The conductive coils 108a, 108b as shown in
In some embodiments, each coil 108a, 108b may comprise straight and parallel leg sections each extending perpendicular to the top sections 130a, 130b at each opposing end edge of the top sections 130a, 130b. The axial length of each of the leg sections may be greater than the axial length of the top sections 130a, 130b such that each coil 108a, 108b as shown is much taller than it is wide. The leg sections may be received in the coil slots of the core pieces 104a, 104b, and 106 in the assembly of the magnetic core structure 102.
At the bottom side of each of the coil leg sections, opposite to the top sections 130a, 130b, surface mount terminations may be formed, which may comprise a lateral section 134 extending perpendicularly to the vertically extending leg sections (i.e., horizontally in the assembly as shown in
The coils 108a, 108b may be inverted relative to one another in the assembly such that the upper and lower extensions 132a, 132b and the lower extensions 138 in each coil 108a, 108b may extend in opposite directions in the assembled component 100. The coils 108a, 108b may be rotated 180° relative to one another when inter-fitted with the coil slots 124a, 124b and the coil slots 128a, 128b in the core pieces 104a, 104b and 106. The lateral sections 134 in each coil 108a, 108b may increase the width of the coils 108a, 108b on their lower ends relative to the vertical leg sections of the inverted U-shaped portion of the coils 108a, 108b. By virtue of such increased width, the terminals 136 of the coils 108a, 108b may extend alongside the outer walls of the magnetic core structure 102, and the lower side of the terminals 136 that abut the circuit board 110 may extend at a distance from the bottom surface of the magnetic core structure 102. This terminal configuration may create a space (best seen in
Each coil 108a, 108b may be fabricated from a sheet of conductive material having a uniform thickness that is cut and formed or bent in the particular shape having the particular features shown. The coils 108a, 108b may be advantageously provided in the shape as shown as a fully preformed element that can be simply assembled with the magnetic core pieces 104a, 104b and 106 at a separate stage of manufacture without additional forming or shaping of the coil 108 being required.
The magnetic materials used to fabricate each respective core pieces 104a, 104b, and 106 may be selected from a variety of soft magnetic particle materials known in the art and formed into the illustrated shapes according to known techniques such as molding of granular magnetic particles to produce the desired shapes. Soft magnetic powder particles used to fabricate the magnetic core pieces 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, Mn—Zn power ferrite materials, Mn—Zn high permeability ferrite core materials, and other suitable materials known in the art. In some cases, magnetic powder particles may be coated with an insulating material such the magnetic core pieces may possess so-called distributed gap properties familiar to those in the art and fabricated in a known manner. In various embodiments, the magnetic core pieces 104a, 104b and 106 may be fabricated from the same magnetic material or from different magnetic materials as desired. In contemplated embodiments, however, the inductor component 100 operates with a fixed or constant inductance in a range of currents up to the point where the magnetic core becomes saturated.
Also, in contemplated embodiments, the coils 108a, 10b may sufficiently spaced apart from one another by the core piece 106 to avoid any magnetic coupling of the coils 108a, 108b. Depending on the particular application of the inductor component 100, however, in some cases the coils 108a, 108b may be magnetically coupled to produce desired effects rather than being uncoupled as described above.
As demonstrated in the following exemplary embodiments described below, the benefits of the inductor component 100 can be further enhanced by providing additional features in the magnetic core pieces that define magnetic gaps in the core structure, in addition to and apart from any gaps that may be optionally provided between the adjacent core pieces themselves. The additional magnetic gaps provided by such additional features are located in a flux path produced by current flowing through the coils, and the additional magnetic gaps reduce a cross sectional area of the magnetic core piece to purposely saturate a portion of the magnetic core at a desired current before the rest of the flux path reaches complete magnetic saturation. The additional magnetic gaps, as implemented in the examples described next, beneficially allow a partial saturation of the magnetic core structure to achieve desirable swing inductor effects wherein the magnetic core is operable at more than one inductance value in different ranges of operating currents.
The inductor component 150 may comprise a magnetic core structure 152 with core pieces 154a, 154b in lieu of the core pieces 104a, 104b described above. The core pieces 154a, 154b, unlike the core pieces 104a, 104b, may comprise exterior grooves 156 in their front sides 120. Otherwise, the core pieces 154a, 154b may be similar to the core pieces 104a, 104b and may be assembled to the coils 108a, 108b and the core piece 106 in the same manner. The grooves 156 may extend vertically in a spaced apart and generally parallel relationship in the example shown, and may further extend fully from the top surface 158 to the bottom surface 160 of the core pieces 154a, 154b. As best shown in
Importantly, the grooves 156 may define physical gaps in the magnetic core structure that create localized magnetic gaps in the core structure 152. The physical gaps defined by the grooves 156 may be located to strategically interrupt a flux path of the coils 108a, 108b in the operation of the inductor component 150 where the localized portion of the magnetic core structure 152 may saturate while the rest of the magnetic core does not. Such interruption of the flux path in localized areas realizes swing-type inductor characteristics wherein the component 150 may operate with an inductance that varies with the current load. Specifically, and by virtue of the gaps formed with the grooves 156, the magnetic core 152 may be operated almost at a maximum level for a range of relatively small currents, and the inductance changes or swings to a lower value for another range of relatively higher currents. The actual high and low inductance values and accompanying low and high current ranges in use may vary depending on the magnetic material utilized to fabricate the core pieces and the specifics of the gaps defined by the grooves (e.g., length width and depth and the location of the groove in the flux path). The shape and geometry of the grooves 156 shown in
The inductor component 200 may comprise a magnetic core structure 202 with core pieces 204a, 204b in lieu of the core pieces 104a, 104b described above. The core pieces 204a, 204b, unlike the core pieces 104a, 104b, may comprise an interior groove 206 in their respective rear side 122. In some embodiments, the core pieces 204a, 204b may be similar to the core pieces 104a, 104b and may be assembled to the coils 108a, 108b and the core piece 106 in the same manner. In the example shown, the groove 206 in each core piece 204a, 204b may extend horizontally across the rear side 122 and may extend fully between side edges 208 and 210 of the core pieces 204a, 204b. The groove 206 in the example shown is about equidistant from the top and bottom surfaces 158 and 160, although it alternatively may be located closer to one of the top and bottom surfaces 158 and 160. In some embodiments, the groove 206 may extend on both sides and in between the clip channels 124a, 124b formed in each core piece 204a, 204b in the example shown. In some embodiments, the groove 206 may be located in between the clip channels 124a, 124b or on the side of the clip channels 124a, 124b but not in between. Numerous variations are possible in this regard.
Importantly, the grooves 206 in each core piece 204a, 204b may define localized physical gaps in the interior of the magnetic core structure 202 that in turn create magnetic gaps in the core structure 202 where the localized portion of the magnetic core structure 202 can saturate while the rest of the magnetic core does not. The physical gaps defined by the grooves 206 may be located to strategically interrupt a flux path of the coils 108a, 108b in the operation of the inductor component 200. Such interruption of the flux path may realize swing-type inductor characteristics wherein the component 200 operates with an inductance that varies with the current load. Specifically, and by virtue of the gaps formed with the grooves 206, the magnetic core 200 can be operated at a maximum level for a range of relatively small currents, and the inductance changes or swings to a lower value for another range of relatively higher currents. The actual high and low inductance values and accompanying low and high current ranges in use may vary depending on the magnetic material utilized to fabricate the core pieces and the specifics of the gaps defined by the groove (e.g., length width and depth and the location of the groove in the flux path). The grooves 206 shown in
The inductor component 250 may comprise a magnetic core structure 252 with core pieces 254a, 254b in lieu of the core pieces 104a, 104b described above. The core pieces 254a, 254b, unlike the core pieces 104a, 104b, may comprise a depressed surface 256 on their respective rear sides 122. The depressed surface 256 in each core piece 254a, 254b may be generally planar and may extend in a recessed manner on the rear sides 122, but has a depth that is less than depth of the coil slots 124a, 124b. Otherwise, the core pieces 204a, 204b may be similar to the core pieces 104a, 104b and may be assembled to the coils 108a, 108b and the core piece 106 in the same manner. The depressed surface 256 in each core piece 204a, 204b may extend vertically across the rear side 122 and may extend between the clip channels 124a, 124b of the core pieces 254a, 254b and extends fully between the top and bottom surfaces 158 and 160 of each core piece, although a depressed surface may be located elsewhere and may extend only partly across the core pieces in another embodiment. Numerous variations are possible in this regard.
Importantly, the depressed surface 256 in each core piece 254a, 254b may define localized physical gaps in the interior of the magnetic core structure 252 that in turn create magnetic gaps in the core structure 252 where the localized portion of the magnetic core structure 252 can saturate while the rest of the magnetic core does not. The physical gaps defined by the depressed surfaces 256 may be located to strategically interrupt a flux path of the coils 108a, 108b in the operation of the inductor component 250. Such interruption of the flux path realizes swing-type inductor characteristics wherein the component 250 operates with an inductance that varies with the current load. Specifically, and by virtue of the gaps formed with the depressed surfaces 256, the magnetic core 250 can be operated at a maximum level for a range of relatively small currents, and the inductance changes or swings to a lower value for another range of relatively higher currents. The actual high and low inductance values and accompanying low and high current ranges in use may vary depending on the magnetic material utilized to fabricate the core pieces and the specifics of the gaps defined by the depressed surface (e.g., length width and depth and the location of the depressed surface 256 in the flux path). The depressed surfaces 256 shown in
The flux paths on the left side of the magnetic core structure shown in
The flux paths on the right side of the magnetic core structure in
The flux paths on the top side of magnetic core structure in
The adjacent sides of the magnetic core pieces in the magnetic core structure may or may not be gapped from one another depending on the initial inductance required for the end use application of the inductor component. Additional magnetic gaps such as those described above may be defined via the core pieces described above in the inductor components 150, 200 and 250 to provide desired swing inductor characteristics in addition to the desired initial inductance of the components.
In the absence of an additional magnetic gap in the core structure (e.g., the magnetic core structure 102) the inductor component may be operable with a fixed inductance across a single range of currents until the magnetic core reaches saturation. When additional localized magnetic gaps are strategically present (e.g., the localized gaps in the magnetic core structures 152, 202, 252), which may be established with an exterior or interior groove or a depressed surface as described above which facilitates a partial saturation of the magnetic core in localized areas of the magnetic core structure, the additional magnetic gaps realize a different magnetic reluctance along the flux paths at different load currents and therefore imparts the type of swing inductor functionality described above. The localized magnetic gaps may be located anywhere in the flux path to help achieve swing inductor effects as long as the gaps are not located along a shared flux path for the respective flux paths present.
For example, in the magnetic core structure shown in
The concepts described above can also be extended to other magnetic core configurations. For example,
The inductor component 300 may comprise a magnetic core structure with core pieces 104a, 104b, and 106 as described above. The three discrete core pieces 104a, 104b, and 106 that in combination may receive and contain a pair of primary conductive coils 320a and 320b, and a pair of secondary conductive coils 308a and 308b that may be surface mounted to a circuit board 110. In some embodiments, the core pieces 104a, 104b and 106 may comprise aligned and generally flat top surfaces, with each piece formed with respective depressions to accept a portion of the primary conductive windings 320a and 320b and a portion of the secondary conductive windings 308a and 308b as shown on the top side of the core pieces 104a, 104b and 106.
The primary conductive windings 320a and 320b as shown in
The secondary conductive windings 308a and 308b as shown in
In some embodiments, each secondary conductive windings 308a and 308b may comprise straight and parallel leg sections each extending perpendicular to the top sections 330a, 330b at each opposing end edge of the top sections 330a, 330b. The leg sections are received in the coil slots of the core pieces 104a, 104b in the assembly of the magnetic core structure 102. Similar to windings 108a, 108b as shown is
In some embodiments, the primary conductive windings 320a and 320b may be of the same height from the top sections 302a, 302b to the terminal section 304 as height if the secondary conductive windings 308a and 308b from the top sections 330a, 330b to the terminal section 336. In some embodiments, distance between the leg sections of the primary conductive windings 320a and 320b may be the same as distance between the leg sections of the secondary conductive windings 308a and 308b. In some embodiments, when assembling, the primary conductive windings and the secondary conductive windings may be assembled with a space in between.
In some embodiments, the inductor component 350 may comprise a magnetic core structure fabricated in three discrete core pieces 354a, 354b, and 356 that in combination to receive and contain a primary conductive winding 340 and a pair of secondary conductive windings 360a and 360b that may be surface mounted to a circuit board 110. The magnetic core pieces 354a, 354b may be similarly sized and shaped core pieces having a front side 420 and a rear side 322. The front side 420 may be flat and smooth while the rear side 122 may be formed with a vertically extending recessed space 324. The recessed space 324 may be spaced from the respective side edges of the core pieces 354a, 354b that interconnect the front and rear sides 420, 322 as shown.
The magnetic core piece 356, unlike the core pieces 354a and 354b, may comprise opposing sides 426a, 426b that each comprise a vertically extending recessed spaces 428a, 428b. The recessed space 428a, 428b may be spaced from the respective side edges of the core pieces 356 that interconnect the front and rear sides opposing sides 426a, 426b as shown. The recessed space 324 on the rear side 322 in each core piece 354a, 354b may align with and face the respective recessed spaces 428a, 428b in each side of the core piece 356.
In some embodiments, the core pieces 354a, 354b, and 356 may comprise aligned and generally flat top surfaces, with each piece formed with respective depressions to accept a portion of the primary conductive winding 340 or secondary conductive windings 360a, and 360b as shown on the top side of the core pieces 354a, 354b and 356. The rear sides 322 of the magnetic core pieces 354a, 354b may be optionally spaced or gapped from the respective sides 426a, 426b of the magnetic core piece 356 in the magnetic core structure as needed to realize initial inductance requirements.
The primary conductive winding 340 as shown in
The secondary conductive windings 360a, and 360b as shown in
The primary winding 340 and each of secondary windings 360a, 360b may be coupled individual, wherein the primary winding 340 may be decoupled or weak coupled between the two secondary windings 360a, 360b.
In some embodiments, the I-shaped core piece 406 may comprise a flat top surface. The primary conductive windings pair 430a, 430b as shown in
Any of the magnetic core structures described above may be constructed from simply shaped core pieces and may therefore be provided at lower cost with simpler assembly than conventional inductor components with bottom sunken features and/or swing-type inductors that necessitate more complicated shapes of magnetic pieces and more complicated winding structures.
The inductance characteristics are shown in
In contrast, and as can be seen in the plot in
The inductor components described above offer a considerable variety of swing-type inductor functionality with bottom sunken features in an economical manner while using a small number of component parts that are manufacturable to provide small inductors at relatively low cost with superior performance advantages. Particularly in the case of high-power density electrical power system applications such as the multi-phase power supply circuits and power converters for computer servers, computer workstations and telecommunication equipment, the swing-type inductor components described herein are operable with desired package size and desired efficiency that is generally beyond the capability of conventionally constructed surface mount swing-type inductor components.
It is understood that the bottom sunken features and the swing inductor features can be practiced separately and in combination. While some of the examples above combine these features into the same component, the magnetic gaps in the magnetic core structures do not necessarily depend on the bottom sunken features of the coils 108a, 108b. Embodiments are therefore contemplated wherein the magnetic core structures and magnetic core pieces are used with coils that do not include integrated bottom sunken features such as those described above and vice versa. In other words, while the magnetic core structures described above may be particularly beneficial for use with the coils 108a, 108b described above, their benefits are not necessarily limited to the coils 108a, 108b and as such other conductive coils may be employed while realizing some of the same benefits. Likewise, the benefits of the coils 108a, 108b are not necessarily limited to the specific magnetic core pieces described herein and as such the coils 108a, 108b may be used with alternative magnetic core pieces while still realizing similar benefits.
Finally, the concepts above can be extended to single phase inductor components (i.e., inductor component having only one coil) and to integrated inductor components having more than two coils. The bottom sunken features and/or the swing inductor features are scalable by adding or subtracting the number of coils and core pieces to flexibly meet different needs while using a reduced number of component parts that can be assembled in various different combinations.
The benefits and advantages of the inventive concepts are now believed to have been amply illustrated in view of the exemplary embodiments disclosed.
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.
