This application claims priority to China Application Serial Number 201510169368.5, filed Apr. 10, 2015 and China Application Serial Number 201510446385.9, filed Jul. 27, 2015, which are herein incorporated by reference.
Field of Invention
The present disclosure relates to a power technology. More particularly, the present disclosure relates to an integrated inductor apparatus and an integrated magnetic core of the same.
Description of Related Art
In recent years, miniaturization of switching mode power supply is an important trend of the development of power technology. In a switching mode power supply, magnetic components occupy a certain degree of the volume and contribute a certain degree of the loss. Therefore, the design and improvement of the magnetic components become very important.
In some application scenarios, such as an application with large current condition, a plurality of paths of circuits connected in parallel are used to decrease the occurrence of the ripples. In common designs of the magnetic components, in order to guarantee the unsaturation and low loss of the material, the volume of the magnetic components has to be increased to decrease the strength of the magnetic induction in the magnetic core. As a result, it is a tradeoff between persuading high efficiency and persuading high power density.
Accordingly, what is needed is a switching mode power supply and an integrated device of the same to address the above issues.
An aspect of the present invention is to provide an integrated magnetic core, integrated with a plurality of inductor windings to form a plurality of inductors. The integrated magnetic core includes at least two windows and a plurality of magnetic core units. Each of the at least two windows has at least one of the inductor windings disposed therein. Each of the magnetic core units has a closed geometrical structure to form one of the at least two windows, wherein two of the neighboring magnetic core units have a shared magnetic core part. The magnetic core units include at least two kinds of material having different magnetic permeability corresponding to different sections of the magnetic core units, wherein the reluctance of the shared magnetic core part is smaller than the reluctance of a non-shared magnetic core part of the magnetic core units.
Yet another aspect of the present invention is to provide an integrated inductor apparatus to integrate a plurality of inductors. The integrated inductor apparatus includes a plurality of inductor windings and an integrated magnetic core integrated with the inductor windings to form the inductors. The integrated magnetic core includes at least two windows and a plurality of magnetic core units. Each of the at least two windows has at least one of the inductor windings disposed therein. Each of the magnetic core units has a closed geometrical structure to form one of the at least two windows, wherein two of the neighboring magnetic core units have a shared magnetic core part. The magnetic core units include at least two kinds of material having different magnetic permeability corresponding to different sections of the magnetic core units, wherein the reluctance of the shared magnetic core part is smaller than the reluctance of a non-shared magnetic core part of the magnetic core units.
These and other features, aspects, and advantages of the present invention will become better understood with reference to the following description and appended claims.
It is to be understood that both the foregoing general description and the following detailed description are by examples, and are intended to provide further explanation of the invention as claimed.
The invention can be more fully understood by reading the following detailed description of the embodiment, with reference made to the accompanying drawings as follows:
Reference will now be made in detail to the present embodiments of the invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers are used in the drawings and the description to refer to the same or like parts.
In embodiments, the integrated inductor apparatus may be multi-phase inductors.
Reference is now made to
The multi-phase inductors 10 are electrically connected to a common output terminal OUT of the switching mode power supply 1. As a result, the multi-phase inductors 10 are the output inductors corresponding to the common output terminal OUT of the switching mode power supply 1. The multi-phase inductors 10 include a plurality of inductors 100a-100c.
The transistors 12a-12c and the corresponding transistors 14a-14c form a plurality of power conversion circuits connected in parallel. The common output terminal OUT is the output of the power conversion circuits. In the present embodiment, as illustrated in
The load 16 is electrically connected to the multi-phase inductors 10 at the common output terminal OUT. In an embodiment, the switching mode power supply 1 further includes other load components, such as but not limited to the capacitor 18 illustrated in
It is appreciated that the disposition of the multi-phase inductors 10 in the switching mode power supply 1 is merely an example. In other embodiments, the multi-phase inductors 10 can be directly electrically connected to the common input terminal IN to become input inductors and are electrically connected to the common output terminal OUT through the transistors.
The multi-phase inductors 10 can be implemented by an integrated inductor apparatus 2 illustrated in
The number of the windings 20a-20c is corresponding to the number of the inductors 100a-100c in the multi-phase inductors 10 illustrated in
In the present embodiment, the integrated magnetic core 22 includes three magnetic core units 220a-220c. The magnetic core units 220a-220c include the corresponding windows 24a-24c. Each of the magnetic core units 220a-220c has a closed geometrical structure to form one of the windows 24a-24c.
As illustrated in
The magnetic core units 220a-220c includes at least two kinds of material having different permeability. In each magnetic core unit, the reluctance of shared part of magnetic core is smaller than that of the non-shared part. Taking the magnetic core units 220a and 220b as an example, the reluctance of the shared magnetic core part 26a is smaller than the reluctance of the non-shared magnetic core part of the magnetic core units 220a and 220b.
In an embodiment, the shared magnetic core part 26a is fabricated by using the material having the permeability higher than the permeability of the non-shared magnetic core part such that the reluctance of the shared magnetic core part 26a is smaller than the reluctance of the non-shared magnetic core part.
In another embodiment, at least part of non-shared magnetic core part in the magnetic core units 220a-220c, i.e., sections 222a-222c, includes a kind of material with lowest permeability among all kinds of material in the magnetic core units 220a-220c, to ensure the reluctance of the non-shared magnetic core part is larger than that of the shared part. For convenience, the kind of material with lowest permeability in non-shared part of magnetic core is called a first material in the application, and thus sections 222a-222c are first material sections. In an embodiment, the permeability of the first material of sections 222a-222c may be lower than or equal to 50. In an embodiment, sections 222a-222c are air gaps and the first material is air.
Reference is now made to
As illustrated in
The magnitude of each of the magnetic flux is calculated according to the reluctance. Taking a section of the integrated magnetic core 22′ illustrated in
As a result, the magnetic flux 300a in
Similarly, the winding 20b also generates three magnetic flux in the integrated magnetic core 22, wherein only the main magnetic flux 302 corresponding to the magnetic core unit 220b is exemplarily illustrated in
The two of the neighboring magnetic core units 220a and 220b generate direct current magnetic fluxes with opposite directions at the shared magnetic core part 26a, such as the magnetic flux 300a and 302 illustrated in
Such a design would cancel the direct current magnetic flux in the shared part of magnetic core 22 such that the core loss of the integrated inductor apparatus decreases. Further, due to magnetic core part 26a shared by the neighboring magnetic core units 220a and 220b, the whole size of the integrated magnetic core 22 can be shrunk. Relatively, in order to prevent the inductor from saturation, the material of the non-shared magnetic core part has a high reluctance relative to the shared magnetic core part 26a. Meantime, the low reluctance of the shared part magnetic core ensures the non-coupled integration of multiphase inductor.
Reference is now made to
In the present embodiment, the integrated magnetic core 40 includes three magnetic core units 400a-400c. The magnetic core units 400a-400c include the corresponding windows 42a-42c. The windings 20a-20c are disposed in the windows 42a-42c respectively. The closed geometrical structure of each of the magnetic core units 400a-400c is a triangle. The magnetic core units 400a and 400b have a shared magnetic core part 44a. The magnetic core units 400b and 400c have a shared magnetic core part 44b. As described in the previous embodiments, the shared magnetic core parts 44a and 44b can be fabricated by the material having a higher initial permeability as compared to the non-shared magnetic core part to have a lower reluctance. Of course in the present embodiment, two columns of the magnetic core unit 400b are the shared magnetic core parts 44a and 44b respectively.
Reference is now made to
In the present embodiment, the integrated magnetic core 50 includes three magnetic core units 500a-500c. The magnetic core units 500a-500c include the corresponding windows 52a-52c. The windings 20a-20c are disposed in the windows 52a-52c respectively. The closed geometrical structure of each of the magnetic core units 400a-400c is a pentagon. The magnetic core units 500a and 500b have a shared magnetic core part 54a. The magnetic core units 500b and 500c have a shared magnetic core part 54b. As described in the previous embodiments, the shared magnetic core parts 54a and 54b can be fabricated by the material having a higher initial permeability as compared to the non-shared magnetic core part to have a lower reluctance.
In other embodiments, the number and the shape of the closed geometrical structure of the magnetic core units of the integrated magnetic core can be adjusted according to practical applications and are not limited to the number and the shape described in the above embodiments.
Reference is now made to
In the present embodiment, the closed geometrical structure of the magnetic core unit 6 is a quadrangle that includes four edges 60a, 60b, 60c and 60d. In an embodiment, the edge 60c is shared by other magnetic core units (not illustrated). As a result, on the non-shared magnetic core parts such as the edges 60a, 60b and 60d, the first material sections can be disposed. The disposition method of the first material sections, such as the number and the position of the first material sections, can be adjusted based on different requirements.
Taking
In
The first material sections mentioned in the above embodiments are examples of discretely disposing the first material sections on the magnetic core units.
In
It is appreciated that various combinations of the positions and the numbers of the first material sections and the numbers of the air gap included in the first material sections mentioned above can be used according to different conditions and are not limited thereto. Surely, the air gap in the first material sections can also be stuffed by other material having a low permeability.
In the present embodiment, the integrated magnetic core 7 includes six magnetic core units 700a-700f and corresponding windows 72a-72f. The closed geometrical structure of each of the magnetic core units 700a-700f is a quadrangle. In the present embodiment, the axes of the windows of the illustrated integrated magnetic core 7 are parallel to each other.
Each of the magnetic core units 700a-700f includes at least one first high magnetic resistance material section. In
In the present embodiment, the integrated magnetic core 8 includes six magnetic core units 800a-800f and corresponding windows 82a-82f. The closed geometrical structure of each of the magnetic core units 800a-800f is a quadrangle. In the present embodiment, each of the magnetic core units 800a-800f has two or more than two neighboring magnetic core units connected thereto. Taking the magnetic core unit 800a as an example, the magnetic core unit 800a has two neighboring magnetic core units 800b and 800d connected thereto. The magnetic core unit 800b has three neighboring magnetic core units 800a, 800c and 800e connected thereto.
Each of the magnetic core units 800a-800c includes a plurality of first material sections disposed intensively at the center of the same side of the edges, such as the first material section 820a corresponding to the magnetic core unit 800a. Each of the magnetic core units 800d-800f includes a plurality of first material sections disposed intensively at the center of the same side of the edges, such as the first material section 820b corresponding to the magnetic core unit 800d.
As a result, the magnetic core units 800a-800f included in the integrated magnetic core 8 have more shared parts to shrink the size of the integrated magnetic core 8 more efficiently.
In the present embodiment, the integrated magnetic core 9 includes six magnetic core units 900a-900f and corresponding windows, such as the window 92 corresponding to the magnetic core unit 900a. The closed geometrical structure of each of the magnetic core units 900a-900f is a quadrangle. In the present embodiment, each of the magnetic core units 900a-900f has two neighboring magnetic core units connected thereto to form a cubic. Taking the magnetic core unit 900a as an example, the magnetic core unit 900a has two neighboring magnetic core units 900b and 900f connected thereto. The magnetic core unit 900c has two neighboring magnetic core units 900b and 900d connected thereto.
Each of the magnetic core units 900a-900f includes a plurality of first material sections disposed at the center of the same side of the edges, such as the first material section 920 corresponding to the magnetic core unit 900a.
As a result, the magnetic core units 900a-900f included in the integrated magnetic core 9 together form a cubic to shrink the size of the integrated magnetic core 9 more efficiently.
In the present embodiment, the integrated magnetic core 1000 includes six magnetic core units 1000a-1000f and corresponding windows, such as the window 1002 corresponding to the magnetic core unit 1000d. The closed geometrical structure of each of the magnetic core units 1000a-1000f is a quadrangle. In the present embodiment, the magnetic core units 1000a-1000c are on the same plane, and the magnetic core unit 1000b has the neighboring magnetic core units 1000a and 1000c connected thereto. The magnetic core units 1000d-1000f are all on another plane, and the magnetic core unit 1000e has the neighboring magnetic core units 1000b and 1000f connected thereto. The magnetic core units 1000e and 1000f are respectively connected to the magnetic core units 1000a and 1000c.
The magnetic core units 1000a-1000c and the magnetic core units 1000d-1000f are vertical to each other. As a result, the axes of the windows that the magnetic core units 1000a-1000c and the magnetic core units 1000d-1000f corresponding to are vertical to each other to form an irregular three-dimensional shape.
In the present embodiment, each of the magnetic core units 1000a-1000f includes a plurality of first material sections disposed at the center of each one of the edges, such as the first material section 1020 corresponding to the magnetic core unit 1000d illustrated in
As a result, the magnetic core units 1000a-1000f included in the integrated magnetic core 1000 can form an irregular three-dimensional shape according to the practical requirements.
In the present embodiment, the integrated magnetic core 1100 includes three magnetic core units 1100a-1100c and corresponding windows, such as the window 1102 corresponding to the magnetic core unit 1100a. The closed geometrical structure of each of the magnetic core units 1100a-1100c is a rectangle. In the present embodiment, a magnetic core part 1104a is partially shared by the edges of the magnetic core units 1100a and 1100b. A magnetic core part 1104b is partially shared by the edges of the magnetic core units 1100b and 1100c.
Further, various combination of the numbers and the positions of the first material sections included in the magnetic core units 1100a-1100c can be used. It is appreciated that though some of the edges of the magnetic core units 1100a-1100c include the shared magnetic core parts 1104a and 1104b, the first material sections can still be formed on the non-shared part of these edges.
As a result, the edges of the magnetic core units 1100a-1100c included in the integrated magnetic core 1100 can be formed with a partially shared manner according to the practical requirements.
In the present embodiment, the integrated magnetic core 1200 includes three magnetic core units 1200a-1200c and corresponding windows, such as the window 1202 corresponding to the magnetic core unit 1200a. The closed geometrical structure of each of the magnetic core units 1200a-1200c is a rectangle. In the present embodiment, a magnetic core part 1204a is partially shared by the edges of the magnetic core units 1200a and 1200b. A magnetic core part 1204b is partially shared by the edges of the magnetic core units 1200b and 1200c.
Further, various combination of the numbers and the positions of the first material sections included in the magnetic core units 1200a-1200c can be used. It is appreciated that though some of the edges of the magnetic core units 1200a-1200c includes the shared magnetic core parts 1204a and 1204b, the first material sections can still be formed on the non-shared part of these edges.
As a result, the edges of the magnetic core units 1200a-1200c included in the integrated magnetic core 1200 can be formed with a partially shared manner according to the practical requirements.
In the present embodiment, the integrated magnetic core 7″ is similar to the integrated magnetic core 7 illustrated in
However, in the present embodiment, taking the shared magnetic core part 704 of the magnetic core units 700a and 700b as an example, the shared magnetic core part 704 includes a section with a second low permeability material. Such a section with low permeability material in shared part is named second material section. As a result, in an embodiment, when the permeability of the first material of the non-shared magnetic core unit 700a section 720a is U1, the permeability of the other parts of the non-shared magnetic core unit 700a is U3, the permeability of the second material section 1300 of the shared part is U2, the permeability of the other part of the shared part is U4, U4 is larger than U2, and U3 is larger than U1. If the cross-sectional area and the length of the non-shared part of the magnetic core unit 700a are S1 and L1, and the cross-sectional area and the length of the shared magnetic core part 704 are S2 and L2, the reluctance Rm1 of the non-shared part would be (2*L1)/(U1*S1) under the condition that U3 is far larger than U1. The reluctance Rm2 of the shared magnetic core part 704 would be L2/(U2*S2) under the condition that U4 is far larger than U2. After the adjustment of the lengths L1 and L2 and the cross-sectional areas S1 and S2, the reluctance Rm2 of the shared magnetic core part 704 can be smaller than the reluctance Rm1 of the non-shared part.
In the embodiment illustrated in
In order to manufacture the integrated magnetic core 1400 in
In order to manufacture the integrated magnetic core 1500 in
In order to follow the principle of sharing the magnetic cores, the first section can be disposed at any place of the non-shared magnetic core part. Therefore, different shapes of the magnetic core can be formed when a multiple of magnetic cores are shared. In combination with
Besides, for the windings of the magnetic cores, the first material sections bring diffusion of the magnetic field that results in the increase of the loss of the inductor windings. The distance to the first material sections is closer, the loss of the inductor windings is larger. Supposed that between
The two shared magnetic cores in
In addition, it needs to point out that when three or more than three paths of shared magnetic cores are expanded along the x dimension (taking the three paths illustrated in
Surely, in other embodiments, the condition that the reluctance of the first material sections in one of the magnetic core units is larger than the reluctance of the first material sections in another one of the magnetic core units can be realized when the permeability of the material of the first material sections in one of the magnetic core units is smaller than the permeability of the material of the first material sections in another one of the magnetic core units.
The advantage of the present invention is to shrink the size of the multiple of integrated inductors by using the design of the integrated magnetic core.
Although the present invention has been described in considerable detail with reference to certain embodiments thereof, other embodiments are possible. Therefore, the spirit and scope of the appended claims should not be limited to the description of the embodiments contained herein.
It will be apparent to those skilled in the art that various modifications and variations can be made to the structure of the present invention without departing from the scope or spirit of the invention. In view of the foregoing, it is intended that the present invention cover modifications and variations of this invention provided they fall within the scope of the following claims.
Number | Date | Country | Kind |
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2015 1 0169368 | Apr 2015 | CN | national |
2015 1 0446385 | Jul 2015 | CN | national |
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