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A magnetic assembly may include a bobbin having one or more windings wound around a central passageway through the bobbin. An inner core is positioned in the central passageway with first and second facing surfaces exposed at or near the two ends of the central passageway. The inner core has an inner core length between the two facing surfaces. An outer core has continuous outer walls that define an inner cavity. The outer core is positioned on the bobbin with the outer walls surrounding the bobbin and with first and second inner surfaces of the inner cavity juxtaposed with the first and second facing surfaces, respectively of the inner core. The outer core has a cavity length between the two inner surfaces. The inner core length and the cavity length are selected such that the cavity length is greater than the inner core length. A first gap is formed between the first facing surface of the inner core and the first inner surface of the inner cavity. A second gap is formed between the second facing surface of the inner core and the second inner surface of the inner cavity. The two gaps have a total gap width equal to the difference between the cavity length and the inner core length. To control the magnetic characteristics of magnetic assembly, it is desirable to control the widths of the two gaps.
The inner core and the outer core may be manufactured from a ceramic ferrite material based on iron-oxide, such as, for example, Mn—Zn ferrite, Ni—ZN ferrite or Mg—Zn ferrite. The ferrite material is formed into a desired size and shape by injection molding. One part of the forming process includes a sintering step at a high temperature (e.g., 1,280-1,380 C for a few hours). During the sintering process, the ferrite material may shrink up to 15 percent in any linear dimension, which may result in a loss of up to approximately 50 percent of the original volume of the original molded size and shape. Accordingly, the inner core and outer core are molded initially with sizes and shapes that are greater than a desired nominal shape to allow for the maximum expected shrinkage during the sintering process. If less than the maximum expected shrinkage of the inner core occurs, the inner core can be ground to the required inner core length. If less than the maximum shrinkage of the outer core occurs, the cavity length will be too short, and one or both of the inner surfaces of the cavity must be ground to provide the desired cavity length. The inner surfaces of the cavity are large compared to the size of each end of the inner core, and excessive grinding may be required to produce the desired cavity length.
An aspect of the present invention is a magnetic assembly including a bobbin having a first end flange and a second end flange. The bobbin has a passageway between the first end flange and the second end flange. The passageway has a passageway length from the first end flange to the second end flange. The magnetic assembly further includes a magnetic core assembly having an inner core and an outer core. The inner core is positioned within the passageway of the bobbin. The inner core has an inner core length from a first end surface to a second end surface. The outer core includes a sintered ferrite material. The outer core has outer surfaces defining an outer wall. The outer wall surrounds a cavity having a first inner surface, a second inner surface, a third inner surface and a fourth inner surface. The first inner surface and the second inner surface are parallel to each other and are spaced apart by an overall cavity length. The first inner surface has at least a first protrusion that extends into the cavity toward the second inner surface. The first protrusion has a first protrusion face. The first protrusion face is spaced apart from a portion of the second inner surface by a modifiable cavity length. The outer core is positioned around the bobbin with the first protrusion face proximate to the first end surface of the inner core and with the portion of a second inner surface of the cavity proximate to the second end surface of the inner core. The first protrusion has a first protrusion length modifiable to adjust the modifiable cavity length to be longer than the inner core length by a total gap distance, wherein the total gap distance is a sum of a first gap distance and a second gap distance. The first gap distance is a distance between the first protrusion face and the first inner core face. The second gap is a distance between the portion of the second face of the inner wall and the second inner core face. In certain embodiments, the first gap distance is substantially equal to the second gap distance.
In certain embodiments of the magnetic assembly, the portion of the second inner surface of the cavity includes a second protrusion extending into the cavity toward the first protrusion. The second protrusion has a second protrusion face, which is spaced apart from the first protrusion face by the modifiable cavity length. The second protrusion has a second protrusion length modifiable to further adjust the modifiable cavity length.
In certain embodiments, the outer core is sintered from a molded outer core. Before the outer core is sintered, the first protrusion extends from the first inner surface by a pre-sintered grinding post length, which is selected to be at least as long as the product of an expected sintering shrinkage factor F times a sum of the inner core length and the total gap distance. The expected sintering shrinkage factor F is determined by a maximum expected sintering shrinkage percentage S, wherein F=S/(100−S).
Another aspect of the present invention is a method for assembling a magnetic assembly, which includes providing a bobbin having a first end flange and a second end flange. The bobbin has a passageway between the first end flange and the second end flange. The passageway has a passageway length from the first end flange to the second end flange. The method further includes inserting an inner core into the passageway of the bobbin. The inner core has a length such that a first end surface of the inner core is proximate to the first end flange of the bobbin and such that a second end face of the inner core is proximate to the second end flange of the bobbin. The inner core has an inner core length from the first end face to the second end face. The method further includes forming an outer core using a sintering process. The outer core has an outer wall surrounding an inner cavity. The inner cavity has at least a first inner surface and a second inner surface. The second inner surface is parallel to the first inner surface. At least the first inner surface has a first protrusion extending into the inner cavity toward the second inner surface. The first protrusion has a first protrusion face. The first protrusion face is initially spaced apart from a portion of the second inner surface by an initial modifiable inner cavity distance. The initial modifiable inner cavity distance is not controllable during the sintering process. The method further includes removing a portion of the first protrusion at the first protrusion face to increase the initial modifiable inner cavity distance to a modified inner cavity distance selected to be greater than the inner core length by a total gap distance. The method further includes positioning the outer core onto the bobbin with the first protrusion face proximate to the first end face of the inner core and with the portion of the second inner surface proximate to the second end face of the inner core.
In accordance with one aspect of the method, the first protrusion face is spaced apart from the first end face of the inner core by a first gap distance and the portion of the second inner surface is spaced apart from the second end face of the inner core by a second gap distance, wherein the second gap distance and the first gap distance being substantially equal.
In certain embodiments of the method, the portion of the second inner surface of the cavity further includes a second protrusion extending into the cavity toward the first protrusion face. The second protrusion has a second protrusion face. The method further includes removing a portion of the second protrusion at the second protrusion face to increase the modifiable inner cavity distance. In accordance with this embodiment of the method, the first protrusion face is spaced apart from the first end face of the inner core by a first gap distance and the second protrusion face is spaced apart from the second end face of the inner core by a second gap distance, wherein the second gap distance and the first gap distance are substantially equal.
In certain embodiments of the method, the outer core is formed by a sintering process. The first protrusion extends from the first inner surface by a pre-sintering grinding post length, which is selected to be at least as long as the product of an expected sintering shrinkage factor F times a sum of the inner core length and the total gap distance. The expected sintering shrinkage factor F is determined by a maximum expected sintering shrinkage percentage S during the sintering process, wherein F=S/(100−S).
Another aspect of the present invention is a method of producing a sintered outer core for a magnetic assembly. The method includes molding a ferrite material into a molded outer core having an outer wall around an inner cavity. The inner cavity has a first inner surface. A second inner surface is parallel to the first inner surface and is spaced apart from the first inner surface by an overall cavity length. A third inner surface is perpendicular to the first inner surface, and a fourth inner surface is parallel to the third inner surface. At least the first inner surface has a first protrusion extending into the cavity toward the second inner surface. The protrusion has a first protrusion face. The first protrusion face is spaced apart from a portion of the second inner surface by an initial modifiable cavity length. The protrusion has a length selected such that the initial modifiable length is no greater than a desired final modifiable cavity length and such that the protrusion length is greater than a selected percentage of the desired final modifiable cavity length. The method further includes sintering the molded outer core to form a sintered outer core. The sintered outer core has a sintered modifiable cavity length between the first protrusion face and the portion of the second inner surface. The method further includes selectively grinding the first protrusion face to shorten the first protrusion by an amount to increase the sintered modifiable cavity length to the final modifiable cavity length.
In certain embodiments of the method, the first protrusion extends from the first inner surface by a pre-sintered grinding post length, which is selected to be at least as long as the product of an expected sintering shrinkage factor F times a sum of the inner core length and the total gap distance. The expected sintering shrinkage factor F is determined by a maximum expected sintering shrinkage percentage S during sintering, wherein F=S/(100−S).
In the following description, various dimensional and orientation words, such as height, width, length, longitudinal, horizontal, vertical, up, down, left, right, tall, low profile, and the like, may be used with respect to the illustrated drawings. Such words are used for ease of description with respect to the particular drawings and are not intended to limit the described embodiments to the orientations shown. It should be understood that the illustrated embodiments can be oriented at various angles and that the dimensional and orientation words should be considered relative to an implied base plane that would rotate with the embodiment to a revised selected orientation.
The magnetic assembly 100 of
The bobbin 110 further includes a winding 140, wherein the turns of the winding 140 are circular. Only the protective outer covering of the winding 140 is shown in
As illustrated in in
The inner core 150 has a longitudinal length between a first end surface 160 and a second end surface 162 that is less than or equal to the longitudinal length of the passageway 130. When the inner core 150 is centered within the passageway 130, the first end surface 160 is proximate to the first end flange 112, and the second end surface 162 is proximate to the second end flange 114. In embodiments where the longitudinal length of the inner core 150 is the same as the longitudinal length of the passageway 130, the first and second end surfaces of the inner core 150 may be flush with the outer surface 122 of the first end flange 112 and the outer surface 126 of the second end flange 114. In other embodiments where the longitudinal length of the inner core 150 is less than the longitudinal length of the passageway, the first and second end surfaces may be recessed by a small amount from the respective outer surfaces of the flanges.
In the illustrated embodiment, the inner core 150 is cylindrical and has a circular profile defined by a cylindrical outer surface 170. The profile of the inner core 150 is selected to conform to the profile of the passageway 130. The diameter of the inner core 150 is selected to be slightly smaller than the diameter of the passageway 130 so that the inner core 150 fits barely within the passageway 130 when inserted from the outer surface of the second end flange 114.
In the illustrated embodiment, the outer core 152 is a rectangular parallelepiped with a hollow inner cavity 180 sized to receive the bobbin 110. The outer core 152 has a continuous wall of a ferromagnetic material (e.g., a sintered ferrite core of iron, manganese and zinc) that surrounds the hollow inner cavity. The hollow inner cavity of the outer core 152 is defined by a first inner surface 182 and a parallel second inner surface 184. The first and second inner surfaces are perpendicular to a third inner surface 186 and to a fourth inner surface 188. The third and fourth inner surfaces are spaced apart by a distance selected to be substantially equal to a width of each of the first end flange 112 and the second end flange 114 so that the outer core 152 is positionable on the bobbin 110 with the third and fourth inner surfaces abutted against the end flanges as shown in
The first inner surface 180 and the second inner surface 182 of the outer core 152 are spaced apart by a distance greater than the longitudinal length of the passageway 130. When the outer core 152 is positioned on the bobbin 110 as shown in
In the illustrated embodiment, the cross-sectional profile of rectangular outer core 152 has a height between the lower surface 190 and the upper surface 192. The inner core 150 has a diameter that is approximately equal to the height of the outer core 152. As illustrated, the height of the outer core 152 is less than the height of the first end flange 112 and the second end flange 114. Thus, the tops of the end flanges extend above the upper surface of the outer core 152 such that the overall height of the magnetic assembly 100 is greater than the height of the rectangular outer core.
As further illustrated in
As shown in the elevational front view of
The inner core 150 is positioned in the passageway 130 by inserting the first end surface 160 of the inner core 150 into the passageway 130 at the outer surface 126 of the second end flange 114. Pressure is applied to the second end surface 162 of the inner core 150 to force the first end surface 160 of the inner core 150 and the cylindrical body 170 into the passageway 130. As the first end surface 160 of the inner core 150 is pressed into the passageway 130, the inner core 150 initially rides upon the shorter portions of the passageway ribs 200 and then begins to crush the nylon ribs as the first end surface 160 of the inner core 150 is pressed further toward the outer surface 122 of the first end flange 112 of the bobbin 110 and encounters the portions of the passageway ribs 200 of increasingly greater height. In certain embodiments, the inner core 150 is positioned such that the end surfaces of the inner core 150 are positioned by approximately the same distance from the respective outer surfaces of the end flanges (e.g., either flush with the respective outer surfaces or recessed by approximately the same distance from the respective outer surfaces). After the inner core 150 is positioned in the passageway 130 and the pressure is removed from the second end, the resilience of the crushable nylon presses against the top and bottom surfaces of the inner core to securely retain the inner core in a fixed longitudinal position within the passageway.
As further illustrated in
Each outer positioning rib 210 can taper continuously from the first (base) end 212 of the rib to the second (terminal) end 214 of the rib. In the illustrated embodiment of
The four outer positioning ribs 210 position and secure the rectangular outer core 152 with respect to the bobbin 110 when the outer core is pushed down onto the ribs until the lower surface 190 of the outer core abuts the upper surfaces of the first base platform 142 and the second base platform 144. Accordingly, the gaps 194, 196 are substantially equal as shown in
In the illustrated embodiment of
The molding and sintering processes to form the inner core 150 and the outer core 152 of
In
In
The hollow inner cavity 350 of the outer core body 310 is defined by a first inner surface 370, a parallel second inner surface 372, a third inner surface 374 and a fourth inner surface 376. The first and second inner surfaces are perpendicular to the third fourth inner surfaces.
The wall 352 of the outer core body 310 includes: a front wall portion 380 between the first outer surface 360 and the first inner surface 370; a rear wall portion 382 between the second outer surface 362 and the second inner surface 372; a right side wall portion 384 between the third outer surface 364 and the third inner surface 374; and a left side wall portion 386 between the third outer surface 364 and the third inner surface 374. In the illustrated embodiment, each wall has a common wall thickness T; however, in other embodiments, the thicknesses may be different. For example, the respective thicknesses of the front and rear wall portions may differ from the thicknesses of the sidewall portions.
In the illustrated embodiment, the wall 352 has a uniform height H between a lower surface 390 and an upper surface 392.
The first inner surface 370 and the second inner surface 372 of the cavity 350 are spaced apart by a cavity length L2. The third inner surface 374 and the fourth inner surface 376 are spaced apart by a cavity width W2. The cavity length L2 is substantially equal to the outer length L1 minus a sum of the thicknesses of the two end walls (e.g., L2=L1−2T in the embodiment where the two end wall thicknesses are equal). The cavity width W2 is substantially equal to the outer width W1 minus a sum of the thicknesses of the two side walls (e.g., W2=W1−2T in the embodiment where the two side wall thicknesses are equal).
Assuming the green inner core body 300 and the green outer core body 310 could be manufactured repeatedly to precise dimensions, the desired gaps between the first and second end surfaces 340, 342 of the green inner core body and the first and second inner surfaces 370, 372 of the green outer core body can be established by dimensioning the cavity length L2 to be substantially equal to the sum of the inner core body length L and the total gap distance G (e.g., L2=L+G). However, the green inner core body 300 and the green outer core body 310 shown in
During the respective sintering processes, the green inner core body 300 of
In the sintered inner core body 300′ and the sintered outer core body 310′ of
The densifications of the two sintered bodies 300′, 310′ result in the shrinkage of the two sintered bodies such that the respective lengths, widths, heights and thicknesses are reduced. The reduced dimensions are identified in
Because of the expected shrinkage during the sintering process, the green inner core body 300 and the green outer core body 310 are produced with initial sizes and shapes that are greater than a desired nominal shape by a sufficient amount to allow for the shrinkage. For example, if the maximum expected shrinkage is known to be no more than 15 percent such that the sintered dimensions are at least 85 percent of the original dimensions, selecting the initial dimensions of the green (pre-sintered) bodies to be about 18 percent greater than the desired nominal dimensions results in the dimensions of the sintered bodies being at least as large as the desired nominal dimensions. As indicated above, the inner core body and the outer core body may incur differing percentages of shrinkage during the respective sintering processes. The inner core body may also be formed using different materials, formed using a different process, or formed using both different materials and a different process.
If less than the maximum expected shrinkage of the green (unsintered) inner core body 300 occurs during the sintering process such that the length L′ of the sintered inner core body 300′ is too large, one or both of the first end surface 340′ or the second end surface 342′ of the sintered inner core body can be ground to the desired inner core length. For the purposes of the following discussion, the desired length of the inner core body is assumed to be the sintered length L′, and the dimensions of the outer core body 310 are adjusted to provide the desired gap distance G.
If less than the maximum shrinkage of the green (unsintered) outer core body 310 occurs during the sintering process, the overall cavity length L2′ of the sintered outer core body 310′ will be too short, which may require grinding of the first inner surface 370′, grinding of the second inner surface 372′, or grinding of both inner surfaces of the sintered cavity 350′ to provide the desired cavity length L2′ of L′+G. To grind at least one of the inner surfaces so that the resulting cavity length is equal to the desired cavity length, a substantial portion of the respective inner surface must be ground away to avoid fringing effects between the end surface of the inner core and the unground portions of the inner surface of the outer core. Such additional grinding is time consuming and may result in an uneven inner surface.
As illustrated in
When the pre-sintered outer core body 410 of
The original (pre-sintered) total grinding post depth PD of the grinding post 420 is selected such that the sintered modified (pre-grinding) cavity length L3′ is adjustable by grinding the post-sintered grinding post 420′ to reduce the sintered total grinding post depth PD′ to a shortened total grinding post depth PD″ shown in
The pre-sintered total grinding post depth PD is selected in accordance with the following criteria. For the purpose of the following discussion, the length L′ of the sintered inner core 300′ is again assumed to be the desired nominal length for the inner core. The sintered inner core is either formed or adjusted (e.g., by grinding) so that the length L′ is the same length for each combination of sintered inner core 300′ and sintered outer core 410′.
The maximum pre-sintering modified cavity length L3 is first determined by assuming the unlikely, but still possible, event that the pre-sintered outer core body 410 incurs no shrinkage during the sintering process. Since the modified cavity length L3′ cannot be shortened after the sintering process, the initial, pre-sintering, modified cavity length L3 can be no longer than the desired final modified cavity length L3″, which is equal to L′+G, as discussed above. This relationship (L3=L′+G) is shown for the pre-sintering (green) outer core body 410 in the upper stage of the process of
As discussed above, the sintering process may result in up to 15 percent shrinkage in all dimensions, which is illustrated by the sintered outer core body 410′ in the middle stage of the process of
To increase the sintered modified cavity length L3′ to a sufficient length, a portion of the sintered grinding post 420′ is removed by grinding the sintered grinding post 420′ from the sintered grinding post depth PD′ to the post-grinding grinding post depth PD″ shown in the lower stage of the process of
The foregoing process for selecting the pre-sintering grinding post depth PD of the molded outer core body 310 can be represented by an equation:
PD=(L′+G)×(S/(100−S))=(L′+G)×F,
where F is a depth selection factor for PD, which is equal to S/(100−S) where S is the maximum percentage of shrinkage.
In the illustrated example of a maximum shrinkage S of 15 percent, F is approximately equal to 0.176. Accordingly, PD is calculated as:
PD=(L′+G)×0.176.
Thus, an initial depth PD of the grinding post 420 of about 0.18×(L′+G) would be adequate to assure that the post-sintering grinding post depth PD′ is sufficient to allow the required post-sintering, post-grinding modified cavity length L3″ to be produced.
In another example where the maximum expected shrinkage S is 5 percent, S=0.05, and PD is calculated as:
PD=(L′+G)×(5/(100−5))=(L′+G)×0.053.
For this example, an initial depth PD of the grinding post 420 of about 0.06×(L′+G) is adequate to assure that the post-sintering grinding post depth PD′ is sufficient to allow the required post-sintering, post-grinding modified cavity length L3″ to be produced.
As discussed above, the original modified cavity length L3 is chosen to be substantially equal to the sum of the length L′ of the sintered inner core body 300′ and the gap distance G (e.g., L3=L′+G); and the original depth PD of the grinding post 420 is selected to be at least as great as the maximum expected shrinkage of the modified cavity length. Accordingly, if no shrinkage of the green outer core 410 occurs during the sintering process, the sintered modified cavity length L3′ is equal to L′+G, and no grinding of the sintered grinding post 420′ is required. If shrinkage up to the maximum expected shrinkage occurs, the depth PD′ of the sintered grinding post can be ground to reduce the depth PD′ to the depth PD″ as needed to adjust the sintered modified cavity length L3′ until the ground modified cavity length L3″ is equal to L′+G.
It should be appreciated that grinding the relatively small surface of the sintered grinding post 420′ is much simpler than grinding the larger inner surface 372′. For example, the surface of the sintered grinding post may be ground with a smaller grinding tool and may be ground with fewer passes of the grinding tool.
As illustrated for a magnetic assembly 450 in
The first grinding post 520 in
Although there have been described particular embodiments of the present invention of a new and useful “Magnetic Core Structure and Manufacturing Method Using a Grinding Post,” it is not intended that such references be construed as limitations upon the scope of this invention except as set forth in the following claims.
This application is a divisional application of U.S. patent application Ser. No. 14/843,621 filed Sep. 2, 2015, entitled “Magnetic Core Structure and Manufacturing Method Using a Grinding Post,” which claims the benefit under 35 U.S.C. 119(e) of U.S. Provisional Patent Application No. 62/047,800 filed Sep. 9, 2014, entitled “Magnetic Core Structure and Manufacturing Method Using a Grinding Post.” Both applications are incorporated by reference in their entireties herein.
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Number | Date | Country | |
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62047800 | Sep 2014 | US |
Number | Date | Country | |
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Parent | 14843621 | Sep 2015 | US |
Child | 15898518 | US |