JP5954071B2 - Inductance core manufacturing method and inductance core - Google Patents

Description

  The present invention relates to an inductance core manufacturing method using centerless machining and an inductance core.

  As a method for manufacturing an inductance core, a grinding method called centerless processing is known. In the conventional centerless processing, a part corresponding to the core part of the core is formed by grinding while rotating the workpiece along the outer peripheral surface of the part corresponding to the collar part of the core (see Patent Document 1, etc.). However, in such a method of manufacturing an inductance core, the shape of the core part of the core is affected by the outer shape of the collar part, which serves as the rotation reference surface for centerless processing. It is difficult to do. For example, when the outer peripheral shape of the collar portion is a polygon, it is difficult to make the outer peripheral shape of the core portion circular. Moreover, when the outer peripheral shape of the collar part used as the rotation reference surface of centerless processing is a polygon, there also exists a problem that it is difficult to grind a core part accurately.

  In addition, as a method of manufacturing an inductance core having a hexagonal flange portion and a cylindrical core portion by centerless processing, for example, a convex portion is provided on both side surfaces of the flange portion, and this convex portion is a rotation reference in the centerless processing. A method of making a surface has been proposed (see Patent Document 2).

JP 2010-135758 A Japanese Utility Model Publication No. 5-25707

  However, in the method in which convex portions are provided on both side surfaces of the collar portion, and the convex portions are used as rotation reference surfaces in centerless processing, the convex portion is smaller than the collar portion, so that the processing accuracy in centerless processing is insufficient. Have

  The present invention has been made in view of such a situation, and a method for manufacturing an inductance core that can form the core portion with high accuracy, and the shape of the flange portion and the core portion can be made different from each other. The present invention relates to an inductance core manufactured by the method.

In order to achieve the above object, an inductance core manufacturing method according to the present invention includes:
A columnar base portion and a reference outer peripheral surface formed integrally with the base portion and connected to one end portion of the base portion, at least a part of which is located on the outer diameter side from the side peripheral surface of the base portion A step of preparing a workpiece having a rotation reference portion comprising:
Grinding a part of the base portion while rotating the workpiece along the reference outer peripheral surface of the rotation reference portion.

  A workpiece used in the method for manufacturing an inductance core according to the present invention has a rotation reference portion including a reference outer peripheral surface serving as a rotation reference surface in centerless processing, in addition to a base portion serving as a flange portion and a core portion of the inductance core. Therefore, according to such a manufacturing method, the shape of the reference outer peripheral surface can be freely determined independently of the shape of the base portion, and an inductance core having different shapes of the flange portion and the core portion is preferably manufactured. Is possible. Further, at least a part of the reference outer peripheral surface is located on the outer diameter side from the side peripheral surface of the base portion, and since the diameter of the reference outer peripheral surface is large, the processing accuracy in centerless processing is high, and the manufacturing method according to the present invention Accordingly, the core portion can be formed with high accuracy.

  Further, for example, the method for manufacturing an inductance core according to the present invention may further include a step of removing the rotation reference portion from the workpiece after the step of grinding a part of the base portion.

  By removing the rotation reference portion, it is possible to manufacture an inductance core that is small but has high processing accuracy.

  Further, for example, the shape of the side circumferential surface of the base body in the circumferential direction may be a polygon.

  The manufacturing method of the inductance core according to the present invention has a processing accuracy in centerless processing even when a workpiece having a polygonal peripheral side surface is used so that the outer peripheral shape of the flange portion of the inductance core is a polygon. It is high and the dimensional variation of the inductance core can be reduced.

  Further, the shape of the reference outer peripheral surface in the circumferential direction may be a circle or an ellipse.

  By setting the shape of the reference outer peripheral surface of the workpiece in the circumferential direction to be a circle or an ellipse, the rotation of the workpiece in the centerless machining is stabilized, and higher-precision machining can be realized. In addition, if the circumferential shape of the reference outer peripheral surface of the workpiece is a circle or an ellipse, the outer periphery shape of the core portion of the inductance core is also a circle or an ellipse. The coil can be wound in close contact with the outer peripheral surface, which contributes to improving the performance of the inductor.

  Further, for example, the other end portion of the base portion may be an end portion of the workpiece.

  A workpiece having a rotation reference portion only at one end of the workpiece can be manufactured by simple compression molding because the shape is simple, and the manufacturing method using such a workpiece is excellent in productivity. Yes.

The inductance core according to the present invention includes a columnar core portion and a pair of flange portions each having a polygonal outer peripheral shape connected to both ends of the core portion,
Grinding marks generated when the rotation reference portion provided with the reference outer peripheral surface, which is the rotation surface in the centerless processing, is formed on the end surface of the one flange portion opposite to the core portion of the pair of flange portions. It is characterized by being.

  The inductance core in which the grinding mark formed when the rotation reference portion in the centerless processing is removed is formed on the entire end face of one flange portion, and the rotation reference having a size larger than the flange portion is separate from the base portion. It is manufactured using a workpiece having a portion, and the rotation reference portion is removed after the centerless processing. Therefore, such an inductance core has a high processing accuracy and little dimensional variation despite the fact that the shape of the collar portion is a polygon and is manufactured using centerless processing.

FIG. 1 is a schematic perspective view showing a workpiece used in a manufacturing method according to an embodiment of the present invention, a semi-finished workpiece manufactured from the workpiece, and an inductance core. FIG. 2 is a conceptual diagram illustrating each step of the manufacturing method according to one embodiment of the present invention. FIG. 3 is a front view and a side view of the semi-finished workpiece and the inductance core manufactured in the process shown in FIG. FIG. 4 is a conceptual diagram showing the relationship among the workpiece, the adjusting wheel, and the grindstone in the centerless machining. FIG. 5 is a front view and a side view of an inductance core manufactured by the manufacturing method according to the second embodiment of the present invention. FIG. 6 is a schematic perspective view of a workpiece used in the manufacturing method according to the third embodiment of the present invention.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 2 shows three processes B to D in the method for manufacturing an inductance core according to the present embodiment. The manufacturing method according to the present embodiment is performed using, for example, a centerless processing machine having an adjustment wheel 54 as shown in FIG. In the centerless processing machine, the workpiece 10 supplied on the outer peripheral surface of the adjustment wheel 54 from a supply unit (not shown) is conveyed along the outer peripheral surface of the adjustment wheel 54 while receiving the rotational force from the adjustment wheel 54 and rotating. The Meanwhile, the workpiece 10 is subjected to processing such as grinding by a grindstone 50 or the like disposed adjacent to the adjusting wheel 54.

  FIG. 2 shows the manufacturing process using the centerless processing machine observed through a cross section passing through the center of the workpiece 10, the semi-finished workpiece 28 manufactured from the workpiece 10, and the inductance core 30. The processing state and conveyance state of the workpiece 10 and the like are shown in the order of steps from the left side (step B) to the right side (step D) in FIG.

  In step A (not shown) performed before step B in FIG. 2, the prepared workpiece 10 is placed in a storage portion of a carrier 58 (see FIG. 2A) disposed on the outer peripheral surface of the adjustment wheel 54. Supplied. The carrier 58 conveys the supplied workpiece 10 along the outer peripheral surface of the adjustment wheel 54. FIG. 1A is a schematic perspective view showing the shape of the workpiece 10 supplied to the centerless processing machine. The workpiece 10 includes a columnar base portion 12 and a rotation reference portion 20 connected to one end portion 14 of the base portion 12.

  The base portion 12 and the rotation reference portion 20 are integrally formed by press molding or the like. The base portion 12 is a portion that becomes an inductance core 30 (see FIG. 1C) after manufacture, and the shape of the side circumferential surface 18 in the base portion 12 in the circumferential direction is a flange portion 36 in the manufactured inductance core 30. 42 is the same as the outer peripheral shape. The outer peripheral shape of the base portion 12 is not limited to the hexagon shown in FIG. 1, and may be determined according to the shape of the flange portion of the inductance core 30 to be manufactured. For example, a circle, an ellipse, an egg shape, a quadrangular shape, and the like It may be a polygon.

  The outer peripheral surface of the rotation reference portion 20 is a reference outer peripheral surface 22 that comes into contact with the outer peripheral surface of the adjustment wheel 54 in the centerless processing machine. The reference outer peripheral surface 22 contacts the outer peripheral surface of the adjustment wheel 54 in the centerless processing machine, and the workpiece 10 rotates along the reference outer peripheral surface 22 on the outer peripheral surface of the adjustment wheel 54. In the workpiece 10, at least a part of the reference outer peripheral surface 22, preferably the whole thereof, is located on the outer diameter side of the side peripheral surface 18 of the base portion 12, and the rotation reference portion 20 is on the outer diameter side of the base portion 12. Protruding. The circumferential shape of the reference outer circumferential surface 22 may be determined according to the outer circumferential shape of the core portion 32 of the inductance core 30 (see FIG. 1C), and may be a circle, an ellipse, an egg shape, a polygon, or the like. be able to.

  The workpiece 10 is made of a metal such as iron or a magnetic material such as ferrite. Moreover, the manufacturing method of the workpiece | work 10 is although it does not specifically limit, For example, manufacturing by press-molding ferrite powder is preferable from surfaces, such as productivity. Particularly, by providing the other end portion 16 of the base portion 12 as the end portion of the workpiece 10 and providing the rotation reference portion 20 only at the one end portion 14 of the base portion 12, such a workpiece 10 can be obtained by a simple mold. It is possible to manufacture by press molding using, and is excellent in productivity. In addition, a groove or the like for installing an end portion of the winding or the like can be easily formed in the other end portion 16 of the base portion 12, and the degree of freedom in design is high.

  In step A and step B (see FIG. 2A), the workpiece 10 is conveyed along the outer peripheral surface of the adjustment wheel 54 with both ends sandwiched between the stopper 52 and the stopper 56. In step A, the reference outer peripheral surface 22 of the workpiece 10 is in contact with the outer peripheral surface of the adjustment wheel 54 as in step B described later, and the workpiece 10 receives the rotational force from the adjustment wheel 54, thereby It rotates (rotates) along the surface 22.

  In step B shown in FIG. 2A, a part of the base 12 in the workpiece 10 shown in step A is ground by centerless processing, and the semi-finished workpiece 28 (see FIGS. 1B and 2B) is obtained. obtain. In step B, the reference outer peripheral surface 22 of the rotation reference unit 20 is in contact with the outer peripheral surface of the adjustment wheel 54, and the workpiece 10 is rotated by receiving the rotational force from the adjustment wheel 54.

  In step B, in a state where the workpiece 10 is rotating along the reference outer peripheral surface 22, the grindstone 50 comes into contact with the side peripheral surface 18 of the base portion 12 of the workpiece 10 and a part of the base portion 12 is ground. Thus, the core portion 32 is formed. FIGS. 1B, 3 </ b> A, and 3 </ b> B are a perspective view, a plan view, and a side view showing the semi-finished workpiece 28 created by the process B. FIGS. The semi-finished work 28 has a columnar core portion 32, a pair of flange portions 36a, 42 connected to both ends thereof, and a rotation reference portion 20 connected to one flange portion 36a. The core portion 32 and the flange portions 36 a and 42 correspond to the portion that was the base portion 12 in the workpiece 10.

  The outer peripheral shape of the core part 32 in the semi-finished work 28 is substantially similar to the shape of the reference outer peripheral surface 22 in the circumferential direction. For example, as shown in FIG. 4, when the circumferential shape of the reference outer circumferential surface 22 is an ellipse, the outer circumferential shape of the core portion 32 is an ellipse that is substantially similar to the circumferential shape of the reference outer circumferential surface 22. The arrangement is a state in which the circumferential shape of the reference outer circumferential surface 22 is rotated by approximately 90 degrees.

  In the process C shown in FIG. 2B, the semi-finished work 28 created in the process B is conveyed to a portion without the stopper 56, and the arrangement of the semi-finished work 28 and the adjusting wheel 54 is changed. The contact between the reference outer peripheral surface 22 and the adjustment wheel 54 is released.

  In step C, the reference outer peripheral surface 22 of the semi-finished workpiece 28 moves to a position shifted from the outer peripheral surface of the adjustment wheel 54, and the adjustment vehicle cover 60 is interposed between the base portion 12 a of the semi-finished workpiece 28 and the adjustment wheel 54. Is inserted. As a result, the contact between the reference outer peripheral surface 22 and the adjustment wheel 54 is released, and the rotation of the semi-finished workpiece 28 is stopped.

  In step D shown in FIG. 2C, the rotation reference portion 20 is removed from the semi-finished work 28 whose rotation has stopped, and the inductance core 30 is obtained.

  In the process D, the grindstone 62 is inserted between the rotation reference portion 20 and the base portion 12a in the semi-finished workpiece 28, and the rotation reference portion 20 is separated from the base portion 12a. Thereby, the inductance core 30 shown in FIG. 1C and FIGS. 3C and 3D is obtained.

  As shown in FIGS. 1C, 3C, and 3D, the inductance core 30 has a columnar core 32 and a pair of flanges connected to both ends of the core 32, respectively. It has (the 1st collar part 36 and the 2nd collar part 42). The core portion 32 is formed by grinding performed in the process B shown in FIG. 2A, and the outer peripheral shape of the core portion 32 is the shape in the circumferential direction of the reference outer peripheral surface 22 of the workpiece 10 (FIG. 3). (See (a)).

  The first flange portion 36 and the second flange portion 42 correspond to regions of the base body portion 12 of the workpiece 10 that have not been ground in the process B and the process D, and the first flange portion 36 and the second flange portion 42. The outer peripheral shape is the same polygonal shape as the outer peripheral shape of the base portion 12. Further, as shown in FIGS. 2C and 3D, the first flange end surface 40 which is the end surface of the first flange 36 opposite to the core portion 32 is the workpiece 10 and the semi-finished workpiece 28. It is an end surface of the side to which the rotation reference part 20 was connected in the state. Therefore, grinding marks generated when the rotation reference portion 20 including the reference outer peripheral surface 22 which is a rotation surface in the centerless processing is removed are formed on the first flange end surface 40. In addition, since the second flange end surface 46 that is the end surface of the second flange 42 is a surface formed when the workpiece 10 is formed, the first flange end surface 40 has a surface roughness that is greater than that of the second flange end surface 46. Is rough.

  As described above, the workpiece used in the method of manufacturing the inductance core 30 according to the present embodiment is a centerless-processed rotation reference plane, separately from the flange portions 36 and 42 of the inductance core 30 and the base portion 12 that becomes the core portion 32. It has the rotation reference | standard part 20 provided with (reference | standard outer peripheral surface 22). Therefore, the shape of the rotation reference surface in the centerless processing can be freely determined independently of the shape of the base portion 12, and the inductance core 30 having different shapes of the flange portions 36 and 42 and the core portion 32 is preferably manufactured. It is possible.

  In addition, the reference outer peripheral surface 22 of the workpiece 10 in the present embodiment is located on the outer diameter side from the side peripheral surface 18 of the base portion 12, and the outer diameter of the reference outer peripheral surface 22 is larger than the side peripheral surface 18 of the base portion 12. large. Therefore, in the method of manufacturing the inductance core 30 using such a workpiece 10, the workpiece 10 can stably rotate during centerless processing, and the dimensional error of the rotation reference plane, the workpiece 10 during rotation, and the like. The dimensional deviation of the core portion 32 caused by vibration can be suppressed as compared with the case where the outer diameter of the reference outer peripheral surface 22 is small. Therefore, the manufacturing method according to the present embodiment has high processing accuracy in centerless processing, and can form the core portion 32 with high accuracy.

  Furthermore, since the workpiece 10 includes the relatively large rotation reference portion 20 in addition to the base body portion 12, the workpiece 10 becomes heavy. Therefore, the workpiece 10 can rotate stably even under the condition of receiving the wind pressure of the adjusting wheel 54 and the grindstone 50, and the problem that the rotation of the workpiece 10 becomes unstable and the machining accuracy is lowered during the centerless machining. In addition, it is possible to effectively prevent the problem that the workpiece 10 jumps out of the storage portion of the carrier 58. Further, by removing the rotation reference portion 20 after the core portion 32 is formed, it is possible to manufacture the inductance core 30 with high processing accuracy while being small.

Other Embodiments The shape of the reference outer peripheral surface 22 in the workpiece 10 in the circumferential direction is not limited to the elliptical shape as shown in FIG. FIGS. 5A and 5B are a front view (FIG. 5A) and a side view (FIG. 5B) of an inductance core 70 manufactured using a workpiece having a circular reference outer peripheral surface. Similarly to the inductance core 30, the inductance core 70 also has a columnar core portion 72 and a pair of flange portions 76 and 82 respectively connected to both end portions of the core portion 32, and the end surface 80 of the flange portion 76. A grinding mark formed when the rotation reference portion is removed is formed.

  According to the manufacturing method described above, by changing the circumferential shape of the reference outer circumferential surface 22 of the workpiece 10, the outer circumferential shape different from the flange portions 36, 42, 76, 82, such as the inductance cores 30, 70, is obtained. The core portions 32 and 72 can be accurately formed by centerless processing. The shape of the reference outer peripheral surface 22 in the circumferential direction (see FIG. 3A) can be a polygon, but is preferably a circle or an ellipse. By setting the circumferential shape of the reference outer peripheral surface 22 of the workpiece 10 to be a circle or an ellipse, the rotation of the workpiece 10 in the centerless machining is stabilized, and higher-precision machining can be realized.

  Further, the rotation reference portion 20 in the workpiece 10 is not necessarily solid, and the workpiece 90 may have a hollow rotation reference portion 92 as shown in FIG. Also, the semi-finished work 28 shown in FIG. 1B and FIGS. 3A and 3B can be used as an inductance core of a finished product.

DESCRIPTION OF SYMBOLS 10,90 ... Work 12, 12a ... Base | substrate part 14 ... One end 16 ... The other end 18 ... Side surface 20,92 ... Rotation reference | standard part 22 ... Reference | standard outer peripheral surface 28 ... Semi-finished work 30,70 ... Inductance Core 32,72 ... Core 36,36a, 76 ... First collar 40,80 ... First collar end 42,82 ... Second collar 46 ... Second collar end 50,62 ... Whetstone 52,56 ... Stopper 54 ... Adjustment wheel 58 ... Carrier 60 ... Adjustment wheel cover

Claims (6)

A columnar base portion and a reference outer peripheral surface formed integrally with the base portion and connected to one end portion of the base portion, at least a part of which is located on the outer diameter side from the side peripheral surface of the base portion A step of preparing a workpiece having a rotation reference portion comprising:
While rotating the workpiece along the reference outer peripheral surface of the rotation reference part, a part of the base part is ground, and from the base part to both ends of the columnar core part and the core part, respectively. And a step of obtaining a pair of connected flanges .   The method of manufacturing an inductance core according to claim 1, further comprising a step of removing the rotation reference portion from the workpiece after the step of grinding a part of the base portion.   The method of manufacturing an inductance core according to claim 1, wherein a shape of the side peripheral surface in the base portion in the circumferential direction is a polygon.   The method of manufacturing an inductance core according to any one of claims 1 to 3, wherein a shape of the reference outer peripheral surface in a circumferential direction is a circle or an ellipse.   The inductance core manufacturing method according to any one of claims 1 to 4, wherein the other end portion of the base portion is an end portion of the workpiece. A columnar core, and a pair of collars connected to both ends of the core, each having a polygonal outer shape,
The surface roughness of the end surface opposite to the core portion in one of the pair of flange portions is rougher than the surface roughness of the end surface opposite to the core portion in the other flange portion. Inductance core.

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