The present disclosure relates to a coil component and a method of manufacturing the coil component.
A known coil component that is used as a common-mode choke coil includes a core that includes a winding core portion and two flange portions that are disposed on both ends of the winding core portion, and a first wire and a second wire that are wound around the winding core portion, as described, for example, in Japanese Unexamined Patent Application Publication No. 2014-75533. The first wire and the second wire are connected to terminal electrodes that are formed on end portions of the two flange portions in the height direction of the core.
As the size of the coil component decreases, the size of the core decreases, and the thickness of the winding core portion of the core and the thickness of the two flange portions decrease. Consequently, the areas of the terminal electrodes decrease. The decrease in the areas of the terminal electrodes increases an effect of separation of the terminal electrodes from the core on the characteristics of the coil component.
Thus, the present disclosure provides a coil component that enables a terminal electrode to be unlikely to be separated from a core and a method of manufacturing the coil component.
According to preferred embodiments of the present disclosure, a coil component includes a core including a winding core portion that extends in a length direction of the coil component and a first flange portion that is disposed on a first end portion of the winding core portion in the length direction, a first wire that is wound around the winding core portion, and a first terminal electrode that is disposed on a bottom part of the first flange portion in a height direction of the coil component perpendicular to the length direction and that is connected to a first end portion of the first wire. A shape of an outer edge of the first terminal electrode includes a convex curve.
If the outer edge of a terminal electrode has a corner, a stress concentrates on the corner when an external force is applied to the terminal electrode due to thermal expansion or vibration of a core, and the terminal electrode is separated from the core in some cases. However, the shape of the outer edge of the first terminal electrode of the coil component includes the convex curve, and a stress is unlikely to concentrate on the outer edge of the first terminal electrode. Accordingly, the first terminal electrode can be unlikely to be separated from the core.
According to preferred embodiments of the present disclosure, a method of manufacturing a coil component including a core including a winding core portion that extends in a length direction of the coil component and a first flange portion that is disposed on a first end portion of the winding core portion in the length direction, and a first wire that is wound around the winding core portion includes an electrode formation step of forming a first terminal electrode on a bottom part of the first flange portion in a height direction of the coil component perpendicular to the length direction, the first terminal electrode being to be connected to a first end portion of the first wire. The electrode formation step includes forming the first terminal electrode such that a shape of an outer edge of the first terminal electrode includes a convex curve.
With this feature, the shape of the outer edge of the first terminal electrode has the convex curve, and a stress is unlikely to concentrate on the outer edge of the first terminal electrode. Accordingly, the first terminal electrode can be unlikely to be separated from the core.
According to preferred embodiments of the present disclosure, a coil component and a method of manufacturing the coil component enable a terminal electrode to be unlikely to be separated from a core.
Other features, elements, characteristics and advantages of the present disclosure will become more apparent from the following detailed description of preferred embodiments of the present disclosure with reference to the attached drawings.
An embodiment will hereinafter be described. In some of the accompanying drawings, an illustration of components is enlarged to make the components easy to understand. The ratio of dimensions of some of the components differs from the actual ratio or differs between the different drawings. In sectional views, some of the components are not hatched to make the components easy to understand.
As illustrated in
The core 10 is composed of a nonconductive material, specifically, a non-magnetic material such as alumina or a magnetic material such as nickel (Ni)-zinc (Zn) ferrite. The core 10 is formed, for example, in a manner in which a molded body composed of a compressed nonconductive material is fired. The core 10 is not limited to the molded body that is composed of a compressed nonconductive material and that is fired. The core 10 may be formed by thermally curing a resin containing magnetic powder such as metal powder or ferrite powder, a resin containing non-magnetic powder such as silica powder, or a resin containing no filler.
As illustrated in
As illustrated in
The length dimension L11 of the winding core portion 11 is larger than the width dimension W11 and the height dimension T11 of the winding core portion 11. The width dimension W11 is larger than the height dimension T11. According to the present embodiment, the width dimension W11 is about 0.6 mm. The width dimension W11 is preferably 1.0 mm or less. The height dimension T11 of the winding core portion 11 according to the present embodiment is smaller than the width dimension W11.
A cross-section of the winding core portion 11 perpendicular to the length direction Ld has a substantially polygonal shape. According to the present embodiment, a sectional shape of the winding core portion 11 is a substantially quadrilateral shape. In the specification, the “substantially polygonal shape” includes a shape a corner portion of which is chamfered, a shape a corner portion of which is rounded, and a shape a side of which is curved. The shape of the cross-section of the winding core portion 11 is not limited to the substantially polygonal shape and can be freely changed. An example of the shape of the cross-section of the winding core portion 11 may be a substantially circular, a substantially elliptic shape, or a combination of these shapes and a substantially polygonal shape.
According to the present embodiment, the winding core portion 11 has a bottom surface 11a and an upper surface 11b that face each other in the height direction Td, and a first side surface 11c and a second side surface 11d that face each other in the width direction Wd. Each of the bottom surface 11a, the upper surface 11b, the first side surface 11c, and the second side surface 11d is one of surfaces that define the winding core portion 11. According to the present embodiment, the bottom surface 11a is parallel to the upper surface 11b, and the first side surface 11c is parallel to the second side surface 11d. The bottom surface 11a faces the circuit board with the coil component 1 mounted on the circuit board.
As illustrated in
The first flange portion 12 has an inner surface 12a, the outer surface 12b, the upper surface 12c, the bottom surface 12d, the first side surface 12e, and the second side surface 12f. The inner surface 12a faces the winding core portion 11 in the length direction Ld. The outer surface 12b is opposite the inner surface 12a in the length direction Ld. The upper surface 12c and the bottom surface 12d face each other in the height direction Td and connect the inner surface 12a and the outer surface 12b to each other. A first end portion of the first flange portion 12 in the height direction Td has the bottom surface 12d. A second end portion of the first flange portion 12 in the height direction Td has the upper surface 12c. The bottom surface 12d faces the circuit board in the height direction Td with the coil component 1 mounted on the circuit board. The upper surface 12c is opposite the bottom surface 12d in the height direction Td. The first side surface 12e and the second side surface 12f face each other in the width direction Wd and connect the inner surface 12a, the outer surface 12b, the upper surface 12c, and the bottom surface 12d to each other. The second side surface 12f is opposite the first side surface 12e in the width direction Wd.
The second flange portion 13 has an inner surface 13a, the outer surface 13b, the upper surface 13c, the bottom surface 13d, a first side surface 13e, and a second side surface 13f. The inner surface 13a faces the winding core portion 11 in the length direction Ld. The outer surface 13b opposite the inner surface 13a in the length direction Ld. The upper surface 13c and the bottom surface 13d face each other in the height direction Td and connect the inner surface 13a and the outer surface 13b to each other. A first end portion of the second flange portion 13 in the height direction Td has the bottom surface 13d. A second end portion of the second flange portion 13 in the height direction Td has the upper surface 13c. The bottom surface 13d faces the circuit board in the height direction Td with the coil component 1 mounted on the circuit board. The upper surface 13c is opposite the bottom surface 13d in the height direction Td. The first side surface 13e and the second side surface 13f face each other in the width direction Wd and connect the inner surface 13a, the outer surface 13b, the upper surface 13c, and the bottom surface 13d to each other. The second side surface 13f is opposite the first side surface 13e in the width direction Wd.
The bottom surface 11a of the winding core portion 11 thus faces in the same height direction Td as the direction in which the bottom surface 12d of the first flange portion 12 and the bottom surface 13d of the second flange portion 13 face. The upper surface 11b of the winding core portion 11 faces in the same height direction Td as the direction in which the upper surface 12c of the first flange portion 12 and the upper surface 13c of the second flange portion 13 face.
As illustrated in
A sloping portion 16 is formed on the first flange portion 12 near the inner surface 12a. The sloping portion 16 extends in the width direction Wd. An end portion of the sloping portion 16 near the first side surface 12e in the width direction Wd is connected to the bottom surface 11a of the winding core portion 11. The sloping portion 16 slopes such that the distance in the height direction Td from the bottom surface 11a of the winding core portion 11 gradually increases in the width direction Wd from the first side surface 12e toward the second side surface 12f. An end portion of the sloping portion 16 near the second side surface 12f in the width direction Wd is connected to the protruding portion 15b. The length dimension, in the length direction Ld, of a part of the sloping portion 16 near the protruding portion 15a gradually decreases in the direction toward the protruding portion 15a. The length dimension, in the length direction Ld, of a part of the sloping portion 16 near the protruding portion 15b is constant.
As illustrated in
As illustrated in
As illustrated in
A sloping portion 20 is formed on the second flange portion 13 near the inner surface 13a. The sloping portion 20 extends in the width direction Wd. An end portion of the sloping portion 20 near the second side surface 13f in the width direction Wd is connected to the bottom surface 11a of the winding core portion 11. The sloping portion 20 slopes such that the distance in the height direction Td from the bottom surface 11a of the winding core portion 11 gradually increases in the width direction Wd from the second side surface 13f toward the first side surface 13e. That is, the direction of the slope of the sloping portion 20 is opposite the direction of the slope of the sloping portion 16. An end portion of the sloping portion 20 near the first side surface 13e in the width direction Wd is connected to the bottom surface 13d. The length dimension, in the length direction Ld, of a part of the sloping portion 20 near the protruding portion 19a is constant. The length dimension, in the length direction Ld, of a part of the sloping portion 20 near the protruding portion 19b gradually decreases in the direction toward the protruding portion 19b.
As illustrated in
As illustrated in
The first terminal electrode 31, the second terminal electrode 32, the third terminal electrode 33, and the fourth terminal electrode 34 each include, for example, an underlying electrode and a plating layer that is formed on a surface of the underlying electrode. Examples of the material of the underlying electrode include metal such as silver (Ag) and copper (Cu), and an alloy such as nickel (Ni)-chrome (Cr). Examples of the material of the plating layer include metal such as tin (Sn), Cu, and Ni, and an alloy such as Ni—Sn. The plating layer may have a multilayer structure.
The first terminal electrode 31 includes a first bottom surface electrode 31a (region surrounded by a dashed line in
As illustrated in
As illustrated in
As illustrated in
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As illustrated in
As illustrated in
As illustrated in
The following description with reference to
As illustrated in
As illustrated in
A surface (surface of the plating layer) of the first end surface electrode 31b has irregularities. More specifically, the irregularities are on the portion of the first end surface electrode 31b in the first region RA1 located nearer than the end portion thereof (region in which the underlying electrode of the first end surface electrode 31b and the underlying electrode of the first bottom surface electrode 31a overlap) near the bottom surface 12d of the first flange portion 12 to the upper surface 12c of the first flange portion 12 in the height direction Td.
In the case where the coil component 1 is mounted on the circuit board PX, as illustrated in
As illustrated in
This will be described in more detail. As illustrated in
A ratio of the length of the first curved portion 22 in the height direction Td to the maximum distance in the height direction Td from the bottom surface 11a of the winding core portion 11 to the first bottom surface electrode 31a of the first terminal electrode 31 on the first flange portion 12 and from the bottom surface 11a to the second bottom surface electrode 32a of the second terminal electrode 32 is preferably no less than 20% and no more than 60% (i.e., from 20% to 60%). According to the present embodiment, the maximum distance in the height direction Td from the bottom surface 11a of the winding core portion 11 to the first bottom surface electrode 31a of the first terminal electrode 31 on the first flange portion 12 and from the bottom surface 11a to the second bottom surface electrode 32a of the second terminal electrode 32 is about 0.56 mm. The length of the first curved portion 22 in the height direction Td is no less than 0.1 mm and no more than 0.3 mm (i.e., from 0.1 mm to 0.3 mm). In other words, the radius R1 of the curve of the first curved portion 22 in a section perpendicular to the width direction Wd is no less than 0.1 mm and no more than 0.3 mm (i.e., from 0.1 mm to 0.3 mm). In this case, the above ratio is no less than 20% and no more than 60% (i.e., from 20% to 60%).
The length of the third curved portion 24 in the height direction Td is about 0.05 mm. In other words, the radius R3 of the third curved portion 24 is about 0.05 mm That is, according to the present embodiment, a ratio of the length of the third curved portion 24 in the height direction Td to the maximum distance in the height direction Td from the upper surface 11b of the winding core portion 11 to the upper surface 12c of the first flange portion 12 is less than 20%. According to the present embodiment, the maximum distance in the height direction Td from the bottom surface 11a of the winding core portion 11 to the first bottom surface electrode 31a of the first terminal electrode 31 on the first flange portion 12 and from the bottom surface 11a to the second bottom surface electrode 32a of the second terminal electrode 32 is defined by the distances in the height direction Td between the bottom surface 11a of the winding core portion 11 and the first bottom surface electrode 31a that is formed on the leg portion 14a of the first flange portion 12 and between the bottom surface 11a and the second bottom surface electrode 32a that is formed on the leg portion 14b of the first flange portion 12.
As illustrated in
According to the present embodiment, the radius of curvature (the radius R1 of the imaginary circle in
As illustrated in
As illustrated in
As illustrated in
The second surface 52 of the plate member 50 that has the substantially rectangular cuboid shape serves as a suction surface when the coil component 1 is moved. For this reason, for example, when the coil component 1 is mounted on the circuit board, the coil component 1 is readily placed on the circuit board by a suction conveyance device. The plate member 50 may be composed of a magnetic material as in the core 10. When the plate member 50 that is composed of a magnetic material, the core 10 and the plate member 50 can form a closed magnetic circuit in corporation with each other, and the efficiency of obtaining an inductance value is improved.
As illustrated in
The plate member 50 is mounted on the core 10 with adhesive AH (see
The plate member 50 is preferably subjected to chemical cleaning. This improves wettability of the adhesive AH and adhesion between the plate member 50 and the core 10. The flatness of the first surface 51 of the plate member 50 is preferably 5 μm or less. This decreases gaps between the plate member 50 and the first flange portion 12 in contact therewith and between the plate member 50 and the second flange portion 13 in contact therewith, and the inductance value is inhibited from decreasing.
As illustrated in
A distance D1 in the height direction Td between the plate member 50 and the first flange portion 12 varies in the length direction Ld. According to the present embodiment, the distance D1 at a position on the first flange portion 12 nearer than the center of the first flange portion 12 in the length direction Ld to the winding core portion 11 is longer than the distance at a position on the opposite side of the center in the length direction Ld from the winding core portion 11. In other words, the distance D1 at a position on the first flange portion 12 on the opposite side of the center in the length direction Ld from the winding core portion 11 is shorter than the distance at a position nearer than the center in the length direction Ld to the winding core portion 11.
Specifically, as illustrated in
The first surface 51 of the plate member 50 is in contact with a part of the end portion of the upper surface 12c of the first flange portion 12 near the outer surface 12b of the first flange portion 12 in the length direction Ld but is not in contact with a part of the end portion located nearer than the part of the end portion to the inner surface 12a of the first flange portion 12 in the length direction Ld. That is, a gap GA is formed between the first surface 51 of the plate member 50 and the upper surface 12c of the first flange portion 12. The length of the gap GA in the height direction Td gradually increases in the direction from the outer surface 12b of the first flange portion 12 toward the inner surface 12a. In other words, the length of the gap GA in the height direction Td gradually decreases in the direction from the inner surface 12a of the first flange portion 12 toward the outer surface 12b. The adhesive AH for sticking the plate member 50 and the core 10 to each other is in the gap GA. The adhesive AH is also in the two recessed portions 17a and 17b (see
The distance D2 in the height direction Td between the plate member 50 and the second flange portion 13 varies in the length direction Ld. According to the present embodiment, the distance D2 at a position on the second flange portion 13 nearer than the center of the second flange portion 13 in the length direction Ld to the winding core portion 11 is longer than the distance at a position on the opposite side of the center in the length direction Ld from the winding core portion 11. In other words, the distance D2 at a position on the second flange portion 13 on the opposite side of the center in the length direction Ld from the winding core portion 11 is shorter than the distance at a position nearer than the center in the length direction Ld to the winding core portion 11.
Specifically, as illustrated in
The first surface 51 of the plate member 50 is in contact with a part of the end portion of the upper surface 13c of the second flange portion 13 near the outer surface 13b of the second flange portion 13 in the length direction Ld but is not in contact with a part of the end portion located nearer than the part of the end portion to the inner surface 13a of the second flange portion 13 in the length direction Ld. That is, a gap GB is formed between the plate member 50 and the upper surface 13c of the second flange portion 13. The length of the gap GB in the height direction Td gradually increases in the direction from the outer surface 13b of the second flange portion 13 toward the inner surface 13a. In other words, the length of the gap GB in the height direction Td gradually decreases in the direction from the inner surface 13a of the second flange portion 13 toward the outer surface 13b. The adhesive AH for sticking the plate member 50 and the core 10 to each other is in the gap GB. The adhesive AH is also in the two recessed portions 21a and 21b (see
As illustrated in
The first end portion 41a of the first wire 41 is connected to the first terminal electrode 31. The second end portion 41b of the first wire 41 is connected to the third terminal electrode 33. The first end portion 42a of the second wire 42 is connected to the second terminal electrode 32. The second end portion 42b of the second wire 42 is connected to the fourth terminal electrode 34. More specifically, the first end portion 41a of the first wire 41 is connected to a portion of the first bottom surface electrode 31a of the first terminal electrode 31 that corresponds to the protruding portion 15a, and the first end portion 42a of the second wire 42 is connected to a portion of the second bottom surface electrode 32a of the second terminal electrode 32 that corresponds to the protruding portion 15b. For this reason, the protruding portions 15a and 15b form a first connection that is connected to the first end portion 41a of the first wire 41 and the first end portion 42a of the second wire 42. The leg portions 14a and 14b that are mounted on the circuit board PX form a second connection that is mounted on a wiring pattern (land RX) of the circuit board PX with the coil component 1 mounted on the circuit board PX. The second end portion 41b of the first wire 41 is connected to a portion of the third bottom surface electrode 33a of the third terminal electrode 33 that corresponds to the protruding portion 19a. The second end portion 42b of the second wire 42 is connected to a portion of the fourth bottom surface electrode 34a of the fourth terminal electrode 34 that corresponds to the protruding portion 19b. For this reason, the protruding portions 19a and 19b form a third connection that is connected to the second end portion 41b of the first wire 41 and the second end portion 42b of the second wire 42. The leg portions 18a and 18b that are mounted on the circuit board PX form a fourth connection that is mounted on the wiring pattern (land RX) of the circuit board PX with the coil component 1 mounted on the circuit board PX.
The relationship in the height direction Td among the protruding portions 15a and 15b and the leg portions 14a and 14b is preferably set such that the first end portion 41a of the first wire 41 that is connected to the protruding portion 15a of the first flange portion 12 and the first end portion 42a of the second wire 42 that is connected to the protruding portion 15b do not protrude from the leg portions 14a and 14b of the first flange portion 12 in the height direction Td. The relationship in the height direction Td among the protruding portions 19a and 19b and the leg portions 18a and 18b is preferably set such that the first end portion 42a of the first wire 41 that is connected to the protruding portion 19a of the second flange portion 13 and the second end portion 42b of the second wire 42 that is connected to the protruding portion 19b do not protrude from the leg portions 18a and 18b of the second flange portion 13 in the height direction Td.
The first wire 41 and the second wire 42 are connected to the terminal electrodes 31 to 34 by, for example, thermo-compression bonding, brazing, or welding. When the coil component 1 is mounted on the circuit board, the first terminal electrode 31, the second terminal electrode 32, the third terminal electrode 33, and the fourth terminal electrode 34 face the circuit board. At this time, the winding core portion 11 is parallel to the main surfaces of the circuit board PX. That is, the coil 40 according to the present embodiment is a common-mode choke coil that has a horizontal winding structure (horizontal type) in which the winding axes of the first wire 41 and the second wire 42 are parallel to the main surfaces of the circuit board PX.
The first wire 41 and the second wire 42 each include a highly conductive wire composed of copper (Cu), silver (Ag), or gold (Au) and an insulating coating that covers the conductive wire and that is composed of, for example, polyurethane, polyamide imide, or fluorine resin. For example, the diameter of the conductive wire is preferably about 15 to 100 μm. For example, the thickness of the insulating coating is preferably about 8 to 20 μm. According to the present embodiment, the diameter of the conductive wire is about 30 μm. The thickness of the insulating coating is about 10 μm.
The first wire 41 and the second wire 42 are wound around the winding core portion 11 in the same direction. Consequently, when an antiphase signal such as a differential signal is inputted into the first wire 41 and the second wire 42 from the same flange portion of the first flange portion 12 and the second flange portion 13, magnetic flux from the first wire 41 and magnetic flux from the second wire 42 cancel out each other, the function of the coil component 1 as an inductor is reduced, and the antiphase signal is allowed to pass. When an in-phase signal such as an extraneous noise is inputted into the first wire 41 and the second wire 42 from the same flange portion of the first flange portion 12 and the second flange portion 13, magnetic flux from the first wire 41 and magnetic flux from the second wire 42 enhance each other, the function of the coil component 1 as an inductor is improved, and the in-phase signal is blocked. Accordingly, the coil component 1 functions as a common-mode choke coil that reduces the transmission loss of a signal in a differential mode such as a differential signal and that attenuates a signal in a common mode such as an extraneous noise.
The coil 40 includes the winding portion 40a that is wound around the winding core portion 11, a first extension portion 40b, a second extension portion 40c, a third extension portion 40d, and a fourth extension portion 40e on both sides of the winding portion 40a. Each of the extension portions 40b, 40c, 40d, and 40e includes the vicinity of the end portions of the first wire 41 and the second wire 42 that are connected to the terminal electrodes 31 to 34. The first extension portion 40b connects the first end portion 41a of the first wire 41 that is connected to the first terminal electrode 31 and the winding portion 40a to each other. The second extension portion 40c connects the second end portion 41b of the first wire 41 that is connected to the third terminal electrode 33 and the winding portion 40a to each other. The third extension portion 40d connects the first end portion 42a of the second wire 42 that is connected to the second terminal electrode 32 and the winding portion 40a to each other. The fourth extension portion 40e connects the second end portion 42b of the second wire 42 that is connected to the fourth terminal electrode 34 and the winding portion 40a to each other.
As illustrated in
According to the present embodiment, the distance LD2 is longer than the distance LD1. That is, a space in which the first extension portion 40b and the third extension portion 40d extend in the length direction Ld is smaller than a space in which the second extension portion 40c and the fourth extension portion 40e extend. With this structure, when the first wire 41 and the second wire 42 that are wound around the winding core portion 11 are connected to the third terminal electrode 33 and the fourth terminal electrode 34, the first wire 41 and the second wire 42 can be inhibited from interfering with the inner surface 13a of the second flange portion 13. Accordingly, the first wire 41 and the second wire 42 can be smoothly connected to the third terminal electrode 33 and the fourth terminal electrode 34.
The relationship between the distance LD1 and the distance LD2 can be freely changed. For example, the distance LD1 may be longer than the distance LD2. That is, the space in which the second extension portion 40c and the fourth extension portion 40e extend may be smaller than the space in which the first extension portion 40b and the third extension portion 40d extend. With this structure, while the first wire 41 that is connected to the first terminal electrode 31 and the second wire 42 that is connected to the second terminal electrode 32 are wound around the winding core portion 11, the second extension portion 40c and the fourth extension portion 40e can be inhibited from being excessively bent. Accordingly, concentration of a stress on the second extension portion 40c and the fourth extension portion 40e can be reduced, and risk of breakage of the second extension portion 40c and the fourth extension portion 40e can be reduced.
As illustrated in
As illustrated in
The third extension portion 40d that extends in the height direction Td toward the bottom surface 11a of the winding core portion 11 extends obliquely from the winding core portion 11 toward the first flange portion 12 while extending from the second side surface 11d of the winding core portion 11 toward the first side surface 11c and is placed on the sloping portion 16 of the first flange portion 12. The first end portion 42a of the second wire 42 extends in the length direction Ld and is connected to the portion of the second bottom surface electrode 32a of the second terminal electrode 32 that corresponds to the protruding portion 15b and that is spaced from the leg portion 14b in the width direction Wd. An end portion of the third extension portion 40d near the first end portion 42a of the second wire 42 includes a first bent portion 42c. The first bent portion 42c is formed so as to have a convex shape toward the inner surface 12a of the first flange portion 12 in the length direction Ld. According to the present embodiment, on the opposite side of the first bent portion 42c from the first end portion 42a of the second wire 42, the third extension portion 40d includes a second bent portion 42d that extends from the first bent portion 42c and that is bent in the length direction Ld opposite the direction in which the first bent portion 42c is bent. Consequently, the end portion of the third extension portion 40d that is placed on the sloping portion 16 and that is near the second bent portion 42d is located nearer than the inner surface 12a of the first flange portion 12 to the outer surface 12b.
According to the present embodiment, the first end portion 42a of the second wire 42 is located nearer than the first side surface 11c of the winding core portion 11 to the second side surface 12f of the first flange portion 12 in the width direction Wd. The first end portion 42a of the second wire 42 is located nearer than the second end portion 42b of the second wire 42 to the second side surface 12f of the first flange portion 12 (the second side surface 13f of the second flange portion 13) in the width direction Wd when viewed in the length direction Ld in front of the first flange portion 12.
As illustrated in
As illustrated in
As illustrated in
The second extension portion 40c that extends in the height direction Td toward the bottom surface 11a of the winding core portion 11 extends obliquely from the winding core portion 11 toward the second flange portion 13 while extending from the first side surface 11c of the winding core portion 11 toward the second side surface 11d and is placed on the sloping portion 20 of the second flange portion 13. The second end portion 41b of the first wire 41 is connected to the third terminal electrode 33. There is thus no bent portion over a region from the second extension portion 40c to the second end portion 41b of the first wire 41, and a stress does not concentrate on the second extension portion 40c and the second end portion 41b. Accordingly, the distance in the length direction Ld between the winding portion 40a and the inner surface 13a of the second flange portion 13 can be decreased, and the number of turns of the winding portion 40a can be increased.
Method of Manufacturing Coil Component
A method of manufacturing the coil component 1 will be described with reference to
In the core preparation step, the core on which the first to fourth terminal electrodes 31 to 34 are not formed is prepared. The core is formed by firing a molded body composed of a compressed nonconductive material with a mold. According to the present embodiment, when the core is formed with the mold, the first curved portion 22, the second curved portion 23, the third curved portion 24, the fourth curved portion 25, the recessed portions 17a and 17b, and the recessed portions 21a and 21b are formed. That is, the shape of the first curved portion 22, the shape of the second curved portion 23, the shape of the third curved portion 24, and the shape of the fourth curved portion 25 is adjusted depending on the shape of the mold. The shapes of the recessed portions 17a and 17b and the shapes of the recessed portions 21a and 21b depend on the shape of the mold.
The electrode formation step includes an end surface electrode formation step (step S21) and a bottom surface electrode formation step (step S22). According to the present embodiment, the bottom surface electrode formation step is performed after the end surface electrode formation step.
In the end surface electrode formation step, as illustrated in
The underlying electrode of the third end surface electrode 33b of the third terminal electrode 33 and the underlying electrode of the fourth end surface electrode 34b of the fourth terminal electrode 34 are formed by using the applicator 100 as in the underlying electrode of the first end surface electrode 31b of the first terminal electrode 31 and the underlying electrode of the second end surface electrode 32b of the second terminal electrode 32.
In the bottom surface electrode formation step, as illustrated in
As illustrated in
The underlying electrode of the second bottom surface electrode 32a overlaps the underlying electrode of the second end surface electrode 32b, the underlying electrode of the third bottom surface electrode 33a overlaps the underlying electrode of the third end surface electrode 33b, and the underlying electrode of the fourth bottom surface electrode 34a overlaps the underlying electrode of the fourth end surface electrode 34b in the same manner as the underlying electrode of the first bottom surface electrode 31a overlaps the underlying electrode of the first end surface electrode 31b.
After the underlying electrodes of the bottom surface electrodes 31a to 34a and the underlying electrodes of the end surface electrodes 31b to 34b of the terminal electrodes 31 to 34 are formed, the plating layers are formed by, for example, electroless barrel plating so as to be stacked on the underlying electrodes of the bottom surface electrodes 31a to 34a and the underlying electrodes of the end surface electrodes 31b to 34b. Each of the plating layers is formed in order of a nickel (Ni) layer and a tin (Sn) layer.
In the first connection step, the first wire 41 is connected to the first bottom surface electrode 31a of the first terminal electrode 31, and the second wire 42 is connected to the second bottom surface electrode 32a of the second terminal electrode 32. Specifically, the core 10 is first set on a winder 120. As illustrated in
When the coil formation step is performed, the second nozzle 122 moves toward the second side surface 11d of the winding core portion 11 of the core 10. At this time, the second wire 42 that is connected to the second terminal electrode 32 is bent by using a first hook 123 of the winder 120 to form the first bent portion 42c. The second wire 42 is bent by using a second hook 124 of the winder 120 to form the second bent portion 42d. The second wire 42 that extends from the second bent portion 42d toward the second side surface 11d of the winding core portion 11 is placed on the sloping portion 16 of the core 10.
In the coil formation step, the first nozzle 121 and the second nozzle 122 revolve around the winding core portion 11 to wind the first wire 41 and the second wire 42 around the winding core portion 11. At this time, the first nozzle 121 and the second nozzle 122 operate such that the first wire 41 and the second wire 42 intersect each other at one time whenever the first wire 41 and the second wire 42 are wound predetermined times (the number of turns).
In the coil formation step, the first nozzle 121 and the second nozzle 122 finish winding the first wire 41 and the second wire 42 around the winding core portion 11 at positions on the first side surface 11c of the winding core portion 11. At this time, the first nozzle 121 and the second nozzle 122 operate such that the first wire 41 and the second wire 42 intersect each other along the first side surface 11c of the winding core portion 11.
In the second connection step, the first wire 41 is connected to the third terminal electrode 33, and the second wire 42 is connected to the fourth terminal electrode 34. Specifically, as illustrated in
In the wire cutting step, a portion of the first wire 41 that extends from the contact between the first wire 41 and the first bottom surface electrode 31a of the first terminal electrode 31 toward the opposite side of the first flange portion 12 from the winding core portion 11 is cut by using a cutting device not illustrated. Consequently, the contact between the first wire 41 and the first terminal electrode 31 corresponds to the first end portion 41a of the first wire 41. A portion of the first wire 41 that extends from the first nozzle 121 and that protrudes from the contact between the first wire 41 and the third bottom surface electrode 33a of the third terminal electrode 33 to the outside of the first side surface 13e of the second flange portion 13 is cut by using the cutting device. Consequently, the contact between the first wire 41 and the third bottom surface electrode 33a of the third terminal electrode 33 corresponds to the second end portion 41b of the first wire 41.
In the wire cutting step, a portion of the second wire 42 that extends from the contact between the second wire 42 and the second bottom surface electrode 32a of the second terminal electrode 32 toward the opposite side of the first flange portion 12 from the winding core portion 11 is cut by using the cutting device. Consequently, the contact between the second wire 42 and the second bottom surface electrode 32a of the second terminal electrode 32 corresponds to the first end portion 42a of the second wire 42. A portion of the second wire 42 that extends from the second nozzle 122 and that protrudes from the contact between the second wire 42 and the fourth bottom surface electrode 34a of the fourth terminal electrode 34 to the opposite side of the second flange portion 13 from the winding core portion 11 is cut by using the cutting device. Consequently, the contact between the second wire 42 and the fourth bottom surface electrode 34a of the fourth terminal electrode 34 corresponds to the second end portion 42b of the second wire 42.
In the plate member mounting step, the plate member 50 is mounted on the core 10 with adhesive. According to the present embodiment, the adhesive AH is applied to the upper surface 12c of the first flange portion 12 and the upper surface 13c of the second flange portion 13 of the core 10. The adhesive AH is epoxy resin adhesive that contains silica filler. The adhesive AH can be applied by a known method. At this time, the adhesive AH is applied to the entire upper surface 12c of the first flange portion 12. Subsequently, the plate member 50 is pressed against the core 10 with the first surface 51 of the plate member 50 faces the upper surface 12c of the first flange portion 12 and the upper surface 13c of the second flange portion 13 of the core 10. At this time, excess adhesive AH between the first surface 51 of the plate member 50 and the upper surface 12c of the first flange portion 12 enters the recessed portions 17a and 17b of the first flange portion 12, and the end portion of the first flange portion 12 near the outer surface 12b comes into contact with the first surface 51 of the plate member 50. Since the excess adhesive AH enters the recessed portions 17a and 17b, the adhesive AH is unlikely to protrude from the gap GA illustrated in
According to the present embodiment, the following effects are achieved. (1) The first curved portion 22 is formed at the connection between the bottom surface 11a of the winding core portion 11 and the inner surface 12a of the first flange portion 12 of the core 10. The ratio of the length of the first curved portion 22 in the height direction Td to the distance between the bottom surface 11a of the winding core portion 11 and the first terminal electrode 31 in the height direction Td is no less than 20% and no more than 60% (i.e., from 20% to 60%). With this structure, when the ratio of the length of the first curved portion 22 in the height direction Td to the distance between the bottom surface 11a of the winding core portion 11 and the first terminal electrode 31 in the height direction Td is 20% or more, the first curved portion 22 can be enlarged, and flexural strength between the winding core portion 11 and the first flange portion 12 can be increased. Accordingly, the deflection strength of the core 10 can be increased. When the ratio of the length of the first curved portion 22 in the height direction Td to the distance between the bottom surface 11a of the winding core portion 11 and the first terminal electrode 31 in the height direction Td is 60% or less, the thickness of the first flange portion 12 can be inhibited from being excessively decreased in the length direction Ld. Accordingly, the length of the first bottom surface electrode 31a of the first terminal electrode 31 and the length of the second bottom surface electrode 32a of the second terminal electrode 32 can be inhibited from being excessively decreased in the length direction Ld, and the coil component 1 can be more appropriately mounted on the circuit board PX.
The second curved portion 23 is formed at the connection between the bottom surface 11a of the winding core portion 11 and the inner surface 13a of the second flange portion 13. The ratio of the length of the second curved portion 23 in the height direction Td to the distance in the height direction Td between the bottom surface 11a of the winding core portion 11 and the third terminal electrode 33 is no less than 20% and no more than 60% (i.e., from 20% to 60%). With this structure, when the ratio of the length of the second curved portion 23 in the height direction Td to the distance in the height direction Td between the bottom surface 11a of the winding core portion 11 and the third terminal electrode 33 is 20% or more, the second curved portion 23 can be enlarged, and flexural strength between the winding core portion 11 and the second flange portion 13 can be increased. Accordingly, the deflection strength of the core 10 can be increased. When the ratio of the length of the second curved portion 23 in the height direction Td to the distance in the height direction Td between the bottom surface 11a of the winding core portion 11 and the third terminal electrode 33 is 60% or less, the thickness of the second flange portion 13 can be inhibited from being excessively decreased in the length direction Ld. Accordingly, the length of the third bottom surface electrode 33a of the third terminal electrode 33 and the length of the fourth bottom surface electrode 34a of the fourth terminal electrode 34 can be inhibited from being excessively decreased in the length direction Ld, and the coil component 1 can be more appropriately mounted on the circuit board PX.
(2) The first curved portion 22 has a curve having a substantially true-circular shape in a section perpendicular to the width direction Wd. With this structure, the first curved portion 22 can be readily formed unlike the case where the curvature of the first curved portion 22 varies, for example, in the case of having a curve of a substantially elliptic shape in a section perpendicular to the width direction Wd.
The second curved portion 23 has a curve having a substantially true-circular shape in a section perpendicular to the width direction Wd. With this structure, the second curved portion 23 can be more readily formed unlike the case where the curvature of the second curved portion 23 varies, for example, in the case of having a curve of a substantially elliptic shape in a section perpendicular to the width direction Wd.
(3) The third curved portion 24 is formed at the connection between the upper surface 11b of the winding core portion 11 and the inner surface 12a of the first flange portion 12 of the core 10. The length of the first curved portion 22 in the height direction Td is longer than the length of the third curved portion 24 in the height direction Td. With this structure, the flexural strength of the core 10 of the coil component 1 at a position near the circuit board PX is increased, and the reliability of connection between the coil component 1 and the circuit board PX can be improved.
The fourth curved portion 25 is formed at the connection between the upper surface 11b of the winding core portion 11 and the inner surface 13a of the second flange portion 13. The length of the second curved portion 23 in the height direction Td is longer than the length of the fourth curved portion 25 in the height direction Td. With this structure, the flexural strength of the core 10 of the coil component 1 at a position near the circuit board PX is increased, and the reliability of connection between the coil component 1 and the circuit board PX can be further improved.
(4) The length of the first curved portion 22 in the length direction Ld is longer than the length of the third curved portion 24 in the length direction Ld in a section perpendicular to the width direction Wd. This structure increases the distances between the end portion (portion of the winding portion 40a that faces the bottom surface 11a) of the winding portion 40a that is near the circuit board PX in the height direction Td and that is near the first flange portion 12 in the length direction Ld and the first terminal electrode 31 of the first flange portion 12 and between the end portion and the second terminal electrode 32. Accordingly, heat that the first terminal electrode 31 and the second terminal electrode 32 generate is unlikely to affect the winding portion 40a, and the quality of the coil component 1 is improved.
The length of the second curved portion 23 in the length direction Ld is longer than the length of the fourth curved portion 25 in the length direction Ld in a section perpendicular to the width direction Wd. This structure increases the distances between the end portion of the winding portion 40a that is near the circuit board PX in the height direction Td and that is near the second flange portion 13 in the length direction Ld and the third terminal electrode 33 of the second flange portion 13 and between the end portion and the fourth terminal electrode 34. Accordingly, heat that the third terminal electrode 33 and the fourth terminal electrode 34 generate is unlikely to affect the winding portion 40a, and the quality of the coil component 1 is improved.
(5) The distance LX1 in the length direction Ld between the first curved portion 22 and the second curved portion 23 is longer than the distance LX2 in the length direction Ld between the third curved portion 24 and the fourth curved portion 25 in a section of the winding core portion 11 along a plane extending in the length direction Ld. With this structure, the distance in the length direction Ld between the winding portion 40a along the bottom surface 11a of the winding core portion 11 and the inner surface 12a of the first flange portion 12 is longer than the distance in the length direction Ld between the winding portion 40a along the upper surface 11b of the winding core portion 11 and the inner surface 12a of the first flange portion 12 when viewed in the height direction Td. This increases the distances between the first terminal electrode 31 and the winding portion 40a and between the second terminal electrode 32 and the winding portion 40a, and heat that the first terminal electrode 31 and the second terminal electrode 32 generate is unlikely to affect the winding portion 40a. Accordingly, the quality of the coil component 1 is improved.
The distance in the length direction Ld between the winding portion 40a along the bottom surface 11a of the winding core portion 11 and the inner surface 13a of the second flange portion 13 is longer than the distance in the length direction Ld between the winding portion 40a along the upper surface 11b of the winding core portion 11 and the inner surface 13a of the second flange portion 13 when viewed in the height direction Td. This increases the distances between each of the terminal electrodes 31 to 34 and the winding portion 40a, and heat that the terminal electrodes 31 to 34 generate is unlikely to affect the winding portion 40a. Accordingly, the quality of the coil component 1 is improved.
(6) The coil component 1 includes the plate member 50 that faces the upper surface 12c of the first flange portion 12 and the upper surface 13c of the second flange portion 13 in the height direction Td. The distance in the height direction Td between the first surface 51 of the plate member 50 and the upper surface 12c of the first flange portion 12 varies in the length direction Ld. With this structure, when the plate member 50 is composed of a magnetic material, the magnetic circuit between the core 10 and the plate member 50 is restricted because the distance in the height direction Td between the first surface 51 of the plate member 50 and the upper surface 12c of the first flange portion 12 partly decreases at a position between the plate member 50 and the first flange portion 12. Accordingly, a variation in the length of the magnetic circuit in the coil component 1 is decreased, and the inductance value of the coil component 1 can be inhibited from varying.
The distance in the height direction Td between the first surface 51 of the plate member and the upper surface 13c of the second flange portion 13 varies in the length direction Ld of the second flange portion 13. Accordingly, regarding the second flange portion 13, the magnetic circuit between the core 10 and the plate member 50 is restricted as in the first flange portion 12. The variation in the length of the magnetic circuit in the coil component 1 is decreased, and the inductance value of the coil component 1 can be further inhibited from varying.
In the case where the plate member 50 is secured to the first flange portion 12 and the second flange portion 13 with the adhesive AH, the adhesive AH moves from the position at which the distance in the height direction Td between the first surface 51 of the plate member 50 and the upper surface 12c of the first flange portion 12 decreases to the position at which the distance in the height direction Td between the first surface 51 of the plate member 50 and the upper surface 12c of the first flange portion 12 increases. For this reason, the adhesive AH is inhibited from protruding to the outside of the core 10 and the plate member 50.
Regarding the second flange portion 13, the adhesive AH moves from the position at which the distance in the height direction Td between the first surface 51 of the plate member 50 and the upper surface 13c of the second flange portion 13 decreases to the position at which the distance in the height direction Td between the first surface 51 of the plate member 50 and the upper surface 13c of the second flange portion 13 increases. For this reason, the adhesive AH is further inhibited from protruding to the outside of the core 10 and the plate member 50.
(7) The position at which the distance in the height direction Td between the first surface 51 of the plate member 50 and the upper surface 12c of the first flange portion 12 increases is near the inner surface 12a of the first flange portion 12. With this structure, the adhesive AH between the first surface 51 of the plate member 50 and the upper surface 12c of the first flange portion 12 moves toward the inner surface 12a of the first flange portion 12 and is unlikely to move toward the outer surface 12b. For this reason, the adhesive AH is unlikely to protrude to the outside of the core 10 and the plate member 50.
Regarding the second flange portion 13, the position at which the distance in the height direction Td between the first surface 51 of the plate member 50 and the upper surface 13c of the second flange portion 13 increases is near the inner surface 13a of the second flange portion 13. Accordingly, the adhesive AH between the first surface 51 of the plate member 50 and the upper surface 13c of the second flange portion 13 moves toward the inner surface 13a of the second flange portion 13 and is unlikely to move toward the outer surface 13b. For this reason, the adhesive AH is more unlikely to protrude to the outside of the core 10 and the plate member 50.
(8) The distance D1 in the height direction Td between the first surface 51 of the plate member 50 and the upper surface 12c of the first flange portion 12 gradually decreases in the direction from the inner surface 12a of the first flange portion 12 toward the outer surface 12b. With this structure, the magnetic circuit between the core 10 and the plate member 50 is restricted by the inner surface 12a of the first flange portion 12. Accordingly, the variation in the length of the magnetic circuit in the coil component 1 is decreased, and the inductance value of the coil component 1 can be inhibited from varying.
In the case where the plate member 50 and the first flange portion 12 are secured to each other with the adhesive AH, the adhesive AH between the first surface 51 of the plate member 50 and the upper surface 12c of the first flange portion 12 near the outer surface 12b in the length direction Ld moves toward the inner surface 12a in the length direction Ld. For this reason, the adhesive AH is inhibited from protruding to the outside of the core 10 and the plate member 50.
Regarding the second flange portion 13, the distance D2 in the height direction Td between the first surface 51 of the plate member 50 and the upper surface 13c of the second flange portion 13 gradually decreases in the direction from the inner surface 13a of the second flange portion 13 toward the outer surface 13b as in the first flange portion 12. Accordingly, the variation in the length of the magnetic circuit in the coil component 1 is decreased, and the inductance value of the coil component 1 can be inhibited from varying. The adhesive AH that secures the plate member 50 and the second flange portion 13 to each other moves from a position near the outer surface 13b in the length direction Ld between the first surface 51 of the plate member 50 and the upper surface 13c of the second flange portion 13 toward the inner surface 13a in the length direction Ld. For this reason, the adhesive AH is further inhibited from protruding to the outside of the core 10 and the plate member 50.
(9) As discussed above, the recessed portions 17a and 17b are formed on the upper surface 12c of the first flange portion 12 that faces the first surface 51 of the plate member 50, or in the plate member 50, or both, at positions outside the winding core portion 11 in the width direction Wd. With this structure, in the case where the plate member 50 is secured to the first flange portion 12 and the second flange portion 13 with the adhesive AH, the adhesive AH enters the recessed portions 17a and 17b, and the adhesive AH is further inhibited from protruding to the outside of the core 10 and the plate member 50.
Since the recessed portions 17a and 17b are formed at the positions outside the winding core portion 11 in the width direction Wd, the recessed portions 17a and 17b inhibit the plate member 50 from affecting the magnetic circuit between the core 10 and the plate member 50 within the range of the width of the winding core portion 11, and the distance between the plate member 50 and the first flange portion 12 is not increased. Accordingly, the inductance value of the coil component 1 can be inhibited from decreasing.
The recessed portions 21a and 21b are formed on the upper surface 13c of the second flange portion 13 as in the first flange portion 12. Also, as discussed above, the recessed portions 21a and 21b are formed on the upper surface 13c of the first flange portion 12 that faces the first surface 51 of the plate member 50, or in the plate member 50, or both, at positions outside the winding core portion 11 in the width direction Wd. Accordingly, the adhesive AH can be further inhibited from protruding to the outside of the core 10 and the plate member 50. In addition, the magnetic circuit between the core 10 and the plate member 50 is further inhibited from being affected. Accordingly, the inductance value of the coil component 1 can be further inhibited from decreasing.
(10) The shape of the outer edge of the first end surface electrode 31b of the first terminal electrode 31 includes the convex curve. With this structure, a stress is unlikely to concentrate on the outer edge of the first end surface electrode 31b of the first terminal electrode 31, and the first end surface electrode 31b of the first terminal electrode 31 is unlikely to be separated from the core 10. Accordingly, the reliability of the coil component 1 can be improved.
The shape of the outer edge of the second end surface electrode 32b of the second terminal electrode 32, the outer edge of the third end surface electrode 33b of the third terminal electrode 33, and the outer edge of the fourth end surface electrode 34b of the fourth terminal electrode 34 includes the convex curve. With this structure, a stress is unlikely to concentrate on the outer edges of the end surface electrodes 32b to 34b of the terminal electrodes 32 to 34, and the end surface electrodes 32b to 34b of the terminal electrodes 32 to 34 are unlikely to be separated from the core 10. Accordingly, the reliability of the coil component 1 can be further improved.
(11) The shape of the outer edge of the first bottom surface electrode 31a of the first terminal electrode 31 includes the convex curve. With this structure, a stress is unlikely to concentrate on the outer edge of the first bottom surface electrode 31a of the first terminal electrode 31, and the first bottom surface electrode 31a of the first terminal electrode 31 is unlikely to be separated from the core 10. Accordingly, the reliability of the coil component 1 can be improved.
The shape of the outer edge of the second bottom surface electrode 32a of the second terminal electrode 32, the outer edge of the third bottom surface electrode 33a of the third terminal electrode 33, and the outer edge of the fourth bottom surface electrode 34a of the fourth terminal electrode 34 includes the convex curve. With this structure, a stress is unlikely to concentrate on the outer edges of the bottom surface electrodes 32a to 34a of the terminal electrodes 32 to 34, and the bottom surface electrodes 32a to 34a of the terminal electrodes 32 to 34 are unlikely to be separated from the core 10. Accordingly, the reliability of the coil component 1 can be further improved.
(12) The first end surface electrode 31b of the first terminal electrode 31 is formed to have an uneven shape when viewed in the width direction Wd or the height direction Td. With this structure, in the case where the coil component 1 is mounted on the circuit board PX with a conductive connection member such as solder SD, the conductive connection member enters an uneven portion of the first end surface electrode 31b of the first terminal electrode 31. This increases connection strength between the coil component 1 and the circuit board PX.
The second end surface electrode 32b of the second terminal electrode 32, the third end surface electrode 33b of the third terminal electrode 33, and the fourth end surface electrode 34b of the fourth terminal electrode 34 are each formed to have an uneven shape when viewed in the width direction Wd or the height direction Td. With this structure, in the case where the coil component 1 is mounted on the circuit board PX with the conductive connection member such as solder SD, the conductive connection member enters uneven portions of the end surface electrodes 32b to 34b of the terminal electrodes 32 to 34. This further increases the connection strength between the coil component 1 and the circuit board PX.
(13) The first flange portion 12 includes the protruding portions 15a and 15b that are connected to the first end portion 41a of the first wire 41 and the first end portion 42a of the second wire 42, and the leg portions 14a and 14b that are to be mounted on the wiring pattern (land RX) of the circuit board PX in the case where the coil component is mounted on the circuit board PX. The second flange portion 13 includes the protruding portions 19a and 19b that is connected to the second end portion 41b of the first wire 41 and the second end portion 42b of the second wire 42, and the leg portions 18a and 18b that are to be mounted on the wiring pattern (land RX) of the circuit board PX in the case where the coil component is mounted on the circuit board PX. The leg portions 14a, 14b, 18a, and 18b protrude from the protruding portions 15a, 15b, 19a, and 19b toward the circuit board PX. The first bottom surface electrode 31a of the first terminal electrode 31 is disposed at a portion that corresponds to the leg portion 14a and the protruding portion 15a, and the second bottom surface electrode 32a of the second terminal electrode 32 is disposed at a portion that corresponds to the leg portion 14b and the protruding portion 15b. The third bottom surface electrode 33a of the third terminal electrode 33 is disposed at a portion that corresponds to the leg portion 18a and the protruding portion 19a. The fourth bottom surface electrode 34a of the fourth terminal electrode 34 is disposed at a portion that corresponds to the leg portion 18b and the protruding portion 19b. With this structure, the first wire 41 and the second wire 42 are electrically connected to the terminal electrodes 31 to 34, and the coil component can be mounted on the circuit board PX without being affected by the end portions 41a and 41b of the first wire 41 and the end portions 42a and 42b of the second wire 42 by using the leg portions 14a, 14b, 18a, and 18b. Accordingly, the coil component 1 is prevented from sloping with respect to the circuit board PX by bringing the end portions 41a and 41b of the first wire 41 and the end portions 42a and 42b of the second wire 42 into contact with the circuit board PX, and the coil component 1 is appropriately connected to the circuit board PX.
(14) In the end surface electrode formation step in the method of manufacturing the coil component 1, the end surface electrodes 31b to 34b of the terminal electrodes 31 to 34 are formed by using the applicator 100 (dispenser). This facilitates formation of the uneven shapes of the end surface electrodes 31b to 34b of the terminal electrodes 31 to 34 by forming the applied portions 35 in rows in the width direction Wd and in columns in the height direction Td.
(15) The bottom surface electrode formation step is performed with the outer surface 12b of the first flange portion 12 and the outer surface 13b of the second flange portion 13 placed on the reference surface 101 of the applicator 100. Assuming that the bottom surface electrodes 31a to 34a of the terminal electrodes 31 to 34 are first formed, in some cases where portions of the bottom surface electrodes 31a to 34a are formed to reach the outer surface 12b of the first flange portion 12 and the outer surface 13b of the second flange portion 13, the core 10 slopes with respect to the reference surface 101 of the applicator 100 due to the bottom surface electrodes 31a to 34a. For this reason, it is necessary to form the end surface electrodes 31b to 34b of the terminal electrodes 31 to 34 in consideration for the slope of the core 10 with respect to the reference surface 101 of the applicator 100.
In view of this, in the electrode formation step of the method of manufacturing of the coil component 1, the end surface electrode formation step is performed before the bottom surface electrode formation step. In this case, when the core 10 is placed on the reference surface 101 of the applicator 100, the terminal electrodes 31 to 34 do not have the bottom surface electrodes 31a to 34a, and the core 10 is inhibited from sloping with respect to the reference surface 101. Accordingly, it is not necessary to consider the slope of the core 10 with respect to the reference surface 101, and the end surface electrodes 31b to 34b of the terminal electrodes 31 to 34 can be more accurately formed by using the applicator 100.
(16) The winding portion 40a includes the N (N is an even number equal to or more than 2) first winding portions 43 and the first intersecting portions 44, and at each of the first winding portions 43, the first wire 41 and the second wire 42 are arranged along the winding core portion 11 and wound therearound in the same direction to have the predetermined number of turns. At each of the first intersecting portions 44, the first wire 41 and the second wire 42 intersect each other at one time between the first winding portions 43 adjacent to each other in the length direction Ld. For this reason, the first winding portions 43 on both sides of each first intersecting portion 44 in the length direction Ld have opposite polarities. There are an even number of such structures, which enables the polarity of the winding portion 40a to balance.
The first wire 41 and the second wire 42 intersect each other to form the second intersecting portion 45 along the first side surface 11c of the winding core portion 11 in the first winding portion 43 of the winding portion 40a at the position nearest to the second flange portion 13. For this reason, the second intersecting portion 45 is not formed to be adjacent in the length direction Ld of the first winding portions 43, and the winding portion 40a is inhibited from being excessively close to the third terminal electrode 33 and the fourth terminal electrode 34 of the second flange portion 13. Accordingly, the quality of the coil component 1 is improved. In the case where the first wire 41 and the second wire 42 are connected to the third terminal electrode 33 and the fourth terminal electrode 34, the first wire 41 and the second wire 42 can be gently bent, and the risk of breakage of the first wire 41 and the second wire 42 can be reduced.
(17) The second intersecting portion 45 is formed along the first side surface 11c of the winding core portion 11 in the first winding portion 43 of the winding portion 40a at the position nearest to the second flange portion 13. With this structure, from the intersection between the first wire 41 and the second wire 42 at the second intersecting portion 45, the first wire 41 can extend toward the third terminal electrode 33, and the second wire 42 can extend toward the fourth terminal electrode 34. Accordingly, the degree of freedom of the first wire 41 and the second wire 42 that are connected to the third terminal electrode 33 and the fourth terminal electrode 34 increases. In addition, the first wire 41 and the second wire 42 can be connected to the third terminal electrode 33 and the fourth terminal electrode 34 with the first wire 41 and the second wire 42 gently bent, and a stress can be inhibited from concentrating on the second extension portion 40c and the fourth extension portion 40e.
(18) The winding portion 40a is formed by winding the first wire 41 and the second wire 42 in a bifilar winding manner. With this structure, the first wire 41 and the second wire 42 adjacent each other in the length direction Ld of the winding portion 40a enable the noise of the first wire 41 and the noise of the second wire 42 to cancel out each other. Accordingly, the quality of the coil component 1 can be improved.
(19) The second wire 42 includes the first end portion 42a that extends in the length direction Ld, the first bent portion 42c that is bent from the first end portion 42a toward the outer surface 12b of the first flange portion 12, and the second bent portion 42d that is bent from the first bent portion 42c in the width direction Wd. With this structure, the first bent portion 42c and the second bent portion 42d enable the third extension portion 40d to be disposed near the first flange portion 12. Accordingly, the extension portion 40b of the second wire 42 can be appropriately placed on the sloping portion 16 of the first flange portion 12.
(20) The third extension portion 40d is disposed so as to extend along the sloping portion 16 of the first flange portion 12. With this structure, it is not necessary to use a so-called point-to-point construction in which the third extension portion 40d is disposed so as to be spaced from the first flange portion 12 in the height direction Td, and the risk of breakage of the second wire 42 can be reduced. The second extension portion 40c is disposed so as to extend along the sloping portion 20 of the second flange portion 13. With this structure, the second extension portion 40c is inhibited from being disposed so as to be spaced from the second flange portion 13 in the height direction Td, and the risk of breakage of the first wire 41 can be reduced.
(21) The length LA of the winding portion 40a in the length direction Ld along the bottom surface 11a of the winding core portion 11 is shorter than the length LB of the winding portion 40a along the upper surface 11b of the winding core portion 11. With this structure, the distance between the winding portion 40a and the land RX of the circuit board PX with the coil component 1 mounted on the circuit board PX is increased. Accordingly, thermal effect on the winding portion 40a due to the land RX of the circuit board PX can be further reduced.
(22) The distance LD1 in the length direction Ld between the inner surface 12a of the first flange portion 12 and the winding portion 40a along the bottom surface 11a of the winding core portion 11 is longer than the distance LD3 in the length direction Ld between the inner surface 12a of the first flange portion 12 and the winding portion 40a along the upper surface 11b of the winding core portion 11, or the distance LD4 in the length direction Ld between the inner surface 13a of the second flange portion 13 and the winding portion 40a along the upper surface 11b of the winding core portion 11, or both. With this structure, the distance between the winding portion 40a and the land RX of the circuit board PX with the coil component 1 mounted on the circuit board PX is increased. Accordingly, the thermal effect on the winding portion 40a due to the land RX of the circuit board PX can be further reduced.
The distance LD2 in the length direction Ld between the inner surface 13a of the second flange portion 13 and the winding portion 40a along the bottom surface 11a of the winding core portion 11 is longer than the distance LD3 in the length direction Ld between the inner surface 12a of the first flange portion 12 and the winding portion 40a along the upper surface 11b of the winding core portion 11, or the distance LD4 in the length direction Ld between the inner surface 13a of the second flange portion 13 and the winding portion 40a along the upper surface 11b of the winding core portion 11, or both. Accordingly, the second flange portion 13 enables the thermal effect on the winding portion 40a due to the land RX of the circuit board PX to be further reduced as in the first flange portion 12.
(23) The distance in the length direction Ld between the winding portion 40a along the bottom surface 11a of the winding core portion 11 and the inner surface 13a of the second flange portion 13 is longer than the distance between the winding portion 40a along the bottom surface 11a of the winding core portion 11 and the inner surface 12a of the first flange portion 12. This structure ensures the space in which the first wire 41 and the second wire 42 extend from the winding portion 40a at the second extension portion 40c and the fourth extension portion 40e and increases the degree of freedom of the first wire 41 and the second wire 42 at the end of winding.
(24) The distance in the height direction Td between an end portion of the first flange portion 12 and the bottom surface 11a of the winding core portion 11 is longer than the distance in the height direction Td between the other end portion of the first flange portion 12 and the upper surface 11b of the winding core portion 11. With this structure, the distance in the height direction Td between the winding portion 40a and the circuit board PX with the coil component 1 mounted on the circuit board PX is increased. Accordingly, thermal effect on the winding portion 40a due to the circuit board PX can be further reduced. The structure of the second flange portion 13 may be the same as the structure of the first flange portion 12, and the thermal effect can be further reduced.
(25) The first wire 41 and the second wire 42 that form the first intersecting portions 44 intersect each other along the upper surface 11b of the winding core portion 11. With this structure, the distance in the height direction Td between the winding portion 40a and a main surface of the circuit board PX with the coil component 1 mounted on the circuit board PX is longer than that in the case where the first wire 41 and the second wire 42 that form the first intersecting portions 44 intersect each other along the bottom surface 11a of the winding core portion 11. Accordingly, thermal effect of the circuit board PX and the terminal electrodes 31 to 34 on the winding portion 40a can be further reduced when the coil component 1 is mounted on the circuit board PX.
Modification
The above embodiment is one of embodiments of a coil component and a method of manufacturing the coil component according to the present disclosure. There is no intention to limit the embodiments. The embodiments of the coil component and the method of manufacturing of the coil component according to the present disclosure can differ from the embodiment described above by way of example. One of the embodiments is obtained by replacing, modifying, or omitting a feature of the above embodiment, or by adding a new feature into the above embodiment. According to modifications described below, components common to those according to the above embodiment are designated by reference characters like to those according to the above embodiment, and a description thereof is omitted.
Modification Related to Shape of First Flange Portion and Shape of Second Flange Portion
According to the above embodiment, the protruding portions 15a and 15b may be omitted from the first flange portion 12. In this case, for example, the leg portions 14a and 14b are formed up to a region that contains the protruding portions 15a and 15b. In this case, the first end portion 41a of the first wire 41 is connected to the first bottom surface electrode 31a of the first terminal electrode 31 that is formed on the leg portion 14a, and the first end portion 42a of the second wire 42 is connected to the second bottom surface electrode 32a of the second terminal electrode 32 that is formed on the leg portion 14b.
According to the above embodiment, the protruding portions 19a and 19b may be omitted from the second flange portion 13. In this case, for example, the leg portions 18a and 18b are formed up to a region that contains the protruding portions 19a and 19b. In this case, the second end portion 41b of the first wire 41 is connected to the third bottom surface electrode 33a of the third terminal electrode 33 that is formed on the leg portion 18a, and the second end portion 42b of the second wire 42 is connected to the fourth bottom surface electrode 34a of the fourth terminal electrode 34 that is formed on the leg portion 18b.
According to the above embodiment, the inner surface 12a of a bottom part (end portion of the first flange portion 12 that protrudes toward the bottom surface 11a of the winding core portion 11) of the first flange portion 12 in the height direction Td, or a bottom part (end portion of the second flange portion 13 that protrudes toward the bottom surface 11a of the winding core portion 11) of the second flange portion 13 in the height direction Td, or both may extend in the height direction Td.
According to the above embodiment, the inner surface 12a of a top part (end portion of the first flange portion 12 that protrudes toward the upper surface 11b of the winding core portion 11) of the first flange portion 12 in the height direction Td, or a top part (end portion of the second flange portion 13 that protrudes toward the upper surface 11b of the winding core portion 11) of the second flange portion 13 in the height direction Td, or both may slope in the length direction Ld away from the winding core portion 11 while extending in the height direction Td away from the upper surface 11b.
Modification related to Connection among Winding Core Portion, First Flange Portion, and Second Flange Portion
According to the above embodiment, the shape of the first curved portion 22 that connects the inner surface 12a of the first flange portion 12 and the bottom surface 11a of the winding core portion 11 of the core 10 to each other, or the shape of the second curved portion 23 that connects the inner surface 13a of the second flange portion 13 and the bottom surface 11a of the winding core portion 11 to each other, or both can be freely changed. The curvature of the curve of the first curved portion 22 may vary at positions in the length direction Ld from the bottom surface 11a of the winding core portion 11 to the inner surface 12a of the first flange portion 12 in a section perpendicular to the width direction Wd. The variation in the curvature of the first curved portion 22 between the winding core portion 11 and the first flange portion 12 enables the deflection strength of the core 10 to be increased, and enables the length of the first flange portion 12 to be inhibited from being excessively decreased in the length direction Ld. Accordingly, the length of the first terminal electrode 31 is inhibited from being excessively decreased in the length direction Ld, and the coil component 1 can be appropriately mounted on the circuit board PX. The second curved portion 23 that has the same shape as the first curved portion 22 achieves the same effect.
For example, as illustrated in
As illustrated in
According to the above embodiment, the first curved portion 22 and the second curved portion 23 may have different shapes in a section parallel to the length direction Ld and to the height direction Td (perpendicular to the width direction Wd). For example, the first curved portion 22 or the second curved portion 23 has a curve of a substantially true-circular shape in a section perpendicular to the width direction Wd, and the curvature of the other curved portion of the first curved portion 22 and the second curved portion 23 varies in a section perpendicular to the width direction Wd as in the case of a substantially elliptic shape. The third curved portion 24 and the fourth curved portion 25 may have different shapes in a section perpendicular to the width direction Wd.
According to the above embodiment, the length of the first curved portion 22, or the second curved portion 23, or both in the height direction Td may be equal to or shorter than the lengths of the third curved portion 24 and of the fourth curved portion 25 in the height direction Td in a section perpendicular to the width direction Wd.
According to the above embodiment, the length of the first curved portion 22, or the second curved portion 23, or both in the length direction Ld may be equal to or shorter than the lengths of the third curved portion 24 and of the fourth curved portion 25 in the length direction Ld in a section perpendicular to the width direction Wd.
According to the above embodiment, the first curved portion 22 may be omitted from the connection between the inner surface 12a of the first flange portion 12 and the portion nearer than the center of the winding core portion 11 in the width direction Wd to the first side surface 12e of the first flange portion 12. In this case, for example, the bottom surface 11a of the winding core portion 11 is flush with the sloping portion 16 that corresponds to the portion nearer than the center of the winding core portion 11 in the width direction Wd to the first side surface 12e of the first flange portion 12.
According to the above embodiment, the second curved portion 23 may be omitted from the connection between the inner surface 13a of the second flange portion 13 and the portion nearer than the center of the winding core portion 11 in the width direction Wd to the second side surface 13f of the second flange portion 13. In this case, for example, the bottom surface 11a of the winding core portion 11 is flush with the sloping portion 20 that corresponds to the portion nearer than the center of the winding core portion 11 in the width direction Wd to the second side surface 13f of the second flange portion 13.
According to the above embodiment, when the ratio of the length of the first curved portion 22 in the height direction Td to the distance in the height direction Td between the bottom surface 11a of the winding core portion 11 and the first terminal electrode 31 is no less than 20% and less than 60% (i.e., from 20% to less than 60%), the ratio of the length of the second curved portion 23 in the height direction Td to the distance in the height direction Td between the bottom surface 11a of the winding core portion 11 and the third terminal electrode 33 may be less than 20% or larger than 60%.
According to the above embodiment, when the ratio of the length of the second curved portion 23 in the height direction Td to the distance in the height direction Td between the bottom surface 11a of the winding core portion 11 and the third terminal electrode 33 is no less than 20% and less than 60% (i.e., from 20% to less than 60%), the ratio of the length of the first curved portion 22 in the height direction Td to the distance in the height direction Td between the bottom surface 11a of the winding core portion 11 and the first terminal electrode 31 may be less than 20% or larger than 60%.
According to the above embodiment, the ratio of the length of the first curved portion 22 in the height direction Td to the distance in the height direction Td between the bottom surface 11a of the winding core portion 11 and the first terminal electrode 31, or the ratio of the length of the second curved portion 23 in the height direction Td to the distance in the height direction Td between the bottom surface 11a of the winding core portion 11 and the third terminal electrode 33, or both may be less than 20% or larger than 60%.
When the ratio of the length of the first curved portion 22 in the height direction Td to the distance in the height direction Td between the bottom surface 11a of the winding core portion 11 and the first terminal electrode 31 is less than 20% or larger than 60%, the curvature of the curve of the first curved portion 22 preferably varies at positions in the length direction Ld from the bottom surface 11a of the winding core portion 11 to the inner surface 12a of the first flange portion 12 in a section perpendicular to the width direction Wd.
When the ratio of the length of the second curved portion 23 in the height direction Td to the distance in the height direction Td between the bottom surface 11a of the winding core portion 11 and the third terminal electrode 33 is less than 20% or larger than 60%, the curvature of the curve of the second curved portion 23 preferably varies at positions in the length direction Ld from the bottom surface 11a of the winding core portion 11 to the inner surface 13a of the second flange portion 13 in a section perpendicular to the width direction Wd.
When the ratio of the length of the first curved portion 22 in the height direction Td to the distance in the height direction Td between the bottom surface 11a of the winding core portion 11 and the first terminal electrode 31 and the ratio of the length of the second curved portion 23 in the height direction Td to the distance in the height direction Td between the bottom surface 11a of the winding core portion 11 and the third terminal electrode 33 are less than 20% or larger than 60%, the curvature of the curve of the first curved portion 22 preferably varies at positions in the length direction Ld from the bottom surface 11a of the winding core portion 11 to the inner surface 12a of the first flange portion 12 in a section perpendicular to the width direction Wd. In addition, the curvature of the curve of the second curved portion 23 preferably varies at positions in the length direction Ld from the bottom surface 11a of the winding core portion 11 to the inner surface 13a of the second flange portion 13 in a section perpendicular to the width direction Wd.
According to the above embodiment, the ratio of the length of the third curved portion 24 in the height direction Td to the distance in the height direction Td between the upper surface 11b of the winding core portion 11 and the upper surface 12c of the first flange portion 12, or the ratio of the length of the fourth curved portion 25 in the height direction Td to the distance in the height direction Td between the upper surface 11b of the winding core portion 11 and the upper surface 13c of the second flange portion 13, or both may be no less than 20% and no more than 60% (i.e., from 20% to 60%). With this structure, when the ratio of the length of the third curved portion 24 in the height direction Td to the distance in the height direction Td between the upper surface 11b of the winding core portion 11 and the upper surface 12c of the first flange portion 12, or the ratio of the length of the fourth curved portion 25 in the height direction Td to the distance in the height direction Td between the upper surface 11b of the winding core portion 11 and the upper surface 13c of the second flange portion 13, or both are 20% or more, the length of the third curved portion 24, or the length of the fourth curved portion 25, or both can be increased, and the flexural strength between the winding core portion 11 and the first flange portion 12, or the flexural strength between the winding core portion 11 and the second flange portion 13, or both can be increased. Accordingly, the deflection strength of the core 10 can be increased. When the ratio of the length of the third curved portion 24 in the height direction Td to the distance in the height direction Td between the upper surface 11b of the winding core portion 11 and the upper surface 12c of the first flange portion 12, or the ratio of the length of the fourth curved portion 25 in the height direction Td to the distance in the height direction Td between the upper surface 11b of the winding core portion 11 and the upper surface 13c of the second flange portion 13, or both are 60% or less, the length of the first flange portion 12, or the length of the second flange portion 13, or both can be inhibited from being excessively decreased in the length direction Ld. Accordingly, the length of the upper surface 12c of the first flange portion 12 and the length of the upper surface 13c of the second flange portion 13 are inhibited from being excessively decreased in the length direction Ld, and the strength of adhesion between the core 10 and the plate member 50 can be ensured.
According to the above embodiment, the shape of the third curved portion 24, or the shape of the fourth curved portion 25, or both may be changed into a substantially elliptic shape as in the first curved portion 22 illustrated in
Modification Related to Connection Structures between First Flange Portion and Plate Member and between Second Flange Portion and Plate Member of Core
According to the above embodiment, the connection structures between the first flange portion 12 and the plate member 50 and between the second flange portion 13 and the plate member 50 can be freely changed.
In the first example, as illustrated in
In the second example, as illustrated in
In
As illustrated in
The position of the projecting portion 26 in the length direction Ld is not limited to the end portion of the upper surface 12c of the first flange portion 12 near the outer surface 12b or near the inner surface 12a and can be freely changed. For example, the projecting portion 26 may be disposed on the upper surface 12c of the first flange portion 12 at the center of the upper surface 12c in the length direction Ld. The structure of the second flange portion 13 can be the same as that of the first flange portion 12.
According to the modification illustrated in
In the first example, as illustrated in
In the case where the plate member 50 and the second flange portion 13 are secured to each other with the adhesive AH, the adhesive AH at the center in the width direction Wd between the first surface 51 of the plate member 50 and the upper surface 13c of the second flange portion 13 moves toward each end portion of the upper surface 13c of the second flange portion 13 in the width direction Wd at which the gap between the first surface 51 of the plate member 50 and the upper surface 13c of the second flange portion 13 increases. For this reason, the adhesive AH is inhibited from protruding to the outside of the core 10 and the plate member 50. The first flange portion 12 that has the same structure as that of the second flange portion 13 enables the adhesive AH to be further inhibited from protruding.
In the second example, as illustrated in
In the third example, as illustrated in
In the case where the plate member 50 and the second flange portion 13 are secured to each other with the adhesive AH, the adhesive AH between the projecting portions 27 on both end portions of the second flange portion 13 in the width direction Wd and the first surface 51 of the plate member 50 moves toward the center of the second flange portion 13 in the width direction Wd at which the length of the gap in the height direction Td between the first surface 51 of the plate member 50 and the second flange portion 13 increases. For this reason, the adhesive AH is inhibited from protruding to the outside of the core 10 and the plate member 50. The first flange portion 12 that has the same structure as that of the second flange portion 13 enables the adhesive AH to be further inhibited from protruding.
According to the above embodiment, the shape of the first flange portion 12 and the shape of the second flange portion 13 are changed to change the distance in the height direction Td between the upper surface 12c of the first flange portion 12 and the first surface 51 of the plate member 50 and the distance in the height direction Td between the upper surface 13c of the second flange portion 13 and the first surface 51 of the plate member 50. However, this is not a limitation. For example, the shape of the first surface 51 of the plate member 50 may be changed to change the distance in the height direction Td between the upper surface 12c of the first flange portion 12 and the first surface 51 of the plate member 50 and the distance in the height direction Td between the upper surface 13c of the second flange portion 13 and the first surface 51 of the plate member 50. Specifically, the portion of the first surface 51 of the plate member 50 that faces the first flange portion 12 in the height direction Td may slope so as to be gradually separated in the height direction Td from the upper surface 12c of the first flange portion 12 in the direction from the inner surface 12a of the first flange portion 12 to the outer surface 12b. The portion of the first surface 51 of the plate member 50 that faces the first flange portion 12 in the height direction Td may slope so as to be gradually separated in the height direction Td from the upper surface 12c of the first flange portion 12 in the direction from the outer surface 12b of the first flange portion 12 to the inner surface 12a. A projecting portion (not illustrated) that projects from the first surface 51 toward the upper surface 12c of the first flange portion 12 may be disposed on the portion of the first surface 51 of the plate member 50 that faces the first flange portion 12 in the height direction Td. The number and position of the projecting portion can be freely changed. The projecting portion may face the entire portion of the upper surface 12c of the first flange portion 12 in the width direction Wd or may face a part of the upper surface 12c of the first flange portion 12 in the width direction Wd. The projecting portion may face the entire portion of the upper surface 12c of the first flange portion 12 in the length direction Ld or may face a part of the upper surface 12c of the first flange portion 12 in the length direction Ld. The portion of the first surface 51 of the plate member 50 that faces the upper surface 13c of the second flange portion 13 in the height direction Td can be changed in the same manner as in the portion of the first surface 51 of the plate member 50 that faces the upper surface 12c of the first flange portion 12 in the height direction Td. With this structure, the second surface 52 of the plate member 50 can be kept flat, and the suction conveyance device can appropriately convey the coil component 1. The second surface 52 may have the same structure as that of the first surface 51 of the plate member 50. With this structure, there is no difference between the back and front of the plate member 50, it is not necessary to check the front and back of the plate member 50 in the plate member mounting step in which the plate member 50 is mounted on the core 10, and work can be inhibited from being complex.
According to the above embodiment, the distance in the height direction Td between the upper surface 12c of the first flange portion 12 or the upper surface 13c of the second flange portion 13 and the plate member 50 may vary in the length direction Ld and in the width direction Wd. With this structure, the adhesive AH can be inhibited from protruding to the outside of the core 10 and the plate member 50, and the inductance value can be more accurately set by adjusting the length of the magnetic circuit.
According to the above embodiment, the distance in the height direction Td between the upper surface 12c of the first flange portion 12 or the upper surface 13c of the second flange portion 13 and the plate member 50 may be constant in the length direction Ld and in the width direction Wd. Also, with this structure, the distance in the height direction Td between the other upper surface of the upper surface 12c of the first flange portion 12 and the upper surface 13c of the second flange portion 13, and the plate member 50 varies. Accordingly, when the plate member 50 is composed of a magnetic material, the magnetic circuit between the other flange portion of the first flange portion 12 and the second flange portion 13 and the plate member 50 is restricted. Accordingly, the variation in the length of the magnetic circuit in the coil component 1 is decreased, and the inductance value of the coil component 1 can be inhibited from varying.
According to the above embodiment, the distances in the height direction Td between the first flange portion 12 and the plate member 50 and between the second flange portion 13 and the plate member 50 may be constant in the length direction Ld and in the width direction Wd.
Modification Related to Recessed Portion of First Flange Portion and Recessed Portion of Second Flange Portion
According to the above embodiment, at least one shape of the shapes of the recessed portions 17a and 17b of the first flange portion 12 and the shapes of the recessed portions 21a and 21b of the second flange portion 13 can be freely changed.
In the first example, as illustrated in
In the second example, as illustrated in
In the third example, as illustrated in
In the first example and the third example, the length of the recessed portion 21a in the length direction Ld can be freely changed. The recessed portion 21a may extend from the inner surface 13a of the second flange portion 13 to a portion nearer than the outer surface 13b of the second flange portion 13 to the inner surface 13a in the length direction Ld. The recessed portion 21a may extend from the outer surface 13b of the second flange portion 13 to a portion nearer than the inner surface 13a of the second flange portion 13 to the outer surface 13b in the length direction Ld. The first flange portion 12 can have the same structure as that of the second flange portion 13.
According to the above embodiment, each of the shapes of the recessed portions 17a, 17b, 21a, and 21b is a substantially rectangular shape when viewed in the height direction Td but is not limited thereto. At least one of the shapes of the recessed portions 17a, 17b, 21a, and 21b when viewed in the height direction Td may be a shape other than a substantially rectangular shape, for example, a substantially polygonal shape such as a substantially circular shape, a substantially square shape, or a substantially quadrilateral shape.
According to the above embodiment, the depths of the recessed portions 17a and 17b are equal to the depths of the recessed portions 21a and 21b when viewed in the height direction Td but are not limited thereto. The depths of the recessed portions 17a and 17b may differ from the depths of the recessed portions 21a and 21b. The depth of the recessed portion 17a may differ from the depth of the recessed portion 17b when viewed in the height direction Td. The depth of the recessed portion 21a may differ from the depth of the recessed portion 21b.
According to the above embodiment, the depth of at least one of the recessed portions 17a, 17b, 21a, and 21b may vary in the length direction Ld and in the width direction Wd. According to the above embodiment, the positions of the recessed portions 17a and 17b of the first flange portion 12 can be freely changed. For example, at least one of the recessed portions 17a and 17b is formed on a portion of the first flange portion 12 that overlaps the winding core portion 11 when viewed in the length direction Ld.
According to the above embodiment, the positions of the recessed portions 21a and 21b of the second flange portion 13 can be freely changed. For example, at least one of the recessed portions 21a and 21b may be formed on a portion of the second flange portion 13 that overlaps the winding core portion 11 when viewed in the length direction Ld.
According to the above embodiment, at least one of the recessed portions 17a and 17b of the first flange portion 12 may be omitted. At least one of the recessed portions 21a and 21b of the second flange portion 13 may be omitted.
Modification Related to First Wire, Second Wire, and Winding Portion
According to the above embodiment, the shape of a connection between the second end portion 41b of the first wire 41 and the third bottom surface electrode 33a of the third terminal electrode 33 can be freely changed. In the first example, as illustrated in
In the second example, as illustrated in
In the third example, as illustrated in
According to the above embodiment, as illustrated in
According to the above embodiment, a portion of the second wire 42 from the extension portion 40b to the second bent portion 42d may be omitted. According to the above embodiment, in the coil 40, the first wire 41 and the second wire 42 are wound so as to form a layer around the winding core portion 11 but are not limited thereto. For example, in the coil 40, the first wire 41 and the second wire 42 are wound around outer side portions of the first wire 41 and the second wire 42 that are wound around the winding core portion 11 so as to form two layers of the winding portion.
As illustrated in
The first wire 41 at the fourth turn of the first winding portion 43A and the second wire 42 at the fourth turn of the first winding portion 43A intersect each other to form the first intersecting portion 44. Consequently, there is an inverse relationship between the positions of the first wire 41 and the second wire 42 in the length direction Ld at the fourth turn and the positions of the first wire 41 and the second wire 42 in the length direction Ld at the fifth turn.
As illustrated by two-dot chain lines in
According to the above embodiment, the winding portion 40a is formed in a manner in which the first wire 41 and the second wire 42 intersect each other whenever the first wire 41 and the second wire 42 are wound predetermined times but is not limited thereto. For example, the first intersecting portions 44 and the second intersecting portion 45 of the winding portion 40a, at which the first wire 41 and the second wire 42 intersect each other, may be omitted. That is, the winding portion 40a may include only the first winding portions 43.
According to the above embodiment, the first wire 41 and the second wire 42 intersect each other along the first side surface 11c of the winding core portion 11 at the end portion (end portion at the end of winding) of the winding portion 40a near the second flange portion 13 as illustrated in
According to the above embodiment, the first wire 41 and the second wire 42 intersect each other along the first side surface 11c of the winding core portion 11 at the end portion (end portion at the end of winding) of the winding portion 40a near the second flange portion 13. However, as illustrated in
In
According to the above embodiment, the second intersecting portion 45 is formed as a part of the first winding portion 43 that is formed on the end portion (end portion at the end of winding) of the winding portion 40a near the second flange portion 13 but is not limited thereto. For example, the second intersecting portion 45 may be formed such that the end portion (end portion at the end of winding) of the winding portion 40a near the second flange portion 13 is adjacent to the first winding portions 43 in the length direction Ld. In the case where the second intersecting portion 45 is formed near the end portion (end portion at the beginning of winding) of the winding portion 40a near the first flange portion 12, for example, the second intersecting portion 45 may be formed so as to be adjacent, in the length direction Ld, to the first winding portions 43 that is formed at the end portion of the winding portion 40a near the first flange portion 12.
According to the above embodiment, the first wire 41 and the second wire 42 that form the first intersecting portions 44 intersect each other along the upper surface 11b of the winding core portion 11 but are not limited thereto. For example, the first wire 41 and the second wire 42 that form the first intersecting portions 44 may intersect each other along the bottom surface 11a, the first side surface 11c, or the second side surface 11d of the winding core portion 11.
According to the above embodiment, the length LA of the winding portion 40a in the length direction Ld along the bottom surface 11a of the winding core portion 11 may be equal to or longer than the length LB of the winding portion 40a along the upper surface 11b of the winding core portion 11.
According to the above embodiment, the distance LD2 in the length direction Ld between the winding portion 40a along the bottom surface 11a of the winding core portion 11 and the inner surface 13a of the second flange portion 13 may be equal to or shorter than the distance LD1 in the length direction Ld between the winding portion 40a along the bottom surface 11a of the winding core portion 11 and the inner surface 12a of the first flange portion 12.
Modification Related to Terminal Electrode
According to the above embodiment, the lengths of the end surface electrodes 31b to 34b of the terminal electrodes 31 to 34 in the height direction Td can be freely changed. For example, as illustrated in
According to the above embodiment, the method of forming the first end surface electrode 31b of the first terminal electrode 31 and the second end surface electrode 32b of the second terminal electrode 32 may differ from the method of forming the third end surface electrode 33b of the third terminal electrode 33 and the fourth end surface electrode 34b of the fourth terminal electrode 34. For example, the first end surface electrode 31b and the second end surface electrode 32b may be formed by using the applicator 100, and the third end surface electrode 33b and the fourth end surface electrode 34b may be formed by screen printing. The third end surface electrode 33b and the fourth end surface electrode 34b may be formed by using the applicator 100, and the first end surface electrode 31b and the second end surface electrode 32b may be formed by screen printing. In this case, the first end surface electrode 31b and the second end surface electrode 32b or the third end surface electrode 33b and the fourth end surface electrode 34b are each formed to have an uneven shape. The method of forming the end surface electrodes 31b to 34b may be individually set. In this case, at least one of the end surface electrodes 31b to 34b is formed by using the applicator 100, and at least one of the end surface electrodes 31b to 34b is formed to have an uneven shape.
According to the above embodiment, at least one of the outer edges of the bottom surface electrodes 31a to 34a of the terminal electrodes 31 to 34 may has a straight portion. In short, it is only necessary for each of the outer edges of the bottom surface electrodes 31a to 34a to have a shape that includes no corner portion on which a stress is likely to concentrate.
According to the above embodiment, at least one of the outer edges of the end surface electrodes 31b to 34b of the terminal electrodes 31 to 34 may has a straight portion. In short, it is only necessary for each of the outer edges of the end surface electrode 31b to 34b to have a shape that has no corner portion on which a stress is likely to concentrate.
According to the above embodiment, at least one of the outer edges of the bottom surface electrodes 31a to 34a of the terminal electrodes 31 to 34 may be straight as a whole. That is, at least one of the outer edges of the bottom surface electrodes 31a to 34a may have a shape that has no convex curve.
According to the above embodiment, at least one of the outer edges of the end surface electrodes 31b to 34b of the terminal electrodes 31 to 34 may be straight as a whole. That is, at least one of the outer edges of the end surface electrode 31b to 34b may have a shape that has no convex curve.
According to the above embodiment, the relationship between the lengths of the end surface electrodes 31b to 34b of the terminal electrodes 31 to 34 in the height direction Td and the lengths thereof in the width direction Wd can be freely changed. The length of at least one of the end surface electrodes 31b to 34b in the height direction Td may be equal to or shorter than the length thereof in the width direction Wd.
According to the above embodiment, the end surface electrodes 31b to 34b of the terminal electrodes 31 to 34 may be omitted. According to the above embodiment, the plate member 50 may be omitted.
According to the above embodiment, after the end surface electrodes 31b to 34b of the terminal electrodes 31 to 34 are formed by using the applicator 100, the bottom surface electrodes 31a to 34a of the terminal electrodes 31 to 34 are formed by using the dip coating device 110. However, this is not a limitation. After the bottom surface electrodes 31a to 34a are formed by using the dip coating device 110, the end surface electrodes 31b to 34b may be formed by using the applicator 100. In this case, the end surface electrodes 31b to 34b are formed on the outer side portions of the bottom surface electrodes 31a to 34a at positions at which the bottom surface electrodes 31a to 34a and the end surface electrodes 31b to 34b overlap.
According to the above embodiment, the end surface electrodes 31b to 34b of the terminal electrodes 31 to 34 are formed by using the applicator 100. However, the method of forming the end surface electrodes 31b to 34b is not limited thereto. For example, the end surface electrodes 31b to 34b of the terminal electrodes 31 to 34 may be formed by using a screen-printing device.
In the end surface electrode formation step according to the above embodiment, the number of the applied portions 35 in a row in the width direction Wd may differ from the number of the applied portions 35 in a column in the height direction Td. For example, the number of the applied portions 35 in a row in the width direction Wd may gradually increase in the direction toward the bottom surface 12d of the first flange portion 12 and in the direction toward the bottom surface 13d of the second flange portion 13.
While preferred embodiments of the disclosure have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing from the scope and spirit of the disclosure. The scope of the disclosure, therefore, is to be determined solely by the following claims.
Number | Date | Country | Kind |
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2019-080206 | Apr 2019 | JP | national |
This application is a Divisional of U.S. patent application Ser. No. 16/850,891, filed Apr. 16, 2020, which claims benefit of priority to Japanese Patent Application No. 2019-080206, filed Apr. 19, 2019, the entire content of which is incorporated herein by reference.
Number | Date | Country | |
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Parent | 16850891 | Apr 2020 | US |
Child | 18504533 | US |