JP2008041924A - Inductor, and its manufacturing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inductor capable of certainly performing a positioning between a first core and a second core, while the inductor being simply constituted. <P>SOLUTION: The inductor is equipped with: a coil 40; a first core 20 in which a pillar leg 24 is vertically arranged with an air core of the coil 40 threaded therethrough from a plate 21, an outer wall core 23 is vertically arranged from the plate 21 in the state of surrounding this pillar leg 24, and a first core positioning 23d is provided at the outer wall core 23; a second core 30 a second core positioning portion 32 is provided in peripheries of a plate state; and a connection terminal 50 in which a first terminal positioning portion 52 is provided for carrying out a positioning to the first core 20 by engaging with the first core positioning portion 23d, and a second terminal positioning portion 53 is provided for carrying out a positioning to the second core 30 by engaging with the second core positioning portion 32. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an inductor mounted on various electronic devices and an inductor manufacturing method.

  Among the inductors included in various electronic devices, there are various types such as EE type, EI type, EP-EP type, EP-I type, type using POT core, type using ring core and drum core, etc. Types exist. Among these types, there is a configuration in which the coil is disposed in the internal space formed by the core and the terminal is disposed on the outer peripheral surface of the core. Among those adopting such a configuration, an EE type is disclosed in Patent Document 1.

Japanese Patent Laying-Open No. 2006-41418 (see abstract, FIG. 1, FIG. 2, etc.)

  By the way, among the above-described types of inductors, the EI type inductor has a problem that it is difficult to position the I type core with respect to the E type core. That is, since the I-type core is a flat core, the E-type core is likely to be displaced in the plane direction.

  Therefore, for example, a method of providing a convex portion on the E-type core or the I-type core and performing positioning using this convex portion, or a method of performing positioning using a tool is adopted. Is also possible. However, when these methods are adopted, the advantage in cost is lost when compared with the type using the EP type and the POT core, which is the merit of the EI type inductor. Similarly, the merit that the winding frame can be enlarged as compared with the type using the ring core and the drum core is also lost.

  Here, in the configuration of Patent Document 1, since the two cores are both E-shaped cores, a certain positioning is achieved by inserting the column bases of these E-shaped cores into the air core of the coil. It is possible to do. However, in the E-I type inductor, the I-type core does not include the column base, and therefore cannot be positioned using the technique of Patent Document 1. Therefore, it is difficult to solve the above-described problem of misalignment even with reference to the configuration disclosed in Patent Document 1.

  The present invention has been made on the basis of the above circumstances, and an object of the present invention is an inductor capable of surely positioning between the first core and the second core while having a simple configuration. The present invention also aims to provide an inductor manufacturing method for manufacturing the inductor.

  In order to solve the above-mentioned problems, the present invention has a coil constituted by winding a conducting wire and a plate portion, and a column base portion through which an air core portion of the coil is inserted is erected from the plate portion. And a first core in which the outer wall core portion is erected from the plate portion in a state surrounding the column base portion, and the first core positioning portion is provided on the outer wall core portion, and in a flat plate shape A second core provided with a second core positioning portion on the flat peripheral edge, and a first core for positioning with respect to the first core by engaging with the first core positioning portion. And a connection terminal provided with a second terminal positioning portion for engaging with the second core positioning portion and positioning with respect to the second core. To do.

  In such a configuration, the first core positioning portion and the first terminal positioning portion are engaged, and both are attached in this state, so that the positioning between the first core and the connection terminal is achieved. Is done. Further, the second core positioning portion and the second terminal positioning portion are engaged, and both are attached in this state, whereby positioning between the second core and the connection terminal is performed. That is, the first core and the second core are each positioned with respect to the connection terminal. For this reason, a 1st core and a 2nd core will be in the state mutually positioned via a connection terminal. Therefore, it is possible to reliably and easily position the second core (I-type core), which has heretofore been difficult to position with respect to the first core.

  Moreover, compared with the structure which forms an unevenness | corrugation between a 1st core and a 2nd core, and positions between a 1st core and a 2nd core by fitting of these unevenness | corrugations, Manufacturing costs can be reduced. Furthermore, compared with the case where positioning between a 1st core and a 2nd core is performed using a tool, it becomes possible to simplify a process and to reduce manufacturing cost.

  In addition, since the first core is provided with the outer wall core portion standing from the plate portion, the winding frame can be made larger than the type using the ring core and the drum core. That is, when using a ring core, in order to ensure the strength of the ring core, it is necessary to ensure a thickness greater than or equal to a predetermined thickness, but in the case of a configuration in which the outer wall core portion is erected from the plate portion as in the present invention, It is possible to reduce the thickness of unnecessary portions of the outer wall core portion.

  In the case of a type using a ring core and a drum core, a coil is wound around the winding frame in accordance with the diameter of the flange portion of the drum core. Here, when the diameters of the upper and lower flange portions of the drum core are different (in the case of unequal wrinkles), the coil is wound around the winding frame so as to correspond to the flange portion having a small diameter. Here, the flange portion having a small diameter cannot be provided with a large winding portion because it is disposed with a predetermined gap with respect to the inner wall of the ring core. However, when the coil is disposed between the column base portion and the outer wall core portion as in the present invention, the conductive wire can be wound until reaching the inner wall of the outer wall core portion, and the winding portion is enlarged. It becomes possible to take.

  According to another invention, in addition to the above-described invention, the connection terminal is arranged along the outer peripheral surface when the first core and the second core are overlapped.

  In such a configuration, the connection terminals can be easily attached. Moreover, it becomes possible to position between the 1st core and the 2nd core only by attaching a connection terminal along an outer peripheral surface.

  Furthermore, another invention is formed by winding a conductive wire with a first core in which a column base portion is erected from a plate portion and an outer wall core portion is erected so as to surround the column base portion. An inductor manufacturing method for manufacturing an inductor comprising a coil, a second core provided in a flat plate shape, and a connection terminal, the first core positioning provided in an outer wall core portion A first joining step in which the first terminal positioning part provided in the connection terminal is engaged with the part, and the first core and the connection terminal are joined in a state of being positioned by this engagement. A coil attachment step of inserting an air core portion into the column base and disposing the coil on the first core, and joining the terminal of the coil in a state of being electrically conductive to the connection terminal; Provided on the flat peripheral edge of the core The second core positioning part is engaged with the second terminal positioning part provided in the connection terminal, and the second core and the connection terminal are joined in a state of being positioned by this engagement. A second joining step.

  In such a configuration, the first core positioning portion and the first terminal positioning portion are engaged, and both are attached in this state, so that the positioning between the first core and the connection terminal is achieved. Is done. Further, the second core positioning portion and the second terminal positioning portion are engaged, and both are attached in this state, whereby positioning between the second core and the connection terminal is performed. That is, the first core and the second core are each positioned with respect to the connection terminal. For this reason, a 1st core and a 2nd core will be in the state mutually positioned via a connection terminal. Therefore, it is possible to reliably and easily position the second core (I-type core), which has heretofore been difficult to position with respect to the first core.

  In addition, a conventional method is used to form irregularities between the first core and the second core, and positioning between the first core and the second core is performed by fitting these irregularities. Compared with the configuration, the manufacturing cost can be reduced. Furthermore, the process can be simplified and the manufacturing cost can be reduced as compared with the case where the positioning between the first core and the second core, which is conventionally performed, is performed using a jig. Is possible.

  In addition, since the first core is provided with the outer wall core portion standing from the plate portion, the winding frame can be made larger than the type using the ring core and the drum core. That is, when using a ring core, in order to ensure the strength of the ring core, it is necessary to ensure a thickness greater than or equal to a predetermined thickness, but in the case of a configuration in which the outer wall core portion is erected from the plate portion as in the present invention, It is possible to reduce the thickness of unnecessary portions of the outer wall core portion.

  In the case of a type using a ring core and a drum core, a coil is wound around the winding frame in accordance with the diameter of the flange portion of the drum core. Here, when the diameters of the upper and lower flange portions of the drum core are different (in the case of unequal wrinkles), the coil is wound around the winding frame so as to correspond to the flange portion having a small diameter. Here, the flange portion having a small diameter cannot be provided with a large winding portion because it is disposed with a predetermined gap with respect to the inner wall of the ring core. However, when the coil is disposed between the column base portion and the outer wall core portion as in the present invention, the conductive wire can be wound until reaching the inner wall of the outer wall core portion, and the winding portion is enlarged. It becomes possible to take.

  According to the present invention, the inductor can be reliably positioned between the first core and the second core while having a simple configuration.

  Hereinafter, an inductor 10 according to an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a perspective view showing the overall configuration of inductor 10 in the present embodiment. FIG. 2 is a bottom view showing the configuration of the inductor 10.

  In the following embodiments, the upper side refers to the side where the I-type core 30 is provided when viewed from the E-type core 20, and the lower side refers to the opposite side of the I-type core 30. The side where the E-type core 20 is provided. Further, one side (one end side) refers to the side on which the plate portion 21 and the like taper due to the presence of a slope 21b and the like described later, and the other side (the other end side) refers to the opposite side.

  As shown in FIG. 1 and the like, the inductor 10 includes an E-type core 20, an I-type core 30, a coil 40, and a connection terminal 50.

  Of these, the E-type core 20 corresponds to the first core. As shown in FIG. 3, the E-type core 20 includes a plate portion 21, an outer wall core portion 23, and a column base portion 24. Among these, the plate part 21 is a part provided in plate shape, and the outer wall core part 23 and the column base part 24 which are mentioned later stand from the upper surface 21a. In the present embodiment, of the planar shape of the plate portion 21, two corners located on one side in the Y direction in FIG. 3 (the side from which a terminal 42 to be described later is pulled out) are in the X direction and the Y direction. It is cut away so as to be diagonal. Thereby, a slope 21b is provided on one side in the Y direction.

  In the present embodiment, the angle formed by the slope 21b with the X direction and the Y direction is approximately 45 degrees. Further, the outer peripheral surface 21c along the X direction in FIG. 3 is provided so that the length dimension is longer than that of the inclined surface 21b. In the present embodiment, each of the slopes 21b is divided into two. Of the two slopes 21b, the slope 21b located at the end in the X-axis direction is provided so as to be flush with a slope 23e of the outer wall core part 23 described later.

  Further, as shown in FIG. 2, a pair of lower surface recesses 22 are provided on the lower surface 21 d of the plate portion 21 along the X-axis direction. The lower surface recess 22 corresponds to the first core positioning portion. The lower surface recess 22 is a portion that is recessed upward from the other portions of the lower surface 21d, and is provided so that the planar shape thereof is rectangular. Further, the pair of lower surface recesses 22 are provided apart from each other by a predetermined distance. Also, a mounting terminal portion 52 described later enters the lower surface recess 22. Here, the depth dimension of the lower surface recess 22 is provided such that when the mounting terminal portion 52 enters, the mounting terminal portion 52 slightly protrudes downward.

  An outer wall core portion 23 is provided on the upper surface 21a of the plate portion 21 so as to protrude upward. A pair of the outer wall core portions 23 is provided along the X-axis direction in FIG. Further, as shown in FIG. 3, the outer wall core portion 23 is provided so that the outer edge thereof is flush with the plate portion 21. Moreover, of the outer wall core portion 23, the opposite sides (inner wall side) face the column base 24. A ring-shaped groove 25 for allowing the coil 40 to enter is formed on the inner wall side of the outer wall core portion 23 and the outer wall side of the column base portion 24.

  Note that the outer wall core portion 23 is not continuous in the entire circumferential direction of the plate portion 21. Therefore, in the E-type core 20, the outer wall core portion 23 is interrupted on one side and the other side in the Y-axis direction in FIG. 3, and the coil 40 disposed in the ring-shaped groove 25 is exposed to the outside. In the present embodiment, an I-type core 30 described later is placed on the upper surface 23 a of the outer wall core portion 23.

  Further, the end 23b on the one end side of the outer wall core portion 23 is provided so as to be separated from the outer peripheral surface 21c along the X-axis direction by a predetermined dimension. And the terminal 42 is provided between the outer peripheral surface 21c and the edge part 23b so that positioning is possible.

  Here, in the present embodiment, a terminal mounting portion 23d is provided between the plate portion 21 and the outer wall core portion 23 in a state where the outer peripheral surface 23c is depressed by a predetermined amount. The connection terminal 50 is disposed in the terminal mounting portion 23d. Therefore, one end side of the terminal mounting portion 23d is continuous with the inclined surface 21b. Further, the terminal mounting portion 23d is positioned substantially the same as the lower surface recess 22 in the Y-axis direction shown in FIG. 1 (in FIG. 1, the terminal mounting portion 23d is slightly more in the Y-axis direction than the lower surface recess 22). It is located on the end side.) The terminal mounting portion 23d is provided so as to be recessed by a predetermined amount as compared to the outer peripheral surface other than the terminal mounting portion 23d (the outer peripheral surface located on the other end side of the outer peripheral surface of the outer wall core portion 23).

  The outer wall core portion 23 is also provided with a slope 23e similar to the slope 21b described above. The slope 23e is provided so as to be flush with the slope 21b.

  Further, a column base portion 24 is provided in a substantially central portion of the upper surface 21 a of the plate portion 21. The upper surface 24 a of the column base portion 24 is provided with a height dimension lower than that of the upper surface 23 a of the outer wall core portion 23. Here, in this Embodiment, the column base part 24 is provided with the external appearance in the column shape. Therefore, a ring-shaped groove 25 is provided between the outer wall surface of the columnar column base portion 24 and the inner wall surface of the outer wall core portion 23. In addition, the width dimension provided in the concave shape of this ring-shaped groove | channel 25 is provided in a magnitude | size large enough for the winding part of the coil 40 mentioned later to enter.

  In addition, the I-type core 30 is placed on the upper surface 23a of the outer wall core portion 23 described above. The I-shaped core 30 is provided so that its planar shape is substantially the same as that of the plate portion 21 described above. The lower surface 30 b of the I-type core 30 is placed on the upper surface 23 a of the outer wall core portion 23. Thereby, the ring-shaped groove 25 and the coil 40 disposed in the ring-shaped groove 25 are surrounded by the E-type core 20 and the I-type core 30. Further, when the I-type core 30 is in contact with the upper surface 23 a, a gap (not shown) is formed between the upper surface 24 a of the column base 24 and the lower surface 30 b of the I-type core 30. This gap functions as a magnetic gap.

  In addition, by being surrounded by the E-type core 20 and the I-type core 30, an opening T that communicates with the ring-shaped groove 25 is provided on one side and the other side in the Y-axis direction in FIG. 1. . The coil 40 can be visually recognized from the outside through the opening T. Moreover, the terminal 42 mentioned later is pulled out from the opening part T1 of one side. Further, as described above, since the I-type core 30 has substantially the same planar shape as the plate portion 21, the I-type core 30 also has an inclined surface 30c.

  Here, the upper surface 30a and the lower surface 30b of the I-type core 30 are provided in a planar shape, and there is no unevenness. However, a positioning recess 32 is provided on the outer peripheral surface 31 of the I-type core 30 (see FIG. 4). The positioning recess 32 corresponds to the second core positioning portion. Further, a positioning portion 53 described later is located in the positioning recess 32. Therefore, the positioning recess 32 is formed by slightly denting the other part of the outer peripheral surface 31. Here, in the present embodiment, the positioning recess 32 is provided so as to have a substantially rectangular appearance, and is provided so as to penetrate the outer peripheral surface 31 of the I-type core 30. Further, the positioning recess 32 is provided at a position substantially the same as the lower surface recess 22 in the Y-axis direction shown in FIG. In the present embodiment, the other end side of the positioning recess 32 and the other end side of the terminal mounting portion 23d are provided so that their positions in the Y-axis direction are substantially the same as shown in FIG. It has been.

  In addition, the part except the positioning recessed part 32 among the outer peripheral surfaces 31 in which the positioning recessed part 32 exists is in a state of projecting relative to the positioning recessed part 32. Therefore, in the following description, the outer peripheral surface 31 that protrudes with respect to the positioning concave portion 32 is referred to as a positioning convex portion 33.

  Moreover, the coil 40 (refer FIG. 5) arrange | positioned at the ring-shaped groove | channel 25 is comprised by winding the rectangular wire 41 as a conducting wire by predetermined number of turns. Here, in the present embodiment, the coil 40 holds the terminal 42 of the rectangular wire 41 having a predetermined length, and is provided in a substantially central portion of the rectangular wire 41 in a cylindrical shape, for example. Arrange the jigs and tools. Then, while holding the two terminals 42, the two terminals 42 are moved along the periphery of the tool so that the rectangular wire 41 is wound around the tool. In this winding, one terminal 42 is wound clockwise and the other terminal 42 is wound counterclockwise. By performing such winding for a predetermined number of turns, a so-called double flat winding (also referred to as α winding) coil 40 is formed.

  The coil 40 is not limited to the configuration in which the flat wire 41 is wound, and a configuration in which a round wire is wound may be employed. The winding method of the coil 40 is not limited to double flat winding, and other winding methods (for example, edgewise winding) may be employed.

  Both ends 42 of the coil 40 are drawn from the opening T1. And this terminal 42 is connected in the state which can be electrically connected with the terminal connection part 54 of the connection terminal 50 via solder etc., for example. In FIG. 1, a solder build-up portion P for fixing the terminal 42 and the connection terminal 50 is shown.

  Moreover, the connection terminal 50 as shown in FIG. 6 is arrange | positioned at the above-mentioned terminal attachment part 23d. The connection terminal 50 includes an outer peripheral extending part 51, a mounting terminal part 52, a positioning part 53, and a terminal connection part 54. In addition, the above-mentioned each part is formed in the connection terminal 50, for example by performing press work, such as punching a metal plate into a predetermined shape and bending.

  Out of these portions, the outer peripheral extending portion 51 is a portion disposed on the terminal attachment portion 23d. Here, the outer peripheral extending portion 51 is attached in a state where the mounting terminal portion 52 and the positioning portion 53 enter the lower surface concave portion 22 and the positioning concave portion 32, respectively. In order to realize such penetration, it is preferable that the outer peripheral extending portion 51 is in a state of being surface-bonded to the terminal mounting portion 23d. However, the outer peripheral extending portion 51 and the terminal attaching portion 23d may be attached in a state having a slight gap.

  Normally, an adhesive is interposed between the outer peripheral extending portion 51 and the terminal attachment portion 23d, and attachment and fixing between the E-type core 20 and the connection terminal 50 are performed. Further, in a state where the outer peripheral extending portion 51 is attached to the terminal attaching portion 23 d, the upper edge portion of the outer peripheral extending portion 51 may be provided so as to contact the edge side of the lower surface 30 b of the I-type core 30.

  Further, the mounting terminal portion 52 corresponds to the first terminal positioning portion. As shown in FIGS. 1 and 2, the mounting terminal portion 52 is provided so as to enter the lower surface recess 22 in a state where the outer peripheral extending portion 51 is attached to the terminal attaching portion 23 d. The mounting terminal portion 52 is bent in a state of being substantially perpendicular to the outer peripheral extending portion 51 and attached in a state of being substantially horizontal to the lower surface 21d. The mounting terminal portion 52 has a length dimension corresponding to the entry into the lower surface recess 22 described above, and is longer than the positioning portion 53. Further, a connecting portion 52 a that is flush with the outer peripheral extending portion 51 is provided between the outer peripheral extending portion 51 and the mounting terminal portion 52. However, you may employ | adopt the structure in which this connection part 52a does not exist.

  Further, the positioning portion 53 corresponds to the second terminal positioning portion and is provided flush with the outer peripheral extending portion 51. The positioning portion 53 is a portion that enters the positioning recess 32. Positioning between the E-type core 20 and the I-type core 30 is achieved by the presence of the positioning portion 53, the outer peripheral extending portion 51, and the mounting terminal portion 52. Here, the positioning portion 53 has a substantially rectangular external appearance, and the width dimension thereof is provided so as to correspond to the width dimension of the positioning recess 32 so as not to prevent entry. In addition, the length dimension of the positioning portion 53 in the height direction is provided to be shorter than the length dimension of the positioning recess 32. As a result, even if the positioning portion 53 is inserted into the positioning recess 32, the positioning portion 53 does not protrude upward.

  Further, the outer peripheral extending portion 51 is provided with a terminal connection portion 54 in a continuous state. The terminal connection portion 54 is a portion to which the terminal 42 is coupled, and is bent at a predetermined angle with respect to the outer peripheral extending portion 51. In addition, the angle which this terminal connection part 54 makes with respect to the outer periphery extension part 51 is equivalent to about 45 degree | times which is an angle which the above-mentioned slope 21b makes with respect to an X-axis and a Y-axis. Here, in the present embodiment, the terminal connection portion 54 is provided such that its lower edge side has the same height as the lower edge side of the outer peripheral extension portion 51. However, the upper edge side of the terminal connection portion 54 is provided to be higher than the upper edge side of the outer peripheral extending portion 51. That is, of the upper edge side of the terminal connecting portion 54, the portion on the outer peripheral extending portion 51 side is provided in a tapered shape so as to gradually increase toward the one side of the Y axis. The height dimension is provided so as not to change in parallel with the lower edge side.

  Further, the terminal connecting portion 54 has a punched portion 540. The punched portion 540 is provided between one end side and the other end side of the terminal connection portion 54. Due to the presence of the punched portion 540, the portion on one end side of the terminal connection portion 54 is branched upward and downward.

  In addition, the width dimension differs between the part branched to the upper side and the part branched to the lower side. Among these branched portions having different width dimensions, the side having the larger width dimension is the wide branch portion 541 and the side having the smaller width dimension is the narrow branch portion 542. Further, in the present embodiment, in the terminal connection portion 54a located on the right side in FIG. 6, the wide branch portion 541 is located below and the narrow branch portion 542 is located above. In FIG. 6, in the terminal connection part 54b located on the left side, the wide branch part 541 is located above and the narrow branch part 542 is located below. By adopting such a configuration for the terminal connection unit 54, each of the terminal connection units 54a and 54b can be satisfactorily connected to the two terminals 42 having different height positions.

  In the present embodiment, the locking protrusion 543 protrudes from the distal end side of the portion facing the punched portion 540 in the wide branch portion 541. The locking projection 543 protrudes from the wide branch portion 541 toward the narrow branch portion 542 by a predetermined height. The width dimension of the locking projection 543 is formed so as not to prevent the terminal 42 from entering.

  Further, due to the presence of the locking projection 543, the width dimension of the opening 544 between the distal end of the locking projection 543 and the narrow branch portion 542 is provided to be narrower than the width dimension of the terminal 42. Yes. Therefore, when the terminal 42 is inserted into the punched portion 540, even if a force in a direction to release the winding of the coil 40 acts on the terminal 42, it is possible to prevent the terminal 42 from moving due to the force. . Thereby, it is possible to prevent the terminal 42 from coming out of the punched portion 540.

  And the terminal connection part 54 and the terminal 42 are fixed by soldering etc. in the state which made the terminal 42 enter in the above-mentioned punching part 540. FIG. Thereby, the coil 40 and the connection terminal 50 are electrically connected.

  A case where the inductor 10 having the above configuration is manufactured will be described below. First, the connection terminal 50 is attached and fixed to the E-type core 20. At the time of mounting and fixing, an adhesive is applied to the outer peripheral extending portion 51 and an adhesive is also applied to the mounting terminal portion 52. After the application of the adhesive, the outer peripheral extending portion 51 and the terminal mounting portion 23d are aligned and brought into surface contact, and the mounting terminal portion 52 and the lower surface recess 22 are aligned and brought into surface contact. When the predetermined time has elapsed and the adhesive is cured, the connection terminal 50 is attached and fixed to the E-type core 20.

  Note that when the mounting terminal portion 52 is inserted into the lower surface recess 22, the other end side of the outer peripheral extending portion 51 comes close to the other end side of the terminal mounting portion 23 d. Further, the application of the adhesive is not limited to the outer peripheral extending portion 51 and the mounting terminal portion 52, and may be applied to the terminal attaching portion 23 d and the lower surface concave portion 22. Further, an adhesive may be interposed between the slope 23e and the terminal connection portion 54.

  Further, in a state where the connection terminal 50 is attached and fixed, the positioning portion 53 protrudes upward from the upper surface 23a, and the outer peripheral extending portion 51 is provided in a state of not protruding upward from the upper surface 23a. .

  The coil 40 is arranged with respect to the ring-shaped groove 25 in a state where the positioning between the E-shaped core 20 and the connection terminal 50 is performed. In this case, the coil 40 wound in advance by a predetermined number of turns is arranged in a state in which the terminal 42 protrudes from the opening T1 on one side. Then, the terminal 42 of the coil 40 is inserted into the punched portion 540. Thereafter, the terminal connection portion 54 and the terminal 42 are attached and fixed in a state of being electrically connected to each other, for example, by soldering.

  Prior to the attachment of the E-type core 20 and the connection terminal 50, the coil 40 is arranged on the E-type core 20, and after the arrangement of the coil 40, the terminal 42 is inserted into the punched portion 540, You may make it perform the attachment fixation between the connection terminals 50. FIG.

  Subsequently, the I-type core 30 is attached and fixed. In this case, the adhesive is applied to the upper surface 23 a and the adhesive is also applied to the positioning portion 53. Then, the positioning portion 53 is inserted into the positioning recess 32 and both are brought into surface contact. When a predetermined time elapses in this state and the adhesive is cured, the I-type core 30 is attached and fixed to the connection terminal 50 and the E-type core 20. The application of the adhesive is not limited to the upper surface 23a and the positioning portion 53, and may be applied to the lower surface 30b and the positioning recess 32. Further, an adhesive may be interposed between the inclined surface 30c and the terminal connection portion 54. As described above, the inductor 10 is formed.

  According to the inductor 10 having such a configuration, the E-type core 20 and the I-type core 30 are positioned with respect to the connection terminal 50, respectively. For this reason, the E-type core 20 and the I-type core 30 are positioned with respect to each other via the connection terminal 50. Therefore, positioning of the I-type core 30 that has been difficult to position with respect to the E-type core 20 can be reliably and easily performed. Moreover, since both cores 20 and 30 are positioned with respect to the metal connection terminal 50 which is easy to produce processing accuracy compared with positioning of the cores which processing accuracy is difficult to produce, positional accuracy becomes high and it becomes easy to assemble.

  In addition, the process can be simplified and the manufacturing cost can be reduced as compared with the case where the positioning between the E-type core 20 and the I-type core 30 is performed using a jig tool. .

  Further, in addition to being easy to position as described above, the E-type core 20 is provided with an outer wall core portion 23 erected from the plate portion 21, so that a type using a ring core and a drum core is used. In comparison, the reel can be enlarged. That is, when a ring core is used, it is necessary to ensure a thickness greater than a predetermined thickness in order to ensure the strength of the ring core. However, in the configuration in which the outer wall core portion 23 is erected from the plate portion 21 as in the present invention, it is possible to reduce the thickness of unnecessary portions of the outer wall core portion 23.

  In the case of a type using a ring core and a drum core, a coil is wound around the winding frame in accordance with the diameter of the flange portion of the drum core. Here, when the diameters of the upper and lower flange portions of the drum core are different (in the case of unequal wrinkles), the coil is wound around the winding frame so as to correspond to the flange portion having a small diameter. In addition, the flange portion having a small diameter cannot be provided with a large winding portion because it is disposed with a predetermined gap with respect to the inner wall of the ring core. However, when the coil 40 is disposed in the ring-shaped groove 25 between the column base portion 24 and the outer wall core portion 23 as in the present invention, the flat wire 41 is wound until reaching the inner wall of the outer wall core portion 23. It becomes possible to make the winding part large.

  The connection terminal 50 is disposed along the outer peripheral surface (the terminal attachment portion 23d, the positioning recess 32, etc.) when the E-type core 20 and the I-type core 30 are overlapped. Therefore, attachment of the connection terminal 50 becomes easy. Moreover, it becomes possible to position between the E-type core 20 and the I-type core 30 only by attaching the connection terminal 50 along the outer peripheral surface.

  Although the inductor 10 according to the embodiment of the present invention has been described above, the present invention can be variously modified in addition to this. This will be described below.

  In the above-described embodiment, the case where the E-type core 30 including the two openings T is used as the first core has been described. However, the first core is not limited to the configuration including two openings, and may be configured to include only one opening. Further, the first core may have a configuration including three or more openings.

  Moreover, in the above-mentioned embodiment, the case where only one coil 40 exists is shown. However, the number of coils 40 is not limited to one, and a configuration in which two or more coils 40 are arranged may be employed.

  In the above-described embodiment, the plate portion 21 and the I-type core 30 protrude with the inclined surfaces 21b and 30c on one side of the Y axis. However, the plate portion 21 and the I-type core 30 may be provided in a rectangular shape instead of the state having the inclined surfaces 21b and 30c.

  In the above-described embodiment, the positioning recess 32 is provided in the I-type core 30 and the positioning portion 53 is provided in the connection terminal 50. However, the concavo-convex relationship between the I-type core 30 and the connection terminal 50 may be reversed.

  In addition, the positioning between the E-type core 20 and the connection terminal 50 is not limited to the configuration performed between the lower surface recess 22 and the mounting terminal portion 52. For example, the first core positioning portion is connected to the terminal mounting portion 23d. In addition, a convex portion or a concave portion corresponding to the first terminal positioning portion may be provided in the outer peripheral extending portion 51.

  The inductor 10 according to the above-described embodiment can be used for various applications such as a transformer and a noise filter.

  The inductor of the present invention can be used in the field of electrical equipment.

It is a perspective view which shows the structure of the inductor which concerns on one embodiment of this invention. It is a bottom view which shows the structure of the inductor of FIG. It is a perspective view which shows the structure of an E-type core among the inductors of FIG. It is a top view which shows the structure of an I-type core among the inductors of FIG. FIG. 2 is a perspective view showing a state where an I-type core is removed and a soldered portion is removed from the inductor of FIG. 1. FIG. 2 is a perspective view illustrating a configuration of a pair of connection terminals in the inductor of FIG. 1.

Explanation of symbols

10 ... Inductor 20 ... E type core (corresponding to the first core)
21 ... Plate part 22 ... Lower surface recess (corresponding to the first core positioning part)
23 ... Outer wall core 24 ... Column base 25 ... Ring-shaped groove 30 ... I-type core (corresponding to the second core)
32 ... Positioning recess (corresponding to the second core positioning part)
33 ... Positioning convex part 40 ... Coil 41 ... Flat wire (corresponding to conducting wire)
50 ... Connection terminal 51 ... Outer peripheral extension part 52 ... Mounting terminal part (corresponding to the first terminal positioning part)
53 ... Positioning part (corresponding to the second terminal positioning part)
54 ... Terminal connection part 540 ... Punching part

Claims (3)

A coil constructed by winding a conducting wire;
There is a plate portion, and a column base portion through which the air core portion of the coil is inserted is erected from the plate portion, and an outer wall core portion is erected from the plate portion so as to surround the column base portion. And a first core provided with a first core positioning part on the outer wall core part,
A second core provided in a flat plate shape and provided with a second core positioning portion on the flat peripheral edge portion;
A first terminal positioning portion is provided for engaging with the first core positioning portion and positioning with respect to the first core, and is engaged with the second core positioning portion to A connection terminal provided with a second terminal positioning portion for positioning with respect to the core of 2;
An inductor comprising:   2. The inductor according to claim 1, wherein the connection terminal is disposed along an outer peripheral surface when the first core and the second core are overlapped with each other. A column base is erected from the plate portion, and a first core in which an outer wall core portion is erected in a state surrounding the column base, a coil formed by winding of a conductive wire, and a flat plate shape An inductor manufacturing method for manufacturing an inductor comprising a second core provided and a connection terminal,
The first core positioning portion provided in the connection terminal is engaged with the first core positioning portion provided in the outer wall core portion, and by this engagement, the first core and the above-mentioned A first joining step in which the connection terminals are joined in a positioned state;
A coil attachment step of inserting the air core portion into the column base and disposing the coil on the first core and joining the end of the coil to the connection terminal in an electrically conductive state. When,
The second core positioning portion provided on the connection terminal is engaged with the second core positioning portion provided on the flat peripheral portion of the second core, and by this engagement, A second joining step in which the second core and the connection terminal are joined in a positioned state;
An inductor manufacturing method comprising:

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