KR101554713B1 - Inductor including plurality of cap structures - Google Patents

Abstract

Provided is an inductor including a plurality of cap structures. The inductor includes a wiring part which comprises a spiral body, and a first terminal and a second terminal which protrude from one side and the other side of the spiral body; a case which covers the spiral body with a ring shape and partly surrounds the first terminal and the second terminal; and a core part which partly surrounds the case and exposes the first and second terminals through the case.

Description

[0001] INDUCTOR INCLUDING PLURALITY OF CAP STRUCTURES [

Embodiments of the present invention relate to an inductor and more particularly to an inductor having a plurality of cap structures (not shown) provided in a power factor correction (PFC) circuit of a DC-DC converter To the inductor.

In general, an inductor is a simple structure in which power is applied to both ends of an electric wire wound around an iron core to store energy therein using self-induction generated between the iron core and the electric wire, And is an electric device for transferring energy to the battery. Further, the inductor is placed on an electric circuit by winding wires on a bobbin of an insulator and providing cores on the bobbin when the inductor is used for a vehicle or an industrial use.

In this case, the manufacturing method of the inductor can be described with reference to Figs. In order to manufacture the inductor, the cores 10 and 30 and the bobbin 50 are prepared as shown in Fig. The bobbin (50) is made of a circular tube and has partition walls (44) and guide grooves (48). The core 10 has a ribbon-shaped connecting member 3, guide sidewalls 6 positioned in the peripheral regions of the connecting member 3 and a filler 9 located in the central region of the connecting member 3, .

The core 30 includes a connecting member 23, guide sidewalls 26 and a filler 29 so as to have the same shape as the core 10. A polishing operation is applied to the fillers 9 and 29 to form air gaps in the cores 10 and 30, respectively. The air gaps of the cores 10, 30 can easily impart a process margin to the inductance of the inductor to the inductor. A winding operation is applied on the bobbin (50). The winding operation is performed to wind the electric wire 60 on the bobbin 50 as shown in FIG.

The electric wire 60 may be wound along the guide grooves 48 of the bobbin 50. A soldering operation is applied on the bobbin 50 and the electric wire 60. The soldering operation is performed to fix the electric wire 60 to the bobbin 50. Bonding is applied to the cores 10, 30 before the cores 10, 30 and the bobbin 50 are combined as shown in FIG. The bond operation is performed to attach the bond to the air gaps of the cores 10,30. The bond prevents noise generated from the fillers (9, 29) during the electrical operation of the inductor.

After the bonding operation is completed, an assembly operation is applied to the cores 10 and 30 and the bobbin 50. [ The assembly operation inserts the fillers 9 and 29 of the cores 10 and 30 in the hollow of the bobbin 50 to fix the fillers 9 and 29 to each other with the bond. The guide sidewalls 6 and 26 of the cores 10 and 30 contact each other around the bobbin 50. [ After the assembly operation is completed, a taping operation is applied to the cores (10, 30). The taping operation is performed so as to fix the cores 10, 30 with respect to each other using an insulating tape 70.

Subsequently, a vacuum impregnation operation is applied to the cores 10, 30, the bobbin 50 and the electric wire 60. The vacuum impregnating operation is carried out by placing the cores 10 and 30, the bobbin 50 and the electric wire 60 in a vacuum device (not shown in the figure) and inserting the cores 10 and 30, the bobbin 50, 60, and impregnating the epoxy resin with the cores 10, 30, the bobbin 50 and the wire 60. Thereafter, a drying operation and a cooling operation are sequentially applied to the epoxy resin including the cores 10, 30, the bobbin 50 and the electric wire 60.

The drying operation is performed to heat the epoxy resin including the cores 10, 30, the bobbin 50 and the electric wire 60 to an elevated temperature. The cooling operation is performed to naturally cool the epoxy resin including the cores 10, 30, the bobbin 50 and the electric wire 60. The inductor 80 of FIG. 3 is thereby fabricated. However, since the above-described manufacturing method has a working order requiring a long time, it has a high operation unit cost per work. In addition, the inductor 80 has magnetic lines of force ml1, ml2 passing through the guide sidewalls 6, 26 and the pillars 9, 29 in the cores 10, 30 during electrical operation.

A part of the magnetic flux lines ml1 and ml2 leaks to the outside from the exposed portion A of the bobbin 50 because the bobbin 50 is exposed to the outside between the cores 10 and 30. Therefore, the inductor 80 restrictively implements magnetic induction through the magnetic flux lines ml1, ml2. Accordingly, the inductor 80 does not secure the desired inductance through limited magnetic induction.

An object of the present invention is to provide an inductor having a plurality of cap structures suitable for simplifying the structure to shorten the time required for the operation procedure of the manufacturing method and for preventing external leakage of magnetic field lines through a modification of the structure have.

Other problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems not mentioned here will be fully understood by those skilled in the art from the following description.

An inductor having a plurality of cap structures according to embodiments of the present invention is provided. Wherein the inductor includes a helical body and a winding portion including a first terminal and a second terminal protruding from one side and the other side of the helical body; A case partially surrounding the first terminal and the second terminal while annularly wrapping the spiral-shaped body; A core portion partially surrounding the case and exposing the first terminal and the second terminal through the case; Wherein the case includes a synthetic resin, and the core portion includes a metal exhibiting a characteristic of magnetization in a magnetic field.

The helical body is formed in a plate shape and is wound toward one direction of the case.

The first terminal and the second terminal are formed in a plate shape and protrude in a same direction from the helical body.

The case includes a lower case and an upper case, and the lower case has a tubular shape to seat the winding part, and the upper case is plate-shaped and is fitted to the lower case.

In some examples, the lower case has an inner side wall and an outer side wall in a central region and a peripheral region of the helical body, respectively, for constituting a lower body, and has an inner wall and an outer wall projecting in parallel to each other from the outer wall, Shaped first seating portion and a second seating portion which are open on the bottom surface between the inner wall and the outer wall and on the bottom surfaces of the first seating portion and the second seating portion, And the winding portion is seated on the bottom surface between the inner wall and the outer wall and on the bottom surfaces of the first and second seating portions.

The upper case includes a first lid, a second lid and a third lid integrally formed to constitute an upper body, wherein the first lid has a second through hole facing the first through hole of the lower body, Wherein the second cover and the third cover are located on the bottom surface between the inner side wall and the outer side wall of the lower body while defining the hole and the second lid and the third lid are located on the bottom surfaces of the first and second seating portions And the first cover and the second cover have the same thickness, and the third cover has a greater thickness than the second cover.

In some examples, the lower case has a sidewall in a peripheral region of the helical body to constitute a lower body, a first U-shaped seat that projects parallel to the sidewalls and penetrates the sidewall, A second seating portion having a first seating portion and a second seating portion on a bottom surface defined by the side wall and on a bottom surface of the first seating portion and the second seating portion, And the winding portion is seated on the bottom surface defined by the side wall and on the bottom surfaces of the first and second seating portions.

The upper case includes a first lid, a second lid and a third lid integrally formed to constitute an upper body, the first lid having a circular tube fitted to the first through hole, The second lid and the third lid being located on the bottom surfaces of the first and second seating portions, respectively, and the circular tube being positioned on the bottom surface defined by the side wall of the body, Two through holes and extending from the first lid to the bottom surface defined by the side walls of the lower body to fit into a central region of the helical body and open toward the bottom surface defined by the side walls Wherein the first cover and the second cover have the same thickness and the third cover has a greater thickness than the second cover Neunda.

In some examples, the lower case has an inner side wall and an outer side wall in a central region and a peripheral region of the helical body, respectively, for constituting a lower body, and has an inner wall and an outer wall projecting in parallel to each other from the outer wall, Shaped first seating portion and a second seating portion which are open on the bottom surface between the inner wall and the outer wall and on the bottom surfaces of the first seating portion and the second seating portion, And the winding portion is seated on the bottom surface between the inner wall and the outer wall and on the bottom surfaces of the first seating portion and the second seating portion.

The upper case includes a first lid, a second lid and a third lid integrally formed to constitute an upper body, and the first lid is disposed on the through hole of the lower body, Wherein the second cover and the third cover are positioned on the bottom surfaces of the first and second seating portions, respectively, and the first cover and the second cover are located on the bottom surface between the outer walls, And the third lid has a greater thickness than the second lid.

In some examples, the lower case has a sidewall in a peripheral region of the helical body to constitute a lower body, a first U-shaped seat that projects parallel to the sidewalls and penetrates the sidewall, And a through hole is formed in a central region of the bottom surface defined by the side wall and having a through hole at a bottom surface defined by the side wall and on the bottom surfaces of the first and second seating portions Wherein the winding portion is seated on the bottom surface defined by the side wall around the through hole and on the bottom surfaces of the first and second seating portions.

The upper case includes a first lid, a second lid and a third lid integrally formed to constitute an upper body, and the first lid has a cylindrical lug which is fitted in the lug Wherein the second lid and the third lid are located on the bottom surfaces of the first and second seating portions, respectively, and the second lid and the third lid are located on the bottom surface defined by the side wall of the lower body, The sphere is open toward the bottom surface defined by the sidewall extending from the first lid to the bottom surface defined by the sidewall of the lower body to be inserted into the central region of the helical body and towards the first lid The first cover and the second cover have the same thickness, and the third cover has a greater thickness than the second cover.

In some examples, the lower case has a sidewall in a peripheral region of the helical body to constitute a lower body, a first U-shaped seat that projects parallel to the sidewalls and penetrates the sidewall, A second seating portion having a first seating portion and a second seating portion, the first seating portion and the second seating portion being open on the bottom surface defined by the side wall and on the bottom surfaces of the first and second seating portions, Wherein the winding portion is seated on the bottom surface defined by the sidewalls and on the bottom surfaces of the first and second seating portions surrounding the fitting.

The upper case includes a first lid, a second lid and a third lid integrally formed to constitute an upper body, the first lid having a circular tube fitted to the fitting hole, Wherein the second lid and the third lid are located on the bottom surfaces of the first and second seating portions respectively and the cylindrical tube is positioned on the bottom surface defined by the side wall, And extending from the first cover to the bottom surface defined by the side wall of the lower body to be inserted into a central region of the helical body and open toward the bottom surface defined by the side wall, The first cover and the second cover have the same thickness, and the third cover has a greater thickness than the second cover.

In some instances, the core portion is configured to cover the outer wall of the lower body, the opposite side of the bottom surface between the outer wall and the inner wall, and the first lid of the upper body, Through the through hole and the second through hole of the upper body to fill the inner wall of the lower body.

In some examples, the core portion may include at least one of a first through-hole and a second through-hole in the lower body, so as to cover the sidewall, the opposite side of the bottom surface defined by the sidewall and the first lid of the upper body, And passes through the second through-hole of the upper body to fill the circular tube of the upper body.

In some instances, the core portion may include at least one of an outer wall of the lower body, an opposite side of the bottom surface between the outer wall and the inner wall, and a through- To fill the inner wall.

In some instances, the core portion may include a plurality of through-holes extending through the through-holes of the lower body so as to cover the side walls, the opposite side of the bottom surface defined by the side walls, and the first lid of the upper body, The cylindrical sphere of the upper body is filled.

In some examples, the core portion may include a plurality of through-holes extending through the through-holes of the upper body so as to cover the side walls, the opposite side of the bottom surface defined by the side walls, And the cylindrical tube of the upper body is filled.

The core portion has at least one heat dissipating groove on the upper body, and the at least one heat dissipating groove extends from the surface of the core portion toward the inside of the core portion.

As described above, since the inductor having a plurality of cap structures according to the embodiments of the present invention completely surrounds the helical body of the winding portion,

The inductor does not expose the spiral-shaped body of the winding portion to the outside, so that the external leakage of the magnetic force lines can be minimized compared with the prior art.

The inductor may form a magnetic path of a closed curve around the helical body of the winding portion to concentrate the magnetic field lines on the helical body of the winding portion more than the prior art to easily implement the magnetic induction.

The inductor has a bobbin in the form of an annular cap to open or close the central region of the bobbin so that the process margin of the inductance can be easily obtained without additional work compared to the prior art.

Since the inductor is manufactured by assembling the formed winding part and the separable case together and placing the winding part and the case on the mold frame to form the core part around the winding part and the case, the conventional polishing, bonding, taping , The vacuum impregnation operation, the drying operation and the cooling operation are not performed, so that the work cost per work can be lowered.

1 to 3 are schematic views for explaining a method of manufacturing an inductor according to the prior art.
4 is a perspective view showing an inductor according to the first embodiment of the present invention.
5 is a plan view showing the inductor taken in the first direction D1 of FIG.
6 is a side view showing the inductor taken in the second direction D2 of FIG.
FIG. 7 is a perspective view showing an internal structure positioned in the inductor of FIG. 4; FIG.
8 is an exploded perspective view showing the internal structure of FIG.
9 is an exploded perspective view showing a modification of the case of Fig.
10 is a perspective view showing an inductor according to a second embodiment of the present invention.
11 is a plan view showing the inductor taken in the first direction D3 of FIG.
12 is a side view showing the inductor taken in the second direction D4 of FIG.
FIG. 13 is a perspective view showing an internal structure positioned in the inductor of FIG. 10; FIG.
14 is an exploded perspective view showing the internal structure of FIG.
15 is an exploded perspective view showing a modification of the case of Fig.
16 is an exploded perspective view showing another modification of the case of Fig.
Figs. 17 to 19 are schematic views for explaining a method of manufacturing the inductor of Fig. 4;
20 is a schematic view for explaining a method of driving the inductor of FIG.

First, an inductor having a plurality of cap structures according to embodiments of the present invention will be described in detail with reference to FIGS. 4 to 16. FIG.

FIG. 4 is a perspective view showing an inductor according to a first embodiment of the present invention, and FIG. 5 is a plan view showing an inductor taken in a first direction D1 of FIG. 6 is a side view showing the inductor taken in the second direction D2 of FIG.

4, an inductor 214 in accordance with a first embodiment of the present invention includes an inner structure 174 and an outer structure 204. In this embodiment, The inner structure 174 includes a ring shape and two branch shapes. The annular shape of the inner structure 174 is enclosed by the outer structure 204. The branch shapes of the internal structure 174 protrude in the same direction from the external structure 204.

Referring to FIG. 5, the inner structure 174 of the inductor 214 includes a winding part 110 and a case 161. The winding part 110 protrudes from the inside of the case 161 toward the outside. The case 161 has an annular shape and has a through hole H1 in a central region thereof. The through hole (H1) passes through the case (161). The case 161 includes an upper case 151 and a lower case 133. The upper case 151 and the lower case 133 have the same shape in plan view.

The upper case 151 and the lower case 133 include synthetic resin. The upper case 151 is located inside the lower case 133. The outer structure 204 of the inductor 214 includes a core portion 194. The core portion 194 partially covers the case 161. [ The core portion 194 exposes the winding portion 110 through the case 161. The core portion 194 includes a metal exhibiting a characteristic of magnetization in a magnetic field. The core portion 194 has a plurality of heat dissipation grooves G. [ The core portion 194 may have one heat dissipation groove G or may not have the heat dissipation groove G. [

Referring to FIG. 6, the upper case 151 of the case 161 is fitted into the lower case 133. The lower case 133 and the upper case 151 define the through hole H1 through the central region of the case 161 of FIG. The core portion 194 partially encloses the case 161 when considering the case 161 of FIG. The core portion 194 includes a first core portion 182 and a second core portion 184. The first core portion 182 and the second core portion 184 are integrally formed through the mold frame.

The heat dissipation grooves G of the core portion 194 are located on the upper case 151 and extend inward from the surface. In this case, the heat dissipating grooves G are opened toward the surface of the core portion 194 and closed inside the core portion 194. The case 161 and the core portion 194 have a cap structure.

FIG. 7 is a perspective view showing an internal structure positioned in the inductor of FIG. 4, and FIG. 8 is an exploded perspective view showing the internal structure of FIG.

Referring to FIG. 7, the case 161 of the internal structure 174 has a winding part 110. The case 161 has a lower case 133 and an upper case 151 fitted to each other. The lower case 133 and the upper case 151 expose the winding part 110 but are located at the lower and upper parts of the winding part 110 so that airtightness Tightly.

In addition, the lower case 133 has a lower body 120 coupled with a donut shape and a tubular shape. The upper case 151 has an upper body 140 that connects the annular shape and the plate shape. The lower body 120 and the upper body 140 are configured to surround the winding unit 110 through a fit-engagement of the lower case 133 and the upper case 151. The lower body 120 and the upper body 140 expose the side wall of the through hole H1 from the central region of the case 161 to the outside.

Referring to FIG. 8, in the internal structure 174, the winding part 110 includes a helical body 92 and a first terminal 96 protruding from one side and the other side of the helical body 92, And a second terminal 98. The spiral-shaped body 92 has a plate-like shape and is wound toward one direction of the case 161 shown in Fig. More specifically, the helical body 92 surrounds the side wall of the through hole H1 of the case 161 of Fig. The spiral-shaped body 92 is a spiral-shaped winding.

The first terminal 96 and the second terminal 98 are formed in a plate shape and are staggered in the same direction from the helical body 92. The winding portion 110 has an air gap 94 in a central region thereof. In the internal structure 174 the case 161 is configured to partially surround the first terminal 96 and the second terminal 98 while annularly wrapping the helical body 92. More specifically, the lower case 133 of the case 161 is formed in a donut shape and a tubular shape to seat the winding unit 110.

The lower case 133 includes an inner wall 122 and an outer wall 121 in a central area and a peripheral area of the helical body 92 of the winding part 110, Shaped first seating portion 128 and a second seating portion 129 protruding from the outer wall 121 in parallel to each other and passing through the outer wall 121. The U- The lower case 133 may be formed on the bottom surface between the inner wall 122 and the outer wall 121 and on the bottom surface of the first and second seating parts 128 and 129 And has a first through-hole 123 defined by an inner wall 122. The first through-hole 123 has a first through-

In this case, the winding part 110 is formed on the bottom surface between the inner wall 12 and the outer wall 121 of the lower body 120 and on the bottom surface between the first seating part 128 and the second seating part 129 And is seated on the bottom surfaces. The upper case 151 of the case 161 has a plate shape and is fitted to the lower case 136. The upper case 151 includes a first lid 141, a second lid 148 and a third lid 149 which are integrally formed to constitute the upper body 140. The first cover 141 defines an inner side wall 122 and an outer side wall 121 of the lower body 120 while defining a second through hole 144 opposed to the first through hole 123 of the lower body 120, As shown in Fig.

The first through hole 123 of the lower body 120 and the second through hole 144 of the upper body 140 constitute a through hole H1 of FIG. The second cover 148 and the third cover 149 are respectively positioned on the bottom surfaces of the first seating portion 128 and the second seating portion 129. The first cover 141 and the second cover 148 have the same thickness. The third cover 149 has a greater thickness than the second cover 148. The first and second seats 128 and 129 and the second cover 148 and the third cover 149 are connected to the first terminal 96 and the second terminal 98 of the winding unit 110, .

4, the core portion 194 of the inductor 214 may include an outer side wall 121 and an outer side wall 121 in the lower body 120, The first through hole 123 of the lower body 120 and the upper body 140 of the lower body 120 are formed so as to cover the first cover 141 of the upper body 140 and the opposite side of the bottom surface between the first body 121 and the inner side wall 122 Through the second through-hole 144 of the lower body 120. The inner wall 122 of the lower body 120 is then filled.

9 is an exploded perspective view showing a modification of the case of Fig. 9, the same reference numerals are used for the same members as those in Fig.

Referring to Fig. 9, the case 163 has a structure similar to the case 161 so as to replace the case 161 of Fig. However, the lower case 136 of the case 163 has the side wall 121 in the peripheral region of the helical body 92 of the winding portion 110 of Fig. 8 to constitute the lower body 124 And a first seating part 128 and a second seating part 129 which protrude from the side wall 121 in parallel and pass through the side wall 121.

The lower case 136 is formed on the bottom surface defined by the side wall 121 and on the bottom surfaces of the first and second seating portions 128 and 129 to form the lower body 124. [ And has a first through hole 125 in the central region of the bottom surface defined by the side wall 121. [ In this case, the winding portion 110 is formed on the bottom surface defined by the side wall 121 of the lower body 124 and on the bottom surfaces of the first and second seating portions 128 and 129 Lt; / RTI >

The upper case 153 of the case 163 includes a first lid 141, a second lid 148 and a third lid 149 which are integrally formed to constitute the upper body 140 do. The first cover 141 has a circular tube 143 inserted in the first through hole 125 of the lower body 124 and is formed on a bottom surface defined by the side wall 121 of the lower body 124 . The second cover 148 and the third cover 149 are respectively positioned on the bottom surfaces of the first seating portion 128 and the second seating portion 129.

The cylindrical tube 143 defines a second through hole 144 and extends from the first lid 141 to the side wall of the lower body 124 so as to fit into the central region of the helical body 92 of the reel 110. [ Extending toward the bottom surface defined by the side wall 121 and opening toward the bottom surface defined by the side wall 121 and toward the first lid 141. [ The first through hole 125 of the lower body 136 and the second through hole 144 of the upper body 153 constitute the through hole H1 of FIG. The first cover 141 and the second cover 148 have the same thickness. The third cover 149 has a greater thickness than the second cover 148.

The first and second seats 128 and 129 and the second cover 148 and the third cover 149 are connected to the first terminal 96 and the second terminal 98 of the winding unit 110, . 4, the core portion 194 of the inductor 214 may be formed in the lower body 124 such that the side wall 121 and the side wall And the second through hole 125 of the lower body 124 and the second through hole 125 of the upper body 140 so as to cover the first cover 141 of the upper body 140, Passes through the hole 144 and fills the cylindrical tube 143 of the upper body 140.

FIG. 10 is a perspective view showing an inductor according to a second embodiment of the present invention, and FIG. 11 is a plan view showing an inductor taken in a first direction D3 of FIG. 12 is a side view showing the inductor taken in the second direction D4 of FIG. Here, Figs. 10 to 12 use the same reference numerals for the same members as those of Figs. 4 to 6. Fig.

Referring to FIG. 10, an inductor 218 according to a second embodiment of the present invention includes an inner structure 178 and an outer structure 208. The inner structure 178 includes a vessel shape and two branch shapes. The container shape of the inner structure 178 is enclosed by the outer structure 208. The branch shapes of the inner structure 178 protrude in the same direction from the outer structure 208.

Referring to FIG. 11, the internal structure 178 of the inductor 218 includes a winding part 110 and a case 165. The winding portion 110 protrudes from the inside of the case 165 toward the outside. The case 165 is formed in a container shape and has a through hole H2 in a central region thereof. The through hole H2 extends from the surface of the case 165 toward the inside and is closed by the bottom surface of the container shape. More specifically, the case 165 includes an upper case 155 and a lower case 133. The upper case 155 and the lower case 133 have a similar shape in plan view.

The upper case 155 and the lower case 133 include synthetic resin. The lower case 133 defines a through hole H2. The upper case 155 is located inside the lower case 133 and covers the through hole H2. The outer structure 208 of the inductor 218 includes a core portion 198. The core portion (198) partially covers the case (165). The core portion 198 exposes the winding portion 110 through the case 165. The core portion 198 includes a metal exhibiting a characteristic of magnetization in a magnetic field. The core portion 198 has a plurality of heat dissipation grooves G. The core portion 198 may have one heat dissipation groove G or may not have the heat dissipation groove G. [

Referring to FIG. 12, the upper case 155 of the case 165 is fitted into the lower case 133. The lower case 133 defines the through hole H2 through a central region of the case 165 of FIG. The upper case 155 closes the through hole H2 on the lower case 133. The core portion 198 partially surrounds the case 161 when the case 165 of FIG. 10 is considered. The core portion 198 includes a first core portion 186 and a second core portion 188. The first core portion 186 and the second core portion 188 are integrally formed through the mold frame.

In this case, the first core portion 186 and the second core portion 188 do not meet through the upper case 155. That is, the upper case 155 separates the first core portion 186 and the second core portion 188 from each other around the through hole H2 of the lower case 133. The heat dissipation grooves G of the core portion 198 are located on the upper case 155 and extend inward from the surface. In this case, the heat dissipating grooves G are opened toward the surface of the core portion 198 and closed inside the core portion 198. The case 165 and the core portion 198 have a cap structure.

FIG. 13 is a perspective view showing an internal structure positioned in the inductor of FIG. 10, and FIG. 14 is an exploded perspective view showing the internal structure of FIG.

Referring to FIG. 13, the case 165 of the internal structure 178 has a winding portion 110. The case 165 has a lower case 133 and an upper case 155 which are fitted to each other. The lower case 133 and the upper case 155 expose the winding part 110 but are located at the lower and upper parts of the winding part 110 so that the air in the vicinity of the winding part 110 Tightly.

In addition, the lower case 133 has a lower body 120 coupled with a donut shape and a tubular shape. The upper case 155 has a plate-like upper body 142. The lower body 120 and the upper body 142 are configured to surround the winding unit 110 through a fit-engagement of the lower case 133 and the upper case 155. The upper body 142 covers the through hole H2 of the lower body 120. The lower body 120 and the upper body 142 are formed in a container shape defining a through hole H2 in a central region of the case 165. [

Referring to FIG. 14, in the internal structure 178, the winding part 110 includes a spiral shaped body 92 and a first terminal 96 protruding from one side and the other side of the spiral shaped body 92, And a second terminal 98. The spiral-shaped body 92 has a plate-like shape and is wound toward one direction of the case 165 shown in Fig. More specifically, the helical body 92 surrounds the side wall of the through hole H2 of the case 165 in Fig. The spiral-shaped body 92 is a spiral-shaped winding.

The first terminal 96 and the second terminal 98 are formed in a plate shape and are staggered in the same direction from the helical body 92. The winding portion 110 has an air gap 94 in a central region thereof. In the internal structure 178, the case 165 is configured to partially surround the first terminal 96 and the second terminal 98 while annularly wrapping the helical body 92. More specifically, the lower case 133 of the case 161 is formed in a donut shape and a tubular shape to seat the winding part 110.

The lower case 133 includes an inner wall 122 and an outer wall 121 in a central area and a peripheral area of the helical body 92 of the winding part 110, Shaped U-shaped first and second seating portions that extend parallel to each other from the outer side wall 121 and pass through the outer side wall 121, respectively. The lower case 133 may be formed on the bottom surface between the inner wall 122 and the outer wall 121 and on the bottom surface of the first and second seating parts 128 and 129 And has a through-hole 123 defined by the inner wall 122. The through-

The through hole 123 corresponds to the through hole H2 of the case 165 in Fig. The winding portion 110 is seated on the bottom surface between the inner wall 122 and the outer wall 121 and on the bottom surfaces of the first seating portion 128 and the second seating portion 129. The upper case 155 includes a first cover 145, a second cover 148 and a third cover 149 which are integrally formed to constitute the upper body 142. The first lid 145 is positioned on the through hole 123 of the lower body 120 and on the bottom surface between the inner wall 122 and the outer wall 121.

The second cover 148 and the third cover 149 are respectively positioned on the bottom surfaces of the first seating portion 128 and the second seating portion 129. The first cover 145 and the second cover 148 have the same thickness. The third cover 149 has a greater thickness than the second cover 148. The first and second seats 128 and 129 and the second cover 148 and the third cover 149 are connected to the first terminal 96 and the second terminal 98 of the winding unit 110, .

10, the core portion 198 of the inductor 218 may include an outer side wall 121 and an outer side wall 121 in the lower body 120. In this case, Through the through hole 123 of the lower body 120 so as to cover the first lid 145 from the upper body 142 and the opposite side of the bottom surface between the inner wall 122 and the inner wall 122 ).

15 is an exploded perspective view showing a modification of the case of Fig. Here, FIG. 15 uses the same reference numerals as those in FIG. 14 for the same members.

Referring to Fig. 15, the case 167 has a structure similar to the case 165 to replace the case 165 of Fig. However, the lower case 136 of the case 167 has a side wall 121 in the peripheral region of the helical body 92 of the winding part 110 of Fig. 14 in order to constitute the lower body 124 And a first seating part 128 and a second seating part 129 which protrude from the side wall 121 in parallel and pass through the side wall 121.

The lower case 136 is formed on the bottom surface defined by the side wall 121 and on the bottom surfaces of the first and second seating portions 128 and 129 to form the lower body 124. [ And has a through hole 125 in a central region of the bottom surface defined by the side wall 121. [ In this case, the winding portion 110 is formed on the bottom surface defined by the side wall 121 around the through hole 125 and on the bottom surfaces of the first and second seating portions 128 and 129 Respectively.

The upper case 157 of the case 167 includes a first lid 145, a second lid 148 and a third lid 149 which are integrally formed to constitute the upper body 142. The first lid 145 is positioned on a bottom surface defined by the side wall 121 of the lower body 124 with a cylindrical lid 146 fitted in the through hole 125. The through hole 125 of the lower body 124 and the cylindrical hole 146 of the upper body 142 constitute the through hole H2 of the case 165 of FIG.

The second cover 148 and the third cover 149 are respectively positioned on the bottom surfaces of the first seating portion 128 and the second seating portion 129. The cylindrical opening 146 extends from the first cover 145 to the bottom surface defined by the side wall 121 of the lower body 124 so as to be inserted into the central region of the helical body 92 of the winding portion 110 Is opened toward the bottom surface defined by the side wall 121 and closed toward the first cover 145. The first cover 145 and the second cover 148 have the same thickness. The third cover 149 has a greater thickness than the second cover 148.

The first and second seats 128 and 129 and the second cover 148 and the third cover 149 are connected to the first terminal 96 and the second terminal 98 of the winding unit 110, . 10, the core portion 198 of the inductor 218 is electrically connected to the side wall 121 and the side wall 121 of the lower body 124, 121 through the through hole 125 of the lower body 124 so as to cover the first lid 145 of the upper body 142 and the cylindrical portion 146 of the upper body 142 ).

16 is an exploded perspective view showing another modification of the case of Fig. Here, in FIG. 16, the same reference numerals are used for the same members as those in FIG. 14. FIG.

16, the case 169 has a structure similar to the case 165 so as to replace the case 165 of FIG. However, the lower case 139 of the case 169 has the side wall 121 in the peripheral region of the helical body 92 of the winding part 110 of Fig. 14 in order to constitute the lower body 126 And a first seating part 128 and a second seating part 129 which protrude from the side wall 121 in parallel and pass through the side wall 121.

The lower case 139 is formed on the bottom surface defined by the side wall 121 and on the bottom surfaces of the first and second seating portions 128 and 129 to constitute the lower body 126. [ And has a fitting 127 on the bottom surface defined by the side wall 121). The fitting hole 127 is fixed to a bottom surface defined by the side wall 121 in the lower body 126. In this case, the winding part 110 is formed on the bottom surface defined by the side wall 121 surrounding the fitting hole 127 and on the bottom surfaces of the first and second seating parts 128 and 129 Lt; / RTI >

The upper case 153 includes a first lid 141, a second lid 148 and a third lid 149 which are integrally formed to constitute the upper body 140. The first cover 141 is positioned on a bottom surface defined by the side wall 121 of the lower body 126 while having a circular tube 143 inserted into the fitting hole 127 of the lower body 126. The second cover 148 and the third cover 149 are respectively positioned on the bottom surfaces of the first seating portion 128 and the second seating portion 129.

The cylindrical tube 143 defines a through hole H2 of FIG. 13 and extends from the first lid 141 to the lower end of the lower body 126 so as to be inserted into the central region of the helical body 92 of the reel 110. [ Extends toward the bottom surface defined by the side wall 121, opens toward the bottom surface defined by the side wall 121, and opens toward the first lid 141. The first cover 141 and the second cover 148 have the same thickness. The third cover 149 has a greater thickness than the second cover 148.

The first and second seats 128 and 129 and the second cover 148 and the third cover 149 are connected to the first terminal 96 and the second terminal 98 of the winding unit 110, . 10, the core portion 198 of the inductor 218 is electrically connected to the sidewall 121 and the sidewall 121 of the lower body 126 in the case where the inductor 218 of FIG. 10 including the case 169 is considered. 121 of the upper body 140 through the through hole 144 of the upper body 140 so as to cover the first cover 141 of the upper body 140, ).

Figs. 17 to 19 are schematic views for explaining a method of manufacturing the inductor of Fig. 4;

Referring to Fig. 17, a lower case 133 is prepared. The lower case 133 is formed by combining a donut shape and a tubular shape so as to form a lower body 120 and has an inner wall 122 and an outer wall 121 at a central region and a peripheral region, respectively. The lower case 133 has a U-shaped first seating part 128 and a second seating part 129 protruding from the outer side wall 121 in parallel to each other and penetrating the outer side wall 121.

In addition, the lower case 133 includes a groove G1 defined by an inner wall 122 and an outer wall 121, grooves G1 defined by a first seating portion 128 and a second seating portion 129 G2, and G3, and has a first through hole 123 defined by the inner side wall 122. The grooves G1, G2 and G3 of the lower body 120 communicate with each other. The first through hole 123 penetrates the lower body 120 through the inner side wall 122.

Referring to FIG. 18, a winding operation is applied on the lower case 133. The winding operation is performed so as to place the winding portion 110 of Fig. 8 on the lower body 120. The winding part 110 can be seated along the grooves G1, G2 and G3 of FIG. 17 of the lower body 120 along the winding traces 110T. The winding part 110 surrounds the inner wall 122 of the lower body 120 and is connected to the first and second seating parts 128 and 129 via the first and second seating parts 128 and 129, As shown in Fig.

A soldering operation is applied on the lower case 133 and the winding part 110. [ The soldering operation is performed to fix the winding part 110 to the lower body 120. An upper case 151 is formed on the lower case 133. The upper case 151 may be aligned with the lower case 133. The upper case 151 includes a first lid 141, a second lid 148 and a third lid 149, which are formed in an annular shape and a plate shape to form an upper body 140 .

The first cover 141, the second cover 148, and the third cover 149 cover the winding portion 110. The first lid 141 is positioned on the groove G1 of the lower body 120 while defining the second through hole 144 facing the first through hole 123 of the lower body 120. [ do. In this case, the first through-hole 123 of the lower body 120 and the second through-hole 144 of the upper body 140 form a through-hole H1. The second cover 148 and the third cover 149 are positioned on the grooves G2 and G3 of the first and second seating portions 128 and 129, respectively.

The lower case 133 and the upper case 151 form a case 161 and the case 161 and the winding 110 form an internal structure 174. [ In this case, the case 161 can be replaced with one of the cases 163, 165, 167, and 169 of FIGS. 9, 14, 15 and 16.

Referring to FIG. 19, the inner structure 174 is seated in a mold frame (not shown). An injection molding operation is applied on the inner structure 174 through the mold frame. The injection molding operation is performed to form the core portion 194 on the internal structure 174 using metal powder. The core portion 194 integrally includes a first core portion 182 and a second core portion 184. The first core portion 182 has at least one heat dissipation groove G. [ The core portion 194 partially encloses the case 161. [

In this case, the core portion 194 passes through the through hole H1 of the case 161. [ The core portion 194 forms an outer structure 204. The core portion 194 may be replaced with the core portion 198 of FIG. 10 according to the structure of the mold frame. The inner structure 174 and the outer structure 204 form an inductor 214.

20 is a schematic view for explaining a method of driving the inductor of FIG.

Referring to FIG. 20, the inductor 214 may be mounted on a printed circuit board (PCB) (not shown). The printed circuit board (PCB) may constitute or constitute a part of a power factor correction (PFC) circuit of a DC-DC converter. The inductor 214 is electrically connected to the control unit 220 of the printed circuit board (PCB), the current input circuit unit 230, and the current output circuit unit 240.

The controller 220 electrically controls the driving of the current input circuit 230 and the current output circuit 240 while supplying power to the current input circuit 230 and the current output circuit 240. Power is supplied to the current input circuit part 230 and the current output circuit part 240 by using the control part 220. [ The current input circuit unit 230 may allow the input current I ₁ to flow toward the first terminal 96 of the winding unit 110 in the inductor 214 using a power source.

The input current I ₁ may form at least one magnetic force line ML in the winding part 110 and the core part 194. The at least one magnetic force line ML can be easily focused on the helical body due to the magnetic path of the closed curved surface around the helical body of the winding part 110. [ Therefore, the at least one magnetic force line ML can smoothly induce magnetic induction in the helical body so as to secure a desired inductance from the helical body of the winding part 110. [

The inductor 214 may cause the output current I ₂ to flow toward the current output circuit portion 240 through the second terminal 98 of the winding portion 110 while generating the magnetic induction. In this case, the inductor 214 uses the magnetic induction to increase the current overlap in the helical body of the winding part 110 to increase the power of the output current I ₂ more than the power of the input current I ₁ And supply power to the current output circuit unit 240. [

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

110; Winding section 133; The lower case
151; An upper case 161; case
174; Internal structure, 194; Core portion
204; External structure, 214; Inductor
G; Heat dissipating groove, H1; Through hole

Claims (20)

A spiral-shaped body, and a winding part composed of a first terminal and a second terminal protruding from one side and the other side of the helical body, respectively; A case partially surrounding the first terminal and the second terminal while annularly wrapping the spiral-shaped body; A core portion partially surrounding the case and exposing the first terminal and the second terminal through the case; , ≪ / RTI &
Wherein the case includes a synthetic resin, and the core portion includes a metal exhibiting a characteristic of magnetization in a magnetic field,
The case includes a lower case formed in a tubular shape to seat the winding portion, and an upper case formed in a plate shape and fitted to the lower case,
The lower case includes an inner side wall and an outer side wall in a central region and a peripheral region of the helical body to form a lower body. The lower case includes a U-shaped A first seat having a first seat portion and a second seat portion and having a first through hole defined on a bottom surface between the inner side wall and the outer side wall and on the bottom surfaces of the first seat portion and the second seat portion, Wherein the winding portion is seated on the bottom surface between the inner wall and the outer wall and on the bottom surfaces of the first and second seating portions. The method according to claim 1,
Wherein the helical body is formed in a plate shape and is wound toward one direction of the case. The method according to claim 1,
Wherein the first terminal and the second terminal are plate-shaped and protrude in the same direction from the helical body in a staggered manner. delete delete The method according to claim 1,
The upper case includes a first lid, a second lid and a third lid integrally formed to constitute an upper body,
Wherein the first lid is positioned on the bottom surface between the inner side wall and the outer side wall of the lower body while defining a second through hole facing the first through hole of the lower body, And a third lid is positioned on the bottom surfaces of the first and second seating portions, respectively,
Wherein the first cover and the second cover have the same thickness and the third cover has a greater thickness than the second cover. A spiral-shaped body, and a winding part composed of a first terminal and a second terminal protruding from one side and the other side of the helical body, respectively; A case partially surrounding the first terminal and the second terminal while annularly wrapping the spiral-shaped body; A core portion partially surrounding the case and exposing the first terminal and the second terminal through the case; , ≪ / RTI &
Wherein the case includes a synthetic resin, and the core portion includes a metal exhibiting a characteristic of magnetization in a magnetic field,
The case includes a lower case formed in a tubular shape to seat the winding portion, and an upper case formed in a plate shape and fitted to the lower case,
The lower case includes a first U-shaped seating portion having sidewalls in the peripheral region of the helical body and projecting parallel to the sidewalls and passing through the sidewall to form a lower body, Having a seating portion and having a first through hole in a central region of the bottom surface defined by the side wall and open on the bottom surface defined by the side wall and on the bottom surfaces of the first seating portion and the second seating portion Wherein the winding portion is seated on the bottom surface defined by the side wall and on the bottom surfaces of the first and second seating portions. 8. The method of claim 7,
The upper case includes a first lid, a second lid and a third lid integrally formed to constitute an upper body,
Wherein the first cover is positioned on the bottom surface defined by the side wall of the lower body while having a circular tube fitted in the first through hole and the second cover and the third cover are located on the first seating portion And on the bottom surfaces of the second seat portion,
The cylindrical tube defining a second through-hole and extending from the first lid to the bottom surface of the lower body to fit into a central region of the helical body, And is opened toward the first lid,
Wherein the first cover and the second cover have the same thickness and the third cover has a greater thickness than the second cover. A spiral-shaped body, and a winding part composed of a first terminal and a second terminal protruding from one side and the other side of the helical body, respectively; A case partially surrounding the first terminal and the second terminal while annularly wrapping the spiral-shaped body; A core portion partially surrounding the case and exposing the first terminal and the second terminal through the case; , ≪ / RTI &
Wherein the case includes a synthetic resin, and the core portion includes a metal exhibiting a characteristic of magnetization in a magnetic field,
The case includes a lower case formed in a tubular shape to seat the winding portion, and an upper case formed in a plate shape and fitted to the lower case,
The lower case includes an inner side wall and an outer side wall in a central region and a peripheral region of the helical body to form a lower body. The lower case includes a U-shaped A through hole defined on the bottom surface between the inner wall and the outer wall and on the bottom surfaces of the first and second seating portions and having a first seating portion and a second seating portion, Wherein the winding portion is seated on the bottom surface between the inner wall and the outer wall and on the bottom surfaces of the first seating portion and the second seating portion. 10. The method of claim 9,
The upper case includes a first lid, a second lid and a third lid integrally formed to constitute an upper body,
Wherein the first lid is located on the through hole of the lower body and on the bottom surface between the inner wall and the outer wall and the second lid and the third lid are located on the first seating portion and the second Respectively, on the bottom surfaces of the seat portion,
Wherein the first cover and the second cover have the same thickness and the third cover has a greater thickness than the second cover. A spiral-shaped body, and a winding part composed of a first terminal and a second terminal protruding from one side and the other side of the helical body, respectively; A case partially surrounding the first terminal and the second terminal while annularly wrapping the spiral-shaped body; A core portion partially surrounding the case and exposing the first terminal and the second terminal through the case; , ≪ / RTI &
Wherein the case includes a synthetic resin, and the core portion includes a metal exhibiting a characteristic of magnetization in a magnetic field,
The case includes a lower case formed in a tubular shape to seat the winding portion, and an upper case formed in a plate shape and fitted to the lower case,
The lower case includes a first U-shaped seating portion having sidewalls in the peripheral region of the helical body and projecting parallel to the sidewalls and passing through the sidewall to form a lower body, And having a through hole in a central region of said bottom surface defined by said side wall, said bottom surface defining said side wall, said bottom surface defining said side wall, said bottom surface defined by said side wall, and on said bottom surfaces of said first and second seating portions,
Wherein the winding portion is seated on the bottom surface defined by the sidewall around the through hole and on the bottom surfaces of the first and second seating portions. 12. The method of claim 11,
The upper case includes a first lid, a second lid and a third lid integrally formed to constitute an upper body,
Wherein the first lid is positioned on the bottom surface defined by the side wall of the lower body while having a cylindrical member fitted in the through hole, and the second lid and the third lid are located on the bottom surface of the lower body, (1) and (2) located on the bottom surfaces of the first and second seating portions, respectively,
The cylindrical sphere opening toward the bottom surface defined by the sidewall extending from the first lid to the bottom surface defined by the sidewall of the lower body to be inserted into a central region of the helical body, Wherein the first cover and the second cover have the same thickness and the third cover has a greater thickness than the second cover. A spiral-shaped body, and a winding part composed of a first terminal and a second terminal protruding from one side and the other side of the helical body, respectively; A case partially surrounding the first terminal and the second terminal while annularly wrapping the spiral-shaped body; A core portion partially surrounding the case and exposing the first terminal and the second terminal through the case; , ≪ / RTI &
Wherein the case includes a synthetic resin, and the core portion includes a metal exhibiting a characteristic of magnetization in a magnetic field,
The case includes a lower case formed in a tubular shape to seat the winding portion, and an upper case formed in a plate shape and fitted to the lower case,
The lower case includes a first U-shaped seating portion having sidewalls in the peripheral region of the helical body and projecting parallel to the sidewalls and passing through the sidewall to form a lower body, A second seating portion having a seating portion and having a fitting on the bottom surface defined by the side wall and on the bottom surfaces of the first and second seating portions defined by the side wall,
Wherein the winding portion is seated on the bottom surface defined by the sidewall and surrounding the shed and on the bottom surfaces of the first and second seating portions. 14. The method of claim 13,
The upper case includes a first lid, a second lid and a third lid integrally formed to constitute an upper body,
Wherein the first lid is positioned on the bottom surface defined by the side wall of the lower body while having a circular tube fitted in the fitting opening and the second lid and the third lid are positioned on the first seating portion and the second seating portion, Respectively, on the bottom surfaces of the second seat portion,
The cylindrical tube defining a through hole and extending from the first lid to the bottom surface defined by the side wall of the lower body to be inserted into a central region of the helical body and toward the bottom surface defined by the side wall Open toward said first lid together with said opening,
Wherein the first cover and the second cover have the same thickness and the third cover has a greater thickness than the second cover. The method according to claim 6,
The core portion
To cover the outer surface of the lower body, the opposite side of the bottom surface between the outer and inner walls, and the first lid of the upper body,
And fills the inner wall of the lower body through the first through-hole of the lower body and the second through-hole of the upper body. 9. The method of claim 8,
The core portion
To cover the sidewall in the lower body, the opposite side of the bottom surface defined by the sidewall, and the first lid of the upper body,
And an inductor which fills the circular tube of the upper body through the first through-hole of the lower body and the second through-hole of the upper body. 11. The method of claim 10,
The core portion
And a second lid disposed on the lower body to cover the first lid on the opposite side of the bottom wall between the outer wall and the outer wall and the inner wall,
And an inner wall through the through-hole of the lower body. 13. The method of claim 12,
The core portion
To cover the sidewall in the lower body, the opposite side of the bottom surface defined by the sidewall, and the first lid of the upper body,
And the cylindrical body of the upper body passes through the through hole of the lower body. 15. The method of claim 14,
The core portion
To cover the sidewall in the lower body, the opposite side of the bottom surface defined by the sidewall, and the first lid of the upper body,
And fills the cylindrical tube of the upper body through the through-hole of the upper body. 20. The method according to any one of claims 15 to 19,
Wherein the core portion has at least one heat dissipating groove on the upper body,
Wherein the at least one heat dissipating groove extends from the surface of the core portion toward the inside of the core portion.

Images