JP3214703U - Magnetic component structure - Google Patents

Abstract

A structure of a magnetic component is provided. The structure of a magnetic component is such that one or more convex bases 11 having a plurality of conductors are installed on one of opposing surfaces of a base material 1 through machining, and the surface of the other base material 1 is provided. Are provided with a plurality of conductive contacts 12, exhibiting electrical contact corresponding to a plurality of conductors of one or more convex bases 11 on the surface of the substrate 1, and relative to the two substrates 1. One or more magnetic inner cores 2 to be assembled on the surface to be mounted are located between one or one or more convex bases 11 and a plurality of conductive contacts 12, and one or one or more magnetic conductors. The inner core 2 is provided with a plurality of localization tank holes 21, and one or one or more convex bases 11 are respectively bored in the inner core 2, and one or one or more magnetically conductive inner cores 2 and one are provided. Alternatively, a plurality of sets of continuous winding conductor induction coils are provided between the plurality of conductors of the one or more convex bases 11 and the plurality of conductive contacts 12. Forming a sensing area of the fruit, machining work is simple and fast, can achieve the purpose of cost reduction. [Selection] Figure 2

Description

  The present invention relates to the structure of a magnetic component, and more particularly, a magnetic component that can be processed, manufactured, and molded quickly. One or more convex bases each having a plurality of conductors on two substrates, and each conductor. A plurality of conductive contacts that are in electrical contact with each other, and one or more magnetic cores are assembled between two substrates, and a large number of continuous winding conductor induction coil effect sensing areas It is related with the structure of the magnetic component which achieves the objective which lowers manufacturing cost and raises an economic effect.

  All transformers, inductors, and other magnetic sensing components that are commonly used at present, wrap two sets of enameled wires on the iron core, and then connect each of the four ends of the two sets of enameled wires. A single transformer is formed by extending on the flanges on both sides of the iron core and exhibiting electrical connection with the circuit of each external electronic device. As a result, the circuit of the electronic device can perform voltage-current conversion, filter general voltage loads such as electromagnetic waves and noise in the circuit, and remove them through the ground.

However, the manufacturing process of winding two sets of enamel wires on an iron core is time consuming, expensive to manufacture, and takes up a large volume and space. I can't respond.
Furthermore, if it is necessary to apply a large number of transformers simultaneously, it is necessary to electrically connect a large number of transformers one by one to the circuit of the electronic device, which increases the difficulty of processing operations. That is, there are a number of drawbacks when actually implementing a transformer.

Utility Model Registration No. 3167476

  An object of the present invention is to provide a structure of a magnetic component.

  In the magnetic component according to the present invention, one or more convex bases having a plurality of conductors are processed on the opposing surfaces of one base material, and the one or more convex bases are equally spaced. A plurality of conductors spaced apart from each other and opposed to the one or more convex bases are provided with a plurality of conductive contacts on the surface of the other substrate, whereby the plurality of conductors and the plurality of conductors are arranged. Corresponding electrical contact points provide electrical contact and electrical continuity, and one or more magnetic cores are assembled on opposite surfaces of the two substrates, and one or more magnetic conductors are assembled. The inner core is provided with a plurality of stereotaxic tank holes, each of which is drilled with one or more convex bases, and one or more magnetically conductive cores and one or more. A large number of continuous winding conductor induction coil effect sensing areas are formed between multiple conductors and multiple conductive contacts , To accelerate the molding of magnetic parts, can achieve the purpose of cost reduction.

  The magnetic component according to the present invention achieves the purpose of reducing the manufacturing cost and enhancing the economic effect.

It is a three-dimensional external view of the present invention. It is the three-dimensional exploded view of this invention. It is a three-dimensional exploded view from another viewing angle of the present invention. It is a three-dimensional external view of the first embodiment of the present invention. It is a three-dimensional exploded view of the first embodiment of the present invention. It is a three-dimensional external view of the second embodiment of the present invention. It is a three-dimensional exploded view of the second embodiment of the present invention. It is a three-dimensional exploded view from another viewing angle of the second embodiment of the present invention. It is side view sectional drawing of 2nd Example of this invention. It is side sectional drawing (1) which shows the assembly method of 2nd Example of this invention. It is side view sectional drawing (2) which shows the assembly method of 2nd Example of this invention. It is a three-dimensional exploded view of the second embodiment of the present invention. It is a three-dimensional exploded view from another viewing angle of the second embodiment of the present invention. It is side view disassembled sectional drawing of 2nd Example of this invention. It is a three-dimensional exploded view of the third embodiment of the present invention. It is a three-dimensional exploded view of the fourth embodiment of the present invention. It is sectional drawing of the side view of 4th Example of this invention.

  As shown in FIG. 1 to FIG. 9, the structure of the magnetic component according to the present invention includes two base materials 1 and one or more magnetic inner cores 2.

  The two base materials 1 are provided with one or more convex bases 11 and a plurality of conductive contacts 12 each having a plurality of concave holes 111 and a plurality of conductors 112 on opposite surfaces through a machining method. In each of the conductors 112, 1 corresponds to each conductive contact 12 and exhibits electrical connection and conduction, respectively.

  A plurality of localization tank holes 21 are installed in the one or more magnetically conductive inner cores 2, and localization side edges 22 are installed on both outer sides of the respective localization tank holes 21.

  At the time of assembling each of the above-described constituent members, one or more magnetic inner cores 2 are assembled between the two base materials 1, and one or more convex bases 11 are connected to each stereotaxic tank hole. The convex base 11 pierced in 21 and located on the outside contacts with each of the two localization side edges 22, and thus by the two base materials 1, one, or one or more magnetic guide cores 2. The structure of the magnetic component according to the present invention is configured, and the magnetic component can be an applied type such as an inductor, a transformer or other magnetic sensing component.

  The two base materials 1 are circuit boards (PCBs) or flexible circuit boards, and the two base materials 1 are provided with a predetermined wiring layout, and one of the base materials 1 is an outer surface. In addition, at least one set of input side 13 and output side 14 is installed.

  Moreover, the two base materials 1 include a first base material 101 having one or more convex bases 11 on the surface and a second base material 102 having a plurality of conductive contacts 12 on the surface.

  On the opposite side of the first base material 101, a plurality of conductors 112 are respectively bored in each concave hole 111 of one or more convex bases 11, and at least one set of input sides is provided on the opposite surface. 13, the output side 14 is installed, and one or more magnetic inner cores 2 are assembled on the opposing surfaces of the first base material 101 and the second base material 102, and one or more A plurality of localization tank holes 21 are installed in the magnetic inner core 2, one or more convex bases 11 of the first base material 101 are drilled and localized, and a plurality of localization tank holes 21 are formed. One or one or more convex bases 11 can be designed to have a homogenous shape and can have a rectangular or elliptical shape.

  The first base material 101 is formed with a plurality of concave holes 111 that are arranged on the surface through cutting, and each of the concave holes 111 is further drilled, electroplated, and injected with a conductive adhesive. The plurality of conductors 112 are formed through a processing method such as conductive wiring printing or welding.

  A first convex base positioned on both outer sides of the surface of the first base material 101 on the surface of the first base material 101 of the plurality of concave holes 111 and the plurality of conductors 112 using a machining method such as milling, polishing or planing. The body 1101 and the ninth convex base body 1109 are formed, and the first and ninth convex base bodies 1101 and 1109 are drilled, electroplated, welded, or the like inside each concave hole 111 having a single arrangement method. A plurality of conductors 112 are formed using a method.

  Between the first convex base 1101 and the ninth convex base 1109, the second convex base 1102, the third convex base 1103, the fourth convex base 1104, the fifth convex base 1105, A six-convex base body 1106, a seventh convex base body 1107, and an eighth convex base body 1108 are installed, and between the second convex base body 1102 and the eighth convex base body 1108, an equidistant arrangement is provided. A plurality of concave holes 111 having a two-row arrangement system are provided from the second convex base 1102 to the eighth convex base 1108.

  That is, inside each concave hole 111, a plurality of conductors 112 are formed by using a processing method such as drilling, electroplating, conductive adhesive injection, conductive wiring printing, or welding, and one or more conductive materials are formed. In the magnetic core 2, seven localization tank holes 21 are provided, and the second convex base 1102 to the eighth convex base 1108 are respectively drilled.

  Thus, the first convex base 1101 and the ninth convex base 1109 come into contact with the positions of the localization side sides 22 installed on both sides of one or more magnetic conducting cores 2, respectively, and one or one or more. The magnetically conductive inner core 2 is fixedly installed inside the first base material 101 and the second base material 102.

  The plurality of conductors 112 in the single row of the first convex base 1101 and the plurality of conductors 112 in the single row of the second convex base 1102 that are adjacent to each other are connected through the conductive layer 113 to be electrically connected. A first sensing area 231 is formed corresponding to the two or more magnetically conductive inner cores 2.

  A plurality of adjacent two rows of conductors 112 between the second convex base 1102 and the third convex base 1103 are connected through the conductive layer 113 to be conductive, and one or more magnetic inner cores 2 are provided. Corresponding to the formation second sensing area 232;

  A plurality of adjacent rows of conductors 112 between the third convex base 1103 and the fourth convex base 1104 are connected through the conductive layer 113 to be conductive, and further, one or more magnetic cores. 2, a third sensing area 233 is formed.

  A plurality of adjacent two rows of conductors 112 between the fourth convex base 1104 and the fifth convex base 1105 are also connected through the conductive layer 113 to be conductive, and further, one or more magnetic cores 2 are provided. And a fourth sensing area 234 is formed.

  The adjacent two rows of conductors 112 between the fifth convex base body 1105 and the sixth convex base body 1106 are also connected through the conductive layer 113 to be conductive, and further, one or more magnetic cores. Corresponding to 2, a fifth sensing area 235 is formed.

  The adjacent two rows of conductors 112 between the sixth convex base body 1106 and the seventh convex base body 1107 are connected through the conductive layer 113 to be conductive, and further, one or more magnetic cores. Corresponding to 2, the sixth sensing area 236 is formed.

  A plurality of adjacent two rows of conductors 112 between the seventh convex base 1107 and the eighth convex base 1108 are connected through the conductive layer 113 to be conductive, and further one or more magnetic cores 2 are provided. And a seventh sensing area 237 is formed.

  The plurality of conductors 112 in the single row of the ninth convex base 1109 adjacent to the plurality of conductors 112 in the single row of the eighth convex base 1108 are connected through the conductive layer 113 to be conductive, and one or one more The eighth sensing area 238 is formed corresponding to the two or more magnetically conductive inner cores 2.

  Each sensing area 23 forms one or more magnetic cores 2 and a continuous winding conductor induction coil effect.

  Moreover, the above-mentioned second base material 102 is provided with a position-limited section 15 on the surface, and one or more magnetically conductive cores 2 are fixed and installed in correspondence with each other. On the edge, a first ward corresponding connecting portion 151 and a ninth ward corresponding connecting portion 159 are installed.

  Each of the plurality of conductive contacts 12 has a single arrangement method, and is sequentially connected between the first section corresponding connection section 151 and the ninth section corresponding connection section 159, the second section corresponding connection section 152, and the third section corresponding connection section 153. , The fourth ward corresponding connecting part 154, the fifth ward corresponding connecting part 155, the sixth ward corresponding connecting part 156, the seventh ward corresponding connecting part 157, the eighth ward corresponding connecting part 158 and the like are installed.

  Moreover, the second section corresponding connection section 152 to the eighth section corresponding connection section 158 have an equidistant arrangement, and the second section corresponding connection section 152 to the eighth section corresponding connection section 158 each have a plurality of conductive contacts. 12 are installed and each presents a two-row parallel system.

  Further, the above-described one or more magnetically conductive cores 2 are made of a magnetic material having a rectangular shape and made of a magnetic material such as nickel zinc, manganese zinc, an amorphous magnetic material, or a magnetic alloy material. Alternatively, the outer surfaces of one or more magnetically conductive inner cores 2 form a fixed bond with the surfaces of the two base materials 1 through the adhesive 3.

  As shown in FIGS. 2, 7, 9, 10, and 11, the structure of the magnetic component according to the present invention is as follows. One or more magnetic inner cores 2 are connected and fixed and coupled in correspondence with the position limited section 15 of one base material 1, and one or more magnetic inner cores 2 are connected to the base material 1. It is localized at the position limited section 15 position.

  In addition, each localization tank hole 21 of one or more magnetically conductive inner cores 2 corresponds to the second section corresponding connecting section 152 to the eighth section corresponding connecting section 158 formed by each conductive contact 12.

  Thereby, the 1st section corresponding connection part 151 and the 9th section corresponding connection part 159 which exhibit the single arrangement system of the several electrically conductive contact 12 of both outer sides are the outer sides of one or one or more magnetism inner cores 2 It is located outside the localization side 22 respectively.

  Furthermore, each convex base 11 (from the second convex base 1102 to the eighth convex base 1108) of the other base material 1 is drilled corresponding to each stereotaxic tank hole 21, and each outer side The convex base body 11 (first convex base body 1101 and ninth convex base body 1109) is located outside the two localization side edges 22 of one or more magnetically conductive cores 2, thereby each convex In the base body 11 (the first convex base body 1101 to the ninth convex base body 1109), the plurality of conductors 112 to be molded in each concave hole 111 are connected through the conductive layer 113 to be conductive.

  Further, the first and second contact connection portions 151 to 159 of the position-limited section 15 exhibit a relative electrical contact continuity with each of the conductive contact 12 of the ninth ward connection connection portion 159, and Are electrically compliant and connected through surface mount technology (SMT).

  Between the plurality of conductors 112, the plurality of conductive layers 113, and the plurality of conductive contacts 12 of the first section corresponding connection section 151 to the ninth section corresponding connection section 159, a plurality of sensing areas 23 of a continuous winding type conductor induction coil effect are provided. A plurality of conductors 12 having a single arrangement method are formed on the surfaces of the first and ninth convex bases 1101 and 1109 of the first plate body 11 by electroplating, respectively, and good conductor induction is achieved. Coil, rectification, transformation performance, etc. can be formed, that is, one or more magnetic inner cores 2 are localized between two base materials 1 to constitute the structure of the magnetic component according to the present invention.

  As shown in FIGS. 2, 4, 7, 12, 13, 14, and 15, one or more magnetic inner cores 2 are assembled between the two base materials 1. Then, two or two or more magnetic cores 2 are assembled between two base materials 1 and the two magnetic cores 2 are the first magnetic core 201 and the second magnetic core. A wick 202 is provided.

  In addition, three localization chamber holes 21 are provided in the first magnetic guide core 201 and the second magnetic guide core 202, respectively, and the first magnetic guide core 201 and the second magnetic guide core 202 are connected to the base. The three localization tank holes 21 of the first magnetic guiding inner core 201 are localized in the position-limited section 15 of the material 1 (second base material 102), and the second section corresponding connection section 152 and the third section corresponding connection section 153. And the three localization chamber holes 21 of the second magnetic core 202 correspond to the sixth section corresponding connection section 154, the sixth section corresponding connection section 156, the seventh section corresponding connection section 157, and the eighth section, respectively. It corresponds to the corresponding connection part 158, respectively.

  The fifth section corresponding connecting portion 155 is located at an inner distance distance 203 at which the first magnetic inner core 201 and the second magnetic inner core 202 are adjacent to each other. The ninth section corresponding connection portion 159 is located outside the second localization side side 2012 on the one side of the second magnetic guiding core 202, and is located outside the first constant side side 2011 on the one side of the inner core 201.

  Furthermore, the plurality of convex bases 11 of the other base material 1 (first base material 101) are formed corresponding to the respective stereotaxic tank holes 21, respectively, and the second convex base 1102 and the third base The convex base 1103 and the fourth convex base 1104 are respectively formed in the three localization tank holes 21 of the first magnetic guiding inner core 201.

  The sixth convex base 1106, the seventh convex base 1107, and the eighth convex base 1108 are respectively drilled in the three localization tank holes 21 of the second magnetic guide core 202, and the fifth convex base 1105. Is drilled at the inner distance distance 203 position where the first magnetic inner core 201 and the second magnetic inner core 202 are adjacent to each other.

  The first convex base 1101 is in contact with the first fixed side 2011 on the outside of the first magnetic guiding core 201, and the ninth convex base 1109 is on the second localizing side 2012 outside the second magnetic guiding core 202. Accordingly, the plurality of conductors 112 formed by the respective convex base bodies 11 (the first convex base body 1101 to the ninth convex base body 1109) in the respective concave holes 111 are connected to the first section corresponding connection portions 151. Corresponding to the plurality of conductive contacts 12 at the position 159 corresponding to the ninth section, the plurality of conductors 112 and the plurality of conductive contacts 12 of the two base materials 1 respectively exhibit electrical connection and conduction, A plurality of sensing areas 23 of a continuous winding type conductor induction coil effect are formed corresponding to each of the inner core 201 and the second inner core 202, and the structure of the magnetic component of the first embodiment of the present invention is configured. To do.

  Further, in the third embodiment of the structure of the magnetic component according to the present invention, one or more magnetic inner cores 2 are assembled between the two base materials 1, and thereby one or more magnetic cores are assembled. The magnetic core 2 includes a third magnetic core 204, a fourth magnetic core 205, a fifth magnetic core 206, and a sixth magnetic core 207.

  Thus, the third magnetic inner core 204 is assembled in correspondence with the eighth convex base 1108 of the first base material 101, and the fourth magnetic inner core 205 is the sixth convex base of the first base material 101. 1105, the fifth magnetic inner core 206 is assembled corresponding to the fourth convex base 1104 of the first base material 101, and the sixth magnetic inner core 207 is the first base material 101. The second convex base 1102 is assembled.

  In this way, the third convex base 1103 is located at the inner distance distance 203 of the two adjacent fifth magnetic inner cores 206 and the sixth magnetic inner core 207, and the fifth convex base 1105 is The fifth convex magnetic core 206 and the fourth magnetic conductive core 205 are located at 203 distances on the inner side opposite to each other, and the seventh convex base 1107 has two adjacent fourth fourth magnetic cores 206. It is located at 203 distances on the inner side where the inner core 205 and the third inner core 204 face each other.

  Thus, the first convex base 1101 to the ninth convex base 1109 are isolated from the third magnetic guiding core 204 through the sixth magnetic guiding core 207, and each convex base 11 (first The plurality of conductors 112 drilled in the inside of the first convex base 1101 to the ninth convex base 1109) are provided at the positions of the first base corresponding connection part 151 to the ninth base corresponding connection part 159 of the second base material 102. Correspond to the conductive contacts 12 respectively.

  In this way, the plurality of conductors 112 and the plurality of conductive contacts 12 of the two base materials 1 exhibit electrical connection and conduction, respectively, and are respectively connected from the third magnetic core 204 to the sixth magnetic core 207. The conductor 112 and each conductive contact 12 correspond to the third magnetic core 204 to the sixth magnetic core 207, respectively, and form a plurality of sensing areas 23 of a continuous winding type conductor induction coil effect, and the present invention Third Embodiment The structure of a magnetic component is constructed.

  As shown in FIGS. 2, 4, 7, 16, and 17, the first base 101 of the present invention is formed by molding a first convex base 1101 to a ninth convex base 1109 through a machining method. A plurality of conductors 112 having a single arrangement method are respectively formed on the surfaces of the ninth convex bases 1101 and 1109 by electroplating.

  Further, a plurality of conductors 112 having a two-row arrangement method are respectively formed on the surface of the second convex base 1102 to the eighth convex base 1108 by electroplating, and the first convex base 1101 to the ninth convex Each conductor 112 on the surface of the base body 1109 includes a first conductive section 1121 located on the surface, a second conductive section 1122 extending to the opposing inner surface, and a third conductive section 1123 located on the inner bottom surface.

  The adhesive 3 is applied to the two surfaces of the one or more magnetic inner cores 2 and the inner wall surface of each localization tank hole 21, whereby one or one or more magnetic inner cores 2 and The first and second conductive sections 1121 and 1122 of each conductor 112 of the first convex base 1101 to the ninth convex base 1109 are isolated and do not make electrical contact.

  However, one or more magnetic inner cores 2 form electrical contact and electrical connection with any two adjacent third conductive sections 1123, respectively, from the first convex base 1101 to the ninth. The first conductive sections 1121 of the plurality of conductors 112 of the convex base 1109 are in electrical contact with the plurality of conductive contacts 12 on the surface of the second substrate 102, respectively.

  The plurality of conductors 112 correspond to one or more magnetic cores 2 and a plurality of conductive contacts 12, and include a first sensing area 231, a second sensing area 232, a second sensing area 232 of a continuous winding type conductor induction coil effect. A plurality of sensing areas 23 including a third sensing area 233, a fourth sensing area 234, a fifth sensing area 235, a sixth sensing area 236, a seventh sensing area 237, and an eighth sensing area 238 are formed. Configure the structure of the magnetic component.

  The present invention has novelty that is a requirement for patent registration, has sufficient progress compared to similar products of the past, is highly practical, meets social needs, and has a very high industrial utility value .

1 base material 101 first base material 102 second base material 11 convex base body 1101 first convex base body 1102 second convex base body 1103 third convex base body 1104 fourth convex base body 1105 fifth convex base body 1106 sixth Convex base 1107 seventh convex base 1108 eighth convex base 1109 ninth convex base 111 concave hole 112 conductor 1121 first conductive section 1122 second conductive section 1123 third conductive section 113 conductive layer 12 conductive contact 13 input Side 14 Output side 15 Position limited section 151 1st ward corresponding connection part 152 2nd ward corresponding connection part 153 3rd ward corresponding connection part 154 4th ward corresponding connection part 155 5th ward corresponding connection part 156 6th ward corresponding connection Portion 157 Seventh Ward Corresponding Connection Portion 158 Eighth Ward Corresponding Connection Portion 159 Ninth Ward Corresponding Connection Portion 2 Magnetic Conductor Core 201 First Magnetic Conductor Core 2011 First Constant Side Side 2012 Second Localization Side 202 Second magnetic core 203 Spacing distance 204 Third magnetic core 205 Fourth magnetic core 206 Fifth magnetic core 207 Sixth magnetic core 21 Localization chamber hole 22 Localization side 23 Sensing area 231 1st sensing area 232 2nd sensing area 233 3rd sensing area 234 4th sensing area 235 5th sensing area 236 6th sensing area 237 7th sensing area 238 8th sensing area 3 Adhesive

Claims (3)

The structure of the magnetic component has two base materials and one or more magnetic cores,
The two base materials have one or more convex bases having a plurality of conductors on the opposing surfaces through machining, and a plurality of the plurality of conductors correspondingly in electrical contact with each other. Forming conductive contacts,
The one or more conductive inner cores are assembled between one or more convex bases and a plurality of conductive contacts on the surface facing two base materials, and the one or one The above-mentioned magnetic inner core is provided with a plurality of stereotaxic holes for drilling the one or more convex bases, respectively, and the one or one or more magnetic inner cores and the 1 A structure of a magnetic component, wherein a plurality of sets of continuous winding type conductor induction coil effect sensing areas are formed between a plurality of conductors of one or more convex bases and a plurality of conductive contacts. The two substrates are a circuit board (PCB) or a flexible circuit board.
A predetermined wiring layout is installed on the two base materials, and the input side and the output side are extended on the outer surface of one of the base materials, and the opposite surface has A plurality of concave holes are formed using cutting, and a plurality of conductive holes are formed in each of the concave holes by using drilling, electroplating, conductive adhesive injection, conductive wiring printing, or welding processing methods. Forming one or more convex bases using a milling, polishing or planing machining method on the surface, and the one or more convex bases are: Each presents an equidistant distance array,
The two substrates are a circuit board (PCB) or a flexible circuit board, and the two substrates are provided with a predetermined wiring layout, and one of the substrates has an input on the outer surface. One side or the output side is extended and installed, and one or more convex bases are formed on the opposite surface using a machining method, and the one or more convex bases are formed. Each have an equidistant distance array, and one or more convex base surfaces, relative inner side surfaces and inner bottom surfaces are each formed with a plurality of conductors by electroplating,
Between the one or one or more outer surfaces of the magnetic inner core and the opposing surfaces of the two substrates, a fixed-bonding adhesive is installed,
Moreover, the two base materials include a first base material having one or more convex bases on the surface, a second base material having a plurality of conductive contacts on the surface, and the first base material surface. Forms a plurality of concave holes through a cutting process, and uses a processing method of drilling, electroplating, conductive adhesive injection, conductive wiring printing, or welding in each concave hole to form a plurality of conductors. The base material surface provided with a plurality of concave holes and a plurality of conductors is further formed into one or more convex bases using a milling, polishing or planing machining method. The one or more convex bases each have an equidistant distance arrangement and are opposed to the one or more convex bases, and at least one set of input sides on the surface opposite to the first substrate. The output side is installed, and one or more convex bases have a plurality of Electrodes are respectively drilled, and one or more magnetic inner cores are assembled on the opposing surfaces of the first base material and the second base material. 2. The structure of a magnetic component according to claim 1, wherein a plurality of stereotaxic tank holes for drilling one or more convex bases of the first base material are provided in the core. The first base material is provided with a plurality of conductors on both sides on the surface, and a first convex base body and a ninth convex base body exhibiting a single array system are installed, the first and ninth convex bodies Between the bases, second to eighth convex bases which are arranged in an equidistant distance in order are installed, and the second to eighth convex bases are a plurality of conductors exhibiting a two-row array system. 7 positioning tank holes for drilling the second to eighth convex bases are provided in at least one of the magnetic inner cores, and the at least one magnetic inner core On the outside, set the localization side where the first and ninth convex bases contact each other,
The plurality of conductors in the second convex base single row adjacent to the plurality of conductors in the single row of the first convex base includes a conductive layer that electrically connects the respective conductors, and one or one Corresponding to more than one conductive inner core, install a first sensing area that forms a continuous winding conductor induction coil effect,
The plurality of adjacent conductors between the second convex base and the third convex base include a conductive layer that electrically connects each of the conductors, and one or more magnetic conductors. Installed a second sensing area corresponding to the inner core, forming a continuous winding type conductor induction coil effect,
The plurality of adjacent conductors between the third convex base and the fourth convex base include a conductive layer that electrically connects each of the conductors, and one or more magnetic conductors. Installed a third sensing area corresponding to the inner core, forming a continuous winding type conductor induction coil effect,
The plurality of adjacent conductors between the fourth convex base and the fifth convex base include a conductive layer that electrically connects each of the conductors, and one or more magnetic conductors. Corresponding to the inner core, install a fourth sensing area that forms a continuous winding type conductor induction coil effect,
The plurality of adjacent conductors between the fifth convex base and the sixth convex base include a conductive layer that electrically connects each of the conductors, and one or more magnetic conductors. Corresponding to the inner core, install a fifth sensing area that forms a continuous winding conductor induction coil effect,
The plurality of adjacent conductors between the sixth convex base and the seventh convex base include a conductive layer that electrically conducts each of the conductors, and one or more magnetic conductors. Corresponding to the inner core, install a sixth sensing area that forms a continuous winding conductor induction coil effect,
The plurality of adjacent conductors between the seventh convex base and the eighth convex base include a conductive layer that electrically conducts each of the conductors, and one or more magnetic conductors. Installed the seventh sensing area corresponding to the inner core, forming a continuous winding type conductor induction coil effect,
The plurality of conductors in a single row of the ninth convex base adjacent to the plurality of conductors in the single row of the eighth convex base includes a conductive layer that electrically connects each of the conductors, or one or Set up an eighth sensing area corresponding to one or more magnetic cores, forming a continuous winding conductor induction coil effect,
The second base material is provided with a position-limited section on the surface correspondingly fixing the one or more magnetically conductive inner cores, and a plurality of conductive materials are provided on both outer edges of the position-limited section. A first zone corresponding connection portion and a ninth zone corresponding connection portion in which the contacts have a single arrangement method are installed, and a second arrangement in which an equidistant distance array is sequentially provided between the first zone and the ninth zone corresponding connection portion. A plurality of conductive contacts having a two-row arrangement method are respectively installed from the second ward to the eighth ward corresponding connection portion from the second ward to the eighth ward corresponding connection portion. 2. The structure of the magnetic component according to 2.