阅读说明：本技术 一种电感、汽车及电感的制备方法 (Inductor, automobile and manufacturing method of inductor ) 是由 李耀光 黄敬新 赵基界 尉朗 李科伟 于 2021-07-15 设计创作，主要内容包括：本申请公开了一种电感、汽车及电感的制备方法,具体涉及电子半导体技术领域,其电感包括：盖板、磁芯、两个绝缘体、导电端子以及线圈,绝缘体分别位于磁芯的两端,磁芯和每个绝缘体之间均卡设有至少一个导电端子,导电端子从绝缘体的表面伸出,伸出部分为导电端子的凸出部；磁芯上绕设有线圈,线圈的线头向磁芯的一端延伸,连接于该端导电端子的凸出部；线圈的线尾向磁芯的另一端延伸,连接于端导电端子的凸出部。导电端子所具有的凸出部分别连接线圈的线头和线尾,使线圈的引出线不直接于焊接部连接,避免漆包线去除不干净及使用热压焊工艺造成线圈引出线与焊接部连接不稳定情况,进一步使电感元件的连接强度稳定保证电感元件的工作性能。(The application discloses inductance, car and inductance's preparation method, concretely relates to electron semiconductor technology field, and its inductance includes: the conductive terminal comprises a cover plate, a magnetic core, two insulators, conductive terminals and a coil, wherein the insulators are respectively positioned at two ends of the magnetic core; the magnetic core is wound with a coil, and the wire end of the coil extends towards one end of the magnetic core and is connected with the protruding part of the conductive terminal at the end; the tail of the coil extends to the other end of the magnetic core and is connected to the protruding part of the end conductive terminal. The salient parts of the conductive terminals are respectively connected with the wire head and the wire tail of the coil, so that the outgoing wire of the coil is not connected with the welding part directly, the situations that the outgoing wire of the coil is not removed cleanly and the connection between the outgoing wire of the coil and the welding part is unstable due to the use of a hot-press welding process are avoided, and the connection strength of the inductance element is further stabilized to ensure the working performance of the inductance element.)

1. An inductor, comprising: the conductive terminal comprises a cover plate, a magnetic core arranged on the cover plate, two insulators arranged on the magnetic core, conductive terminals and a coil, wherein the two insulators are respectively positioned at two ends of the magnetic core;

the magnetic core is wound with at least one coil, and the wire end of the coil extends towards one end of the magnetic core and is connected with the protruding part of the conductive terminal at the end; the tail of the coil extends to the other end of the magnetic core and is connected with the bulge of the end conductive terminal.

2. The inductor as claimed in claim 1, wherein said magnetic core comprises: the coil is wound on the first magnetic column, the two insulators are fixedly connected with the two second magnetic columns respectively, and the conductive terminals are clamped on the surfaces of the insulators respectively.

3. The inductor according to claim 2, wherein a bump is disposed in the middle of the second magnetic pillar, and grooves are disposed at two ends of the second magnetic pillar and the bump of the second magnetic pillar; a concave part is arranged in the middle of the insulator, and bosses are arranged at two ends of the insulator and the concave part of the insulator; the lug of the second magnetic column is accommodated in the sunken part of the insulator, the groove on the lug of the second magnetic column is matched and connected with the boss of the sunken part of the insulator, the bosses at two ends of the insulator are matched and connected with the grooves at two ends of the second magnetic column, and the conductive terminal is clamped between two ends of the second magnetic column and two ends of the insulator and is arranged on the side edge of the boss of the insulator.

4. The inductor according to claim 2, wherein a chamfer or fillet is provided at a junction of the first magnetic pillar and the second magnetic pillar.

5. The inductor according to claim 2, wherein the conductive terminal further comprises a connecting portion and a soldering portion, the soldering portion is used for being soldered to an external circuit, the connecting portion comprises a first portion and a second portion, the first portion of the connecting portion is disposed between the insulator and the second magnetic pillar, the second portion is embedded in the insulator, the protruding portion of the conductive terminal extends from the first portion of the connecting portion, and the soldering portion extends from the second portion and is hooked to an end portion of the insulator.

6. An inductor according to claim 5, wherein the side of the protruding portion is provided with a groove, and the head or tail of the coil is connected to the protruding portion and is clamped in the groove of the protruding portion.

7. The inductor of claim 1, wherein the insulator is a gel.

8. An inductor according to claim 1, characterised in that the protrusions are provided with solder joints fixedly connecting the coil to the protrusions.

9. A method of making an inductor, the method comprising:

providing a magnetic core mold, wherein the magnetic core mold is used for manufacturing a magnetic core;

placing the magnetic core material into a magnetic core die to form a magnetic core;

sequentially placing the magnetic core and the conductive terminal material into an inductance mold, and injecting an insulating material to form an insulator; the conductive terminal material comprises a connecting frame and at least two conductive terminals connected in the connecting frame;

removing the connecting frame on the conductive terminal material;

taking out the combined magnetic core formed by combining the conductive terminal, the magnetic core and the insulator from the inductance mold; the magnetic core is fixedly connected with the insulator, the conductive terminal extends out of the surface of the insulator, and the extending part is a protruding part of the conductive terminal;

winding the enameled copper wire on the magnetic core to form a coil, extending the wire end of the coil to one end of the magnetic core, and connecting the wire end to the protruding part of the conductive terminal; and a protrusion extending the tail of the coil to the other end of the magnetic core and connected to the end conductive terminal; respectively fixedly connecting the wire head and the wire tail corresponding to the conductive terminals by welding and/or bonding with a conductive adhesive;

and providing a cover plate, and bonding the magnetic core on the cover plate so as to form the inductor.

10. An automobile, comprising: an inductor as claimed in any one of claims 1 to 8 is provided in the vehicle.

Technical Field

The application relates to the technical field of electronic semiconductors, in particular to an inductor, an automobile and a preparation method of the inductor.

Background

As shown in fig. 1, in the inductance component used in the prior art, the inductance coil wire head 10 of the inductance component is connected with the magnetic core metalized electrode 20 by thermocompression bonding, because the paint film of the enameled wire is not easy to be removed completely during the thermocompression bonding of the inductance coil wire head 10, the surface cleanliness of the magnetic core metalized electrode 20 is also difficult to be ensured (for example, the paint film of the enameled wire remains), and the internal resistance of the welding point formed by thermocompression bonding is increased because the surface of the electrode is not easy to be cleaned and the paint film of the copper wire remains; as the temperature of the solder joint increases, the solder joint softens, thereby reducing the strength of the connection between the inductor end 10 and the core metallized electrode 20. For example: when the working temperature of the vehicle inductor exceeds +125 ℃, the wire end and the wire tail of the existing vehicle inductor coil are connected with the magnetic core metalized electrode through hot pressure welding under high mechanical impact, so that the wire end and the wire tail of the inductor coil fall off from the magnetic core metalized electrode, and the working performance of an inductor element is further influenced.

Disclosure of Invention

In view of this, the present application provides an inductor, an automobile, and a method for manufacturing the inductor, which are used to solve the problem in the prior art that the working performance of an inductor element is affected due to the decrease of the connection strength between the end and the tail of an inductor coil and a magnetic core metalized electrode.

According to a first aspect, the present application provides an inductor comprising: the conductive terminal comprises a cover plate, a magnetic core arranged on the cover plate, two insulators arranged on the magnetic core, conductive terminals and a coil, wherein the two insulators are respectively positioned at two ends of the magnetic core; the magnetic core is wound with at least one coil, and the wire end of the coil extends towards one end of the magnetic core and is connected with the protruding part of the conductive terminal at the end; the tail of the coil extends to the other end of the magnetic core and is connected with the bulge of the end conductive terminal.

Optionally, the magnetic core includes: the coil is wound on the first magnetic column, the two insulators are fixedly connected with the two second magnetic columns respectively, and the conductive terminals are clamped on the surfaces of the insulators respectively.

Optionally, a bump is arranged in the middle of the second magnetic column, and grooves are formed in the two ends of the second magnetic column and the bump of the second magnetic column; a concave part is arranged in the middle of the insulator, and bosses are arranged at two ends of the insulator and the concave part of the insulator; the second magnetic column lug is accommodated in the sunken part of the insulator, a groove on the lug of the second magnetic column is matched and connected with a boss of the sunken part of the insulator, bosses at two ends of the insulator are matched and connected with grooves at two ends of the second magnetic column, and the conductive terminal is clamped between two ends of the second magnetic column and two ends of the insulator and is arranged on the side edge of the boss of the insulator.

Optionally, a chamfer or a fillet is arranged at a joint of the first magnetic column and the second magnetic column.

Optionally, the conductive terminal further has a connection portion and a welding portion, the welding portion is used for welding with a peripheral circuit, the connection portion includes a first portion and a second portion, the first portion of the connection portion is disposed between the insulator and the second magnetic pole, the second portion is embedded inside the insulator, the protruding portion of the conductive terminal extends out of the first portion of the connection portion, and the welding portion extends out of the second portion and is hooked to the end portion of the insulator.

Optionally, a groove is formed in the side portion of the protruding portion, and the head or tail of the coil is connected to the protruding portion and clamped in the groove of the protruding portion.

Optionally, the insulator is a colloid.

Optionally, the protrusion is provided with a solder joint for fixedly connecting the coil to the protrusion.

According to a second aspect, the present application provides a method for manufacturing an inductor, which includes providing a magnetic core mold for manufacturing a magnetic core; placing the magnetic core material into a magnetic core die to form a magnetic core; sequentially placing the magnetic core and the conductive terminal material into an inductance mold, and injecting an insulating material to form an insulator; the conductive terminal material comprises a connecting frame and at least two conductive terminals connected in the connecting frame; removing the connecting frame on the conductive terminal material; taking out the combined magnetic core formed by combining the conductive terminal, the magnetic core and the insulator from the inductance mold; the magnetic core is fixedly connected with the insulator, the conductive terminal extends out of the surface of the insulator, and the extending part is a protruding part of the conductive terminal; winding enamelled copper wire around locating the magnetic core, forming the coil, will the end of a thread of coil to the one end of magnetic core extends, and be connected to conductive terminal's bulge, and will the end of a thread of coil to the other end of magnetic core extends, and be connected to this end conductive terminal's bulge, through the welding, and/or, electrically conductive adhesive bonds, corresponds end of a thread and end of a thread respectively conductive terminal links firmly, provides the apron, bond the magnetic core in on the apron, thereby form the inductance.

According to a third aspect, the present application provides an automobile comprising: the inductor provided by the first aspect.

The application provides an inductance, through set up conductive terminal between magnetic core and insulator, the line head and the line tail of coil are connected to the bulge that utilizes conductive terminal to have, so that the lead-out wire of coil can not directly connect in the welding part lug connection, thereby avoid the enameled coil to get rid of unclean and the coil lead-out wire and the unstable condition of welding part connection that hot pressure welding technology caused, and through being connected the lead-out wire (line head or line tail) of coil with the protruding portion of conductive terminal, later link to each other with product or circuit through the welding part of conductive terminal, thereby make its inductance component's joint strength more stable, further guarantee inductance component's working property.

According to the inductor preparation method, the magnetic core, the conductive terminals and the insulator are pressed into a whole through an injection molding solidification process, then the protruding parts of the conductive terminals are fixedly connected with the wire ends and the wire tails of the coils, and finally the cover plate is installed, so that the coil paint film is prevented from being removed cleanly and the electrode surface cleanliness is low due to the fact that a hot pressing process is used in the prior art, the connection stability of the inductor coils and the working performance stability of the inductor elements are improved, and the difficulty of the inductor preparation process is reduced.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present application and together with the description, serve to explain the principles of the application. In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings needed to be used in the description of the embodiments will be briefly described below, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise.

Fig. 1 is a schematic structural diagram of an inductor used in the prior art;

fig. 2 is a schematic structural diagram of an inductor according to this embodiment;

fig. 3 is a schematic structural diagram of an optional inductor provided in this embodiment;

fig. 4 is a schematic structural diagram of an alternative inductor core provided in this embodiment;

fig. 5 is a schematic structural diagram of an alternative inductive insulator provided in this embodiment;

fig. 6 is a schematic structural diagram of an optional conductive terminal of an inductor according to this embodiment;

fig. 7 is a schematic structural diagram of an optional conductive terminal of an inductor according to this embodiment;

fig. 8 is a schematic diagram of an alternative connection structure of the inductor according to the present embodiment;

fig. 9 is a schematic structural diagram of a magnetic core of an alternative inductor according to this embodiment;

fig. 10 is a schematic structural diagram of an alternative inductor provided in this embodiment;

fig. 11 is a schematic structural diagram of an alternative inductor provided in this embodiment;

fig. 12 is a schematic structural diagram of an alternative inductor provided in this embodiment;

fig. 13 is a schematic structural diagram of an alternative inductor provided in this embodiment;

fig. 14 is a flowchart of a method for manufacturing an inductor according to this embodiment.

Reference numerals

10-an inductor coil stub; 20-magnetic core metallized electrodes; 30-a cover plate; 40-a magnetic core; 50-an insulator; 60-conductive terminals; 70-a coil; 80-welding spots; 401 — a first magnetic pillar; 402-a second magnetic pillar; 402 a-groove; 402 b-chamfering; 501-a boss; 601-a projection; 602-a connecting portion; 603-a weld; 602 a-a first portion of the connection; 602 b-the second part of the connection.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present application. Rather, they are merely examples of apparatus and methods consistent with certain aspects of the present application, as detailed in the appended claims.

It is to be noted that, unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs; the terminology used in the description presented herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention, e.g., the terms "top," "bottom," "inner," "outer," "upper," "lower," etc., refer to orientations and positions shown in the drawings, which are for convenience of description only and are not to be construed as limiting the present disclosure.

As shown in fig. 1, in the prior art, an inductance coil stub 10 is connected to a magnetic core metalized electrode 20 by thermocompression bonding, which burns a paint film of the inductance coil in the thermocompression bonding process, and a foreign matter that is not easily removed remains, so that when the stub of the inductance coil is connected to the metal electrode, internal resistance increases, temperature rise of the solder joint is high, which causes the solder joint connected to the stub and the tail of the coil to soften, thereby affecting the stability of the connection between the stub and the tail of the inductance coil and the electrode, and in order to improve the connection strength and the connection point stability of the stub and the tail of the inductance coil, the working performance of the inductance coil is ensured, therefore, the present embodiment provides an inductance, which can be a common mode inductance or a differential mode inductance, and can be applied to an inductance in an automobile, and in addition, the inductance provided by the present embodiment can also be applied to a severe environment, such as high temperature, low temperature, mechanical vibrations.

As shown in fig. 2, a schematic structural diagram of an inductor provided in this embodiment is that, in the inductor, conductive terminals are added by changing a connection structure between an existing inductor and an electrode, and a stub and a tail of the inductor are fixedly connected by a protruding portion of the conductive terminal, and then a welding portion of the conductive terminal is used as the electrode, so that a phenomenon that a paint film of the inductor remains on a surface of the electrode due to the fact that the stub and the tail of the inductor need to be connected with a metallized electrode in a hot-press welding manner, which affects the stability of the connection strength of the stub and the tail of the inductor is avoided. In this embodiment, the protruding portion of the metal terminal is connected to the head and tail of the inductor coil, and the head and tail of the inductor coil wound around the protruding portion of the metal terminal are welded by a simple welding process, so as to ensure the stability of the head and tail of the inductor coil when being connected to the electrode.

Specifically, the inductor provided in this embodiment includes: the conductive terminal comprises a cover plate 30, a magnetic core 40 arranged on the cover plate 30, two insulators 50 arranged on the magnetic core 40, conductive terminals 60 and a coil 70, wherein the two insulators 50 are respectively positioned at two ends of the magnetic core 40, at least one conductive terminal 60 is clamped between the magnetic core 40 and each insulator 50, the magnetic core 40 is fixedly connected with the insulators 50, the conductive terminals 60 extend out from the surface of the insulators 50, and the extending parts are protrusions of the conductive terminals; at least one coil 70 is wound on the magnetic core 40, and the wire end of the coil 70 extends towards one end of the magnetic core 40 and is connected with the protruding part of the conductive terminal at the end; the tail of the coil 70 extends toward the other end of the core 40 and is connected to the projection of the end conductive terminal.

In the inductor provided by the embodiment, the conductive terminal 60 is arranged between the magnetic core 40 and the insulator 50, and the terminal and the tail of the coil 70 are connected by using the protrusion part of the conductive terminal 60, so that the lead wire of the coil 70 can not be directly connected with the welding part, thereby avoiding the unstable connection between the lead wire (terminal or tail) of the coil and the welding part caused by the incomplete removal of the enameled coil and the hot-press welding process, and the lead wire (terminal or tail) of the coil is connected with the protrusion part of the conductive terminal and then connected with a product or a circuit through the welding part of the conductive terminal, so that the connection strength of the inductance element is more stable, and the working performance of the inductance element is further ensured.

Optionally, the conductive terminal 60 extends from the surface of the insulator 50, and the extending portion is a protrusion of the conductive terminal, which can be understood as that a part of the conductive terminal 60 is embedded in the insulator 50, and the protrusion of the conductive terminal 60 protrudes out of the outer surface/side surface of the insulator 50, wherein the protrusion is disposed away from the magnetic core 40 wound with the coil 70, so as to prevent a short circuit of the device caused by too close proximity between the conductive terminal 60 and the magnetic core 40 wound with the coil 70. Preferably, the protrusion of the conductive terminal may protrude from the junction of the core 40 and the insulator 50; alternatively, the protrusion of the conductive terminal may protrude from the side surface of the insulator 50.

Optionally, in this embodiment, the protruding portion connected to the conductive terminal may temporarily fix the end or the end of the coil 70 by winding, clamping, or the like, so as to increase the stability of the connection between the coil 70 and the soldering portion, and the connection between the coil 70 and the conductive terminal 60 is also stable by the temporary connection, so as to prevent the end or the end of the coil from accidentally falling off when the coil 70 and the conductive terminal 60 are soldered.

Optionally, in order to save the layout space of the PCB, the cover plate 30 needs to be disposed on the magnetic core 40, and in some special cases, for example, when the inductance performance is considered preferentially, the cover plate 30 may be disposed as a housing, the housing covers the magnetic core 40, the conductive terminals 60 and the insulators 50 in the housing, and the welding portions reserved for the conductive terminals 60 are disposed on the surface of the housing, so as to facilitate the attachment and welding of the inductance component to the PCB.

Optionally, in order to improve the stability of the connection between the magnetic core 40 and the cover plate 30, grooves may be formed at two ends of the cover plate 30, and the grooves at the two ends are respectively used for accommodating the magnetic pillars at the two ends of the magnetic core 40, so as to improve the stability between the magnetic core 40 and the cover plate 30.

Alternatively, the core 40 may be an integrally formed i-shaped core 40, as shown in fig. 2 to 4, and the core 40 may include a center leg and core legs provided at both ends of the center leg of the core 40, and electromagnetic interference caused by a gap generated between the cores 40 can be minimized by using the integrally formed i-shape.

Optionally, the insulator 50 may be a colloid obtained by injection molding and curing of a rubber material adapted to a high temperature environment, preferably, the insulator 50 is a colloid which can ensure that the inductor works in a high temperature environment and the inductor can work normally, and in addition, the insulator 50 is used to separate electrical signals between the conductive terminals 60 and between the magnetic cores 40, so as to prevent the conductive terminals 60 from being short-circuited to influence the normal working performance of the inductor.

Optionally, when the head and the tail of the inductance coil 70 are wound on the protruding portions of the conductive terminals, in order to ensure the connection firmness and further ensure the connection strength between the head and the tail of the inductance coil 70 and the electrodes, the head and the tail of the inductance coil 70 can be fixedly connected with the protruding portions of the conductive terminals 60 by welding on the protruding portions of the conductive terminals.

The present embodiment provides an inductor, which is composed of a cover plate 30, a magnetic core 40, an insulator 50, a conductive terminal 60 and a coil 70, as shown in fig. 2-4, the magnetic core 40 of the inductor may include a first magnetic pillar 401 and two second magnetic pillars 402 respectively disposed at two ends of the first magnetic pillar 401, the two second magnetic pillars 402 are respectively stacked with the two insulators 50, and the conductive terminal 60 is clamped at a connection position of the second magnetic pillar 402 and the insulator 50, wherein the coil 70 is wound on the first magnetic pillar 401, and optionally, a wire of the coil 70 may be an enameled copper wire.

As shown in fig. 2-5, a protrusion is disposed in the middle of the second magnetic pillar 402, and both ends of the second magnetic pillar 402 and the protrusion of the second magnetic pillar 402 are provided with a groove 402 a; a concave part is arranged in the middle of the insulator 50, and bosses 501 are arranged at two ends of the insulator 50 and the concave part of the insulator 50; the second magnetic pillar 402 is accommodated in the recess of the insulator, the groove 402a of the protrusion of the second magnetic pillar 402 is connected with the boss 501 of the recess of the insulator 50 in a matching manner (the size of the groove 402a is matched with that of the boss 501), the bosses 501 of the two ends of the insulator 50 are connected with the grooves 402a of the two ends of the second magnetic pillar 402 in a matching manner, and the conductive terminal 60 is clamped between the two ends of the second magnetic pillar 402 and the two ends of the insulator 50 and is arranged at the side edge of the boss 501 of the insulator 50.

Optionally, the height of the conductive terminal 60 is lower than the height of the boss 501 along the height direction of the boss 501. The size of the groove 402a can be adapted to the size of the protruding boss 501 portion after the conductive terminal 60 is disposed on the side, so that the insulator and the magnetic core can be more fixedly connected.

Alternatively, as shown in fig. 3, in order to increase the connection strength of the magnetic core and the bending resistance of the magnetic core, a chamfer or a fillet is required to be provided at the connection position of the first magnetic pillar 401 and the second magnetic pillar 402.

Optionally, as shown in fig. 2 to 7, the conductive terminal includes: the connection portion 602 includes a first portion 602a of the connection portion disposed between the insulator 50 and the second magnetic pillar 402, a second portion 602b of the connection portion embedded inside the insulator 50, a protrusion 601 of the conductive terminal 60 extending from the first portion 602a of the connection portion, and a soldering portion 603 extending from the second portion 602b of the connection portion and hooked on an end of the insulator 50.

Alternatively, as shown in fig. 6-8, in order to prevent the coil from falling off, the head and tail of the coil 70 can be tightly connected to the protrusion 601, a groove can be provided on the side of the protrusion 601, and the head or tail of the coil 70 is wound around the protrusion 601 and clamped in the groove of the protrusion.

Optionally, in order to further ensure the working performance of the inductor and prevent the problem of the decrease of the connection strength between the head and the tail of the coil caused by environmental factors, as shown in fig. 7, a solder 80 for fixedly connecting the coil 70 to the protrusion may be provided on the protrusion 601 around which the coil 70 is wound.

Alternatively, as shown in fig. 9, in order to fasten the core 40 to the insulator, a chamfer 402b may be provided at a central protrusion of the second pillar 402 of the core or a protrusion parallel to two ends of the second pillar, and a concave portion of the opposite insulator may be provided at a connecting portion where the chamfer/protrusion provided at the central protrusion of the second pillar of the core is engaged with each other, so as to firmly connect the core to the insulator and the conductive terminal.

The inductor provided in this embodiment may further include: the magnetic cover plate is fixedly connected with the combined magnetic core through an adhesive, wherein the adhesive can be magnetic glue, a coil is wound at the middle contraction part of the combined magnetic core, the wire head and the wire tail of the coil are wound on the metal flange extending out of the side surface of the combined magnetic core, the wire head is fixedly connected with the metal flange extending out of the side surface of the combined magnetic core in a conductive manner through welding after the wire head is wound, and a welding spot after the wire head is fixedly connected needs to be trimmed so as to ensure that a connecting point protrudes out of the height of the side surface of the combined magnetic core; optionally, the combined magnetic core may include a magnetic core, a metal terminal and a colloid, and the magnetic core and the metal terminal are combined into a whole through filling and coating of the colloid; optionally, a metal flange is extended from the side surface of the combined magnetic core and used for being connected with the wire head and the wire tail of the coil to form conductive fixed connection, and the bottom surface of the metal terminal is exposed out of the colloid and is in conductive connection with a circuit/product pad when a product is used; optionally, the side surface of the combined magnetic core is also conductively connected with the head and the tail of the coil, and the protrusion is conductively communicated with the bottom surface of the metal terminal; it is optional, the colloid face is exposed to metal terminal bottom outside face, its metal terminal can set up and also can set up in the colloid side in the colloid bottom surface, when being used for the product, can carry out the side and climb tin and AOI (Automated Optical Inspection, automatic Optical Inspection) and detect, metal terminal sets up in magnetic core lower part and colloid interlock, thereby prevent that magnetic core and colloid pine from taking off axial separation, magnetic core lower part surface sets up the slot, prevent that magnetic core and colloid pine from taking off lateral separation, the magnetic core middle contraction position can the chamfer with the protruding connection position of side, promote connection position structural strength.

Alternatively, as shown in fig. 10-13, the conductive terminal soldering portion 603 may be connected to the soldering pad of the circuit board as a soldering pad, the first portion of the conductive terminal connecting portion and the second portion of the connecting portion are folded to be 90 ° and disposed at the connection position between the core 40 and the insulator 50, or the soldering portion and the connecting portion may be directly connected, and finally the protrusion is disposed in the insulator 50.

In the prior art, the magnetic core metalized electrode processing technology is complex, and needs to execute the processing steps of shielding, silver terminating, silver burning, shielding removing, nickel plating, tin plating and the like, so that the cost is relatively high, the electrode quality protection difficulty is high, hazardous waste is generated in the magnetic core metal process, the energy consumption is high, and the policy requirements of energy-saving consumption-reducing clean production are difficult to adapt to, therefore, the embodiment also provides a preparation method of the inductor, as shown in fig. 14, the method is a flow chart of the preparation method of the inductor, and the steps are as follows:

s10, providing a magnetic core mould, wherein the magnetic core mould is used for manufacturing the magnetic core.

And S11, putting the magnetic core material into a magnetic core die to form the magnetic core.

S12, sequentially placing the magnetic core and the conductive terminal material into an inductance mold, and injecting an insulating material to form an insulator; the conductive terminal material comprises a connecting frame and at least two conductive terminals connected in the connecting frame.

And S13, removing the connecting frame on the conductive terminal material.

S14, taking out the combined magnetic core formed by the conductive terminal, the magnetic core and the insulator from the inductance mould; the magnetic core is fixedly connected with the insulator, the conductive terminal extends out of the surface of the insulator, and the extending part is a protruding part of the conductive terminal.

S15, winding the enameled copper wire on the magnetic core to form a coil, extending the wire head of the coil to one end of the magnetic core and connecting the wire head to the protruding part of the conductive terminal, extending the wire tail of the coil to the other end of the magnetic core and connecting the wire tail to the protruding part of the conductive terminal at the end, and fixedly connecting the wire head and the wire tail to the conductive terminal respectively by welding and/or bonding with a conductive adhesive.

And S16, providing a cover plate, and bonding the magnetic core on the cover plate to form the inductor.

In this embodiment, an inductance mold, a magnetic core material, a conductive terminal material, and a glue material for manufacturing an insulator, which are required for manufacturing an inductor, need to be obtained first, where the magnetic core material may also be a finished i-shaped magnetic core; the conductive terminal material is a metal material belt provided with a metal connecting frame, and the conductive terminals with the connecting frame are placed to complete the adjustment of a plurality of conductive terminals at one time, so that the production efficiency of the inductor is improved, and the rubber material can be liquid or an insulator prepared in advance; secondly, sequentially putting magnetic core materials, conductive terminal materials and sizing materials into the inductance mold, and then carrying out injection molding solidification on the filled inductance mold to obtain the combined magnetic core with the metal connecting frame; after the combined magnetic core is obtained, an enameled copper wire needs to be wound on the combined magnetic core, wherein a wire head and a wire tail of the enameled copper wire need to be wound on the protruding part of the conductive terminal, and in order to prevent the enameled wire from falling off from the protruding part due to excessive winding of the enameled coil, a groove needs to be arranged on the protruding part of the conductive terminal for clamping the enameled copper wire, optionally, in order to further prevent the enameled wire from falling off, the ratio of the enameled wire wound on the protruding part of the conductive terminal is not more than three quarters of the protruding part; after the wire head and the wire tail of the enameled copper wire are wound on the protruding parts of the conductive terminals, the wire head and the wire tail of the enameled copper wire and the protruding parts of the conductive terminals need to be fixedly connected in a welding mode, and in order to ensure the attractiveness after welding, the welded welding points need to be cut and trimmed; and finally, bonding the cover plate and the combined magnetic core wound with the enameled wire by using magnetic glue, then testing the inductance performance, and marking and encapsulating on the cover plate after the test is finished, thereby finishing the preparation process of the inductor.

Optionally, the material frame of the conductive terminal needs to be pre-cut before the conductive terminal is placed in the inductor die, so as to facilitate the disassembly of the finished inductor.

Optionally, the enameled copper wire and the conductive terminal protruding part can be connected through laser welding, soft soldering, dip soldering, tin-spraying soldering and the like, and compared with hot-press welding, the welding mode is more sufficient in connection and less in foreign matter and impurity residue.

Optionally, the combined magnetic core may be formed by molding the conductive terminal and the insulator into a whole, and then bonding the i-shaped magnetic core to the combined body of the conductive terminal and the insulator. Optionally, the insulator is made of rubber.

Optionally, in order to ensure that the wire head and the wire tail of the coil can be stably connected with the conductive terminals, the wire head and the wire tail of the coil can be wound on the convex parts of the conductive terminals, the wire head and the wire tail are respectively welded with the corresponding convex parts of the conductive terminals by using a welding process, and after the temperature of a welding spot is cooled, the welded welding spot is encapsulated by using an adhesive, so that the wire head and the wire tail of the coil are stably connected with the convex parts of the conductive terminals, and the working performance of the inductance element is indirectly ensured.

Optionally, in this embodiment, the method may further include: the magnetic core, the conductive terminal and the insulator are fixedly connected, the conductive terminal extends out from the side face of the insulator, and the extending part is a protruding part of the conductive terminal; or, the conductive terminal is fixedly connected with the insulator, the conductive terminal extends out from the side surface of the insulator, the extending part is a protruding part of the conductive terminal, and the magnetic core is adhered and fixed on the conductive terminal and insulator combination body.

In this embodiment, the fixed point terminal of the head and tail of the original enameled copper wire is separated from the Surface Mount Technology (SMT) soldering surface, so that the SMT soldering surface is cleaner, the resistance of the connection between the finished inductor and the PCB pad is smaller, and the connection strength is stronger.

Optionally, the conductive terminal may be a metal conductive terminal, and preferably, the metal terminal is a copper terminal.

In this embodiment, compared with the complex process of tin plating on the ferrite core by the magnetic core metallization electrode used in the prior art group, the difficulty of the tin plating (nickel plating and tin plating) process on the conductive terminal by using the conductive terminal is greatly reduced, the cost is reduced, the quality of the inductor finished product is easy to guarantee, and the complex environment is easier to adapt.

The embodiment provides an automobile, wherein the inductor provided in the above embodiment is disposed in the automobile, and the inductor structure and the manufacturing method thereof can be referred to the above embodiment and are not described herein again.

According to the inductor provided by the embodiment, the structure of an inductor product is optimized, the conductive terminal (terminal outer electrode) is introduced, the connection between the coil and the conductive terminal and the connection surface between the terminal and a PCB (printed circuit board) pad are separated by adjusting the fixed connection position and the fixed connection mode between the coil and the conductive terminal, the reliability of the fixed connection between the coil and the conductive terminal is further improved by laser welding, the quality of the welding surface between the conductive terminal and the PCB is improved, the internal resistance of the connection is reduced, the temperature rise of a welding spot is reduced, the side tin-climbing surface of the conductive terminal is increased to improve the connection strength of the welding spot, and the applicable temperature range of the inductor is expanded to-50 ℃ to +150 ℃ so as to improve the probability of covering all the working temperature ranges of a vehicle.

The above description is only a preferred embodiment of the present application, and not intended to limit the scope of the present application, and all modifications of equivalent structures and equivalent processes, which are made by the contents of the specification and the drawings of the present application, or which are directly or indirectly applied to other related technical fields, are included in the scope of the present application.