The present invention relates to a method of producing a multilayer electronic component used in various electronic equipment.
Recently, there are various electronic components used as surface mount components, such, for example, as multilayer ceramic capacitors and multilayer ceramic varistors. There is a problem which does not occur in a case where the size of these electronic components is small, but which would likely occur as the size of the electronic components increases to increase capacitance or to increase current. Specifically, in a case where the size of the electronic component is increased, a mechanical stress is caused due to the difference in linear expansion coefficient between the circuit board material and the ceramic material, which would likely cause the electronic component to be broken. To avoid this problem, in some conventional electronic components, lead terminals made by machining a metal plate are attached to external terminals at both end surfaces of each electronic component, and the electronic component is mounted via these lead terminals.
A conventional electronic component similar to the above-described electronic component is disclosed in PTL 1.
A sintered body that includes semiconductor ceramic layers and an internal electrode which are alternately stacked on one another is prepared. A first external electrode is formed on a side surface of the sintered body such that the first external electrode is connected to the internal electrode. An insulating layer is formed on a surface of the sintered body by applying a glass coating over an entire of the sintered body having the formed first external electrode. The insulating layer is exposed from the first external electrode. A second external electrode is formed on the first external electrode. This method provides the produced multilayer electronic component with a stable electric connection between the internal electrodes and the external electrodes.
Multilayer electronic component 1000 includes sintered body 11, insulating layer 15 provided on sintered body 11, external electrodes 13A and 13B provided on sintered body 11, external electrode 14A provided on external electrode 13A, external electrode 14B provided on external electrode 13B, plated layer 16A provided on external electrode 14A, plated layer 16B provided on external electrode 14B, bonding material 18A provided on plated layer 16A, bonding material 18B provided on plated layer 16B, lead terminal 17A bonded to plated layer 16A, i.e., to external electrode 14A, with bonding material 18A; and lead terminal 17B bonded to plated layer 16B, or to external electrode 14B, with bonding material 18B. Sintered body 11 includes insulating layers 22 and internal electrodes 12A and 12B which are alternately laminated. Sintered body 11 has side surface 11A from which internal electrodes 12A are exposed, side surface 11B from which internal electrodes 12B are exposed, mount surface 11C which is connected to side surfaces 11A and 11B, opposite surface 11D which is connected to side surfaces 11A and 11B and which is opposite to mount surface 11C, surface 11E which is connected to side surfaces 11A and 11B, mount surface 11C and opposite surface 11D, and surface 11F which is connected to side surfaces 11A and 11B, mount surface 11C and opposite surface 11D and which is opposite to surface 11E. Insulating layers 15 are provided on mount surface 11C, opposite surface 11D, surface 11E, and surface 11F of sintered body 11. Multilayer electronic component 1000 is configured to be mounted on mounting body 2001, such as a circuit board, by connecting lead terminals 17A and 17B to mounting body 2001.
A method of producing multilayer electronic component 1000 will be described below.
A mixture material which is obtained by adding bismuth oxide or the like, plasticizer, binder or the like to zinc oxide is shaped into have a sheet shape to form plural green sheets 122. Silver powder is mixed with binder or the like to form internal electrode paste 112. Internal electrode paste 112 for internal electrodes is printed on green sheets 122, and then, green sheets 122 are laminated such that green sheets 122 and the printed layers of internal electrode paste 112 are alternately arranged. Then, the thus obtained multilayer product is divided into pieces to obtain plural multilayer bodies 111 each having a structure shown in
A conductive paste is prepared by mixing silver powder with a binder or the like. Next, sintered bodies 11 are arranged such that side surfaces 11A from which internal electrodes 12A are exposed are aligned with one another, and side surfaces 11B from which internal electrodes 12B are exposed are aligned with one another. Then, the conductive paste is printed on side surfaces 11A and 11B of each sintered body 11 so as to cover the exposed internal electrodes 12A and 12B, respectively. Then, each sintered body 11 is fired at about 800° C. so that the printed conductive paste is baked to form external electrodes 13A and 13B to obtain intermediate component 1001. In this process, external electrodes 13A and 13B directly contact internal electrodes 12A and 12B, respectively, hence providing stable electrical connection of external electrodes 13A and 13B to internal electrodes 12A and 12B. Each of external electrodes 13A and 13B has a thickness of about 20 μm. Electrical characteristics of multilayer electronic component 1000 depend on regions of insulating layers 22 sandwiched between internal electrodes 12A and 12B. The conductive paste obtained by mixing silver powder with the binder to form external electrodes 13A and 13B prevents undesired matters, such as dielectric matters, other than the conductive silver powder that would affect the electrical characteristics of multilayer electronic component 1000 from diffusing into these regions. Accordingly, stable electrical characteristics of multilayer electronic component 1000 can be obtained.
As shown in
A mixture paste is prepared by mixing silver powder, a glass frit, and a binder or the like. Next, sintered bodies 11, or intermediate components 1002, are arranged such that the side surfaces having external electrodes 13A formed thereon are aligned with one another, and the side surfaces having external electrode 13B formed thereon are aligned with one another. Then, the mixture paste is applied onto external electrodes 13A and 13B to completely cover external electrodes 13A and 13B such that external electrodes 13A and 13B are not exposed. Then, intermediate components 1002 are fired at about 700° C. so that the applied mixture paste is baked to form external electrodes 14A and 14B shown in
Next, plated layers 16A and 16B are formed on external electrodes 14A and 14B, respectively, by electroplating to form individual component 1003, as shown in
Lead terminals 17A and 17B are prepared by pressing a plate of iron or phosphor bronze to have predetermined shapes and then folding the punched plates to have an L-shape. Each of lead terminals 17A and 17B is coated with a plated layer of nickel and tin, and are respectively provided with bonding layers 18A and 18B made of bonding material, such as solder, on regions which configured to contact external electrodes 14A and 14B. Next, as shown in
Individual component 1003 shown in
In a case where a position error is produced during attaching lead terminals to the above-described conventional electronic component, a problem described below would occur when the electronic component is mounted on a circuit board. The conventional surface mount electronic component with lead terminals is produced by attaching the lead terminals to ordinary surface mount electronic components. In order to mount the electronic component on a circuit board, electrodes are formed on the mount surface of the electronic component by a dipping method or the like. Accordingly, the electrodes are formed not only on the mount surface, but also on other surfaces, such as an upper surface and side surfaces of the electronic component. When the lead terminals are attached to the electronic component with reference to the outer shape of the electronic component, position errors may be produced due to thickness variations of the electrodes.
On the other hand, multilayer electronic component 1000 according to the embodiment is mounted on mounting body 2001 accurately and easily.
In a process of positioning lead terminals 17A and 17B, individual component 1003 contacts reference surface 54 at a part which is opposite to mounting surface 53C and farthest from mounting surface 53C. In individual component 1003 shown in
Number | Date | Country | Kind |
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2017-197380 | Oct 2017 | JP | national |
This is a Divisional of U.S. patent application Ser. No. 16/622,572, filed on Dec. 13, 2019, which is the U.S. National Phase under 35 U.S.C. § 371 of International Patent Application No. PCT/JP2018/034534, filed on Sep. 19, 2019, which in turn claims priority to Japanese Patent Application No. 2017-197380, filed on Oct. 11, 2017. The entire disclosures of these applications are incorporated by reference herein.
Number | Date | Country | |
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Parent | 16622572 | Dec 2019 | US |
Child | 17838961 | US |