The present disclosure relates to an electrolytic capacitor, and particularly to an electrolytic capacitor including a plurality of stacked capacitor elements.
The capacitance of an electrolytic capacitor has been required to be increased along with increase of functionalities of electronic devices. For example, Unexamined Japanese Patent Publication No. 2004-319795 discloses an electrolytic capacitor including a capacitor element group including a plurality of sheet capacitor elements stacked on each other.
Each of the capacitor elements includes a dielectric layer formed on a surface of a sheet anode body, a solid electrolyte layer formed on a surface of the dielectric layer, and a cathode lead-out layer formed on a surface of the solid electrolyte layer. The dielectric layer is formed on all or part of a surface of the anode body. The solid electrolyte layer and the cathode lead-out layer are formed to cover a part of the surface of the dielectric layer. A part of the anode body, the dielectric layer, the solid electrolyte layer, and the cathode lead-out layer serve as a cathode part of the capacitor element. The rest of the anode body (and the dielectric layer), on which the solid electrolyte layer and the cathode lead-out layer are not formed, serves as an anode part. The anode parts of the capacitor elements included in the capacitor element group are joined, and electrically connected with each other.
An electrolytic capacitor according to the present disclosure includes a capacitor element group including a plurality of capacitor elements stacked on each other, an anode terminal electrically connected with an anode body, and an outer package body covering the capacitor element group so as to expose a part of the anode terminal. The plurality of capacitor elements each include an anode body, a dielectric layer on the anode body, a solid electrolyte layer on the dielectric layer, and a cathode lead-out layer on the solid electrolyte layer. The anode body has a sheet shape and includes a first side edge and a second side edge opposite to the first side edge. The anode body includes a first region close to the first side edge, a second region close to the second side edge, and a boundary between the first region and the second region. The solid electrolyte layer is disposed on the surface of the dielectric layer which is positioned in the first region. The second region includes a narrowed part and a junction part. The narrowed part has a length shortened in a direction along the second side edge. The junction part is for joining the capacitor element to another capacitor element adjacent to the capacitor element in the capacitor element group. The junction part is disposed between the narrowed part and the second side edge. A shortest distance W1 between a central line and a side edge of a cutout is shorter than a shortest distance W2 between the junction part and the central line. The central line extends in a direction orthogonal to both of the direction along the second side edge and a thickness direction of the anode body and equally dividing the anode body. The cutout forms the narrowed part.
In the electrolytic capacitor according to the present disclosure, stress applied on a boundary between an anode part and a cathode part can be reduced. As a result, reliability is improved.
Problems with the conventional technique will be briefly described before description of an exemplary embodiment of the present disclosure.
Since a cathode part includes a solid electrolyte layer and a cathode lead-out layer, the cathode part is thicker than an anode part. Thus, when a plurality of capacitor elements are stacked and the anode parts of the capacitor elements are joined with each other, stress is applied on each capacitor element at a boundary between the anode part and the cathode part. Accordingly, leakage current of an electrolytic capacitor that has such a configuration increases in some cases. In addition, the stacked capacitor elements are shifted from each other in some cases. Such failure is more significant when a length (length in a direction orthogonal to the boundary between the anode part and the cathode part) of the anode part is short.
The present disclosure is intended to solve the above-described problems and to provide an electrolytic capacitor that can reduce stress applied on a boundary between an anode part and a cathode part.
An electrolytic capacitor includes a capacitor element group including a plurality of capacitor elements stacked on each other, an anode terminal, and an outer package body covering the capacitor element group. Each of the plurality of capacitor elements includes a sheet anode body, a dielectric layer formed on a surface of the anode body, a solid electrolyte layer formed on a surface of the dielectric layer, and a cathode lead-out layer formed on a surface of the solid electrolyte layer. The anode body includes a first region close to a first side edge, a second region close to a second side edge opposite to the first side edge, and a boundary between the first region and the second region. The dielectric layer is formed on a surface of the first region.
Configurations of an electrolytic capacitor, a capacitor element, and an anode body according to the present exemplary embodiment will be described below in detail with reference to the accompanying drawings.
For example, as illustrated in
For example, the plurality of stacked capacitor elements 100 are joined with each other by laser welding, resistance welding, needle swaging, brazing and soldering, or the like at a predetermined position in second region R2 of each capacitor element 100, and are electrically connected with each other. Specifically, junction part 12 (refer to
For example, as illustrated in
Anode body 10 includes first region R1 and second region R2. Dielectric layer 20 is formed at least on a surface of first region R1. First region R1, dielectric layer 20, solid electrolyte layer 30, and cathode lead-out layer 40 serve as cathode part 100N of capacitor element 100. Second region R2 serves as anode part 100P of capacitor element 100. Thus, boundary LB between first region R1 and second region R2 is a boundary between anode part 100P and cathode part 100N of capacitor element 100. In other words, boundary LB is a boundary of division based on whether solid electrolyte layer 30 is provided. A region in which solid electrolyte layer 30 is formed in anode body 10 is first region R1, and the other region is second region R2.
Anode body 10 is a sheet containing valve metal as conductive material. Examples of the valve metal include titanium, tantalum, aluminum, and niobium. Anode body 10 may contain one, or two or more of the above-described valve metals. Anode body 10 may contain valve metals as alloy or intermetallic compound. Anode body 10 is not limited to a particular thickness, but may have a thickness ranging from 15 μm to 300 μm, inclusive, for example.
First region R1 of anode body 10 is disposed at a side closer to first side edge 101. A surface of first region R1 is preferably etched. The etching increases capacitance. Second region R2 is disposed at a side closer to second side edge 102 opposite to first side edge 101. Second region R2 may or may not be etched.
Since cathode part 100N includes solid electrolyte layer 30 and cathode lead-out layer 40, cathode part 100N is thicker than anode part 100P. Thus, when the plurality of capacitor elements 100 are stacked and joined with each other at a predetermined position in second region R2, capacitor elements 100 are typically bent at boundary LB and between boundary LB and second side edge. Accordingly, stress is likely to be applied near boundary LB of anode body 10. When distance L (refer to
In the present exemplary embodiment, second region R2 includes narrowed part 11 having a length shortened in a direction along second side edge 102 (direction parallel to second side edge 102). When second regions R2 of the plurality of capacitor elements 100 are joined with each other, a region between narrowed part 11 and second side edge 102 is easily bent in a thickness direction of the capacitor element group. The bending is conducted along a line extending from an end part of narrowed part 11 (near connection part 110E, described later) in direction T different from the direction along second side edge 102. Direction T is, for example, a direction (refer to
Accordingly, thickness difference Td between thickness Tn (refer to
Thickness Tn is, for example, an average value of thicknesses at optional five points in a stacking direction in the region corresponding to first region R1 in the capacitor element group. The optional five points corresponding to first region R1 are preferably positioned on central line LC extending in a direction orthogonal to second side edge 102 and equally dividing anode body 10, and selected except for points near boundary LB. Thickness Tp is a length connecting centers of junction parts 12 of two outermost capacitor elements 100 (in
Narrowed part 11 is formed by cutting out part of second region R2 along the direction parallel to second side edge 102. Side edge 110 of a cutout forming narrowed part. 11 is entirely disposed in second region R2.
A relation between a degree of narrowing at narrowed part 11 and a position of junction part 12 is important to reduce the above-described stress. Specifically, the stress is reduced when narrowed part 11 is narrowed closer to central line LC as a reference than junction part 12. More specifically, narrowed part 11 is provided in such a shape that shortest distance W1 between central line LC and side edge 110 of the cutout is shorter than shortest distance W2 between junction part 12 and central line LC. In particular, when distance L is short (for example, distance L<shortest distance W1), the above-described stress is more likely to be reduced as shortest distance W1 is shorter.
In
Each narrowed part 11 is preferably disposed in a vicinity of boundary LB. Accordingly, the region between narrowed part 11 and second side edge 102 increases, and thickness difference Td becomes likely to be absorbed by bending along a line in direction T. Thus, stress applied near boundary LB is further reduced. For example, when one end part (first end part 110A; refer to
Distance D1 is a shortest distance between first end part 110A and boundary LB. Similarly, distance D2 is a shortest distance between first end part 110A and second side edge 102. When anode body 10 includes a round corner and a boundary between second side edge 102 and third side edge 103 is unclear, distance D2 is set to be a shortest distance between an extended line from second side edge 102 and first end part 110A as illustrated in
A width of anode body 10 in the direction along second side edge 102 at narrowed part 11 is preferably as small as possible with respect to width W5 of second side edge 102. Accordingly, anode body 10 can be easily bent along a line in direction T. On the other hand, in order to maintain strength of anode body 10, the width of narrowed part 11 is preferably not excessively smaller than width W5 of second side edge 102. With these requirements taken into consideration, a ratio W4/W5 of shortest width W4 of anode body 10 in the direction along second side edge 102 at narrowed part 11 with respect to width W5 of second side edge 102 preferably ranges from 0.25 to 0.5, inclusive. When anode body 10 includes a round corner, width W5 is set to be a shortest distance between two extended lines of third side edges 103 as illustrated in
The shape of narrowed part 11 is not particularly limited. In particular, side edge 110 of the cutout preferably includes, at a side closer to second side edge 102, first straight part 110C extending in the direction along second side edge 102 as illustrated in
Side edge 110 of the cutout preferably includes, at a side closer to boundary LB, second straight part 110D extending in the direction along second side edge 102. Accordingly, the region between narrowed part 11 and second side edge 102 is increased. Specifically, a preferable shape of side edge 110 of the cutout is, for example, a U shape including first straight part 110C and second straight part 110D which are along second side edge 102. Connection part 110E connecting first straight part 110C and second straight part 110D is not limited to a particular shape, but may be a straight shape or a curved shape.
A ratio L2/L1 of distance L2 between boundary LB and second straight part 110D with respect to distance L1 between first straight part 110C and second straight part 110D preferably ranges from 0.1 to 4.0, inclusive, more preferably ranges from 0.1 to 0.5, inclusive. When narrowed part 11 is disposed close to boundary LB, second region R2 can be bent at multiple stages (or gradually) because of second straight part 110D and sufficiently long distance L1. Thus, the above-described stress is reduced. Moreover, in this case, the extremely simple shape of side edge 110 of the cutout leads to excellent productivity. For example, when narrowed part 11 is formed by punching out anode body 10, a blade used in the punching only need to be have a simple shape, thereby accurately forming narrowed part 11.
When side edge 110 of the cutout has the U shape including first straight part 110C and second straight part 110D, a ratio L2/L3 of distance L2 between boundary LB and second straight part 110D with respect to distance L3 between first straight part 110C and second side edge 102 preferably ranges from 0.1 to 1.7, inclusive, more preferably ranges from 0.1 to 0.3, inclusive. Accordingly, a sufficient area for connection with anode terminal 202 can be obtained in a region between first straight part 110C and second end part 102.
Distance L1 is an average value of lengths of lines extending from optional three points at first straight part 110C to second straight part 110D in a direction orthogonal to first straight part 110C. Distances L, L2, and L3 are average values, too, and can be calculated similarly.
Anode terminal 202 is disposed at a position corresponding to junction part 12, in other words, between narrowed part 11 and second side edge 102. In particular, anode terminal 202 is preferably disposed near third side edge 103 intersecting second side edge 102. This is because bending is unlikely to occur in this region. As illustrated in
A depth (length in a direction orthogonal to central line LC) of the cutout at narrowed part 11 is preferably greater than a length of anode terminal 202 in the direction orthogonal to central line LC. In other words, shortest distance W1 between side edge 110 of the cutout and central line LC is preferably shorter than shortest distance W3 between anode terminal 202 and central line LC. Accordingly, bending along a line extending in direction T is unlikely to occur in a region in which anode terminal 202 is disposed, and thus connection reliability is likely to be obtained.
Dielectric layer 20 is formed through oxidation of the surface of first region R1 by performing, for example, anodization processing. The anodization may be achieved by a well-known method. Dielectric layer 20 is not particularly limited, but may be any insulating layer functioning as dielectric. Dielectric layer 20 is formed at least on the surface of first region R1.
Solid electrolyte layer 30 is formed on at least part of the surface of dielectric layer 20. Solid electrolyte layer 30 contains, for example, manganese compound and conductive polymer. Examples of the conductive polymer include polypyrrole, polythiophene, polyaniline, and derivatives of polypyrrole, polythiophene, and polyaniline.
Solid electrolyte layer 30 containing the conductive polymer may be formed through, for example, chemical polymerization and/or electrolytic polymerization of material monomer on dielectric layer 20. Alternatively, solid electrolyte layer 30 may be formed by applying, to dielectric layer 20, liquid containing conductive polymer polymerized in advance.
Cathode lead-out layer 40 is formed on at least part of the surface of solid electrolyte layer 30. Cathode lead-out layer 40 includes, for example, a carbon layer, and a metal (for example, silver) paste layer formed on a surface of the carbon layer (both not illustrated). Cathode lead-out layer 40 is formed by sequentially applying carbon paste and silver paste.
Capacitor elements 100 are joined with each other in second region R2 as illustrated in
Swaging member 202A is joined with each of second regions R2 of two outermost capacitor elements (in
Anode lead 202B is electrically connected with second region R2 of each capacitor element 100 through swaging member 202A. Anode lead 202B and swaging member 202A may be integrated with each other. Materials of swaging member 202A and anode lead 202B are not particularly limited but may be any conductive materials.
Outer package body 201 is formed of, for example, insulating resin. Examples of the insulating resin include epoxy resin, phenol resin, silicone resin, melamine resin, urea resin, alkyd resin, polyurethane, polyimide, polyamide-imide, and unsaturated polyester.
Cathode terminal 203 is electrically connected with cathode lead-out layer 40. A material of cathode terminal 203 is not particularly limited but may be any conductive material. Cathode terminal 203 is joined with cathode lead-out layer 40 through, for example, conductive adhesive agent 204 as described above.
The electrolytic capacitor according to the present disclosure has excellent reliability and thus is applicable to various usages.
Number | Date | Country | Kind |
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2016-062581 | Mar 2016 | JP | national |
This application is a continuation of the PCT International Application No. PCT/JP2017/001890 filed on Jan. 20, 2017, which claims the benefit of foreign priority of Japanese patent application No. 2016-062581 filed on Mar. 25, 2016, the contents all of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/JP2017/001890 | Jan 2017 | US |
Child | 16128670 | US |