JP2006108709A - Solid electrolytic capacitor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an anode/cathode terminal structure for improving soldering at the time of mounting on a printed wiring board in a solid electrolytic capacitor comprising: a capacitor element consisting of an anode member, a dielectric member, and a cathode member; an anode terminal and a cathode terminal connected, respectively, with the anode member and the cathode member of the capacitor element; and coating resin covering the capacitor element. <P>SOLUTION: In the solid electrolytic capacitor, anode/cathode terminals have a portion exposed from the coating resin on the lower surface of the solid electrolytic capacitor and on the first/second side faces connected with the lower surface, a recess opening toward the lower surface is formed in the portion on the first/second side faces of the anode/cathode terminals exposed from the coating resin on the first/second side faces, and the surface of the recess formed in the anode/cathode terminals is covered with a plating layer. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a chip-type solid electrolytic capacitor in which a capacitor element is covered with a resin layer.

  A chip-type solid electrolytic capacitor includes a capacitor element composed of an anode member, a dielectric member, and a cathode member, an anode terminal and a cathode terminal connected to the anode member and the cathode member of the capacitor element, respectively, and an exterior covering the capacitor element With resin. As an example, the capacitor element has a configuration in which an insulating layer, an electrolyte layer, and a cathode layer are formed on the surface of a sintered body block in which one end of an anode lead wire is embedded. In general chip-type solid electrolytic capacitors, a thin plate-like terminal is bonded to the anode lead wire and the cathode layer, respectively, and an exterior resin portion is formed around the capacitor element by a resin mold, and then the tip of the terminal is the exterior resin portion. These terminals are bent so as to be arranged on the lower surface. However, as the demand for miniaturization and low ESR of chip-type solid electrolytic capacitors has increased, structural limitations have been seen in such chip-type solid electrolytic capacitors.

  Among those conceived for further miniaturization and low ESR, there is a chip-type solid electrolytic capacitor disclosed in JP-A-2001-44077. In this type of solid electrolytic capacitor, the anode terminal hangs down from the anode lead wire, and the cathode terminal is joined to the lower surface (or side surface) of the capacitor element. Unlike the conventional solid electrolytic capacitor, since the terminal is not pulled out to the side, the capacitor can be miniaturized and the length of the terminal is shortened, so that the ESR can be reduced.

An outline of a method for producing a solid electrolytic capacitor described in JP-A-2001-44077 will be described with reference to FIG. First, as shown in FIG. 9 (a), a plated L-shaped cathode terminal (36) is attached to a capacitor element (31) having an anode lead wire (32) fixed to a metal ribbon (7). Glue using a conductive adhesive. The outer surface of the cathode terminal (36) is masked with an insulator (36a) so that the resin does not adhere directly when the exterior resin portion (34) is formed. Next, as shown in FIG. 9B, the exterior resin portion (34) is formed so as to cover the capacitor element (31) using a powder coating machine. The exterior resin part (34) is formed so as not to cover the outer surface of the cathode terminal (36). Then, as shown in FIG. 9C, the insulator (36a) is removed from the outer surface of the cathode terminal (36). Finally, as shown in FIG. 9D, after the plated L-shaped anode terminal (35) is joined to the anode lead wire (32) and the exterior resin portion (34), the anode lead wire (32 ) To separate the solid electrolytic capacitor from the metal ribbon (7).
JP 2001-6978 A Japanese Patent Laid-Open No. 2001-44077 JP 2001-110676 A

  The method of manufacturing a solid electrolytic capacitor as described above includes a step of masking the cathode terminal (35) with an insulator (36a), and a step of removing the insulator (36a) after forming the exterior resin portion (34). Is complicated. In addition, it is easier to form the exterior resin portion (34) by resin molding as is generally done conventionally than to form the exterior resin portion (34) using a powder coating machine. A resin part (34) can be formed. Therefore, it is desired that a solid electrolytic capacitor of the type without pulling out and bending of the electrode as described above can be easily manufactured by a method close to the conventional manufacturing method.

  However, when manufacturing the above solid electrolytic capacitor by a method close to the conventional method, there are the following problems. For example, as shown in FIG. 10A, the manufacturing frame (1) used in the manufacturing process protrudes inward so that the anode terminal member (12) and the cathode terminal member (13) face each other. In addition, a plurality of pairs of the terminal members (12) and (13) are arranged in the longitudinal direction of the manufacturing frame (1). After the manufacturing frame (1) is plated to form the plating layer (23) on the surface, the anode lead wire (32) of the capacitor element (31) is joined to the anode terminal member (12), and the capacitor element ( 31) is joined to the cathode terminal member (13). And as shown in FIG.10 (b), the exterior resin part (34) which covers a capacitor | condenser element (31) with a resin mold is formed.

  Next, in order to separate the solid electrolytic capacitor (3) from the manufacturing frame (1), the anode terminal member (12) and the cathode terminal member (13) are cut as shown in FIG. 10 (c). . Then, the cut surfaces, that is, the side surfaces of the anode terminal (35) and the cathode terminal are not covered with the plating layer (23) (the plating layer (23) is only formed at the edge of the side surface portion). After the cutting process, it is necessary to perform a plating process on these vertical surfaces. The reason is that when the fixed electrolytic capacitor is mounted on the substrate, the solder also adheres to the side surfaces of the anode terminal (35) and the cathode terminal (36). This is because it needs to be covered with a plating layer. However, in the manufacturing process of a solid electrolytic capacitor, it is inefficient that the plating process is performed twice, and the plating process after separation is performed individually for each solid electrolytic capacitor. Therefore, it is extremely complicated. Therefore, it is preferable that the plating process in the manufacturing process of the solid electrolytic capacitor is only the plating process for the manufacturing frame (1).

  The present invention solves the above-described problem, and in the process of manufacturing a solid electrolytic capacitor of a type that does not lead out and bend the electrode, the plating process can be simplified and the solder for mounting on the substrate can be simplified. Provided is a solid electrolytic capacitor that can be attached safely and quickly.

A solid electrolytic capacitor according to a first aspect of the present invention includes a capacitor element composed of an anode member, a dielectric member, and a cathode member, and an anode terminal and a cathode terminal respectively connected to the anode member and the cathode member of the capacitor element, A solid electrolytic capacitor comprising an exterior resin covering the capacitor element,
The anode terminal has a portion exposed from the exterior resin on a lower surface of the solid electrolytic capacitor and a first side surface connected to the lower surface,
In the first side exposed portion of the anode terminal exposed from the exterior resin on the first side, a depression opened toward the lower surface is formed,
The surface of the depression is covered with a plating layer.

A solid electrolytic capacitor according to a second aspect of the present invention includes a capacitor element composed of an anode member, a dielectric member and a cathode member, and an anode terminal and a cathode terminal respectively connected to the anode member and the cathode member of the capacitor element, A solid electrolytic capacitor comprising an exterior resin covering the capacitor element,
The cathode terminal has a portion exposed from the exterior resin on a lower surface of the solid electrolytic capacitor and a second side surface connected to the lower surface,
In the second side exposed portion of the cathode terminal exposed from the exterior resin on the second side, a depression opened toward the lower surface is formed,
The surface of the depression is covered with a plating layer.

A solid electrolytic capacitor according to a third aspect of the present invention includes a capacitor element composed of an anode member, a dielectric member and a cathode member, and an anode terminal and a cathode terminal respectively connected to the anode member and the cathode member of the capacitor element, A solid electrolytic capacitor comprising an exterior resin covering the capacitor element,
The anode terminal has a lower surface of the solid electrolytic capacitor and a portion exposed from the exterior resin on a first side surface connected to the lower surface, and the cathode terminal is a second side surface connected to the lower surface of the solid electrolytic capacitor and the lower surface. And having a portion exposed from the exterior resin,
The first side exposed portion of the anode terminal exposed from the exterior resin on the first side is formed with a recess opened toward the lower surface, and the second side exposed of the cathode terminal exposed from the exterior resin on the second side. In the part, a dent opened toward the lower surface is formed,
The surface of the depression formed in the anode terminal and the cathode terminal is covered with a plating layer.

  In the solid electrolytic capacitor according to the first, second and / or third aspect of the present invention, the depression formed in the first side exposed portion of the anode terminal and / or the second side exposed portion of the cathode terminal is In addition to opening toward the lower surface of the solid electrolytic capacitor, it may be configured to open upward.

  The solid electrolytic capacitor according to the first, second and / or third aspects of the present invention can be manufactured, for example, through the following steps.

In the manufacturing process, the anode terminal member protrudes from one of the pair of side frame members arranged in parallel, and the cathode terminal member protrudes from the other side so as to face the anode terminal member. A step of plating a manufacturing frame which is formed in a step shape so that the front end side is lowered, and a through hole is formed in each of the high step portions of the anode terminal member and the cathode terminal member;
Bonding the anode lead wire of the capacitor element to the upper surface of the anode terminal member of the manufacturing frame after the plating process, and bonding the lower surface of the capacitor element to the upper surface of the lower step portion of the cathode terminal member; Leaving a hole and forming an exterior resin part around the capacitor element;
Cutting the manufacturing frame at a vertical plane passing through the through hole formed in the anode terminal member and a vertical plane passing through the through hole formed in the cathode terminal member and taking out the solid electrolytic capacitor; Including
In the step of plating the manufacturing frame, a plating layer is formed at least in a region inside the vertical plane.

  In the manufacturing process described above, a recess may be formed on the lower surface of the anode terminal member and on the lower surface of the high step portion of the cathode terminal member instead of the through hole.

  In manufacturing the solid electrolytic capacitor according to the present invention, it is possible to use a manufacturing frame in which a through hole or a recess is formed in each of the anode terminal member and the cathode terminal member. After such a manufacturing frame is plated and the capacitor elements are joined to form an exterior resin portion covering the capacitor elements, the manufacturing frame, that is, the anode terminal member and the cathode are formed on a vertical plane passing through the through hole or the recess. Cut the terminal member. This separates the solid electrolytic capacitor from the manufacturing frame.

  When the anode terminal member and the cathode terminal member are cut, the parts of the member separated from the manufacturing frame become the anode terminal and the cathode terminal of the solid electrolytic capacitor, respectively. In the plating process, the plating layer is formed at least on the inner side of the vertical surface, and the anode terminal member and the cathode terminal member are cut on the vertical surface passing through the through hole or the recess. A region constituting the inner surface of the through hole or the recess in the side surface is covered with a plating layer. Therefore, after the solid electrolytic capacitor is cut out from the manufacturing frame, it is not necessary to perform the plating process on the electrode. Type solid electrolytic capacitor can be manufactured. In addition, since the exterior resin portion is formed so as to leave the through hole or the concave portion, that is, the resin does not enter the through hole or the concave portion, it is not necessary to protect the region with an insulating layer or the like. If the member for the cathode terminal is cut, a solid electrolytic capacitor is completed.

  In the solid electrolytic capacitor according to the present invention, depressions are formed in the side portions of the anode terminal and the cathode terminal. These recesses are also open on the mounting surface (lower surface) side or on the opposite side (upper side) in addition to the mounting surface side. When mounting the solid electrolytic capacitor on the mounting board using solder, From the surface side to the bottom surface of the recess, the bottom surface is joined. When soldering, the flow range of the melted solder is limited by the depression, so that the solder is prevented from protruding to the exterior resin portion. Therefore, according to the solid electrolytic capacitor of the present invention, it is possible to safely and quickly mount the substrate on the substrate without worrying about the protrusion of the solder.

  Hereinafter, a chip-type solid electrolytic capacitor according to a first embodiment of the present invention and a manufacturing method thereof will be described with reference to the drawings. In the drawings, the same reference numerals are used for the same or similar components as those in the conventional method.

  With reference to FIG. 1, the process of producing the manufacturing frame (1) will be described. First, as shown in FIG. 1 (a), a metal thin plate (for example, a copper plate having a thickness of about 0.3 mm) is stepped, and a strip-shaped step is formed along the longitudinal direction at the approximate center of the upper surface of the thin plate. Forming part. In the figure, a part of the thin plate is shown. Next, the thin plate is subjected to press working (punching) to produce a manufacturing frame (1) as shown in FIG. The manufacturing frame (1) has a pair of side frame members (11) and (11) extending along the longitudinal direction, and an anode terminal member (12) is formed from one of the side frame members (11). The cathode terminal member (13) protrudes inward from the other side frame member (11) so as to protrude inward and to face the anode terminal member (12). A plurality of pairs of terminal members (12) and (13) are formed in the longitudinal direction of the manufacturing frame (1). The width of the cathode terminal member (13) in the longitudinal direction of the manufacturing frame (1) is set to be approximately the same as the width of the anode terminal member (12). FIG. 1B shows a part of the manufacturing frame (1). Although not shown in the figure, the side frame members (11) and (11) are connected at both ends. In addition, the connection location of both side frame members (11) (11) is not restricted to both ends, You may provide in the arbitrary locations between the member (12) (13) pair for terminals.

  The anode terminal member (12) is formed in a rectangular parallelepiped shape, and a through hole (21) is formed in the vertical direction near the tip thereof. The cathode terminal member (13) is formed in a step shape having different thicknesses in the vertical direction, and the tip side of the cathode terminal member (13) is a low step portion corresponding to the above-described step processing portion. A through hole (22) is vertically formed in the vicinity of the low step portion in the high step portion of the cathode terminal member (13). In this embodiment, the through holes (21) and (22) are square holes.

  When the manufacturing frame (1) as shown in FIG. 1 (b) is produced, electrolytic plating is performed to form a plating layer (23) on the surface of the manufacturing frame (1). In the present embodiment, the plating layer (23) is formed over almost the surface of the manufacturing frame (1) (for example, at the portion where the member supporting the manufacturing frame (1) abuts during the plating process. Is not formed), the plated layer (23) is also formed on the inner surfaces of the through holes (21) and (22). The plating layer (23) is made of, for example, Ni / Pd / Au. For the purposes of the present invention, at least in the region inside the vertical plane (AA and BB described later) for cutting the anode terminal member (12) and the cathode terminal member (13), the anode The plating layer (23) should just be formed in the member (12) for terminals, and the member (13) for cathode terminals.

  After electrolytic plating of the manufacturing frame (1), the capacitor element (31) is joined to the manufacturing frame (1) as shown in FIG. The capacitor element (31) is made on the basis of a block (33) of a valve metal sintered body such as tantalum, and the anode lead wire (32) is embedded in the sintered body block (33). Projecting from the surface. Although not shown, a dielectric oxide film is formed on the surface of the sintered body block (33) by anodic oxidation, and on the dielectric oxide film, a conductive material such as polypyrrole is formed by electrolytic polymerization or chemical polymerization. A solid electrolyte layer made of a polymer is formed. A cathode layer composed of a carbon layer and a silver paint layer is formed on the solid electrolyte layer.

  The tip of the anode lead wire (32) is joined to the top surface of the tip of the anode electrode member (12) by electric welding or the like. The tip end face of the anode lead wire (31) is preferably located inside the inner surface (21a) located on the anode lead wire (32) side of the through hole (21). The lower surface of the sintered body block (33) and the side surface opposite to the anode lead wire (32) are the upper surface of the lower step portion of the anode terminal member (12), and the upper surface of the lower step portion and the upper surface of the high step portion. Are joined to the vertical planes connecting the two. A conductive adhesive is used for joining the sintered body block (33) to the manufacturing frame (1).

Next, an exterior resin portion (34) is formed for each capacitor element (31) joined to the manufacturing frame (1) by a resin mold. FIG. 3 is a vertical cross-sectional view around the capacitor element (31) showing a pattern for forming the exterior resin portion (34) using a transfer mold. When the manufacturing frame (1) to which the capacitor element (31) is bonded is mounted on the lower mold (51) and the upper mold (52) is placed on the lower mold (51), the capacitor element ( An internal space (53) is formed around 31). And when the epoxy resin which melted | fused is inject | poured into this internal space (53) and this epoxy resin hardens | cures, the exterior resin part (34) which covers a capacitor | condenser element (31) will be formed.
The molds (51) and (52) are configured so that the resin does not enter the through hole (21) of the anode terminal member (12) and the through hole (22) of the cathode terminal member (13). . In the embodiment, these through holes (21) and (22) are closed by the surface portions of the upper mold (52) and the lower mold (51), but it is not always necessary to have such a configuration. In resin molding, it is sufficient if there is no space that communicates with the internal space (53) and the through holes (21) and (22).

  FIG. 2B is a perspective view showing a state in which an exterior resin portion (34) covering each capacitor element (31) joined to the manufacturing frame (1) is formed. The outer surface of the exterior resin part (34) is formed in a substantially rectangular parallelepiped shape, and both side surfaces on the side frame (11) (11) side are located inside the through holes (21) (22). That is, the exterior resin portion (34) is formed leaving the through holes (21) (22). After forming the exterior resin portion (34), the anode terminal member (12) and the cathode are formed on the vertical plane AA passing through the through hole (21) and the vertical plane BB passing through the through hole (22). Each of the terminal members (13) is cut to separate the solid electrolytic capacitor (3) from the manufacturing frame (1).

  FIG.2 (c) is a perspective view of the taken-out solid electrolytic capacitor (3). FIG. 4 is a vertical sectional view of the solid electrolytic capacitor (3) mounted on the substrate (8). The anode terminal (35) whose vertical cross section is a rectangular shape is joined to the lower side of the anode lead wire (32) of the capacitor element (31), and the cathode terminal (36) whose vertical cross section is L-shaped, It is joined to the lower surface and the side surface of the sintered body block (33). The anode terminal (35) is configured by the tip of the anode terminal member (12) including a part of the inner surface of the through hole (21), and the cathode terminal (36) includes a part of the inner surface of the through hole (22). It is comprised by the front-end | tip part of the member (13) for cathode terminals. The exterior resin part (34) is formed so as to cover the capacitor element (31), and the solid electrolytic capacitor (3) is formed in a substantially rectangular parallelepiped shape as a whole. The bottom surface of the solid electrolytic capacitor (3) is a mounting surface located on the substrate (8) side during mounting. On the mounting surface, the bottom surfaces of the anode terminal (35) and the cathode terminal (36) are exterior resin portions. Exposed from (34). Further, on the first side surface of the solid electrolytic capacitor (3) perpendicular to the mounting surface, the side surface portion of the anode terminal (35) is exposed from the exterior resin portion (34), and the second side surface facing the first side surface. Then, the side part of the cathode terminal (36) is exposed from the exterior resin part (34).

  The first side surface exposed portion of the anode terminal (35) exposed from the exterior resin on the first side surface and the second side surface exposed portion of the cathode terminal (36) exposed from the exterior resin on the second side surface are below (mounted) Recesses (37) and (38) opened to the upper side and the upper side are formed, respectively. These dents (37) and (38) are composed of a flat surface portion and inner surfaces of convex portions (39) formed on both sides of the flat surface portion. The anode terminal (35) and the cathode terminal (36) are covered with a plating layer (23) except for the convex side surface (39a) which is a cut surface formed along with the separation of the solid electrolytic capacitor (3). . The metal bars of the anode terminal (35) and the cathode terminal (36) bordered by the plating layer (23) are exposed on the side surface (39a) of the convex portion.

  The solid electrolytic capacitor (3) is joined to the substrate (8) using solder (9), and the solder (9) is connected to the lower surface of the anode terminal (35), the lower surface of the cathode terminal (36) and the substrate (8). It interposes in layers between them, and further forms a mountain shape on the side of the solid electrolytic capacitor (3). The mountain-shaped portions of the solder (9) are joined to the flat portions of the depressions (37) and (38). Since these flat portions are covered with the plating layer (23), the solder (9) and the flat portions are joined. (37) Join to (38) with high strength. Since convex portions (39) are formed on both sides of the flat portion, the flow of the solder (9) melted during soldering is restricted, and the situation where the solder (9) protrudes into the exterior resin portion (34) is prevented. Has been.

  Next, a second embodiment of the present invention will be described. As shown in FIG. 5A, a metal thin plate is cut and pressed or etched to produce a manufacturing frame (1) similar to the first embodiment. However, the through-holes (21) and (22) as in the first embodiment are not formed in the manufacturing frame (1) in the second embodiment. Instead, the anode terminal member (12) and the cathode are formed. A rectangular parallelepiped recess (24) (25) is formed on the lower surface of the terminal member (13). The recesses (24) and (25) are formed by, for example, an etching process. FIG.5 (b) is a perspective view of the state which turned over the manufacturing frame (1). After forming the recesses (24) and (25) in the manufacturing frame (1), the manufacturing frame (1) is plated in the same manner as in the first embodiment to form a plating layer (23). A plating layer (23) is also formed on the inner surfaces of the recesses (24) and (25). Then, as shown in FIG. 5C, the capacitor element (3) is joined to the manufacturing frame (1). In addition, although it is the range which forms the plating layer (23) in the manufacturing frame (1), at least in the region inside the vertical surfaces (CC, DD) described later, the anode terminal member (12) And the plating layer (23) should just be formed in the member (13) for cathode terminals.

  Next, as shown in FIG. 6A, an exterior resin portion (34) that covers the capacitor element (3) is formed by a resin mold. In the first embodiment, the exterior resin portion (34) is individually formed for each capacitor element (3). However, in the second embodiment, the exterior resin portion (34) is formed to cover all the capacitor elements (3). Forming. Of course, also in the second embodiment, an exterior resin portion (34) may be formed for each capacitor element (3).

  FIG. 7 is a cross-sectional view showing a pattern for forming the exterior resin portion (34). The manufacturing frame (1) to which the capacitor element (31) is bonded is mounted on the lower mold (51), and the upper mold (52) formed in a frame shape is placed on the lower mold (51). Place. The upper mold (52) is arranged so as to surround all the capacitor elements (31). An internal space (53) formed around the capacitor element (31) by these molds (51) and (52) is opened upward, and an epoxy resin is poured into the internal space (53) from above, so that the exterior A resin part (34) is formed around the capacitor element (31).

  After forming the exterior resin portion (34) as shown in FIG. 6 (a), the anode terminal member is formed on the vertical plane CC passing through the recess (24) and the vertical plane DD passing through the recess (25). (12) and the cathode terminal member (13) are respectively cut. In this embodiment, since the exterior resin part (34) is also formed on the terminal members (12) (13) above the recesses (24) and (25), the resin layer (34) is formed at this time. A part of is also cut off. Thereafter, the exterior resin portion (34) is cut in a vertical plane between the capacitor elements (31), thereby completing the solid electrolytic capacitor (3) as shown in FIG. 6 (b).

  FIG. 8 is a vertical sectional view showing a state in which the solid electrolytic capacitor (3) manufactured in this example is mounted on the substrate (8). The solid electrolytic capacitor (3) manufactured by the second embodiment has the same configuration as that manufactured by the first embodiment except for the side surfaces of the anode terminal (35) and the cathode terminal (36). . On the side surfaces of the anode terminal (35) and the cathode terminal (36), depressions (40) (41) opened downward are formed. These recesses are formed by dividing the recesses (24) and (25). Since the plating layer (23) is formed on the inner surfaces of the recesses (24) and (25), each surface constituting the recesses. Also, a plating layer (23) is formed. Therefore, when the solid electrolytic capacitor (3) is joined to the substrate (8) using the solder (9), the mountain-shaped portion of the solder (9) formed on the side of the capacitor (3) is the anode terminal ( 35) and the bottom surfaces of the depressions (40) and (41) of the cathode terminal (36) are joined with high strength. The depressions (40) and (41) function to restrict the flow of the melted solder (9) during soldering so that the solder (9) does not protrude into the exterior resin portion (34). To do. Surface portions (42) and (43) surrounding the depressions (40) and (41) are cut surfaces of the anode terminal member (12) or the cathode terminal member (13) and are not covered with the plating layer (23) ( These face portions (42) and (43) are only bordered by the plating layer (23)).

  In the first embodiment, the through holes (21) and (22) are square holes. However, in the practice of the present invention, the manufactured solid electrolytic capacitor (3), the anode terminal (35), the cathode terminal (36), and the solder The shape of the through holes (21) and (22) is not particularly limited as long as a sufficient contact area with the mountain-shaped portion of (9) can be secured. The same applies to the recesses (24) and (25) in the second embodiment.

  The above description of the embodiments is for explaining the present invention, and should not be construed as limiting the invention described in the claims or reducing the scope thereof. Each part configuration of the present invention is not limited to the above embodiment, and various modifications can be made within the technical scope described in the claims.

It is a perspective view which shows the process of producing the manufacturing frame which concerns on 1st Example of this invention. It is a perspective view which shows the process of 1st Example of this invention. It is a vertical sectional view around a capacitor element showing a pattern for forming an exterior resin portion in the first embodiment of the present invention. 1 is a vertical sectional view illustrating a state in which a chip-type solid electrolytic capacitor manufactured according to a first embodiment of the present invention is mounted on a substrate. It is a perspective view which shows the process of 2nd Example of this invention. It is a perspective view which shows the process of 2nd Example of this invention. It is a vertical sectional view around a capacitor element showing a pattern for forming an exterior resin portion in the second embodiment of the present invention. It is a vertical sectional view showing a state mounted on a chip-type solid electrolytic capacitor substrate manufactured according to a second embodiment of the present invention. It is a side view which shows the manufacturing method of the conventional chip type solid electrolytic capacitor. It is a perspective view which shows the manufacturing method of the conventional chip type solid electrolytic capacitor.

Explanation of symbols

(1) Manufacturing frame (3) Solid electrolytic capacitor (8) Substrate (11) Side frame member (12) Anode terminal member (13) Cathode terminal member (21) Through hole (22) Through hole (23) Plating Layer (24) Recess (25) Recess (31) Capacitor element (32) Anode lead wire (33) Sintered body block (34) Exterior resin part (35) Anode terminal (36) Cathode terminal (37) Dimple (38) Dent (40) dent (41) dent

Claims (7)

A solid electrolytic capacitor comprising a capacitor element comprising an anode member, a dielectric member and a cathode member, an anode terminal and a cathode terminal connected to the anode member and the cathode member of the capacitor element, respectively, and an exterior resin covering the capacitor element Because
The anode terminal has a portion exposed from the exterior resin on a lower surface of the solid electrolytic capacitor and a first side surface connected to the lower surface,
The first side exposed portion of the anode terminal exposed from the exterior resin on the first side is formed with a recess opened toward the lower surface,
A solid electrolytic capacitor characterized in that the surface of the recess is covered with a plating layer. A solid electrolytic capacitor comprising: a capacitor element comprising an anode member, a dielectric member and a cathode member; an anode terminal and a cathode terminal connected to the anode member and the cathode member of the capacitor element; and an exterior resin covering the capacitor element. Because
The cathode terminal has a portion exposed from the exterior resin on a lower surface of the solid electrolytic capacitor and a second side surface connected to the lower surface,
The second side exposed portion of the cathode terminal exposed from the exterior resin on the second side is formed with a recess that opens toward the lower surface,
A solid electrolytic capacitor characterized in that the surface of the recess is covered with a plating layer. A solid electrolytic capacitor comprising a capacitor element comprising an anode member, a dielectric member and a cathode member, an anode terminal and a cathode terminal connected to the anode member and the cathode member of the capacitor element, respectively, and an exterior resin covering the capacitor element Because
The anode terminal has a portion exposed from the exterior resin on a lower surface of the solid electrolytic capacitor and a first side surface connected to the lower surface,
The cathode terminal has a portion exposed from the exterior resin on a lower surface of the solid electrolytic capacitor and a second side surface connected to the lower surface,
In the first side exposed portion of the anode terminal exposed from the exterior resin on the first side, a depression opened toward the lower surface is formed,
The second side exposed portion of the cathode terminal exposed from the exterior resin on the second side is formed with a recess that opens toward the lower surface,
A solid electrolytic capacitor characterized in that the surface of the depression formed in the anode terminal and the cathode terminal is covered with a plating layer.   The solid electrolytic capacitor according to claim 3, wherein the first side surface and the second side surface face each other.   2. The recess formed in the first side exposed portion of the anode terminal and / or the second side exposed portion of the cathode terminal is also open toward the upper side of the solid electrolytic capacitor. 2. The solid electrolytic capacitor according to 2, 3 or 4.   In the first side exposed portion of the anode terminal and / or the second side exposed portion of the cathode terminal, the metal of the anode terminal and / or the cathode terminal is exposed around the recess. 6. The solid electrolytic capacitor according to claim 1, 2, 3, 4 or 5. 7. The solid electrolysis according to claim 1, 2, 3, 4, 5 or 6, wherein an exposed portion of the lower surface of the anode terminal and / or the cathode terminal exposed from the exterior resin on the lower surface is covered with a plating layer. Capacitor.