Abstract: The present disclosure provides a stacked-type solid electrolytic capacitor package structure and a method of manufacturing the same. The capacitor package structure includes a capacitor unit, a solder unit, a package unit and a conductive unit. The capacitor unit includes a plurality of first stacked capacitors. Each first stacked capacitor includes a first positive portion and a first negative portion. The first positive portion has at least one first through hole. The first through holes of the first positive portions are in communication with each other to form a first communication hole. The solder unit includes a first connection solder for filling the first communication hole so as to connect the first positive portions with each other. The package unit includes a package body for enclosing the capacitor unit and the solder unit. The conductive unit includes a first conductive terminal and a second conductive terminal.

Abstract: A capacitor detection system and an active-type pin-diverging module thereof are disclosed. The active-type pin-diverging module is applied to two conductive pins of a capacitor, and active-type pin-diverging module includes a base structure and a swingable structure. The swingable structure is swingably disposed on the base structure, and the swingable structure includes two swingable elements. The two conductive pins of the capacitor respectively pass through two through holes of a seat board, and each conductive pin has a lateral contact surface. The two swingable elements concurrently slidably contact the two lateral contact surfaces of the two conductive pins of the capacitor so as to diverge the two conductive pins of the capacitor, and the seat board is held by the two diverged conductive pins so as to prevent the seat board from being separated from the capacitor.

Abstract: The present disclosure provides a capacitor assembly having a non-symmetrical electrode structure and a capacitor seat structure thereof. The capacitor assembly includes a capacitor seat structure and a capacitor package structure. The capacitor seat structure includes a capacitor seat, a first electrode layer and a second electrode layer. The capacitor seat has a first through hole, a first groove, a second through hole and a second groove. The capacitor package structure includes a first conductive pin and a second conductive pin. The first conductive pin passes through the first through hole and is disposed inside the first groove to electrically contact the first electrode layer. The second conductive pin passes through the second through hole and is disposed inside the second groove to electrically contact the second electrode layer.

Abstract: The instant disclosure relates to a manufacturing method of capacitor cathode foil structure, comprising the following steps. The first step is providing a base foil, subsequently inserting the foil into a reactor. The next step is executing a heating process for heat the base foil to a temperature region of 400° C. to 1000° C. The next step is directing a carbon containing precursor gas into the reactor. The last step is executing a cooling process for cooling the base foil to a temperature below 100° C. to deposit a graphene-based layer on one surface of the base foil, wherein the graphene-based layer is consisted of a plurality of graphene-based thin films in stacked arrangement.

Abstract: The instant disclosure relates to a stacked-type solid electrolytic capacitor capable of increasing welding effect and a manufacturing method of the same. The stacked-type solid electrolytic capacitor includes a plurality of solid electrolytic capacitor units, each of which has an anode part and a cathode part connected to the anode part, characterized in that the anode part is formed with at least one buffering via-hole in a welding area thereof. When each of the anode parts is compressed in a welding process, the volume of the corresponding buffering via-hole decreases accordingly. Therefore, the soldering performance of the anode part solid electrolytic capacitor is enhanced and the connection stability is increased.

Abstract: The present disclosure provides a solid electrolytic capacitor package structure for increasing electrical performances and a method of manufacturing the same, and a capacitor unit thereof. The capacitor unit includes at least one first capacitor, the at least one first capacitor includes a conductive polymer composite material layer. The conductive polymer composite material layer includes a conductive polymer material and a first nanometer material mixed with the conductive polymer material, and the first nanometer material includes a plurality of first fully embedded nanometer structures completely enclosed by the conductive polymer material and a plurality of first partially exposed nanometer structures partially exposed from the conductive polymer material.

Abstract: An impregnation apparatus for impregnating a material in a combined medicament. The impregnation apparatus includes a delivery device, a dispensing device, a transmission device, a scraper device, and an impregnation execution device. The combined medicament is poured into a receiving unit by the dispensing device. The scraper device includes a scraper moving unit and a scraper structure arranged on the scraper moving unit. The scraper moving unit drives the scraper structure, leveling the combined medicament in the receiving unit. The impregnation execution device includes a carrying unit and a carrier moving unit. The material is disposed in the carrying unit and is impregnated into the receiving unit carrying the combined medicament by moving the carrying unit. The instant disclosure further provides an impregnation method.

Abstract: The instant disclosure relates to a method for making solid electrolytic capacitor package structure with improved conductive terminals. The first step is to provide at least one conductive terminal having an electrical contact portion and a lead-out portion. The next step is to remove a portion of mantle layer from the surface of the core layer of at least one conductive terminal by a dry-type process. The next step is to sequentially stack together a plurality of stacked-type capacitors to form a capacitor unit and then electrically connect the capacitor unit to at least one conductive terminal. The next step is to form a package body to encapsulate the capacitor unit and the electrical contact portion of at least one conductive terminal. The last step is to bend the lead-out portion of at least one conductive terminal to an axis that extends along the surface of the package body.

Abstract: The instant disclosure provides a solid electrolytic capacitor package structure and method of manufacturing the same. The solid electrolytic capacitor package structure includes a capacitor assembly, at least one electrode pin and a package body enclosing the capacitor assembly and the electrode pin. The electrode pin includes an embedded portion enclosed by the package body and an exposed portion positioned outside the package body. The method of manufacturing the solid electrolytic capacitor package structure includes a protection step including forming a protecting film on the exposed portion; a coating step including depositing a nanomaterial on the solid electrolytic capacitor package structure to form a nanofilm, wherein the nanomaterial penetrates into defects of the solid electrolytic capacitor package structure; and a deprotection step including removing the protecting film.

Abstract: The instant disclosure relates to a solid electrolytic capacitor with improved metallic anode and a method for manufacturing the same. The solid electrolytic capacitor includes a substrate layer, a conductive polymer layer and an electrode layer. The substrate layer has a cathode portion and an anode portion having a smaller thickness than the cathode portion. The conductive polymer layer is formed to cover the cathode portion of the substrate layer. The electrode layer is formed to cover the conductive polymer layer. Therefore, the instant solid electrolytic capacitor can be applied to a packing process, and welding success yield rate can be improved.

Abstract: A stacked-type solid electrolytic capacitor package structure includes a capacitor unit, a package unit, and a conductive unit. The capacitor unit includes a plurality of first stacked-type capacitors sequentially stacked on top of one another, and each first stacked-type capacitor has a first positive portion and a first negative portion. The package unit includes a package resin body for enclosing the capacitor unit. The conductive unit includes a first conductive terminal and a second conductive terminal. The first conductive terminal has a first embedded portion and a first exposed portion, and the second conductive terminal has a second embedded portion and a second exposed portion. An outermost one of first stacked-type capacitors has a plurality of first exposed soldering microgrooves formed on an outer surface thereof for contacting the package resin body. The instant disclosure further provides a method of manufacturing a stacked-type solid electrolytic capacitor package structure.

Abstract: A sealing element of the instant disclosure includes a cover body, an exterior convex portion, and an interior convex portion. The cover body has a first surface, a second surface arranged opposite to the first surface, and a pair of terminal holes formed on the cover body and extending through the first and second surfaces. The exterior convex portion has at least one first abutting surface arranged on the first surface of the cover body and an expansion space formed concavely in the exterior convex portion. The interior convex portion has at least one second abutting surface arranged on the second surface of the cover body. Specifically, the sealing element is configured to prevent the capacitor element from swaying, so that the electrical property of the wound-type solid state electrolytic capacitor with the sealing element can be improved.

Abstract: A solid electrolytic chip capacitor is provided which comprises a substrate layer, an electrical insulating block, a conductive polymer layer, a patterned reinforcement layer, and an electrode layer. The electrical insulating block is formed on the substrate layer to define an anode region and a cathode region on the substrate layer. The conductive polymer layer is formed to cover the cathode region of the substrate layer. The patterned reinforcement layer is formed to cover the conductive polymer. The electrode layer is formed to cover the patterned reinforcement layer. Whereby, the mechanical strength of the chip solid electrolytic capacitor can be improved without loss of capacitance.

Abstract: The instant disclosure relates to an improved method for the production of solid electrolytic capacitor, comprising the following steps. First, provide an insulating substrate. Next, form a plurality of conducting gels including aluminum powder on the insulating substrate. Thirdly, execute a high-temperature sintering process to metalize the conducting gels to form a plurality of aluminum plates. Next, form a dielectric layer on every aluminum plate. Then form an isolation layer on every dielectric layer to define an anodic region and a cathodic region. Lastly, form a conductive layer on the dielectric layer of every cathodic region, thus defining a solid electrolytic capacitor unit.

Abstract: A winding-type solid electrolytic capacitor package structure without using any lead frame includes a winding capacitor and a package body. The winding capacitor has a winding body enclosed by the package body, a positive conductive lead pin extended from a first lateral side of the winding body, and a negative conductive lead pin extended from a second lateral side of the winding body. The positive conductive lead pin has a first embedded portion enclosed by the package body and a first exposed portion exposed outside the package body and extended along the first lateral surface and the bottom surface of the package body. The negative conductive lead pin has a second embedded portion enclosed by the package body and a second exposed portion exposed outside the package body and extended along the second lateral surface and the bottom surface of the package body.

Abstract: A winding-type solid electrolytic capacitor package structure includes a winding capacitor unit, a package body and a conductive unit. The winding capacitor has a winding body enclosed by the package body, a positive conductive lead pin having a cutting surface, and a negative conductive lead pin having a grinding surface. The conductive unit includes a positive conductive terminal electrically connected to the positive conductive lead pin and a negative conductive terminal electrically connected to the negative conductive lead pin. The positive conductive terminal has a first embedded portion enclosed by the package body and a first exposed portion exposed outside the package body. The negative conductive terminal has a second embedded portion enclosed by the package body and a second exposed portion exposed outside the package body. The first and the second exposed portions are extended along the outer surface of the package body.

Abstract: A winding-type solid electrolytic capacitor package structure includes a substrate body, a winding capacitor, a package body and an electrode unit. The winding capacitor has a winding body, a positive conductive lead pin having a positive end surface, and a negative conductive lead pin having a negative end surface. The package body is disposed on the substrate body to enclose the winding body, and the package body has a first lateral surface substantially flushed with the positive end surface and a second lateral surface substantially flushed with the negative end surface. The electrode unit includes a positive electrode structure for covering the first lateral surface and electrically contacting the positive end surface and a negative electrode structure for covering the second lateral surface and electrically contacting the negative end surface.

Abstract: A solid electrolytic capacitor package structure includes a capacitor unit, a package unit and a conductive unit. The package unit includes a package body for enclosing the capacitor unit. The conductive unit includes at least one first conductive terminal and at least one second conductive terminal. The first conductive terminal includes a first core layer and a first enclosing layer. The first core layer has a first top exposed surface exposed from the first enclosing layer, and the first top exposed surface has a first top covering area covered by the package body. The second conductive terminal includes a second core layer and a second enclosing layer. The second core layer has a second top exposed surface exposed from the second enclosing layer, and the second top exposed surface has a second top covering area covered by the package body.

Abstract: A winding-type solid electrolytic capacitor package structure without using any lead frame includes a winding capacitor and a package body. The winding capacitor has a winding body enclosed by the package body, a positive conductive lead pin extended from a first lateral side of the winding body, and a negative conductive lead pin extended from a second lateral side of the winding body. The positive conductive lead pin has a first embedded portion enclosed by the package body and a first exposed portion exposed outside the package body and extended along the first lateral surface and the bottom surface of the package body. The negative conductive lead pin has a second embedded portion enclosed by the package body and a second exposed portion exposed outside the package body and extended along the second lateral surface and the bottom surface of the package body.

Abstract: A winding-type solid electrolytic capacitor package structure includes a winding capacitor unit, a package body and a conductive unit. The winding capacitor has a winding body enclosed by the package body, a positive conductive lead pin having a cutting surface, and a negative conductive lead pin having a grinding surface. The conductive unit includes a positive conductive terminal electrically connected to the positive conductive lead pin and a negative conductive terminal electrically connected to the negative conductive lead pin. The positive conductive terminal has a first embedded portion enclosed by the package body and a first exposed portion exposed outside the package body. The negative conductive terminal has a second embedded portion enclosed by the package body and a second exposed portion exposed outside the package body. The first and the second exposed portions are extended along the outer surface of the package body.