Abstract:
The present invention aims to provide a chip-type solid electrolytic capacitor of large capacitance and low ESR. An element section of the capacitor is composed of an anode oxide film layer which functions as a dielectric, a solid electrolyte layer including conductive polymer and a cathode conductive body, which are stacked on a metallic electrode. A plurality of flat capacitor elements with the element section and an anode pulling-out section are stacked, and a laminated unit is produced where the cathode conductive layer and the anode pulling-out section of the flat capacitor elements are connected to a single metallic terminal member each. The solid electrolytic capacitor of the present invention has at least two laminated units placed parallel to each other, and connected to a transversely disposed comb terminal. The construction presented by the present invention achieves a solid electrolytic capacitor of a large capacitance and a low ESR without expanding its mounting surface area.

Description:
FIELD OF THE INVENTION 
     The present invention relates to a solid electrolytic capacitor and production method thereof that achieves a large capacitance and a low equivalent serial resistance (hereinafter, low ESR). 
     BACKGROUND OF THE INVENTION 
     Recently, the development of smaller electronic devices used at higher frequencies has been increasing. Solid electrolytic capacitors using conductive polymers as solid electrolyte have been commercialized, as capacitors suitable for such electronic devices. Since the solid electrolytic capacitors use conductive polymers of high conductivity as solid electrolyte, they achieve high frequencies characteristics and low impedance. The ESR of these solid electrolytic capacitors is much lower than that of conventional electrolytic capacitors which use electrolytic solution as driving electrolytes and that of solid electrolytic capacitors using manganese dioxide, thereby achieving an ideally large capacitance. Since these new solid electrolytic capacitors are compact, various aspects have been improved allowing them to be gradually accepted in the marketplace. 
     With the development of faster and larger power consuming CPUs for computers, capacitors must achieve high frequency transient response characteristics. A large capacitance and a low ESR have also become essential characteristics. For the solid electrolytic capacitors to satisfy these demands, they need to achieve a large capacitance and low ESR while occupying the smallest possible mounting area in a device. 
     To realize these characteristics, techniques to laminate flat capacitor elements or thin sintered elements have been used. However, if conventional solid electrolytic capacitors are used to obtain the capacitance required to backup a CPU, five to ten large-capacitance tantalum solid electrolytic capacitors need to be mounted in parallel. Such arrangement increases the mounting area occupied by the capacitors, thus limiting the reduction of the size of the equipment. 
     With the increasing speed of CPUs, the amount of current flowing at high frequencies has significantly increased as well. If the ESR of a capacitor is not reduced, the temperature of the capacitor will become hot, thus increasing the chance of component break down or failure. These factors heighten the necessity to develop a capacitor of large capacitance and low ESR without increasing the size of its mounting area. 
     In one technique to increase the capacitance of the capacitor without expanding the size of its mounting area, a plurality of sintered elements are disposed in the same external housing and connected so as to be a single capacitor. In another technique, a plurality of flat capacitor elements are stacked to produce one solid electrolytic capacitor. 
     However, with the technique of using the sintered elements, there is a limitation in lowering ESR due to the resistance occurring when pulling out a cathode. Such resistance cannot be avoided since one&#39;s ability to produce thinner sintered elements is limited. The solid electrolytic capacitor made of a laminate of a plurality of flat sintered elements has problems. The number of the layers cannot be increased. Because, if there is an excessive number of layers, the sintered elements are deformed due to the difference in thickness between the anode connecting section and the cathode electric conductor laminated section, dielectric oxide films crack, and a leakage current failure occurs. 
     The present invention aims to provide a solid electrolyte capacitor of large capacitance and low ESR and its production method by overcoming the problems mentioned above. 
     SUMMARY OF THE INVENTION 
     The solid electrolytic capacitor of the present invention is manufactured by stacking at least two capacitor element laminated units (hereinafter, laminated unit), and connecting each electrode. In other solid electrolytic capacitors of the present invention, more than two laminated units using a conductive polymer as solid electrolyte are stacked and each electrode is connected. 
     ESR of the solid electrolytic capacitor of the present invention can be reduced inversely proportional to the number of the stacked laminated units. Moreover, since total capacitance of the layered capacitor elements equals the capacitance of the solid electrolytic capacitor, a large capacitance and low ESR solid electrolytic capacitor can be obtained without expanding its surface mounting area. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 illustrates a partially broken perspective view of a plate capacitor element in accordance with a first preferred embodiment of the present invention. 
     FIG. 2 illustrates a perspective view of the construction of a laminated unit in accordance with the first preferred embodiment of the present invention. 
     FIG. 3 illustrates a perspective view of the construction of a solid electrolytic capacitor in accordance with the first embodiment of the present invention. 
     FIG. 4 illustrates a perspective view of the construction of a laminated unit formed as a continuous hoop in accordance with a fourth embodiment of the present invention. 
     FIG. 5 is a chart illustrating the impedance and frequency characteristics of ESR of the solid electrolytic capacitor in accordance with the first and second embodiments of the present invention. 
     FIG. 6 illustrates a perspective view of the construction of the solid electrolytic capacitor in accordance with a fifth embodiment of the present invention. 
     FIG. 7 illustrates a perspective view of the construction of the solid electrolytic capacitor in accordance with the fifth embodiment of the present invention. 
     FIG. 8 illustrates a perspective view of the construction of the solid electrolytic capacitor in accordance with the fifth embodiment of the present invention. 
     FIG. 9 illustrates a perspective view of the construction of the solid electrolytic capacitor in accordance with the fifth embodiment of the present invention. 
     FIG. 10 illustrates a perspective view of the construction of the solid electrolytic capacitor in accordance with the fifth embodiment of the present invention. 
     FIG. 11 illustrates a perspective view of the construction of the solid electrolytic capacitor in accordance with the fifth embodiment of the present invention. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Preferred embodiments of the present invention are described below with reference to the accompanying drawings. 
     First Embodiment 
     Aluminum foil of 99.9% purity to be used as an electrode body  16  is roughened by electrolytic etching by a known method. The aluminum foil then is anodized in a solution of 3% ammonium adipate by applying a voltage of 13 volts for 30 minutes, to form an aluminum oxide layer which functions as a dielectric. The electrode body  16  is cut 3.5 mm in width and 6.5 mm in length. Polyimide tacking tape  2  is attached on predetermined places on both sides of the electrode body  16  as shown in FIG. 1 before dividing it into an element section  3  and an anode pulling out section  4 . The surface of each side of the electrode body, exposed by the cutting process, is anodized again in a solution of 3% ammonium adipate by applying a voltage of 13 volts for 30 minutes. 
     Subsequently, the element section  3  is dipped in a manganese nitrate aqueous solution and decomposed at 300° C. to form a conductive manganese oxide layer. The element section  3  is then dipped in a solution containing 0.1 mol of pyrrol and 0.15 mol of alkyl naphthalene sulphonic acid salt. By electrolytic polymerization, a conductive polymer layer  5  comprising polypyrrol is evenly deposited on the element section  3 . The electrolytic polymerization is carried out by applying a constant voltage of 2 volts, for 30 minutes through an electrode contacted on part of the manganese oxide. A flat capacitor element  1  described in FIG. 1 is produced after carbon paste layer  6  and silver paste layer  7  are formed on the element section  3  of a capacitor element  1 . 
     After a silver paste is painted as a conductive adhesive on the element sections  3 , four pieces of flat capacitor elements  1  generated in an above-described manner are stacked in such a way that the element sections  3  as well as anode pulling-out sections  4  are facing each other respectively. And a layered element  8  is formed as shown in FIG.  2 . 
     Metallic terminal members  9   a  and  9   b  are respectively connected to the element sections  3  and anode pulling-out sections  4  of the layered element  8 . The metallic terminal member  9   a  has three perpendicularly standing faces arranged on the three sides of the section where the element section  3  of the plate capacitor element  1  is placed. The terminal member  9   b  has a section which can be fabricated to cover the anode pulling-out section  4 . The element sections  3  of the layered element  8  are bonded to the terminal member  9   a  with silver paste. The anode pulling-out sections  4  of the layered element  8  are disposed on the terminal member  9   b  which has standing faces on two sides. Then, the standing faces are fabricated to cover the anode pulling-out sections  4 . Subsequently, four pieces of anodes are welded together by a YAG laser irradiated from above the terminal member  9   b , penetrating the anode pulling-out sections  4  of the stacked capacitor elements  1  to form a laminated unit  10 . The connection of the four anodes does not have to be provided by penetrating the center of the anode section as shown in FIG.  2 . The connection can be made by welding the sides of the anodes of the laminated elements by a laser. 
     The terminal member  9   a  made in a manner described above is electrically connected to a comb terminal  11   a  for connecting element sections with conductive adhesive as shown in FIG.  3 . Three laminated units  10  are stacked with the aid of epoxy resin based silver paste and cured by heat. The terminal members  9   b  of the laminated units  10  are electrically connected to a comb terminal  11   b  which is disposed opposite of the comb terminal  11   a , by laser welding. 
     The whole laminated unit is coated by encapsulating resin (not illustrated), and aged. The comb terminals  11   b  and  11   b  are bent along the line of the encapsulating resin to generate a solid electrolytic capacitor with a rating of 6.3 V, 150 μF. 
     Second Embodiment 
     In this embodiment, solid electrolytic capacitors are produced by the same method as in the first embodiment. The only difference is that the number of the flat capacitor elements  1  is changed from two to ten when the laminated unit  10  is formed. The rating of the solid electrolytic capacitors are, according to the number of capacitor elements, 75 μF, 112 μF, 150 μF (as is the case with the first embodiment), 187 μF, 225 μF, 262 μF, 300 μF, 337 μF, and 375 μF at the voltage of 6.3 volts. 
     When more than 10 capacitor elements are stacked, the anode section is distorted and the capacitor elements  1  are severed, failing to achieve desirable electrostatic capacitance or resulting in a large amount of leakage current. Due to such problems, it is impossible to generate a solid electrolytic capacitor with more than 10 flat capacitor elements. 
     FIG. 5 shows the result of the measurement made on the impedance and frequency characteristics of the solid electrolytic capacitor of the first and second embodiments. 
     As FIG. 5 indicates, the solid electrolytic capacitors of the present invention have large capacitance and idealistic impedance and low ESR characteristics. 
     Laser welding is taught in the first and second embodiments. However, other welding methods can also be applicable to the practice of this invention. 
     Third Embodiment 
     Three laminated units  10  produced by the same method described in the first embodiment are stacked by providing epoxy resin based silver paste between element sections  3 . The anode pulling-out sections  4  of the laminated units  10  are electrically connected by providing epoxy resin based silver paste between the comb terminals  11   b  and the terminal members  9   b  and curing it by heat. The whole units are encapsulated with encapsulating resin (not illustrated) and aged. The comb terminals 11 a  and 11 b  are bent along the encapsulating resin to produce a solid electrolytic capacitor with a rating of 6.3 V, 150 μF. As described in this embodiment, the anode sections can be bonded with conductive adhesive. 
     Fourth Embodiment 
     As FIG. 4 shows, after the element sections  3  are coated with silver paste, the flat capacitor elements  1  are stacked to a continuous hoop lead frame  12  such that the element sections  3  are facing each other. The lead frame  12  is a belt-shaped metallic frame which has continuously arranged wide protruding terminals on the locations corresponding to the anode pulling-out sections  4  and the element sections  3 . The layered element  8  is formed by stacking four pieces of anode pulling-out sections  4  on top of the other. The terminal members  9   b  are fabricated to cover the anode pulling-out sections  4 . Then, four pieces of anode pulling-out sections  4  of the capacitor elements  1  are laser welded by a irradiation from above the terminal member  9   b , to form the four-layered laminated unit  10 . 
     Of the lead frame  12  having the laminated units  10  thereon, only the parts of the laminated units  10  are cut out to obtain independent laminated units  10  with metallic terminal members  9   a  and  9   b . Subsequently, two independent laminated units  10  are bonded on the laminated unit  10  disposed on the lead frame  12  with silver paste, to form a twelve-layered solid electrolytic capacitor on the continuous lead frame  12  as shown in FIG.  3 . 
     The whole unit is then encapsulated with encapsulating resin (not illustrated) and aged. The terminals are bent along the face of encapsulating resin to complete the manufacturing process of a solid electrolytic capacitor with a rating of 6.3 V, 150 μF. 
     In this embodiment the lead frames  12  of the same shape are used for producing the laminated unit  10  and the capacitor element  1 . However, the shape of the lead frame  12  as taught above may be modified without deviating from the spirit of the invention. In the above explanation, conductive adhesive is used to connect the terminal members  9   a  and  9   b , when the laminated units  10  are stacked. However, laser welding can be used to connect the terminal members without adversely affecting the effectiveness of this invention. 
     In the location of the terminal member  9   b , a connecting element can also be provided separately from the laminated unit  10  to connect anodes. 
     Fifth Embodiment 
     FIGS. 6 through 11 show detailed description of connecting the anode pulling-out sections  4  of each laminated unit  10  when three laminated units  10  are stacked in this embodiment. 
     In FIG. 6, connecting elements  13   a ,  13   b  and  13   c  are provided on the bottom surface of each terminal member  9   b  of the top, middle and bottom laminated units  10 . The connecting elements  13   a ,  13   b  and  13   c  can be connected to the bottom surface of the terminal member  9   b  by laser welding or resistance welding. The terminal  9   b  can be bent to give it a shape illustrated in FIG.  6 . The connecting elements  13   a ,  13   b  and  13   c  are layered at the tip when the top, middle and bottom laminated units are stacked. In this state, the layered potions of the connecting elements  13   a ,  13   b  and  13   c  can be electrically connected by laser welding as indicated by arrows in the FIG. 6, thereby connecting the anode pulling-out sections  4 . 
     In FIG. 7, connecting elements  13   d  are provided to the bottom surface of the top and middle terminal members  9   b . The connecting elements  13   d  are connected to the bottom surface of the terminal members  9   b  by laser welding or resistance welding, or electrically connected to the terminal members  9   b  by bending them to provide the shape shown in FIG.  7 . The connecting elements  13   d  function as spacers to fill the gap between the top, middle and bottom capacitor element laminated units  10  when they are stacked. The connecting elements  13   d  and the terminal member  9   b  at the bottom are electrically connected by laser welding provided from above diagonally as arrows in FIG. 7 indicate. This process of laser welding connects the anode pulling-out sections  4  with each other. 
     In FIG. 8, connecting elements  13   e  are provided to the bottom surface of the top and middle terminal members  9   b . The connecting elements  13   e  are connected to the bottom surface of the terminal members  9   b  by laser welding or resistance welding, or electrically connected to the terminal members  9   b  by bending them to provide the shape shown in FIG.  8 . When the top, middle and bottom laminated units  10  are stacked, the connecting element  13   e  at the top sandwiches the terminal member  9   b  in the middle from the side. Likewise, the connecting element  13   e  in the middle sandwiches the terminal member  9   b  at the bottom from the side. In this state, the connecting elements  13   e  are welded by a laser irradiated from above diagonally or from the side to electrically connecting them to the middle and bottom terminal members  9   b , thereby connecting the anode pulling-out sections  4  with each other. 
     In FIG. 9, connecting element  13   f  is provided to the bottom surface of the top terminal member  9   b . The connecting element  13   f  is connected to the bottom surface of the terminal members  9   b  by laser welding or resistance welding, or electrically connected to the terminal member  9   b  by bending it to provide the shape shown in FIG.  9 . When the top, middle and bottom laminated units  10  are stacked, the connecting element  13   f  at the top sandwiches the middle and bottom terminal member  9   b . In this state, the connecting element  13   f  is welded by a laser irradiated from above diagonally or from the side to electrically connecting it to the middle and bottom terminal members  9   b , thereby connecting the anode pulling-out sections  4  with each other. 
     In FIG. 10, connecting elements  14  are disposed to the sides of the terminal members  9   b . The connecting elements  14  are then welded by a laser irradiated from above diagonally or from the side as indicated by arrows in FIG.  10 . By the laser welding, the connecting elements  14  are electrically connected to the top, middle and bottom terminal members  9   b , thereby connecting the anode pulling-out sections  4  of each laminated unit  10  with each other. The connecting elements  14  are desirably provided with two protrusions so that positioning can be conducted using the space between top and middle as well as middle and bottom terminal members  9   b.    
     In FIG. 11, connecting elements  15  are inserted from the front of the terminal members  9   b . In this state, the connecting elements  15  are welded by a laser irradiated from above diagonally or from the side to electrically connecting them to the top and middle terminal members  9   b , thereby connecting the anode pulling-out sections  4  to each other. In this case, it is difficult to provide the comb terminal  11   b . Therefore, the connecting elements  15  are desirably hoop-shaped to secure stable supply of the laminated unit  10 . 
     In the present invention, the laminated unit comprising at least more than one plate capacitor element which use conductive polymer as solid electrolyte, are connected parallel to each other on a single lead frame. ESR at high frequencies can be reduced, inversely proportional to the number of the stacked laminated units. Moreover, the total capacitance of the layered capacitor elements equals the capacitance of the solid electrolytic capacitor. Thus, the present invention provides a solid electrolyte capacitor of a large capacitance and a low ESR without expanding it&#39;s surface mounting area in a device.