CA1289208C - Aluminum solid electrolytic capacitor and manufacturing method thereof - Google Patents

Abstract

Abstract:
An aluminum foil type of solid electrolytic capacitor has the distance between two foils in the capacitor element as determined by the thickness of a separator kept at a value between ten to sixty micrometers. A solid electrolyte is formed between the two foils by the thermal decomposition of an electrolytic solution impregnated into the capacitor element. A manganese dioxide electrolytic layer is formed between the electrode foils by thermally decomposing the electrolytic solution at a temperature between 200 and 260°C
for a time between 20 and 40 minutes. The result is a capacitor with an improved impedance characteristic manufactured at low cost.

Description

Aluminum Solid Electrolytic Capacitor and Manufacturing Method Thereof _ The present invention relates to an aluminum solid electrolytic capacitor and a manufacturing method thereof.
A conventional solid electrolytic capacitor is manu-factured by sintering fine powders (of the order of ten to one hundred micrometers) of aluminum or the like in the shape of a column or a plate, including forming an oxide film on the surface of the sintered body by anode oxidation in an electrochemical conversion solution containing a weak acid as the main component, and subsequently forming manganese dioxide (solid electrolyte) on the oxide film by thermal decomposition of manganese nitrate. However, a solid electrolytic capacitor of this type is not of the winding type, and therefore it is difficult to manufacture such a capacitor with a large capacitance. In order to manufacture such a capacitor with a larger capacitance, the size oE the capacitor is required to become large which i8 not economical.
Another type of solid dry electrolytic capacitor has been proposed wherein aluminum or tantalum foils forming the anode and cathode of the capacitor, which have been etched and treated for electrochemical conversion, are wound to form a capacitor element with a separating paper inserted between them, with manganese dioxide Eormed on the foils, for example, by thermal decomposition of a , , 1~8~1208 manganese nitrate solution immersed into the element (refer to Japanese Patent Publication No. 33-5177). The impedance characteristic of a capacitor of tnis type is not good, especially in a frequency range higher than 500 kHz, and the size thereof inevitably becomes large, making practical use of a capacitor of this type difficult.
It is an object of the present invention to provide an aluminum solid electrolytic capacitoe having a good impedance characteristic at high frequencies.
It is another object of the present invention to provide an aluminum solid electrolytic capacitor capable of reducing the leakage current.
It is still another object of the present invention to provide a method of manufacturing an aluminum solid lS electrolytic capacitor having these qualities.
It is a further object of the present invention to provide a method of manufacturing an aluminum solid electrolytic capacitor having a high moisture resistance.
It is a still further object of the present invention to provide a method of manufacturing a chip-type of aluminum solid electrolytic capacitor having good workability and productivity.
More specifically, the invention consists of an aluminum solid electrolytic capacitor, comprising: an anode aluminum foil having an oxide film formed on a surface thereof, a cathode aluminum foil and a separator for ~eparating said anode and cathode aluminum foils, the two foils and the separator being wound to form a capacitor element, the distance between the two foils in the capacitor element as determined by the thickness of the separator being kept at a value between ten to sixty micrometers, a solid electrolyte being formed between the - two foils by thermal decompositlon of an electrolytic solution impregnated into the capacitor element.
~ The invention also consists of a manufacturing method for an aluminum solid electrolytic capacitor, comprising io .
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: ' ' ' . -~;~8~08 the steps of: winding an anode aluminum foil and a cathode aluminum foil together with a separator for separating said anode and cathode aluminum foils to form a capacitor element, impregnating an electrolytic solution of manganese nitrate into the capacitor element, and forming a SOlia electrolytic layer of manganese dioxide between the electrode foils by thermally decomposing the electrolytic solution at a temperature between 200 to 260C for a time between 20 and 40 minutes.
The invention also consists of a manufacturing method for an aluminum solid electrolytic capacitor comprising the steps of: winding an anode aluminum foil and a cathode aluminum foil together with a separator for separating said anode and cathode aluminum foils to form a capacitor element, the anode foil having an oxide film formed on its surface, impregnating an electrolytic solution of manganese nitrate into the capacitor element, to which solution a fine powder of manqanese dioxide is added, and forming solid electrolytic layer between the electrode foils by thermally decomposing the electrolytic solution.
The invention also consists of a manufacturing method for an aluminum solid electrolytic capacitor comprising the steps of: winding an anode aluminum foil and a cathode aluminum foil together with a separator for separating said anode and cathode aluminum foils to form a capacitor element, while keeping the distance between said aluminum foils at a value between ten to sixty micrometers, impreg-nating an electrolytic solution of manganese nitrate into the capacitor element, forming a solid electrolytic layer ~between said aluminum foils by thermally decomposinq the electrolytic solution, and doping lithium into the solid electrolytic layer.
The invention also consists of a manufacturing method for an aluminum solid electrolytic capacitor, comprising ~35 the steps of: winding an anode aluminum foil, a cathode ,~
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aluminum foil together with a separator for separating said anode and cathode aluminum foils to form a capacitor element, the anode foil having an oxide film formed on its surface, impregnating an electrolytic solution of manganese nitrate into the capacitor element, forming a solid electro-lytic layer of manganese dioxide between the electrode foils by thermal decomposition of the electrolytic solution, performing electrochemical conversion treatment in a weak acidic solution for restoring deterioration of the oxide film on the aluminum foil before completion of forming the solid electrolyte, again forming a manganese dioxide layer by impregnating a manganese nitrate solution with carbon added into the capacitor element, and baking carbon on the solid electrolytic layer after impregnating carbon powder lS added into the manganese nitrate solution in an amount much larger than that used when again forming the mahganese dioxide layer.
The invention also consists of a manufacturing method for an aluminum solid electrolytic capacitor, comprising the steps of: winding an anode aluminum foil, a cathode aluminum foil together with a separator for separating said anode and cathode aluminum foils to form a capacitor element, forming a solid electrolytic layer between the electrode foils, placing an amount of resin for fixing the capacitor element at the bottom of a case having an opening, inserting the capacitor element into the case, fixing the capacitor element in the case with the resin, and sealing the o~ening of th~ case with a further amount of the same resin.
The invention also consists of a manufacturing method for an aluminum solid electrolytic capacitor, comprising the steps of: winding an anode aluminum foil, a cathode aluminum foil together with a separator for separating said anode and cathode aluminum foils to form a capacitor element, each foil having been bonded with a lead, forming , . ~ .
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, ' ' . .- , '' ~28g~08 a solid electrolytic layer between the electrode foils, placing the capacitor element in a metallic case having an opening, connecting one of the leads electrically to the inside of the metallic case using a binder, and sealing the opening of the case with insulating resin.
In the drawings:
Fig. 1 is a flow chart showing steps in manufacturing a capacitor according to a first preferred embodiment of the present invention;
Fig. 2 is a perspective view of an aluminum solid electrolytic capacitor according to an embodiment of the present invention;
Figs. 3(a) and 3(b) are enlarged schematic sectional views of a part of a capacitor element after an impreg-lS nation process and after a baking process, respectively;
Fig. 4 is a graph showing the frequency characteristic o the impedance of capacitors manufactured according to the first preferred embodiment of the present invention;
Fig. 5 is a graph showing the change in capacitance plotted against frequency, of capacitors according to the first preferred embodiment of the present invention;
Fig. 6 is a graph showing the frequency characteristic of the impedance of capacitors according to the first preferred embodiment of the present invention;
Fig. 7 is a flow chart showing steps in manufacturing a capacitor according to a second preferred embodiment of the present invention;
F~gs 8(a) and 8~b) are enlarged schematic sectional views of a part of a capacitor element after an impreg-nation process and after a baking process, respectively;
Fig. 9 (with Fig. 6) is a graph showing the frequency characteristic of the impedance of capacitors manufactured according to the second preferred embodiment;

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1~89208 Fig. 10 is a flow chart showing steps in manufacturing a capacitor according to a third preferred embodiment of the present invention;
Fig. 11 is a graph showing~the frequency characteristic of capacitors manufactured according to the third preferred embodiment of the present invention;
Fig. 12 is a flow chart showing steps in manufacturing a capacitor according to a fourth preferred embodiment of the present invention;
Fig. 13 (with Fig. 11) is a graph showing the frequency characteristic of the impedance of capacitors manufactured according to the fourth preferred embodiment of the present invention;
Fig. 14 is a flow chart showing steps in manufacturing a capacitor according to a fifth preferred embodiment of the present invention;
Figs. 15(a) and 15(b) are perspective views of a chip capacitor accordLng to embodiments of the present invention;
Fig. 16 is a perspective view of another chip capacitor according to an embodiment of the present inventionl Figs. 17(a) and 17(b) are respectively a perspective view and an elevational view of still another chip capacitor according to an embodiment of the present invention;
Figs. 18(a) and 18(b) are respectively a perspective view;and an end view of a rurther chip capacitor according to an embodiment of the present invention;
Figs. l9(a) and l9(b) are respectively a perspective view and an end view of a still further chip capacitor according to an embodiment of the present invention;
Figs. 20(a) and 20(b) are respectively a perspective view and a side view of one more chip capacitor according - to an embodiment of the present invention;

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Fig. 21 is a sectional view of a capacitor of another type according to an embodiment of the present invention;
and Figs. 22, 23, 24 and 25 are respectively sectional views of capacitors showing various connecting methods for leads according to embodiments of the present invention.
Fig. 1 shows a flow chart of a manufacturing method of an aluminum solid electrolytic capacitor according to the first preferred embodiment of the present invention while Fig. 2 shows the structure of a capacitor element 10 manu-factured according to this method.
First, aluminum foils 1 and 2 of high purity (99.99~or more) are subjected to an etching step Sl for engraving them electrochemically to increase their effective surface areas. Next, oxide films la (thin films of aluminum oxide) are formed on both surfaces of one aluminum film, by treating it electrochemically in an electrolyte (electro-chemical conversion treatment) in a second step S2. The aluminum foil 1 having been subjected to the etching and the electrochemical conversion treatment, is used as an anode foil 1, while another film, having only been etched, is used as a cathode foil 2 arranged opposed to the anode foil 1, two sheets of manila paper 3 being put between the foils 1 and 2 as a separator and on the outer surface of the cathode foil 2. Stacked foils 1 and 2 and separators 3 are then wound cylindrically to form a capacitor element 10 in a winding step S3, as shown in Fig. 2. Reference numerals 4, 6 and 5, 7 respectively designate aluminum leads and lead wires, the leads 4, 6 being connected to the foils 1, 2 after the electrochemical conversion treatment.
The capacitor element 10 thus formed is then subjected to an impregnation treatment using a manganese nitrate solution 8, as shown schematically in Fig. 3(a). The portions of the manganese nitrate solution 8 on both sides of the separators 3 are connected to each other through , the separators 3. The capacitor element 10 is then heated in air to deposit manganese dioxide layers 9 of solid electeolyte by thermally decomposing the manganese nitrate, as shown schematically in Fig. 3(b). These impregnation and thermal decomposition processes are repeated several times to form dense manganese dioxide layers 9, in step s4.
The manganese dioxide layers 9 on both sides of the manila paper separators 3 are connected to each other through such separators. Further, graphite (carbon) powder dispersed in manganese nitrate solution is impregnated into a space between the manganese dioxide layer 9 and the cathode foil

2, and a carbon layer (not shown) is baked on the electro-lytic layer. Next, in order to restore the thermal deterioration of the oxide film caused by the thermal decomposition used for forming the manganese dioxide layer 9, an electrochemical treatment in an electrolytic solution, namely a reformation, is performed in a fifth step S5. This reformation treatment enables the leakage current to be decreased remarkably. A capacitor element 10 produced in this way is molded with resin, or is installed in a metal case of aluminum or the like or in a resin case, and is sealed with a sealant, such as an epoxy resin, to complete the formation of a capacitor in a sixth step S6.
In this capacitor, the separator 3 prevents mechanical contact of the anode foil 1 with the cathode foil 2 and separates these foils by a constant distance to prevent a shor~ circuit between them and to guarantee a high voltage breakdown. Further, it has been found that the thickness of the separator 3 greatly affects the formation of the manganese dioxide layer which largely plays the role of cathode. The present invention is intended to improve the impedance characteristic by setting the distance between the foils 1 and 2 to be determined by the thickness oÇ the separator 3.

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)8 Fig. 4 shows the frequency characteristic of theimpedance of aluminum solid electrolytic capacitors that have been manufactured by the method described above to have an electrostatic capacitance of 1 ~F and a rated voltage of 16 V, as a function of the thickness of the separator. In Fig. 4, curves 4A, 4B, 4C, 4D and 4E
correspond to capacitors having a separator thickness of 10, 30, 50, 60 and 100 ~m, respectively. As is apparent from Fig. 4, the frequency characteristic of the impedance improves with a decrease in the thickness of the separator.
The capacitor with a separator thickness of 100 ~m has a too high an impedance to be used in practice, because it is higher than 10 Q at 1 MHz. On the other hand, the other capacitors with separator thicknesses up to 60 ~m have impedances lower than lQ at 1 MHz, so that they are suitable for practical use.
Fig. 5 shows the frequency characteristic of the ratio of change in the electrostatic capacitance to that at 0.1 kHz of the capacitors having a capacitance of 1 ~F and a rated voltage of 16 V, as a function of the thickness of the separator, wherein curves 5A to 5E correspond to capacitors having a separator thickness of 10, 30, 50, 60 and 100 ~m, respectively. As is apparent from Fig. 5, the frequency characteristic of the ratio of change of capacit-ance is better up to a higher frequency with smaller separator thicknesses. For the capacitor with a separatorthickness of 100 ~m, the ratio of capacitance begins to increase rapidly around 10 kHz, so that this capacitor is hard to use in practice. On the other hand, the other capacitors with a separator thickness up to 60 ~m have curves of this ratio that increase comparatively gradually, so that they can be used without any problem.
Fig. 6 shows the impedance characteristic of an aluminum solid electrolytic capacitor manufactured according to the first preferred embodiment of the present invention, together with conventional capacitors for ~,''..

~28~0~3 comparison. In Fig. 6, the curve 6A denotes the impedance characteristic of a capacitor according to the present invention having a separator thickness of 30 ~m (capacitance 10 ~F, rated voltage 16 V), while curves 6B, 6C and 6D respectively denote that of a conventional tantalum capacitoe (capacitance 10 ~F, rated voltage 16 V), a conventional aluminum solid electrolytic capacitor (capacitance 10 ~F, rated voltage 16 V) and a conventional solid electrolytic capacitor using a TCNQ salt as an organic semiconductor (capacitance 10 ~F, rated voltage 25 V). It is apparent from Fig. 6 that the capacitor according the invention, curve 6A, has a superior impedance characteristic to the conventional tantalum capacitor and aluminum solid electrolytic capacitor, especially at high frequencies, and is as good as the solid electrolytic capacitor that uses a TCNQ salt as an organic semiconductor.
Table 1 shows the relation between the thickness of the separator and the measured defective ratio of short circuit of aluminum solid electrolytic capacitors (capacitance 1 ~F, rated voltage 16 V) made according to the first preferred embodiment of the present invention. The number of samples was fifth for each thickness.
The data compiled in Table 1 shows that the defective ratio increases with a decrease in the thickness of the separator and becomes as high as 8.26% at 5 ~m, while it is lower than 1% at 10 ~m or more.
By taking into account the data shown in Figs. 4 to 6 and Table 1, it is preferred to set the thickness of separator that determines the distance between the electro-lytic foils at a value in the range between 10 and 60 ~m,preferably between 30 and 60 ~m.

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Table 1 .._ thickness of defective ratio separator of short circuit . _ .
100 ~m 0.20 %

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As explained above, the impedance characteristic of an aluminum solid electrolytic capacitor can be greatly improved, especially at high frequencies, without increasing the size thereof, so that it becomes applicable to frequencies from 100 kHz to 10 MHz. Further, because such a capacitor uses manganese dioxide the cost of which is only about a hundredth of that of TCNQ salt, a capacitor with a frequency characteristic as good a that of a conven-tional solid electrolytic capacitor that uses an organic semiconductor can be manufactured more cheaply.

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Fig. 7 shows a flow chart of a manufacturing method of an aluminum solid electrolytic capacitor according to a second preferred embodiment of the present invention, which capacitor has improved impedance characteristic of capacitance.
The capacitor element 10 is manufactured in the same way as in the first preferred embodiment. Aluminum foils of high purity (99.99% or more) are first subjected to an etching treatment for engraving the foils electrochemically to increase their effective surface area in a first step Sll. Next, oxide films (thin films of aluminum oxide) la are electrochemically formed on the surface of one of the aluminum foils in the electrolytic solution (electro-chemical conversion treatment) in a second step S12. The aluminum foil 1, which has been subjected to both the etching and the electrochemical conversion treatment, is used as the anode, while another film 2, which has only been etched, is used as the cathode arranged opposed to the anode, and sheets 3 of manila paper as separators are put between the foils 1 and 2 and on the foil 2, respectively.
The stacked foils 1 and 2 and the separators 3 are then wound cylindrically, as shown in Fig. 2 to form the capacitor element 10 in a third step S13.
The capacitor element 10 is then subjected to thermal treatment to carbonize the manila paper to form separators

3' to lower the density by making the filaments thinner (step S14). In this heat treatment, a temperature between 150 and 300C and a time of between 10 and 40 minutes are suitable. By this treatment, the amount of manganese nitrate to be impregnated into the capacitor element can be increased and as a result the characteristics of the capacitor can be improved.
The capacitor element 10 thus formed is then subjected to impregnation treatment with a manganese nitrate solution 8, as shown schematically in Fig. 8 (a). The portions of the manganese dioxide solution 8 on both sides of the separators 3' are connected to each other through the separators 3'. The capacitor element 10 is then heated in air to deposit manganese dioxide layers 9 of solid electrolyte by thermally decomposing the manganese nitrate, as shown schematically in Fig. 8(b). The manganese dioxide layers 9 on the two sides of the separators are connected to each other through such separators. This impregnation and thermal decomposition step S15 is repeated several times to form dense manganese dioxide layers 9. Further, graphite (carbon) powder dispersed in a manganese nitrate solution is impregnated into a space between the manganese dioxide layer 9 and the cathode foil 2, and the carbon layer ~not shown) is baked on the electrolytic layer.
Next, in order to restore the thermal deterioration of the manganese dioxide layers 9 caused by the thermal decompo-sition used for forming the manganese dioxide layer, an electrochemical treatment in an electrolyte solution, namely reformation, is performed at a sixth step S16.
~his reformation treatment enables the leakage current to be reduced remarkably. An element 10 produced in this way is molded with a resin, or is installed in a metal case of aluminum or the like or in a resin case, and is sealed with a sealant, such as an epoxy resin, to finish the element as a capacitor (step S17).
In the manufacturing method the thermal decomposition conditions of the manganese nitrate greatly affect the formation of the manganese dioxide layer. If the tempera-ture is too l.ow, the thermal decomposition of the manganesenitrate proceeds efficiently to invite a so-called "under-decomposed" state, whereas if the temperature is too high, the manganese nitrate is decomposed too much and this invites a so-called "overdecomposed" state. In addition, if the time for thermal decomposition is too short, the manganese nitrate remains in the underdecomposed state, ,~ .

whereas if the time is too long, it enters the "overde-composed" state. In either of such an underdecomposed or overdecomposed state, the manganese dioxide layer will not function efficiently as a solid electrolyte, so that the S characteristics of the capacitor, such as tan ~ or the impedance, are deteriorated.
Table 2 shows the relation between the conditions of thermal decomposition and the characteristics of an aluminum solid electrolytic capacitor having a capacitance of 10 ~F and rated voltage of 16 V. The number of samples was fifth for each test. The temperature was varied within a range between 180 and 280C and the decomposition time was varied within a range between 10 and 50 minutes. In Table 2, tan ~ and impedance denote values measured at 1 kHz and at 100 kHz, respectively. The evaluation is derived from both tan ~ and the impedance together, that is, the evaluation is good (O) if tan ~ is less than 0.04 and the impedance is less than 0.4 Q, not so good (~) if tan ~ is between 0.4 and 0.5 Q, and bad (x) if tan ~ is 0.051 or more and the impedance is 0.51 Q or more. It was found that a decomposition temperature between 200 and 260C and a decomposition time between 20 and 40 minutes are optimum.

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Table 2 . . _ _ .
temp (C) time (min) tan 6 impedance (n) Evaluation .. .. _ _ 180 10 0.091 1.18 180 20 0.083 0.96 180 30 0.079 0.84 X
180 40 0.073 0.84 X
180 50 0.070 0.82 X
200 10 0.071 0.84 X
200 20 0.046 0.49 ~00 30 0.042 0.48 ~
200 40 0.038 0.45 o -200 50 0.049 0-53 . _ _ 220 10 0.065 0.76 X
220 20 0.043 0.48 ~
.. _ _ . .. . . . _ 220 30 0.036 0.39 o 220 40 0.030 0.33 O
220 S0 0.051 0.57 X
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240 10 0.053 0.63 -240 20 0.037 0.39 O
. . _ _ _ 240 30 0.023 0.29 O
240 40 0.025 0.30 O
240 S0 0.054 0.58 X
260 10 0.053 0.61 X
260 20 0.030 0.32 O
_ _ _ _ 260 30 0.032 0.35 260 40 0.040 0.40 260 50 0.050 0.67 _ _ _ _ _ 280 10 0.053 0.62 X
-280 20 0.057 0.67 X
280 30 0.061 0.70 . .
280 40 0.064 0.79 X
280 50 0.072 0.91 X

128~08 Fig. 9 shows the frequency characteristic of impedance obtained under various decomposition conditions. Curves 9A, 9B and 9C correspond to conditions of 180C, 30 minutes;
280C, 30 minutes and 240c, 30 minutes, respectively. The last conditions of 240C and 30 minutes give an excellent impedance characteristic.
Fig. 10 shows a flow chart for a manufacturing method according to a third preferred embodiment of the present invention.
As is apparent from a comparison of Fig. 10 with Fig. 7, the only difference is that the manganese nitrate solution with a fine powder of manganese dioxide (MnO2) is used for impregnation (step S25).
Namely, in the third preferred embodiment, a fine powder of manganese dioxide is added beforehand to the manganese nitrate solution, although manganese dioxide itself is formed by the thermal decomposition of the manganese nitrate. The amount of added fine powder of manganese dioxide greatly affects the formation of the manganese dioxide layer.
The other steps S21-S24 and S26-S28 corresponds to the steps Sll-S17, respectively (Fig. 7).
Table 3 shows the relation between the amount (weight percent) of fine powder of manganese dioxide and the impedance of 100 kHz, wherein fifty capacitors of rated voltage 16 V and capacitance 10 ~F were measured for each amount of addition between 0 and 10% in steps of 2%.
The eesult shown in Table 3 suggests that an amount of addition between about 4 and 6 wt% is the most favorable for the impedance chaeacteristic.
Fig. 11 shows the relation of the frequency character-istic of impedance with the amount of addition of manganese diox$de powder, wherein curves llA, 11~, llC, 11D, llE and llF correspond respectively to amounts of addition of 0, 2

4, 6, 8 and 10%.

, , 39~08 Table 3 . __ . _ amount of MnO2 added impedance (at 100k~z) 0 % 0.46 n . .' 2 % 0.48 n . ._ 4 % 0.30 n . . ~
6 % 0.26 n 8 % 0.46 n . _ 10 % ¦ 0.54 n I

Fig. 11 also suggests that the amount of the addition of the fine powder of manganese dioxide is best in the range between about 4 and 6 wt%.
By using a fine powder of manganese dioxide of about 4 to 6 wt%, the frequency characteristic of an aluminum solid electrolytic capacitor can be improved, especially at high frequencies, without enlarging its size. Further, this process is favorable for lowering the cost, because no new steps; are required, and it can be adopted for practical use.
Fig. 12 shows a flow chart for a manufacturing method of a capacitor according to a fourth preferred embodiment of the present invention.
The fourth preferred embodiment is characterized in that a lithium doping step S36 is performed after the thermal decomposition of the manganese nitrate impregnated into the capacitor element. A carbon layer is then baked in a space between the manganese dioxide layer 9 and the cathode foil 2 (step S37). Other steps S31-S34, S38 and S39 are substan-tially the same to those Sll-S14, S16 and S17 of the second preferred embodiment (Fig. 7).

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In step S36, the capacitor element 10 in which the manganese dioxide layer has been formed is immersed as an active electrode together with a lithium plate as a counter electrode in a mixed electrolytic solution of lithium chlorate, propylene carbonate and dimethyl ether, and a constant current of 0.1 to 0.3 mA per element is applied in the electrolytic solution. During this process, Li+ ions in the electrolytic solution diffuse into the crystal lattice of manganese dioxide (MnO2) in the solid state, so as to cause the following reaction to reduce quadrivalent Mn to trivalent Mn:

Li + Mn ~IV) 2 + ~n (III) O (Li Further, a carbon layer is baked on the electrolytic layer in step S37.
The lithium doping after the formation of the manganese dioxide layers 9 in the manufacture of a capacitor enhances the electrical conductivity of the manganese dioxide layers and improves the characteristics of the capacitor.
Table 4 shows differences in the characteristics between capacitors manufactured with and without using tbe lithium doping process. The impedance at 100 kHz and tan ~ at 120 kHz were measured for fifty samples of each capacitor having a rated voltage of 16 V and a capacitance of 10 ~F, and respective averages being calculated from the measured valuies.

Table 4 lithium impedance (lOOkHz) tan 6 (120Hz) doping none0.46 n 2.6 %
doping 0.21 n 1.8 ~

As is clear from Table 4, both of the impedance and the tan ~ of the capacitor in which lithium was doped are improved remarkably relative to one without doped lithium.
Fig. 13 shows the frequency characteristic of impedance of a capacitor manufactured using lithium doping (13A~ and of a capacitor manufactured without using lithium doping (13B). Fig. 13 clearly indicates that the impedance charac-teristic is greatly improved, especially at high frequen-cies, when using the lithium dopin~ process.
Fig. 14 shows a flow chart for a manufacturing method of a capacitor according to a fifth preferred embodiment of the present invention.
A capacitor element 10 as shown in Fig. 2 is manufac-tured through the first to third step S41 to S43 similar to those of the foregoing preferred embodiments.
Next, any scratches on the aluminum foils or defects in the foils caused at their cut edges or the like are restored with an electrochemical conversion treatment in a weak acidic electrolytic solution (cut edge reformation) in a fourth step S44.
The element 10 is then subjected to thermal treatment to carbonize the manila papers to form the separators 3' and lower the density by making the filaments thinner in a fifth step S4S, under conditions of a temperature between 150 and 300C and a time between 10 and 40 minutes.
The element 10 is then subjected to an electrochemical conversion treatment (step S46) to restore the oxide film which has been deteriorated thermally.
The element 10 thus formed is then subjected to impreg-nation with the manganese nitrate solution. Then, the element 10 is heated in air under conditions, for example,of a temperature between 200 and 260C and a time between 20 and 40 minutes, whereby to decompose thermally the impregnated manganese nitrate to deposit a manganese dioxide layer of solid electrolyte (step S47). The impregnation and thermal decomposition processes are repeated several , . .
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~;~8~t~08 times to form dense manganese dioxide layers similarly to the foregoing preferred embodiment. During this manganese dioxide formation process or before completion of the forma-tion of the solid electrolyte of manganese dioxide, a S further electrochemical conversion treatment (mid-formation) (step S48) is performed through the solid electrolytic layer similarly to the electrochemical conversion treatment of step S42. The thermal deterioration of the oxide film caused by thermal decomposition is thus restored.
Next, another thermal decomposition treatment (step S49) is performed using manganese nitrate wherein graphite (carbon) powder has been added under conditions substan-tially the same as those of the above-mentioned thermal decomposition, whereby to perfect the formation of the solid electrolytic layers 9 of manganese dioxide (manganese nitrate thermal decomposition). Further, graphite ~carbon) powder in an amount much laeger than that used in the manganese nitrate thermal decomposition process, dispersed in the manganese nitrate solution, is impregnated into the space between the solid electrolytic layer 9 and the cathode foil 2, and a carbon layer is formed on the solid electro-lyte by baking the carbon under conditions substantially the same as in the above-mentioned thermal decomposition condi-tions (carbon layer baking) (step S49). The carbon layer fills the space between the solid electrolyte 9 and the cathode foil 2, so that the contact resistance between them is decreased and the layer 9 is protected.
Next, in order to restore the thermal deterioration of the oxide film caused by the foregoing carbon layer baking (step S49), an electrochemical treatment in an electrolytic solution, namely reformation, is performed (step S50).
The capacitor element 10 thus manufactured is molded with resin (resin dip), or is sealed with epoxy resin or the like after being inserted into a metallic case of ~i:

,, aluminum or the like or into a resin case (case inseetion or resin sealing) (step SSl) to form a finished capacitor.
Table S shows the relation between the leakage current and the defective ratio of short circuits of various combinations of the cut edge formation (step S44), mid-formation (step S48) and reformation (step S49), wherein O
and X denote the adoption and the non-adoption of each step, respectively. All of the samples used for measurement had a eated voltage of 16 V and a capacitance of 10 ~F.

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The leakage current shows an average o~ fifty samples, while the defective ratio of short circuits denotes a ratio of the samples having a large leakage current (of an order of nA) to 100 samples.
Table 5 shows clearly that both of leakage current and the short circuit ratio are most improved when all the cut edge reformation, mid-formation and reformation processes are performed (No. 5). The comparison of cases of No. 5 and No. 7 makes the effect by the mid-formation process clear.
In this preferred embodiment, because the mid-formation treatment (step S48) is performed before the carbon baking treatment and before forming a solid electrolytic layer (step S49), the oxide film deteriorated in the thermal decomposition step S47 can be restored completely without suppressing the electrochemical conversion with the solid electrolyte and carbon layers.
Although manufacturing methods for a capacitor of the winding type have been explained in the foregoing preferred embodiments, the present invention is also applicable to a chip capacitor (surface mount type of capacitor), as will now be explained~
Figs. 15(a) and 15(b) shows a chip capacitor, namely a cylindrical capacitor 20 with a cylindrical case 21 wherein a capacitor element manufactured according to the present invention is installed. A small rectangular sheet 22 is fixed on the cylindrical surface 20a of the capacitor 20.
The 8heet 22 is made of a fluorine-contained resin, silicone resin, polyimide resin or the like, of a size of about 4 mm x 5 ~m with a thickness 0.2 mm, and it is bonded on the surface 20a with a heat resistant binder, such as an epoxy resin or W resin, or with a pressure sensitive adhesive double coated tape. Any binder can be used if its position does not move at room temperature and it does not peel on reflow of solder.
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f,, "( ';.' 2~8 The cylindrical capacitor 20 with the sheet 22 can be used as a chip capacitor which can be set in the horizontal direction.
The chip capacitor 20 can be mounted stably on a printed circuit board. Further, the heat resistant sheet 22 can protect the main body of the capacitor 20 from the heat of the circuit board on soldering. Leads 23 can be bent properly for use as a chip capacitor.
Fig. 16 shows a similar type of chip capacitor 20 with a sheet 24 which has a curved inner face along the side 20a.
Such a sheet can be produced, for example, by a formation process. The sheet 24 makes it stable to locate the capa-citor on the printed circuit board, and prevents possible cracking of the casing tube of the capacitor and deteriora-tion of its characteristics due to heat transmitted from the circuit board.
Figs 17(a) and 17(b) show a chip capacitor e~uipped witha first sheet 25 for fixing the capacitor 20 stably on a printed circuit board and a second sheet 26 for serving as a plane for engagement when mounting the capacitor on a printed circuit board using an absorbing chuck. The second sheet 26 has a similar size and thickness of about 0.2 to 0.3 mm as the first one 25, and is adhered to the capacitor 20 with, for example, a quick-drying epoxy resin. By forming a plane for engagement, the absorbing chuck need not necessarily have an engagement surface adapted to the curved surface of the chip capacitor. As a result, no special chuck is needed, but an ordinary one can be used for mounting the chip capacitor, and it is not necessary to dis-criminate between the top and bottom thereof. The second sheet 26 is preferably made of a polyvinyl chloride resin,polyimide resin, fluorine-contained resin or the like.
Figs. 18(a) and 18(b) show a chip capacitor similar to - that shown in Figs. 17(a) and 17(b), except that a second sheet 28 has a curved face adjacent the periphery 20a of , :

the capacitor 20. A second sheet 28 with such a curved face can be obtained, for example, by a forming process.
Figs. l9(a) and l9(b) show a capacitor 20 similar to that shown in Figs. 17(a) and 17(b), except that a spacer 29 having an upper plane 29a and a lower plane 29b is employed instead of using the two sheets 25, 26. This capacitor 20 can be put on a printed circuit board on the plane 29a, while the other plane 29b serves as an engaging plane. Because the capacitor 20 has upper and lower planes, it can be mounted using an ordinary chip mounter, in the same way as an ordi-nary chip capacitor having rectangular cross-section.
Figs. 20(a) and 20(b) show a capacitor 20 having a sheet 31 of a roughly square shape adhered to an end face 20b of the capacitor 20. The sheet 31 is fixed offset from the axis of the capacitor 20, so that the sheet 31 and bent leads 23 can support the main body of the capacitor 20 a little above the surface of a printed circuit board. Thus, the capacitor 20 can be fixed firmly on the circuit board with a gap there-between, by adhering the lower portion of the sheet 31 thereon.
In the sealing process in the manufacturing method for an aluminum foil type of solid electrolytic capacitor, such as steps S6, S28, S39 or S51 in Figs. l, 10, 12 or 14, a capa-citor element such as shown in Fig. 2 is inserted into a case and is sealed with resin. If the filling with resin makes the position of the capacitor element deviate from the centre, defects such as a short circuit are liable to happen.
It is thus necessary to fix the capacitor element in the case temporarily for sealing with resin. In the sealing process, a small amount of thermoplastic resin is placed in the case and is melted by heating. After the capacitor element has been installed in the case, the resin is cooled to fix the capacitor element therein. Thermoplastic resin is then - inserted to fill the case for sealing.

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However, this sealing step has the following problems.
First, it does not take into account the moisture resistance of resin for temporary fixing. Therefore, water is liable to penetrate the contact boundary between the resin layer and either the case or the leads and be absorbed into the capacitor element. Because water acts as an electrolyte, the electrostatic capacitance is thus increased. Further, two kinds of resin are needed for temporary fixing and for sealing.
A capacitor element 40 manufactured according to any one of the foregoing preferred embodiments is installed in a case 41 of metal, such as aluminum, or of resin, as shown in Fig. 21. Thermosetting resin 42 has been put in the case 41 beforehand to fill about ten percent of the inner volume of the case 41. After the capacitor 40 has been installed in the case 41, it is heated for hardening the resin 42, for example, at a temperature of 80-90C for ten minutes, so that the capacitor element 40 is fixed temporarily in the case 41. The case 41 is then filled up to its mouth 44 with thermosetting resin 43 which is of the same kind as the thermosetting resin 42. Next, the case 41 is heated for hardening, for example, at a temperature of 50 to 110C for a time between six and ten hours.
The heating temperature of the resin 43 for sealing the mouth 44 of the case 41 should desirably be as low as possLble in order to make it easy to remove resin adhered to the leads 46, 47 in the subsequent rinse process.
~ s explained above, the same thermosetting resin is used both for fixing the capacitor element in the case and for sealing the opening of the case in which the capacitor element has been fixed. Therefore, water can be intercepted so as not to penetrate into the capacitor element 40 from the exterior, so that any enhancement of the electrostatic capacitance can be prevented, since the capacitor element does not absorb water. Further, since the same resin is used for temporary fixing and for sealing, the manufacturing . ~

steps can be shortened.
Conventionally, such a chip capacitor is manufactured by deforming leads of an aluminum solid electrolytic capacitor, welding the leads to metallic terminal plates and molding the capacitor and the welded parts with resin. However, such a welding step requires complicated work in which the efficiency and productivity are low. Further, the resin molding step requires large-scale apparatus which is expensive.
Figs. 22 and 23 show examples of a chip capacitor according to the present invention which can solve the above-mentioned problems. Capacitor elements 60, 70 are manufactured as a capacitor element 10 as explained above.
The leads 61 and 62 are arranged on the same side of the element 60 in the case of Fig. 22, while the leads 71 and 72 are arranged on different ends of the element 70 in the con-necting step to the aluminum foils in the case of Fig. 23.
In the case of Fig. 22, one lead 61 is cut shorter than the height of the metallic case 63 which contains the ca2a-citor element. Liquid epoxy resin 64 of good moistureresistance is put on the bottom of the metallic case 63.
Next, the capacitor element 60 is inserted into the metallic case 63 and is bonded with the resin to the metallic case 63 with a thermal setting process. Then, the shorter lead 61 and the inside of the metallic case 63 are bonded with a conductive adhesive 65 of high heat resistance of 270C or more. Then, the opening of the metallic case 63 is poured with,the same liquid epoxy resin 66 of good moisture resist-ance as used for the bonding, and the resin 66 is hardened thermally for sealing. The lead 62 passing through the sealing material 66 is formed beforehand like a plate insulated from the case by an insulating member 67.
In the case of Fig. 23, a shorter lead 71 is formed as an "Ln. Solder 74 having a melting point of 270C or more is melted in the bottom of the metallic case 73. The capacitor element 70 is then inserted into the case 73 so ; ,~, ""~

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that the lead 71 is bonded to the case 73 with solder 74.
Next, the opening of the case 73 is sealed with epoxy resin 75 of good moisture resistance which is the same as used in the above-mentioned chip capacitor of Fig. 22. Then, the other lead 72 which penetrates the sealant material 75 is formed like a plate as a metallic terminal plate insulated from the case 73 by an insulating element 76.
Figs. 24 and 25 show modified examples wherein metallic terminal plates 68 and 77 are bonded to the metallic cases 63 and 73 by welding or the like and are fixed on insulating material 67' and 76' at the bottom before inserting the capacitor element 60, 70 into the metallic case 63, 73.
Both plates 62, 68 and 72, 77 can be set in the same plane.
In the examples of this embodiment, one of the leads of a capacitor element is bonded with a metallic case so that the metallic case can be used as an extension of the electrode. Thus, resin molding is not necessary, and cheap and compact chip type capacitors can be provided.
This invention may be embodied in still other ways without departing from the spirit of the essential characters thereof. The preferred embodiments described herein are therefore illustrative and not restrictive, the scope of the invention being indicated by the appended claims and all variations which come within the meaning of the claims are intended to be embraced herein.

Claims (31)

Claims

1. An aluminum solid electrolytic capacitor comprising:
an anode aluminum foil having an oxide film formed on a surface thereof, a cathode aluminum foil and carbonized separators for separating said anode and cathode aluminum foils, the two foils and the separators being wound to form a capacitor element, the distance between the two foils in the capacitor element to be determined by the thickness of the separator being kept at a value between ten to sixty micrometers, solid manganese nitrate electrolyte being formed between the two foils by the thermal decomposition of electrolytic solution impregnated in the capacitor element.

2. A manufacturing method of making an aluminum solid electrolytic capacitor, comprising the steps of:
winding an anode aluminum foil and a cathode aluminum foil together with carbonized separators for separating said anode and cathode aluminum foils to form a capacitor element, impregnating an electrolytic solution of manganese nitrate in the capacitor element, and forming a solid electrolytic layer of manganese dioxide between the electrode foils by thermally decomposing the electrolytic solution at a temperature of between 200° and 260° C for a time interval of between 20 and 40 minutes.

3. A manufacturing method according to claim 2, further comprising a step of molding the capacitor element with resin.

4. The manufacturing method according to claim 2, further comprising a step of sealing the capacitor element in a metallic case.

5. A manufacturing method of making an aluminum solid electrolytic capacitor comprising the steps of:
winding an anode aluminum foil and a cathode aluminum foil together with separators for separating said anode and cathode aluminum foils to form a capacitor element, the anode foil having an oxide film formed on the surface, impregnating an electrolytic solution of manganese nitrate in the capacitor element to which fine powder of manganese dioxide is added, and forming a solid electrolytic layer between the electrode foils by thermally decomposing the electrolytic solution.

6. The manufacturing method according to claim 5, wherein the amount of manganese dioxide to be added is between four and six weight percent of the electrolytic solution.

7. The manufacturing method according to claim 5, further comprising the step of carrying out an electrochemical conversion treatment for forming oxide film on cut edges of the aluminum foils.

8. The manufacturing method according to claim 5, wherein said separators are Manila papers which are carbonized by heat treatment.

9. The manufacturing method according to claim 5, wherein said thermal decomposition takes place at a temperature of between 200° and 260° C for a time of between 20 and 40 minutes.

10. The manufacturing method according to claim 5, further comprising the step of molding the capacitor element with resin.

11. The manufacturing method according to claim 5, further comprising the step of sealing the capacitor element in a metallic case.

12. A manufacturing method of making an aluminum solid electrolytic capacitor comprising the steps of:
winding an anode aluminum foil and a cathode aluminum foil together with separators for separating said anode and cathode aluminum foils to form a capacitor element, while keeping the distance between said aluminum foils at a value between ten to sixty micrometers, impregnating an electrolytic solution of manganese nitrate in the capacitor element, forming a solid electrolytic layer between said aluminum foils by thermally decomposing the electrolytic solution, and doping lithium in the solid electrolytic layer.

13. The manufacturing method according to claim 12, wherein said separators are Manila papers which are carbonized by heat treatment.

14. The manufacturing method according to claim 12, wherein said thermal decomposition takes place at a temperature of between 200° and 260° C for a time of between 20 and 40 minutes.

15. The manufacturing method according to claim 12, further comprising the step of molding the capacitor element with resin.

16. The manufacturing method according to claim 12, further comprising the step of sealing the capacitor element in a metallic case.

17. A manufacturing method of making an aluminum solid electrolytic capacitor, comprising the steps of:
winding an anode aluminum foil, a cathode aluminum foil together with separators for separating said anode and cathode aluminum foils to form a capacitor element, the anode foil having formed oxide film on the surface, impregnating an electrolytic solution of manganese nitrate in the capacitor element, forming a solid electrolytic layer of manganese dioxide between the electrode foils by thermal decomposition of the electrolytic solution, again performing an electrochemical conversion treatment in a weak acidic solution for restoring the deterioration of the oxide film on the aluminum foil before the completion of forming solid electrolyte, again forming a manganese dioxide layer by impregnating a manganese nitrate solution with carbon added in the capacitor element, and baking carbon on the solid electrolytic layer after impregnating carbon powder added in manganese nitrate solution to an amount much larger than that of the step of forming the manganese dioxide layer again.

18. The manufacturing method according to claim 17, further comprising the step of performing of the electrochemical conversion treatment for forming oxide film on the cutting edge of the aluminum foils.

19. The manufacturing method according to claim 17, wherein said separators are Manila papers which are carbonized by heat treatment.

20. The manufacturing method according to claim 17, wherein said thermal decomposition in the step of forming manganese dioxide first wherein said thermal decomposition takes place at a temperature between 200° and 260° C for a time interval of between 20 and 40 minutes.

21. The manufacturing method according to claim 17, wherein said thermal decomposition in the step of forming manganese dioxide again takes place at a temperature of between 200° and 260° C for a time of between 20 and 40 minutes.

22. The manufacturing method according to claim 17, further comprising the step of molding the capacitor element with resin.

23. The manufacturing method according to claim 17, further comprising the step of sealing the capacitor element in a metallic case.

24. A manufacturing method of making an aluminum solid electrolytic capacitor, comprising the steps of:
winding an anode aluminum foil, a cathode aluminum foil together with carbonized separators for separating said anode and cathode aluminum foils to form a capacitor element, forming a solid electrolytic layer between the electrode foils, placing an amount of resin for fixing the capacitor element at the bottom of a case having an opening, inserting the capacitor element in the case, fixing the capacitor element to the case with the resin, and sealing the opening of the case with another amount of the same resin used for fixing.

25. The manufacturing method according to claim 24, wherein the resin for fixing and the resin for sealing have good moisture resistance.

26. The manufacturing method according to claim 25, wherein the resin of good moisture resistance is epoxy resin.

27. A manufacturing method of making a chip-type aluminum solid electrolytic capacitor, comprising the steps of:
winding an anode aluminum foil, a cathode aluminum foil together with carbonized separators for separating said anode and cathode aluminum foils to form a capacitor element, each foil having been bonded with a lead, forming a solid electrolytic layer between the electrode foils, placing the capacitor element in a metallic case having an opening, connecting one of the leads electrically with the inside of the metallic case with use of a binder, and sealing the opening of the metallic case with insulating resin.

28. The manufacturing method according to claim 27, wherein the binder is a solder.

29. The manufacturing method according to claim 27, wherein the binder is an electrically conductive binding agent.

30. A manufacturing method for making an aluminum solid electrolytic capacitor, said capacitor including an anode aluminum foil having an oxide film formed on a surface thereof, a cathode aluminum foil and separators for separating said anode and cathode aluminum foils, comprising the steps of:

winding said anode aluminum foil and said cathode aluminum foil together with separators for separating said anode and cathode aluminum foils to form a capacitor element, the distance between the two foils in the capacitor element to be determined by the thickness of separator being kept at a value between ten to sixty micrometers, carbonizing said separators by heat treatment, impregnating electrolytic solution of manganese nitrate in the capacitor element, and forming a solid electrolytic layer of manganese dioxide between the electrode foils by thermally decomposing the electrolytic solution at a temperature of between 200° and 260° C for a time interval of between 20 and 40 minutes.

31. The manufacturing method according to claim 30, wherein said separators are Manila papers which are carbonized by heat treatment.