KR20080069734A - Unit electrode for the stacked type of polymer-condenser and stacking method its - Google Patents

Abstract

A unit cell for a stacked type aluminum polymer-condenser and a method for stacking the same are provided to improve quality of a product by preventing withstand voltage reduction, leakage current increment and resistance increment. A plurality of unit cells(18) for a stacked type aluminum polymer-condenser are formed by reformation, generation of a conductive polymer layer, generation of a carbon layer, and generation of a silver layer and connected to each other through anode units(19). The anode units are stacked at predetermined numbers by being bent with respect to a boundary line. The other anode units except one anode unit include cut units(21). The unit cell is welded to an anode frame(16) through the one anode unit without the cut unit.

Description

Unit electrode for the stacked type of polymer-condenser and stacking method its}

1 is a block diagram showing a manufacturing process of an aluminum multilayer polymer capacitor.

2 is a cross-sectional view showing a capacitor element of an aluminum multilayer polymer capacitor.

Figure 3 is a perspective view showing a capacitor element lamination method of a conventional aluminum multilayer polymer capacitor.

4 is a perspective view showing an example of a capacitor stacking method of an aluminum multilayer polymer capacitor according to an embodiment of the present invention.

5 is a perspective view showing another example of a capacitor stacking method of an aluminum multilayer polymer capacitor according to an embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

10 aluminum oxide film 11: etching foil

12 conductive polymer layer 13 carbon layer

14 silver layer 15 cathode frame

16: anode frame 17: epoxy molding

18: capacitor element 19: anode portion

20: boundary line 21: incision

22: cathode

The present invention relates to a capacitor element, which is a basic unit of an aluminum multilayer solid capacitor, and a method of stacking the capacitor element. More particularly, when the capacitor element is laminated, the battery is folded and stacked in a state in which the anode portions of the element are connected without being separated. By implementing a new type of lamination method, aluminum lamination type which can improve productivity and quality, such as shortening of working time, reduction of defective rate, reduction of ESR, and improvement of lamination efficiency and lamination accuracy of capacitor element can be expected. A capacitor element and a lamination method of a polymer capacitor.

In general, a stacked type aluminum polymer-condenser is a type in which a plurality of dielectrics and electrodes overlap each other, and are mounted on printed circuit boards of various electronic products such as mobile communication terminals, notebook computers, and personal digital assistants (PDAs). It is a capacitor in the form of a chip that plays an important role in charging or discharging the battery.

In order to manufacture such an aluminum multilayer polymer capacitor, a unit capacitor device is manufactured and then stacked. The main process is briefly described as follows.

As shown in FIG. 1, first, an etched aluminum foil having an enlarged surface area of about 100 μm is prepared (S10, S20), and then used as a substrate to anodic oxidation ( The aluminum oxide film (Al ₂ O ₃ ), which is a dielectric, is produced by anodizing (S30), and polyaniline, polypyrrole, and polythiophene are produced by electrochemical oxidation. By forming a conductive polymer, such as polythiophene) with a solid electrolyte (S40), then forming a carbon layer (S50), and further forming a silver layer (S60) to form a solid solid electrolyte, A capacitor unit cell of the required rated voltage and rated capacitance is manufactured.

Then, by stacking the unit electrodes prepared as described above in parallel by a suitable quantity using a conductive adhesive, to complete the designed capacitor capacitance (S70), after drawing the lead frame for the anode and cathode ( S80), epoxy molding (S90) to complete the capacitor exterior.

On the other hand, after completion of the above molding process, printing the rated content and the like (S100), and then subjected to an aging (S110), and then go through the process of inspection and packaging (S120). The manufacturing process of the multilayer polymer capacitor is completed.

Here, the anode is connected to the anode frame by a method of spot welding, laser welding or ultrasonic welding, and the cathode is connected to the unit electrodes by using a conductive adhesive. The aluminum laminate polymer capacitor is completed by bonding with the cathode frame.

As shown in Fig. 2, the capacitor element of the aluminum multilayer polymer capacitor is shown here.

The aluminum multilayer polymer capacitor is a conductive electrode layer of polyaniline, polypyrrole, polythiophene, etc., by electrochemical oxidation on the microporous aluminum etching foil 11 having the dielectric and insulator aluminum oxide film 10 formed thereon as a capacitor electrode. 12 is formed, the carbon layer 13 and the silver layer 14 are formed thereon, and then the cathode frame 15 is drawn out through the silver adhesive and the anode frame 16 is welded to the anode foil. This is taken out, and the structure of the capacitor | condenser exterior is completed by the epoxy molding 17 continuously.

In the lamination process of the aluminum multilayer polymer capacitor manufacturing process, two to twelve unit capacitor elements are stacked according to the rated capacitance designed on the lead frame.At this time, when stacking the capacitor elements, a large number of unit capacitor elements are stacked. After preliminary cutting, the method of laminating the capacitor elements thus cut on one lead frame is applied.

That is, as shown in FIG. 3, the unit capacitor elements 18, which are completed until the formation of the conductive polymer, the carbon layer, and the silver layer on the lead frame, are stacked one by one using silver adhesive as needed based on the designed capacitance. The method is applied.

The anode portions 19 of the stacked capacitor elements 18 are connected to the anode frame 16 by welding or the like in a fixed state by clamping means.

Here, reference numeral 22 denotes the negative electrode portion.

This condenser element stacking process is one of the most difficult processes among the entire condenser manufacturing process, and the stacking operation of the individual condenser elements must be repeatedly performed one by one, which increases the difficulty of the work and lengthens the working time. As a result, as a bottleneck of the entire production time, there is a problem that the overall productivity is lowered.

In addition, repeated stacking operations in such a difficult process may result in an increase in the stacking failure rate, such as contact failure between the anodes of the capacitors stacked, resulting in a decrease in the breakdown voltage of the capacitor due to a high stacking failure rate. There is a problem that the quality of the product is deteriorated, such as deterioration of characteristics such as increased leakage current (ESR), increased resistance.

In addition, since the clamping means for closely contacting the anode portion of the condenser element has to be provided, there is a disadvantage in terms of the volume of the condenser, such as the overall thickness of the condenser element becomes thick.

Accordingly, the present invention has been made in view of the above, and in the manufacturing process of an aluminum laminated solid capacitor, a new type of lamination method in which the anode parts are connected in one state without being cut individually, is laminated. In this way, it is possible to improve the lamination efficiency and the lamination accuracy of the condenser element, for example, to increase the accuracy of the work and to facilitate the welding of the anode frame, and to improve the quality of the condenser element by lowering the ESR as much as possible. An object of the present invention is to provide a condenser element and a lamination method for an aluminum multilayer polymer capacitor.

The objects of the present invention are not limited to the above-mentioned objects, and other objects which are not mentioned will be clearly understood by those skilled in the art from the following description.

The condenser element stacking method of the present invention for achieving the above object is a set type in which a plurality of unit capacitor elements completed by reformation, conductive polymer layer generation, carbon layer generation, and silver layer generation are connected to each other through an anode part. Preparing a unit capacitor element by stacking the unit capacitor elements in an appropriate number by folding and bending the anode portions connected to the set unit capacitor elements based on their boundary lines to complete the designed capacitor capacitance. Include.

In this case, the preparing of the set unit capacitor element may include a cutout portion in the remaining anode portions except for one of the anode portions assigned to each unit capacitor element constituting a set, and thus have no cut portion. It may include a process to enable welding the anode frame through the part.

Here, when folding the positive electrode portion of the capacitor element in the step of completing the capacitor capacitance, it is preferable to be configured to bend in a form such that the folded portions are staggered one by one.

On the other hand, the condenser element of the present invention for achieving the above object is a plurality of unit capacitor elements completed by reformation (reformation), conductive polymer layer generation, carbon layer generation, silver layer generation is connected to each other through the anode portion, respectively The unit condenser elements of the can be configured to be stacked in an appropriate amount as the anode portion is bent on the basis of the boundary that connects each other.

In addition, a cutout portion is formed in the remaining anode portion except for one of the anode portions of each anode portion of the unit capacitor element, and may be configured to be welded to the anode frame through the anode portion having no cutout portion.

At this time, it may be preferable that the anode portion of the capacitor element is configured in such a way that the folded portions are staggered one by one.

The method of stacking capacitor elements provided by the present invention constitutes a set unit capacitor element of a type that is connected to each other through an anode portion having a plurality of unit capacitor elements, and the set unit capacitor elements configured as above are integrally stacked. However, in this case, by stacking each unit capacitor elements in the form of a stacked number of layers by folding and bending the anodes connected to each other during the stacking operation, it is easy to stack the capacitors having a difficult operation and a high defective rate. By folding the anodes without cutting and separating the elements separately, the current flows directly through the anodes connected to each condenser element, thereby lowering the ESR.

In particular, the ESR management goal of the polymer capacitor is required to be as low as possible. As described above, the ESR can be lowered by folding the anode side without cutting the device individually.

In addition, since the anode part of the condenser element is cut out, that is, the incision part is formed on the anode part, only one anode part is welded when the anode frame is connected to the anode frame, thereby increasing the accuracy of the work and making the welding work easier.

That is, even if a plurality of anode portions of the capacitor element overlap, only one surface of the anode portion needs to be spot or laser welded to the anode frame, so that the welding operation can be easily performed.

In the case of the capacitor element stacking method provided by the present invention, two to twelve sets of unit capacitor elements are molded by press mold, press punching, etc. After the polymer layer, carbon layer, and silver layer are completed, the unit capacitor elements connected to each other through the anode part are laminated using the anode parts connected to each other, without cutting the unit capacitor elements individually. The lamination operation at this time is laminated in a folding manner by bending the anode part.

For example, based on the boundary line of the anode part, the unit capacitor elements are repeatedly folded to be folded so as to overlap with each other, and stacked as needed.

At this time, it is preferable that the folded portions of the anode part be arranged in a staggered manner so that the unit capacitor elements can be sequentially stacked in a zigzag form.

Subsequently, a unit capacitor element having a designed capacitance is completed by welding the anode frame to the anode portion of any one capacitor element in the stacked element as described above.

Specific details of other embodiments are included in the detailed description and the drawings.

Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be embodied in various forms, and the present embodiments are merely provided to make the disclosure of the present invention complete and the general knowledge in the art to which the present invention belongs. It is provided to fully inform the person having the scope of the invention, the invention is defined only by the scope of the claims. Like reference numerals refer to like elements throughout.

4 is a perspective view showing an example of a capacitor stacking method of an aluminum multilayer polymer capacitor according to an embodiment of the present invention, Figure 5 is a capacitor stacking method of an aluminum multilayer polymer capacitor according to an embodiment of the present invention. It is a perspective view which shows another example.

As shown in FIGS. 4 and 5, first, reformation, conductive polymer layer generation, carbon layer generation, and silver layer generation are completed, and a plurality of unit capacitor elements 18 are formed using the anode part 19. A step of preparing a set unit capacitor device of a connected type is performed.

In other words, the original foil, which is formed of a dielectric, is cut to a thickness of about 10 to 40 mm and press punched by a press mold to form a plurality of unit condenser elements continuously. 20 to 30 unit capacitor elements are connected through the anode portion).

The set unit capacitor device 18 cut in this manner has a long strip shape and a plurality of unit capacitor devices 18 are connected to each other and arranged at regular intervals.

At this time, each unit capacitor element 18 is composed of an anode portion 19 and a cathode portion 22.

Subsequently, the set unit condenser element 18 is continuously processed to produce recyclability, conductive polymer layer generation, carbon layer generation, and silver layer generation.

At this time, the above process can be applied to the conventional method.

Next, the set unit capacitor element 18 is stacked by an appropriate amount using the anode portion 19 as necessary to complete the designed capacitor capacitance.

That is, the positive electrode 19 of the unit capacitor element set is folded and folded based on the boundary line 20 so as to stack as much as necessary to realize the designed capacitance of the unit capacitor element itself.

At this time, one of the positive electrode portions 19, for example, the positive electrode portion of the capacitor element located at one end of the positive electrode portion 19, which is assigned to each unit capacitor element 18 constituting a set ( After the indentation 21 is formed in the anode portion 19 of the remaining capacitor elements except for 19), the anode is formed on the anode portion 19 having no cut portion 21 when the anode frame 16 is connected. By welding the frame 16, it is possible to easily perform a welding operation for connecting the anode frame.

In addition, when the anode portion 19 of the condenser element 18 is folded and bent so that the folded portions are staggered in a zigzag form one by one, the condenser elements in the stacked state are both sides without variation in thickness due to the folded portions. This uniform thickness ensures a balanced form.

Next, after the stacking of the unit capacitor device, the cathode frame 16 is welded to the anode unit 19 to complete a capacitor device having a designed capacitance.

That is, by welding the anode frame to the anode portion of the stacked unit capacitor element (substantially, by bonding the cathode frame to the cathode portion), one condenser element having a designed capacitance is completed. The device is placed on a lead frame, and the anode part is connected to the anode frame by welding, and the cathode part is connected to the cathode frame by silver adhesive or the like.

At this time, the welding and connecting method is not particularly limited and may be adopted as long as it is commonly known in the art.

After completing the frame connection work as described above, by performing the epoxy molding of the post-process to complete the housing of the capacitor (housing), all the basic processes for the manufacture of the aluminum multilayer polymer capacitor is completed.

Although embodiments of the present invention have been described above with reference to the accompanying drawings, those skilled in the art to which the present invention pertains may implement the present invention in other specific forms without changing the technical spirit or essential features thereof. I can understand that. Therefore, the embodiments described above are to be understood in all respects as illustrative and not restrictive.

As described above, the present invention implements a new type of lamination method that bends and folds in a state in which the anode parts are connected to one without cutting individual elements in the manufacturing process of the aluminum multilayer solid capacitor, thereby increasing the accuracy of the work. It can improve the lamination efficiency and the lamination accuracy of the condenser element by facilitating the welding of the anode frame, and in particular, prevents the deterioration of characteristics such as lowering the breakdown voltage of the capacitor, increasing the leakage current (ESR), and increasing the resistance. There is an effect that can greatly improve the quality of the product.

Claims (6)

In the capacitor element lamination method of the aluminum multilayer polymer capacitor, Preparing a set unit capacitor device of a type in which a plurality of unit capacitor devices completed from reformation, conductive polymer layer generation, carbon layer generation, and silver layer generation are connected to each other through an anode part; And Stacking the unit capacitor elements by an appropriate amount by folding and bending the connected anode portions of the set unit capacitor elements on the basis of the boundary lines to complete the designed capacitor capacitance of the aluminum multilayer polymer capacitor. Lamination method. The method of claim 1, In the preparing of the set unit capacitor element, an anode portion having no cut portion is formed by forming an incision in the remaining anode portion except for one of the anode portions assigned to each unit capacitor element constituting a set. Capacitor device laminating method of the aluminum laminated polymer capacitor, characterized in that it comprises a process for welding the anode frame through. The method according to claim 1 or 2, Comprising the step of completing the capacitor capacitance, when bending the anode portion of the capacitor element folded method of folding the capacitor parts of the aluminum laminated polymer capacitor, characterized in that folded in a form so as to cross one by one. In the capacitor element of the aluminum multilayer polymer capacitor, A plurality of unit capacitor elements completed from reformation, conductive polymer layer generation, carbon layer generation, and silver layer generation are connected to each other through the anode part, and each of the unit capacitor elements has an anode part connected to each other. A capacitor device of an aluminum multilayer polymer capacitor, characterized in that it is configured to be stacked in an appropriate amount as it is folded based on a boundary line. The method of claim 4, wherein A cutout portion is formed in the remaining anode portion except for one anode portion of each anode portion of the unit capacitor element, and the aluminum multilayer polymer capacitor is configured to be welded to the anode frame through the anode portion having no cut portion. Capacitor element. The method according to claim 4 or 5, A capacitor element of an aluminum multilayer polymer capacitor, characterized in that the anode portion of the capacitor element is formed so that the folded portion is staggered one by one.

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