JP6614558B2 - Metallized film and metallized film capacitor - Google Patents

Description

  The present invention relates to a metallized film in which a vapor deposition electrode is formed on a dielectric film, and a metallized film capacitor using the same.

  In a metallized film, a vapor deposition electrode deposited on the surface of a dielectric film is divided by insulating slits, and the divided small electrodes (divided electrodes) are connected to each other via a fuse portion, for example, in Patent Document As shown in FIG. In the capacitor using the metallized film having the above configuration, even if dielectric breakdown occurs in a certain divided electrode due to an overcurrent or the like, the fuse portion is blown, and the divided electrode is separated from the other divided electrode, thereby insulating the capacitor. Recovers so-called self-protection function.

JP 2004-134561 A

  However, when the self-protection function is exhibited, the current must flow so as to bypass the separated divided electrodes. For this reason, the current path becomes longer than before the fuse operation, resulting in an increase in equivalent series resistance (ESR). When ESR increases, heat generation at the time of ripple current load increases, and the capacitor life is shortened. There is also the possibility of causing dielectric breakdown due to thermal runaway due to increased heat generation.

  Accordingly, the present invention has been made to solve the above-described problem, and an object thereof is to provide a metallized film capable of suppressing an increase in ESR after a fuse operation and a metallized film capacitor using the same. .

  In order to solve the above-mentioned problems, the metallized film of the present invention is a metallized film formed by forming a vapor deposition electrode 4 on a dielectric film 3, and the vapor deposition electrode 4 is divided into a plurality of divided electrodes by insulating slits. 10 and a corner fuse portion 11 provided at the corner portion 10a of the divided electrode 10, and the corner fuse portion 11 is an aggregate of small fuse portions 11a provided at the corner portions 10a of the divided electrodes 10. The small fuse portions 11a operate independently of each other.

  Moreover, the metallized film capacitor of the present invention is characterized in that the metallized film is overlaid.

  The metallized film of the present invention has a corner fuse portion provided at the corner portion of the divided electrode, and one divided electrode is connected to a plurality of divided electrodes through the corner fuse portion. In addition, the corner fuse portion is an assembly of small fuse portions provided at the corner portions of each divided electrode, and since each small fuse portion operates independently, even if some of the small fuse portions operate. The connection with the other divided electrodes can be maintained and the current path can be secured. Since this current path continues through the same corner fuse part before and after the fuse operation, the change in the length of the current path can be kept small, and an increase in ESR due to the fuse operation can be suppressed. it can.

It is sectional drawing which shows a part of metallized film capacitor which concerns on embodiment of this invention. It is a top view of the metallized film which concerns on embodiment of this invention. FIG. 5A is an enlarged view of a main part, and FIG. 5B is a plan view showing a current path before and after the fuse operation, showing the operation state of the corner fuse part. It is a graph which shows the relationship between an electrostatic capacitance change rate and an ESR increase rate. It is a top view of the metallized film which concerns on different embodiment of this invention. It is a top view of the conventional metallized film.

  Next, an embodiment of the metallized film of the present invention will be described in detail based on the drawings. As shown in FIG. 1, the metallized film 2 is configured by depositing aluminum, zinc, or the like on the surface of the dielectric film 3 to form a deposited electrode 4.

  As shown in FIG. 2, the vapor deposition electrode 4 is provided up to one end of the dielectric film 3 in the width direction (hereinafter, film width direction). On the other hand, the other end portion is not provided over the entire length of the dielectric film 3 in the length direction (hereinafter, film length direction). This is to prevent both the metallicon electrodes 5 and 5 provided at both ends in the film width direction from being connected to the vapor deposition electrode 4 when the capacitor element is manufactured by superimposing the metallized film 2. It is. Hereinafter, for the sake of explanation, a portion on one end side in the film width direction and connected to the metallicon electrode 5 is referred to as a connection portion 6, and a non-deposition portion on the other end side in the film width direction is referred to as an insulation margin. 7 is called.

  The vapor deposition electrode 4 of the said structure is divided | segmented by the insulation slit which consists of an elongate non-vapor deposition part except for the connection part 6. FIG. Specifically, it is divided by a plurality of first insulating slits 8 parallel to the film width direction and a plurality of second insulating slits 9 orthogonal to the film width direction. The first insulating slits 8 are provided at substantially equal intervals in the film length direction. The second insulating slits 9 are provided at substantially equal intervals in the film width direction. Therefore, the insulating slit is in a lattice shape, and the vapor deposition electrode 4 is divided into small rectangular electrodes (divided electrodes) 10 arranged in a plurality in the film width direction and the film length direction. In FIG. 2, five divided electrodes 10 are arranged in the film width direction.

  All the divided electrodes 10 are connected to each other by adjacent divided electrodes 10 or connecting portions 6 and fuse portions provided so as to divide the first insulating slit 8 and the second insulating slit 9. Hereinafter, the first insulating slit 8 divided by the fuse portion is referred to as a first dividing slit 8a, and the second insulating slit 9 divided by the fuse portion is referred to as a second dividing slit 9a. While the fuse portion becomes a current path in a steady state, the fuse is blown when dielectric breakdown occurs in the divided electrode 10, and the divided electrode 10 is disconnected from the other divided electrodes 10 and the connection portion 6, so that the entire capacitor is formed. It is for restoring insulation. The fuse portion has three types of fuses, that is, a corner fuse portion 11, a first fuse portion 12, and a second fuse portion 13.

  The corner fuse portion 11 is a fuse for connecting the corner portions 10a of the plurality of divided electrodes 10 and is provided at the corner portion 10a of the divided electrode 10 having a substantially rectangular shape. Specifically, the corner portions 10a of the four divided electrodes 10 adjacent to each other are provided at a portion where they are gathered at one place. These four divided electrodes 10 are connected to each other. In this state, a corner fuse portion 11 is provided at a virtual intersection of the first insulating slit 8 and the second insulating slit 9, and four divided electrodes 10 surrounding the virtual intersection are formed by the corner fuse portion 11. It can be said that they are connected to each other. Further, as shown in FIG. 3a, the corner fuse portion 11 is provided between the tip portion of the first dividing slit 8a and the tip portion of the second dividing slit 9a (that is, the corner portion 10a of each divided electrode 10). It can be said that it is an aggregate of a plurality of (four) small fuse portions 11a formed. A width L1 of each small fuse portion 11a (a distance between the tip portion of the first dividing slit 8a and the tip portion of the second dividing slit 9a) L1 is, for example, 0.25 to 0.40 mm. The corner fuse portion 11 having the above-described configuration is provided in the divided electrode 10 excluding at least the divided electrode 10 closest to the insulation margin 7. Specifically, the third divided electrode 10 is arranged between the first divided electrode 10 and the second divided electrode 10 as viewed from the connection portion 6 of the five divided electrodes 10 arranged in the film width direction. And the fourth divided electrode 10. In addition, it can be said that this state is provided every other second insulating slit 9 arranged in the width direction of the dielectric film 3. However, the corner fuse portions 11 may be provided at the corner portions 10 a of all the divided electrodes 10.

  The first fuse portion 12 is a fuse for connecting the divided electrodes 10 adjacent to each other in the film width direction and the connecting portion 6 or connecting the divided electrodes 10 and 10 adjacent to each other in the film width direction. The insulating slit 9 is provided so as to be divided. Specifically, five divided electrodes 10 arranged in the film width direction are connected between the first divided electrode 10 and the connecting portion 6 as viewed from the connecting portion 6 (connected to the divided electrode 10 closest to the connecting portion 6). Between the second divided electrode 10 and the third divided electrode 10, and between the fourth divided electrode 10 and the fifth divided electrode 10 (most in the insulation margin 7). Between the adjacent divided electrode 10 and the divided electrode 10 adjacent to the divided electrode 10 in the film width direction). Therefore, it can be said that the first fuse portions 12 and the corner fuse portions 11 are alternately provided in the film width direction. The first fuse portion 12 is provided so as to be located at the center of the divided electrode 10 in the film length direction.

  The second fuse portion 13 is a fuse for connecting the divided electrodes 10 and 10 adjacent to each other in the film length direction, and is provided so as to divide the first insulating slit 8. Specifically, it is provided between the divided electrodes 10 and 10 closest to the insulation margin 7. The second fuse portion 13 is provided at a position slightly offset toward the insulating margin 7 side from the center of the divided electrode 10 in the film width direction. However, the present invention is not limited to this, and it may be provided so as to be shifted toward the center or the connecting portion 6 side.

  As shown in FIG. 1, the two metallized films 2 and 2 having the above-described configuration are arranged such that the positions of the insulation margins 7 are staggered vertically and the dielectric film 3 is interposed between the vapor deposition electrodes 4 and 4. In this manner, the metallized film capacitor 1 of the present invention is manufactured by overlapping a plurality of layers and forming the metallicon electrodes 5 and 5 at both ends in the film width direction.

  In a capacitor using the metallized film 2, dielectric breakdown may occur due to overcurrent or the like. When dielectric breakdown occurs, normally, the vapor deposition electrode 4 around the portion B where the insulation is broken evaporates and the insulation is restored. However, if the insulation still does not recover, the fuse portion is melted, and the divided electrode 10 where the dielectric breakdown has occurred and the surrounding divided electrodes 10 are separated. When the corner fuse part 11 is blown, as shown in FIG. 3a, the tip part of the first dividing slit 8a and the tip part of the second dividing slit 9a are connected, that is, pass through the shortest distance. The deposited metal between the two melts (evaporates) (see the melted part F in FIG. 3a). At this time, the deposited metal between the tip of the other first dividing slit 8a and the tip of the second dividing slit 9a does not evaporate. Moreover, the vapor deposition metal between the front-end | tip parts of the 1st parting slits 8a and 8a whose distance is longer than L1, and between the front-end | tip parts of the 2nd parting slits 9a and 9a does not evaporate. That is, the four small fuse portions 11a constituting the corner fuse portion 11 do not operate all at once, but operate independently (individually). Therefore, among the four divided electrodes 10 connected to each other by the corner fuse portion 11, only the divided electrode 10 in which dielectric breakdown has occurred is cut off, and the other divided electrodes 10 and 10 remain connected. If an excessive voltage is applied to the capacitor, a plurality of small fuse portions 11a may be operated simultaneously, but the potential gradient (voltage [VDC] / dielectric film thickness [μm]) is 340 VDC. If it is less than / μm, it is confirmed that each small fuse part 11a operates individually.

  When the divided electrode 10 is cut off, the current (solid line arrow in FIG. 3b) passing therethrough flows around the divided electrode 10 (see the dotted arrow). However, since the current can pass through the same corner fuse portion 11 without changing after the fuse operation, there is no change in the length of the current path. Therefore, there is no change in ESR before and after the fuse operation, or the increase rate of ESR can be kept low.

  FIG. 4 is a graph showing the rate of increase in ESR with respect to the rate of change (decrease) in capacitance. A solid line shows the result of the metallized film 2 of the present invention, and a dotted line shows the result of the conventional metallized film shown in FIG. As shown in the graph, the metallized film 2 of the present invention has a slower ESR increase rate (ΔESR) relative to the capacitance decrease rate (ΔC) than the conventional metallized film. From this, it can be seen that in the metallized film 2 of the present invention, ESR is unlikely to increase even if each fuse portion operates.

  Then, the metallized film of other embodiment is demonstrated. As shown in FIG. 5, the metallized film 2 </ b> A includes a divided electrode 10 adjacent to the connection portion 6 in the film width direction, a divided electrode 10 closest to the insulation margin 7 between the connection portion 6, and the divided electrode. The divided electrodes 10 and 10 are connected to each other by a corner fuse portion 11 except for between the electrode 10 and the divided electrodes 10 adjacent in the film width direction.

  Even with the metallized film 2A having such a configuration, as shown by the solid and dotted arrows in FIG. 5, there is no significant change in the length of the current path before and after the fuse operation, and the ESR before and after the fuse operation. The increase can be suppressed.

  Although specific embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the present invention. For example, the shape of the divided electrode 10 is not limited to a substantially rectangular shape, and may be a triangle or a pentagon or more polygon. In this case, of course, the number of small fuse portions 11a constituting the corner fuse portion 11 changes. Further, the insulating slit is not limited to a straight one but may be a curved one. The number of divided electrodes 10 in the film width direction is not limited to five and can be changed as appropriate. However, when the first fuse portions 12 and the corner fuse portions 11 are alternately provided in the film width direction, the number is set to an odd number. Further, as the connection portion 6, a so-called heavy edge using a vapor deposition electrode thicker than the divided electrode 10 may be employed. As a method of superimposing a plurality of metallized films 2 and 2A, they may be simply superposed or superposed by winding. Alternatively, a capacitor may be formed by superimposing a double-sided metallized film in which vapor-deposited electrodes are formed on both sides of a single dielectric film and a dielectric film. Furthermore, it is not always necessary to use metallized films having the same vapor deposition pattern, and metallized films having different vapor deposition patterns may be combined.

In addition, the thing of the following structures is also contained in the metallized film of this invention.
(1) The connection part 6 is provided in the one end part of the width direction of the dielectric material film 3, the insulation margin 7 is formed in the other end part, and the vapor deposition electrode 4 and the division | segmentation electrode 10 divided | segmented by the insulation slit A corner fuse 11 provided in a corner portion 10a of the divided electrode 10 excluding the divided electrode 10 closest to the insulation margin 7. A metallized film comprising a portion.
(2) The fuse portion connecting the divided electrode 10 closest to the insulation margin 7 and the divided electrode 10 adjacent to the divided electrode 10 in the width direction of the dielectric film 3 is orthogonal to the width direction of the dielectric film 3. A metallized film located in the center of the split electrode 10 in the direction.
(3) The metallized film in which the fuse portion connecting the divided electrode 10 closest to the connecting portion 6 and the connecting portion 6 is located at the center of the divided electrode 10 in the direction orthogonal to the width direction of the dielectric film 3 .
(4) A metallized film in which the divided electrodes 10 and 10 closest to the insulation margin 7 are connected by a fuse portion.
(5) A metallized film in which fuse portions that connect the corner portions 10 a of the divided electrodes 10 are provided every other second insulating slit 9 that is arranged in the width direction of the dielectric film 3.

DESCRIPTION OF SYMBOLS 1 Metallized film capacitor | condenser 2, 2A Metallized film 3 Dielectric film 4 Vapor deposition electrode 5 Metallicon electrode 6 Connection part 7 Insulation margin 8 1st insulation slit 8a 1st dividing slit 9 2nd insulating slit 9a 2nd dividing slit 10 Divided electrode 10a corner portion 11 corner fuse portion 11a small fuse portion 12 first fuse portion 13 second fuse portion L1 distance between the leading end of the first dividing slit and the leading end of the second dividing slit B portion where the insulation is broken F fusing Part

Claims (3)

A metallized film formed by forming a vapor deposition electrode (4) on a dielectric film (3),
A connecting portion (6) is provided at one end in the width direction of the dielectric film (3), and an insulating margin (7) is formed at the other end,
The vapor deposition electrode (4)
A dielectric film (3) the first insulating slits of the plurality of parallel to the width direction (8), several divided by a plurality of second insulating slits (9) perpendicular to the width direction of the dielectric film (3) Split electrodes (10) of
A fuse part for connecting the divided electrodes (10, 10) adjacent to each other;
The fuse part
A corner fuse portion (11) provided at a corner portion (10a) of the divided electrode (10) excluding at least the divided electrode (10) closest to the insulation margin (7) ;
A first fuse portion (12) provided so as to divide the second insulating slit (9) and to be positioned at the center of the divided electrode (10) in the longitudinal direction of the dielectric film (3);
A second fuse portion (13) connecting the divided electrodes (10, 10) closest to the insulation margin (7) ;
The divided electrode (10) closest to the insulation margin (7) and the divided electrode (10) and the divided electrode (10) adjacent in the width direction of the dielectric film (3) are connected by the first fuse portion (12). And
Corner fuse portions (11) and first fuse portions (12) are alternately provided in the width direction of the dielectric film (3),
Each of the plurality of divided electrodes (10) arranged in the width direction of the dielectric film (3) is connected to three fuse portions per divided electrode (10),
The corner fuse part (11) is an assembly of small fuse parts (11a) provided at the corner part (10a) of each divided electrode (10), and each small fuse part (11a) operates independently. A metallized film characterized by that. The metallized film according to claim 1 , wherein the divided electrode (10) closest to the connection part (6) and the connection part (6) are connected by a first fuse part (12) . Claim 1 or 2 superposed metallized film according comprising, metalized film capacitor.

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