KR101987781B1 - Metallized film capacitor - Google Patents

Abstract

The present invention relates to a metallized film capacitor comprising a first dielectric film and a plurality of first inclined groove portions spaced apart from each other in a first direction on a top surface of the first dielectric film and having a first fuse disposed therein, A plurality of first reverse oblique groove portions disposed between the first inclined groove portions and communicating with the first inclined groove portion and having a first fuse disposed on the inner side thereof and a plurality of second reverse oblique groove portions spaced apart from each other by a predetermined distance in the first direction, A first electrode forming film having a first electrode pattern portion having a groove portion and a plurality of first linear groove portions connected to communicate with the first reverse oblique groove portion; And a second dielectric film disposed to be in contact with an upper surface of the first electrode pattern portion and a plurality of second tilted groove portions spaced apart from each other in the first direction by a predetermined distance on the upper surface of the second dielectric film, A plurality of second reverse oblique groove portions which are arranged between the plurality of second oblique groove portions and communicate with the second oblique groove portion and in which a second fuse is disposed, spaced apart from each other by a predetermined distance in the first direction, And a second electrode forming film having a second electrode pattern portion in which a plurality of second linear groove portions connected to communicate with the second oblique groove portion and the second reverse oblique groove portion are formed.

Description

[0001] METALIZED FILM CAPACITOR [0002]

The present invention relates to a metallized film capacitor, and more particularly to a metallized film capacitor, in which a tip of a segmented electrode protrudes in a direction in which a current flows when a current is applied to the metalized film capacitor, the segment electrodes generated in the defect by evaporation or vaporization due to the heat generated as the current momentarily flows in the fuse connecting the segment electrodes by causing the current to flow instantaneously at the defects during the self-healing operation, 0001] The present invention relates to a metallized film capacitor that protects an electrode-forming film from a serious malfunction.

The metallized film capacitor is formed by overlapping two or more electrode forming films. The electrode-forming film is formed with a segmented electrode and a fuse so as to self-heal on the surface of the dielectric film. The self-healing is to protect the metallized film capacitor by causing the fuse to evaporate when the insulation breakdown occurs in the metallizing film capacitor, and this related art is disclosed in Korean Patent Registration No. 10-836567 (Patent Document 1) have.

Patent Document 1 relates to a metallized plastic film for a film capacitor, and comprises a split electrode portion and a fuse portion. The split electrode portion is formed in a rectangular shape elongated from 1/4 to 4/5 of the film width toward the other side in the film width direction from the margin portion on one side where the electrode metal is not deposited and the fuse portion extends from the split electrode at the end of the margin portion to the electrode And is formed to be patterned so as to be continuously formed at regular intervals along the longitudinal direction of the film so as to be formed at any one of the portions in contact with the metal.

The metallized plastic film for a film capacitor described in Patent Document 1, that is, a conventional metallized film capacitor is formed such that the number of divided electrode portions, that is, segment electrodes, is large in the width direction of the electrode forming film, There is a problem that the resistance is increased and heat generation is increased.

Korean Patent Registration No. 10-836567

SUMMARY OF THE INVENTION It is an object of the present invention to provide a metal film capacitor in which the end of a segmented electrode protrudes in a direction in which a current flows when a current is applied to the metal film capacitor to cause a self- The segment electrode generated in the defect is opened in a circuit by a fuse operation by evaporating or vaporizing by the heat generated as the current momentarily flows in the fuse connecting the segment electrodes by allowing the instantaneous current to flow instantaneously to the defect And to provide a metallized film capacitor that protects against serious failure of the electrode forming film.

It is another object of the present invention to provide a fuse blower in which the fuse is arranged to be staggered with respect to the segment electrode when the electrode forming film is stacked, And a metallized film capacitor.

Another object of the present invention is to reduce the number of divided electrodes arranged in the width direction of the electrode-forming film to reduce the number of fuses connecting the divided electrodes, thereby increasing heat generation due to an increase in equivalent series resistance (ESR) And a metal film capacitor.

The metallized film capacitor of the present invention comprises a first dielectric film and a plurality of first inclined groove portions spaced apart from each other at a predetermined interval in a first direction on the upper surface of the first dielectric film and having a first fuse disposed therein, A plurality of first reverse oblique groove portions which are disposed between the first oblique groove portions and communicate with the first oblique groove portion and in which a first fuse is disposed, and a plurality of first reverse oblique groove portions spaced apart from each other by a predetermined distance in the first direction, A first electrode forming film having a first electrode pattern portion having a groove portion and a plurality of first linear groove portions connected to communicate with the first reverse oblique groove portion; And a second dielectric film disposed on an upper surface of the second dielectric film so as to be in contact with an upper surface of the first electrode pattern portion, and a plurality of second tilting portions spaced apart from each other in a first direction and having a second fuse disposed therein, A plurality of second reverse oblique groove portions arranged between the plurality of second oblique groove portions and communicating with the second oblique groove portion and having a second fuse disposed on the inner side thereof and a plurality of second reverse oblique groove portions spaced apart from each other by a predetermined distance in the first direction, And a second electrode pattern formed on the first electrode forming film and having a second electrode pattern portion in which a plurality of second straight groove portions are formed to be connected to the second inclined groove portion and the second reverse oblique groove portion, The second electrode forming film is superposed on each other and overlapped with each other by the first oblique groove portion, the first reverse oblique groove portion, the first rectilinear groove portion, the second oblique groove portion, the second reverse oblique groove portion and the second rectilinear groove portion in the second direction One side of A plurality of 'M' shaped unit film capacitors are formed along a first direction and a plurality of inverted 'M' shaped unit film capacitors are formed along a first direction on the other side of the second direction, And a plurality of hexagonal unit film capacitors are formed along the first direction between the film capacitors and the inverted 'M' shaped unit film capacitors.

The metallized film capacitor of the present invention is formed by protruding the end of a segmented electrode in a direction in which a current flows when a current is applied to the metallized film capacitor, and a self-healing (Or vaporization) by heat generated as a current flows instantaneously in a fuse connecting the segment electrodes by causing the current to flow instantaneously in the defects during the operation of the fuse. There is an advantage in that a serious failure of the electrode forming film is protected by opening the electrode forming film. When the electrode forming film is overlapped, the fuse is formed so as to be staggered with respect to the segment electrode, The openings of the segment electrodes are opened in a circuit so that the reliability of the fuse operation The number of divided electrodes arranged in the width direction of the electrode-forming film is reduced to reduce the number of fuses connecting the divided electrodes, thereby increasing the heat generation due to an increase in equivalent series resistance (ESR) due to fuses There is an advantage that it can be prevented.

1 is a top view of a metallized film capacitor of the present invention,
2 is a sectional view taken along the line A1-A1 of the metallized film capacitor shown in Fig. 1,
FIG. 3 is a plan view of the first electrode forming film shown in FIG. 1,
4 is a sectional view taken along the line A2-A2 of the first electrode forming film shown in Fig. 3,
5 is a plan view of the second electrode forming film shown in FIG. 1,
6 is a cross-sectional view taken along the line A3-A3 of the first electrode forming film shown in Fig.

Hereinafter, embodiments of the metallized film capacitor of the present invention will be described with reference to the accompanying drawings.

As shown in FIGS. 1 and 2, the metallization film capacitor of the present invention includes a first electrode forming film 100 and a second electrode forming film 200.

The first electrode forming film 100 is spaced apart from the upper surface of the first dielectric film 110 and the first dielectric film 110 by a predetermined distance in a first direction X and a first fuse 144 is disposed inside The plurality of first inclined groove portions 141 and the plurality of first inclined groove portions 141 are connected to the first inclined groove portion 141 and the first fuse 144 is disposed on the inner side, The first inclined groove portion 141 and the first inverted inclined groove portion 142 are spaced apart from each other by a predetermined distance in the first direction X and are formed along the second direction Y, And a first electrode pattern portion 120 on which first straight groove portions 143 are formed.

The second electrode forming film 200 may include a second dielectric film 210 arranged to be in contact with the upper surface of the first electrode pattern part 120 and a second dielectric film 210 disposed on the upper surface of the second dielectric film 210 in the first direction X, A plurality of second inclined groove portions 241 spaced apart from each other by a predetermined distance and having a second fuse 244 disposed therein and a plurality of second inclined groove portions 241 to communicate with the second inclined groove portion 241 A plurality of second reverse slanting grooves 242 in which a second fuse 244 is disposed and a second slanting groove portion 241 which is formed along the second direction Y and spaced apart from each other by a predetermined distance in a first direction X, And a second electrode pattern part 220 formed with a plurality of second rectilinear groove parts 243 connected to the second reverse oblique groove part 242.

The first electrode forming film 100 and the second electrode forming film 200 are stacked to form a first inclined groove portion 141, a first reverse inclined groove portion 142, a first straight groove portion 143, M 'unit type film capacitors C1 (C1, C2) are formed along the first direction (X) on one side of the second direction Y by the second reverse slanting groove portion 242, the second reverse slanting groove portion 242, And a plurality of inverted M'-shaped unit film capacitors C2 are formed on the other side of the second direction Y along the first direction X. The M'-shaped unit film capacitors C1, A plurality of hexagonal unit film capacitors C3 are formed along the first direction X between the inverted 'M' shaped unit film capacitors C2. Here, a detailed configuration of a plurality of 'M' shaped unit film capacitors C1, a plurality of inverted 'M' shaped unit film capacitors C2 and a plurality of hexagonal unit film capacitors C3 will be described later.

The structure of the metallized film capacitor of the present invention having the above-described structure will be described in detail as follows.

3 and 4, the first electrode-forming film 100 is spaced apart from the upper surface of the first dielectric film 110 and the first dielectric film 110 at regular intervals in the first direction X, A plurality of first inclined groove portions 141 in which the first fuse 144 is disposed and a plurality of first inclined groove portions 141 are disposed to communicate with the first inclined groove portions 141 and a first fuse 144 is provided inside, The first inclined groove portion 142 and the second inclined groove portion 142 are spaced apart from each other by a predetermined distance in the first direction X and are formed along the second direction Y, And a first electrode pattern part 120 formed with a plurality of first straight groove parts 143 connected to be connected to the first electrode pattern part 142. That is, the first electrode forming film 100 includes the first dielectric film 110, the first electrode pattern 120, and the first head electrode 130.

The first dielectric film 110 is longer than the second direction Y in the first direction X and is made of polypropylene, polyethylene terephthalate polyester (PETP), polyphenyl One of polyphenylene sulfide (PPS), polyethylene naphthalate (PEN), polyether imide (PEI) or polycarbonate (PC) is selected and used. That is, the first dielectric film 110 has the first direction X in the longitudinal direction and the second direction Y in the width direction.

The first electrode pattern part 120 is formed by applying one of copper, nickel, zinc, and aluminum on the upper surface of the first dielectric film 110 to form a plurality of first inclined groove parts 141, a plurality of first inverted inclined groove parts 142, a plurality of first straight groove portions 143, and a first fuse 144 are formed. The plurality of first inclined groove portions 141 are spaced apart from each other by a predetermined distance in the first direction X so that the upper surface of the first dielectric film 110 is exposed. The plurality of first reverse slanting grooves 142 are positioned between the first slanting grooves 141 and the first slanting slits 141 so as to communicate with the first slanting grooves 141, Are spaced apart in the first direction (X) so as to expose the surfaces. The plurality of first rectilinear trenches 143 are spaced apart from each other at regular intervals in the first direction X so as to expose the upper surface of the first dielectric film 110 and are formed along the second direction Y, And is connected to be communicated with the first reverse slant groove part (141) and the first reverse slant groove part (142). That is, the plurality of first straight groove portions 143 are connected to the first inclined groove portion 141 and the first reverse inclined groove portion 142 so as to communicate with each of the two 'V' groove portions 140. Here, one 'V' -shaped groove part 140 is formed by connecting one first inclined groove part 141 and one first reverse oblique groove part 142, and one V '-shaped groove part 140 3, the vertex is formed so as to be directed toward the first head electrode 130, that is, protruded in a direction in which a current flows when current is applied to the first head electrode 130, thereby generating a weak point So that the first fuse 144 can be evaporated or vaporized by the heat generated as the current instantaneously flows into the first fuse 144 by allowing the current to flow instantaneously to the defect at the time of self- do. The first fuse 144 is disposed in each of the first inclined groove portion 141 and the first reverse inclined groove portion 142, respectively.

The first electrode pattern portion 120 may include a first common segment by a plurality of first inclined groove portions 141, a plurality of first inverted inclined groove portions 142 and a plurality of first straight groove portions 143, Electrode 121 and a plurality of first split electrodes 122. [

The first common segment electrode 121 is formed on the upper surface of the first dielectric film 110 by a plurality of first inclined groove portions 141 and a plurality of first inverted inclined groove portions 142, The plurality of first rectilinear grooves 143 and the plurality of second rectilinear grooves 243 are divided into a plurality of first inclined grooves 141 and a plurality of first inverted inclined grooves 142 arranged in a first direction X Shaped first unit electrodes 120a are formed.

The plurality of first split electrodes 122 may include a plurality of first inclined groove portions 141, a plurality of first inverted inclined groove portions 142 and a plurality of first straight groove portions 143 on the upper surface of the first dielectric film 110 And are arranged along the first direction X on one side of the first common segment electrode 121 in the second direction Y to be connected to the first common segment 121 and the first fuse 144 . Each of the plurality of first split electrodes 122 is divided into a first inverted M'-shaped unit electrode 120b and a first hexagonal unit electrode 120c. The plurality of first inverted 'M' shaped unit electrodes 120b each include a plurality of first rectilinear trenches 143, a plurality of second inclined trenches 241, a plurality of second inverted trenches 242, 2 rectilinear trenches 243 and arranged in the first direction X. As shown in Fig. The first hexagonal unit electrode 120c includes a plurality of first inclined groove portions 141, a plurality of first inverted inclined groove portions 142, a plurality of first rectilinear groove portions 143, a plurality of second inclined groove portions M 'shaped unit electrodes 120a and 120b are divided by a plurality of second reverse slanting grooves 242 and a plurality of second rectilinear groove portions 243, arranged in a first direction X, And is positioned between the plurality of first inverted 'M' shaped unit electrodes 120b. Here, a plurality of first 'M' -shaped unit electrodes 120a are used as electrodes of an 'M' -shaped unit film capacitor C1 as shown in FIG. 2, and a plurality of first M'shaped unit electrodes 120b Is used as an electrode of the inverted 'M' shaped unit film capacitor C2 as shown in FIG. 2, and a plurality of first hexagon unit electrodes 120c is used as an electrode of the hexagonal unit film capacitor C3.

A plurality of first inclined groove portions (first inclined groove portions) 120a forming a plurality of first 'M' shaped unit electrodes 120a, a plurality of first inverted 'M' shaped unit electrodes 120b and a plurality of first hexagon unit electrodes 120c The plurality of first reverse slanting grooves 142 and the plurality of first linearly extending grooves 143 are located between the first common segment electrodes 121 and the plurality of first split electrodes 122, The upper surface of the film 110 is exposed.

The plurality of first inclined groove portions 141 are formed to be inclined by 30 to 60 degrees in the clockwise direction with respect to the first direction X as shown in FIGS. 1 and 3, respectively, (142) are each formed to be inclined by 130 to 160 degrees in the clockwise direction with respect to the first direction (X). Each of the plurality of first rectilinear trenches 143 is formed to have a right angle with respect to the second direction Y, and the respective widths, that is, the widths of the grooves are equal to each other. The first fuse 144 is disposed inside each of the plurality of first inclined groove portions 141 and the plurality of first inverted inclined groove portions 142 to form a plurality of first divided segments 121 in the first common segment electrodes 121, The electrodes 122 are formed on the upper surface of the first dielectric film 110 so as to be electrically connected to each other. Each of the electrodes has a plurality of first inclined groove portions 141, a plurality of first inverted inclined groove portions 142, Is equal to or larger than one of the first straight groove portions (143).

The first head electrode 130 is formed on the other side of the upper surface of the first electrode pattern part 120, that is, on the other side of the upper surface of the first common segment electrode 121 of the first electrode pattern part 120 , And is used to connect the metallized film capacitor of the present invention to external electrical signals. The first head electrode 130 is formed with a first alignment groove 145 so as to communicate with the first inclined groove 141, the first reverse gradient groove 142, and the first straight groove 143. The first alignment groove part 145 is aligned with the second linear groove part 243 formed on the second electrode pattern part 220 so that the first electrode forming film 100 is laminated on the upper surface of the second electrode forming film 200 Is used.

5 and 6, the second electrode forming film 200 includes a second dielectric film 210 arranged to be in contact with the upper surface of the first electrode pattern part 120 and a second dielectric film 210 disposed on the upper surface of the second dielectric film 210, A plurality of second inclined groove portions 241 spaced apart from each other by a predetermined distance in the first direction X and having a second fuse 244 disposed on the inner side thereof and a plurality of second inclined groove portions 241 disposed on the second A plurality of second reverse oblique groove portions 242 communicating with the inclined groove portion 241 and having a second fuse 244 disposed therein are spaced apart from each other by a predetermined distance in the first direction X and extend along the second direction Y And a second electrode pattern part 220 formed with a plurality of second straight groove parts 243 connected to the second inclined groove part 241 and the second reverse inclined groove part 242. That is, the second electrode forming film 200 includes the second dielectric film 210, the second electrode pattern 220, and the second head electrode 230.

The second dielectric film 210 is longer than the second direction Y in the first direction X. The material of the second dielectric film 210 may be polypropylene, polyethylene terephthalate polyester (PETP), polyphenyl One of polyphenylene sulfide (PPS), polyethylene naphthalate (PEN), polyether imide (PEI) or polycarbonate (PC) is selected and used. That is, the second dielectric film 210 has the first direction X in the longitudinal direction and the second direction Y in the width direction.

The second electrode pattern part 220 is formed by applying one of copper, nickel, zinc, and aluminum on the upper surface of the second dielectric film 210 to form a plurality of second inclined groove parts 241, 242, a plurality of second straight groove portions 243, and a second fuse 244 are formed. The plurality of second inclined groove portions 241 are spaced apart from each other by a predetermined distance in the first direction X so that the upper surface of the second dielectric film 210 is exposed. The plurality of second reverse slanting grooves 242 are located between the second slanting grooves 241 and the second slanting grooves 241 and are connected to the upper surface of the second dielectric film 210 Are spaced apart in the first direction (X) so as to expose the surfaces. The plurality of second rectilinear trenches 243 are spaced apart from each other by a predetermined distance in the first direction X so as to expose the upper surface of the second dielectric film 210 and are formed along the second direction Y, And is connected to be communicated with the first reverse slope groove portion 241 and the second reverse slope groove portion 242. That is, each of the plurality of second rectilinear groove portions 243 is connected to the second inclined groove portion 241 and the second reverse oblique groove portion 242 for each of the two reverse 'V' groove portions 240. Here, one inverted V-shaped groove portion 240 is formed by connecting one second inclined groove portion 241 and one second inverted inclined groove portion 242, and one inverted V-shaped groove portion 240 Is formed so as to face the second head electrode 230 as shown in FIG. 3, that is, to protrude in a direction in which a current flows when a current is applied to the second head electrode 230, So that the second fuse 244 can be evaporated or vaporized by the heat generated as the current flows instantaneously into the second fuse 244. The second fuse 244 is disposed in each of the second inclined groove portion 241 and the second reverse inclined groove portion 242, respectively.

The second electrode pattern portion 220 may include a second common segment by a plurality of second inclined groove portions 241, a plurality of second reverse inclined groove portions 242 and a plurality of second straight groove portions 243, The electrode 221 and the plurality of second split electrodes 222 are formed separately.

The second common segment electrode 221 is separated from the upper surface of the second dielectric film 210 by a plurality of second inclined groove portions 241 and a plurality of second inverted inclined groove portions 242, The first rectilinear groove portion 241 and the second rectilinear groove portion 243 are divided by the second inclined groove portion 241, the second reverse inclined groove portion 242, the second rectilinear groove portion 243 and the first rectilinear groove portion 143, M '-shaped unit electrodes 220b arranged in the second direction' X '. The plurality of second inverted 'M' shaped unit electrodes 220b are disposed at positions corresponding to the plurality of first inverted 'M' shaped unit electrodes 120a shown in FIGS. 1 and 2, respectively, And are arranged in the same number as the number of the inverted 'M' shaped unit electrodes 120a.

The plurality of second split electrodes 222 are formed on the upper surface of the second dielectric film 220 by a plurality of second inclined groove portions 241, a plurality of second inverted inclined groove portions 242 and a plurality of second straight groove portions 243 So that they are connected to the second common segment 221 and the second fuse 244 by being arranged along the first direction X on one side of the second common electrode segment 221 in the second direction Y . The plurality of second split electrodes 222 are divided into a plurality of second 'M' shaped unit electrodes 220a and a plurality of second hexagonal unit electrodes 220c. Each of the plurality of second M'-shaped unit electrodes 220a includes a plurality of second rectilinear groove portions 243, a plurality of first inclined groove portions 141, a plurality of first inverse oblique groove portions 142, And are arranged in the first direction X by being divided by the straight groove portions 143, respectively. The plurality of second hexagonal unit electrodes 220c includes a plurality of first inclined groove portions 141, a plurality of first inverted inclined groove portions 142, a plurality of first rectilinear groove portions 143, a plurality of second inclined groove portions 241 M 'shaped unit electrodes 220a, which are divided by a plurality of second reverse slanting grooves 242 and a plurality of second straight groove portions 243 and are arranged in a first direction X, And is positioned between the plurality of second inverted 'M' shaped unit electrodes 220b. here,

As shown in FIG. 2, the plurality of second inverted 'M' shaped unit electrodes 220b are disposed at positions corresponding to the plurality of first inverted 'M' shaped unit electrodes 120b, The second M'-shaped unit electrode 220a is used as an electrode of the first unit electrode C1, and each of the second M'-shaped unit electrodes 220a is disposed at a position corresponding to the plurality of first M'- Shaped unit film capacitor C2 and the plurality of second hexagonal unit electrodes 220c are arranged at positions corresponding to the plurality of second hexagonal unit electrodes 220c as shown in FIG. And is used as an electrode of the unit film capacitor C3.

A plurality of second inclined groove portions 241 and a plurality of second inverted inclined groove portions 242 are formed to divide the second electrode pattern portion 220 into a second common segment electrode 221 and a plurality of second split electrodes 222, 242 and the plurality of second rectilinear trenches 243 are positioned between the second common segment electrode 221 and the plurality of second split electrodes 222 so that the upper surface of the second dielectric film 210 is exposed do. The plurality of second inclined groove portions 241 are formed to be inclined by 30 to 60 degrees in the counterclockwise direction with respect to the first direction X, And the second linear straight grooves 243 are formed to be perpendicular to the second direction Y with respect to the first direction X. The second linear straight grooves 243 are formed to be inclined by 130 to 160 degrees counterclockwise with respect to the first direction X, , And the respective widths, that is, the width lengths are formed to be equal to each other.

The second fuse 244 is disposed on the inner side of the plurality of second inclined groove portions 241 and the plurality of second reverse oblique groove portions 242 so that the second common segment electrode 221 is divided into a plurality of second divided portions The electrodes 222 are formed on the upper surface of the second dielectric film 210 so as to be electrically connected to each other. Each of the electrodes has a plurality of second inclined groove portions 241, a plurality of second inverted inclined groove portions 242, Is equal to or larger than one of the second straight groove portions (243).

The second head electrode 230 is formed on the other side of the upper surface of the second electrode pattern unit 220, that is, on the other side of the upper surface of the second common segment electrode 221 of the second electrode pattern unit 220 , And is used to connect the metallized film capacitor of the present invention to external electrical signals. The second alignment groove portion 245 is formed in the second head electrode 230 so as to communicate with the second inclined groove portion 241, the second reverse inclined groove portion 242, and the second straight groove portion 243, respectively. The second alignment groove portion 245 is aligned with the first straight groove portion 143 formed on the first electrode pattern portion 120 so that the first electrode forming film 100 is laminated on the upper surface of the second electrode forming film 200 Is used.

The metalized film capacitor of the present invention is formed in the first electrode pattern part 120 and the second electrode pattern part 220 respectively provided in the first electrode forming film 100 and the second electrode forming film 200 The first fuse 144 and the second fuse 244 are formed in the first inclined groove portion 141, the first reverse inclined groove portion 142, the second inclined groove portion 241 and the second reverse inclined groove portion 242, respectively The first fuse 144 is formed in the first inclined groove portion 141 and the first inverted inclined groove portion 142 and the second fuse 244 is formed in the second inclined groove portion 241 and the second reverse inclined groove portion 142, The first fuse 144 and the second fuse 244 are formed in the first direction 242 so as to be spaced apart from each other in the second direction Y. [ The materials of the first electrode pattern part 120, the second electrode pattern part 220, the first fuse 144 and the second fuse 244 are the same as each other and one of copper, nickel, Is selected and used.

2, the inverted 'M' shaped unit film capacitor C1 includes a first inverted 'M' shaped unit electrode 120b and a second inverted 'M' shaped unit electrode 120b, The unit film capacitors C2 are formed by a first M'-shaped unit electrode 120a and a second'M'-shaped unit electrode 220a, and the hexagonal unit film capacitors C2a, (C3) is formed by the first hexagonal unit electrode 120c and the second hexagonal unit electrode 220c. The first hexagonal unit electrode 120c and the second hexagonal unit electrode 220c are formed such that the corner portions of the first hexagonal unit electrode 120c and the second hexagonal unit electrode 220c have the first 'M' shaped unit electrode 120a and the second ' The first M'-shaped unit electrode 120a and the second M'-shaped unit electrode 220b are spaced apart from the M'-shaped unit electrode 220a, the first inverted M'-shaped unit electrode 120b and the second inverted M'- Shaped unit electrode 220a, the first inverted M'-shaped unit electrode 120b and the second inverted M'-shaped unit electrode 220b. That is, as shown in FIG. 1, the plurality of hexagonal unit film capacitors C3 are spaced apart from each other with the corner portions inserted into the 'M' shaped unit film capacitors C1 and the inverted 'M' shaped unit film capacitors C2 do. The first direction X is perpendicular to the second direction Y and the upper surface of the second electrode forming film 200 has a third direction Z orthogonal to the second direction Y, And shows the direction opposite to the lower surface of the second electrode forming film 200.

The operation of the metallized film capacitor of the present invention having the above-described configuration will be described below.

The metalized film capacitor of the present invention is formed by stacking the first electrode forming film 100 and the second electrode forming film 200 on the upper surface of the second electrode forming film 200, When the first electrode forming film 100 and the second electrode forming film 200 are stacked, the first alignment trench 145 is formed at the end of the second straight groove portion 243 or the second alignment trench 245 The first head electrode 130 and the second head electrode 230 are laminated in the second direction Y so that the first and second head electrodes 130 and 230 are spaced apart from each other in the second direction Y. [ The end of the first rectilinear groove portion 143 is a position that is not communicated with the first inclined groove portion 141 and the first reverse sloped groove portion 142. The end of the second rectilinear groove portion 243 is located at the second inclined groove portion 241 and the second reverse oblique groove portion 242, respectively.

When the first electrode forming film 100 and the second electrode forming film 200 are stacked one over the other using the first alignment trenches 145 and the second alignment trenches 245, A plurality of inverted 'M' shaped unit film capacitors C1 are arranged in the direction X and a plurality of 'M' shaped unit capacitors C1 are arranged in the second direction Y of the inverted 'M' shaped unit film capacitor C1, Film capacitors C2 are formed in the first direction X. [ A hexagonal unit film capacitor C3 is arranged between the inverted 'M' shaped unit film capacitor C1 and the 'M' shaped unit film capacitor C2 and the hexagonal unit film capacitor C3 is arranged in the first direction X Are arranged in the same number as the inverted 'M' shaped unit film capacitors C1 or 'M' shaped unit film capacitors C2.

The 'M' shaped unit film capacitor C1, the 'M' shaped unit film capacitor C2 and the hexagonal unit film capacitor C3 are formed by projecting the first electrode forming film 100 on the upper surface, When the film 200 is projected on the lower surface, the first inclined groove portion 141, the first inverted inclined groove portion 142, the first straight groove portion 143, the second inclined groove portion 241, And is formed by the groove portion 242 and the second straight groove portion 243. The hexagonal unit film capacitor C3 of the inverted 'M' shaped unit film capacitor C1, the M 'shaped unit film capacitor C2 and the hexagonal unit film capacitor C3 is connected to one side or the other side of the second direction Y Are arranged to be inserted into the inverted 'M' shaped unit film capacitors C1 and the 'M' shaped unit film capacitors C2, respectively. That is, the plurality of hexagonal unit film capacitors C3 are arranged in a state in which they are spaced apart from each other with corner portions inserted in the inverted 'M' shaped unit film capacitor C1 and the 'M' shaped unit film capacitor C2, 1 fuse 144 and the second fuse 244. [

Two first fuses 144 and two second fuses 244 are provided and the two first fuses 144 are spaced apart from each other so that the first inclined groove 141 and the first inverted inclined groove 142, And the two second fuses 244 are formed in the second inclined groove portion 241 and the second reverse inclined groove portion 242 in a state where they are spaced apart from each other. The two first fuses 144 and the second fuses 244 are electrically connected to the first inclined groove portion 141 and the first reverse inclined groove portion 142 or the second inclined groove portion 241 and the second reverse inclined groove portion 242 The edge portion of the hexagonal unit film capacitor C3 is inserted into the inverted M'-shaped unit film capacitor C1 and the M'-shaped unit film capacitor C2 to form the first fuse 144 The second fuse 244 causes a current concentration phenomenon.

As described above, in the metallization film capacitor of the present invention, the end of a segmented electrode protrudes in a direction in which a current flows when a current is applied, that is, a corner portion of the hexagonal unit film capacitor C3 is in an inverted 'M' The metal film capacitor C1 of the present invention is inserted and disposed in the film capacitor C1 and the M-shaped unit film capacitor C2 and is formed to be orthogonal to the first head electrode 130 and the second head electrode 230, The occurrence of a weak point known to the fuse 144 causes the current to instantaneously flow through the first fuse 144 or the second fuse 244 to the defect at the time of self-healing operation, The number of the first fuse 144 or the second fuse 244 may be used to isolate the inverted M-shaped unit film capacitor C1, the M-shaped unit film capacitor C2 or the hexagonal unit film capacitor C3 The increase in the number of the first fuse 144 or the second fuse 244 It is possible to prevent an increase in resistance and an increase in heat generation. That is, by reducing the number of the first division electrodes 122 and the second division electrodes 222 arranged in the width direction of the first electrode formation film 100 or the second electrode formation film 200, The number of the first fuse 144 or the second fuse 244 connecting the first common electrode 121 and the first split electrode 122 or connecting the second common segment electrode 221 and the second split electrode 222 is reduced The increase in the equivalent series resistance (ESR) due to the first fuse 144 or the second fuse 244 can be prevented.

The metallized film capacitor of the present invention is characterized in that the first fuse 144 is formed in the first inclined groove 141 and the first inclined groove 142 and the second fuse 244 is formed in the second inclined groove 241 The first fuse 144 and the second fuse 244 are arranged to be offset from each other with respect to the second direction Y to form a segment electrode or an inverted M shape The occurrence of defects in the unit film capacitor C1, the M-shaped unit film capacitor C2 or the hexagonal unit film capacitor C3 causes the reverse M-shaped unit film capacitor C1, the M-shaped unit film capacitor M 'shaped unit film capacitor C1, the' M 'shaped unit film C2, and the hexagonal unit film capacitor C3 by evaporating or vaporizing the heat generated by the current instantaneously flowing through the fuses 144 and 244, The capacitor C2 and the hexagonal unit film capacitor C3 are opened in a circuit manner to form the first electrode Protecting the catastrophic failure of the name 100 and the second electrode formation film 200 and it is possible to improve the reliability of the fuse action.

The metallized film capacitors of the present invention are applicable to the manufacturing industry of film capacitors.

100: first electrode forming film 110: first dielectric film
120: first electrode pattern part 130: first head electrode
141: first inclined groove portion 142: first inclined groove portion
143: first straight groove portion 144: first fuse
200: second electrode forming film 210: second dielectric film
220: second electrode pattern portion 230: second head electrode
241: second inclined groove portion 242: second reverse inclined groove portion
243: second straight groove portion 244: second fuse

Claims (12)

A first dielectric film and a plurality of first inclined groove portions spaced apart from each other at a predetermined interval in a first direction on the upper surface of the first dielectric film and in which a first fuse is disposed, A plurality of first reverse oblique groove portions communicating with one oblique groove portion and having a first fuse disposed therein and a plurality of first reverse oblique groove portions spaced apart from each other by a predetermined distance in the first direction and formed along the second direction, A first electrode forming film having a first electrode pattern portion in which a plurality of first linear groove portions connected to be connected are formed; And
A second dielectric film disposed on the upper surface of the second dielectric film so as to be in contact with the upper surface of the first electrode pattern portion, a plurality of second tilt grooves spaced apart from each other at a predetermined interval in the first direction, And a plurality of second reverse oblique groove portions which are disposed between the plurality of second oblique groove portions and communicate with the second oblique groove portion and in which a second fuse is disposed, a plurality of second reverse oblique groove portions spaced apart from each other by a predetermined distance in the first direction, And a second electrode pattern portion having a second electrode pattern portion formed with a plurality of second linear groove portions connected to communicate with the second inclined groove portion and the second reverse oblique groove portion,
The first electrode forming film and the second electrode forming film overlap each other to form the first inclined groove section, the first reverse gradient section, the first rectilinear groove section, the second inclined groove section, the second reverse gradient section, A plurality of 'M' -shaped unit film capacitors are formed on one side of the second direction by the two straight line grooves along the first direction, and a plurality of reverse 'M' -shaped unit film capacitors are formed on the other side of the second direction along the first direction. Wherein a plurality of hexagonal unit film capacitors are formed along the first direction between the 'M' shaped unit film capacitors and the inverted 'M' shaped unit film capacitors,
Wherein the first electrode pattern portion has a first head electrode disposed on the other side of the upper surface thereof, one of the first inclined groove portion and the first inverted inclined groove portion is connected to form a 'V' groove portion, Wherein a vertex of the V-shaped groove is disposed to face the first head electrode, and the first fuse is disposed in each of the one first inclined groove portion and the one first reverse gradient groove portion,
Wherein the second electrode pattern portion has a second head electrode disposed on the other side of the upper surface, one of the second inclined groove portion and the second inverted inclined groove portion is connected to form one inverted V groove, Wherein a vertex of the inverted V-shaped groove portion is disposed to face the second head electrode, and the second fuse is disposed in the one of the one of the second inclined groove portions and the one of the second inversed groove portions, . The method according to claim 1,
Each of the first dielectric film and the second dielectric film may be formed of a material selected from the group consisting of polypropylene, polyethylene terephthalate polyester (PETP), poly A metallized film capacitor in which one of polyphenylene sulfide (PPS), polyethylene naphthalate (PEN), polyether imide (PEI), or polycarbonate (PC) is selected and used. The method according to claim 1,
The first electrode pattern portion, the second electrode pattern portion, the first fuse, and the second fuse may be made of the same material, and one of copper, nickel, zinc, and aluminum may be selected and used. . The method according to claim 1,
The first electrode pattern portion includes a first common segment electrode formed on the upper surface of the first dielectric film and separated from the plurality of first inclined groove portions and the plurality of first reverse oblique groove portions; And
The first dielectric film is divided into a plurality of first inclined groove portions, a plurality of first inverted inclined groove portions, and a plurality of first linear groove portions on the upper surface of the first dielectric film, And a plurality of first split electrodes arranged along one direction and connected to the first common segment by a first fuse,
The first common segment electrode is divided by the plurality of first inclined groove portions, the plurality of first inverted inclined groove portions, the plurality of first linear groove portions, and the plurality of second linear groove portions, And a plurality of first divisional electrodes each having a plurality of first rectilinear groove portions, a plurality of second inclined groove portions, a plurality of second reverse inclination portions, M 'shaped unit electrodes divided into a plurality of first rectilinear groove portions and a plurality of second rectilinear groove portions arranged in a first direction, the plurality of first rectilinear groove portions, And a plurality of second straight groove portions, each of which is divided into a plurality of first straight groove portions, the plurality of second inclined groove portions, the plurality of second inverted groove portions, and the plurality of second straight groove portions, Shaped unit electrode and And a plurality of first hexagonal unit electrodes are formed so as to be positioned between several first inverted 'M' shaped unit electrodes, and the plurality of first 'M' shaped unit electrodes are used as electrodes of an 'M' shaped unit film capacitor And the plurality of first inverted M'-shaped unit electrodes are used as electrodes of an inverted M'-shaped unit film capacitor, and the plurality of first hexahedron unit electrodes are used as electrodes of a hexagonal unit film capacitor, Film capacitor. 5. The method of claim 4,
The plurality of first inclined groove portions, the plurality of first inverted inclined groove portions, and the plurality of first linear groove portions are positioned between the first common segment electrode and the plurality of first split electrodes, respectively, Wherein the plurality of first inclined groove portions are formed to be inclined by 30 to 60 degrees in a clockwise direction with respect to the first direction, And the plurality of first straight groove portions are formed to be perpendicular to each other with respect to the second direction, and the widths of the first and second straight groove portions are set so as to be equal to each other, Film capacitors. The method according to claim 1,
The first fuse is disposed inside each of the plurality of first inclined groove portions and the plurality of first inverted inclined groove portions so that the plurality of first split electrodes are electrically connected to the first common segment electrodes. Wherein each of the widths is formed to be equal to or larger than one of the plurality of first inclined groove portions, the plurality of first reverse gradient groove portions, and the plurality of first straight groove portions. The method according to claim 1,
The second electrode pattern portion includes a second common segment electrode formed on the upper surface of the second dielectric film by being separated by the plurality of second inclined groove portions and the plurality of second inverted inclined groove portions; And
The second dielectric film is divided into the plurality of second inclined groove portions, the plurality of second reverse oblique groove portions, and the plurality of second linear groove portions on the upper surface of the second dielectric film, And a plurality of second split electrodes arranged along the first direction and connected to the second common segment by a second fuse,
The second common segment electrode is divided by the plurality of second inclined groove portions, the plurality of second inverted inclined groove portions, the plurality of second straight groove portions, and the plurality of first straight groove portions, M 'shaped unit electrodes arranged in the second direction,
The plurality of second split electrodes are respectively divided by the plurality of second rectilinear groove portions, the plurality of first inclined groove portions, the plurality of first reverse oblique groove portions, and the plurality of first rectilinear grooves, A plurality of first oblique groove portions, a plurality of first rectilinear groove portions, a plurality of second oblique groove portions, a plurality of first oblique groove portions, a plurality of second oblique groove portions, a plurality of second oblique groove portions, M '' shaped unit electrodes and the plurality of second 'M' shaped unit electrodes are arranged in the first direction and are divided by the second reverse slope groove portions and the plurality of second straight groove portions, Wherein the plurality of second M'-shaped unit electrodes are used as electrodes of an M'-shaped unit film capacitor, and the plurality of second M'-shaped unit electrodes are formed of a plurality of second hexagonal unit electrodes, Each inverted 'M' shaped unit film Wherein the plurality of second hexagonal unit electrodes are used as electrodes of the hexagonal unit film capacitors, respectively. 8. The method of claim 7,
The plurality of second inclined groove portions, the plurality of second inverted inclined groove portions, and the plurality of second linear groove portions are positioned between the second common segment electrode and the plurality of second divided electrodes, respectively, Wherein the plurality of second inclined groove portions are formed to be inclined by 30 to 60 degrees in a counterclockwise direction with respect to the first direction, Wherein the width of the metallization film capacitor is equal to the width of the metal film capacitor. The method according to claim 1,
The second fuse is disposed inside each of the plurality of second oblique groove portions and the plurality of second reverse oblique groove portions so that the plurality of second split electrodes are electrically connected to the second common segment electrodes. Wherein each of the widths is formed to be equal to or greater than one of the plurality of second inclined groove portions, the plurality of second inverted groove portions, and the plurality of second rectilinear grooves. The method according to claim 1,
Wherein the first fuse and the second fuse are respectively formed in the first inclined groove portion, the first inverted inclined groove portion, the second inclined groove portion, and the second inverted inclined groove portion, And the second fuse is formed in the second inclined groove portion and the second inverted slope groove, respectively, so that the first fuse and the second fuse are spaced apart from each other in the second direction Metallized film capacitors. The method according to claim 1,
Wherein the plurality of hexagonal unit film capacitors are spaced apart from each other with corner portions inserted into the 'M' shaped unit film capacitors and the inverted 'M' shaped unit film capacitors. The method according to claim 1,
Wherein the first head electrode and the second head electrode are formed on the other side of the first common segment electrode of the first electrode pattern portion and the second head electrode is formed on the second common electrode side of the second electrode pattern portion Wherein the metal film capacitor is disposed on one side of the segment electrode.

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