JP5601718B2 - Metallized film capacitors - Google Patents

Description

  The present invention relates to a metallized film capacitor used for smoothing and filtering inverter circuits for industrial equipment and automobiles.

  In general, metallized film capacitors used for smoothing inverter circuits, etc. are strongly required to be safe because they are used at high temperatures and high voltages. For this reason, as shown in FIG. 4, the metallized film capacitor used for such an application employs a metallized film 10 having divided electrode portions 2A and 2B and non-divided electrode portions 3A and 3B (for example, , See Patent Document 1).

  The metallized film 10 shown in FIG. 4 has a metallicon connecting part 4a to which a metallicon part for electrode extraction is connected at one end in the width direction of the metallized film 10, and an insulating margin 4b is formed at the other end. Yes.

On the insulating margin 4b side of the metallized film 10, a plurality of Y-shaped insulating slits 6 are arranged at a constant pitch in the longitudinal direction, and the base end portion of the Y-shaped insulating slit 6 is connected to the insulating margin 4b.
In addition, in the center of the metallized film 10 in the width direction, there is a row of Mueller-Rearer (metallized film) in parallel with the arrangement direction of the Y-shaped insulating slits 6 at substantially the same pitch as the Y-shaped insulating slits 6. 10) Insulating slits 5 are arranged on both ends of a line segment extending in the width direction.

The divided electrode portions 2A and 2B are divided into the first divided electrode portion 2A having a plurality of divided electrodes 2a in which the vapor deposition electrodes are dividedly formed by the Mueller-Rear type insulating slit 5 and the Y-shaped insulating slit 6 to be divided. And a second divided electrode portion 2B having a plurality of divided electrodes 2b.
Further, a non-divided electrode portion 3A in which vapor deposition electrodes are continuous in the longitudinal direction is adjacently disposed on the metallicon connection portion 4a side of the first divided electrode portion 2A. A non-divided electrode portion 3B is disposed adjacently between the one divided electrode portion 2A and the second divided electrode portion 2B.

The divided electrode 2a is connected to the non-divided electrode portion 3A via a first fuse portion 7a formed between the end portions of the Mueller-rear insulating slit 5 on the metallicon connecting portion 4a side, and the Mueller-rear insulating slit. 5 is connected to the non-divided electrode portion 3B through a second fuse portion 7b formed between the end portions on the insulating margin 4b side.
The divided electrode 2b is connected to the non-divided electrode portion 3B via a third fuse portion 8 formed between the tip portions of the Y-shaped insulating slit 6. The width W _A1 of the first fuse part 7a, the width W _B of the width W _A2 and the third fuse portion 8 of the second fuse part 7b are the same.

In a metallized film capacitor using such a metallized film 10, for example, when dielectric breakdown (clear) occurs in the divided electrode 2a, a large current is generated in the divided electrode 2a that has caused dielectric breakdown from the non-divided electrode portions 3A and 3B. Flows in.
As a result, the first and second fuse portions 7a and 7b are operated (the vapor deposition electrodes of the first and second fuse portions 7a and 7b are scattered), and the divided electrode 2a that has caused the dielectric breakdown becomes the non-divided electrode portion 3A. Insulated and separated from 3B. Therefore, according to the metallized film capacitor using the metallized film 10, high safety can be ensured.

JP 2010-182848 A

By the way, in the conventional metallized film capacitor using the metallized film 10, as shown in FIG. 5, when dielectric breakdowns C1 and C2 of the same scale occur in the divided electrodes 2a and 2b, the division that caused the dielectric breakdown C1. Since the total amount of current flowing into the electrode 2a (total amount of energy) and the total amount of current flowing into the split electrode 2b causing the dielectric breakdown C2 are equal, the current E _B flowing through the third fuse portion 8 is applied to the first fuse portion 7a. This is equal to the sum of the flowing current E _A1 and the current E _A2 flowing through the second fuse portion 7b.
That is, a current E _B larger than the currents E _A1 and E _A2 flowing through the first fuse unit 7a and the second fuse unit 7b flows through the third fuse unit 8.

In the conventional metalized film capacitor, since the width W _A1 of the first fuse part 7a, the width W _B of the width W _A2 and the third fuse portion 8 of the second fuse part 7b are identical, conventional metallization In the film capacitor, the first fuse portion 7a, the second fuse portion 7b, and the third fuse portion 8 may not operate properly. Specifically, the operation of the first fuse portion 7a and the second fuse portion 7b may be delayed, or the third fuse portion 8 operates even for a small dielectric breakdown that is not necessary to operate originally. I had to do it.
Therefore, when dielectric breakdowns C1 and C2 occur, the conventional metallized film capacitor may cause a decrease in withstand voltage performance and a decrease in life characteristics.

  This invention is made | formed in view of the said situation, The place made into the subject is providing the metallized film capacitor excellent in withstand voltage performance and lifetime characteristics.

In order to solve the above problems, a metallized film capacitor according to the present invention is formed by winding or laminating a metallized film provided with a vapor deposition electrode on at least one surface of a dielectric film to form a capacitor element. A metallized film capacitor in which a metallicon part for electrode extraction is connected to both end faces of
The vapor deposition electrode includes a divided electrode portion having a plurality of divided electrodes divided by insulating slits arranged at predetermined intervals in the longitudinal direction of the metallized film, and at least one large electrode having a larger electrode area than the divided electrodes A large electrode portion having
The divided electrode portions and the large electrode portions are alternately arranged in the width direction of the metallized film, the divided electrode portions are the first divided electrode portions in which the large electrode portions are arranged on both sides, and the large electrode portions are only on one side. A second divided electrode portion disposed,
The divided electrode in the first divided electrode portion is connected to a large electrode adjacent to one side through a first fuse portion formed between the insulating slits on one side in the width direction of the divided electrode, and the divided electrode Is connected to a large electrode adjacently disposed on the other side through a second fuse portion formed between the insulating slits on the other side in the width direction of
The divided electrode in the second divided electrode portion is connected to the large electrode via a third fuse portion formed between insulating slits that exist only on one side of the divided electrode,
The width of the third fuse portion is larger than the width of the first fuse portion and the second fuse portion.

According to this configuration, since the width of the third fuse portion is larger than the width of the first fuse portion or the second fuse portion, an allowable current that can be passed through the third fuse portion (to operate the third fuse portion). Required current) can be made larger than an allowable current (current required to operate the first fuse portion and the second fuse portion) that can flow through the first fuse portion and the second fuse portion.
Therefore, according to this configuration, the first fuse portion and the second fuse portion can be reliably operated, and the third breakdown portion is generated when the dielectric breakdown is small enough not to operate the third fuse portion. It is possible to prevent the fuse portion from operating.

  In the metallized film capacitor according to the present invention, the width of the third fuse portion is preferably equal to or less than the sum of the width of the first fuse portion and the width of the second fuse portion.

  According to this configuration, when the dielectric breakdown that should cause the third fuse portion to operate occurs, the third fuse portion can be more reliably operated, so that the safety performance of the third fuse portion can be improved, High safety can be ensured.

  In the metallized film capacitor according to the present invention, each of the third fuse portions may be composed of a plurality of fuses, and the width of the third fuse portion is the sum of the widths of the plurality of fuses. Also good.

  The large electrode is a non-divided electrode in which the vapor deposition electrode is continuous in the longitudinal direction, or a large divided electrode in which the vapor deposition electrode is divided and formed by insulating slits arranged at intervals larger than a predetermined interval. It is characterized by that.

  ADVANTAGE OF THE INVENTION According to this invention, the metallized film capacitor excellent in withstand voltage performance and lifetime characteristics can be provided.

It is a top view of the metallized film which comprises the metallized film capacitor which concerns on this invention. It is a top view which shows the 1st modification of the metallized film in this invention. It is a top view which shows the 2nd modification of the metallized film in this invention. It is a top view of the metallized film which comprises the conventional metallized film capacitor. It is a figure for demonstrating operation | movement of each fuse part at the time of a dielectric breakdown.

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

In FIG. 1, the top view of 1 A of metallized films which comprise the metallized film capacitor which concerns on one Embodiment of this invention is shown.
The metallized film 1A shown in the figure has a vapor deposition electrode provided on at least one surface of a dielectric film, and an electrode is drawn out at one end in the width direction (hereinafter simply referred to as “width direction”) of the metallized film 1A. A metallicon connecting portion 4a to which a metallicon portion for use is connected is formed and an insulating margin 4b is formed at the other end.

On the insulating margin 4b side of the metallized film 1A, a plurality of Y-shaped insulating slits 6 are arranged at a constant pitch in the longitudinal direction of the metallized film 1A (hereinafter simply referred to as “longitudinal direction”). Is connected to the insulation margin 4b.
In addition, at a substantially central position in the width direction of the metallized film 1A, a row of Mueller-Rear insulating slits 5 are arranged in parallel with the arrangement direction of the Y-shaped insulating slits 6 at substantially the same pitch as the Y-shaped insulating slits 6. Has been.

  The vapor deposition electrode is composed of divided electrode portions 2A and 2B and non-divided electrode portions 3A and 3B corresponding to the “large electrode portion (large electrode)” of the present invention, and has an insulation margin 4b, Mueller-Rear type insulating slit 5 And provided in a region excluding the Y-shaped insulating slit 6.

  The divided electrode portions 2A and 2B are divided into a first divided electrode portion 2A having a plurality of divided electrodes 2a divided by Müller-Rear insulating slits 5 and a plurality of divided electrodes 2b formed by dividing the Y-shaped insulating slits 6. The 2nd division | segmentation electrode part 2B which has.

A non-divided electrode portion 3A in which vapor deposition electrodes are continuous in the longitudinal direction is adjacently disposed on the metallicon connection portion 4a side of the first divided electrode portion 2A, and the insulation margin 4b side (first divided electrode side) of the first divided electrode portion 2A. Between the electrode portion 2A and the second divided electrode portion 2B), the non-divided electrode portion 3B is disposed adjacently.
That is, in the metallized film capacitor according to the present embodiment, the divided electrode portions 2A and 2B and the non-divided electrode portions 3A and 3B are alternately arranged in the width direction, and of the two divided electrode portions 2A and 2B, The divided electrode portion 2A is provided with the non-divided electrode portion 3A (3B) on both sides, but the divided electrode portion 2B is provided with the non-divided electrode portion 3B only on one side.

  The divided electrode 2a is connected to the non-divided electrode portion 3A via a first fuse portion 7a formed between the end portions of the Mueller-rear insulating slit 5 on the metallicon connecting portion 4a side, and the Mueller-rear insulating slit. 5 is connected to the non-divided electrode portion 3B through a second fuse portion 7b formed between the end portions on the insulating margin 4b side.

Each of the first fuse portion 7a and each of the second fuse portion 7b is composed of one fuse. The width of the first fuse portion 7a (the width of the fuse constituting the first fuse portion 7a) _WA1 is the same as the width of the second fuse portion 7b (the width of the fuse constituting the second fuse portion 7b) _WA2. .

The divided electrode 2b is connected to the non-divided electrode portion 3B through a third fuse portion 8 formed between the tip portions of the Y-shaped insulating slit 6. Each of the third fuse portion 8 is composed of one fuse, the width (third width of the fuse constituting the fuse portion 8) W _B of the third fuse portion 8, the width W of the first fuse part 7a It is larger than _A1 and the width W _A2 of the second fuse portion 7b.

[Example 1]
In the metallized film capacitor according to Example 1, two metallized films 1A are wound so that the metallicon connection part 4a and the insulation margin 4b face each other, and metallized parts for electrode extraction are connected to both ends. A capacitor element is formed, and the five capacitor elements are connected by an electrode plate, connected to a lead terminal, housed in a case, filled with epoxy resin, and cured.

The metalized film capacitor according to Example 1, the width W _A1 of the first fuse part 7a 0.3 mm, the width W _A2 of the second fuse part 7b 0.3 mm, a width W _B of the third fuse part 8 0 .5 mm.

[Example 2]
Metalized film capacitor according to the second embodiment, in points other than that the width W _B of the third fuse portion 8 and 0.6 mm, in common with metalized film capacitor according to the first embodiment.

[Example 3]
The metallized film capacitor according to Example 3 is common to the metallized film capacitor according to Example 1 except that the width W _A2 of the second fuse portion 7b is 0.2 mm.

[Example 4]
Metalized film capacitor according to the fourth embodiment, in terms of except that the width W _B of the third fuse portion 8 and 0.8 mm, in common with metalized film capacitor according to the first embodiment.

[Conventional example]
The metalized film capacitor in the prior art, the first through third fuse portion 7a, in terms of except that the width W _A1, W _A2, W all _B 0.3 mm of 7b, 8, metal according to Example 1 This is the same as the film capacitor.

  A high temperature bias test (temperature 105 ° C., 280 V / μm, applied for 1000 hours) was performed using the metalized film capacitors of Examples 1 to 4 and the conventional example, and after the test was completed, these metallized film capacitors The capacity change rate and the safety performance (operation performance of the third fuse portion 8) were measured. The measurement results are shown in Table 1.

In Table 1, the ○ in the column of safety performance indicates the state in which the third fuse portion 8 is operating properly, in other words, when a dielectric breakdown occurs in one metallized film, It means that it had reached only one metallized film above and below the direction.
In addition, Δ in the column of safety performance means that there is a possibility of causing short circuit breakage even when there is no problem in the capacity change rate.

[Comparison of capacity change rate]
As shown in Table 1, the metallized film capacitors according to Examples 1 to 4 have a smaller capacitance change rate than the conventional metallized film capacitors, and the decrease in capacitance is small.
This is because the metallized film capacitor of the conventional example operates the third fuse part 8 even with a small dielectric breakdown that does not require the third fuse part 8 to operate. the metalized film capacitor according to larger width W _B of the third fuse portion 8 is first and second fuse portion 7a, than the width W _A1, W _A2 of 7b, the first and second fuse portion 7a, and 7b This is because a current larger than the flowing current can flow through the third fuse portion 8, and thus the third fuse portion 8 did not operate in the small breakdown as described above.

[Comparison of safety performance]
Further, as shown in Table 1, the metalized film capacitor according to Examples 1 to 3, the width W _B of the third fuse portion 8 is first and second fuse portion 7a, than the width W _A1, W _A2 of 7b larger, and the width W _B of the third fuse portion 8 is less than the sum of the width W _A2 of the width W _A1 of the first fuse part 7a the second fuse portion 7b. According to the metallized film capacitors according to Examples 1 to 3 under such conditions, as shown in Table 1, good security performance is exhibited.
On the other hand, metalized film capacitor according to Example 4 is greater the width W _B of the third fuse portion 8 than the sum of the width W _A2 of the width W _A1 of the first fuse part 7a the second fuse portion 7b. Under such conditions, as shown in Table 1, the safety performance is Δ (possibly causing a short circuit breakdown), and the third fuse portion 8 may not operate at a current that should be originally operated.
Thus, from the measurement results, in order to ensure good security performance, such as the metalized film capacitor according to Examples 1 to 3, the width W _B of the third fuse portion 8 of the first fuse part 7a width It can be seen that it is preferable to make it less than the sum of W _A1 and the width W _A2 of the second fuse portion 7b.

As described above, the width W _B of the third fuse part 8 first and second fuse portion 7a, to be larger than the width W _A1, W _A2 of 7b, it is possible to suppress the reduction in capacitance.
Further, by the following sum of the width W _A2 of the width W _B of the third fuse portion 8 the width W _A1 of the first fuse part 7a the second fuse part 7b, not only suppress the reduction of the capacitance, Good security performance can be obtained.

[First Modification]
Next, FIG. 2 shows a first modification of the metallized film constituting the metallized film capacitor according to the present invention.

In the metallized film 1B shown in FIG. 2, a plurality of T-shaped insulating slits 16a are arranged at a constant pitch in the longitudinal direction on the insulating margin 4b side, and the base end portion of the T-shaped insulating slit 16a is formed on the insulating margin 4b. It is connected. Rectangular insulating slits 16b are arranged between the tips of the T-shaped insulating slits 16a.
Further, in the metallized film 1B, a row of I-shaped insulating slits 15 are arranged in parallel with the arrangement direction of the T-shaped insulating slits 16a at substantially the same pitch as the T-shaped insulating slits 16a.

  In a region excluding the insulating margin 4b, the T-shaped insulating slit 16a, the rectangular insulating slit 16b, and the I-shaped insulating slit 15, a first divided electrode portion 2A having a plurality of divided electrodes 2a and a first divided electrode portion 2b having a plurality of divided electrodes 2b. The vapor deposition electrode which comprises the 2 division | segmentation electrode part 2B and the non-division electrode parts 3A and 3B in which the vapor deposition electrode continued in the longitudinal direction is provided.

  The divided electrode 2a is connected to the non-divided electrode portion 3A through the first fuse portion 7a formed between the end portions of the I-shaped insulating slit 15 on the metallicon connecting portion 4a side, and the insulating margin of the I-shaped insulating slit 15 It is connected to the non-divided electrode portion 3B via a second fuse portion 7b formed between the end portions on the 4b side.

  The divided electrode 2b is connected to the non-divided electrode portion 3B via a third fuse portion 8 formed between the tip portions of the T-shaped insulating slit 16a.

The third fuse portion 8, two fuses 8a formed between the tip and the rectangular insulating slit 16b of the T-shaped insulating slits 16a, are composed of 8b, the width W _B of the third fuse portion 8, the fuse the sum of the width W _B2 of width W _B1 and fuse 8b of 8a.

Width W _B of the third fuse portion 8 (the sum of the width W _B2 of width W _B1 and fuse 8b fuse 8a), as well as the metallized film 1A shown in FIG. 1, Ya width W _A1 of the first fuse part 7a It is larger than the width W _A2 of the second fuse portion 7b. Furthermore, the width W _B of the third fuse portion 8 is the width W _A1 of the first fuse part 7a becomes more than the sum of the width W _A2 of the second fuse part 7b.

For this reason, in the metallized film capacitor using the metallized film 1B according to the present modification, the first and second fuse parts 7a and 7b can be operated reliably, and the third fuse part 8 must be operated. It is possible to prevent the third fuse portion 8 from operating against such a small dielectric breakdown as there is no.
Therefore, according to the metallized film capacitor according to this modification, it is possible to prevent a decrease in capacitance, and it is possible to prevent a decrease in withstand voltage performance and life characteristics.

Furthermore, the metallized film capacitor of the present modification example, since the width W _B of the third fuse portion 8 is equal to or less than the sum of the width W _A2 of the width W _A1 of the first fuse part 7a the second fuse portion 7b Good security performance can also be ensured.

[Second Modification]
In FIG. 3, the 2nd modification of the metallized film which comprises the metallized film capacitor based on this invention is shown.

  A metallized film 1C shown in FIG. 3 includes large divided electrode portions 3A ′, 3B ′ (main book) having large divided electrodes 3a ′, 3b ′ formed by insulating slits 9 instead of the non-divided electrode portions 3A, 3B. 1 is common to the metallized film 1A shown in FIG. 1 except that the “large electrode portion” of the invention is formed.

  The large divided electrodes 3 a ′ and 3 b ′ are divided and formed by the insulating slits 9 arranged at a larger interval than the interval between the Mueller-Rear insulating slit 5 and the Y-shaped insulating slit 6. The electrode area is larger than 2b.

  According to the metallized film capacitor using the metallized film 1C according to the present modified example, the first and second fuse portions 7a and 7b are surely secured in the same manner as the metallized film capacitor according to the embodiment and the first modified example. In addition, it is possible to prevent the third fuse portion 8 from operating against a small dielectric breakdown that does not require the third fuse portion 8 to be operated. The deterioration of characteristics can be prevented.

  As mentioned above, although preferable embodiment and the modification of the metallized film capacitor concerning this invention were described, this invention is not limited to said structure.

For example, the number of fuses constituting the first to third fuse unit 7a, 7b, 8 of the fuse width W _B of the third fuse part 8 which constitutes the width (first fuse portion 7a of the first fuse part 7a if greater than the width of the sum) W _A1 and width of the second fuse part 7b (the sum of the width of the fuse constituting the second fuse part 7b) W _A2, can be arbitrarily changed.

  In addition, the shape of insulating slits such as the Mueller-Rear insulating slit 5 and the Y-shaped insulating slit 6 and the interval between these insulating slits can be arbitrarily changed.

1A, 1B, 1C Metallized film 2A First divided electrode portion 2B Second divided electrode portion 2a, 2b Divided electrode 3A, 3B Non-divided electrode portion 3A ', 3B' Large divided electrode portion 3a ', 3b' Large divided electrode 4a Metallicon connection 4b Insulation margin 5 Müller-Rear insulation slit 6 Y-shaped insulation slit 7a First fuse part 7b Second fuse part 8 Third fuse part 8a, 8b Fuse 9 Insulation slit 15 I-shaped insulation slit 16a T-shaped insulation slit 16b Rectangular insulation slit

Claims (5)

A metallized film capacitor in which a metallized film provided with a vapor deposition electrode on at least one side of a dielectric film is wound or laminated to form a capacitor element, and metallized parts for extracting electrodes are connected to both end surfaces of the capacitor element. There,
The vapor-deposited electrode has a divided electrode part having a plurality of divided electrodes divided by insulating slits arranged at predetermined intervals in the longitudinal direction of the metallized film, and has an electrode area larger than the divided electrode, at least 1 A large electrode portion having two large electrodes,
The divided electrode portions and the large electrode portions are alternately arranged in the width direction of the metallized film, and the divided electrode portions are arranged on one side with a first divided electrode portion on which the large electrode portions are arranged on both sides. Only the second divided electrode portion on which the large electrode portion is disposed,
The divided electrode in the first divided electrode portion is connected to the large electrode disposed adjacent to the one side through a first fuse portion formed between the insulating slits on one side in the width direction of the divided electrode. And connected to the large electrode disposed adjacent to the other side through a second fuse portion formed between the insulating slits on the other side in the width direction of the divided electrodes,
The divided electrode in the second divided electrode portion is connected to the large electrode via a third fuse portion formed between the insulating slits existing only on one side of the divided electrode,
The metallized film capacitor, wherein a width of the third fuse part is larger than a width of the first fuse part and the second fuse part.   2. The metallized film capacitor of claim 1, wherein a width of the third fuse portion is equal to or less than a sum of a width of the first fuse portion and a width of the second fuse portion. Each of the third fuse portions is composed of a plurality of fuses,
3. The metallized film capacitor according to claim 1, wherein a width of the third fuse portion is a sum of widths of the plurality of fuses.   The metallized film capacitor according to claim 1, wherein the large electrode is a non-divided electrode in which the vapor deposition electrode is continuous in the longitudinal direction.   The metal according to any one of claims 1 to 3, wherein the large electrode is a large divided electrode in which the vapor deposition electrode is divided and formed by insulating slits arranged at intervals larger than the predetermined interval. Film capacitor.

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