DE3733410A1 - Wound capacitor, especially a plastic-film capacitor - Google Patents

Abstract

A wound capacitor, especially a metallised plastic-film capacitor, consisting of at least two metal layers with an interposed insulating layer, the metal layers having mutually opposite capacitor surface regions as well as connecting surface regions for connecting capacitor surface regions to connecting contacts and possibly for connecting capacitor surface regions of a metal layer to one another is provided with a lead cross-sectional constriction in at least one of the connecting surface regions, which constriction vaporises in the event of a capacitor breakdown. A capacitor short-circuit is in this way reliably prevented.

Description

The invention relates to a wound capacitor, in particular special metallized plastic film capacitor at least two metal layers with an intermediate one Insulating layer, with the metal layers facing each other have overlying capacitor surface areas and Connection surface areas for connecting the capacitor surface areas with connection contacts, and possibly for ver binding of capacitor surface areas of a metal layer together.

When voltages are applied to capacitors that exceed the exceed maximum allowable voltage, for example as a result of a lightning strike or during switching operations in the connected network, there may be a breakdown of the corresponding capacitor come with the result that a correspondingly higher one due to the damaged capacitor Current flows, depending on whether a fine circuit or a short there is a short in the capacitor. This flow of current can lead to Consequential damage in the circuit leads to which of the condensers stor is used. To avoid such damage, has one thought of a separate fuse resistor to be connected in series with the capacitor, which according to Art a fuse destroys itself and thus the Line interrupts when a peak current through it flows. However, this solution did not catch on can. In order to get one with such separate resistors To achieve reliable line separation, the ohmic Resistance value can be chosen relatively high with the result that the loss factor of the switching element from the ge secreted resistance and the capacitor increased accordingly. The separate resistor also increases the assembly effort as well as the required installation space.

The object of the invention is to provide a winding Capacitor of the type mentioned with integrated Protection against current flow in the event of capacitor breakdown provide.

This object is achieved in that at least one of the connecting surface areas with a capacitor Breakdown evaporating line cross-section narrowing is provided. This line cross-section constriction is located according to the invention in the immediate vicinity of possible breakdown point, so that the momentary on kicking peak breakdown currents fully on the safe tion acts, whereas in the more distant Fuses the respective peak current pulse, in particular due to inevitable line inductances, in in a weakened form, the fuse is achieved. Because of the special structure of winding capacitors, with extremely thin metal layer between both electrical and thermally insulating insulating layers, will only be relative little power is required to achieve the cable cross-section Constriction to self-destruct, especially for vaporizing bring to. Accordingly, with a given Current value for blowing the fuse a relative low resistance value for the cable cross-section Narrowing can be chosen. The loss factor of the condensa tors increases due to the installation of the line cross incision narrowing only slightly.

The invention can be applied to the usual wound capacitors Use types, e.g. for paper winding capacitors, for metal paper capacitors and plastic film condensers sators (see e.g. "Taschenbuch der Elektrotechnik und Elek tronik "by Helmut Lindner, Harry Brauer and Constans Lehmann, Verlag Harri Deutsch, Thun and Frankfurt / Main, 1985 Pages 254-256). The metal layer can consequently from a separate metal foil, in particular aluminum foil, be formed or from a metal vapor deposition layer on paper or on plastic film. Particularly however, the use of the invention is preferred for metallized plastic film capacitors (MK condensers sators), especially because the Ver The increase in pleasure factor is particularly small. A preferred one Area of application of the condenser designed according to the invention sators is the radio interference suppression for AC operation, especially when used in conjunction with fluorescent material lamps.

The line cross-section narrowing can be different Way, for example by locally reducing the Metal layer thickness can be achieved. Particularly simple Her adjustability thanks to the constant layer thickness according to the invention then guaranteed when the line cross cut narrowing at least one between recesses the respective metal layer formed in the direction comprises conductor strips extending along the winding axis, whose width is small compared to the width in µm direction of the wound capacitor of a capacitor Area. In the case of a metallized plastic film Condenser therefore need when the carrier film is vaporized only the recess areas currently covered will.

The conductor strips can be in the manner of ladder rungs run parallel to the winding axis with mutual from stood in the circumferential direction.

To increase the resistance and thus to lower the a blowout of the fuse triggering lower limit value of the breakdown current, can be given at a given Line strip width increases its length as a result be that this one extending in the circumferential direction Has section.

In order in a particularly simple way, also in this case, according to the already mentioned ladder rung Solution the appropriate winding capacitor foil on to be able to manufacture running meters, regardless of the respective winding size, it is suggested that for formation of conductor strips in the corresponding connection areas area in the circumferential direction aligned with each other ver running first recess that ends at a distance from one another strips are provided, which beab in the axial direction stood second, aligned with one another in the circumferential direction running recess ending at a distance from one another stripes are opposite, the ends of which are opposite the Ends of the first recess strips in the circumferential direction are arranged offset. Based on these Displacement results in a correspondingly branched stream paths with line strips running in the circumferential direction between the first and second recess strips. The distance between the ends of the first is preferred Recess strips roughly equal to the distance between the Ends of the second recess strips and approximately equal to that Double the distance in the axial direction between the first and second recess strip. It then surrenders Conductor strips with a distance between the first and second recess strips corresponding Strip width.

It is also proposed that with a capacitor inner capacitor series connection of the connecting surfaces area between two successive partial condensers of the series connection with the line cross-section Narrowing is provided. In the event of a breakdown in one of the two partial capacitors results in a doubling of the Total capacitance of the wound capacitor and consequently one Doubling of the value created by the series resistor Line cross-section narrowing of flowing current. this has a four times higher drop in power at the series resistor with the result that the cable cross-section Constriction (fuse link) evaporates and the electricity line is interrupted by the capacitor. Is there a breakdown occurs in both partial capacitors a short-circuit current through the capacitor whose Height of the connected circuit, in particular from internal resistance of a connected voltage source depends and which is generally much higher is, so that the fuse link or the intended Vaporize fuse links quickly and reliably and interrupt the current flow. The same applies to one Condenser without internal division into several parts capacitors.

To increase the safety of the release, it is proposed that that in both connection surface areas between the both connection contacts and the respective capacitor Area provided a line cross-section constriction see is.

The axial length of the winding capacitor does not need ver to become larger when the line cross-section constriction is arranged in the contact edge region of a metal layer. This contact edge area, which after winding with the forehead contact, especially with the Schoopierung, ver will see, is present from the start and only has to be provided with the corresponding recesses.

The line strips open out on the connection contact side into a circumferential conductive edge strip. This edge strip reliably establishes contact with the terminal contact, especially in the case of a to be attached contact washer. In the case of a connection contact Schooping is usually sufficient contact with the metal layers over the conductor strips even then guaranteed, if only the conductor strips unmit have a remote connection with the terminal contact, i.e. in run into this. The advantage of this arrangement is that that the conductive edge strips can be omitted and thus, for a given axial length of the capacitor winding, the Metal layers brought closer to the connection contacts with a corresponding increase in capacity.

In the last-mentioned embodiment, the ent speaking face of the capacitor winding in the usual chen way fully contacted (in particular by Schoopierung). The "fuse-like" line cross the narrowing of the incision occurs directly on this connection contact in the form of conductor strips. In a related to this al Alternative embodiment of the invention, however, can also proceed in such a way that the line cross-section constriction due to only partial connection contacting of the capacitor wrap formed at least at one of the two end faces is. Here, the connection contact of one or of several, preferably two, metallized partial surfaces rich formed the end face of the capacitor winding be, the remaining sub-area or the remaining Partial areas are not metallized. The metal layers of the Winding capacitor layers are contrary to the above Embodiments through to the front the edge of the capacitor layer running in the circumferential direction, in particular preferred to the respective plastic film, so that the usual capacitor foils can be used. On due to the reduction of the connection contact to metal cal partial surface areas of the end face does not result agile way a reduction of the line cross-section between between the metallized partial surface area on the one hand and the associated metal layer on the other hand on the metal layer area immediately adjacent to the metallized th partial surface area, i.e. on the edge section of the Me tall layer that shares this metal layer with the ever has some metallized partial surface area. With cor The same dimensioning is used in the case of a breakdown current the said edge strips evaporate and reliably the Switch off the winding capacitor.

In the case of several partial areas, it is suggested that to connect these with a terminal contact wire, wherein then this wire at the same time as a terminal lug to the one solder the capacitor in the appropriate circuit can.

The metallized partial surface areas can be of a Schoopierung be formed.

The invention also relates to a method of manufacture of a wound capacitor with the last described on building. The method is characterized in that the End face of the wound capacitor under cover of the not metallized partial surface areas schoopiert.

In the following, the invention is based on preferred embodiments examples explained with reference to the drawing. It shows:

Fig. 1 shows two metallized plastic to a first embodiment of the invention, stacked and wound give a winding capacitor;

Winding capacitors 2 is a basic circuit diagram for using the foil according to FIG 1, 4 and 5 received..;

. Fig. 3 is an exploded diagrammatic schematic representation of a winding capacitor of plastic sheeting according to Figure 1 along the capacitor axis in section (corresponding to section line III-III in Fig. 1);

FIG. 4 shows two metallized plastic films, similar to FIG. 1, of a second embodiment; FIG.

FIG. 5 shows two metallized plastic films of another embodiment;

Fig. 6 and Fig. 7 are two plastic films of two further imple mentation forms with the principle circuit diagram according to FIG. 8,

. Fig. 9 and 10 two further metallized plastic Fig From EMBODIMENTS in accordance with basic circuit diagram of Fig. 11;

. Fig. 13 and Fig 14 metallized plastic from two other guide shapes with basic circuit diagram according to FIG 12 and 15a, respectively.

Fig. 16a to Fig. 19b frontal and side views of four further embodiments of inventive catalysts Wickelkonden with basic circuit diagram according to Fig. 15a and 15b.

The basic structure of a metallized plastic film capacitor is shown in FIGS. 1-3. The two recognizable in Fig. 1 plastic films 10 and 12 are mutually overlapping and superimposed on a cylindrical core 14 , for example made of plastic, wound at the same time. It can be seen in Fig. 3 together with four windings that are pulled apart to clarify the Dar position. In reality, the layers are adjacent to one another with a generally wesent Lich higher number of turns, corresponding to the desired capacity. Accordingly, the two plastic films 10 , 12 in the circumferential direction (in Fig. 1 from bottom to top) are formed much longer than shown. Otherwise, the figures are not to scale.

Both foils 10 and 12 are metallized plastic foils, the metallized areas in FIG. 1 being indicated by dots. On the side recognizable in FIG. 1, the film 10 is provided with two metallized areas 14 which extend as far as the side edges 16 parallel to the circumferential direction (double arrow A ) and which are separated by a strip-shaped recess (non-metallized surface area) 18 extending in the circumferential direction A are separated. This area 18 is at the same distance from both longitudinal edges 16 .

The slightly narrower film 12 is provided on both longitudinal edges 20 with a narrow, non-metallized edge strip 22 serving as an insulating edge. Furthermore, a row of successive rectangular recesses 24 extending in the circumferential direction A is provided in the region of the center of the width of the film 12 , that is to say again surface areas of the film without metallization. In this way, surface areas with metallization, referred to as line strips 26 , are formed between successive cutouts 24 (see also FIG. 3 in this regard). These line strips 26 together form an ohmic resistance, denoted by R in Fig. 2, which is dimensio ned such that the line strips 26 evaporate, provided that current flows through this with excessive amperage (breakdown current).

The capacitor labeled C 1 in FIG. 2 , to the left of the resistor R , is formed by the overlapping areas of the metallized surface areas of the foils 10 and 12 , to the left of the recess 18 or the recesses 24 , which are consequently called capacitor surface areas 28 and 30 , respectively. The left border of the capacitor surface area 28 of the film 10 is marked with a dash-dot line 32 and the right edge of the capacitor surface region 30 of the film 12 with a dash-dot line 34 . The metallized surface area of the foil 10 opposite the insulating edge strip 22 of the foil 12 , which joins the line 32 to the left, is referred to as the connecting surface area 38 , since it establishes the connection between the corresponding connection contact and the capacitor C after contacting the winding capacitor on the face side 1 manufactures. In Fig. 3 the left terminal contact is symbolically indicated with a circular contact plate 40 with broken contact line 42 shown . The contact is made in the usual way, for example by shooping.

The two foils 10 and 12 are designed mirror-symmetrically to the longitudinal center line 40 , so that accordingly to the right of the recess 18 or the recesses 24 capacitor surface areas 30 'and 28 ' are formed, with a connecting surface area 38 'connected to the capacitor surface area 28 '. . The dash-dot line 32 'forms the boundary between the two areas mentioned. Between the already mentioned right boundary line 34 of the capacitor surface area 30 and the boundary line 34 corresponding to this line, as the left boundary of the capacitor surface area 30 ', there is the connecting surface area 42 comprising the conductor strips 26 and forming the resistor R , which connects the capacitor surface areas 30 and 30 ' with one another connects.

The number as well as the length (in the direction of the capacitor axis B ) and the width (in the circumferential direction A ) of the conductor strips 26 is now determined in such a way that in the event of a breakdown through one of the capacitors C 1 and C 2 due to an overvoltage on the capacitors ( Lightning strike with the resulting mains overvoltage or voltage peaks due to switching processes in the circuit comprising the capacitors C 1 and C 2 ) evaporate the conductor strips 26 instantly and in this way interrupt the connection between the two capacitors C 1 and C 2. In spite of breakdown in one or both capacitors C 1 and C 2 , no more current can flow from the stop contact 40 to the terminal contact 40 'of the film capacitor which is located on the opposite side.

If one of the two capacitors C 1 and C 2 breaks down, the total capacitance of the film capacitor doubles with a corresponding doubling of the current flowing during charging or discharging. This results in a four-fold drop in power at the series resistor R with the result that the thermally well-insulated, extremely thin conductor strips 26 can no longer give off the heat generated in a sufficient manner and thus evaporate.

In the event of a breakdown through both capacitors C 1 and C 2 , there is a momentary short circuit between the connection contacts 40 and 40 'with a significantly increased momen taner amperage, which immediately leads to the destruction of the line strip 26 , so that the current flow is instantly interrupted.

Fig. 4 shows a second embodiment of the invention with unchanged contact with the terminal contacts 40 and 40 'serving film 10 , but modified, now designated 112 second film. The modification relates to the connecting surface area 142 of this film 112 between the boundary lines 34 and 34 '. To form line strips in this surface area 142 , two rows of first recess strips 150 and second recess strips 152, which are aligned with one another in the circumferential direction A, are provided symmetrically to the longitudinal center line 40. Successive strips 150 and 152 each end at the same distance a from one another. This distance a is approximately twice as large as the (clear) distance b between the two rows, measured in axial direction B. According to FIG. 1, the respective film 10 or 112 in the circumferential direction A has to be imagined in FIG. 4 as well.

The recess strips of one row are offset by half the period with respect to the recess strips of the other row, in other words, the spacing area with length a between successive first recess strips 150 is the center of the length of a recess strip 152 of the other row. From the above-mentioned distance area, two current paths of equal length in FIG. 4 go down and up, which then open into the corresponding distance areas between the recess strips 152 (current arrows c in FIG. 4). In this way, line strips 154 are defined between the recess strips 150 and 152 , which in FIG. 4 run upwards and downwards in the circumferential direction A , with a strip width corresponding to the spacing b of the recess strip rows. In this way, the length and thus also the ohmic resistance of the conductor strips can optionally be increased.

The basic circuit of the film capacitor made from the films 10 and 112 corresponds to FIG. 2. This also applies to the films 10 and 212 of the embodiment according to FIG. 5. The film 10 is again unchanged. The film 212 is provided with a conductor strip 254 in the connecting surface area 242 , which has an approximately Z-shaped course. At a extending in the circumferential direction A center leg 256 of the Z-shape close at both ends at right angles protruding end portions 258 , for connection to the left and right capacitor surface area 230 and 230 ' in FIG. By appropriate dimen sioning of width and length, in particular of the central section 256 , a desired ohmic resistance of the line strip 254 can be set, which corresponds to a lower limit value for the evaporation of the line strip triggering current strength.

In the embodiments of the invention according to FIGS. 6 and 7, the line strips serving as a fuse link are not provided in the connecting surface area between the capacitors C 1 and C 2 but, while maintaining the series connection of two capacitors C 1 and C 2 according to FIG. 8, in the two connecting surface areas 338 and 338 'of the film 310 ( Fig. 6) and in the connecting surface areas 438 and 438 ' of the film 410 ( Fig. 7). According to the connecting surface areas 38 and 38 'in Fig. 1, said connecting surface areas 338 , 338 ' and 438 and 438 'the connection between the respective terminal contact and the associated capacitor surface area 28 and 28 '. Between the capacitor surface areas 28 and 28 'there is again the recess 18 for isolating the two capacitor surface areas 28 and 28 ' on the film 310 and 410, respectively. The second film labeled 12 ' corresponds to the film 12 , omitting the recesses 24 . As a result, apart from the insulating edge strips 22 , it is continuously metallized on one side.

In the embodiment of FIG. 6, the two depending weils serving as securing section and in Figure 8 connecting surface regions denoted by R 1 and R 2 338 and 338 'with rectangular, in the circumferential direction A with spaced recesses 324 are. Provided for the formation of Rung-like conductor strips 326 running parallel to the axial direction A between successive recesses 324 . Preferably, the training is both connecting surface areas 338 and 338 'with these evaporating at breakdown strip line 326, although already forming only one of the two surface areas 338, 338' satisfies these stripline 326th

In the embodiment of Fig. 7 are the two Ver bonding surface areas 438 and 438 'corresponding to the connection area 142 in Fig. 4 are formed, that is each with two axially spaced rows of first recess stripes 450 and the second from nehmungsstreifen 452, with transfer of the two rows in Circumferential direction relative to each other.

The 3 wound films of execution according to FIG. Shapes shown in FIG. 9 and 10 provide a circuit of the winding capacitor according to Fig. 11. The two About lappungsbereiche of the two films 510 and 512 of the imple mentation form according to FIG. 9, respectively form a condensate sator area 514 or 516 . The upper film in Fig. 9 is provided with its left edge in the wound to stand with the terminal contact 40 shown in FIG . Between this left margin 516 and the capacitor area 514, therefore, a connection is again area provided 538 of the film 310 is provided in Fig. 6 with recesses 524 in accordance with, for forming a formed by the intermediate strip line 526 Punch backup route. The Fig. 9 right longitudinal edge of the film 510 is designed as an insulating edge 570 .

The other film 512 , on the other hand, has an insulating edge 570 'on its left longitudinal edge in FIG. 9 and a connecting surface area 538 ' on its right longitudinal edge in the same shape as the connecting surface area 538 of the foil 510 . The film 512 therefore corresponds to a film rotated by 180 ° about an axis perpendicular to the plane of the film, corresponding to the film 510 . The resistance R 1 in Fig. 11 consequently corresponds to the breakdown fuse section formed by the connection surface area 538 and the resistance R 2 of the connection surface area 538 'formed breakdown fuse section. In the event of a breakdown through the single capacitor C formed by the capacitor surface areas 514 and 516 , the breakdown current strength that occurs immediately leads to the evaporation of one and / or the other fuse link. The short circuit is canceled again immediately.

To be on the safe side, both foils 510 and 512 are provided with the safety section with the additional advantage that both foils 510 and 512 have the same vapor deposition pattern and therefore only one type of foil has to be produced. However, a single safety link is sufficient in itself to function.

In the embodiment according to FIG. 10, finally, both connecting edge regions 638 and 638 'of the two foils 610 and 612 are each provided with two rows of first and second recess strips 650 and 652 , corresponding to the connecting sections 438 , 438 ' in FIG. 142 in FIG. 4.

It should be added to Fig. 3 that the foils 10 and 12 are wound on each other that the metallized, in Fig interposed, non-electrically conductive film bodies are electrically insulated from one another.

The films 710, 712 correspond to the films 310 and 12 'accelerator as Fig. 6 with the only difference being that the line stripes 726 of the film 710 directly open into the front side relative to the capacitor winding edge 701 of the film 710, directly to here with to be provided with the corresponding connection contact (Schoopierung). In the embodiment according to FIG. 6, on the other hand, the line strips 326 open into a narrow conductive edge strip 303 which runs along the front edge 301 . In the exemplary embodiment according to FIG. 6, the contact takes place with this edge strip 303 extending over the entire circumferential length of the film 310 .

The film 712 is formed with two insulating edge strips 722 corresponding to the film 12 'in FIG . In this way, a circuit according to FIG. 2 or FIG. 12 is obtained.

The embodiment according to FIG. 14 in turn corresponds to the embodiment according to FIG. 9 with the difference described above. So there are provided on both metal foils 810 and 812 on one side of each line strip 827 , which are pulled forward to the respective peripheral edge 801. In the embodiment according to FIG. 9, on the other hand, the conductor strips 526 in turn each lead into a narrow, metallically conductive edge strip 503 . In accordance with foils 510 and 512 , foils 810 , 812 are also vapor-deposited in the same way, albeit rotated by 180 ° relative to one another about an axis perpendicular to the plane of the foil.

In Figs. 16a to 19b four further embodiments of the invention are shown schematically in front view (with a designated figure) and in side view (with b designated figure).

For example, in FIGS. 16a and 16b a winding body 1002 can be seen, which can have a conventional structure, that is to say, for example, consists of two metallized plastic films which each form one of the two capacitor plates and which are rolled up to form the winding with winding axis 1004. One of the two plastic films is provided at one end 1006 with a connection contact generally 1008 and accordingly the other plastic film at the other end with a corresponding connection contact 1008 . The capacitor winding 1002 has a circular cylindrical shape.

The two connection contacts 1008 have the same shape. They consist of two metallic partial surface areas 1010 and 1012 , which are separated or isolated from one another by a non-metallic partial surface area 1014. The subarea area 1014 is formed by a central to the axis 1004 Strei fen with parallel longitudinal edges 1016 , whose Strei fenbreite g corresponds to about half the cylinder radius of the capacitor winding 1002. Accordingly, the two metallic partial surface areas 1010 and 1012 form diametrically opposite circular segments of the same shape. These partial surface areas can be obtained by covering the strip 1014 accordingly momentarily when Schoopieren. The thickness of the Schoopier layer forming the respective metallized partial surface area 1010 or 1012 is shown greatly enlarged in FIG. 16b - in reality it is in the range of 0.5 mm.

A connecting contact wire 1018 for soldering the capacitor within the circuit provided is soldered with its upper end as shown in FIGS. 16a and 16b with two metallized partial surface areas 1010 and 1012 (soldering points 1020 and 1022 ). Since, according to this embodiment of the invention, the respective end face 1024 , 1026 of the capacitor winding 1002 is no longer contacted over the entire end face (schooped here), i.e. the respective circumferential edge of the metallized plastic film is no longer contacted over its entire length, the occurring is concentrated Current flow inevitably on the contacted part length sections of the respective circumferential Ran of the metallized plastic film. In each winding layer of the plastic film, a contacted partial length section corresponding to the metallized surface area 1012 results, a non-contacted partial length area corresponding to the non-metallized partial surface area 1014 , a contacted partial length section corresponding to the metallized partial surface area 1010 and finally a contacting partial length section corresponding to the partial surface area 1014 non-contacted part-length section of the film. The contacted part-length sections evaporate immediately after the Schoopierung if, due to a momentary breakdown between the metallized plastic films, there is a momentarily greatly increased current flow. These line constrictions form part resistances connected in parallel, which are symbolized as a whole with R 1 and R 2 in FIG. 15a. The embodiment according to FIGS. 17a and 17b again shows a capacitor winding 1102 , which corresponds to the winding 1002 at its end faces 1121 , 1126 with two diametrically opposed metallic (or metallized by Schoopierung) partial surface areas 1110 and with respect to the winding axis 1104 1112 is provided with there intermediate non-metallized partial surface area 1114 . In contrast to the lap 1002 , the lap 1102 is not circular-cylindrical, but rather in cross-section elongated Lich with rounding at both longitudinal ends. The outline of the partial surface area 1114 is essentially square with a square side length g . The two essentially semicircular metallized partial areas 1110 and 1112 adjoin two opposite square sides with a diameter corresponding to the square side length g. The electrical function of the metallized partial surface areas 1110 and 1112 is the same as that of the metallized partial surface areas 1010 and 1012 of the embodiment described above. This function is therefore independent of the selected cross-sectional shape of the roll. The shape of the coil 1102 is comparatively flat and is therefore preferably used in circuits with corresponding installation space restrictions.

In FIGS. 18a and 18b, a capacitor winding 1202 is shown schematically, the two end faces 1224 , 1226 of which are also subdivided into partial surface areas 1210 , 1212 and 1214 in basically the same geometric shape. However, the electrical function of the partial surface areas was reversed. This can be seen directly from the drawings, since the metallized surface areas are characterized by fine dots in all the drawings, whereas the non-metallized surface areas are free from this puncturing. The sector-shaped partial surface areas 1210 and 1212 are therefore non-metallic or non-metallic, in contrast to the partial surface area 1214 . The connection contact wire 1218 is soldered to the schoopierten partial surface area 1214 in a single soldering point 1221. This does not change anything in terms of the functional principle. In the case of a single winding layer, here too, two contacted partial length sections of the corresponding peripheral edge of the metallized plastic film alternate with two non-metallized lengths. Corresponding to the number of windings, double the number of line cross-sectional constrictions result, which form partial resistances of the resistor R 1 or R 2 connected in parallel in FIG. 15a or FIG. 15b.

In their internal structure, the capacitor windings 1002 , 1102 , 1202 and 1302 can correspond to the circuit according to FIG. 15a, i.e. with only a single inner capacitor C , or, according to FIG. 15b, with an inner series connection of two capacitors C 1 and C 2 or other capacitors.

Finally, in FIGS. 19a and 19b, a capacitor coil 1302 is shown schematically, which corresponds in cross section and area distribution of the respective end face 1324 and 1326 of the embodiment according to FIGS. 17a and 17b, but again with complementary metallization of the surface areas. The inner square surface area 1314 is accordingly metallized and connected to the connection contact wire 1318 via a soldering point 1321 . The semicircular diametrically opposed partial surfaces areas 1310 and 1312 , however, are not metallized. Here, too, two contacted and two non-contacted partial length sections of the corresponding peripheral edge of the respective plastic film are provided per winding layer.

Claims (16)

1. Winding capacitor, in particular metallized plastic film capacitor, made of at least two metal layers with an insulating layer in between, where the metal layers have opposing capacitor surface areas and connecting surface areas for connecting capacitor areas with terminal contacts and possibly for connecting Capacitor surface areas of a metal layer with one another, characterized in that at least one of the connecting surface areas (42 ; 142 ; 242 ) is provided with a line cross-section constriction which evaporates in the event of a capacitor breakdown. 2. wound capacitor according to claim 1, characterized in that the line cross-section constriction is at least one line strip ( 26 ) formed between recesses (24 ; 150 ; 154 ; 324 ; 524 ) of the respective metal layer and extends in the direction of the winding axis ( B) ), the width ( a , b ) of which is small compared to the width in the circumferential direction ( A ) of the wound capacitor of a capacitor surface area ( 28 , 30 ). 3. winding capacitor according to claim 2, characterized in that several parallel to the winding axis ( B ) extending in the circumferential direction ( A ) at a mutual distance from each other adjacent line strips (26 ; 326 ; 526 ) are provided ( Fig. 1, 6, 9). 4. wound capacitor according to claim 3, characterized in that at least one conductor strip ( 154 ; 254 ) has a section ( 256 ) extending in the circumferential direction ( A ) (Fig. 4, 5). 5. wound capacitor according to claim 4, characterized in that for the formation of conductor strips in the corresponding connection surface area in the circumferential direction ( A ) mutually aligned, at a distance ( a ) from each other ending first recess strips ( 150 ; 450 ; 650 ) are provided, which in the axial direction ( B ) spaced second, in the circumferential direction aligned ver running, spaced from each other ending recess strips ( 152 ; 452 ; 652 ) opposite, the ends of which are offset from the ends of the first recess strips in the circumferential direction ( A ) (Fig. 4, 7, 10). 6. wound capacitor according to claim 5, characterized in that the distance ( a ) between the ends of the first recess strips ( 150 ) is approximately the distance between the ends of the second recess strips ( 152 ) and about twice the distance ( b ) between the first and second recess strips ( 150 , 152 ). 7. wound capacitor according to one of the preceding claims, characterized in that in a capacitor with an inner capacitor series circuit of the connecting surface area (42 ; 142 ; 242 ) between two successive partial capacitors ( C 1 , C 2 ) cut the series circuit with the power cross - Narrowing is provided ( Fig. 1, 4, 5). 8. wound capacitor according to one of the preceding claims, characterized in that in both connection surface areas (338, 358 '; 438 , 438 '; 538 , 538 '; 638 , 638 ') between the two connection contacts ( 40 , 40 ') and the respective capacitor surface area ( 28 , 28 ') a line cross-section narrowing is easily seen, preferably in a capacitor without an internal capacitor series circuit ( Fig. 3, 6, 7, 9, 10). 9. Winding capacitor according to one of the preceding Expectations, characterized, that the line cross-section constriction in the contact edge area area of a metal layer is arranged. 10. wound capacitor according to claim 9, characterized in that the line strips (326 ; 526 ) open on the connection contact side in a circumferential conductive edge strip ( 303 ; 503 ). 11. wound capacitor according to claim 9, characterized in that the line strips ( 726 , 827 ) open directly into the connection contact. 12. wound capacitor according to claim 1 with connection contacts (1008 ) on both ends of the capacitor winding ( 1002 , 1102 , 1202 , 1302 ), characterized in that the line cross-sectional constriction by only partial connection contacting the capacitor winding ( 1002 , 1102 , 1202 , 1302 ) is formed at least on one of the two front ends. 13. wound capacitor according to claim 12, characterized in that the partially contacted terminal contact of one or more, preferably two, metallic partial surface areas (1010 , 1012 ; 1110 , 1112 ; 1214 ; 1314 ) of the end face ( 1024 , 1026 ; 1124 , 1126 ; 1224 , 1226 ; 1324 , 1326 ) of the capacitor winding ( 1002 ; 1102 ; 1202 ; 1302 ) is formed, the remaining partial area or partial areas ( 1014 ; 1114 ; 1210 , 1212 ; 1310 , 1312 ) being non-metallic. 14. wound capacitor according to claim 13, characterized in that the partial areas ( 1010 , 1012 ; 1110 , 1112 ) are connected to one another by a terminal contact wire ( 1018 , 1118). 15. wound capacitor according to claim 13 or 14, characterized in that the metallic partial surface areas ( 1010 , 1012 ; 1110 , 1112 ; 1214 ; 1314 ) are each formed by a Schoopierung. 16. A method for producing a wound capacitor according to one of claims 12 to 15, characterized in that the end faces ( 1024 , 1026 ) of the capacitor winding (1002 ; 1102 ; 1202 ; 1302 ) while covering the non- metallized partial surface areas (1014 ; 1114 ; 1210 , 1212 ; 1310 , 1312 ) schoopiert.