DE2200582A1 - Book electrolytic capacitor - Google Patents

Description

January 5, 1972 Gzs / goe

SPRAGUE ELECTRIC COMPANY

Book electrolytic capacitor.

The invention relates to an electrolytic book capacitor, more precisely, a book capacitor design that lengthened Anode and cathode foils used by spacer paper are separated in order to weld the units together to form a stripline, so that a low inductance is achieved.

Reference is made to US Patent Application No. 19 »192, pending March 13, 1997, referenced.

An electrolytic Buch capacitor is made by using anode electrode foils, dielectric spacer papers, and cathode electrode foils stacked or rolled that thereafter the composite sheets are flattened in such a manner and cut to create elongated anodes and elongated cathodes passing through the center of the capacitor be separated through by means of spacer paper, the rolled or stacked foils for a predetermined tension were previously formed. The anode extensions or attachments of three such electrodes are welded together, just like the cathode extensions or approaches,

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creating a single electrode package. One of these electrode packs is then attached to a stripline on each side welded on. The stripline consists of two conductive plates, which are essentially of greater thickness than the anode and cathode foils that make up the capacitor turn off. The strip line construction is such, that it takes a T-shape when an L-shaped anode plate is laminated to an L-shaped cathode plate, which is in opposite Show directions and are separated by an insulating layer. One wing of the T is the anode plate and the other wing is the cathode plate. The welded-on anode attachments of the electrode package are on the anode plate of the stripline welded, and the cathode lugs of the electrode package are welded to the cathode plate of the stripline. The connected The unit is impregnated with an electrolyte and the capacitor is placed in a can.

Have capacitors that are used at high frequencies This created difficulties for the earlier electronic applications and led to the development of electrolytic capacitors high capacitance and low voltage filtering at low frequencies and high switching speed at high Allow frequencies. Electrolytic capacitors that can operate at high frequencies require lower effective series— resistances (ESH) and lower effective series inductivities

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(ESL), so the power consumed within the capacitor to diminish and thus to reduce the destructive effects of overheating. Attempts to obtain these parameters have so far been made limited success. Capacitors that have a strip line construction used, liafoen achieved this goal, however new stripline constructions are constantly sought to reduce the cost of manufacturing these capacitors.

An object of the present invention is to provide a book capacitor produce, in which the resistance and the inductance of the capacitance are lowered, so that little impedance on the capacitor is applied and that a high effective operating frequency is possible.

It is another object of the present invention to provide a capacitor to create that has a reliable Ilochfrequenzffekt and which can be produced economically.

Further advantages, features and possible uses of the invention result from the attached illustration of an exemplary embodiment and from the following description.

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_ I ₁ _

It shows:

1 is a perspective view of a rolled foil electrode unit,

FIG. 2 is a perspective view of the electrode unit of FIG. 1 which has been flattened;

3 is a perspective view of the electrode unit of FIG Fig. 2, which has been cut and bent,

Fig. K is a perspective view of an electrode package of three electrode units which are welded together;

5 is a perspective view of a strip line arrangement;

FIG. 6 shows a cross section of the stripline of FIG. 5 along line 6-6 with an electrode package attached to each side,

7 is a perspective view of a condenser container, which has been opened to reveal the electrode package therein, and

8 is a perspective view of a stacked HICU electrode unit.

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The rolled book electrolytic capacitor of this invention is made by first wrapping anode foils, dielectric spacer papers and cathode foils in such an overlapping manner that anode foils and cathode foils flank the central portion of the capacitor roll which contains alternating layers of anode foils, dielectric spacer papers and cathode foils. Such an arrangement is shown in Fig. 1 with the anode foils H1 extending on one side to the center of the roll, spacer papers 12 in the center, and cathode foils 13 extending from the perforated line Ik in the center to the outer edge the other side of the roll, the spacer paper being arranged between alternating layers of cathode foil and anode foil. This roll is then flattened in FIG. 2 and can be cut at all four edges 15a, 15b, 15c and I5d in order to produce the construction shown in FIG extend to the other side of the rolled unit. This configuration facilitates any subsequent bending of the foils.

The anode foil lugs 11 and the cathode foil lugs I3 are bent down to the positions shown at 11a and 13a, respectively are, and the outermost parts of these approaches are bent laterally for a subsequent assembly and welding.

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Three such units are rolled, cut and appropriately bent and mounted on top of each other in a piggyback fashion, with all of the anode foils in alignment with one another and on the other side with all of the cathode foils in alignment with one another. These three units are then welded together, as shown in Fig. K shown, to form an electrode package 10. The cathode foils 13 are cut so that the pack has a substantially flat dode after welding at the points 16, and the anode foils 11 are cut and welded on the other side of the electrode pack in the same way. However, fewer cuts can be made on the roll to form similar but less inexpensive units. The flattened rolls can be bent without cutting them, but bending problems and electrical defects in them make it advantageous to make some cuts on the flattened rolls.

This type of structure retains the low values of ESR and ESL ₁ obtainable from a stacked structure such as that achieved in the referenced patent, with great savings being achieved because of the speed at which these reel units can be manufactured. The anode and cathode foils of the capacitor shown here are made of high purity aluminum (99 % or higher), which eliminates corrosion problems and prevents the formation of aluminum oxide.

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Quality is assured. As an alternative, anode

and cathode foils also made of another metal forming a film,
/ such as 13. Tantalum or MoMum, are manufactured. The anode foils 11 are made for the required stress strengths using the same processes that are well known in the art for the manufacture of capacitors to form the foils for the use of rolled capacitors of the known type. The cathode foils can also formed _{9 to} achieve a non-polar capacitor. "The anode and cathode foils are on the order of 0.05 to 0.076 mm (2 to 3 mils) in thickness. While dj ~ ei (3) rolled end flattened Elelctrodeneinheiten were welded to each electrode package in this embodiment of Fig vorzugsTireisen _o%, so kön-

the

but now also packs contain more or less rolled electrode units, depending on which capacitance properties are desired. The spacer comb paper 12 O _s Ol27 to 0.1 mm thick (0.0005 to 0.004 inch), and it may be of a force or Benares type, which is normally used for electrolytic capacitors. The foil outlets can be welded together with the aid of a tungsten inert gas welding process (TIG).

The stripline structure 20 shown in FIG. 5 consists of an anodized aluminum anode plate 21 and a partially overlapping anodized aluminum cathode plate 231 which are separated from one another by an insulating layer 2V. These

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Units are laminated together. At 28 and 29 are connections educated. Each plate has an L-like shape. As another option You can choose the anode and cathode plates from one another anodizable metal, such as tantalum or niobium, be manufactured, however, it should be a conductive material. Both the anode plate 21 and the cathode plate 23 are the same Size and shape, and when placed in the stripline 20 an aluminum plate is slipped over so as to form a symmetrical T-structure shown in Fig. 5, wherein the central part of the anode plate is essentially identical. with the central part of the cathode plate, however, is the wing part the anode plate the mirror image of the cathode plate and arranged directly opposite the cathode plate in alignment. the Thickness of the cathode and anode plates 21 and 23 and that of the insulating layer 22 have been exaggerated in the drawing to better illustrate the structure of the stripline. The anode and cathode plates the preferred embodiment are normally 1.6 mm (64 mils) thick, but can be made thinner or thicker depending on the respective requirements on the capacitor. The insulating layer 22 would be in the range of 0.025 to 0.25 mm (1 to 10 mils) thick, although other insulating materials such as epoxy-coated fabric or Teflon could be used for this. The wing part of the anode and Cathode plates 21 and 23 are provided to facilitate the welding of the packs of rolled anode and cathode foils,

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as shown along line 6-6 in FIG. Although this particular geometric configuration for the stripline seems to be favorable, the scope of the invention is in no way the scope of the invention limited to this particular size and shape of the stripline.

Two electrode packs, each with three flattened, cut, Containing curved and welded rolls of foil and spacer paper, are then TIG welded to the stripline assembly, a roll being welded on each side to the outer edge of the wing portion of the respective plate. In Fig. 6 are the cathode foils 13 of the electrode packs with the wing parts the cathode plate 23 welded, and the anode foils 11 are welded to the wing part of the anode plate 21. The two circuit boards in the stripline are electrical and physically separated by an insulating layer 22 and the foils are separated from one another by spacer paper 12. A Anode terminal 28 and a cathode terminal 29 are on the extended portion of the stripline, and the capacitor 10 is with a standard electrolyte, such as a glycol borate type, impregnated and packed in a can 31 with a lid 27.

In another embodiment, the strip line could do so it can be provided that the connections extend to opposite ends of the condenser box or pack. These capacitors can be of the two-port type or of the four-port type,

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- OK -

In this embodiment, each rolled unit has the A film length of 152 cm (60 inches) was used to form an electrode package. This applies to anode and Cathode foils. Thus, since six (6) rolled units are used, and each unit 152 is one (60 inches), the Total length of anode per capacitor 91 ** cm (36O inches). Six capacitors of this design have an average ESR of 0.00153 ohms. The ESH takes ah with an increasing number of approaches or with a larger number of Units that provide a larger number of approaches. Those previously described for connecting the cathode foil and plate Diminish procedure for a stripline capacitor drastically reduce the film and terminal resistances and thus contribute to a low series impedance for the capacitor and make the capacitor suitable for filtering at low impedance and for switching applications at high frequency.

Many different embodiments are of course possible. For example, similar, although somewhat less favorable results could be obtained with a rectangular stacked design shown in FIG. In this alternative embodiment, overlapping layers are anode foils 41, spacer papers 42 and cathode foils 43 stacked on top of one another so that that the cathode foils 43 only up to the perforated Line 44 extend, and that the anode foils extend into a ^ m

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same point on the other side of the midsection of the Stacks extend. From this point on, the units can be edited in the same way as before for the flat rolled units. The extending anode tabs 41 and the extending cathode tabs 43 can be bent to piggyback on other units assembled and welded. These packs can then be welded to the stripline assembly 20, as shown in Fig. 5, wherein an anode plate 21 of anodinfertem Aluminum from a cathode plate 23 of anodized aluminum is separated by an insulating layer 22. The stripline arrangement is laminated to each other.

The input inductance of the electrolytic stripline type or electrostatic type capacitors is much less than what is achievable with the multiple approaches of the prior art using the convoluted arrangement. One of the greatest advantages of the stripline type capacitor described herein is the economics of manufacture discovered in connection with the flat rolled units. The work required for the units was reduced by approximately 70% compared to the stacked film units according to the prior art, while even lower ESR ¹ s and ESL's could be maintained.

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Claims (3)

22,0582 claims 1.) Book capacitor, characterized by a strip line arrangement with an anode plate, from which a connection part extends to the outside of the book capacitor extends to provide at least one terminal for outside electrical contact with that capacitor, and a central portion of which may have foils attached to either side thereof; a cathode plate of about the the same size as the anode plate, the central part of which is essentially is identical to the central part of the anode plate, fleeing
the central portion directly facing the central portion of the anode plate and partially overlapping the central portion of the anode plate, one end portion of the cathode plate extending outwardly from the Buch capacitor to provide at least one other terminal for external electrical contact with the capacitor zvi; an insulating layer sandwiched between the overlapping anode and cathode lead plates to electrically isolate the two plates from one another; and at least one electrode unit of overlapping, rolled and flattened anode foils, cathode foils and dielectric spacer material, which is arranged in relation to the spacer material in order to prevent an electrical short circuit between the foils. 209846/0644 22Ό0582 dern, the anode foils in electrical and physical Are in contact with each other and with the anode plate, the Cathode foils · electrically and physically in contact with one another and stand with the cathode plate. 2. book capacitor according to claim 1, characterized in that that the anode plate has an L-shape, and that the central part includes a wing part of this L-shape; has that the cathode plate has an L-shape and that the central part thereof includes a wing part of the cathode plate, and that this wing part is arranged in alignment directly opposite the wing part of the anode plate; that the flattened Electrode unit is cut at all four corners, so that a plurality of anode foils from one side of the unit and a plurality of cathode foils extend from the other side of the electrode unit; and that at least another electrode unit is attached to the other side of the stripline arrangement so that the anode foils are in physical and electrical contact with each other and with the anode plate, and that the cathode foils are in physical and electrical contact with each other and with the anode plate. 209846/0644 22OC582 - Ik - 3. book capacitor according to claim 2, characterized in that three electrode units Mounted on top of each other in a piggyback fashion and attached to each other Side of the stripline are attached so that the Anode foils in physical and electrical contact with one another and with the anode plate, and that the cathode foils are in physical and electrical contact with one another and stand with the cathode plate. k. Book capacitor according to Claim 2, characterized in that the anode and cathode plates consist of film-forming metal; that anode and cathode foils consist of a film-forming metal; that the anode foil forms for a predetermined voltage, the
and that dielectric spacer material with an electrolyte is impregnated. 2098A6 / 06AA Blank page