DE911521C - Device for manufacturing metal-free parts on metallized dielectric strips for electrical capacitors - Google Patents

Description

Device for the production of metal-free parts on metallized Dielectric Tapes for Electrical Capacitors The invention relates to to improvements in apparatus for making metallized dielectric Tapes for electrical capacitors.

The invention relates to a device that combines devices falls over to accommodate a feed roll with metallized dielectric tapes, furthermore one or more demetallizing contacts, expediently in the form of one or several rotatable disks, which are mounted so that the metallized side of the dielectric can be guided past it and in connection with the or the contacts of one or more other conductors, preferably in the form of one or more Rolls that are also connected to the dielectric tape coming from the supply roll, namely with its metallized side, are in contact. An electric one The current source is connected to the one or the other by means of a current-limiting resistor demetallizing contacts and the other conductor or conductors connected in such a way that a voltage difference between the demetallizing contact or contacts and the metallized side of the dielectric is created. In this case arises a demetallizing discharge between the contact and the surface in contact with it of the dielectric.

The invention also includes an apparatus of the type described for the production of metallized dielectric tapes with metal-free Share, wherein the demetallizing contact or each of the demetallizing contacts, if there are several, parallel to a capacitor of suitable capacity is switched. Contact and capacitor «grounded from a circuit, the has a current-limiting resistance of such strength that it is the demetallizing Discharge extinguishes without it being able to spread randomly from the contact, and the nevertheless a flow of the appropriate current is allowed to the capacitor during the pauses between the successive demetallizing discharges.

With such a circuit should be achieved that immediately when there is contact between the metallized surface and the demetallizing pane a current discharge takes place through the metallized surface, the is strong enough to face in a certain width and at a certain distance the demetallizing disc to remove the metal by evaporation. The current then stops for a moment, and that during the demetallization discharged capacitor is recharged until the metallized surface again comes into contact with the demetallizing disc. A new momentary discharge then occurs one, then another recharge, and this process continues in rapid succession continue as long as the metallized dielectric tape is over the demetallizing disc or the discs is guided. The speed of demetallization can be below these conditions compared to the speed without capacitors increase.

In practice, the above change takes place so quickly that a apparently uninterrupted demetallization takes place; by a precise choice the magnitudes of the resistance and the capacitance is also a very precise regulation the demetallization possible.

`` 'If a plurality of demetallizing contacts is attached, will it is best to assign a special resistor and capacitor to each individual contact, whereby the contacts are isolated from each other and solely by the associated resistor and capacitor are fed. However, it is possible to use the demetallizing contacts to be arranged in groups, each with a single resistor or capacitor or both is assigned. If you have a single or multiple resistor and capacitor groups switches off, the demetallization regulated by the contact in this area continues the end. Thus, the distance between the demetallized strips on the dielectric be kept changeable by having any desired contact or contact group on or off.

The figures show an embodiment of the invention.

Fig. I is a circuit diagram, Fig. 2 is a plan view of part of the device and shows the demetallizing contacts; Fig. 3 is an elevation of the same part seen in the direction of arrow 3 in Fig. 4, and Fig. q. is a cut on the Line 4-4 of Figure a, viewed in the direction of the arrows.

In Fig. I, the alternating current lines 11, 12 are via a control booster transformer 13 to the primary winding 1d. of a transformer switched. The transformer has a secondary winding 15, the ends of which are connected to the anodes of two rectifier tubes 16, 17. The direct current line of the tubes is connected by lines 1ä, ig via a choke coil 2o to the positive terminal 2i of the demetallizing direct current circuit. In its center, the transformer winding 15 is connected by line 22 to the negative or ground terminal 23 of the circuit. Two capacitors 24, 25 are arranged between the terminals of the choke coil 2o, and from the middle between the capacitors 2q., 25 a line 26 goes to the earth of the circuit. The job of the choke coil and the capacitors is to control the DC power. to smooth the tubes. A connection goes from the positive terminal 2i via a current-limiting resistor 30 to a demetallizing disk 31. Connected in parallel with the demetallizing disk is a connection 32 to a capacitor 33, the other terminal of which is connected to the earth of the circuit. Metallized paper dielectric is passed with the metallized side up under a roller 34, which is connected to the earth terminal of the circuit by a line 35, then runs over a guide roller 36 and past the demetallizing disc 31 to a second guide roller 37 and becomes another Treatment forwarded.

It can be seen that with a suitable efficiency of the resistor 30 and the capacitor 33, the demetallizing disk 31 causes an intermittent electrical discharge when it comes into contact with the metallized paper surface, which effectively demetallizes the paper along the contact line, and that the throughput speed of the paper in the device is more effective Demetallization can be much higher than would be the case if the capacitor 33 were omitted, provided that the resistor 3o is adjusted to the best efficiency for cooperation with the capacitor and demetallization disk. Another demetallization disk 41 is fed by line 4.2 and resistor .4o and is connected in parallel with a capacitor 43. This disk .I1 presses on the paper along a line that runs parallel to that generated by disk 31 at a distance. Similarly, there is another demetallizing disk 5 i along a further line, which is fed through line 52 from a resistor 5o and connected in parallel to a capacitor 53. Other similar disks 61 can be added, each connected to a resistor, such as 60, and a capacitor, such as 63, and so on, up to any useful number desired. For example, paper dielectric with a thickness of 8 microns and an aluminum layer on one side of a thickness of about 80 microns has been satisfactorily demetallized. A direct current voltage of 500 volts was used between terminals 21 and 23, resistors 30, 40, 50 etc. each had 3000 ohms and capacitors 33, 43, 53 etc. each had a capacitance of 0.003 microfarads. In this case, the speed of the paper on the guide rollers next to the demetallizing disks was 17.67 m per minute, which is considerably more than can be achieved with a device in which no capacitors were installed. In this case the demetallizing disks 31, 41 etc. had a thickness of about r.58 mm.

Figs. 2, 3 and 4 show the mechanical arrangement for the demetallizing Disc in relation to the paper. The device is intended in addition to a machine be used, in which a tape 38 (see. Fig. 4) of paper dielectric to the demetallizing Slices passed by a set of cutting knives that it is passed along by Cut the lines into strips passing through the center of the resulting metal-free Run tracks and also through the middle of the remaining metallized tracks, like this that each strip has a metallized surface that extends to one edge enough, but separated from the other edge by a narrow, metal-free paper web is.

The different roles that the paper dielectric has in the machine runs, rest in bearings of the frame side parts 70, 71 and encompass the rollers 34, 36, 37, which have already been mentioned in connection with FIG. In Fig.2 and 4 is the roller 36 only indicated in dashed lines so that it does not have the view of it other parts covered, and the roller 37 in a continuous line. In Fig. 3 is the Roll 37 omitted. The roller 36 has pins at its ends which are in plain bearing blocks 76 rest in grooves 77 of the side walls 70, 71, the brackets 76 being supported by springs 78 and held in position by adjusting screws 79. The recess 77 is after closed at the top by a plate 8o which is held by screws 81. At On one side, the plate 8o is formed into an arm 82 which carries a shaft 83. On one side of the device, the shaft 83, as indicated at 84, is with Provided screw threads, and the arm 82 receives the thread. At the end of the thread the shaft carries a handwheel 85. With this arrangement, the shaft can opposite the Arms 82 can be adjusted.

On the shaft 83 a frame is attached, which consists of two with pins provided arms 86, 87, which can rotate freely on the shaft and rods 88, 89, which are firmly connected to one another by a transverse rod 9o. Limiting rings 9i, 92 prevent lateral displacement of the frame on the shaft 83, let however, it can pivot freely around the shaft so that it is different from that shown in the figure Position can be pivoted up to a position in which the arms 86, 87 stand vertically. At the ends of the arms 86, 87 there are protruding sides Rods 93, 94 overlying plates 95, 96 attached to the upper edge of the side panels 70, 71 of the frame of the device are attached. Adjusting screws 97 (Fig. 3) go through the rods 93, 94 and, after their adjustment, are locked by lock nuts 98 secured. In a position according to the figure, the screws 97 sit with the Head down on the plates 95, 96. The plates 95, 96 are large enough to hold the To keep screw heads 97 on the plates at all shaft adjustments.

The arms 86, 87 have bearings for the ends of a shaft 99, which the demetallizing disks 31, 41, 51, 61, etc. carries. The wave is from one Surrounding insulating jacket on which the demetallizing disks 31 to 61 are screwed are just like metal slip rings ioi, the demetallizing on one side Discs touch but are of smaller diameter. Between the other side each slip ring ioi and the next demetallizing disk is located an insulating ring 102. The arrangement of demetallizing disks, slip rings and insulation is pressed together by nuts io4, io5 that are on the ends the shaft 99 are screwed on. A wheel is attached to one end of the shaft, with which it can be driven. The nuts io4, io5 are knurled on the outside, like this that they can be solved quickly by hand. By inserting various insulating Intermediate members 102 of a thickness other than that shown in the figure may be the intermediate space between the demetallizing disks 31, 41 etc. according to the work project to be changed.

On the shaft 83 sits a row of brush holders i io, which can rotate freely around the shaft and the intermediate nuts i i i, which are attached to the Shaft screwed and held on both sides by rings 112, secured are. Each brush holder carries a brush 113 on one of the slip rings ioi is located, and the brush holders are held by springs 114 attached to the Rod 9o are attached, resiliently pressed towards the slip rings. The springs 114 are on a surface 115 of the rear end of the brush holder i io, and each The brush holder can be lifted out of connection with its slip ring if desired and pivoted 9o ° backwards, in which case the surface 115 on the spring 114 jumps by, leaving the brush holder out of contact with the slip ring can be. So you can quickly choose which of the demetallizing discs 34 41 etc. in the manner just described by the brush holder to the electrical To be connected to the power grid. The crossbar 9o consists of insulating material, and the electrical circuitry to each brush holder is through springs 114. The already mentioned capacitors 43, 53, 63 and the Resistors 30, 40, 5o etc. on the Insulating rod 9o attached, so that an appropriate, coherent union of these parts is ensured is. The resistors and capacitors are not shown in the figure. the Intermediate sleeves i i i are also made of insulating material, and the brush holders i io have insulating bushings that separate them from the shaft 83.

The roller 36 is provided with a gear wheel i2o (Fig. 4), which meshes with the gear wheel io6 on shaft g9, so that the demetallizing disks can be driven to roller 36 at a suitable speed. if the frame with the side levers 86, of which the demetallizing discs lifts, the gear wheel io6 automatically comes out of the gear wheel i2o, but intervenes again when the frame is in a position according to FIG is pivoted back.

The path of the paper dielectric 38 is shown in FIG. It is coming with its metallized surface in contact with roller 34, then overflows the roller 36, under the demetallizing discs 31, 41, etc. through and on over the roller 37. The screws 97 are adjusted so that the demetallizing Slices just touch the surface of the paper with the required pressure and the gear io6 sufficiently engages with the gear i2o. Another Adjustment is made using screws 79.

Demetallizing disks are usually required during operation lift off the paper for a moment so that the capacitors 33, 43 etc. are charged will. When the frame 86, 87 is pivoted back so that the demetallizing Slices touch the paper, the demetallization begins immediately and is, continued as described above.

The demetallizing disks are mounted on a swing frame and can therefore be lifted off the paper at the same time, because when they come into contact with the metallic surface of the paper before turning on the power of the Capacitor would and would not be shorted through the metal surface of the paper could be charged. Which under these circumstances only through the @N'iderstand going stream of the size of the example given above is alone and without the help of the capacitor unable to discharge and demetallize too cause. On the other hand, if you don't use a capacitor or just focus on the leaves natural capacity of the supply line, the resistance should be less than according to the present invention. Then the discharge would continue from the disks spread out and create a less precise and smooth metal-free line on the paper.

It turns out that the actual resistance and capacitance values in each individual case on the thickness of the metal coating and the throughput speed depend on the paper. The above values are given for the case that the paper in a known method of metallization in a vacuum from aluminum vapor Aluminum covering approximately 80 to 100 millimeters thick. A simple practical one Trying in any other case will suffice to get the best resistance and capacitance values to investigate. However, the present invention does not give satisfactory results on metal coverings of great thickness.

Claims (6)

PATENT CLAIMS: i. Device for the production of metal-free parts on metallized dielectric tapes for electrical capacitors having a Arrangement for receiving a feed roll with metallized dielectric strips as well as demetallizing contacts in the form of rotating disks on which the metallized Side of the dielectric is passed, and in connection with these contacts has other conductors in the form of rolls connected to the metallized side of the dielectric tape and connected to a source of electrical power, each through a current-limiting resistor with the demetallizing Contacts and is connected to the other conductors so that a voltage difference between the demetallizing contacts and the demetallizing side of the dielectric arises, characterized in that each demetallizing contact to a capacitor of suitable capacitance is connected in parallel and d-aß contact and capacitor fed from a circuit that has a current-limiting resistor of of such a size that it cancels the demetallizing discharge so that it cannot spread out randomly from the contact, and which still allows the flow of a Allowing sufficient current to run the capacitor during each interruption recharge between successive demetallizing discharges. 2. Apparatus according to claim i, characterized in that means for simultaneous Lifting the demetallizing contacts from the metallized surface of the paper are provided. 3. Device according to any one of the preceding claims, characterized characterized in that the demetallizing contacts from a series of each other consist of insulated disks and are mounted on a common shaft and that each disc is connected to a slip ring for the power supply and one Number of contact brushes rests on the slip rings. . 4. Device according to Claim 3, characterized in that each one or more of the contact brushes can be lifted off their slip ring. 5. Device according to claim 4, characterized in that the shaft which the demetallizing Discs carries, is mounted on a swing frame, which also carries the brushes, so that Frame and brushes are lifted from the dielectric depending on the desired demetallization can be. 6. Apparatus according to claim 5, characterized in that the Oscillating frame with devices for adjusting the pressure of the demetallizing Disks on the dielectric is provided.