DE4000779C2 - - Google Patents

Description

The invention relates to a method for centering and fixing an electrical capacitor in a prefabricated cup made of thermoplastic material, in which the capacitor, which is provided with end contact layers and power supply wires is inserted into the cup so that the power supply wires from an opening of the cup in the same direction protrude, and in which the cavities between the cup and Condenser filled with liquid, hardenable potting material be cured.

Such a method is known from DE-OS 37 05 868.

Capacitors in the sense of the invention are wound or layer capacitors, which are constructed from metallized plastic films are.

When casting wired capacitors in plastic Increasingly, the problem of fixation is not at stake during the casting and curing phase, but the centering problem in the foreground. It is about the customer required, extremely tight tolerances of the wire rope to ensure the external capacitor configuration. With the manufacturing methods used so far, the as Prerequisite for the use of automatic placement machines or Ro necessary tolerances can no longer be adhered to. The need for centering results on the one hand from the fact that the Capacitor to be used, as well as the cup, manufacturing are technically subject to a certain tolerance. To the other economically sensible production is only possible when capacitors of different capacitance, i.e. H. with various those volumes, in one and the same prefabricated cup  can be placed. Its volume is of course only from large volume of the different sized capacitors optimal filled out.

When solving the centering or fixing problems in general always make sure that the available Installation space of the cup by fixing or Centering elements (for example tabs or knobs) if possible is not downsized.

To solve this problem area was therefore in the DE-OS 37 05 868 proposed the condenser in the cup thermal deformation from outside through embossing to fix and center against the cup walls. This solution however, is still not entirely satisfactory because of the deformations of the cup on the finished condenser. Especially but is only a limited deformation depending on the cup wall thickness possible, which means that only a limited volume tolerance can be bridged.

From the Italian patent application 3550 A / 82 a Ver drive known for anchoring capacitive elements the at least a portion of the side walls of a housing after the inside of this housing until it touches the kapa citive element is plastically deformed. The deformation can be there with such extensive heating of the part to be deformed preceded area that the latter is plastically deformable. These deformations can lead to a power supply, for example guidewire be assigned symmetrically in pairs.

Furthermore, it is known from this patent application to which Power supply wires to provide bends related to the end faces of the capacitor in the longitudinal direction or in Cross direction over the end faces and, given if via recesses additionally present in the housing, the cause the bulges of the power supply lines to snap into place, a tight fit of the capacitive element in the housing  Have consequence. The disadvantage is the tolerance sensitivity, i. H. the tolerance that occurs between the cup, the winding and the wire can be greater than the dimension that can be absorbed by the wire elasticity.

In each of the procedures of the Italian patent application centering is done indirectly by connecting wires can be fixed by precisely guided clamps. Bent wires thus have an inaccurate centering of the component Episode. This error persists if partial reach the side walls of the housing up to the kapa cited element are deformed.

It is also known in capacitor technology and in DE-PS 25 20 130 described an insulating plastic layer by means of an HF induction heating device on parts of the Apply surface of a capacitor. The Capacitors in a container with whirled plastic powder introduced and there by means of an RF induction heater heating device. The alignment of the layers of the Capacitor relative to the field lines of the RF induction Heater has a desired distribution of the order wrapping material over the surfaces of the capacitors Episode.

From US-PS 42 42 717 is also a method similar to that known at the outset, but in which the front contact layers and the power supply wires only during insertion of the capacitor are pressed together in the cup. The actual electrical contact between the wires and the forehead contact layers is after insertion into the Mug made by electrically heating and using the wires the front contact layers are welded. It's about the lowest possible contact resistance between the capacitor and its connections while centering and fixing problems not be mentioned.

The object of the invention is a method of the beginning  Specify the type mentioned, in which the cup dimensions - independently of tolerance - fully used for the capacitor can and in which an exact centering of the capacitor in Mug, especially with regard to tight tolerances of the Wire exit to the condenser outer configuration, in simple Way is possible, in the same way as with the existing ones Automatic tape production is insertable.

To solve this problem, the method is as specified in the introduction Art according to the invention characterized in that the  Front contact layers and / or the power supply wires of the Condenser during insertion into the cup on the Melting temperature of the cup material are heated so that the material of the inner cup walls where it is heated Metal parts of the capacitor come into contact, melts and becomes soft, and the condenser when cooling in fixed in a centered position.

Advantageous refinements are set out in the subclaims.

The object of the method according to the invention and its advantages are illustrated by the following examples explained.

In the accompanying drawing shows

Fig. 1 shows a section through a high-frequency induction heating device and are arranged one in its field, located in the cup capacitor,

Fig. 2 is a side view of a field located in the Hf-cut capacitor,

Fig. 3 is a side view of the insertion process shown in several stages,

FIGS. 4 to Fig. 8 different configurations of the cup inside walls and various forms of power supply wires.

Fig. 1 shows a capacitor 1 with power supply wires 2 in a plastic cup 3. Corners 4 are formed on the bottom of the cup interior, in which the condenser 1 is centered and fixed. The cup with the capacitor is located between the induction plates 5 and 6 of an RF induction coil which generates a magnetic field which penetrates the cup and the capacitor and which is indicated in FIG. 1 by magnetic field lines 7 . The metal parts of the capacitor, that is to say its end contact layers, its current supply wires 2 and the metallizations of the plastic films, the coatings, heat up in the magnetic field of the inductor. It is important to ensure that the coatings in the interior of the capacitor are parallel to or in the direction of the field lines 7 and thus - in contrast to the relatively massive end contact layers and current supply wires 2 - heat up only slightly. The heated to the melting temperature of the cup material metal parts of the capacitor 1 are pressed into the softening corners 4 when inserted.

The intensity and the time of heating are - for a given frequency of the field - primarily dependent on the field strength in the inductor and on the cutting angle ( Fig. 2). The desired cutting angle can either be tilted by the capacitor 3 zen trated capacitor 1 in the inductor or the inductor for loading cher 3 with the capacitor 1 or its transport direction, it is sufficient. Fig. 2 shows a in the cup 3 Kon capacitor 1 similar to that shown in Fig. 1, with front contact layers 8 and 9th The arrow 10 indicates the direction of the Feldli lines, against which the condenser 1 located in the cup 3 is in an inclined position. The intersection angle is given by the angle between the front contact layer 8 or 9 and the field lines. In contrast to FIG. 1, the capacitor 1 is not yet completely inserted into the cup 3 in FIG. 2. The lower corners of the front contact layers 8 and 9 have not, as provided, been pressed into the corners 4 formed on the cup base.

An advantage of the inductive heating of the forehead contact layers 8 or 9 or the power supply wires 2 is that the heating is contactless with a precisely measured amount of heat either in very short times (<0.1 sec) or continuously in or outside the cup 3 can be done. Depending on the design of the inductor, this can result in heating during the insertion process in one or more assembly stations, but also during the upstream or intermediate transport routes.

Fig. 3 shows five snapshots of the process of insertion of the capacitor 1 into the cup 3, while the capacitor 1 is transported by a hairpin inductor. The associated RF generator works, for example, with a frequency of 2.1 MHz. With today's usual cycle times of less than 1 sec for the intermittent movement of the production line, it is often favorable for the condenser 1 to be distributed over several assembly stations.

Through the described fixing and centering processes the previously available automatic beaker almost unchanged be used. This can be done through a convenient arrangement the cup automat also inductors of several automats from one central RF generator.

The desired heating of the front contact layers 8 and 9 and / or the power supply wires 2 of the capacitor 1 can be done not only by an HF induction heating device, but also, for example, by electrically heated wire clamping jaws. It should be noted that the front contact layers 8 and 9 and the wire ends are heated up relatively slowly.

The shape of the cup inner walls essentially depends on whether one wants to achieve anchoring through the end contact layers 8 or 9 and / or the correspondingly shaped Stromzuführungsdräh te 2 . So with a normally wired condenser manufacturing today, anchoring can be done either by ver reinforced cup corners 4 ( Fig. 1 and Fig. 2) or on internal cups. It can be achieved by obliquely molded inner cup corners 4 a certain self-centering of the capacitor in loading cher during the insertion process. It is he inventively also possible to produce a centered in a cup 3 capacitor 1 in that about Stirnkontaktflä surfaces of the capacitor beyond shaped current supply wires 2 is heated and the heated by heat conduction parts of the power supply wires 2 inside walls cups are pressed into the. Anchoring via shaped connecting wires has the advantage of being easier to carry out since less plastic material that has been softened has to be displaced.

Fig. 4, 5, 6 and 7 show various embodiments of the Be cherinnenwände and various wire shapes. The connecting wires can be shaped in such a way that either guiding and fi xing can take place on the cup narrow sides, long sides, bottom or corners. The cup walls or cup bottoms can be shaped in such a way that the capacitor is guided or centered exactly relative to the cup external configuration when it is inserted, possibly even before it is heated.

The capacitors in FIGS. 1 to 7 are film capacitors. In addition, axially wired wound capacitors, as shown in FIG. 8, can also be used in cups. Fig. 8 accordingly shows a possible shape of the cup and of the power supply wires.

Experiments were carried out to test the method according to the invention performed with a hairpin inductor. Of course Depending on the application, the shape of the inductor and the generator frequency vary. As a material for art fabric cups basically come in condenser technology usual thermoplastics in question, i.e. polypropylene, polyester, Polycarbonate, polysulfone, but also the modern heat-resistant plastics such as polyphenylene sulfide. At It is cups made of plastics with higher melting temperatures cheap, the cup with or without condenser at 100 to 120 ° C preheat, for example by means of warm air, so that Stromzu guide wires and face contact layers with a lower Amount of heat applied to cups that have not been preheated have to.

Claims (8)

1. A method for centering and fixing an electrical capacitor ( 1 ) in a prefabricated cup ( 3 ) made of thermoplastic material, in which the capacitor ( 1 ), which is provided with end contact layers ( 8 , 9 ) and current supply wires ( 2 ), in the cup ( 3 ) is inserted so that the power supply wires ( 2 ) protrude from an opening in the cup ( 3 ) in the same direction, and in which the cavities between the cup ( 3 ) and the capacitor ( 1 ) are filled with liquid, hardenable potting material, that is cured, characterized in that the end contact layers ( 8 , 9 ) and / or the power supply wires ( 2 ) of the capacitor ( 1 ) are heated to the melting temperature of the cup material during insertion into the cup ( 3 ), so that the material of the Inner cup walls where it comes into contact with the heated metal parts of the condenser ( 1 ), melts and becomes soft, and the condenser ( 1 ) fixed in a centered position during cooling. 2. The method according to claim 1, characterized in that the end contact layers ( 8, 9 ) and / or the power supply wires ( 2 ) of the capacitor ( 1 ) are heated by means of an RF induction heating device. 3. The method according to claim 1, characterized in that the end contact layers ( 8, 9 ) and / or the power supply wires ( 2 ) of the capacitor ( 1 ) are heated by electrically heated wire jaws. 4. The method according to any one of claims 1 to 3, characterized in that the longitudinal edges of the end contact layers ( 8, 9 ) are anchored self-centering in obliquely molded inner cup corners ( 4 ). 5. The method according to any one of claims 1 to 4, characterized in that only over the front contact surfaces of the capacitor ( 1 ) or bent from them bent parts of the power supply wires ( 2 ) heated and the parts heated by heat conduction of the power supply wires ( 2 ), which at Insert process into the inside of the cup into which the inside of the cup is pressed. 6. The method according to any one of claims 1 to 5, characterized, that the heating during the insertion process in one or several assembly stations. 7. The method according to claim 6, characterized, that the heating even during the upstream or intermediate Transport routes between the assembly stations. 8. The method according to any one of claims 1 to 7, characterized in that cups ( 3 ) made of high-melting plastic are preferably preheated to 100 to 120 ° C.