DE1104066B - Process for the production of metal coatings on insulating strips for MP capacitors - Google Patents

Description

Process for the production of metal coverings on insulating strips for MP capacitors For the production of MP capacitor windings one uses as the dielectric carrying the metal covering is an insulating tape on which a very thin metal layer made of z. B. zinc or aluminum adheres firmly in a vacuum through condensation is precipitated from the vapor phase. As is well known, these metal coverings must be very thin in order to allow electrical healing of defects at all.

In zinc has now been found to be disadvantageous that z. B. on Paper tapes applied zinc layers of such low thickness against moisture are very sensitive and are therefore easily prone to corrosion, if not completely special manufacturing measures for the storage and processing of these zinc-plated Papers this corrosion formation is inhibited, which extends the life of the capacitor can greatly shorten.

In the case of aluminum, on the other hand, the main manufacturing difficulties are in that the vapor deposition of this metal on thin strips of insulating material for the purpose MP capacitor production requires a relatively high vacuum and very high evaporator furnace temperatures required in the evaporation system. Both demands are conditional in their overall effect a considerable technical effort in order to even such, with regard to their temperature and mechanical strength of very sensitive organic materials such as paper or plastic film to be able to metallize.

It is also disadvantageous to use zinc and aluminum to be seen as a coating agent for MP capacitors that both metals only in a vacuum can be vapor-deposited on insulating strips, so that in a mass production operational disruptions that do occur, such as B. Tearing off the to be metallized Paper tape in the bell jar or not winding the Insulation sheet after metallization, inevitably to considerable underperformance can lead to metallized insulating tape.

Among other things, to avoid the aforementioned disadvantages is also already attempts have been made to remove metal coverings by thermal decomposition of metal carbonyls, such as nickel tetracarbonyl. But this material has, among other things three properties that can make its technical application very difficult. Once is that the relatively high price of nickel carbonyl and then the unpleasant one from a health point of view Effects of inhaling air containing nickel carbonyl as well as the deflagration or Tendency to explode with higher percentage nickel carbonyl vapors enriched with oxygen.

According to the invention, therefore, to avoid the aforementioned disadvantages the use of nickel tetracarbonyl, the escape in vapor form from the metallization equipment thereby practically one hundred percent avoided that of the known per se Metallization process of any insulating strips in the metallization zone unused and therefore undecomposed nickel carbonyl vapor due to strong cooling condensed and fed back to the evaporator in a circuit. It will the carrier gas is freed from the carbon oxide formed during the decomposition, that the gas mixture is passed in a known manner over heated nickel. That Nickel carbonyl recovered in liquid form and purified from foreign gases becomes so continuously fed back to the evaporator, from which it is via a large area evaporation, which takes place almost at room temperature, again the actual metallization zone is fed.

In this way it has been possible to achieve an optimally economical and Reliable manufacturing process for the thermal decomposition of nickel carbonyl and to achieve the metallization of insulating tapes made possible by this.

In terms of technical details that are important for the metallization itself Among other things, the following should be mentioned in order to avoid that in the metallization zone Insulating tape heated to 80 ° C and more releases moisture to a greater extent - this will be the case with paper tapes in particular - the insulation strips will be predried before entering the metallization zone and also in or Provided on both sides with a protective layer that is as impermeable to water vapor as possible. It has shown that the latter measure the application of a flawless metal layer is made much easier.

The concentration of the not yet thermally decomposed nickel carbonyl vapor in the metallization zone, the temperature of the insulating strip to be metallized as well as the speed of passage of this strip and the length of the metallization zone in the running direction of the tape are coordinated so that in the unit of time produced the greatest possible length of perfectly metallized insulating tape can be. It is important that the metallized covering is practically free of is unwanted foreign matter, i.e. it consists exclusively of nickel, and is solid adheres to the respective insulating material.

Claims (3)

PATENT ANSYRUCHE: 1. Process for the production of metal coverings Insulating tapes for MP capacitors through thermal decomposition of metal compounds, preferably from nickel tetracarbonyl, from the vapor phase in the presence of a carrier gas, characterized in that the nickel carbonyl vapor which is not decomposed in the metallization zone prevented by freezing from escaping to the outside air and recirculated is fed to the evaporator. 2. The method according to claim 1, "characterized in that that the carrier gas, preferably nitrogen, also in a circuit within the metallization equipment is used. 3. The method according to claims 1 and 2, characterized in that the entire metallization apparatus including the insulating tape rolls is sealed against the outside atmosphere with a slight overpressure. Considered publications: German Patent Nos. 755 073, 900 971, 918 882; French Patent No. 881 146; British Patent No. 620 405.