EP0650537B1 - Metallisation of plastics - Google Patents

Abstract

The descrition relates to a process for metallising plastics in which the plastic surface is pretreated first in a solution of swelling agent containing compounds of general formula R1-(O-(CH2)n)m-OCO-R2 in which R1, R2 = CkH2k+1, n = 2 or 3 and k, m = 1, 2, 3 or 4, and then in a solution containing permanganate ions. In addition, there is an improved process for coating especially polymers with metal which provides better adhesion of the metal to the polymer substrate and a greater stability of the metal-polymer bond and reduced noble metal consumption in the catalysis/activation of the polymer surface.

Description

The invention relates to a method for metallization of plastics.

Polymers have been coated with metal for many years Mistake. The applications of the coated with metal Polymers can be divided into two groups: a decorative and a functional. After these Applications also differ in requirements on the applied metal layers. One for decorative purposes metallized plastic should look like solid metal if possible: a shiny one or have a satin surface and be corrosion resistant.

Functional layers on polymers are made in very different areas of application: Example as a circuit board (circuit board) or for Shielding against electromagnetic radiation.

In principle, the metal application can be done by spraying, Steaming or other vacuum techniques (sputtering) or by painting or flame spraying.

The electroplating metallization of plastics is done by various methods. Usually is the substrate to be coated by a chemical pretreatment process roughened to a sufficient adhesive strength of the metal layer too to reach. In some cases, they are also sent to certain Treatment solutions adapted to the materials used, that do not contain chemicals that Roughen the polymer surface visibly. With thermal or corrosion is the liability of the pretreated substrate surfaces in this way generally not sufficient.

Processes for pretreating plastics with roughening the substrate to produce a mechanical interlocking of the metal coating with the polymer have been known to the person skilled in the art for a long time. For this purpose, aqueous chromic acid, chromium / sulfuric acid solutions or mixtures thereof with phosphoric acid, sulfuric acid and permanganate solutions are typically used as etching solutions. Chromium / sulfuric acid solutions in particular have been used for some time for the metallization of acrylonitrile / butadiene / styrene polymer (ABS) substrates (K. Stoeckert, in: Kunststoffe 55 (1965) 857). Improved processes take advantage of the increased roughening effect that is obtained if the plastic is treated in a solution of an organic solvent before the etching step. In this sense, various compounds or mixtures of organic compounds are used as swelling agents. Typical representatives are glycol ethers, such as diethylene glycol dimethyl ether (DE-39 22 477 A1, US Pat. No. 4,775,557), ethylene glycol non-ethyl ether (FR-A-22 22 459), N-methylpyrrolidone, dimethylformamide (DE-38 07 618 A1), dimethyl sulfoxide and propylene carbonate ( DE-AS 22 22 941).

Other swelling agents for use before the etching step are mentioned in EP 0 309 243 A1: According to this, ethylene glycol ether carboxylates can also be used in conjunction with a surface-active compound and, if appropriate, additionally with compounds having the general formula CH ₃ - (OH) CH-CH ₂ (OC ₃ H ₆ ) _p -R ⁴ , with R ⁴ = lower alkyl and p = low integer. Nickel and copper layers are deposited electrolessly as metal layers on polycarbonates, polysulphones, polyesters and ABS resins. The shielding of electromagnetic radiation is specified as the field of application.

DE-41 08 461 C1 describes swelling agents for PCB polymers before an alkaline-oxidative Etching step described, containing carbonic acid esters, for example propylene carbonate and ethylene carbonate.

These carbonic acid esters are well suited for swelling of inner walls of boreholes in Epoxy resin material, but not satisfactory for surface treatment when used for Shielding against electromagnetic radiation, using plastics that are difficult to metallize are, for example polycarbonates, ABS copolymers with polycarbonates or polyphenylene oxide.

The most commonly used method uses the Generation of the roughening of a catalytic seeding the plastic surface, which consists, for example, Palladium particles from a palladium colloid to deposit on the polymer surface. Subsequently can be made of electroless copper or Nickel baths creates a firmly adhering metal layer become. Usually only small layer thicknesses are used formed, which then to generate the actual functional layer on electrolytic Walk with suitable metal baths to the desired one Layer thickness can be reinforced.

Most of the plastics metallized with this process are the already mentioned ABS material, Polypropylene, polyphenylene oxide, epoxy resins, polyimide, Polyamide and others. For certain applications also polycarbonate resins or mixtures thereof other polymers used.

For shielding against electromagnetic radiation are naturally particularly suitable such metals that have a high electrical conductivity. copper united except for a very low electrical Resistance also some other preferred Characteristics. Therefore, many are de-energized copper deposition systems well known. With a Copper layer thickness from one to a few micrometers a sufficient shielding effect can already be achieved of more than 40dB. However, copper is not very stable against oxidation respectively Corrosion and oxidized copper or copper salts have no shielding effect: the copper surface must therefore be protected against corrosion. This can for example with a suitable varnish, however, corrosion protection with a accordingly resistant metal, especially since this is still there to increase electrical conductivity contributes. Such layer sequences of copper and one other metal (e.g. nickel or cobalt) also described for a long time and in use (US-PS 4,514,586 or U.S. Patent 4,751,110). The system of Metal layers on polymers to shield However, electromagnetic radiation can still be improve significantly.

According to US Pat. No. 4,514,586, the Plastic parts have an inner and an outer surface on, with at least one of the surfaces pore-free, electrolessly deposited copper layer with a layer thickness of at least 0.125 µm and above an electrolessly deposited nickel layer with a Layer thickness of at least 0.125 microns is applied. For the pretreatment of the plastics to be metallized becomes the toxic chromium / sulfuric acid process specified.

The adhesive strength of the metal coating is in the most cases after the so-called tape test judged. For this, a one-sided self-adhesive Adhesive tape on the metallized surface of the Plastic part pressed on and then with strong pull demolished again. With sufficient The metal layer must not adhere to any metal particles stick to the tape.

Good adhesion of the metal coating to the mentioned materials with the known methods only with a solution containing chromium (VI) ions as Etching medium enables, in this case, a sufficient chemical attack on the polymer surface he follows.

A major disadvantage of the methods described consists of solutions containing chromic acid Use etching medium as these solutions as aerosols are carcinogenic. In addition, because of the high Toxicity of chromium (VI) ions very low limit values required in the wastewater. Therefore, a very high effort be operated during wastewater treatment. this makes possible much less effort for the Occupational safety and wastewater treatment.

Another disadvantage of chromic acid is its property as a strong catalyst poison in the electroless To act metallization. Already traces of Chromium (VI) ions in the activation solution or the electroless baths lead to one significantly deteriorated occupancy of the plastic surface with metal. For this reason, the Chromium (VI) residues from the polymer surfaces completely be rinsed off. On the one hand, this leads to a very high flushing water requirement and secondly too long Procedural consequences as there are many rinsing steps in the process need to be integrated. For these reasons, there is the desire to add chromic acid through less toxic substances replace.

The invention is therefore based on the problem these known disadvantages of the prior art methods to avoid technology and that Optimize metallization processes.

This problem is solved by the method according to claim 1. Preferred embodiments of the invention are described in the subclaims.

R¹, R² = C_kH_2k+1 und

n = 2 oder 3,

k, m = 1, 2, 3 oder 4 bedeuten,

beschrieben.The organic compounds according to the invention are used as swelling agents, preferably in an aqueous swelling solution, in a treatment step before an etching treatment in order to prepare the polymer surface for the etching attack. The compounds are represented by the general formula R ¹ - (O- (CH ₂ ) _n ) _m -OCO-R ² , in which

R ¹ , R ² = C _k H _{2k + 1} and

n = 2 or 3,

k, m = 1, 2, 3 or 4,

described.

After the pretreatment with the swelling solution, it will The substrate is subjected to the etching process in a permanganate solution.

Beschichten der Kunststoffteile mit Edelmetallkeimen, um die Kunststoffteile zur nachfolgenden stromlosen Metallisierung zu aktivieren,

stromlos Abscheiden einer ersten, mit dem Kunststoff in Kontakt stehenden Schicht aus Metallen, ausgewählt aus der Gruppe, bestehend aus Nickel, Kobalt, Palladium, Gold und deren Legierungen,

darauf stromlos Abscheiden einer zweiten Metallschicht aus Kupfer,

auf die zweite Schicht stromlos Abscheiden mindestens einer dritten Schicht aus Metallen, ausgewählt aus der Gruppe, bestehend aus Nickel, Kobalt, Palladium, Gold und deren Legierungen.

The following process steps are then carried out:

Coating the plastic parts with noble metal nuclei in order to activate the plastic parts for subsequent electroless metallization,

electrolessly depositing a first layer of metals in contact with the plastic, selected from the group consisting of nickel, cobalt, palladium, gold and their alloys,

then electrolessly deposit a second metal layer made of copper,

Electrolessly deposit at least a third layer of metals on the second layer, selected from the group consisting of nickel, cobalt, palladium, gold and their alloys.

A particular advantage of the process is that that instead of the usual etching solutions, the contain toxic chromic acid, less toxic and that Metallization process not disruptive etching media, such as for example, solutions containing permanganate become.

Another advantage of the method according to the invention consists in the more uniform roughening of the substrate than with the conventional methods. In particular, such as the ABS copolymers, individual polymer areas through the Etching process detached from the polymer composite. At the Rather, the method according to the invention finds one more uniform roughening of the polymer surface with less etching depth instead. This will make it smoother Appearance of the surface achieved.

The organic compounds ethylene glycol methyl ether acetate (CH ₃ O-CH ₂ CH ₂ O-COCH ₃ ), diethylene glycol ethyl ether acetate (C ₂ H ₅ O-CH ₂ CH ₂ O-CH ₂ CH ₂ O-COCH ₃ ) and propylene glycol methyl ether acetate (CH ₃ O-CH ₂ CH ₂ CH ₂ O-COCH ₃ ) proved to be particularly suitable. The concentrations of these compounds can be set between about 5 vol.% And 95 vol.%, If necessary in water. In practice, a preferred range of 20% to 80% by volume has proven to be particularly suitable. In addition, these compounds can also be used in mixtures with one another or with other compounds.

The effect of these compounds and their mixtures consists in the attack of the following Etching solution is intensified. However, it was also found that on the plastic surface by the Exposure to the source solution already produces a roughness is only in the subsequent etching solution is reinforced.

In addition to the organic according to the invention Connections become the source solutions Solving other organic compounds, such as for example, lower alcohols or glycol ethers added. Possible compounds are methanol, ethanol, n- and i-propanol, ethylene glycol, propylene glycol and Diethylene glycol monoethyl and butyl ether. Furthermore can the source attack by alkali hydroxide, ammonia or quaternary ammonium bases. Indeed it should be noted that this results in a faster Aging of the solution due to increased absorption of carbon dioxide from the air to form the appropriate Carbonate takes place, so that gradually Salting of the swelling solution results. This happens all the more faster the higher the working temperature.

To ensure adequate wetting of the plastic surfaces can be achieved with the source solution Treatment solutions also wetting agents or others surface-active compounds are added.

The temperature of the treatment solution can be any Values between room temperature and the boiling point of the Accept solution. In any case, it is one on the special composition of the source solution, the process parameters the subsequent process stages and the temperature of the substrate to be coated adjust. Mostly, however, one is above room temperature lying temperature selected, preferably 40 to 75 ° C. The treatment time is the same depending on the parameters mentioned chosen so that sufficient liability of the Metal coating reached on the polymer surface becomes.

The swelling agent treatment is usually in the Dipping process carried out. However, it is also possible apply other methods by which the Plastic surfaces in contact with the swelling solution to be brought. These include spraying, gushing, Injecting the solution or other types of orders.

Following the swelling agent treatment usually rinsed with water. Then follows the etching process with a permanganate-containing Solution, the solution usually also by Diving into contact with the plastic surface but there are other ways of contacting, such as spraying, Swell or splash, possible.

The most used solutions contain potassium and / or Sodium permanganate. Sodium permanganate then used when concentrations of permanganate should be set that are higher than about 70 g / l are. In this case the concentration exceeds of the potassium salt, its solubility at room temperature. However, it is also conceivable that other salts of permanganate can be used. Mostly these are Salts used in alkaline solution. The pH these solutions can, for example, with baking soda or Potassium hydroxide solution set to a value greater than 13 become. The practical area for the above Permanganate concentrations range up to about 250 g / l.

In addition to the main components, these form Solutions when standing, but especially when Processing of plastic parts by implementation or Decomposition of the permanganate manganate compounds. In In this case, the manganate that has formed must be added again Permanganate can be reoxidized. This can be done by adding of strong oxidizing agents such as Sodium peroxodisulfate, sodium hypochlorite or others Salting takes place or, much more elegantly, through electrolytic regeneration in which the manganate ions oxidized to permanganate at an inert anode become.

In addition to these compounds, the etching solutions are salts to stabilize the pH of the solution such as Phosphates and for improved wetting surface-active substances on the plastic surface admitted. In this case, mostly come because of their higher chemical resistance to oxidation Fluorosurfactants used.

The temperature of these solutions is preferably above 60 ° C selected, but depending on the remaining process parameters and the selected one Plastic also set lower temperatures become. Treatment times are usually between 1 and 20 minutes set. Also in this Case applies that the optimal treatment time of the Process parameters of the entire process and the Type of polymer depends. Most times are preferred between 2 and 6 minutes.

After creating the roughness on the polymer surface the substrate is generally coated with a reducing agent treated to residues of the oxidizing solution and adhering reaction products such as Remove manganese dioxide from the surface. Acidic solutions are used for this. Mostly Hydrogen peroxide, hydrazine or hydrazine salt, hydroxylammonium salts, Glyoxal, oxalic acid or others Solutions containing compounds used.

Then another treatment in aqueous Solutions of conditioning agents are made that adequate adsorption of the following on the Plastic surface produced catalytic germs enable. For this purpose, polymeric quaternaries are usually used Connections used. After conditioning the plastic surface is activated with Precious metal none. In the commonly used Solutions become palladium as a catalytic metal used. It can either be a hydrochloric acid Palladium colloid or a complex compound of Palladium can be used. Other options are but also known, such as a two-stage Procedure in which the plastic first in a hydrochloric acid tin (II) chloride solution is treated and then also in one hydrochloric acid palladium chloride solution.

When using palladium chloride with tin (II) chloride is the protective colloid in a commercially available Accelerator solution removed again, at Using a palladium complex compound becomes a Reduction of the adsorbed on the substrate surface Palladium complexes to palladium nuclei with hydrogen boron compounds performed.

When using electroless copper baths are usually with Ethylenediaminetetraacetic acid, ethylenediaminetetrakis (progan-2-ol) or tartrate complex solutions used. Formaldehyde is used as the reducing agent. The pH is generally above 1. Depending on the thickness of the metal layer to be deposited Temperatures set between room temperature and 75 ° C. Nickel baths mostly contain hypophosphite Reducing agent. Therefore, they contain from these Deposited layers of baths depending on the process conditions up to 13% phosphorus. The pH of these solutions can be set between 4 and 9. Corresponding the temperature is chosen between Room temperature and 95 ° C can be. For the metallization of plastics, however, is one possible low temperature chosen to the plastic part not to harm. As complexing agents are in These baths mostly use hydroxycarboxylic acids. All of these baths also have stabilizers, shine-forming or ductility-increasing additives admitted. The treatment times depend on the desired layer thickness.

Depending on the intended use of the metallized Plastic parts are made according to the above Process sequence then different metals applied by electroless or electrolytic means.

According to the invention consist of those applied to the substrate Metal layers of at least three layers, whereby - after pretreatment with the above-described swelling, etching and activation solutions - the first layer a metal layer of the metals nickel, Is cobalt, palladium, gold or their alloys and the metals from an electroless plating bath to be deposited, the second layer is de-energized deposited copper and the third layer a metal layer of the metals nickel, cobalt, Is palladium, gold or their alloys and the Metals from an electroless plating bath be deposited.

The advantage of the method according to the invention is in that a very high liability of the deposited Metal layers also immediately after Metallization is achieved. The procedure is in Contrary to known methods according to the prior art Technology without problems for plastics such as polycarbonate or its mixtures with others Plastics, such as ABS, or others difficult to metallize polymers applicable.

The first metal layer can be in a special Embodiment as a thin, highly adhesive layer be trained on in an economic Process with higher deposition speed thicker metal layers are deposited.

Critical problems in the metallization of Polymer surfaces are the adhesive strength of the Metal layer on the surface that Environmental friendliness of the process (type of used Chemicals and chemical consumption) and the cost of the procedure. Between these parameters compromises can be found: an environmentally friendly and little aggressive pretreatment of the polymer surface often attracts a longer dwell time Treatment baths after themselves or worsens the Quality of the products, for example the Adhesion strength of the metal on the surface. So can the exchange of chromic acid or chromic sulfuric acid in the first pretreatment step Plastic surface against pretreatment with a source system and alkaline permanganate solution although the range of the procedure with regard to significantly expand metallizing plastics. This exchange does not avoid that either safe use of solution with chromium compounds in oxidation state + VI and replaces it against the harmless permanganate solutions. Straight the higher bandwidth brings with some Plastics a lower adhesive strength of the electroless deposited metal on the plastic surface with yourself.

It has been found that the conventional electroless metallization of polymeric materials for shielding against electromagnetic radiation is significantly improved if there is a layer of nickel or a similar metal under the copper layer as the first metal layer. This layer prevents a reaction of the polymer with the copper layer or of solvent or electrolytes still diffused into the polymer with the copper layer, drastically increases the adhesive strength of the metal layers on the plastic surface and allows the surfaces to be activated / catalyzed with smaller amounts of noble metal. The following overview compares some values of the adhesive strength of the metal on plastic surfaces with a first nickel layer of a sole copper layer (the metallization processes are explained in more detail in the examples of this invention). The peel tests are carried out with an Instron tensile testing machine. Plastic grade copper alone Nickel / copper Lexan BE2130 0.74 N / mm 1.1-1.5 N / mm Bayblend FR1441 0.25 N / mm 0.80 N / mm Pulse 1725 0.45N / mm 0.47 N / mm FR4 0.91 N / mm 1, 4 2 N / mm

Nickel layers have been used for the purpose described with phosphorus or boron as an alloy component proven suitable. Below is one such Base metallization electroless applied in copper one to achieve sufficient Shielding effect necessary layer thickness. The shielding effect should be 20dB in the shielding Frequency range (10 kHz to 1 GHz) at least exceed. Then the copper layer with another electrolessly deposited metal layer (Nickel, cobalt, palladium, gold or alloys thereof) protected against corrosion. The entire So the procedure is, first, the Plastic surface for the metallization to pre-treat, then to de-energize To activate metal deposition and then a layer made of nickel, cobalt, palladium, gold or one Electrolessly deposit alloy from these metals, then copper in one to achieve the Shielding necessary thickness and then preferably from the same electroless plating bath like in the first metallization step another Deposit metal layer as corrosion protection.

For decorative purposes, after applying the first electroless metal layer a the Appropriate layer sequence of metals deposited on the plastic surface (copper, Nickel, chrome, tin, silver, palladium, gold or Alloys such as brass).

The following examples are intended to illustrate the invention:

Example 1:

A molded part made of the plastic BAYBLEND, brand from Bayer AG, (polycarbonate / ABS blend) was metallized in accordance with the following procedure: 1. swell 10 min 4 0 ° C 2nd Etching in alkaline permanganate solution 10 min 7 0 ° C 3rd Hot rinse 1 min 5 0 ° C 4th To reduce 3 min 2 5 ° C 5. Pre-dive 1 min 2 5 ° C 6. Activate 3 min 3 5 ° C 7. To reduce 5 min 2 5 ° C 8th. Electroless copper plating 20 min 4 5 ° C

Between all successive process stages, except between 2nd and 3rd, 3rd and 4th and 5th and 6th, was rinsed.

The swelling agent contained 70% by volume of diethylene glycol ethyl ether acetate in water. The permanganate solution had the following composition:
100 g / l NaMnO ₄
15 g / l Na ₂ MnO ₄
20 g / l NaOH.

The electroless copper bath contained formaldehyde as Reducing agent. As a complexing agent Ethylenediaminetetrakis (propan-2-ol) used.

Good adhesion was obtained after the tape test the electrolessly deposited copper layer on the Base material.

Examples 2 and 3:

The same result as in Example 1 was obtained if instead of diethylene glycol ethyl ether acetate 50% by volume solution of ethylene glycol methyl ether acetate was used. In this case the Plastic PULSE, brand of Dow Chemicals, Inc., (also a blend of polycarbonate and ABS) be metallized with adhesive.

Examples 4 and 5:

The same result as in Example 1 was obtained if as a swelling agent a 50 vol.% or 70 vol.% Solution of diethylene glycol ethyl ether acetate and 5 Vol.% N-propanol was used. In both cases became a permanent copper plating of the plastics BAYBLEND, PULSE and LEXAN, brand for one Polycarbonate from General Electric Plastics, reached.

Comparative Examples 6 to 9:

When using a swelling solution which contained diethylene glycol dimethyl ether as a 68% by volume solution in water instead of the organic solvents according to the invention, plastic parts made from BAYBLEND could not be metallized with adhesive. The following treatment times were chosen: Experiment no. Swelling agent Permanganate- Treatment time 6. 3 min 6 min 7. 3 min 15 minutes 8th. 10 min 6 min 9. 10 min 15 minutes

The copper layer was tested in all of the tapes Cases detached from the plastic surface.

Examples 10-21:

In further experiments, a pre-coppering step with a low deposition temperature, which was specially adapted to the plastic surface, was inserted before the electroless copper plating in order to achieve better adhesion of the metal coating to the substrate surface. The following procedure was used: 1. swell conditions see below 2nd Etching in alkaline permanganate solution 6 min 70 ° C 3rd Hot rinse 1 min 50 ° C 4th To reduce 2 min 25 ° C 5. Pre-dive 1 min 25 ° C 6. Activate 5 min 35 ° C 7. To reduce 5 min 25 ° C 8th. Electroless pre-copper plating 5 min 30 ° C 9. Electroless copper plating 20 min 45 ° C 10th Enable copper 1 min 25 ° C 11. Electroless nickel plating 10 min 40 ° C

Between all process stages, except between 2nd and 3rd, 3rd and 4th as well as 5th and 6th is rinsed.

The permanganate solution had the following composition: 140 g / l NaMnO ₄
15 g / l Na ₂ MnO ₄
40 g / l NaOH.

The electroless nickel bath contained as a reducing agent Sodium hypophosphite and worked at a pH from 8 to 8.5.

A mixture of 68% by volume of propylene glycol methyl ether acetate, 25% by volume of i-propylglycol and 7% by volume of water was used to prepare the swelling solutions. A 30, 50 or 70% by volume solution in water was prepared from this concentrate. The results are shown in Tables 1 and 2 (the first symbol indicates the result of the tape test for BAYBLEND, the second for PULSE ("+": adhesive; "-": non-adhesive)): (Swelling agent temperature 45 ° C) Swelling agent concentration Treatment time in the swelling agent 50 vol.% 70 vol.% 2 min - / - - / - 4 min - / - +/- 6 min - / + +/- (Swelling agent temperature 70 ° C) Swelling agent concentration Treatment time in the swelling agent 50 vol.% 70 vol.% 2 min +/- - / - 4 min +/- - / - 6 min + / + - / -

Example 22:

The conditions of the aforementioned process were repeated with the following parameters for the swelling agent treatment: Treatment time 4 min temperature 45 ° C concentration 7 0 V o 1. % of the concentrate

Instead of the electroless pre-copper plating bath, a alkaline nickel bath with hypophosphite as Reducing agents used. They became the same Results like with an electroless copper bath receive.

Example 23:

To clean the plastic surface, the Parts before the metallization treatment subjected to alkaline degreasing. For this, a alkaline wetting agent solution used at 60 ° C. The Treatment time was 9 minutes. Through the The plastic parts were pretreated by Contaminants, such as release agents, from injection molding exempted. It was a very good liability of the Metal coating found on the metal surface.

Example 24:

A housing part made of plastic Acrylonitrile / butadiene / styrene (ABS) has been injected was in a 360g / l solution for ten minutes Pretreated chromic acid and 360 g / l sulfuric acid, rinsed with a solution of 80 g / l sodium sulfite 'detoxifies', then with a solution of 300 g / l Sodium chloride and 10 g / l hydrochloric acid treated and in a solution of 8.8 g / l tin (II) chloride, 11.25 g / l Hydrochloric acid and 0.15 g / l palladium chloride activated. After removing the protective colloid with a solution from 90 g / l citric acid and 10 g / l oxalic acid chemically reductive for five minutes at 40 ° C from one commercial bathroom metallized, which is an alloy farewell from nickel and phosphorus with one Phosphorus content of 5% and one Deposition speed of about 4 µm / h. Then a reductively separating bath deposited on a quadrol base at 45 ° C copper. In 15 Minutes became a layer thickness of about 1.0 to 1.2µm achieved. This copper layer was in the same Nickel bath, as previously described, with a 1µm thick nickel layer and so against corrosion protected.

Example 25:

A plastic molded part made from Lexan BE2130 was added Room temperature for five minutes in a well that consisted of 15% of a diglycol ether in water, and after rinsing in a solution of 140 g / l Permanganate and 50 g / l sodium hydroxide at 65 ° C in 10 Minutes pretreated. That on the surface Manganese oxide was then deposited by a solution removed from hydrogen peroxide and sulfuric acid. After rinsing and pre-immersion in an acid Surfactant solution was made using an ionic activator system with 70 ppm palladium content at 45 ° C and pH = 11.0 in activated five minutes and the palladium ions after Rinse through an alkaline solution of 5 g / l Sodium borohydride reduced. Then - as in Example 24 described - first nickel, then copper and then deposited nickel again. For comparison became the first nickel layer in some samples deposited. The adhesive strength of some such Layer systems were described in the Overview listed.

Example 26:

As example 25. Instead of the plastic Lexan was an epoxy resin FR4 (flame-resistant, glass fiber reinforced laminate, supplier for example Ciba Geigy AG), which is normally used for Manufacture of printed circuit boards in electronics Is used. It could be one in the peel test Adhesion strength of the metal on the polymer surface of 1.42 N / mm can be determined compared to a Adhesive strength of only 0.91 N / mm if after the same Process copper directly onto the polymer surface had been brought.

Claims (5)

1. Method of coating plastics material parts with metals, more especially for shielding from electromagnetic radiation by at least one of the deposited metal layers, having the method steps:

   a. swelling with a swelling solution containing organic compounds of the general formula R¹-(O-(CH₂)_n)_m-OCO-R², wherein

   R¹, R² = C_kH_2k+1,

   n = 2 or 3, and

   k, m = 1, 2, 3 or 4,

   b. etching with a solution containing permanganate ions,

   c. subsequently coating the plastics material parts with precious metal powders, in order to activate the plastics material parts for the subsequent currentless metallisation,

   d. currentlessly depositing a first layer, which is in contact with the plastics material and formed from metals selected from the group consisting of nickel, cobalt, palladium, gold and their alloys,

   e. then currentlessly depositing a second metal layer formed from copper, and

   f. currentlessly depositing on the second layer at least a third layer formed from metals selected from the group consisting of nickel, cobalt, palladium, gold and their alloys.
2. Method according to claim 1, characterised in that the first currentlessly deposited metal layer is applied at a deposition speed of less than 5 µm/h.
3. Method according to one of the preceding claims, characterised in that the first currentlessly deposited metal layer is substantially formed from nickel.
4. Method according to one of the preceding claims, characterised in that the first currentlessly deposited metal layer is formed from a nickel/phosphorus alloy or nickel/boron alloy.
5. Method according to one of the preceding claims, characterised in that, prior to being treated in the swelling solution, the plastic material parts are initially cleaned in a solution containing wetting agents in a separate treatment step.