WO2016185044A1 - Metallised plastic part for a motor vehicle - Google Patents

Abstract

The invention relates to a metallised plastic part for a motor vehicle, comprising at least one surface made of a plastic material, and at least one coating of said surface, said coating being a multi-layer coating including, in this order: i) at least one layer of a metal coating; ii) at least one layer of a polymer coating made of at least one polysiloxane; and iii) at least one layer of a transparent polymer coating. The invention also relates to a method for preparing such a metallised plastic part as well as a lighting and/or signalling device comprising such a metallised plastic part.

Description

 Automotive Metallic Plastic Part

The present invention relates to a metallized plastic part for automobile, to a process for preparing such a plastic part, as well as to a light device for a motor vehicle comprising such a plastic part.

The invention is more particularly concerned with parts called masks or hubcaps, which essentially fulfill an aesthetic function in the fire or the headlamp of a vehicle, or to parts having a mechanical function in this type of product, including pedestals or plates on which other parts may be mounted, such as optical parts and / or electrical or mechanical connection elements, or which, in the form of a unitary element, may play, in the traffic lights, both role of reflector and mask. It can also be applied to metallized parts having an optical role in obtaining light beams, including reflectors.

The invention relates more particularly to a metallized plastic part which comprises at least one surface of a plastic material, at least one metal coating which at least partially covers said surface and at least one outer coating, in particular resistant to external aggressions such as scratch and abrasion, to protect said metal coating.

Masks, plates, pedestals or reflectors are important elements in a lighting and / or signaling device of a motor vehicle.

By way of example, the reflector has the function of reflecting the light emitted by one or more light sources so that the light beam emitted by the lighting and / or signaling device respects an accurate photometry. The mask must be able to give an aesthetic appearance, shiny or satin for example, which is homogeneous and durable over time, as the bases and turntables, especially when they are visible from outside the projector or fire. Whatever their function, these parts need to have certain properties, especially at the surface, whether for aesthetic reasons and / or for technical reasons such as good resistance to external aggressions, in particular to abrasion or a surface appearance so as not to disturb the reflection of the light emitted by the fire and / or projector.

These parts are most often made of a material based on polymer (s), in particular thermosetting or thermoplastic, which have the advantage of leading to light materials and variable shapes on demand given that parts can be manufactured by injection molding techniques. After molding, these parts are made reflective by depositing a metal coating, in particular based on aluminum, on at least a portion of the surface of the plastic material.

Thus, it has already been proposed, particularly in the patent application ES 2 304 858, a process specifically adapted to the metallization of plastic parts based on certain particular polymers, that is to say the polyamides, the acrylonitrile-butadiene-styrene copolymers (ABS) and ABS / polycarbonate copolymers (ABS / PC) and copolymers. This process requires many steps, in particular a step of metallization of the surface of the plastic part in a hexavalent chromium-based catalytic bath. This method is however not suitable for any type of thermoplastic polymer and is long, expensive and very water-consuming for the different washing steps. In addition, it uses hexavalent chromium, the discharge of which is prohibited in the effluents, which requires the establishment of a treatment plant. Finally, the metal surfaces obtained according to this method are unsatisfactory from the point of view of their resistance to external aggression.

Indeed, the surface of the metallized parts made from polymer-based materials can be modified by many factors, among which:

- Thermal variations that may cause surface defects such as deformations, blistering, cracking or other. In addition, when these parts comprise a reflective metal coating of the aluminum type, the repeated temperature variations, in particular the increases in temperature, cause a deformation phenomenon of the material, leading to blistering on the surface of the metal coating.

- friction and / or abrasions during transport and handling resulting in the formation of scratches on its surface. It is therefore important to have metallized plastic parts having good properties of resistance to external aggressions, in particular temperature variations and abrasion.

There is therefore a need for a metallized plastic part having enhanced external resistance properties and for a process for preparing such a metallized plastic part which is simple and non-polluting to implement.

This need is satisfied by the invention which will be described below and whose first object is a metallized plastic part for automobile, comprising at least one surface of a plastic material, and at least one coating of said surface, said coating being a multilayer coating comprising in this order: i) at least one layer of a metal coating, said metal coating being deposited on said plastic material, ii) at least one layer of a polymer coating based on at least one polysiloxane, said layer being deposited on the metal coating, and iii) at least one layer of a transparent polymer coating, said transparent polymer coating being deposited on the polymer coating based on at least one polysiloxane.

According to the invention, the term "deposited on" relating to the metal coating means that there may be one or more additional layers between said plastic material and the metal coating.

According to the invention, the expression "deposited on" relative to the polymer coating based on at least one polysiloxane means that there may be one or several additional layers between said metal coating and said polymer coating based on at least one polysiloxane.

According to the invention, the expression "deposited on" relative to the transparent polymer coating means that there may be one or more additional layers between said polymer coating based on at least one polysiloxane and said transparent polymer coating.

According to the invention, the term "transparent polymer coating" means a polymer coating transmitting light by refraction and through which the objects are visible with more or less sharpness. More particularly, it is a polymer coating through which an object is observed without significant loss of contrast: the interposition of said transparent polymer coating between an object and an observer thereof does not significantly reduce the image quality of said object perceived by the observer. Indeed, within the meaning of the invention, a transparent polymer coating can transmit at least a portion of the incident light (or incident light beam) with very little or no dispersion. Preferably, the light transmission, in particular the transmission of visible light, through the transparent polymer coating is at least 87%. Light transmission is the amount of light that the transparent polymer coating passes through from an incident light ray. According to a preferred embodiment of the invention:

said metal coating is in direct contact with the plastic material; and or

said polymer coating based on at least one polysiloxane is in direct contact with said metal coating; and / or - said transparent polymer coating is in direct contact with said polymer coating based on at least one polysiloxane.

Also according to a preferred embodiment of the invention, the transparent polymer coating constitutes the outermost layer of the coating. multilayer, that is to say, the layer likely to be directly exposed to external aggression.

The metal coating is preferably a coating of at least one metal selected from aluminum, chromium, nickel and chromium alloys and iron and carbon alloys optionally comprising chromium and / or nickel (steels, especially stainless steels).

According to a preferred embodiment of the invention, the metal is aluminum or an aluminum alloy, and even more preferably, the metal is aluminum.

The metal coating preferably has a thickness ranging from about 50 to 500 nm, and even more preferably from about 40 to 150 nm.

The nature of the plastic material that can be used according to the invention is not critical, it can be chosen from any type of material based on thermoplastic or thermosetting polymers, among which polycarbonates (PC), high-carbon polycarbonates may be mentioned in particular. temperature (PC-HT), polyamides (PA), acrylonitrile-butadiene-styrene copolymers (ABS), copolymers of acrylonitrile-butadiene-styrene and polycarbonates (ABC / PC), polybutylene terephthalates (PST), polyethylene terephthalates (PET), polypropylenes (PP), unsaturated polyesters (UP), polyepoxides (EP), polymethyl methacrylates (PMMA), polysulfones (PSU), polyethersulfones (PES) and polysulfides of phenylene (PPS).

Preferably, the polymer (s) are chosen from the group consisting of polycarbonates (PC), high temperature polycarbonates (PC-HT), polyamides (PA), acrylonitrile-butadiene-styrene copolymers (ABS) copolymers of acrylonitrile-butadiene-styrene and polycarbonates (ABC / PC) and polybutylene terephthalates (PST).

According to the invention, the term "material based on" a material comprising in volume at least 5% polymer (s), preferably at least 15%, and even more preferably at least 20%. The plastic material may also contain one or more fillers, in particular reinforcing mineral fillers making it possible to improve the strength of the plastic material and its resistance to shocks, such as, for example, calcium carbonate, glass fibers, talc, etc.

The coating layer based on at least one polysiloxane preferably has a thickness ranging from about 20 to 250 nm, and even more preferably from 20 to about 50 nm.

The coating layer based on at least one polysiloxane of the invention may comprise one or more silicon-carbon group (s) (Si-C), and one or more group (s) silicon-oxygen (Si-O) .

The transparent polymeric coating layer is preferably a layer of at least one at least partially crosslinked polymer chosen from acrylic polymers, polysiloxanes and polyurethanes, more preferably a layer of at least one crosslinked polymer chosen from acrylic polymers. polysiloxanes and polyurethanes.

The transparent polymeric coating layer preferably has a thickness ranging from 3 to 50 μηι approximately, and even more preferably from 6 to 12 μηι approximately.

The transparent polymeric coating layer comprises a polysiloxane predominantly or wholly inorganic. In other words, the polysiloxane of the transparent polymeric coating layer will then be of the quasi-silica type (Si _x C _y O _z ), the ratios y / x varying from 0 to 3 and z / x from 0.5 to 2, preferably the ratio y / x is 0 and the ratio z / x is 2.

The subject of the invention is also a method for preparing a metallized automotive plastic part comprising a multilayer coating and as defined according to the first subject of the invention, said method being characterized in that it comprises at least the following steps: i) depositing at least one layer of a metal coating on at least a portion of the surface of a plastic part, ii) depositing at least one polymeric coating layer based on at least one polysiloxane on the metal coating layer obtained in step i), iii) activating the polymer coating layer obtained above in step ii) using an oxidizing agent, iv) depositing at least one layer of a transparent polymer coating on the polymer coating layer based on at least one polysiloxane obtained above in step iii).

Stage i) of deposition of the metal coating layer (s) may be carried out by sputtering under vacuum (or "sputtering" according to the corresponding English expression) or by vacuum evaporation of at least one selected metal among aluminum, chromium, nickel and chromium mixtures and mixtures of iron and carbon optionally including chromium and / or nickel.

According to a preferred embodiment of the invention, the metal coating is an aluminum-based coating and step i) is carried out by aluminum vacuum sputtering using argon as a carrier gas or by evaporation under empty of aluminum.

According to a particular and preferred form of the invention, step i) is preceded by a preliminary step of cleaning the surface of the plastic material, in order to improve the adhesion of the metal coating to the surface of the plastic material. This cleaning step is preferably effluvage (or "Glow Discharge" according to the corresponding English expression), that is to say by high voltage discharge with a mean vacuum to cause ion bombardment of a residual gas such as argon or oxygen on the surface of the plastic material. This pretreatment is preferably carried out at a pressure of between 1.10 ^"1 mbar and ^1.10" 3 mbar approximately with a gas flow rate between 50 and 200 sccm of ( "standard cubic centimeter per minute", between 50 and 200 smlm for " standard millimeter per minute, which is a standard unit at a temperature T = 0 ° C and a pressure of 1 atm). The duration of this pre-treatment is generally of the order of a few seconds, typically about 20 to 30 seconds.

Stage ii) deposition of at least one polymer coating layer based on at least one polysiloxane may be carried out by plasma polymerization of an organosilicone monomer. Plasma polymerization refers to the Plasma Enhanced Chemical Vapor Deposition (PECVD) technique.

The organosilicone monomer is chosen from hexamethyldisiloxane (HMDSO), tetramethyldisiloxane (TMDSO), tetraethoxysilane (TEOS) and tetramethylsilane (TMS). Among these monomers, it is preferred to use HMDSO or TMDSO.

The plasma used is preferably a plasma of argon, air or oxygen.

The activation step iii) is intended to oxidize the coating layer based on at least one polysiloxane obtained in step ii) so as to increase its surface energy and thus facilitate the subsequent deposition step of the transparent polymer coating layer.

The activation step iii) can be carried out by treating the polymer layer based on at least one polysiloxane with the aid of an oxidizing agent such as, for example, nitroethane. In this case, the use of nitroethane makes it possible to obtain surface energies greater than 40 Nm ^-1 .

The duration of step iii) may vary from about 10 seconds to about 10 minutes. Typically, it is of the order of a few seconds.

Stage iv) of deposition of at least one layer of a transparent polymer coating is preferably carried out by spraying a solution of at least one monomer or an oligomer or an acrylic polymer, polyurethane or polysiloxane said spray being followed by a crosslinking step.

The crosslinking step can be carried out by heat treatment or by exposure to ultraviolet (UV) radiation. According to a preferred embodiment of the invention, the crosslinking step is carried out by heat treatment for a period greater than about 20 minutes (preferably for a period of time ranging from about 20 minutes to about 40 minutes) and at a temperature above 125 ° C, preferably from about 128 ° C to about 132 ° C.

The solution used in step iv) may furthermore contain one or more pigments intended to adjust the tone of the transparent layer.

The metallized plastic part defined according to the first subject of the invention is particularly suitable for the manufacture of lighting and / or signaling devices for a motor vehicle, such as headlamp masks, hubcaps, pedestals, plates and brackets. reflectors. Preferably, the part according to the invention is a piece of lighting and / or signaling device for a motor vehicle, for example a reflector. For example, the reflector of a car projector or a traffic light. This reflector is intended to be associated with a light source, such as LEDs, or incandescent lamps. This may be the reflector of a projector, for example intended to be associated with LEDs, halogen lamps or discharge lamps. The piece according to the invention may also be a piece of style of a lighting and / or signaling device of a motor vehicle, such as a mask. By "piece of style", we aim for a piece having at least one aesthetic function. A mask is a part intended to mask parts of the lighting and / or signaling device, such as the wiring, the actuating mechanisms, the fixing means. The metallized plastic part according to the invention can also be chosen from: hubcaps, bases, plates.

Another object of the invention is a luminous device, especially a lighting and / or signaling device, comprising at least one metallized plastic part as defined according to the first subject of the invention, in particular a front searchlight or a rear light.

The light device may further comprise a housing and a closure glass of said housing defining an interior volume, the metallized plastic part being at least partly outside said interior volume. Other features and advantages of the invention will be described in the examples which follow.

EXAMPLE 1 Preparation of a metallized plastic part according to the process according to the invention

1.1: Preparation of the plastic part

A polycarbonate exterior trim type plastic part (Lexan® LS2 1 1 1 resin) was subjected to a cleaning step by effluvage of its surface. To do this, the part was inserted into an airtight chamber equipped with a vacuum pump (DYNAMET 4V, Leybold Optics company) and an ion bombardment apparatus sold under the trade name PE5000 by Avanced Energy, in which there is provided a vacuum of between 1.10 ^"and 1.10 ^1" mbar.

The ion bombardment parameters were as follows:

- Gas: Argon

- Gas flow: 100 sccm,

- Discharge power: 3500 W,

- Treatment energies received by the room: 2000 to 5000 V,

- Duration of treatment: 25 seconds.

 1.2: Aluminum deposit

The plastic part thus cleaned was then introduced into the chamber of a sputtering apparatus sold under the trade name MAGNETRON ZPT by Leybold Optics and wherein there is provided a vacuum of between 1.10 ^"and 1.10 ^1" 3 mbar.

The vacuum sputtering parameters were as follows:

- Metal: aluminum,

- Degassification time: 20 seconds,

- Power: 70 kW, - Intensity: 55 to 180 A,

- Duration of treatment: 7 seconds.

There was thus obtained a plastic part whose surface was coated with an aluminum layer with a thickness of about 100-150 nm.

1.3: Deposition of the polysiloxane coating layer

A polysiloxane coating layer was then applied to the aluminum layer by plasma enhanced chemical vapor deposition. The metallized part obtained above in the previous step was introduced into the reactor of a PECVD apparatus sold under the commercial name DFS 3000 by Avanced Energy.

The following parameters were used:

Organosilicone monomer: hexamethyldisiloxane (HMDSO) (Wacker, AK0.65),

- HMDSO flux: 60 sccm,

- Power: 2000 W,

- Duration of treatment 20 seconds.

There was thus obtained a plastic part comprising an aluminum coating itself coated with a layer of a polysiloxane-based polymer coating with a thickness of about 40-70 nm.

1.4: Activation of the polysiloxane-based polymer coating layer.

The polysiloxane-based polymer coating layer was then activated by nitroethane, by PECVD.

To do this, the part obtained above at the end of step 1.3 was again introduced into the reactor of the PECVD apparatus and this time treated with nitroethane by applying the following parameters:

- Oxidant: Nitroethane (Leybold Optics), - Nitroethane flow: 70 sccm,

- Power: 2000 W,

- Duration of treatment 4 seconds.

1.5: Deposit of the transparent polymer coating layer

A transparent polymeric coating layer was then applied to the activated polysiloxane-based polymer layer of the part from step 1.4.

 An alcoholic solution of a siloxane resin sold under the trade name SilFORT® PHC587C by Momentive was sprayed onto the activated polysiloxane-based polymer layer.

After sputtering, the siloxane resin layer was crosslinked by heat treatment at 128 ° C for 30 minutes.

Thus, a transparent polymeric coating layer having a thickness of about 7-1 microns was formed on the polysiloxane-based polymer coating.

We obtained a plastic part for automobile with a multilayer reflective coating resistant to external aggression.

EXAMPLE 2 Preparation of a metallized plastic part according to the process according to the invention

2.1: Preparation of the plastic part

A polycarbonate exterior trim type plastic part (Lexan® LS2 1 1 1 resin) was subjected to a cleaning step by effluvage of its surface. To do this, the part was inserted into an airtight chamber equipped with a vacuum pump (DYNAMET 4V, Leybold Optics company) and an ion bombardment apparatus sold under the trade name PE5000 by Avanced Energy, in which there is provided a vacuum of between 1.10 ^"and 1.10 ^1" mbar.

The ion bombardment parameters were as follows: - Gas: Argon,

- Gas flow: 100 sccm,

- Discharge power: 3500 W,

- Treatment energies received by the room: 2000 to 5000 V,

- Duration of treatment: 25 seconds.

 2.2: Deposition of aluminum

The plastic part thus cleaned was then introduced into the chamber of a sputtering apparatus sold under the trade name MAGNETRON ZPT by Leybold Optics and wherein there is provided a vacuum of between 1.10 ^"and 1.10 ^1" 3 mbar.

The vacuum sputtering parameters were as follows:

 - Metal: aluminum,

- Degassification time: 20 seconds,

- Power: 70 kW,

 - Intensity: 55 to 180 A,

- Duration of treatment: 7 seconds.

There was thus obtained a plastic part whose surface was coated with an aluminum layer with a thickness of about 100-150 nm.

2.3: Deposition of the polysiloxane coating layer

A polysiloxane coating layer was then applied to the aluminum layer by plasma enhanced chemical vapor deposition. The metallized piece obtained above in the previous step was introduced into the reactor of a PECVD apparatus sold under the commercial name RDFS 3000 by Avanced Energy.

The following parameters were used: Organosilicon Monomer: Hexamethyldisiloxane (HMDSO) (Wacker, AK0.65)

- HMDSO flux: 60 sccm,

- Power: 2000 W,

- Duration of treatment 8 seconds.

There was thus obtained a plastic part comprising an aluminum coating itself coated with a layer of a polysiloxane-based polymer coating with a thickness of about 40-70 nm.

2.4: Activation of the polysiloxane-based polymer coating layer.

The polysiloxane-based polymer coating layer was then activated by nitroethane, by PECVD.

To do this, the part obtained above at the end of step 1.3 was again introduced into the reactor of the PECVD apparatus and this time treated with nitroethane by applying the following parameters:

- Oxidant: Nitroethane (Leybold Optics),

- Nitroethane flow: 70 sccm,

- Power: 2000 W,

- Duration of treatment 4 seconds.

 2.5: Deposit of the transparent polymer coating layer

A clear polymeric coating layer was then applied to the activated polysiloxane-based polymer layer of the part from step 2.4.

An alcoholic solution of a siloxane resin sold under the trade name SilFORT® PHC587C by Momentive was sprayed onto the activated polysiloxane-based polymer layer. After sputtering, the siloxane resin layer was crosslinked by heat treatment at 128 ° C for 30 minutes.

Thus, a transparent polymeric coating layer having a thickness of about 7-1 microns was formed on the poly siloxane-based polymer coating.

We obtained a plastic part for automobile with a multilayer reflective coating resistant to external aggression.

Claims

A metallized automotive plastic part, comprising at least one surface of a plastic material, and at least one coating of said surface, said coating being a multilayer coating comprising in this order: i) at least one layer of a metal coating, said metal coating being deposited on said plastic material, ii) at least one layer of a polymer coating based on at least one polysiloxane, said layer being deposited on the metal coating, and iii) at least one layer of a coating transparent polymer, said transparent polymer coating being deposited on the polymer coating based on at least one polysiloxane.

2. metallized plastic part according to claim 1, characterized in that:

said metal coating is in direct contact with the plastic material; and or

said polymer coating based on at least one polysiloxane is in direct contact with said metal coating; and or

said transparent polymer coating is in direct contact with said polymer coating based on at least one polysiloxane.

3. metallized plastic part according to claim 1 or 2, characterized in that the transparent polymer coating is the outermost layer of the multilayer coating.

4. metallized plastic part according to any one of the preceding claims, characterized in that the metal coating is a coating of at least one metal selected from aluminum, chromium, alloys of nickel and chromium and alloys of iron and carbon optionally comprising chromium and / or nickel.

5. metallized plastic part according to any one of the preceding claims, characterized in that the metal coating has a thickness of 50 to 500 nm.

6. Metallized plastic part according to any one of the preceding claims, characterized in that the plastic material is selected from thermoplastic or thermosetting polymer materials.

7. metallized plastic part according to any one of the preceding claims, characterized in that the plastic material comprises one or more mineral fillers.

8. metallized plastic part according to any one of the preceding claims, characterized in that the coating layer based on at least one polysiloxane has a thickness ranging from 20 to 250 nm.

9. metallized plastic part according to any one of the preceding claims, characterized in that the transparent polymeric coating layer is preferably a layer of at least one crosslinked polymer selected from acrylic polymers, polysiloxanes and polyurethanes.

10. Metallized plastic part according to any one of the preceding claims, characterized in that the transparent polymeric coating layer has a thickness ranging from 3 to 50 μηι.

1. A method for preparing a metallized automotive plastic part comprising a multilayer coating as defined in any one of the preceding claims, characterized in that it comprises at least the following steps: i) the deposition of minus one layer of a metal coating on at least a portion of the surface of a plastic part, ii) depositing at least one layer of polymer coating based on at least one polysiloxane on the metal coating layer obtained in step i), iii) activating the polymer coating layer obtained in step ii) above using an oxidizing agent, iv) depositing at least one layer of a transparent polymer coating on the polymer coating layer based on at least one polysiloxane obtained above in step iii).

12. The method of claim 1 1, characterized in that the step i) of deposition of the layer (s) of metal coating is carried out by sputtering in a vacuum or by vacuum evaporation of at least one selected metal. among aluminum, chromium, nickel and chromium mixtures and mixtures of iron and carbon optionally including chromium and / or nickel.

13. Method according to any one of claims 1 1 to 12, characterized in that the step ii) depositing at least one polymer coating layer based on at least one polysiloxane is carried out by plasma polymerization of an organosilicone monomer.

14. Process according to any one of claims 1 1 to 13, characterized in that step iii) of activation is carried out by treatment of the polymer layer based on at least one polysiloxane with the aid of an oxidizing agent.

15. Method according to any one of claims 1 1 to 14, characterized in that the step iv) depositing at least one layer of a transparent polymer coating is carried out by spraying a solution of at least a monomer or an oligomer or an acrylic polymer, polyurethane or polysiloxane, said sputtering being followed by a crosslinking step.

16. Luminous device comprising at least one metallized plastic part as defined in any one of claims 1 to 10.