High-ductility periodic variable alloy protective film and forming method thereof

Abstract

The disclosure provides a metal protective layer, sequentially comprising an organic powder coating, a high-gloss organic coating, a ductile periodic variable alloy protective film and a transparent powder coating, wherein the base powder layer is an epoxy resin or pure polyester powder coating; the high-gloss organic coating is an epoxy resin powder coating, a polyester powder coating, or a polybutadiene organic coating; the ductile periodic variable alloy protective film is formed by direct current magnetron sputtering with two targets in a high vacuum environment, and the material of the targets is composed of a Ni—Cr alloy layer and pure Cr; and the transparent powder layer is an acrylic powder coating or a polyester transparent powder coating.

Claims

1. A protective film, sequentially consisting of: a base powder layer, a high-gloss organic coating, a ductile periodic variable alloy protective film, and a transparent powder coating, wherein: the base powder layer is an epoxy resin or a pure polyester powder coating; the high-gloss organic coating is an epoxy resin powder coating, a polyester powder coating, or a polybutadiene organic coating; the ductile periodic variable alloy protective film is formed by simultaneously opening two targets and performing direct current magnetron sputtering in a high vacuum environment, and the two targets are a Ni—Cr alloy target and a pure Cr metal target, wherein a Ni content periodically varies from more than 0% to 85% by mass and a Cr content periodically varies from 15% to 100% by mass in the ductile periodic variable alloy protective film; and the transparent powder coating is an acrylic powder coating or a polyester transparent powder coating.

2. The protective film according to claim 1, wherein a thickness of the base powder layer is 100-300 μm; a thickness of the high-gloss organic coating is 80-120 μm; a thickness of the transparent powder coating is 80-150 μm; and a thickness of the ductile periodic variable alloy protective film is 0.1-0.8 μm.

3. A method for forming the protective film of claim 1, comprising steps of: (1) providing a surface of a workpiece made of an aluminum alloy or other metal for pretreatment, the pretreatment comprising steps of water washing, alkaline washing, water washing, acid washing, pure water washing, passivation, pure water washing, sealing, pure water washing and drying; (2) spraying base powder onto the surface of step (1) and curing same to obtain the base powder layer, the base powder being an epoxy resin powder or the pure polyester powder coating; (3) performing fine grinding and polishing the surface of step (2); (4) cleaning the surface of step (3), comprising steps of water washing, alkaline washing, water washing, acid washing, pure water washing, pure water washing and drying; (5) spraying a high-gloss and high-leveling resin powder coating or a solvent-type liquid paint onto the surface of step (4), and curing same to obtain the high-gloss organic coating, the high-gloss and high-leveling resin powder coating or the solvent-type liquid paint being epoxy resin powder, the polyester powder coating or the polybutadiene organic coating; (6) performing the direct current magnetron sputtering on the surface of step (5), the sputtering comprising simultaneous opening of the Ni—Cr alloy target and the pure Cr metal target and simultaneous auto-rotation and revolution to obtain the ductile periodic variable alloy protective film; and (7) spraying transparent powder onto the surface of step (6) and curing same to obtain the transparent powder coating, the transparent powder being acrylic resin or the polyester transparent powder coating.

4. The method according to claim 3, wherein in step (2), a powder spraying thickness is 100-300 μm, a curing temperature on the surface of the workpiece reaches 180° C., and a curing time is 20 min.

5. The method according to claim 3, wherein in step (3), 800/1000-mesh sandpaper is used for grinding and polishing in the fine grinding step.

6. The method according to claim 3, wherein in step (5), the high-gloss organic coating is sprayed with a thickness of 80-120 μm, a curing temperature on the surface of the workpiece reaches 215° C., and a curing time is 20 min.

7. The method according to claim 3, wherein in step (6), a temperature of the workpiece for the sputtering is 80-140° C., a flow rate of gas is 40-80 cc/min, a direct current for the sputtering is 20-30 A, and a voltage of a direct current power supply is less than or equal to 800 v; a vacuum degree is (2-8)×10.sup.−3 Pa, a sputtering time of the two targets is 15-80 s, a working gas is 99.999% argon, and an ambient humidity for the sputtering is less than or equal to 50%.

8. The method according to claim 3, wherein in step (7), the transparent powder is sprayed with a thickness of 80-150 μm, a curing temperature on the surface of the workpiece reaches 180° C., and a curing time is 17.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 shows the schematic diagram of the high-ductility periodic variable alloy protective film.

DETAILED DESCRIPTION

(2) Unless otherwise specified, the embodiments of the disclosure adopt two targets, one is NiCr alloy containing 60%-80% of Ni and 20%-80% of Cr by mass, and the other one is Cr having the purity of 99.99%. The PVD equipment is a high vacuum magnetron sputtering coating machine.

(3) The sputtering base material is A356.2 aluminum alloy; the base powder is a pure polyester powder coating; the high-gloss powder coating is a pure epoxy resin coating; and the transparent coating is a pure acrylic transparent powder coating.

(4) The coating is inspected in accordance with the US general motor hub coating performance standards, and the inspection items include Adhesion Cross-Cut Test, CASS, FLIFORM, NASS, tape sticking test, high humidity resistance test, gravel impact test, thermal shock resistance test, oil resistance test, detergent resistance test, aging resistance test, etc.

(5) A method of forming a high-ductility periodic variable alloy protective film includes the steps of:

(6) (1) providing an aluminum alloy surface or other metal surface for pretreatment, the pretreatment including water washing, alkaline washing, water washing, acid washing, pure water washing, passivation, pure water washing, sealing, pure water washing and drying;

(7) (2) spraying base powder onto the metal surface of step (1) and curing same, the base powder being an epoxy resin powder or pure polyester powder coating; (3) performing fine grinding and polishing on the surface of step (2);

(8) (4) cleaning the surface of step (3), including the steps of water washing, alkaline washing, water washing, acid washing, pure water washing, pure water washing and drying;

(9) (5) spraying a high-gloss and high-leveling resin powder coating or a solvent-type liquid paint onto the surface of step (4), and curing same, the base paint being epoxy resin powder, a polyester powder coating or a polybutadiene liquid coating;

(10) (6) performing high-vacuum direct current magnetron sputtering on the surface of step (5), the sputtering including simultaneous opening of a NiCr alloy target and a pure Cr metal target and simultaneous auto-rotation and revolution to obtain a periodic variable alloy protective film; and

(11) (7) spraying transparent powder onto the surface of step (6) and curing same, the transparent powder being acrylic resin or a polyester powder coating.

(12) In step (2), the powder spraying thickness is 100-300 μm, the curing temperature on the surface of the workpiece reaches 180° C., and the curing time is 20 min.

(13) In step (3), 800/1000-mesh sandpaper is used for grinding and polishing in the fine grinding step.

(14) In step (5), the base paint is sprayed with a thickness of 80-120 μm, the curing temperature on the surface of the workpiece reaches 215° C., and the curing time is 20 min.

(15) In step (6), the workpiece coating temperature is 80-150° C., the flow rate of gas is 40-80 cc/min, the coating direct current is 20-30 A, and the direct current voltage is less than or equal to 800 v; the vacuum degree is (2-8)×10.sup.−3 Pa, the double target coating time is 15-80 s, the working gas is 99.999% argon, and the coating ambient humidity is less than or equal to 50%.

(16) In step (7), the transparent powder is sprayed with a thickness of 80-150 μm, the curing temperature on the surface of the workpiece reaches 180° C., and the curing time is 17 min.

Comparative Example 1

(17) A PVD protective layer is prepared using a common method in the art. The target is a pure Cr single target. The adopted process method and coating structure are same as those of the preparation method of the disclosure.

Comparative Example 2

(18) A PVD protective layer is prepared using a common method in the art. The target is a NiCr alloy single target. The adopted process method and coating structure are same as those of the preparation method of the disclosure.

(19) The metal surface ductility periodic high-vacuum magnetron sputtering coatings in Embodiment 1 and Comparative Examples 1 and 2 are tested and compared as the following table:

(20) TABLE-US-00001 Group Comparative Comparative Embodiment 1 Example 1 Example 2 Surface cracking No cracking Intensive Cracking cracking Adhesion 100% 93% 92% Cross-Cut Test shedding-free shedding-free shedding-free Tape sticking test 100% 95% 92% shedding-free shedding-free shedding-free CASS 2.0 mm 3.1 mm 6.1 mm FLIFORM 3.3 mm 4.1 mm 4.8 mm NASS 1.8 mm 2.2 mm 5.2 mm Water resistance No change, No change, No change, test adhesion 100% adhesion 85% adhesion 67% shedding-free shedding-free shedding-free Gravel impact Superior to level 8 Level 8 Level 8 resistance Thermal impact Shedding-free 10% shedding 13% shedding Oil resistance test No change No change No change Detergent No change No change No change resistance Aging resistance No change, No change, No change, adhesion 100% adhesion 91% adhesion 90% shedding-free shedding-free shedding-free

(21) Hence, in the method of the disclosure, the coating temperature, the argon flow rate, the coating current, the vacuum degree, the NiCr alloy target and the pure Cr coating time are the key parameters. A PVD film with good properties is obtained by optimizing the above process. In the disclosure, the technical solution of the embodiment obtains the optimal condition by exploring the above conditions. The coating test results are best under this optimal condition.

(22) The disclosure discloses a high-ductility periodic variable alloy protective film, sequentially comprising a metal or non-metal substrate, a high-gloss organic resin coating, a high-ductility periodic variable alloy film and a transparent resin film. The disclosure also provides a forming method of the high-ductility periodic variable alloy protective film. The method can improve the bonding force between the coating film and the surface transparent coating and the durability of the bonding force, and form a bright metal appearance of metallic chrome, and the coating system has good corrosion resistance.