WO2013123756A1

WO2013123756A1 - Method for integrally molding metal and resin and metal-resin composite structure obtainable by the same

Info

Publication number: WO2013123756A1
Application number: PCT/CN2012/078832
Authority: WO
Inventors: Qing Gong; Xiong Zhang; Yihu ZHANG; Wei Zhou
Original assignee: Shenzhen Byd Auto R&D Company Limited; Byd Company Limited
Priority date: 2012-02-24
Filing date: 2012-07-18
Publication date: 2013-08-29
Also published as: KR20140130202A; CN103286909B; EP2817134A1; US9889588B2; EP2817134B1; CN103286909A; JP2015512804A; JP6014171B2; EP2817134A4; KR101690592B1; US20140363631A1

Abstract

A method for integrally molding a metal and a resin and a metal-resin composite structure obtainable by the same are provided. The method comprises steps of: A) forming a nanopore in a surface of a metal sheet; and B) melting a thermoplastic resin on the surface of the metal sheet formed with the nanopore, and then injection molding the thermoplastic resin onto the surface of the metal sheet, in which the thermoplastic resin is a mixture of a main resin and a polyolefin resin, the main resin is a polycarbonate, and the polyolefin resin has a melting point of about 65ºC to about 105ºC.

Description

METHOD FOR INTEGRALLY MOLDING METAL AND RESIN AND METAL-RESIN COMPOSITE STRUCTURE OBTAINABLE BY THE SAME

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority to and benefits of Chinese Patent Application Serial No.

201210043644.X, filed with the State Intellectual Property Office of P. R. China on February 24, 2012, the entire content of which is incorporated herein by reference.

FIELD

The present disclosure relates to the field of metal-plastic integrally molding, and more particularly to a method for integrally molding a metal and a resin, and a metal-resin composite structure obtainable by the same.

BACKGROUND

In the fields of manufacture of articles such as automobiles, household appliances and industrial machines, a metal and a resin need to be firmly bonded together. Currently, in a conventional method, an adhesive is used at normal temperature or under heating to integrally bond a metal and a synthetic resin. One research direction is to integrally bond an engineering resin with high strength to a magnesium alloy, an aluminum alloy, or ferroalloys such as stainless steel directly without an adhesive.

Nano molding technology (NMT) is a technique of integrally bonding a metal and a resin, which allows the resin to be directly injection molded on a surface of a metal sheet by nano molding the surface of the metal sheet so as to obtain a metal-resin integrally molded product. For effective bonding of a metal and a resin, NMT may replace commonly used insert molding or zinc-aluminum or magnesium-aluminum die casting so as to provide a metal-resin integrally molded product with low cost and high performance. Compared with the bonding technology, NMT may reduce the whole weight of the product, and may ensure excellent strength of the mechanical structure, high processing rate, high output, and many appearance decoration methods, and consequently may apply to vehicles, IT apparatuses and 3C products.

Japan Taisei Plas Co., Ltd. filed a series of patent applications, for example, CN1492804A,

CN1717323A, CN101341023A and CN101631671A, which propose a method for integrally molding a metal and a resin composition. In this method, by using a resin composition containing polyphenylene sulfide (PPS), polybutylene terephthalate (PBT) and polyamide (PA) with high crystallinity as an injection molding material, the resin composition is directly injection molded on a surface of a nano molded aluminum alloy layer to allow the resin composition to immerse in a nanoscale micropore, so as to obtain a metal-resin integrally molded product with a certain mechanical strength. However, because the resins used in this method are all highly crystalline resins, components with light transmission effect may not be made of the resins, which may restrict the design and the application scope of the product. SUMMARY

Embodiments of the present disclosure seek to solve at least one of the problems existing in the prior art to at least some extent, particularly technical problems of complex molding process, strict conditions, the fact that the surface of the plastic layer is difficult to process, the surface decoration of a plastic article, and low mechanical strength when the plastic is a highly crystalline resin in nano molding technology ( MT).

According to a first aspect of the present disclosure, there is provided a method for integrally molding a metal and a resin. The method comprises steps of:

A) forming a nanopore in a surface of a metal sheet; and

B) melting a thermoplastic resin on the surface of the metal sheet formed with the nanopore, and then injection molding the thermoplastic resin onto the surface of the metal sheet,

in which the thermoplastic resin is a mixture of a main resin and a polyolefin resin, the main resin is a polycarbonate, and the polyolefin resin has a melting point of about 65°C to about 105°C.

According to a second aspect of the present disclosure, there is provided a metal-resin composite structure, which is obtainable by the method according to the first aspect of the present disclosure.

In the method for integrally molding the metal and the resin according to an embodiment of the present disclosure, a polycarbonate with higher light transmittance is used, and a polyolefin resin with a melting point of about 65°C to about 105°C is also used. Therefore, injection molding at a specific mould temperature may be not required during the molding, subsequent annealing treatment may also be not required, the molding process may be simplified, and it may be ensured that the obtained metal-resin composite structure may have high mechanical strength and good surface treatment characteristics, thus enhancing the light transmittance of a plastic article largely to meet the requirement when this technology applies to an appearance article.

Additional aspects and advantages of embodiments of present disclosure will be given in part in the following descriptions, become apparent in part from the following descriptions, or be learned from the practice of the embodiments of the present disclosure.

DETAILED DESCRIPTION

Reference will be made in detail to embodiments of the present disclosure. The embodiments described herein are explanatory, illustrative, and used to generally understand the present disclosure. The embodiments shall not be construed to limit the present disclosure.

According to a first aspect of the present disclosure, a method for integrally molding a metal and a resin is provided. The method comprises steps of:

A) forming a nanopore in a surface of a metal sheet; and

Because the resins used in the prior art are all highly crystalline resins, the surface of the plastic layer may be difficult to treat. In the present disclosure, based on this reason, a non-crystalline polycarbonate, which has a surface gloss and a toughness both superior to those of the highly crystalline resins in the prior art, is used as an injection molding material, and a polyolefin resin with a melting point of about 65°C to about 105°C is also used. Therefore, injection molding at a specific mould temperature may be not required during the molding, subsequent annealing treatment may also be not required, the molding process may be simplified, and it may be ensured that the obtained metal-resin composite structure may have high mechanical strength and good surface treatment characteristics, thus solving the problem of the surface decoration of a plastic article and enhancing the light transmittance of a plastic article largely to meet the requirement when this technology applies to an appearance article.

In the present disclosure, the mechanism of the metal-resin integrally molding is as follows: a nanoscale micropore is formed in the surface of the metal sheet; a resin composition is melted on the surface of the metal sheet, at this time, a part of melted resin composition permeates into the nanoscale micropore; and then the metal and the resin composition are integrally injection molded.

Particularly, in step A), forming a nanopore in a surface of a metal sheet comprises: anodizing the surface of the metal sheet to form an oxide layer on the surface of the metal sheet, in which the oxide layer is formed with the nanopore. The anodizing technique is well known to those skilled in the art. In some embodiments, anodizing the surface of the metal sheet may comprise: placing a pretreated metal sheet as an anode in a H₂S0₄ solution with a concentration of about 10wt% to about 30wt%; and electrolyzing the metal at a temperature of about 10°C to about 30°C at a voltage of about 10V to about 100V for about lmin to about 40min to form the oxide layer with a thickness of about Ιμπι to about ΙΟμιη on the surface of the metal sheet. An anodizing apparatus may be a well-known anodizing apparatus, for example, an anodizing bath.

By anodizing, the oxide layer formed with the nanopore is formed on the surface of the metal sheet. Preferably, the oxide layer has a thickness of about Ιμπι to about ΙΟμιη, more preferably about Ιμπι to about 5μιη.

The nanopore preferably has a pore size of about lOnm to about lOOnm, more preferably has a pore size of about 20nm to about 80nm, most preferably has a pore size of about 20nm to about 60nm. The nanopore has a depth of about 0.5μιη to about 9.5μιη, preferably has a depth of about 0.5μιη to about 5μιη. By optimizing the structure of the nanopore, the filling degree of the melted resin composition in the nanopore may be enhanced, and it may be ensured that the nano mocropore with this depth may be filled with the melted resin in a conventional injection molding process, which may not reduce the bonded area between the resin and the oxide layer but may further improve the bonding force between the resin and the metal because there are no gaps in the nanopore.

In one preferred embodiment, in step A), forming a nanopore in a surface of a metal sheet may further comprise a step of: immersing the metal sheet formed with the oxide layer on the surface thereof in an etching solution to form a corrosion pore in an outer surface of the oxide layer. The corrosion pore is communicated with the nanopore. By a double-layer three-dimensional pore structure formed by the corrosion pore and the nanopore, the permeability of the resin composition may be further enhanced, and the bonding force between the resin composition and the metal may be improved, thus further facilitating the molding.

The corrosion pore preferably has a pore size of about 200nm to about 2000nm, more preferably has a pore size of about 200nm to about lOOOnm, most preferably has a pore size of about 400nm to about lOOOnm. The corrosion pore has a depth of about 0.5μιη to about 9.5μιη, preferably has a depth of about 0.5μιη to about 5μιη. By optimizing the structure of the corrosion pore, direct injection of the resin composition and the bonding between the resin composition and the alloy during the injection molding may be further facilitated.

The etching solution may be a solution which may corrode the oxide layer. Generally, the etching solution may be a solution which may dissolve the oxide layer and have a concentration to be adjusted, for example, an acid/base etching solution. Preferably, the etching solution may be a single basic solution with a pH of about 10 to about 13 or a complex buffer solution. The single basic solution with a pH of about 10 to about 13 may be at least one selected from the group consisting of a Na₂C0₃ aqueous solution, a NaHC0₃ aqueous solution and a NaOH aqueous solution, preferably a Na₂C0₃ aqueous solution and/or a NaHC0₃ aqueous solution, thus allowing the corrosion pores to be uniformly distributed in the surface of the oxide layer and to have uniform pore size, and achieving better bonding performance between the resin layer and an aluminum alloy substrate as well as higher tensile strength and better integral bonding of an aluminum alloy composite structure. The Na₂C0₃ aqueous solution and/or the NaHC0₃ aqueous solution may have a solid content of about 0.1 wt% to about 15wt%. The complex buffer solution may be a mixed solution of a soluble hydrophosphate and a soluble base, for example, an aqueous solution of sodium dihydrogen phosphate and sodium hydroxide. The aqueous solution of sodium dihydrogen phosphate and sodium hydroxide may have a solid content of about 0.1 wt% to about 15wt%.

Immersing the metal sheet formed with the oxide layer on the surface thereof in an etching solution may comprise repeatedly immersing the metal sheet in the etching solution 2 times to 10 times with each immersing time of about lmin to about 60min, and cleaning the metal sheet with deionized water after each immersing. Cleaning the metal sheet may comprise placing the metal sheet in a washing bath to wash the metal sheet for about lmin to about 5min, or placing the metal sheet in a washing bath to place the metal sheet for about lmin to about 5min.

It has been found by the inventors through many experiments that in the present disclosure, by using a polyolefin resin with a melting point of about 65°C to about 105°C in the non-crystalline main resin, the flowing capability of the resin in the nanoscale micropore in the surface of the metal sheet may be enhanced, thus ensuring strong adhesive force between the metal and the plastic as well as high mechanical strength of the metal-resin composite structure. Preferably, based on 100 weight parts of the thermoplastic resin, the amount of the main resin is about 95 weight parts to about 99 weight parts, and the amount of the polyolefin resin is about 1 weight part to about 5 weight parts.

It has also been found by the inventors that by using a flow improver in the thermoplastic resin, the flowing capability of the resin may be enhanced, thus further enhancing the adhesive force between the metal and the plastic as well as the injection molding performance of the resin.

Preferably, based on 100 weight parts of the thermoplastic resin, the thermoplastic resin further contains about 1 weight part to about 5 weight parts of a flow improver. Preferably, the flow improver is a methyl methacrylate composition.

In the present disclosure, the main resin is a polycarbonate (PC), which may be selected from any straight chain polycarbonate and/or any branched chain polycarbonate commonly used in the prior art. For example, the polycarbonate may be PC IR2500 or IR2200 available from Idemitsu

Kosan Co., Ltd., without special limits.

In the present disclosure, the polyolefin resin has a melting point of about 65°C to about 105°C. Preferably, the polyolefin resin may be a grafted polyethylene. More preferably, the polyolefin resin may be a grafted polyethylene with melting point of about 100°C or about 105°C.

In the present disclosure, the metal may be any metal commonly used in the prior art, and may be properly selected according to its application areas. For example, the metal may be at least one selected from the group consisting of aluminum, stainless steel and magnesium.

According to a second aspect of the present disclosure, a metal-resin composite structure is also provided, which is obtainable by the method according to the first aspect of the present disclosure.

In the metal-resin composite structure according to an embodiment of the present disclosure, the metal sheet and the plastic layer are of an integrally formed structure, which has strong adhesive force and high mechanical strength. As shown in Table 1, each metal-resin composite structure has a fracture strength of about 15MPa to about 20MPa, an impact strength of about 350J/m to about 400J/m and a light transmittance of about 50% to about 52%.

In order to make the technical problem, the technical solution and the advantageous effects of the present disclosure more clear, the present disclosure will be further described below in detail with reference to examples thereof. It would be appreciated that particular examples described herein are merely used to understand the present disclosure. The examples shall not be construed to limit the present disclosure. The raw materials used in the examples and the comparative examples are all commercially available, without special limits.

Example 1

(1) Pretreatment:

A commercially available A5052 aluminum alloy plate with a thickness of 1mm was cut into

18mm x 45mm rectangular sheets, which were then immersed in a 40g/L NaOH aqueous solution. The temperature of the NaOH aqueous solution was 40°C. After lmin, the rectangular sheets were washed with water and dried to obtain pretreated aluminum alloy sheets.

(2) Surface Treatment 1 :

Each aluminum alloy sheet as an anode was placed in an anodizing bath containing a 20wt%

H₂S0₄ solution, the aluminum alloy was electrolyzed at a voltage of 20V at 18°C for lOmin, and then the aluminum alloy sheet was blow-dried.

The cross section of the aluminum alloy sheet after the surface treatment 1 was observed by a metalloscope, to find out that an aluminum oxide layer with a thickness of 5μπι was formed on the surface of the electrolyzed aluminum alloy sheet. The surface of the aluminum alloy sheet after the surface treatment 1 was observed by an electron microscope, to find out that a nanopore with a pore size of about 40nm to about 60nm and a depth of Ιμπι was formed in the aluminum oxide layer.

(3) Surface Treatment 2:

500ml of 10wt% sodium carbonate solution (pH=12) with a temperature of 20°C was prepared in a beaker. The aluminum alloy sheet after step (2) was immersed in the sodium carbonate solution, taken out after 5min, and placed in a beaker containing water to be immersed for lmin. After 5 cycles, after water immersing for the last time, the aluminum alloy sheet was blow-dried.

The surface of the aluminum alloy sheet after the surface treatment 2 was observed by an electron microscope, to find out that a corrosion pore with a pore size of 300nm to lOOOnm and a depth of 4μπι was formed in the surface of the immersed aluminum alloy sheet. It may also be observed that there was a double-layer three-dimensional pore structure in the aluminum oxide layer, and the corrosion pore was communicated with the nanopore.

(4) Molding:

95 weight parts of a straight chain polycarbonate PC (IR2200 available from Idemitsu Kosan Co., Ltd.), 3 weight parts of a flow improver (TP003 available from Mitsubishi Rayon Co., Ltd.) and 2 weight parts of a grafted polyethylene with a melting point of 65°C (Lotader AX8900 available from Arkema Group) were weighed, and mixed uniformly to obtain a resin mixture. Then, using an injection molding machine, the melted resin mixture was injection molded on the surface of the aluminum alloy sheet after step (3), to obtain a metal-resin composite structure SI in this example.

Example 2

A metal-resin composite structure S2 in this example was prepared by a method which is substantially the same as the method in Example 1, with the following exceptions.

In step (1), instead of the aluminum alloy plate in Example 1, a commercially available magnesium alloy plate with a thickness of 3mm was cut into 18mm x 45mm rectangular sheets.

In step (2), each magnesium alloy sheet as an anode was placed in an anodizing bath containing a 20wt% H₂S0₄ solution, the magnesium alloy was electrolyzed at a voltage of 15V at 18°C for lOmin, and then the magnesium alloy sheet was blow-dried.

The cross section of the magnesium alloy sheet after the surface treatment 1 was observed by a metalloscope, to find out that a magnesium oxide layer with a thickness of 5μπι was formed on the surface of the electrolyzed magnesium alloy sheet. The surface of the magnesium alloy sheet after the surface treatment 1 was observed by an electron microscope, to find out that a nano micropore with a pore size of 20nm to 40nm and a depth of Ιμηι was formed in the magnesium oxide layer.

The surface of the magnesium alloy sheet after the surface treatment 2 was observed by an electron microscope, to find out that a corrosion pore with a pore size of 300nm to lOOOnm and a depth of 4μπι was formed in the surface of the immersed magnesium alloy sheet. It may also be observed that there was a double-layer three-dimensional pore structure in the magnesium oxide layer, and the corrosion pore was communicated with the nanopore.

After the above steps, the metal-resin composite structure S2 in this example was obtained.

Example 3

A metal-resin composite structure S3 in this example was prepared by a method which is substantially the same as the method in Example 1, with the following exceptions.

In step (2), each aluminum alloy sheet as an anode was placed in an anodizing bath containing a 20wt% H₂S0₄ solution, the aluminum alloy was electrolyzed at a voltage of 40V at 18°C for lOmin, and then the aluminum alloy sheet was blow-dried.

The cross section of the aluminum alloy sheet after the surface treatment 1 was observed by a metalloscope, to find out that an aluminum oxide layer with a thickness of 5μπι was formed on the surface of the electrolyzed aluminum alloy sheet. The surface of the aluminum alloy sheet after the surface treatment 1 was observed by an electron microscope, to find out that a nanopore with a pore size of 60nm to 80nm and a depth of Ιμπι was formed in the aluminum oxide layer.

After the above steps, the metal-resin composite structure S3 in this example was obtained.

Example 4

A metal-resin composite structure S4 in this example was prepared by a method which is substantially the same as the method in Example 2, with the following exceptions.

In step (4), 98 weight parts of a straight chain polycarbonate PC (IR2200 available from Idemitsu Kosan Co., Ltd.) and 2 weight parts of a grafted polyethylene with a melting point of 105°C (Lotader 4210 available from Arkema Group) were weighed, and mixed uniformly to obtain a resin mixture. Then, using an injection molding machine, the melted resin mixture was injection molded on the surface of the aluminum alloy sheet after step (3), to obtain a metal-resin composite structure S4 in this example.

Comparative Example 1

A metal-resin composite structure DS1 in this example was prepared by a method which is substantially the same as the method in Example 1, with the following exceptions.

In step (4), 97 weight parts of a straight chain polycarbonate PC (IR2200 available from

Idemitsu Kosan Co., Ltd.) and 3 weight parts of a flow improver (TP003 available from Mitsubishi Rayon Co., Ltd.) were weighed, and mixed uniformly to obtain a resin mixture. Then, using an injection molding machine, the melted resin mixture was injection molded on the surface of the aluminum alloy sheet after step (3), to obtain a metal-resin composite structure DS1 in this example.

Comparative Example 2 A metal-resin composite structure DS2 in this example was prepared by a method which is substantially the same as the method in Example 1, with the following exceptions.

In step (4), 84 weight parts of polyphenylene sulfide PPS (PPS-HC1 available from Sichuan Deyang Chemical Co., Ltd., China), 3 weight parts of a flow improver, i.e., a cyclic polyester (CBT100), 8 weight parts of a grafted polyethylene with a melting point of 105°C (Lotader AX8900 available from Arkema Group) and 5 weight parts of a toughener (Lotader AX8840 available from Arkema Group) were weighed, and mixed uniformly to obtain a resin mixture. Then, using an injection molding machine, the melted resin mixture was injection molded on the surface of the aluminum alloy sheet after step (3) to obtain an injection molded metal-resin composite structure, which was annealed at 180°C for lh to obtain a metal-resin composite structure DS2 in this example.

Performance Test

1) The metal-resin composite structures S1-S4 and DS1-DS4 were fixed on a universal testing machine for tensile test to obtain maximum loads thereof respectively. The test results were shown in Table 1.

2) The impact strength of standard samples of the metal-resin composite structures S1-S4 and DS1-DS4 was tested using a cantilever beam impact tester according to the method disclosed in ASTM D256.

3) 40.0mm x 40.0mm x 2.0mm square samples were made of the resin mixtures in Examples 1-4 and Comparative Examples 1-2 respectively, and the light transmittance of the square samples were tested using a spectrophotometer respectively.

The test results were shown in Table 1.

Table 1

It may be seen from the test results in Table 1 that the metal-resin composite structures S1-S4 have a fracture strength of about 19MPa to about 22MPa, which indicates that the bonding force between the metal sheet and the plastic layer in the metal-resin composite structures S1-S4 is very strong; the metal-resin composite structures S1-S4 have an impact strength of about 350J/m to about 400J/m, which indicates that the metal-resin composite structures S1-S4 have high mechanical strength; and the metal-resin composite structures S1-S4 have a light transmittance of about 50% to about 52%, which may meet the requirement of light transmission application.

By comparing the test results of the metal-resin composite structure SI with the test results of the metal-resin composite structure DS2, it may be seen that the toughness of the polyphenylene oxide resin used in the prior art is very poor, the toughness of the polyphenylene oxide resin after modified with a toughener is still poor, and the metal-resin composite structure DS2 is far unable to meet the requirement of the product for the light transmission.

Although explanatory embodiments have been shown and described, it would be appreciated by those skilled in the art that the above embodiments can not be construed to limit the present disclosure, and changes, alternatives, and modifications can be made in the embodiments without departing from spirit, principles and scope of the present disclosure.

Claims

WHAT IS CLAIMED IS:

1. A method for integrally molding a metal and a resin, comprising steps of:

A) forming a nanopore in a surface of a metal sheet; and

wherein the thermoplastic resin is a mixture of a main resin and a polyolefin resin, the main resin is a polycarbonate, and the polyolefin resin has a melting point of about 65°C to about 105°C.

2. The method according to claim 1, wherein in step A), forming a nanopore in a surface of a metal sheet comprises:

anodizing the surface of the metal sheet to form an oxide layer on the surface of the metal sheet, in which the oxide layer is formed with the nanopore.

3. The method according to claim 2, wherein the oxide layer has a thickness of about Ιμπι to about ΙΟμπι, and the nanopore has a pore size of about lOnm to about lOOnm and a depth of about

0.5μπι to about 9.5μπι.

4. The method according to claim 2, wherein anodizing the surface of the metal sheet comprises:

placing a pretreated metal sheet as an anode in a H₂S0₄ solution with a concentration of about

10wt% to about 30wt%; and

electrolyzing the metal at a temperature of about 10°C to about 30°C at a voltage of about 10V to about 100V for about lmin to about 40min to form the oxide layer with a thickness of about Ιμπι to about ΙΟμπι on the surface of the metal sheet.

5. The method according to claim 2, wherein in step A), forming a nanopore in a surface of a metal sheet further comprises a step of:

immersing the metal sheet formed with the oxide layer on the surface thereof in an etching solution to form a corrosion pore in an outer surface of the oxide layer.

6. The method according to claim 5, wherein the corrosion pore is communicated with the nanopore, and the corrosion pore has a pore size of about 200nm to about 2000nm and a depth of about 0.5μιη to about 9.5μιη.

7. The method according to claim 5, wherein the etching solution is a solution which corrodes the oxide layer.

8. The method according to claim 1, wherein based on 100 weight parts of the thermoplastic resin, the amount of the main resin is about 95 weight parts to about 99 weight parts, and the amount of the polyolefin resin is about 1 weight part to about 5 weight parts.

9. The method according to claim 8, wherein based on 100 weight parts of the thermoplastic resin, the thermoplastic resin further contains about 1 weight part to about 5 weight parts of a flow improver, and the flow improver is a cyclic polyester.

10. The method according to claim 1, wherein the polyolefin resin is a grafted polyethylene.

11. The method according to claim 1, wherein the metal is at least one selected from the group consisting of aluminum, stainless steel and magnesium.

12. A metal-resin composite structure, obtainable by the method according to any one of claims 1-11.