Patent Publication Number: US-2023150244-A1

Title: Method of manufacturing composite member and the composite member

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application is based on and claims the benefit of priority from Japanese Patent Application No. 2021-184971 filed on Nov. 12, 2021, and the entire contents of which are incorporated herein by reference. 
     TECHNICAL FIELD 
     The present disclosure relates to a method of manufacturing a composite member and the composite member. 
     BACKGROUND 
     WO 2017/141381 discloses a method of manufacturing a composite member. In this method, the composite member is manufactured using a base material and a resin member that are bonded to each other. On a surface of the base material, micro-order or nano-order asperities are formed. A resin member is applied into the micro-order or nano-order asperities and is hardened therein, producing an enhanced anchor effect as compared with millimeter-order asperities. Thus, the composite member manufactured by this method has high bonding strength. 
     SUMMARY 
     Aluminum is lighter and stronger than iron and thus is useful as a base material of the composite member. The manufacturing method described in WO 2017/141381 is susceptible to improvement in view of improvement in the bonding strength and airtightness of the composite member including the base material of aluminum. 
     According to an aspect of the present disclosure, a method of manufacturing a composite member is provided, the composite member including an aluminum member and a resin member that are bonded to each other. The manufacturing method includes blasting, performing, applying, and bonding. In the blasting, blasting is performed on the surface of the aluminum member, so that asperities are formed on the surface of the aluminum member. In the performing, the surface of the aluminum member on which asperities are formed is subjected to hydrothermal treatment, so that the surface of the asperities is modified into aluminum hydroxide and a surface nano structure is formed on the surface of the asperities. In the applying, a binder containing a triazine thiol derivative is applied to the surface of the asperities of the aluminum member, the surface being modified into aluminum hydroxide and having the surface nano structure, thereby forming a coating bonded to the aluminum member. In the bonding, the coating and the resin member are bonded to each other. 
     According to the manufacturing method, blasting is performed on the surface of the aluminum member. In the blasting, a natural oxide film formed on the surface of the aluminum member is reduced in thickness (removed) by blasting. Asperities are formed on the surface of the aluminum member by blasting. By the performing, the surface of the aluminum member on which asperities are formed is subjected to hydrothermal treatment, so that the surface of the asperities is modified into aluminum hydroxide and a surface nano structure is formed on the surface of the asperities. By the modifying, a functional group (e.g., a hydroxy group) of aluminum hydroxide is applied to the asperities on the surface of the aluminum member. In the applying, a binder containing a triazine thiol derivative is applied to the surface of the aluminum member, so that a coating bonded to the aluminum member modified into aluminum hydroxide is formed. Thus, three effects are combined as follows: the formation of the coating into the asperities on the surface of the aluminum member, the formation of the coating into the surface nano structure with a contact surface area extended between the aluminum member and the coating by the surface nano structure on the surface layer of the asperities, and molecular bonding between the functional group on the surface of the asperities and the triazine thiol derivative contained in the coating. An organic combination of these three configurations produces a synergy effect, which cannot be obtained by simply adding the effects of the individual configurations, achieving strong bonding. In the bonding, the resin member is bonded to the surface of the aluminum member on which the coating is formed. The resin member is strongly bonded by molecular bonding between the functional group on the surface and the triazine thiol derivative contained in the coating. Sharp portions on the asperities formed by the blasting are rounded by the modifying and are strongly bonded to the coating as described above. Thus, this manufacturing method achieves an additional effect of reducing the occurrence of breaks on the coating from sharp portions. As described above, with a chemical bond by molecular bonding and a mechanical bond by an anchor effect in a large surface area, the composite member is manufactured such that the aluminum member and the resin member are strongly and tightly bonded to each other with the coating interposed therebetween. The tightly bonded composite member has high airtightness and high thermal conductivity at a bonded interface, achieving high practicability. Thus, according to the method of manufacturing the composite member, the composite member can be manufactured with high bonding strength and airtightness. 
     In an embodiment, a plurality of pores having a pore size of 10 nm or more and less than 1000 nm may be formed on the surface nano structure, and the surface nano structure may have a thickness of 0.01 μm or more and 1 μm or less. In this case, the resin member is applied into the plurality of pores formed on the surface nano structure and is hardened therein, achieving an anchor effect. Thus, in this manufacturing method, the surface nano structure is formed on the surface of the aluminum member by the surface hydroxylation, so that the aluminum member can be changed to a shape including a coating and a resin member with higher adhesion than an aluminum member having not been subjected to surface hydroxylation. 
     According to an embodiment, in the blasting, abrasive grains having sharp projections with a particle size of 30 μm or more and 710 μm or less may be injected to blast with a projection pressure of 0.5 MPa or more and 2.0 MPa or less. Hence, in this manufacturing method, asperities can be formed on the surface of the aluminum member after a natural oxide film formed on the surface of the aluminum member is properly removed. Thus, in this manufacturing method, the surface nano structure can be uniformly formed on the surface of the aluminum member and the anchor effect can be properly obtained in the surface hydroxylation. 
     In an embodiment, in hydrothermal treatment in the performing, the hydrothermal treatment may be performed on the surface of the aluminum member such that the surface reacts with pure water at 70° C. or more and 100 C° or less. 
     In an embodiment, the electric conductivity of pure water may be 0.054 μS/cm or more and 10 μS/cm or less. Pure water with a low electric conductivity has a low impurity content. In this manufacturing method, residual impurities other than aluminum hydroxide on the surface of the aluminum member can be reduced by using pure water having the electric conductivity in the surface hydroxylation. Thus, this manufacturing method can prevent impurities from depriving a functional group on the surface of the aluminum member, achieving strong molecular bonding. 
     In an embodiment, in the performing, the surface of the aluminum member may be cleaned with the water, and the surface of the aluminum member may be modified into aluminum hydroxide. When the surface of the aluminum member has organic contamination, the contamination may reduce the wettability of the coating and the resin member and interfere with a chemical bond between the surface of the aluminum member and the coating and the resin member. In this manufacturing method, the surface of the aluminum member is cleaned with water used for modification into aluminum hydroxide. Thus, this manufacturing method can suppress a reduction in bonding strength, the reduction being caused by organic contamination. 
     In an embodiment, the aluminum hydroxide may contain at least one of diaspore, boehmite, pseudo-boehmite, bayerite, norstrandite, gibbsite, and doyleite. 
     In an embodiment, the triazine thiol derivative may contain at least one functional group selected from primary amine, secondary amine, tertiary amine, an epoxy group, a hydroxy group, a thiol group, an azido group, and an alkyl group. In this case, in the coating, a coating is formed by binding the triazine thiol derivative and the functional group on the surface of the aluminum member modified into aluminum hydroxide. In the bonding, the triazine thiol derivative contained in the coating and the functional group on the surface of the resin member bind to each other, and the resin member is bonded to the surface of the aluminum member on which the coating is formed. In this way, the coating is molecular bonded to the aluminum member modified into aluminum hydroxide and the resin member by the functional group of the triazine thiol derivative, so that the coating is strongly bonded. 
     In an embodiment, in the bonding, the resin member may be bonded to the surface of the aluminum member on which the coating is formed by injection molding, thermal compression molding, press forming, or ultrasonic bonding. Thus, this manufacturing method can easily bond the resin member to the surface of the aluminum member. 
     According to another embodiment of the present disclosure, a composite member is provided. The composite member contains an aluminum member, on which asperities are formed, and a triazine thiol derivative and includes a coating bonded to the surface of the aluminum member and a resin member bonded to the coating. A surface nano structure is formed on the asperities, and the surface nano structure is made of aluminum hydroxide. 
     In this composite member, the asperities are formed on the surface of the aluminum member. The surface nano structure is formed on the asperities. The surface nano structure is made of aluminum hydroxide. The triazine thiol derivative contained in the coating and the functional group of aluminum hydroxide on the surface of the aluminum member bind to each other, thereby bonding the coating to the aluminum member. Thus, three effects are combined as follows: the formation of the coating into the asperities on the surface of the aluminum member, the formation of the coating into the surface nano structure with a contact surface area extended between the aluminum member and the coating by the surface nano structure on the surface layer of the asperities, and molecular bonding between the functional group on the surface of the asperities and the triazine thiol derivative contained in the coating. An organic combination of these three configurations produces a synergy effect, which cannot be obtained by simply adding the effects of the individual configurations, achieving strong bonding. Moreover, the resin member is bonded to the surface of the aluminum member on which the coating is formed. The resin member is strongly bonded by, for example, molecular bonding between the functional group on the surface and the triazine thiol derivative contained in the coating. Sharp portions on the asperities on the surface of the aluminum member are rounded by forming the surface nano structure (forming aluminum hydroxide) and are strongly bonded to the coating as described above. Thus, this manufacturing method achieves an additional effect of reducing the occurrence of breaks on the coating from sharp portions. As described above, with a chemical bond by molecular bonding and a mechanical bond by an anchor effect in a large surface area, the composite member is configured such that the aluminum member and the resin member are strongly and tightly bonded to each other with the coating interposed therebetween. The tightly bonded composite member has high airtightness and high thermal conductivity at a bonded interface, achieving high practicability. Thus, this composite member can improve bonding strength and airtightness between the aluminum member and the resin member. 
     In an embodiment, the surface of the aluminum member may be substantially phosphorus-free, and the aluminum hydroxide may contain at least one of boehmite, pseudo-boehmite, diaspore, bayerite, norstrandite, gibbsite, and doyleite. In this case, phosphorus is not left on the surface of the aluminum member and thus it is assumed that a functional group on the surface of the aluminum member and a triazine thiol derivative contained in the coating are molecular bonded to each other while the functional group on the surface of the aluminum member is not deprived by these elements. Thus, this composite member has a structure that improves bonding strength and airtightness between the aluminum member and the resin member. 
     In an embodiment, the triazine thiol derivative may contain at least one functional group selected from primary amine, secondary amine, tertiary amine, an epoxy group, a hydroxy group, a thiol group, an azido group, and an alkyl group. In this case, in the composite member, a coating is formed by binding the triazine thiol derivative and the functional group on the surface of the aluminum member made of aluminum hydroxide. Subsequently, the triazine thiol derivative contained in the coating and the functional group on the surface of the resin member bind to each other, and the resin member is bonded to the surface of the aluminum member with the coating interposed therebetween. In this way, the coating is molecular bonded to the aluminum member made of aluminum hydroxide and the resin member by the functional group of the triazine thiol derivative, so that the coating is strongly bonded. 
     In an embodiment, the surface of the aluminum member may be substantially magnesium-free and sodium-free. In this case, magnesium and sodium are not left on the surface of the aluminum member and thus it is assumed that a functional group on the surface of the aluminum member and a triazine thiol derivative contained in the coating are molecular bonded to each other while the functional group on the surface of the aluminum member is not deprived by these elements. Thus, this composite member has a structure that improves bonding strength and airtightness between the aluminum member and the resin member. 
     In an embodiment, the surface of the aluminum member may be substantially iron-free and calcium-free. In this case, iron and calcium are not left on the surface of the aluminum member and thus it is assumed that a functional group on the surface of the aluminum member and a triazine thiol derivative contained in the coating are molecular bonded to each other while the functional group on the surface of the aluminum member is not deprived by these elements. Thus, this composite member has a structure that improves bonding strength and airtightness between the aluminum member and the resin member. 
     In an embodiment, an arithmetic mean inclination on the surface of the aluminum member bonded to the coating may be 0.17 or more and 0.50 or less. By using the aluminum member having a surface with an arithmetic mean inclination of 0.17 or more and 0.50 or less, the composite member can increase the surface area of the aluminum member, thereby properly obtaining an anchor effect. 
     In an embodiment, a root-mean-square inclination on the surface of the aluminum member bonded to the coating may be 0.27 or more and 0.60 or less. By using the aluminum member having a surface with a root-mean-square inclination of 0.27 or more and 0.60 or less, the composite member can increase the surface area of the aluminum member, thereby properly obtaining an anchor effect. 
     According to an aspect and an embodiment of the present disclosure, a method of manufacturing a composite member having high bonding strength and airtightness and a composite member having high bonding strength and airtightness are provided. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG.  1    is a perspective view illustrating a composite member according to an embodiment; 
         FIG.  2    is a cross-sectional view of the composite member taken along line II-II of  FIG.  1   ; 
         FIG.  3    is a conceptual diagram illustrating the composite member of  FIG.  2   ; 
         FIG.  4    is a conceptual diagram illustrating a blasting machine used for a method of manufacturing the composite member according to the embodiment; 
         FIG.  5    is an explanatory drawing illustrating the configuration of the blasting machine used for the method of manufacturing the composite member according to the embodiment; 
         FIG.  6    is a cross-sectional view of a blast nozzle illustrated in  FIG.  5   ; 
         FIG.  7    is a top view of a mold used for injection molding; 
         FIG.  8    is a cross-sectional view of the mold taken along line VIII-VIII of  FIG.  7   ; 
         FIG.  9    is a flowchart of the method of manufacturing the composite member according to the embodiment; 
         FIG.  10    is a conceptual diagram of blasting; 
         FIG.  11    is an explanatory drawing of a scan of blasting; 
         FIGS.  12 A- 12 E  are explanatory drawings of the manufacturing process of the composite member; and 
         FIG.  13    indicates the analysis results of the surface compositions of aluminum members. 
     
    
    
     DETAILED DESCRIPTION 
     An embodiment will be described below with reference to the accompanying drawings. In the following explanation, the same or equivalent elements are indicated by the same reference numerals and a duplicate explanation thereof is omitted. Moreover, “bonding strength” in the present embodiment will be described as “shearing strength”. A blasting material (an abrasive grain) in the present embodiment is a component to be injected during blasting. Examples of the blasting material includes ceramic (alumina, silicon carbide) grains. The particle size of the blasting material in the present embodiment is indicated by a mean particle diameter (D50) unless otherwise specified. 
     [Composite Member] 
       FIG.  1    is a perspective view illustrating a composite member  1  according to the embodiment. As illustrated in  FIG.  1   , the composite member  1  is a member including a plurality of members integrated by bonding. For example, the composite member  1  includes an aluminum member  2 , a coating  3  bonded to the aluminum member  2 , and a resin member  4  bonded to the coating  3 . The aluminum member  2  is, for example, a plate member. The coating  3  is interposed between the aluminum member  2  and the resin member  4  and is in direct contact with the surfaces of the members. In  FIG.  1   , the resin member  4  is bonded to a part or the whole of the surface of the aluminum member  2  with the coating  3  interposed therebetween and has a lap joint structure. The material of the aluminum member  2  is, for example, A5052 or ADC12. The material is not limited thereto. The materials of the resin member  4  include resins such as polybutylene terephthalate, polyphenylene sulfide, polyamide, a liquid crystal polymer, polypropylene, and acrylonitrile-butadiene-styrene. 
       FIG.  2    is a cross-sectional view of the composite member  1  taken along line II-II of  FIG.  1   . As illustrated in  FIG.  2   , the aluminum member  2  has asperities  2   b  on a part of a surface  2   a . Hereinafter, the surface  2   a  of the aluminum member  2  is the outermost surface layer of the aluminum member  2  regardless of the presence or absence of treatment and modifying on the surface. The surface  2   a  of the aluminum member  2  is also referred to as a surface  2   c  of the asperities  2   b  when the surface layer of the asperities  2   b  are particularly described. The asperities  2   b  are micro-order asperities. The micro-order asperities are asperities having a height difference of 1 μm or more and 1000 μm or less.  FIG.  3    is a conceptual diagram illustrating the composite member of  FIG.  2   . As illustrated in  FIG.  3   , tilting portions  2   e  are formed on the asperities  2   b  in such a manner as to tilt from a projection to a recess of the asperities  2   b . The tilting portions  2   e  contribute to bonding to the coating  3 , which will be described later, and bonding to the resin member  4  and serve as stress concentrating portions that contribute to shearing strength. Arithmetic mean roughness Ra determined for the asperities  2   b  by JIS B 0601(1994) may be 0.7 μm or more and 5.0 μm or less. An arithmetic mean inclination RΔa determined for the asperities  2   b  by JIS B 0601(1994) may be 0.17 or more and 0.50 or less as obtained by an arithmetic expression in  FIG.  3   . A root-mean-square inclination RΔq determined for the asperities  2   b  by JIS B 0601(1994) may be 0.27 or more and 0.60 or less. On the surface  2   c  of the asperities  2   b , a modifying layer (e.g., a surface nano structure described later) of aluminum hydroxide, which will be described later, is formed. The resin member  4  is fixed into the asperities  2   b  and thus produces an anchor effect. 
     Referring to  FIG.  2    again, the composite member will be described. On the asperities  2   b  of the aluminum member  2 , a surface nano structure  2   d  is formed. The surface nano structure  2   d  is made of aluminum hydroxide. For example, on the surface  2   c  of the asperities  2   b  formed on the aluminum member  2 , the surface nano structure  2   d  made of aluminum hydroxide is formed. In other words, the surface nano structure  2   d  is exposed on the surface  2   a  of the aluminum member  2 . The surface nano structure  2   d  is a film that is made of aluminum hydroxide and is spongy (porous). The surface nano structure  2   d  has a plurality of pores with a pore size of 10 nm or more and less than 1000 nm. The surface nano structure  2   d  is 0.01 μm or more and 1 μm or less in thickness. The aluminum hydroxide is a hydroxide of aluminum and an aluminum compound having a hydroxyl group. The aluminum hydroxide formed on the surface  2   a  of the aluminum member  2  contains at least one of diaspore, boehmite, pseudo-boehmite, bayerite, norstrandite, gibbsite, and doyleite. The aluminum hydroxide formed on the surface  2   a  of the aluminum member  2  may be made of any one of diaspore, boehmite, pseudo-boehmite, bayerite, norstrandite, gibbsite, and doyleite. The aluminum hydroxide formed on the surface  2   a  of the aluminum member  2  may be made of a plurality of kinds of aluminum hydroxide selected from diaspore, boehmite, pseudo-boehmite, bayerite, norstrandite, gibbsite, and doyleite. 
     Between the aluminum member  2  and the coating  3 , impurities other than elements serving as a material of the aluminum member  2  and a material of the coating  3  are removed. For example, the surface  2   a  of the aluminum member  2  is substantially phosphorus-free. In other words, if the surface nano structure  2   d  is subjected to chemical composition analysis by X-ray photoelectron spectroscopy, phosphorus falls below the detection limit of X-ray photoelectron spectroscopy and is not detected. If the aluminum member  2  is substantially magnesium-free and sodium-free, the surface  2   a  of the aluminum member  2  is substantially magnesium-free and sodium-free. In other words, if the surface  2   a  of the aluminum member  2  is subjected to chemical composition analysis by X-ray photoelectron spectroscopy, magnesium and sodium fall below the detection limit of X-ray photoelectron spectroscopy and are not detected. If pure water is used when the aluminum member  2  is modified into aluminum hydroxide, the surface  2   a  of the aluminum member  2  is substantially iron-free and calcium-free. In other words, if the surface  2   a  of the aluminum member  2  is subjected to chemical composition analysis by X-ray photoelectron spectroscopy, iron and calcium fall below the detection limit of X-ray photoelectron spectroscopy and are not detected. 
     The surface  2   a  of the aluminum member  2  is covered with the coating  3 , the surface  2   a  being modified into aluminum hydroxide and having a surface nano structure. The coating  3  contains a triazine thiol derivative including at least one functional group selected from primary amine, secondary amine, tertiary amine, an epoxy group, a hydroxy group, a thiol group, an azido group, and an alkyl group. The coating  3  is formed with a composition including a triazine thiol derivative. The triazine thiol derivative is a compound obtained by changing a part of the structure of triazine thiol through substitution or other chemical reactions. Examples of the triazine thiol derivative contained in the coating  3  include 6-(3-(Triethoxysilyl)propylamino)-1,3,5-triazine-2,4-Dithiol-Monosodium Salt (TES), 6-(3-(Ethoxydimethylsilylpropylamino)-1,3,5-triazine-2,4-Dithiol-Monosodium (IVIES), and 6-bis(3-(Triethoxysilyl)propyl)amino-1,3,5-triazine-2,4-Dithiol-Monosodium (B-TES). The triazine thiol derivative contained in the coating  3  may be a derivative not containing silane. Specifically, the derivative may be 6-(4-vinylbenzyl-n-propyl)amino-1,3,5-triazine-2,4-dithiol, 1,3,5-triazine-2,4,6-trithiol, 6-dimethylamino-1,3,5-triazine-2,4-dithiol, 6-benzylamino-1,3,5-triazine-2,4-dithiol, 6-dibutylamino-1,3,5-triazine-2,4-dithiol, 6-dioctylamino-1,3,5-triazine-2,4-dithiol, 6-didodecathylamino-1,3,5-triazine-2,4-dithiol, 6-diallylamino-1,3,5-triazine-2,4-dithiol, 6-dioleoylamino-1,3,5-triazine-2,4-dithiol, or a salt thereof. 
     The functional groups in the triazine thiol derivative of the coating  3  and aluminum hydroxide on the surface  2   a  of the aluminum member  2  form a chemical bond. The functional group in the triazine thiol derivative of the coating  3  is at least one functional group selected from primary amine, secondary amine, tertiary amine, an epoxy group, a hydroxy group, a thiol group, an azido group, and an alkyl group. The functional group of aluminum hydroxide on the surface of the aluminum member  2  is a hydroxy group. For example, if the triazine thiol derivative of the coating  3  is TES and a hydroxy group is present on the surface  2   a  of the aluminum member  2 , an alkyl group contained in the TES and the hydroxy group on the surface  2   a  of the aluminum member  2  react with each other and form a chemical bond. Thus, the aluminum member  2  and the coating  3  are bonded to each other, and the surface  2   a  of the aluminum member  2 , on which the asperities  2   b  and the surface nano structure  2   d  are formed, is covered with the coating  3 . The coating  3  is bonded to the surface  2   a  of the aluminum member  2  while being partially placed into the asperities  2   b  on the surface  2   a  of the aluminum member  2  and the pores of the surface nano structure  2   d.    
     The resin member  4  is bonded to the coating  3  while being partially placed into the asperities  2   b  on the surface  2   a  of the aluminum member  2  and the pores of the surface nano structure  2   d . The triazine thiol derivative of the coating  3  and the functional group on the surface of the resin member  4  form a chemical bond. In this case, the functional group in the triazine thiol derivative of the coating  3  is, for example, a thiol group. The functional group in the resin member  4  is, for example, a hydrocarbon radical or a hydroxy group. For example, if the triazine thiol derivative of the coating  3  is TES, by a reaction (copolymerization) between the thiol group of TES and a hydrocarbon radical contained in the resin member  4 , a carbon atom contained in the resin member  4  substitutes for a sulfur atom, and the coating  3  and the resin member  4  are bonded to each other. The resin member  4  is bonded to the aluminum member  2  by a chemical bond formed by the coating  3 . 
     As described above, the composite member  1  according to the present embodiment has the micro-order asperities  2   b  partially on the surface  2   a  of the aluminum member  2  that is in contact with the resin member  4 . Furthermore, the surface nano structure  2   d  is formed on the asperities  2   b . The surface nano structure  2   d  is made of aluminum hydroxide. The surface nano structure  2   d  has a plurality of pores with a pore size of 10 nm or more and less than 1000 nm. The triazine thiol derivative contained in the coating  3  and the functional group of aluminum hydroxide on the surface  2   a  of the aluminum member  2  form a chemical bond, thereby bonding the coating  3  to the aluminum member  2 . Thus, three effects are combined as follows: the formation of the coating  3  into the asperities  2   b  on the surface  2   a  of the aluminum member  2 , the formation of the coating  3  into the surface nano structure  2   d  with a contact surface area extended between the aluminum member  2  and the coating  3  by the surface nano structure  2   d  on the surface layer of the asperities  2   b , and molecular bonding between the functional group on the surface  2   c  of the asperities  2   b  and the triazine thiol derivative contained in the coating. An organic combination of these three configurations produces a synergy effect, which cannot be obtained by simply adding the effects of the individual configurations, achieving strong bonding. The resin member  4  is then bonded to the surface  2   a  of the aluminum member  2  with the coating  3  interposed therebetween. The resin member  4  is strongly bonded by molecular bonding between the functional group on the surface and the triazine thiol derivative contained in the coating  3 . Also when the asperities  2   b  formed on the surface  2   a  of the aluminum member  2  have sharp portions, the sharp portions are rounded by forming the surface nano structure  2   d  (forming a film of aluminum hydroxide) and are strongly bonded to the coating  3  as described above. Thus, the composite member  1  achieves an additional effect of reducing the occurrence of breaks on the coating  3  and the resin member  4  from sharp portions. The surface nano structure  2   d  is formed on the tilting portions  2   e , which serve as stress concentrating portions on the asperities  2   b , to obtain an anchor effect and the chemical bonding forces are applied, thereby achieving higher bonding strength and higher airtightness. As described above, with a chemical bond by molecular bonding and a mechanical bond by an anchor effect in a large surface area, the composite member  1  is configured such that the aluminum member  2  and the resin member  4  are strongly and tightly bonded to each other with the coating  3  interposed therebetween. The tightly bonded composite member  1  has high airtightness and high thermal conductivity at a bonded interface, achieving high practicability. Thus, this composite member  1  can improve bonding strength and airtightness between the aluminum member  2  and the resin member  4 . If airtightness is not obtained between the aluminum member and the resin member, for example, water enters between the aluminum member and the resin member from the outside and corrodes an interface, resulting in a large reduction in bonding strength and airtightness. If the composite member keeps only high bonding strength, the stability of the interface is obtained only after high airtightness is secured, resulting in no practical use for the composite member. In the composite member  1  of the present embodiment, high bonding strength and high airtightness are obtained by the anchor effect by the asperities  2   b  and the surface nano structure  2   d  and strong chemical bonding forces between the aluminum member  2  and the coating  3  and between the coating  3  and the resin member  4 . Thus, high stability is kept at the interface between the aluminum member  2  and the resin member  4  in the composite member  1 . Hence, the composite member  1  is practical and reliable and can be used for various purposes. For example, the composite member  1  is applicable to an apparatus requiring high airtightness and high thermal conductivity. For example, on a sealing portion between a resin terminal strip used for manufacturing semiconductors and an aluminum conductor, sealing is conventionally performed as retrofitting by using encapsulating resins such as an epoxy resin liquid, whereas by applying the composite member  1  of the present embodiment, high airtightness can be obtained and the heat dissipation and cooling of the aluminum conductor are facilitated. 
     In the composite member  1 , the surface  2   a  of the aluminum member  2  is substantially phosphorus-free, and the aluminum hydroxide contains at least one of boehmite, pseudo-boehmite, diaspore, bayerite, norstrandite, gibbsite, and doyleite. Phosphorus is not left on the surface  2   a  of the aluminum member  2  and thus it is assumed that a functional group on the surface  2   a  of the aluminum member  2  and a triazine thiol derivative contained in the coating  3  are molecular bonded to each other while the functional group on the surface  2   a  of the aluminum member  2  is not deprived by these elements. Thus, this composite member  1  has a structure that improves bonding strength and airtightness between the aluminum member  2  and the resin member  4 . 
     The triazine thiol derivative in the composite member  1  contains at least one functional group selected from primary amine, secondary amine, tertiary amine, an epoxy group, a hydroxy group, a thiol group, an azido group, and an alkyl group. In this case, in the composite member  1 , the coating  3  is formed by binding the triazine thiol derivative and the functional group on the surface  2   a  of the aluminum member  2  made of aluminum hydroxide. Subsequently, the triazine thiol derivative contained in the coating  3  and the functional group on the surface of the resin member  4  bind to each other, and the resin member  4  is bonded to the surface of the aluminum member  2  on which the coating  3  is formed. In this way, the coating  3  is molecular bonded to the aluminum member  2  made of aluminum hydroxide and the resin member  4  by the functional group of the triazine thiol derivative, so that the coating  3  is strongly bonded. 
     In the composite member  1 , the surface  2   a  of the aluminum member  2  is substantially magnesium-free and sodium-free. Magnesium and sodium are not left on the surface  2   a  of the aluminum member  2  and thus it is assumed that a functional group on the surface  2   c  of the aluminum member  2  and a triazine thiol derivative contained in the coating  3  are molecular bonded to each other while the functional group on the surface  2   a  of the aluminum member  2  is not deprived by these elements. Thus, this composite member  1  has a structure that improves bonding strength and airtightness between the aluminum member  2  and the resin member  4 . 
     In the composite member  1 , the surface  2   a  of the aluminum member  2  is substantially iron-free and calcium-free. Iron and calcium are not left on the surface  2   a  of the aluminum member  2  and thus it is assumed that a functional group on the surface  2   a  of the aluminum member  2  and a triazine thiol derivative contained in the coating  3  are molecular bonded to each other while the functional group on the surface  2   a  of the aluminum member  2  is not deprived by these elements. Thus, this composite member  1  has a structure that improves bonding strength and airtightness between the aluminum member  2  and the resin member  4 . 
     In the composite member  1 , an arithmetic mean inclination RΔa on the surface  2   a  of the aluminum member  2  bonded to the coating  3  is 0.17 or more and 0.50 or less. By using the aluminum member  2  having the surface  2   a  with an arithmetic mean inclination RΔa of 0.17 or more and 0.50 or less, the composite member  1  can increase the surface area of the aluminum member  2 , thereby properly obtaining an anchor effect. 
     In the composite member  1 , a root-mean-square inclination RΔq on the surface  2   a  of the aluminum member  2  bonded to the coating  3  is 0.27 or more and 0.60 or less. By using the aluminum member  2  having the surface  2   a  with a root-mean-square inclination RΔq of 0.27 or more and 0.60 or less, the composite member  1  can increase the surface area of the aluminum member  2 , thereby properly obtaining an anchor effect. 
     [Method of Manufacturing the Composite Member] 
     The outline of a machine used for the method of manufacturing the composite member  1  will be described below. The machine for blasting the surface  2   a  of the aluminum member  2  will be first discussed below. The blasting machine may be any type of a gravity (suction) air-blast machine, a straight-hydraulic (pressure) air-blast machine, and a centrifugal blasting machine. In the manufacturing method according to the present embodiment, a so-called straight-hydraulic (pressure) air-blast machine is used as an example.  FIG.  4    is a conceptual diagram illustrating a blasting machine  10  used for the method of manufacturing the composite member  1 . The blasting machine  10  includes a blast chamber  11 , a blast nozzle  12 , a storage tank  13 , a pressure chamber  14 , a compressed-air feeder  15 , and a dust collector (not illustrated). 
     The blast nozzle  12  is stored in the blast chamber  11  and blasting is performed on a workpiece (aluminum member  2 ) in the blast chamber  11 . A blasting material from the blast nozzle  12  fall with dust to the bottom of the blast chamber  11 . The fallen blasting material is fed into the storage tank  13  and the dust is fed into the dust collector. The blasting material stored in the storage tank  13  is fed into the pressure chamber  14  and then the pressure chamber  14  is pressurized by the compressed-air feeder  15 . The blasting material stored in the pressure chamber  14  is fed with compressed air into the blast nozzle  12 . In this way, the workpiece undergoes blasting while the blasting material is circulated. 
       FIG.  5    is an explanatory drawing illustrating the configuration of the blasting machine  10  used for the method of manufacturing the composite member  1  according to the embodiment. The blasting machine  10  in  FIG.  5    is the straight-hydraulic blasting machine illustrated in  FIG.  4   . In  FIG.  5   , the wall surface of the blast chamber  11  is partially omitted. 
     As illustrated in  FIG.  5   , the blasting machine  10  includes the blasting-material storage tank  13  and the pressure chamber  14  that are connected to the compressed-air feeder  15  and have sealed structures, a fixed-quantity feeding part  16  communicating with the storage tank  13  in the pressure chamber  14 , the blast nozzle  12  communicating with the fixed-quantity feeding part  16  via a connecting pipe  17 , a work table  18  that can move while holding a workpiece below the blast nozzle  12 , and a control unit  19 . 
     The control unit  19  controls the constituent elements of the blasting machine  10 . The control unit  19  includes, for example, a display unit and a processing unit. The processing unit is a typical computer including a CPU and a storage unit. The control unit  19  controls a feed rate from the compressed-air feeder  15  that feeds compressed air to the storage tank  13  and the pressure chamber  14  based on a set projection pressure and a set blast velocity. Moreover, the control unit  19  controls the position of a blast from the blast nozzle  12  based on a distance between the set workpiece and the nozzle and the scanning conditions (including a speed, a feed pitch, and the number of scans) of the workpiece. As a specific example, the control unit  19  controls the position of the blast nozzle  12  by using a scanning speed (X direction) and a feed pitch (Y direction) that are set before blasting. The control unit  19  controls the position of the blast nozzle  12  by moving the work table  18  holding the workpiece. 
       FIG.  6    is a cross-sectional view of the blast nozzle  12  illustrated in  FIG.  5   . The blast nozzle  12  has a blast-tube holder  120  serving as a body part. The blast-tube holder  120  is a cylindrical member having a space for passing the blasting material and compressed air therein. One end of the blast-tube holder  120  is a blasting-material inlet port  123  and the other end of the blast-tube holder  120  is a blasting-material outlet port  122 . The blast-tube holder  120  includes a convergence acceleration part  121  that is conical with an angle of tilt, the convergence acceleration part  121  having an inner wall surface tapering from the blasting-material inlet port  123  toward the blasting-material outlet port  122 . A cylindrical blast tube  124  communicates with the blasting-material outlet port  122  of the blast-tube holder  120 . The convergence acceleration part  121  tapers from the midpoint of the cylindrical shape of the blast-tube holder  120  toward the blast tube  124 . This forms a compressed airflow  115 . 
     The connecting pipe  17  of the blasting machine  10  is connected to the blasting-material inlet port  123  of the blast nozzle  12 . This forms a blasting material passage that sequentially connects the storage tank  13 , the fixed-quantity feeding part  16  in the pressure chamber  14 , the connecting pipe  17 , and the blast nozzle  12 . 
     In the blasting machine  10  configured thus, compressed air is fed from the compressed-air feeder  15  to the storage tank  13  and the pressure chamber  14  after the quantity of compressed air is controlled by the control unit  19 . Subsequently, the blasting material in the storage tank  13  is quantitatively determined by the fixed-quantity feeding part  16  in the pressure chamber  14  with a constant pressure flow force, the blasting material is fed into the blast nozzle  12  through the connecting pipe  17 , and then the blasting material is directed from the blast tube  124  of the blast nozzle  12  onto the work surface of the workpiece. Thus, a fixed quantity of the blasting material is always directed onto the work surface of the workpiece. Subsequently, the position of a blast directed from the blast nozzle  12  onto the work surface of the workpiece is controlled by the control unit  19  and then the workpiece undergoes blasting. 
     The directed blasting material and cut powder generated by blasting are sucked by the dust collector, which is not illustrated. On a passage from the blast chamber  11  to the dust collector, a classifier, which is not illustrated, is disposed to separate reusable blasting material and other fine powder (blasting material not in a reusable size or cut powder generated by blasting). The reusable blasting material is stored in the storage tank  13  and then are fed into the blast nozzle  12  again. The fine powder is collected by the dust collector. 
     Injection molding will be described below. In this case, insert molding is used as injection molding. In insert molding, an insert is placed into a predetermined mold and then resin is injected and is cured after being retained for a predetermined period of time. Thereafter, the residual stress of the resin is removed by heat treatment.  FIG.  7    is a top view of a mold used for injection molding;  FIG.  8    is a cross-sectional view of the mold taken along line VIII-VIII of  FIG.  7   . As illustrated in  FIGS.  7  and  8   , a mold  20  includes a mold body  21  (a cope  21   a  and a drag  21   b ). Between the cope  21   a  and the drag  21   b , a space  22  for placing the insert (in this configuration, the aluminum member  2 ) and a space  23  for injecting resin are provided. On the top surface of the cope  21   a , a resin inlet is provided. The resin inlet communicates with the space  23  through a sprue  24 , a runner  25 , and a gate  26 . A pressure sensor  27  and a temperature sensor  28  are provided in the space  23  and detect a pressure and a temperature in the space  23 . Based on the detection results of the pressure sensor  27  and the temperature sensor  28 , the parameters of a molding machine, which is not illustrated, are adjusted and then a molded article is manufactured. The parameters include a mold temperature, a temperature of resin being charged, a charging pressure, an injection rate, a retention time, a pressure during retention, a heat treatment temperature, and a heat treatment time. The article molded by the mold  20  has a lap joint structure that is joined with a predetermined area. 
     The flow of the method of manufacturing the composite member  1  will be described below.  FIG.  9    is a flowchart of a method MT of manufacturing the composite member  1  according to the embodiment. As depicted in  FIG.  9   , first, predetermined blasting material is charged into the blasting machine  10  as a preparing step (S 10 ). The particle size of the blasting material is, for example, 30 μm to 710 μm. The smaller the particle size of the blasting material is, the smaller mass of the blasting material is. This leads to a small inertial force. Thus, if the particle size of the blasting material is smaller than 30 μm, it is difficult to form the asperities  2   b  in desired shapes. Moreover, the aluminum member  2  to be industrially used is typically stored in the atmosphere and the surface of the aluminum member  2  is covered with an uneven aluminum natural oxide film having a thickness of 60 nm to 300 nm. Hence, surface etching using a chemical agent and surface laser beam machining may cause uneven surface treatment because of the aluminum natural oxide film. In order to uniformly modify the surface  2   a  of the aluminum member  2  in a surface hydroxylation step, which will be discussed later, the aluminum natural oxide film needs a thickness of about 30 nm or less. However, if the particle diameter of the blasting material exceeds 710 μm, it is difficult to grind the aluminum natural oxide film to a thickness of about 30 nm or less. Hence, the natural oxide formed on the surface  2   a  of the aluminum member  2  before performing a blasting step (S 12 ) cannot be sufficiently removed. The blasting step will be discussed later. The asperities  2   b  can be formed and the aluminum natural oxide film can be removed if abrasive grains have a particle size of 30 μm to 710 μm. The material of the blasting material, for example, alumina. The blasting material has, for example, sharp projections. 
     The control unit  19  of the blasting machine  10  acquires blasting conditions as the preparing step (S 10 ). The control unit  19  acquires the blasting conditions based on an operation by an operator or information stored in the storage unit. The blasting conditions include a projection pressure, a blast velocity, a distance between nozzles, and workpiece scanning conditions (a speed, a feed pitch, and the number of scans). The projection pressure is, for example, 0.5 MPa or more and 2.0 MPa or less. The lower the projection pressure, the smaller the inertial force. Thus, if the projection pressure is smaller than 0.5 MPa, it is difficult to form the asperities  2   b  in desired shapes. The higher the projection pressure, the larger the inertial force. Hence, the blasting material is likely to be crushed by a collision with the aluminum member  2 . This leads to the following problems: (1) poor working efficiency caused by the dispersion of collision energy in a process other than the formation of the asperities  2   b  and (2) high cost because of considerable wear of the blasting material. Such problems become apparent when the projection pressure exceeds 2.0 MPa. The control unit  19  precisely performs micro-order or nano-order control on the size, depth, and density of the asperities  2   b  on the surface  2   a  of the aluminum member  2  by managing the blasting conditions. The blasting conditions may include a condition for specifying a blasting region. In this case, selective surface treatment is achieved. 
     Subsequently, the blasting machine  10  performs a series of processing as the blasting step (S 12 ) as follows: First, the aluminum member  2  as a target of blasting is set on the work table  18  in the blast chamber  11 . The aluminum member  2  is substantially magnesium-free and sodium-free. The control unit  19  then activates the dust collector, which is not illustrated. The dust collector reduces a pressure in the blast chamber  11  to a negative pressure based on the control signal of the control unit  19 . Thereafter, based on the control signal of the control unit  19 , the blast nozzle  12  sends a blast of the blasting material as a solid/gas two-phase flow of compressed air at a projection pressure of 0.5 MPa or more and 2.0 MPa or less. The control unit  19  then activates the work table  18  and moves the aluminum member  2  into a blast flow of the solid/gas two-phase flow (below the blast nozzle in  FIG.  5   ).  FIG.  10    is a conceptual diagram of blasting. As illustrated in  FIG.  10   , the blasting material is injected from the blast nozzle  12  to a partial region 2f of the surface  2   a  of the aluminum member  2 . At this point, the control unit  19  continuously activates the work table  18  such that a blast flow draws a predetermined path on the aluminum member  2 .  FIG.  11    is an explanatory drawing of a scan of blasting; As illustrated in  FIG.  11   , the control unit  19  operates the work table  18  according to a path L for scanning with the feed pitch P.  FIGS.  12 A- 12 E  are explanatory drawings of the manufacturing process of the composite member; and as illustrated in  FIG.  12 A , the asperities  2   b  are not formed on the aluminum member  2  before blasting. By operating the work table  18 , as illustrated in  FIG.  12 B , the desired micro-order asperities  2   b  are formed on the surface  2   a  of the aluminum member  2 . 
     By blasting using the blasting material having a particle size of 30 μm or more and 710 μm or less at a projection pressure of 0.5 MPa or more and 2.0 MPa or less, the desired micro-order asperities  2   b  are formed on the surface  2   a  of the aluminum member  2 . By blasting, the arithmetic mean roughness Ra determined for the asperities  2   b  by JIS B 0601(1994) may be set at 0.7 μm or more and 5.0 μm or less. By blasting, the arithmetic mean inclination RΔa determined for the asperities  2   b  by JIS B 0601(1994) may be 0.17 or more and 0.50 or less. By blasting, the root-mean-square inclination RΔq determined for the asperities  2   b  by JIS B 0601(1994) may be set at 0.27 or more and 0.60 or less. Furthermore, the natural oxide film on the surface  2   a  of the aluminum member  2  has a thickness of, for example, about 9 nm or less. After the operation of the blasting machine  10  is stopped, the aluminum member  2  is removed and blasting is completed. As illustrated in  FIG.  12 B , the asperities  2   b  on the surface  2   a  of the aluminum member  2  have sharp projections after blasting. 
     Subsequently, as the surface hydroxylation step (S 14 ), the surface  2   a  of the aluminum member  2  on which asperities  2   b  are formed is subjected to hydrothermal treatment, so that the surface  2   c  of the asperities  2   b  is modified into aluminum hydroxide and the surface nano structure  2   d  is formed on the surface  2   c  of the asperities  2   b . In hydrothermal treatment in the surface hydroxylation step, the surface  2   a  of the aluminum member  2  and heated water are caused to react with each other. In hydrothermal treatment, the aluminum member  2  on which the asperities  2   b  are formed is immersed in pure water, which is heated to 70° C. or more and 100° C. or less, for a predetermined period. The electric conductivity of pure water used in the surface hydroxylation step (S 14 ) is 0.054 μS/cm or more and 10 μS/cm or less. The pure water is substantially magnesium-free, sodium-free, and phosphorus-free. Furthermore, the pure water is substantially iron-free and calcium-free. In other words, magnesium, sodium, phosphorus, iron, and calcium in the pure water fall below the detection limit of X-ray photoelectron spectroscopy. Thus, the surface  2   c  of the asperities  2   b  is mainly modified into boehmite, thereby forming the surface nano structure  2   d . By using the pure water, residual impurities other than aluminum hydroxide on the surface  2   a  of the aluminum member  2  can be reduced. In particular, magnesium, sodium, phosphorus, iron, and calcium are not left on the surface  2   a  of the aluminum member  2  and thus it is assumed that a functional group on the surface  2   a  of the aluminum member  2  and a triazine thiol derivative contained in the coating  3  are molecular bonded to each other while the functional group on the surface of the aluminum member  2  is not deprived by these elements. The aluminum hydroxide formed on the surface  2   a  of the aluminum member  2  is not limited to boehmite and may be made of any one of diaspore, pseudo-boehmite, bayerite, norstrandite, gibbsite, and doyleite. The aluminum hydroxide formed on the surface  2   a  of the aluminum member  2  may be made of a plurality of kinds of aluminum hydroxide selected from diaspore, boehmite, pseudo-boehmite, bayerite, norstrandite, gibbsite, and doyleite. As illustrated in  FIG.  12 C , the surface nano structure  2   d  is formed on the surface  2   c  of the asperities  2   b . The surface nano structure  2   d  is a film that is made of aluminum hydroxide and is spongy (porous). The surface nano structure  2   d  has a plurality of pores with a pore size of 10 nm or more and less than 1000 nm. The surface nano structure  2   d  is 0.01 μm or more and 1 μm or less in thickness. Thus, the spongy (porous) surface nano structure  2   d  is formed on the sharp portions (sharp projections) of the asperities  2   b  formed by the blasting step (S 12 ) and is modified into aluminum hydroxide, thereby achieving an additional effect of reducing the occurrence of breaks on the coating  3 , which is placed into the asperities  2   b , and the resin member  4  from the sharp portions. The coating  3  will be described later. 
     After the blasting step (S 12 ), a natural oxide film peeled off by blasting or fine particles such as blasting material may be deposited on the surface  2   a  of the aluminum member  2 . For example, fine particles may be adsorbed to the surface  2   a  of the aluminum member  2  by an electrostatic force of the aluminum member  2  or may be collided into the surface  2   a  of the aluminum member  2  by a blasting force of the blasting material in the blast nozzle  12 . In this case, in the surface hydroxylation step (S 14 ), the surface  2   a  of the aluminum member  2  may be cleaned with water. Thus, fine particles on the surface  2   a  of the aluminum member  2  are removed and a surface carbon concentration can be reduced. Hydrothermal treatment and ultrasonic cleaning may be combined to positively reduce the surface carbon concentration. In other words, in the hydrothermal treatment, the surface  2   a  of the aluminum member  2  is cleaned with water (pure water) and the surface  2   a  of the aluminum member  2  is modified into aluminum hydroxide. For example, pure water is irradiated with ultrasonic waves while the aluminum member  2  is immersed in pure water heated to 70° C. or more and 100° C. or less. This can simultaneously perform hydrothermal treatment and surface washing. 
     Thereafter, as a coating step (S 16 ), a binder containing a triazine thiol derivative is applied to the surface  2   c  of the asperities  2   b  of the aluminum member  2 , which has been modified into aluminum hydroxide and has the surface nano structure  2   d , so that the coating  3  is formed by binding the triazine thiol derivative and a functional group on the surface  2   a  of the aluminum member  2  modified into aluminum hydroxide. As illustrated in  FIG.  12 D , the asperities  2   b  and the surface nano structure  2   d  on the surface  2   a  of the hydrothermally treated aluminum member  2  are coated with the coating  3 . The triazine thiol derivative contains at least one functional group selected from primary amine, secondary amine, tertiary amine, an epoxy group, a hydroxy group, a thiol group, an azido group, and an alkyl group. In a coating step (S 16 ), for example, immersion, spraying, or brush coating is performed such that the surface  2   a  of the aluminum member  2  and a binder containing a triazine thiol derivative react with each other. 
     First, the formation of the coating  3  by immersion will be described. The binder containing a triazine thiol derivative is liquid. In the immersion, the surface  2   a  of the aluminum member  2  modified into aluminum hydroxide is immersed in a liquid binder for a predetermined time. The triazine thiol derivative in the binder forms a chemical bond with a functional group (e.g., a hydroxyl group) on the surface  2   a  of the aluminum member  2 . In this way, the liquid binder containing the triazine thiol derivative can form a chemical bond in contact with the surface  2   a  of the aluminum member  2 , thereby forming the coating  3  on the surface  2   a  of the aluminum member  2 . 
     The formation of the coating  3  by spraying will be described below. In the spraying, for example, a liquid binder containing a triazine thiol derivative is stored in a spray container. The spray container can spray the liquid binder. In the spraying, the liquid binder is sprayed through the spray container onto the surface  2   a  of the aluminum member  2  modified into aluminum hydroxide and is deposited on the surface  2   a  of the aluminum member  2 . In this way, the liquid binder containing a triazine thiol derivative can be brought into contact with the surface  2   a  of the aluminum member  2 , thereby forming the coating  3  on the surface  2   a  of the aluminum member  2 . 
     The formation of the coating  3  by brush coating will be described below. In the brush coating, for example, a liquid binder containing a triazine thiol derivative is stored in a storage container, a brush is immersed into the storage container, and the liquid binder is applied to the brush. In the brush coating, the liquid binder is applied with the brush to the surface  2   a  of the aluminum member  2  modified into aluminum hydroxide and is deposited on the surface  2   a  of the aluminum member  2 . In this way, the liquid binder containing a triazine thiol derivative can be brought into contact with the surface  2   a  of the aluminum member  2 , thereby forming the coating  3  on the surface  2   a  of the aluminum member  2 . 
     In the coating step (S 16 ), ultrasonic cleaning may be performed with pure water after the coating  3  is formed by a reaction between the surface  2   a  of the aluminum member  2  and a binder containing a triazine thiol derivative. Thus, an unnecessary binder remaining around the coating  3  can be properly removed. 
     Subsequently, the molding machine, which is not illustrated, performs molding using the mold  20  as a bonding step (S 18 ). The mold  20  is first opened, the aluminum member  2  having the coating  3  is placed into the space  22 , and then the mold  20  is closed. The molding machine then injects dissolved resin, which has a set resin temperature, into the mold  20  from the resin inlet. The injected resin passes through the sprue  24 , the runner  25 , and the gate  26  and is charged into the space  23 . The molding machine controls the charging pressure and the injection rate of resin based on the detection result of the pressure sensor  27 . The molding machine controls a mold temperature to a set value based on the detection result of the temperature sensor  28 . Moreover, the molding machine controls a pressure to the set value during a set retention time based on the detection result of the pressure sensor  27 . Thereafter, the molding machine performs heat treatment based on a set heat-treatment temperature and a set heat-treatment time. At this point, as illustrated in  FIG.  12 E , the coating  3  and the resin member  4  are bonded to each other by copolymerization between a functional group (e.g., a thiol group, an azido group, and an amino group) contained in the coating  3  and the functional group of the resin member  4 . The molding machine then opens the mold  20  and removes the composite member  1  in which the aluminum member  2 , the coating  3 , and the resin member  4  are integrated. At the end of the bonding step (S 18 ), the flowchart in  FIG.  9    is completed. 
     As described above, according to the manufacturing method MT of the composite member  1 , blasting is performed on the surface  2   a  of the aluminum member  2 . In the blasting step (S 12 ), a natural oxide film formed on the surface  2   a  of the aluminum member  2  is reduced in thickness (removed) by blasting. The micro-order asperities  2   b  are formed on the surface  2   a  (a surface exposed by blasting) of the aluminum member  2  by blasting. By the surface hydroxylation step (S 14 ), the surface  2   a  (the surface  2   c  of the asperities  2   b ) of the aluminum member  2  on which the asperities  2   b  are formed is modified into aluminum hydroxide, and the surface nano structure  2   d  is formed on the surface  2   c  of the asperities  2   b . The surface nano structure  2   d  is made of aluminum hydroxide. By the modifying, a functional group (e.g., a hydroxy group) of aluminum hydroxide is applied to the asperities  2   b  of the aluminum member  2 . In the coating step (S 16 ), a binder containing a triazine thiol derivative is applied to the surface  2   a  of the aluminum member  2 , so that the coating  3  is formed by binding the triazine thiol derivative and a functional group on the surface  2   a  (asperities  2   b ) of the aluminum member  2  modified into aluminum hydroxide. Thus, three effects are combined as follows: the formation of the coating  3  into the asperities  2   b  of the aluminum member  2 , the formation of the coating  3  into the surface nano structure  2   d  with a contact surface area extended between the aluminum member  2  and the coating  3  by the surface nano structure  2   d  on the surface  2   c  of the asperities  2   b , and molecular bonding between the functional group on the surface  2   c  of the asperities  2   b  and the triazine thiol derivative contained in the coating  3 . An organic combination of these three configurations produces a synergy effect, which cannot be obtained by simply adding the effects of the individual configurations, achieving strong bonding. In a bonding step (S 18 ), the resin member  4  is bonded to the surface of the aluminum member  2  on which the coating  3  is formed. The resin member  4  is strongly bonded by molecular bonding between the functional group on the surface and the triazine thiol derivative contained in the coating  3 . Sharp portions on the asperities  2   b  formed by the blasting step (S 12 ) are rounded by the surface hydroxylation step (S 14 ) and are strongly bonded to the coating  3  as described above. Thus, the manufacturing method MT achieves an additional effect of reducing the occurrence of breaks on the coating  3  and the resin member  4  from sharp portions (sharp projections). As described above, with a chemical bond by molecular bonding and a mechanical bond by an anchor effect in a large surface area, the composite member  1  is manufactured such that the aluminum member  2  and the resin member  4  are strongly and tightly bonded to each other with the coating  3  interposed therebetween. The tightly bonded composite member  1  has high airtightness and high thermal conductivity at a bonded interface, achieving high practicability. Thus, according to the manufacturing method MT of the composite member  1 , the composite member  1  can be manufactured with high bonding strength and airtightness. If airtightness is not obtained between the aluminum member and the resin member, for example, water enters between the aluminum member and the resin member from the outside and corrodes an interface, resulting in a large reduction in bonding strength and airtightness. If the composite member keeps only high bonding strength, the stability of the interface is obtained only after high airtightness is secured, resulting in no practical use for the composite member. In the composite member  1  of the present embodiment, high bonding strength and high airtightness are obtained by the anchor effect by the asperities  2   b  and the surface nano structure  2   d  and strong chemical bonding forces between the aluminum member  2  and the coating  3  and between the coating  3  and the resin member  4 . Thus, high stability is kept at the interface between the aluminum member  2  and the resin member  4  in the composite member  1 . Hence, the composite member  1  is practical and reliable and can be used for various purposes. For example, the composite member  1  is applicable to an apparatus requiring high airtightness and high thermal conductivity. For example, on a sealing portion between a resin terminal strip used for manufacturing semiconductors and an aluminum conductor, sealing is conventionally performed as retrofitting by using encapsulating resins such as an epoxy resin liquid, whereas by applying the composite member  1  of the present embodiment, high airtightness can be obtained and the heat dissipation and cooling of the aluminum conductor are facilitated. 
     In the manufacturing method MT, a plurality of pores having a pore size of 10 nm or more and less than 1000 nm are formed on the surface nano structure  2   d , and the surface nano structure  2   d  has a thickness of 0.01 μm or more and 1 μm or less. In this case, the resin member  4  is applied into the plurality of pores formed on the surface nano structure  2   d  and is hardened therein, achieving an anchor effect. Thus, in this manufacturing method MT, the surface nano structure  2   d  is formed on the surface  2   a  of the aluminum member  2  by the surface hydroxylation step (S 14 ), so that the aluminum member  2  can be changed to a shape including the coating  3  and the resin member  4  with higher adhesion than an aluminum member  2  having not been subjected to the surface hydroxylation step (S 14 ). 
     According to the manufacturing method MT, in the blasting step (S 12 ), blasting material having sharp projections with a particle size of 30 μm or more and 710 μm or less may be injected to blast with a projection pressure of 0.5 MPa or more and 2.0 MPa or less. Thus, in this manufacturing method MT, the asperities  2   b  can be formed on the surface  2   a  of the aluminum member  2  after the natural oxide film formed on the surface  2   a  of the aluminum member  2  is properly removed, thereby forming the uniform surface nano structure  2   d  on the surface  2   a  of the aluminum member  2  in the surface hydroxylation step (S 14 ) and properly achieving an anchor effect. In this case, if spherical blasting material such as glass beads is used to perform blasting, asperities like dimples are formed on the surface  2   a  of the aluminum member  2 . The asperities and the resin member  4  are hardly fit to each other, and the resin member  4  is difficult to lock onto the asperities, so that the composite member is formed and obtained with low bonding strength. By using the blasting material having sharp projections, the asperities  2   b  can be formed like spikes (sharp projections). The asperities  2   b  like spikes are formed on the surface  2   a  of the aluminum member  2 , so that the resin member  4  is fit onto the asperities  2   b . Thus, the resin member  4  fit onto the asperities  2   b  like spikes exhibits high bonding strength between the resin member  4  and the aluminum member  2 . 
     According to the manufacturing method MT, in hydrothermal treatment in the surface hydroxylation step (S 14 ), the hydrothermal treatment is performed on the surface  2   a  of the aluminum member  2  such that the surface  2   a  reacts with pure water at 70° C. or more and 100 C° or less. The surface of the aluminum member  2  can be modified by the foregoing treatment. If the aluminum member  2  is substantially magnesium-free and sodium-free, the interface (surface  2   a ) of the aluminum member  2  in the composite member  1  manufactured by the manufacturing method MT is substantially magnesium-free, sodium-free, and phosphorus-free. 
     According to the manufacturing method MT, the electric conductivity of pure water is 0.054 μS/cm or more and 10 μS/cm or less. Pure water with a low electric conductivity has a low impurity content. In the manufacturing method MT, residual impurities other than aluminum hydroxide on the surface  2   a  of the aluminum member  2  can be reduced by using pure water having the electric conductivity in the surface hydroxylation step (S 14 ). The impurities are, for example, magnesium, sodium, phosphorus, iron, and calcium. Thus, the manufacturing method MT can prevent impurities from depriving a functional group on the surface  2   a  of the aluminum member  2 , achieving strong molecular bonding. 
     According to the manufacturing method MT, in the surface hydroxylation step (S 14 ), the surface  2   a  of the aluminum member  2  is cleaned with water, and the surface  2   a  of the aluminum member  2  is modified into aluminum hydroxide. When the surface  2   a  of the aluminum member  2  has organic contamination, the contamination reduces the wettability of the coating  3  and the resin member  4  and interferes with a chemical bond between the surface  2   a  of the aluminum member  2  and the coating  3  and the resin member  4 . In the manufacturing method MT, the surface  2   a  of the aluminum member  2  is cleaned with water used for modification into aluminum hydroxide. Thus, the manufacturing method MT can suppress a reduction in bonding strength, the reduction being caused by organic contamination. 
     According to the manufacturing method MT, the aluminum hydroxide contains at least one of diaspore, boehmite, pseudo-boehmite, bayerite, norstrandite, gibbsite, and doyleite. The surface  2   a  (surface nano structure  2   d ) of the aluminum member  2 , which contains a combination of multiple hydroxides of aluminum from among the foregoing hydroxides of aluminum, is formed such that water is heated at a lower temperature in the surface hydroxylation step (S 14 ) than the surface nano structure  2   d  containing any one of the hydroxides of aluminum. 
     According to the manufacturing method MT, the triazine thiol derivative contains at least one functional group selected from primary amine, secondary amine, tertiary amine, an epoxy group, a hydroxy group, a thiol group, an azido group, and an alkyl group. In this case, in the coating step (S 16 ), the coating  3  is formed by binding the triazine thiol derivative and the functional group on the surface  2   a  of the aluminum member  2  modified into aluminum hydroxide. Subsequently, in the bonding step (S 18 ), the triazine thiol derivative contained in the coating  3  and the functional group on the surface of the resin member  4  bind to each other, and the resin member  4  is bonded to the surface  2   a  of the aluminum member  2  on which the coating  3  is formed. In this way, the coating  3  is molecular bonded to the aluminum member  2  modified into aluminum hydroxide and the resin member  4  by the functional group of the triazine thiol derivative, so that the coating  3  is strongly bonded. 
     According to the manufacturing method MT, in the bonding step (S 18 ), the resin member  4  may be bonded to the surface  2   a  of the aluminum member  2  on which the coating  3  is formed by injection molding, thermal compression molding, press forming, or ultrasonic bonding. Thus, the manufacturing method MT can easily bond the resin member  4  to the surface  2   a  of the aluminum member  2  with the coating  3  interposed therebetween. 
     The present embodiment was described above. As a matter of course, the present disclosure is not limited to the present embodiment and can be modified in various forms other than the present embodiment without departing from the scope of the disclosure. 
     [Modification of the Aluminum Member and the Resin Member] 
     The aluminum member  2  and the resin member  4  were described as plate members in the embodiment. The shapes are not limited thereto, and any shapes can be used if the members can be brought into contact with each other. The resin member  4  according to the embodiment is in contact with a part of the surface  2   a  of the aluminum member  2 . The resin member  4  may be brought into contact with the overall surface  2   a  of the aluminum member  2 . 
     The material of the resin member is not limited to the foregoing example. For example, the material of the resin member may be thermoplastic fiber-reinforced resin or thermosetting fiber-reinforced resin. The thermoplastic fiber-reinforced resin includes, for example, aromatic polyamide fiber reinforced thermo plastics (AFRTP), carbon fiber reinforced thermo plastics (CFRTP), and glass fiber reinforced thermo plastics (GFRTP). The thermosetting fiber-reinforced resin includes, for example, aromatic polyamide fiber reinforced plastics (AFRP), carbon fiber reinforced plastics (CFRP), and glass fiber reinforced plastics (GFRP). 
     [Modification of Injection Molding] 
     Injection molding is not limited to insert molding and outsert molding may be used instead. 
     EXAMPLE 
     [Grain Size of the Blasting Material] 
     First, the thickness of the natural oxide film of the aluminum member  2  was measured before the blasting step (S 12 ) was performed. The natural oxide film was analyzed in the depth direction by using “Auger electron spectroscopy (AES)”. An oxide and a metal component were simultaneously detected around an oxide/metal interface and thus were separated by a spectral synthesis method, so that the thickness of the natural oxide film was determined. The natural oxide film was 72 nm in thickness. Subsequently, the blasting step (S 12 ) was performed using the blasting machine illustrated in  FIGS.  4  to  6    and then the thickness of the natural oxide film of the aluminum member  2  was measured. In the case of blasting material in which abrasive grains had a center particle size of 600 μm to 710 μm, a natural oxide film was 13 nm in thickness. In the case of blasting material in which abrasive grains had a center particle size of 41 μm to 50 μm (a maximum particle size of 127 μm or less and a mean particle size of 57 μm±3 μm), a natural oxide film was 9 nm in thickness. Thus, it was confirmed that the natural oxide film of the surface  2   a  of the aluminum member  2  can be removed by using at least the blasting material of 710 μm or less. 
     [Confirmation of a Surface State of the Aluminum Member] 
     The blasting step (S 12 ) was performed by using the blasting machine illustrated in  FIGS.  4  to  6   . An aluminum plate (Japanese Industrial Standards (JIS): A5052) was used as the aluminum member. The blasting material containing alumina with a blasting-material center particle size of 106 μm to 125 μm was used for blasting. The projection pressure was 1.0 MPa. After the blasting step, the surface was observed using a field emission scanning electron microscope (FE-SEM). 
     Subsequently, the surface hydroxylation step (S 14 ) was performed. The aluminum member having undergone blasting was immersed in pure water at 90° C. for two minutes. The surface was then observed by using the field emission scanning electron microscope (FE-SEM). Thus, it was confirmed that a plurality of pores with a pore size of 10 nm or more and less than 1000 nm are present on the surface of the aluminum member after the surface hydroxylation step (S 14 ). 
     [Confirmation of the Surface Composition of the Aluminum Member] 
     [Example: Surface Treated Article] 
     The blasting step (S 12 ) was performed by using the blasting machine illustrated in  FIGS.  4  to  6   . An aluminum plate (JIS: A5052) was used as the aluminum member. The blasting material containing alumina with a blasting-material center particle size of 106 μm to 125 μm was used for blasting. The projection pressure was 1.0 MPa. Subsequently, the surface hydroxylation step (S 14 ) was performed. The aluminum member having undergone blasting was immersed in pure water at 90° C. for two minutes. 
     [Comparative Example: Untreated Article] 
     The blasting step (S 12 ) and the surface hydroxylation step (S 14 ) were not performed on an aluminum plate (JIS: A5052). 
     The surface compositions of the surface treated article and the untreated article were analyzed using Fourier transform infrared spectroscopy (FT-IR) according to attenuated total reflectance (ATR). The analysis results are indicated in  FIG.  13   . 
       FIG.  13    indicates the analysis results of the surface compositions of the aluminum members. In the graph of  FIG.  13   , the abscissa indicates a wave number and the ordinate indicates an absorbance. Waveform data in the upper part of the graph indicates the composition analysis result of the surface treated article, whereas waveform data in the lower part of the graph indicates the composition analysis result of the untreated article. As indicated in  FIG.  13   , the waveform data of the untreated article reached peaks at wave numbers of 3960 m-1, 3930 m − 1, and 2873 m-1 because of contamination with carbon (e.g., C—H) and a peak (Al—O) at a wave number of 946 m-1 because of an aluminum oxide. Any peak caused by boehmite was not confirmed. In the data of the surface treated article, a peak caused by contamination with carbon (e.g., C—H) before treatment and a peak caused by an aluminum oxide (Al—O) disappeared and peaks caused by boehmite appeared at wave numbers of 3268 m-1 and 3113 m-1. Hence, it was confirmed that organic contamination with on the surface of the aluminum member was removed by surface treatment and aluminum hydroxide was formed. 
     [Confirmation of a Surface Carbon Concentration] 
     The surface carbon concentration of the aluminum member  2  having undergone the surface hydroxylation step (S 14 ) and the surface carbon concentration of the untreated article were measured and compared with each other. For the measurement, X-ray photoelectron spectroscopy (XPS) was used. Consequently, the surface carbon concentration of the untreated article was 40 at %, whereas the aluminum member  2  having undergone the surface hydroxylation step (S 14 ) had a surface carbon concentration of 8 at %. Thus, a cleaning effect was confirmed as a secondary effect of hydrothermal treatment. 
     [Confirmation of Shearing Strength] 
     Example 1 and comparative examples 1 to 4 were prepared to confirm shearing strength. 
     Example 1 
     The blasting step (S 12 ) was performed by using the blasting machine illustrated in  FIGS.  4  to  6   . An aluminum plate (JIS: ADC12) was used as the aluminum member. The blasting material containing alumina having sharp projections with a blasting-material center particle size of 106 μm to 125 μm was used for blasting. The projection pressure was 1.0 MPa. At this point, asperities are formed on the surface of the aluminum member such that arithmetic mean roughness Ra, arithmetic mean inclination RΔa, and root-mean-square inclination RΔq that are determined by JIS B 0601(1994) are 2.5 μm, 0.35, and 0.42, respectively. Subsequently, hydrothermal treatment in the surface hydroxylation step (S 14 ) was performed. The aluminum member having undergone blasting was immersed in pure water at 90° C. for two minutes. For the hydrothermal treatment, pure water having an electric conductivity of 0.05 μS/cm was used. The pure water was ion exchanged water. Thereafter, immersion in the coating step (S 16 ) was performed. The aluminum member having undergone the surface hydroxylation step was immersed in a molecule binder for one minute. For the coating, a-TES (triazine molecule binder 0.1% solution) by Sulfur Chemical Laboratory Inc. was used as a molecule binder. After the coating, ultrasonic cleaning was performed with pure water for one minute. Thereafter, the bonding step (S 18 ) was performed. By using the mold illustrated in  FIGS.  7  and  8   , the resin member was bonded to the aluminum member by injection molding. Polyphenylene sulfide (PPS) was used as the material of the resin member. During injection, a mold temperature was 150° C., an injection rate was 20 mm/s, an injection pressure was 53 MPa or more and 93 MPa or less, and an injection time was 0.56 s. During the retention time, the retention pressure was set at 80 MPa and the retention time was set at 8 s. In a test specimen of shearing strength, the area of a bonded portion between the aluminum member and the resin member measured 5 mm×10 mm, 50 mm 2 . In a test specimen of airtightness, the aluminum member was formed with an inside diameter of 20 mm. The resin member was bonded to the aluminum member under the foregoing conditions and had an outside diameter of 24 mm. The bonded portion between the aluminum member and the resin member was 2 mm in width. 
     Example 2 
     In example 2, an aluminum plate (JIS: A5052) was used as the aluminum member. Other conditions, the blasting step (S 12 ), the surface hydroxylation step (S 14 ), the coating step (S 16 ), and the bonding step (S 18 ) are identical to those of example 1. 
     Example 3 
     In example 3, an aluminum plate (JIS:ADC12) having undergone the blasting step (S 12 ), the surface hydroxylation step (S 14 ), and the coating step (S 16 ) as in example 1 was used as an aluminum member. In the bonding step (S 18 ), carbon fiber reinforced thermo plastics (CFRTP) acting as fiber-reinforced resin were used as the resin member. In the bonding step (S 18 ), the resin member was bonded to the surface of the aluminum member on which the coating is formed by press forming instead of injection molding. During the retention time of the press forming (the closing of the mold), the mold temperature was set at 220° C., the retention pressure was set at 5 MPa and the retention time was set at 300 s. The conditions of a test specimen of shearing strength and a test specimen of airtightness are identical to those of example 1. 
     Comparative Example 1 
     In comparative example 1, an aluminum plate (JIS:ADC12) having undergone the same blasting step (S 12 ) as in example 1 was used as an aluminum member. Unlike in the surface hydroxylation step of example 1, the aluminum member having undergone blasting in hydrothermal treatment was immersed in pure water at 90° C. for two minutes. Ordinary tap water containing metal ions was used for the hydrothermal treatment. The coating step (S 16 ) and the bonding step (S 18 ) were performed as in example 1. 
     Comparative Example 2 
     In comparative example 2, an aluminum plate (JIS:A5052) having undergone the same blasting step (S 12 ) as in example 2 was used as an aluminum member. Unlike in the surface hydroxylation step of example 2, the aluminum member having undergone blasting in hydrothermal treatment was immersed in pure water at 90° C. for two minutes. Ordinary tap water containing metal ions was used for the hydrothermal treatment. The coating step (S 16 ) and the bonding step (S 18 ) were performed as in examples 1 and 2. 
     Comparative Example 3 
     In comparative example 3, the same aluminum plate (JIS:ADC12) as in example 1 was used as an aluminum member. The blasting step was performed by using the blasting machine illustrated in  FIGS.  4  to  6   . The blasting material containing alumina not having sharp projections with a blasting-material center particle size of 106 μm to 125 μm was used for blasting. The projection pressure was 1.0 MPa. At this point, asperities are formed on the surface of the aluminum member such that arithmetic mean roughness Ra, arithmetic mean inclination RΔa, and root-mean-square inclination RΔq that are determined by JIS B 0601(1994) are 2.5 μm, 0.16, and 0.42, respectively. The surface hydroxylation step (S 14 ), the coating step (S 16 ), and the bonding step (S 18 ) were performed as in example 1. 
     Comparative Example 4 
     In comparative example 4, the same aluminum plate (JIS:ADC12) as in example 1 was used as an aluminum member. The blasting step was performed by using the blasting machine illustrated in  FIGS.  4  to  6   . The blasting material containing glass beads with a blasting-material center particle size of 106 μm to 125 μm was used for blasting. The projection pressure was 1.0 MPa. At this point, asperities are formed on the surface of the aluminum member such that arithmetic mean roughness Ra, arithmetic mean inclination RΔa, and root-mean-square inclination RΔq that are determined by JIS B 0601(1994) are 2.5 μm, 0.15, and 0.20, respectively. The surface hydroxylation step (S 14 ), the coating step (S 16 ), and the bonding step (S 18 ) were performed as in example 1. 
     Comparative Example 5 
     In comparative example 5, an aluminum plate (JIS:A5052) having undergone the same surface hydroxylation step (S 14 ) as in example 1 was used as an aluminum member without undergoing the blasting step (S 12 ). The coating step (S 16 ) and the bonding step (S 18 ) were performed as in example 1. 
     [Evaluation of Bonding Strength] 
     The shearing strengths of examples 1 to 3 and comparative examples 1 to 5 prepared under the foregoing conditions were measured. An evaluation apparatus conducted measurements according to a testing method in conformity with ISO19095-2 (overlapped test specimens (type B)). The shearing strength of example 1 was 42 MPa, the shearing strength of example 2 was 44 MPa, the shearing strength of example 3 was 37 MPa, the shearing strength of comparative example 1 was 8 MPa, the shearing strength of comparative example 2 was 6 MPa, and the shearing strength of comparative example 3 was 10 MPa. In comparative example 4 and comparative example 5, the aluminum member and the resin member were not bonded to each other, so that shearing strength was unmeasurable. 
     By a comparison between example 1 and comparative example 1 and a comparison between example 2 and comparative example 2, it was confirmed that pure water used as water in the hydrothermal treatment of the surface hydroxylation step (S 14 ) contributes more greatly to the improvement of shearing strength. In the case of pure water, only a few impurities (e.g., magnesium, sodium, phosphorus, and calcium) are contained in water, so that the functional group (hydroxyl group) of aluminum hydroxide formed on the surface of the aluminum member by the impurities is not deprived. Thus, it is assumed that more hydroxyl groups of aluminum hydroxide formed on the surface of the aluminum member and the functional group of a triazine thiol derivative can react with each other and thus shearing strength is improved between the aluminum member and the coating, achieving higher shearing strength for the composite member. 
     By comparing examples 1 and 2 with example 3, it was confirmed that injection molding performed as the bonding (S 18 ) contributes more greatly to the improvement of shearing strength. Although fiber-reinforced resin is used in example 3, the shearing strength is lower than in examples 1 and 2 in which fiber-reinforced resin is not used. This is because fiber-reinforced resin improves shock absorption but does not greatly contribute to shearing strength between the aluminum member and the resin member. Furthermore, it is assumed that injection molding can more properly bond the aluminum member and the resin member than press forming. 
     By comparing example 1 with comparative example 3 and comparing example 1 with comparative example 4, it was confirmed that the formation of asperities in the blasting step (S 12 ) contributes greatly to the improvement of shearing strength with an arithmetic mean inclination RΔa controlled to 0.17 or more and 0.50 or less and a root-mean-square inclination RΔq controlled to 0.27 or more and 0.60 or less on the surface of the aluminum member. It was confirmed that shearing strength considerably decreases if the arithmetic mean inclination RΔa and the root-mean-square inclination RΔq have values outside the range even when the arithmetic mean roughness Ra has a constant value. The resin member can be placed onto sharp-angled asperities formed by blasting, and the asperities and the resin member placed on the asperities interfere with each other and are not broken by a force applied from the outside. Thus, it is assumed that example 1 achieves higher shearing strength than comparative examples 3 and 4. 
     By comparing comparative example 3 and comparative example 4, it was confirmed that alumina serving as blasting material has a larger arithmetic mean inclination RΔa and a larger root-mean-square inclination RΔq than glass beads serving as blasting material, contributing to the proper formation of the composite member. In the case of alumina serving as blasting material, asperities are formed like spikes on the surface of the aluminum member, whereas in the case of glass beads serving as blasting material, asperities are formed like dimples on the surface of the aluminum member. Thus, alumina serving as blasting material is more likely to produce an anchor effect between the aluminum member and the coating and between the aluminum member and the resin member than glass beads serving as blasting material, so that the composite member was properly formed (the aluminum member and the resin member are bonded to each other). 
     By comparing example 1 and comparative example 5 and comparing comparative example 3 and comparative example 5, it was confirmed that the blasting step (S 12 ) contributes to the proper formation of the composite member. In other words, it was confirmed that the composite member is not properly formed even if only the surface hydroxylation step (S 14 ), the coating step (S 16 ), and the bonding step (S 18 ) are properly performed. 
     [Evaluation of Airtightness] 
     The airtightness of examples 1 to 3 and comparative examples 1 to 5 prepared under the foregoing conditions was measured. An evaluation apparatus measured the degree of leak of helium (He) according to a testing method in conformity with ISO19095-2 (overlapped test specimens for sealing properties (type D)). The airtightness (the leak rate of helium) of examples 1 to 3 was less than 5.0×10 −7  Pa·m 3 /s, whereas the airtightness (the leak rate of helium) of comparative examples 1 to 3 was 5.0×10 −5  Pa·m 3 /s or more. In comparative example 4 and comparative example 5, the aluminum member and the resin member were not bonded to each other, so that airtightness (the leak rate of helium) was unmeasurable. 
     By comparison between example 1 and comparative example 1 and a comparison between example 2 and comparative example 2, it was confirmed that pure water used as water in the hydrothermal treatment of the surface hydroxylation step (S 14 ) contributes more greatly to the improvement of airtightness. In the case of pure water, only a few impurities (e.g., magnesium, sodium, phosphorus, iron and calcium) are contained in water, so that the functional group (hydroxyl group) of aluminum hydroxide formed on the surface of the aluminum member by the impurities is not deprived. Thus, it is assumed that more hydroxyl groups of aluminum hydroxide formed on the surface of the aluminum member and the functional group of a triazine thiol derivative can react with each other and thus the aluminum member and the coating can be more tightly bonded to each other, achieving higher airtightness for the composite member. 
     By comparing example 1 with comparative example 3 and comparing example 1 with comparative example 4, it was confirmed that the formation of asperities in the blasting step (S 12 ) contributes greatly to the improvement of airtightness with an arithmetic mean inclination RΔa controlled to 0.17 or more and 0.50 or less and a root-mean-square inclination RΔq controlled to 0.27 or more and 0.60 or less on the surface of the aluminum member. It was confirmed that airtightness considerably decreases if the arithmetic mean inclination RΔa and the root-mean-square inclination RΔq have values outside the range even when the arithmetic mean roughness Ra has a constant value. The resin member can be placed onto sharp-angled asperities formed by blasting, and the asperities and the resin member placed on the asperities are tightly engaged with each other. Thus, it is assumed that example 1 achieves higher airtightness than comparative examples 3 and 4. 
     REFERENCE SIGNS LIST 
       1  . . . composite member,  2  . . . aluminum member,  2   a , 2   c  . . . surface,  2   b  . . . asperities,  2   d  . . . surface nano structure,  3  . . . coating,  4  . . . resin member,  10  . . . blasting machine,  11  . . . blast chamber,  12  . . . blast nozzle,  13  . . . storage tank,  14  . . . pressure chamber,  15  . . . compressed-air feeder,  16  . . . fixed-quantity feeding part,  17  . . . connecting pipe,  18  . . . work table,  19  . . . control unit,  20  . . . mold,  21  . . . mold body