JP5495419B2 - Fastening structure of magnesium alloy members - Google Patents

Description

  The present invention relates to a fastening structure of a magnesium alloy, which is a lightweight metal structure material, and a dissimilar metal, and in particular, can prevent a corrosion phenomenon (electric corrosion) due to an electrochemical reaction occurring between dissimilar metals. It is related with the fastening structure of the magnesium alloy member which enables weight reduction.

Aluminum alloys and magnesium alloys are lightweight and have strength as structural materials, so they are useful as structural materials that can reduce fuel consumption by reducing the weight of vehicles, such as automobiles and railways. It attracts attention and is expected to expand demand in the future.
However, since magnesium is a metal element having a large ionization tendency (base), when assembled and fastened to another metal material having a small ionization tendency, there is a weak point that it is corroded by electric corrosion (dissimilar metal contact corrosion).

  In the case of an aluminum alloy, an alumite treatment (anodization treatment) can be applied to provide a practical level of corrosion resistance. However, since an alumite treatment needs to be energized by connecting a member to a power source, Application to an aluminum alloy member has the drawback of requiring labor and cost.

As for the magnesium alloy, for example, Patent Document 1 discloses a bolt fastening structure of a magnesium alloy member.
In this fastening structure, the surface of the fastening part of the magnesium alloy member is subjected to cation electrodeposition coating and powder coating, while using a bolt that has been subjected to cosmetic treatment by zinc-nickel plating, the bolt head and the magnesium alloy member An anodized aluminum washer is interposed between them.

On the other hand, various coating agents and paints with excellent insulating properties have been developed. For example, Patent Document 2 discloses an electron that has excellent heat resistance, low thermal expansion, insulating properties, and adhesion, and does not generate voids or cracks. A resin composition for material insulation is disclosed.
That is, this insulating resin composition includes a methoxy group-containing silane-modified epoxy resin obtained by a condensation reaction of a bisphenol type epoxy resin, a novolac type epoxy resin, and a methoxysilane partial condensate.

JP 2002-188616 A JP 2003-55435 A

However, in the fastening structure of the magnesium alloy member described in Patent Document 1, since an anodized aluminum washer is used, it takes time for the anodizing process as described above, and an increase in cost is inevitable. There's a problem.
On the other hand, it is conceivable to form an insulating layer made of a resin composition as described in Patent Document 2 on the washer surface. However, in order to replace the alumite treatment, the insulating film has scratch resistance and abrasion resistance. Is required, and there is a problem that it is not sufficient to prevent electrolytic corrosion in the fastening structure as described above.

  The present invention has been made in view of the above-described problems in the conventional fastening structure of magnesium alloy members with dissimilar metals, and can insulate between dissimilar metals at low cost, even if used in a humid atmosphere. It aims at providing the fastening structure of the magnesium alloy member which can prevent generation | occurrence | production of a corrosion.

  As a result of intensive studies aimed at achieving the above object, the present inventors have determined that an alkoxy group-containing silane-modified epoxy resin containing nano-sized alumina fine powder between the fastening surfaces of both members made of different metals. It has been found that the above-mentioned problems can be solved by providing an insulating coating film comprising the following, and the present invention has been completed.

The present invention is based on the above knowledge, and the fastening structure of the magnesium alloy member of the present invention is a fastening structure of a first member made of a magnesium alloy and a second member mainly composed of a metal nobler than magnesium. there are, between the fastening surfaces of the members, comprising 0.5% to 10% average particle diameter of 10~40nm alumina fine powder in the epoxy resin modified with partial condensate of alkoxysilane in a mass ratio, 10 An insulating coating film having a thickness of ˜12.2 μm is provided, and the curing agent of the modified epoxy resin is mensendiamine .
In the same fastening structure, the epoxy resin modified with the alkoxysilane partial condensate contains 0.5 to 10% by mass of alumina fine powder having an average particle size of 10 to 40 nm in a mass ratio of 10 to 12.2 μm. Both members are fastened together through an aluminum alloy member having an insulating coating film having a thickness of 5 mm, and the curing agent for the modified epoxy resin is mensendiamine .

  According to the present invention, an insulating coating having excellent scratch resistance and pressure resistance is interposed between the fastening surfaces of both members made of different metals, and the both members are insulated, so that an electrolyte such as water can be used. Even if it is interposed between both members, generation of local batteries can be suppressed and electrolytic corrosion of the magnesium alloy member can be prevented.

It is sectional drawing which shows one Embodiment of the fastening structure of the magnesium alloy member of this invention. It is sectional drawing which shows the shape of the fastening structure test piece for the electrolytic corrosion evaluation used for the salt spray test and the combined cycle corrosion test. It is a graph which shows the combined cycle corrosion test result in the fastening structure of an Example and a comparative example.

  Hereinafter, the fastening structure of the magnesium alloy member of the present invention will be described more specifically. In the present specification, “%” means mass percentage unless otherwise specified.

FIG. 1 shows an example of an embodiment of a fastening structure of a magnesium alloy member according to the present invention. The fastening structure includes a first member 1 made of a magnesium alloy, a second member 2 made of a steel material mainly composed of Fe (a higher standard electrode potential) than Mg, and a galvanized bolt 3 made of steel. And a washer 4 as an aluminum alloy member. In the present invention, the “main component” refers to a component occupying the largest content in the metal material constituting the second member.
Then, with the washer 4 interposed between the first and second members 1 and 2, a screw 3 for forming the bolt 3 inserted into the insertion hole provided in the second member 2 in the first member 1. Both members 1 and 2 are fastened by being screwed into the holes.

The aluminum alloy washer 4 is provided with a coating film of an insulating coating having a thickness of 3 to 20 μm on at least one surface, preferably the entire surface thereof. This insulating coating contains 0.5 to 10% by mass of alumina fine powder having an average particle size of 70 nm or less in an epoxy resin modified with a partial condensate of alkoxysilane.
Here, the thickness of the insulating coating film is in the range of 3 to 20 μm because when the coating film thickness is less than 3 μm, sufficient coating film strength cannot be obtained, and the insulation between both members is When the coating thickness exceeds 20 μm, there is a disadvantage that the fastening portion is loosened.

In the present invention, the washer 4 is made of an aluminum alloy because Al is a base metal next to Mg in practical metals, and the potential difference with the magnesium alloy member 1 becomes small. Even if the coating film is destroyed, the progress of electrolytic corrosion can be suppressed.
For the same reason, it is a preferable form that the steel bolt is galvanized.

In the above-described fastening structure of the present invention, it is possible to fasten by fastening a steel nut to the tip of the bolt 3 inserted into the magnesium alloy member 1, but in that case, the nut and the magnesium alloy Needless to say, it is necessary to use a washer 4 having a similar coating film between the members 1.
In addition, when the steel bolt 3 is directly screwed to the magnesium alloy member 1, direct contact between the steel and the magnesium alloy occurs at the screw portion. There is no intrusion of water and so on, and it is considered that almost no electrolytic corrosion occurs at the site. However, depending on the shape and usage environment of both members, it is desirable to apply a sealant to the threaded portion.

In the fastening structure of the magnesium alloy member of the present invention, the second member is typically a steel member as described above. Secondly, the material of the member is not particularly limited, and is made of iron (casting). Etc.), copper, copper alloy, zinc alloy, Ni-base alloy, titanium alloy, and other various metals.
Further, a fastening structure of magnesium alloy members (in FIG. 1, the second member 2 is also made of a magnesium alloy) is conceivable. In this case, the steel galvanized bolt 3 is a second member mainly composed of Fe that is nobler than Mg, and the head of the bolt 3 and the member 2 made of a magnesium alloy (in this case) It is necessary to interpose a washer 4 having an insulating coating film between the first member and the second member.

In the magnesium alloy member fastening structure of the present invention, instead of the washer 4 having an insulating coating film, an insulating coating film having the same composition as described above is formed between the fastening surfaces of both members to have the same thickness. It may be.
Both members, that is, the fastening surface of the first member 1 made of magnesium alloy and the second member 2 made of steel, the fastening surface of the first member 1 made of magnesium alloy and the steel nut, or the bolt 3 made of steel An insulating coating film is formed on one or both of the head and the fastening surface of the second steel member so that the total thickness is 3 to 20 μm.

  In the above-described fastening structure, the example in which the bolt 3 is used as the fastening means has been shown. However, the fastening means used in the present invention is not limited to the bolt alone. Etc. can be used.

In the fastening structure of the magnesium alloy member of the present invention, when the aluminum alloy washer 4 and the bolt 3 provided with the insulating coating are used, the plate thickness of the washer 4 may be 0.1 to 0.5 times the bolt diameter. desirable.
Generally, the potential difference between the second member 2 and the magnesium alloy member 1 is larger than the potential difference between the aluminum alloy washer 4 and the magnesium alloy member 1. In this case, the thick washer 4 can be used to increase the distance between the second member 2 and the magnesium alloy member 1, and a leakage current flows on the surface between the wet members 1 and 2. In this case, it is preferable because leakage current related to electrolytic corrosion can be reduced and potential difference corrosion can be suppressed. The plate thickness of the washer 4 is more preferably 0.2 to 0.4 times the bolt diameter. At this time, if the plate thickness of the washer 4 exceeds 0.5 times the bolt diameter, the effects of the invention are not impaired, but the influence on the weight and cost is likely to occur.

In the present invention, as an aluminum alloy member interposed between the first member 1 made of a magnesium alloy and the second member 2 made of a different metal nobler than Mg, typically, the aluminum alloy member is made as described above. Although the washer 4 is used, it is desirable that the surface of such an aluminum alloy member is previously subjected to chemical conversion treatment. The film formed by the chemical conversion treatment is effective for preventing corrosion of the base material, and can simultaneously improve the adhesion of the coating film.
As such a chemical conversion treatment agent, a chromate surface treatment agent (including hexavalent chromium) and the like can be exemplified. Some chemical conversion treatment agents used for these contain a chromium component as described above, but it is preferable to use a treatment agent not containing a chromium component in view of environmental measures.

Next, the insulating coating used in the present invention, the method for forming (coating) the coating, and the like will be described.
In the fastening structure of the magnesium alloy member of the present invention, as described above, the fastening surface of the first member 1 (made of magnesium alloy) and the second member 2 (made of dissimilar metal), or aluminum interposed therebetween. An insulating coating film is formed on the surface of the alloy member. As described above, this insulating coating film is obtained by adding fine alumina powder having an average particle size of 70 nm or less in an epoxy resin modified with an alkoxysilane (R _4-n Si (OR ′) _n ) partial condensate. 5 to 10%, and has a thickness of 3 to 20 μm. In addition, although this n is 3 or 4, it is preferable because the coating film hardness is improved, but it is particularly preferably 3 in consideration of rust prevention performance.

The type of resin that constitutes the insulating coating is good adhesion, excellent chemical resistance, heat resistance, and top coating characteristics even when blasting, which is a pretreatment during coating, cannot be performed. In the present invention, an epoxy resin modified with a partial condensate of alkoxysilane is used.
Here, the alkoxysilane partial condensate specifically refers to an alkoxy group-containing silane-modified epoxy resin or the like, and the hybrid epoxy resin modified with this partial condensate is a fine silica site (polysiloxane network). It has excellent heat resistance and hardness as compared with ordinary epoxy resins, and exhibits excellent characteristics as an insulating coating film used in the present invention.

It is preferable to use mensendiamine as a curing agent for the modified epoxy resin.
Many types of curing agents for epoxy resins are known. Among amine curing agents, insulating epoxy resin coatings cured with mensendiamine have excellent alkali resistance. Therefore, it has excellent electrolytic corrosion prevention characteristics.

As the alkoxysilane, methyltrimethoxysilane (CH ₃ Si (OCH ₃ ) ₃ ) is particularly preferable. Epoxy resin modified with a partial condensate of methyltrimethoxysilane has a slightly lower hardness compared to an epoxy resin modified with a partial condensate of tetramethoxysilane or other alkoxysilane, and the cured resin coating film. Since it is difficult for cracks to occur, it is preferable to ensure insulation.

  The modified epoxy resin is preferably a bisphenol A type epoxy resin, and by using such an epoxy resin, a film excellent in adhesion, electrical insulation and heat resistance can be obtained.

Furthermore, it is desirable that the silicon content (SiO ₂ equivalent) contained in the modified epoxy resin is more than 30%.
That is, in the organic-inorganic composite epoxy resin used in the present invention, the coefficient of thermal expansion of the coating film is reduced by increasing the proportion of alkoxysilane or polycondensation silane to be combined with the epoxy resin to more than 30% in terms of SiO _2. Therefore, thermal stability and hardness can be secured.

The insulating coating contains alumina fine powder. This alumina is an insulating material having a high hardness, and since the fine alumina fine powder having an average particle size of 70 nm or less is contained in the coating film, the fluidity of the coating liquid is improved, and a uniform insulating coating film is obtained. Can be formed. In addition, the presence of such fine alumina powder in the coating film imparts scratch resistance to the coating film without impairing the insulating properties, exerts a filler function, ensures a film thickness, and cures. Even if pressure is applied to the insulating coating film, the coating film can be prevented from being crushed or laterally flowed.
Here, the reason why the average particle size of the alumina fine powder is set to 70 nm or less is that when the average particle size is exceeded, there is an inconvenience that the alumina fine powder is easily dispersed without being uniformly dispersed. In addition, as for the alumina fine powder mix | blended in a coating material, it is more preferable that an average particle diameter exists in the range of 10-40 nm from a viewpoint of the dispersibility in a resin liquid, and imparting scratch resistance.

  The average particle size of the fine powder means the weight average particle size, and the particle size can be obtained from a high-magnification micrograph, and the average particle size can be obtained by calculation from the particle size distribution measured by the micrograph. .

  Further, the content of the fine alumina powder in the insulating coating film needs to be 0.5 to 10%. That is, when the content is less than 0.5%, the effect of adding fine alumina powder is hardly obtained. Conversely, when the content exceeds 10%, the coating cost for forming such a coating film increases. In addition, the more suitable range of alumina fine powder content in an insulating coating film is 2 to 8%.

From the viewpoint of further improving the fluidity of the insulating paint containing the alumina fine powder and improving the scratch resistance of the coating film, the particle shape of the alumina fine powder may be substantially spherical. desirable.
In the present invention, “substantially spherical” means that when the representative particle diameter D of one particle is appropriately set, the projected contour of the particle falls within a double circle of 0.85D and 1.15D. In other words, it means an aggregate of particles containing 90% or more of “substantially spherical particles” satisfying this condition.

The insulating coating film having the composition described above is composed of a paint prepared by blending the above-described modified epoxy resin or fine alumina powder with a known additive such as an epoxy resin curing agent, a dispersant, or a solvent so as to have the above composition after curing. It can form by apply | coating so that it may become a coating film of -20 micrometers in thickness.
The coating film formation method at this time is selected along with the adjustment of the concentration and viscosity of the paint depending on the shape and dimensions of the member. For example, any one of the dip and spin method, the dip drain method, and the spray coating method is used. It is preferable to employ a coating method.

  EXAMPLES Hereinafter, although this invention is demonstrated concretely based on an Example, this invention is not limited at all by these Examples.

[Insulating paint materials]
Propylene glycol monomethyl ether (hereinafter abbreviated as “PGME”) was used as the main solvent of the paint.
As epoxy resins, hybrid epoxy resins modified with alkoxysilane partial condensate produced by Arakawa Chemical Industries, Ltd. Composelan E-103 (modified methyltrimethoxysilane) and Composelan E-102 (modified tetramethoxysilane) Was used. Further, Adeka Resin EPU-78-11 (urethane-modified epoxy resin) manufactured by Adeka Co., Ltd. was used as a comparative example.

As the curing agent for the alkoxysilane-modified epoxy resin, MDA (Mensendiamine, manufactured by Wako Pure Chemical Industries, Ltd.) recommended by the resin manufacturer and acid anhydride curing agent, the pot life of the paint after blending Rikacid MH-700 (manufactured by Shin Nippon Science Co., Ltd.) was used. Moreover, Adeka Hardener EH-3842 (manufactured by Adeka Co., Ltd.) was used as a curing agent for the urethane-modified epoxy resin.
In addition, said MDA was added 3.5% with respect to the composeran, and Rikacid MH-700 was used 2.2 equivalent with respect to 1 molecular weight of composelane, and 1.1 equivalent with respect to the epoxy part.

As the fine alumina powder, nano-tech alumina (manufactured by C-I Kasei Co., Ltd.) composed of substantially spherical particles having an average particle diameter of 33 nm, and NANOBYK-3610 (BIC Chemie, a methoxypropyl acetate dispersion of substantially spherical particles having an average particle diameter of 22 nm) Japan Co., Ltd.) was used.
Further, an angular non-spherical alumina powder AKP-3000 (manufactured by Sumitomo Chemical Co., Ltd.) having an average particle diameter of 600 nm and a fine silica powder methoxypropyl acetate / substantially spherical having an average particle diameter of 22 nm as a filler other than alumina / Using NANOBYK-3650 (manufactured by Big Chemie Japan Co., Ltd.) which is a methoxypropanol dispersion, each was used as a comparative example.

[Aluminum alloy washer]
A washer having an outer diameter of 22 mm, an inner diameter of 10.5 mm, and a thickness of 1.5 mm made of an aluminum alloy defined as A5052 (Al-Mg-based) and A6061 (Al-Mg-Si-based) was prepared in JIS H4000. Then, as will be described later, the insulating paints prepared in the respective Examples and Comparative Examples were respectively applied and subjected to a rust prevention performance test according to the procedure described later. In some cases, prior to the application of the insulating paint, phosphoric acid was added using Chemibonder 5703 (Nihon CB Chemical Co., Ltd.) and Alsurf 501M (Nihon Paint Co., Ltd.), which are chromium-free chemical conversion treatment agents. A chemical conversion treatment for forming a salt film was performed.
In addition, an alumite treatment and a trivalent chromium treatment (treatment for forming a chromate film) were prepared on a washer made of an A6061 alloy without applying an insulating paint, and subjected to the same rust prevention performance test as a comparative example.

  The details of the raw materials and the chemical conversion treatment agent used for the preparation of the insulating paint are summarized in Table 1.

Example 1
First, 1.35 parts by weight of the curing agent MDA was added to 50 parts by weight of PGME and stirred for about 1 hour to obtain a solution in which the curing agent was dissolved.
Next, 3 parts by weight of PGME and 0.014 parts by weight of the dispersing agent BYK110 (manufactured by Big Chemie Japan Co., Ltd.) are mixed with 1 part by weight of Nanotech alumina, and dispersion treatment is performed by a ball mill to form a nanotech alumina slurry (solid 25%).

The nanotech alumina slurry was prepared by the following method.
First, a 1: 1 ratio of 5 mm and 3 mm zirconia balls (800 g each, zirconia balls are YTZ balls manufactured by Nikkato Co., Ltd.) is placed in a polypropylene bottle having a capacity of about 1 liter, and the slurry is mixed with zirconia balls. Filled and sealed until the same level. Then, the bottle was fixed in a container on which a ball mill was placed so that the bottle rotated vertically, and the container was rotated at about 60 rpm for 24 hours to disperse the alumina fine powder slurry.

Next, 53.5 parts by weight of the above PGME solution in which the curing agent was dissolved, 38.46 parts by weight of Composelan E-103 (methyltrimethoxysilane modified product, solid content 50.4%), and 11.54 parts by weight Part of the nanotech alumina slurry (solid content 2.88 parts by weight) was mixed to obtain an insulating paint for spray coating used in this example.
The content of fine alumina powder in the solid content (coating film after curing) of this insulating coating is 5.45%.

The insulating paint was spray-coated on a washer having the above dimensions made of A6061 alloy.
As a spray coating machine, a small WIDER SPRAYGUN W-61 model manufactured by Anest Iwata Co., Ltd. was used, and the air pressure of the compressor was adjusted to 0.16 MPa (1.6 atm) with a regulator and supplied to the spray coating machine. .

When painting, aluminum alloy washers were placed on a wire mesh placed on a turntable, and the spray direction could be changed by turning the wire mesh. In addition, spray coating was performed in the vicinity of the draft facility, and the coating liquid that was sprayed and not painted was placed in the draft.
Spray coating was also performed from an obliquely upward direction so that a coating film was formed on the side portion of the washer.

After the spray coating, the washer is placed in a drier in a state of being placed on a wire mesh, dried at 100 ° C. for about 10 minutes, then heated to a curing temperature of 180 ° C., and this temperature is maintained for about 20 minutes. Holding and baking the coating. After applying the coating on one side of the washer, turn all the washers upside down, arrange them on the same wire mesh, apply the insulating coating on the back side in the same way, and bake it. Aluminum with the insulating coating of this example An alloy washer was obtained.
The film thickness of the insulating coating formed on the washer is that the washer has bolt holes and the flat part is small and difficult to measure. The thickness of the film was measured with a dielectric film thickness meter, and this thickness was regarded as the coating thickness of the washer. As a result, the average film thickness was 12 μm.

(Example 2)
By adding 1.35 parts by weight of the curing agent MDA to 53.74 parts by weight of PGME and stirring for about 1 hour, a solvent solution of the curing agent was obtained.
Next, 7.80 parts by weight (containing 2.88 parts by weight of solid content) of nano-alumina dispersion NANOBYK-3610 (containing alumina fine powder having an average particle diameter of 22 nm in a state of 37% dispersion) in the PGME solution of the curing agent ) Was mixed.

Next, 38.46 parts by weight of Composelan E-103 was mixed with this mixed solution to obtain an insulating paint for spray coating used in this example.
Then, by repeating the same operation as in the above example, this insulating paint was applied to a washer made of A6061 alloy to obtain an aluminum alloy washer provided with the insulating coating film of this example. In addition, the average thickness of the insulating coating film formed on the washer was 11.5 μm as a result of measurement in the same manner.

( Reference Example 3 )
Ricacid MH-700 which is a curing agent of acid anhydride is used, except that 2.2 equivalents (9.23 parts by weight) of the curing agent is added to 38.46 parts by weight of Composelan E-103. By blending in the same manner as in Example 1, the insulating paint for spray coating used in this example was obtained. The content of fine alumina powder in the solid content (coating film after curing) of this insulating coating is 5.45%.
Then, by repeating the same operation as in the above example, this insulating paint was applied to a washer made of A6061 alloy to obtain an aluminum alloy washer provided with the insulating coating film of this example. In addition, the average thickness of the insulating coating film formed in the said washer was 7.8 micrometers as a result of the same measurement.

(Example 4)
The same operation as in Example 1 was repeated except that the washer made of A6061 alloy was subjected to a chemical conversion treatment using a chromium-free chemical conversion treatment agent Chemibonder 5703 and then an insulating coating film was formed. An aluminum alloy washer provided with In addition, the average thickness of the insulating coating film formed on the washer was 11.0 μm.

(Example 5)
By repeating the same operation as in Example 1 above, except that the washer made of A6061 alloy was subjected to chemical conversion treatment using the zirconium phosphate-based chromium-free chemical conversion agent Alsurf 501M and then an insulating coating film was formed. An aluminum alloy washer provided with the insulating coating film of this example was obtained. In addition, the average thickness of the insulating coating film formed in the said washer was 11.2 micrometers as a result of the same measurement.

(Example 6)
An aluminum alloy washer provided with the insulating coating film of this example was obtained by repeating the same operation as in Example 1 except that a washer of the same size made of A5052 alloy was used. In addition, the average thickness of the insulating coating film formed on the washer was 11.1 μm.

(Example 7)
An aluminum alloy washer provided with the insulating coating film of this example was obtained by repeating the same operation as in Example 2 except that a washer made of A5052 alloy was used. In addition, the average thickness of the insulating coating film formed on the washer was 11.0 μm.

(Example 8)
Except that the blending amount of PGME was reduced to 40 parts by weight, the same operation as in Example 1 was repeated to obtain an insulating coating material for coating used in this example. And the said insulating coating material was apply | coated by the dip and spin method to the washer which consists of A5052 alloy, and the aluminum alloy washer provided with the insulating coating film of this example was obtained.
In other words, a washer is immersed in the prepared insulating paint, and the removed washer is placed in a stainless steel bowl attached to a centrifuge and rotated (rotation radius 150 mm, rotation speed 400 rpm), and the extra paint adhering to the surface is shaken. After flying, it was similarly dried and cured. In addition, although the average thickness of the insulating coating film formed in the said washer was 10.0 micrometers, some unevenness was recognized by the film thickness, and it became a little uneven. The average thickness was determined by measuring the coating film appearing on the cross section after cutting the washer.

Example 9
As the alkoxysilane-modified epoxy resin, the same operation as in Example 1 except that Composelan E-102 (tetramethoxysilane-modified product, solid content 48.8%) was used instead of Composelane E-103. By repeating the above, an insulating paint for spray coating used in this example was obtained.
And the said insulating coating material was spray-coated by the method similar to Example 1 to the washer which consists of A5052 alloy, and the aluminum alloy washer provided with the insulating coating film of this example was obtained. The average thickness of the insulating coating film formed on the washer was 11.0 μm as a result of measurement in the same manner.

(Comparative Example 1)
Adeka Resin EPU-78-11 (urethane-modified epoxy resin, 100% resin component) was diluted 2-fold with PGME to obtain an epoxy resin solution.
Next, 11.60 parts by weight (solid content 2.90 parts by weight) of nanotech alumina slurry used in Example 1 and 3 hardeners Adeka Hardener EH-3842 were added to 65 parts by weight of the PGME solution of this epoxy resin. Mixing 9 parts by weight, an insulating paint for spray coating used in this example was obtained.

  Then, this insulating paint was spray-coated on a washer made of A6061 alloy, and the same operation as in Example 1 was repeated except that the baking temperature was set to 160 ° C. Got a washer. In addition, the average thickness of the insulating coating film formed on the washer was 8.0 μm.

(Comparative Example 2)
An aluminum alloy washer provided with the coating film of this comparative example was obtained by repeating the same operation as in Example 1 except that the paint for spray coating prepared without blending the slurry of fine alumina powder was used. It was. In addition, the average thickness of the insulating coating film formed on the washer was 8.0 μm.

(Comparative Example 3)
The same procedure as in Example 1 was used except that a slurry of alumina powder AKP-3000 having an average particle diameter of about 600 nm dispersed in the same manner as nanotech alumina was used instead of the slurry of fine alumina powder. The operation was repeated to obtain an aluminum alloy washer provided with the coating film of this comparative example. In addition, the average thickness of the insulating coating film formed on the washer was 6.5 μm.

(Comparative Example 4)
The same procedure as in Example 1 was used, except that a nanosilica slurry NANOBYK-3650 (a dispersion containing 31% silica fine powder having an average particle size of 22 nm) was used instead of the alumina fine powder slurry. By repeating the operation, an aluminum alloy washer provided with the insulating coating film of this comparative example was obtained. In addition, the average thickness of the insulating coating film formed on the washer was 7.0 μm.

(Comparative Example 5)
An aluminum alloy washer of this comparative example was made by subjecting a washer made of A6061 alloy and having the above dimensions to alumite treatment.

(Comparative Example 6)
The washer made of A6061 alloy and having the above dimensions was subjected to trivalent chromium treatment to obtain an aluminum alloy washer of this comparative example.

[Electrical corrosion resistance evaluation method]
[1] Preparation of test piece for evaluation As shown in FIG. 2, a galvanized bolt 3 inserted through each of the aluminum alloy washers 4 obtained in the above-described examples and comparative examples is used as a first member made of magnesium alloy. A fastening structure test piece for electrolytic corrosion evaluation was obtained by screwing into the female screw hole provided in No. 1. Note that a silicone sealant was applied around the tip of the bolt 3 to prevent salt water from entering from the threaded portion.
The bolt 3 is a galvanized steel bolt having a nominal diameter of 10 mm. In this case, the bolt 3 corresponds to a second member made of a dissimilar metal with respect to the first member 1 made of magnesium alloy. Become.

[2] Salt spray test Each of the fastening structure test pieces prepared as described above was put into a salt spray test apparatus for each of the examples and comparative examples, and a salt spray test in accordance with the method defined in JIS Z 2371 was performed. The rust prevention performance was evaluated.
As a test result, it evaluated in the time which white rust was recognized in the member 1 made from a magnesium alloy of the 2nd test piece among three test pieces.

[3] Combined cycle corrosion test Similarly to the above, each of the three fastening structure test pieces was stored in a test apparatus, sprayed with salt water having a sodium chloride concentration of 50 ± 5% and a temperature of 50 ± 5 ° C. for 20 minutes, and a temperature of 60 Drying at ± 5 ° C. for 145 minutes and wetness at a temperature of 65 ± 5 ° C. for 75 minutes were performed. Subsequently, 160 minutes of drying at the above temperature and 80 minutes of wetting were repeated 5 times (convenience 24 hours), and this was taken as one cycle, and a test was repeated for a total of 720 hours (30 times). The relative humidity in each drying process was less than 30%, and the relative humidity in each wet process was 95 ± 5%.
And after the test of 720 hours, the depth of the corrosion hole produced in the magnesium alloy member 1 is measured, and the corrosion hole depth indicating an intermediate value among the three test pieces is obtained as a result of the combined cycle corrosion test. did.

The components or surface treatment conditions of the paints used in the above Examples and Comparative Examples are shown in Table 2. The salt spray test and the combined cycle corrosion together with the curing conditions and the coating thickness when these paints were applied to an aluminum alloy washer. The test results are shown in Table 3, respectively. The combined cycle corrosion test results are also shown in the bar graph of FIG.

As a result of the salt spray test, when an aluminum alloy washer provided with the insulating coating film of Example 1 was interposed between both members, white rust did not occur even after 3000 hours. On the other hand, in the washer provided with the insulating coating film of Comparative Example 1, white rust occurred in 1448 hours. That is, when Example 1 is compared with Comparative Example 1, in Comparative Example 1, since a normal epoxy resin was used without using a hybrid epoxy resin modified with an alkoxylane partial condensate, rust prevention performance was poor. ing.
Further, according to the combined cycle corrosion test, in Example 1, the corrosion depth was 440 μm, but in Comparative Example 1, the corrosion depth was 980 μm, and a clear difference was recognized.

Next, when the antirust performance by the salt spray test of Example 1 and Comparative Example 2 was compared, in Example 1, white rust did not occur even after 3000 hours as described above, whereas Comparative Example When a washer provided with 2 insulating coatings was used, white rust occurred in 1512 hours. That is, since the insulating paint of Comparative Example 2 does not contain alumina fine powder, the antirust performance compared with the time of occurrence of white rust is clearly inferior.
Also, with respect to the combined cycle corrosion test result of Comparative Example 2, the corrosion depth in Example 1 was 440 μm, whereas when the washer of Comparative Example 2 was used, an obvious difference was recognized as 993 μm. It was.

In the salt spray test of Comparative Example 3, white rust was observed in 576 hours. That is, since the alumina powder blended in the insulating paint of Comparative Example 3 is not a nano-sized alumina fine powder of 70 nm or less, the rust prevention performance when compared with the time of occurrence of white rust is clearly inferior to that of Example 1. It became a thing.
Moreover, also in the evaluation result by the combined cycle corrosion test, when the washer provided with the insulating coating film of Comparative Example 3 was interposed, the corrosion depth according to Example 1 was 440 μm, whereas the corrosion depth was 1300 μm. It was depth.

  The insulating paint used in Example 2 is an insulating paint in which NANOBYK-3610 (commercially available slurry in which nano-alumina having an average particle size of 22 nm is dispersed) is blended as an alumina fine powder. Salt spray test and combined cycle test Comparing the results, it can be seen that the anticorrosive performance comparable to that of the insulating paint used in Example 1 is exhibited.

On the other hand, the insulating coating used in Comparative Example 4 is an insulating coating in which NANOBYK-3650 (a commercially available slurry in which silica having an average particle size of 22 nm is dispersed) is blended instead of fine alumina powder.
Comparing the salt spray test with the washer provided with the coating film made of the insulating paint of Example 2 and Comparative Example 4 and the combined cycle corrosion test result, the rust prevention performance of Example 2 (white rust occurrence time of 3000 hours or more, corrosion depth) 430 μm) was confirmed to be clearly superior to Comparative Example 4 (white rust generation time 1200 hours, corrosion depth 1180 μm).

Compared to Example 1 (using MDA as a curing agent for insulating paint), the results of salt spray test using a washer provided with a coating film made of the insulating paint according to Reference Example 3 (using an acid anhydride as a curing agent for insulating paint) are compared. In Example 1, white rust did not occur even after 3000 hours, whereas white rust occurred in 2448 hours.
Also in the combined cycle corrosion test, it is 440 μm in Example 1 but 520 μm in Reference Example 3 , and it can be seen that the insulating paint using MDA as the curing agent is superior. This is presumed to be due to excellent alkali resistance.

  Furthermore, when the evaluation result by the combined cycle corrosion test of Example 4 and Example 5 is compared with the result by Example 1, after performing a chemical conversion treatment (chromium free treatment) in advance, the aluminum which applied the insulating coating to the surface It can be seen that the alloy washer is superior in corrosion resistance.

The result by the combined cycle corrosion test of Example 1 , Example 2 using A6061 alloy (Al-Mg-Si system) as a material of a washer, and Examples 6-8 using A5052 alloy (Al-Mg system) is shown. In comparison, it is presumed that the Al—Mg-based alloy is slightly superior in rust prevention performance, and that a difference due to the quality of the rust prevention performance of the base material appears.

  Example 6 with an insulating paint using a methylmethoxysilane modified product (Composeran E-103) as an epoxy resin, and Example 9 with an insulating paint using a tetramethoxysilane modified product (Composeran E-102) Comparing the results of the combined cycle corrosion test, it was confirmed that the latter rust prevention performance was slightly inferior.

  In Comparative Example 5 using an alumite-treated washer, no white rust was observed even after 3000 hours in the salt spray test, but in the combined cycle corrosion test, the corrosion depth was as large as 830 μm. Further, in Comparative Example 6 using a trivalent chromium-treated washer, white rust was observed in 2500 hours in the salt spray test, and in the combined cycle corrosion test, the corrosion depth was as extremely large as 5500 μm. .

As described above, according to the fastening structures of Example 1 , Example 2, and Examples 4 to 9 in which the aluminum alloy washer having an insulating coating film having a predetermined composition is interposed between the magnesium alloy member and the steel bolt. It was confirmed that the electric corrosion resistance performance is equivalent to or better than that using an alumite-treated washer or the like.

1 First member (made of magnesium alloy)
2 Second member 3 Galvanized bolt 4 Washer (aluminum alloy member)

Claims (8)

An epoxy resin having a fastening structure of a first member made of a magnesium alloy and a second member mainly composed of a metal nobler than magnesium, which is modified with a partial condensate of alkoxysilane between the fastening surfaces of both members average particle size comprises 0.5% to 10% of fine alumina powder 10~40nm at mass ratio during comprises an insulative coating having a thickness of 10～12.2Myuemu, curing agent the modified epoxy resin fastening structure of the magnesium alloy member, characterized in that the menthenediamine. A fastening structure of a first member made of a magnesium alloy and a second member mainly composed of a metal nobler than magnesium, and having an average particle size of 10 to 10 in an epoxy resin modified with a partial condensate of alkoxysilane Both members are fastened together with an aluminum alloy member comprising an insulating coating film having a thickness of 10 to 12.2 μm containing 0.5 to 10% by mass of 40 nm alumina fine powder, and the modified epoxy resin A fastening structure for a magnesium alloy member, wherein the hardener is mensendiamine .   The said aluminum alloy member is a washer, and is fastened with the steel volt | bolt, The fastening structure of the magnesium alloy member of Claim 2 characterized by the above-mentioned.   4. The magnesium alloy member fastening structure according to claim 3, wherein a plate thickness of the aluminum alloy washer is 0.1 to 0.5 times a diameter of the steel bolt.   The magnesium alloy according to any one of claims 2 to 4, wherein the surface of the aluminum alloy member is subjected to a chemical conversion treatment, and an insulating coating film is formed through the chemical conversion treatment layer. Fastening structure for members. The magnesium alloy member fastening structure according to any one of claims 1 to 5, wherein the particle shape of the alumina fine powder is substantially spherical. The fastening structure for a magnesium alloy member according to any one of claims 1 to 6, wherein the alkoxysilane is methyltrimethoxysilane. The fastening structure of a magnesium alloy member according to any one of claims 1 to 7, wherein the formation method of the insulating coating film is any one of a dip and spin method, a dip drain method, and a spray coating method. .

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