The present invention relates to a technology for preventing the occurrence of electrolytic corrosion in fastening parts in a fastening structure for a magnesium alloy member and a fastening member made of a metal other than that of the magnesium alloy member.
In the automobile industry, recently, there have been an increasing demands for fuel economy as concerns about environmental problems mount. To meet such demands, the automobile industry is researching ways to reduce the weight of car bodies, and is attempting to increase the use of magnesium alloy in automotive parts because of it is lightest in weight among metals which may be practically used. Recently, in particular, it has been research for use in parts demanding very high corrosion resistance, such as the outer housing and structural parts.
However, since magnesium alloy is the most common practical alloy, when fastened together with different metals such as iron and aluminum, electrolytic corrosion is likely to occur in the presence of moisture containing electrolytes. In particular, in the engine space and at the underside of an automobile, electrolytic corrosion is extremely promoted by the action of electrolytes contained in rainwater, melting snow, salt, etc., and problems, that is, loosening, may occur in the fastened parts. Hitherto, as disclosed in Japanese Patent No. 2715758, aluminum washers were insulated by anodic oxidation, or bolts were coated with resin as disclosed in Japanese Patent Publication No. S58-40045.
However, anodic oxidation of aluminum washers is very expensive. In the case of coating bolts with resin, contact adhesion of resin coating films on bolts and durability are insufficient, and the coating film may peel off, resulting in electrolytic corrosion, and improvement in contact adhesion is required.
It is therefore an object of the invention to provide a structure and a method for resistance to electrolytic corrosion which can assure sufficient contact fastening of a magnesium alloy member securely and at low cost while preventing electrolytic corrosion by insulating a fastening member such as steel bolt or washer.
The structure which is resistant to electrolytic corrosion for an magnesium alloy member of the invention is characterized by coating at least the surface of a fastening member which is to contact with the magnesium alloy member with a first coating layer by electro deposition, and coating a second coating layer having polytetrafluoroethylene particles (PTFE particles) dispersed therein on the first coating layer.
The method of preventing electrolytic corrosion of a magnesium alloy member of the invention is characterized by the steps of applying a first coating layer by electro deposition on at least the surface of a fastening member which is to contact the magnesium alloy member, and a step of applying a second coating layer having PTFE particles dispersed therein on the first coating layer, thereby forming a crosslinking structure of the first coating layer and second coating layer.
According to the invention, the first coating layer formed by electro deposition has outstanding contact adhesion on the fastening member and outstanding durability compared with conventional dip coatings. Therefore, the first coating layer is difficult to peel off the surface of the fastening member, and electrolytic corrosion is thereby prevented effectively. The second coating layer formed by disposing PTFE particles is crosslinked to the first coating layer and is firmly adhered to the first coating layer. The second coating layer has extremely low frictional resistance, and the contact adhesion and durability thereof are extremely high. In addition, since the second coating layer is water repellent, the electrolytic corrosion preventive effects and weatherability of the coating are enhanced.
When the fastening member is a bolt, since the frictional resistance is low, variation in friction in fastening is reduced. Accordingly, the fastening torque is stable when fastening the bolt, variations in the axial force of the bolt are suppressed, and a uniform axial force is obtained. Hitherto, it was difficult to obtain a uniform axial force in a completely degreased state, or in a state contaminated with coolant, rust preventive, or other oil or grease, or when surface conditions varied; however, since the second coating layer forming the surface has low frictional resistance and is water repellent, a uniform axial force is obtained, regardless of surface conditions.
The material for the first coating layer of the invention includes various resins such as cationic or anionic epoxy, acrylic, polybutadiene, and alkyd resins; cationic epoxy resins are preferably used from the viewpoint of high corrosion resistance and contact adhesion. The thickness of the first coating layer should be 5 μm or more in order to assure contact adhesion and durability; however, if the thickness exceeds 50 μm, uniform thickness may not be obtained, and improvement of effect is not expected, and the electro deposition consumes too much energy. Therefore, the thickness of the first coating layer is preferred to be 5 to 50 μm, or more preferably 20 to 50 μm. When forming the first coating layer on the fastening member, in the case in which the fastening member is made of steel, it is preferred to form a base coat by forming a film of phosphate or black oxide. As the base coat, a Zn or Cr plating may also be applied.
The second coating layer of the invention is formed by dispersing PTFE particles in a synthetic resin and an organic solvent such as alcohol or ketone in order to adhere more firmly to the first coating layer, and drying, and the concentration of PTFE particles in the solvent is, for example, 1 to 30%. At this time, the content of the synthetic resin is preferred to be 10 to 50% of the solid content of the PTFE. In order that the second coating layer may exhibit a desired low frictional coefficient, the molecular weight of PTFE particles is preferred to be 1000 or less, and the particle size should be 1 μm or less. The thickness of the second coated layer is preferred to be 1 to 10 μm in order to obtain durability and stability of frictional torque. These materials for the first coating layer and second coating layer are inexpensive, and therefore the invention is realized at low cost.
Actions and effects of the invention are described below with reference to an embodiment.
(1) Test by Ring-on-Disk Method
A. Adhesion Test of Surface Layer
Referring first to
According to the descriptions shown in Table 1, coating layers were formed on the surface of steel disks 50 mm in diameter and 1 mm thick, and test pieces of the Example and Comparative Examples 1 to 4 were obtained. While rotating the disks about the shaft at a speed of 20 rpm, the end face of a magnesium alloy ring of Ra 0.13 to 0.20 μm, 20 mm inner diameter and 25.6 mm outer diameter was pressed against the surface, and while raising the pressing load at a rate of 100 kgf/min, changes in frictional torque (kgf-cm) on the basis of the driving torque for rotating the disk were measured. Results of measurement are shown in
The strength resisting shear peeling is judged to be inferior when the frictional torque is high as compared with the load of the ring, and excellent when the frictional torque is low. As shown in
B. Adhesion Test of Each Coating Layer in the Example
In the Example, the first coating layer was prepared in five thicknesses of 3 μm, 5 μm, 20 μm, 50 μm, and 70 μm, and in these first coating layers, the frictional torque was measured similarly by the ring-on-disk method. Furthermore, the second coating layer to be laminated on the first coating layer was prepared in five thick of less than 1 μm, 1 μm, 3 μm, 10 μm, and 15 μm, and in these second coating layers, the frictional torque was measured similarly by the ring-on-disk method. Results of the first coating layers are shown in
(2) Durability Test of Resin by Salt Spray Test
A base coat was applied on the surface of steel test pieces, and the first coating layer was formed on the base coat by electro deposition of resins, such as cationic or anionic epoxy resin, acrylic resin, polybutadiene resin, and alkyd resin, and salt water was sprayed on the coating layers for a specified time, and occurrence of rust was investigated. The test method conforms to JIS K 5400. Results are shown in Table 2. In Table 2, results were evaluated as ⊚: no rust, ◯: small spots of rust, and Δ: signs of rust, but no practical problems.
According to Table 2, the coating layer of epoxy resin was not torn by pencil of hardness 3H, and therefore, it was high in strength. The coating layers by acrylic resin and polybutadiene resin were strong enough by a pencil of hardness 2H, and the coating layer by alkyd resin had no practical problem by a pencil of hardness H. Therefore, these resins can be used as resins for the first coating layer, and in particular, the cationic epoxy resin is most suitable.
(3) Water Repellence Test
Purified water was dropped on the surface of the Example and Comparative Examples 1 and 2 with a drop diameter of 2 mm, and the contact angle of the water drop on each coating layer was measured. Results are shown in Table 3. The larger the contact angle, the higher is the water repellence.
According to Table 3, the second coating layer of the Example is superior in water repellence to the coating layer of the prior art. As compared with the first coating layer, the second coating layer of the Example is extremely improved in water repellence, and the effect of the second coating layer as a dispersed layer of PTFE particles was observed.
(4) Measurement of Axial Force
Plural samples were prepared by forming the coating layer by applying the Example on M8 flanged bolts, and these were engaged and fastened with nut members, and the fastening torque and axial force were measured. Conventional samples which were galvanized were similarly tested. Results are shown in
(5) Measurement of Axial Force (Comparison Between Oiled State and Degreased State)
Plural samples were prepared by forming the coating layer by applying the Example on M8 flanged bolts, and these were tested in an oiled state and in a degreased state, and the fastening torque and axial force were measured. Conventional samples which were galvanized were similarly tested. Results are shown in
(6) Test by Ball-on-Disk Method
As the second coating layer, dispersed layers of three types of PTFE particles which were different in molecular weight and particle size were used, and their frictional coefficients were measured by the ball-on-disk method. In the ball-on-disk method, as shown in
Number | Date | Country | Kind |
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2001-251006 | Aug 2001 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP02/08385 | 8/20/2002 | WO | 00 | 2/23/2004 |
Publishing Document | Publishing Date | Country | Kind |
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WO03/018873 | 3/6/2003 | WO | A |
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6209409 | Kitahata et al. | Apr 2001 | B1 |
6323264 | Nazaryan et al. | Nov 2001 | B1 |
20020127083 | Ando et al. | Sep 2002 | A1 |
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56-015872 | Feb 1981 | JP |
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Number | Date | Country | |
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20040206635 A1 | Oct 2004 | US |