The present disclosure pertains to an anti-electrolytic corrosion bearing.
In recent years, with the progress in development of EV vehicles (electric cars), HV vehicles (hybrid cars), and the like, the number of high-voltage components mounted in a single automobile has been increasing. If electric current from these high-voltage components flows through a bearing, then electrolytic corrosion may occur, for example, on: (a) the surface of a rolling element, (b) raceway surfaces of an outer ring, and (c) an inner ring of the bearing, which can cause damage to the bearing. For this reason, the inventor of the present application invented the anti-electrolytic corrosion rolling ball bearing disclosed in Japanese Patent Application JP H7-43488U.
The anti-electrolytic corrosion rolling ball bearing in JP H7-43488U is provided with a cross-sectional step portion, or a protruding semi-circular portion, or a linear chamfered portion on a peripheral edge between a radially inner surface (a shoulder portion next to balls) of an outer ring or a radially outer surface of an inner ring, and an end surface. The step portion or the chamfered portion is coated with an electrical insulator, which extends from a radially outer surface of the outer ring or a radially inner surface of the inner ring, then reaches and goes beyond the end surface, to the step portion or the chamfered portion.
However, if the chamfered portion formed on the radially inner surface of the outer ring is also coated with the electrical insulator as in JP H7-43488U, the thickness accuracy deteriorates if insert molding is used. For this reason, finishing needs to be performed after forming an electrical insulator coating by means of insert molding, which leads to higher costs. Moreover, if a coating is formed by means of insert molding, the thickness of the coating becomes large, and thus a problem arises in that the coating is deformed and an axial shift is likely to occur when a load is received. Although an insulating coating can also be made in the form of a thin film, if the coating is applied to the radially inner surface of the outer ring, it is difficult to apply the coating solely to the shoulder portion, so the raceway surface is also covered. Therefore, it has been difficult to apply the insulating coating to the radially inner surface.
In view of the foregoing problem, an object of the present invention is to provide an anti-electrolytic corrosion bearing that has a high dimensional accuracy of the outer cylindrical surface, and in which an axial shift due to a load is unlikely to occur and electrolytic corrosion can be favorably prevented.
To solve the foregoing problem, a representative configuration of the anti-electrolytic corrosion bearing according to the present invention lies in an anti-electrolytic corrosion bearing including: an insulating coating applied to an outer cylindrical surface of an outer ring; and an insulating washer having a ring shape that covers an end surface of the outer ring.
According to the above configuration, the insulating coating is applied only to the outer cylindrical surface of the outer ring. In other words, the insulating coating is not applied to the radially inner surface of the outer ring. Since the insulating coating is thinner than a coating formed by means of insert molding, the dimensional accuracy of the outer cylindrical surface increases, and an axial shift due to deformation can also be prevented. Also, finishing performed in the case of insert molding can be simplified, and cost reduction can be achieved. In addition, due to the end surface of the outer ring being covered by the ring-shaped insulating washer, high insulation performance can be ensured even though the insulating coating is not applied to the radially inner surface. Accordingly, electrolytic corrosion of the bearing can be favorably prevented.
If the insulating washer has a flange that protrudes along a radially inner surface of the outer ring from a wall that covers the end surface of the outer ring, and the insulating washer is fitted to the outer ring, the radially inner surface of the outer ring can be reliably insulated. Accordingly, the aforementioned effect can be enhanced. Furthermore, since the outer ring and the insulating washer are integrated, handling at the time of attachment can be made easier.
It is preferable that a groove in a circumferential direction is formed on a radially inner surface of the outer ring, and a claw that engages with the groove is formed on a flange of the insulating washer. Thus, it can be favorably prevented that the insulating washer is detached (comes off).
According to the present invention, an anti-electrolytic corrosion bearing can be provided that has a high dimensional accuracy of the outer cylindrical surface, and in which an axial shift due to a load is unlikely to occur and electrolytic corrosion can be favorably prevented.
Hereinafter, a preferable embodiment of the present invention will be described in detail with reference to the attached drawings. Dimensions, materials, other specific values, and the like described in this embodiment are merely examples for facilitating understanding of the invention, and are not intended to limit the present invention unless stated otherwise. Note that in the present specification and drawings, elements having substantially the same functions and configurations are assigned the same reference numerals to omit redundant descriptions, and elements that do not directly relate to the present invention are omitted in the description or drawings.
In the bearing 100 of the present embodiment, an insulating coating 110 is applied to an outer cylindrical surface 104a of the outer ring 104, as shown in
The end surface 104b of the outer ring 104 is covered by the insulating washer 120. As shown in
The insulating coating 110 can be applied since the radially inner surface 104c is not coated and only the outer cylindrical surface 104a and the end surface 104b of the outer ring 104 are coated as in the above-described configuration. This is because, since the radially inner surface 104c is not coated, there is no concern that the raceway surface is covered when a liquid coating material is applied. Furthermore, since the insulating coating 110 is thinner than a coating formed by means of insert molding, the dimensional accuracy of the outer cylindrical surface of the bearing 100 increases, and an axial shift due to deformation can also be prevented. Also, finishing performed in the case of insert molding can be simplified. Accordingly, the cost at the time of manufacturing the bearing 100 can be reduced.
By covering the end surface 104b of the outer ring 104 with the ring-shaped insulating washer 120, a portion between the radially inner surface 104c and the casing 10 can be reliably insulated even though the insulating coating is not applied to the radially inner surface 104c. Accordingly, it is possible to ensure high insulation performance and favorably prevent electrolytic corrosion of the bearing 100.
In a bearing 100b as shown in
A wall 128 of an insulating washer 120c of a bearing 100c shown in
Although preferable embodiments of the present invention have been described above with reference to the attached drawings, the present invention is not limited to the above-described examples. It is apparent that a person skilled in the art may conceive various modifications and variations within the scope of the appended patent claims, and those modifications and variations should be understood to be naturally encompassed in the technical scope of the present invention.
The present invention can be used as an anti-electrolytic corrosion bearing.
Number | Date | Country | Kind |
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2019-205400 | Nov 2019 | JP | national |