Cage for constant-velocity joint and method for manufacturing the same
First Claim
1. A heat-treated cage of a stationary type constant-velocity joint having an outer ring and an inner ring, said cage having a cylindrical portion formed with a plurality of pockets at equal angular intervals to receive balls for transmitting a turning torque between said outer ring and said inner ring, said cage having a spherical outer surface kept in contact with and guided by a spherical inner surface of said outer ring and a spherical inner surface kept in contact with and guided by a spherical outer surface of said inner ring,wherein each of said pockets has a pair of machined end faces that oppose each other in a circumferential direction of the cage and a pair of side faces that oppose each other in an axial direction of the cage, and said pair of machined end faces have a lower surface hardness than said pair of side faces that oppose each other in an axial direction of the cage.
1 Assignment
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Accused Products
Abstract
A cage having a plurality of pockets, and a pair of end faces of each pocket formed in the cage that oppose each other in a circumferential direction of the cage are formed by surfaces cut after hardening and their surface hardness is reduced to a value lower than the surface hardness of a pair of side faces of each pocket that oppose each other in an axial direction of the cage to impart toughness to the bridge portions defined between the pockets and thus to increase the strength of the cage.
19 Citations
15 Claims
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1. A heat-treated cage of a stationary type constant-velocity joint having an outer ring and an inner ring, said cage having a cylindrical portion formed with a plurality of pockets at equal angular intervals to receive balls for transmitting a turning torque between said outer ring and said inner ring, said cage having a spherical outer surface kept in contact with and guided by a spherical inner surface of said outer ring and a spherical inner surface kept in contact with and guided by a spherical outer surface of said inner ring,
wherein each of said pockets has a pair of machined end faces that oppose each other in a circumferential direction of the cage and a pair of side faces that oppose each other in an axial direction of the cage, and said pair of machined end faces have a lower surface hardness than said pair of side faces that oppose each other in an axial direction of the cage.
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14. A method of manufacturing a cage of a constant-velocity joint, the method comprising;
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turning outer and inner surfaces of a tubular cage blank to form spherical outer and inner surfaces;
pressing said cage blank to form a plurality of pockets at equal regular intervals;
hardening said cage blank by carburizing;
grinding said spherical outer and inner surfaces of said cage blank after heat treatment; and
cutting a pair of end faces of each of said pockets so that said pair of end faces will have a lower surface hardness than a pair of side faces of each of said pockets.
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15. A stationary constant-velocity joint comprising an outer ring, an inner ring, said outer ring being formed with a plurality of curved track grooves in a spherical inner surface thereof and said inner ring being formed with a plurality of curved track grooves in spherical outer surface thereof, the center of curvature of said track grooves of said outer ring and the center of curvature of said track grooves of said inner ring being offset by equal distances in opposite directions from the angular center of the joint, a plurality of torque-transmitting balls mounted between said track grooves formed in said outer ring and said track grooves formed in said inner ring, and a heat-treated cage having a cylindrical portion formed with a plurality of pockets at equal angular intervals to receive said balls for transmitting a turning torque between said outer ring and said inner ring,
wherein said pockets each have a pair of machined end faces that oppose each other in a circumferential direction of the cage and a pair of side faces that oppose each other in an axial direction of the cage, and said pair of machined end faces have a lower surface hardness than said pair of side faces that oppose each other in an axial direction of the cage.
Specification