Patent ID: 7544131
Filing Date: 2009-06-09
Classification: F16D,Y10S

Abstract:
1. A tripod-type constant velocity joint, comprising: an outer joint member coaxially connected to a first rotation shaft and formed of a cylindrical tubular body having three guide grooves formed on an inner surface thereof at substantially equal circumferential intervals, the guide grooves extending parallel to a center axis of the tubular body; an inner joint member coaxially connected to a second rotation shaft and having a boss portion, and three tripod shafts provided on the boss portion at substantially equal circumferential intervals and extending radially outward, each of the tripod shafts having a tripod spherical surface formed at a distal end portion thereof; and three-roller units each having a cylindrical center hole and a cylindrical surface formed on an outer periphery thereof and being coaxial with the center hole, the outer joint member, the inner joint member, and the three roller units being assembled together such that the roller units are rotatably supported on the corresponding tripod shafts of the inner joint member and received in the corresponding guide grooves of the outer joint member, wherein each of the guide grooves includes a pair of parallel elongated flat surfaces facing each other while sandwiching a first center plane including the center axis of the tubular body; each roller unit is supported on the corresponding tripod shaft such that a wall surface of the center hole is slidably fitted on the corresponding tripod spherical surface, and the cylindrical surface is located between and in engagement with the pair of elongated flat surfaces of the corresponding guide groove such that only rolling along the center axis of the tubular body is permitted; the outer periphery cylindrical surface of each roller unit has a width smaller than that of each roller unit; and the radius, outer width, and inner width of the outer periphery cylindrical surface of each roller unit, and the radius of the center hole of each roller unit are determined to satisfy the following two inequalities: where Rtc: the radius of a circle passing through the respective centers of the tripod spherical surfaces, Θ: the maximum joint angle formed between the outer joint member and the inner joint member, R R μ: coefficient of friction between each tripod spherical surface and the wall surface of the center hole of the corresponding roller unit, W W whereby a line of action of a force transmitted through a contact position between each tripod spherical surface and a wall surface of a corresponding center hole does not pass through a point outside a side edge of the cylindrical surface of the roller unit located opposite the center axis side.