Method for measuring bearing cup gap in universal joint and method for manufacturing universal joint to which the measuring method is applied

What is claimed is: 1. A method for manufacturing a universal joint, the universal joint including: a yoke member including a yoke main body portion and a pair of arms extending in a bifurcated manner from the yoke main body portion and each having a holding hole formed therein; a pair of bearing cups shaped like bottomed tubes and press-fitted into the holding holes such that openings of the bearing cups face each other; a joint spider member with a pair of shaft portions supported by the bearing cups so as to be able to swing; grooves formed in inner peripheral surfaces of the holding holes in the arms or in outer peripheral surfaces of the bearing cups; and snap rings fitted into the grooves to restrain the bearing cups from moving away from the joint spider member, the manufacturing method comprising: measuring gaps between bottom surfaces of the bearing cups and end surfaces of the shaft portions by acquiring first relationship data that indicates a relationship between a first pressing load and a first deformation amount of the arms when, with the yoke member alone, the first pressing load is applied to the arms in an approaching direction in which the arms approach each other so that the arms are subjected to elastic bending deformation; acquiring second relationship data that indicates a relationship between a second pressing load and a second deformation amount of the joint spider member and the bearing cups when, with the bearing cups fitted over the shaft portions, the second pressing load is applied to the bearing cups in an approaching direction in which the bearing cups approach each other so that the joint spider member and the bearing cups are subjected to elastic compressive deformation; acquiring a displacement amount of the bearing cups when, with the bearing cups and the joint spider member assembled to the yoke member, a third pressing load is applied to the bearing cups in the approaching direction; and calculating gaps between the bottom surfaces of the bearing cups and end surfaces of the shaft portions based on the first relationship data, the second relationship data, and the displacement amount of the bearing cups; and selecting a plate thickness for the snap rings based on the measured gaps and fitting the snap rings into the grooves to manufacture the universal joint. 2. The method for manufacturing a universal joint according to claim 1 , wherein the step of calculating gaps comprises, in a graph representing the pressing load on an axis of abscissas and the deformation amount and the displacement amount on an axis of ordinate, linearly approximating a group of the first relationship data to calculate a first line; linearly approximating a group of the second relationship data to calculate a second line and calculating a gradient of the second line; calculating a third line having the same gradient as the second line and passing through a point obtained by plotting on the graph the displacement amount resulting from application of the third pressing load; and calculating an intersection point between the first line and the third line, which corresponds to the bearing cup gap resulting from release of the third pressing load. 3. A method for manufacturing a universal joint, the universal joint including: a yoke member including a yoke main body portion and a pair of arms extending in a bifurcated manner from the yoke main body portion and each having a holding hole formed therein; a pair of bearing cups shaped like bottomed tubes and press-fitted into the holding holes such that openings of the bearing cups face each other; a joint spider member with a pair of shaft portions supported by the bearing cups so as to be able to swing; grooves formed in inner peripheral surfaces of the holding holes in the arms; and snap rings fitted into the grooves to restrain the bearing cups from moving away from the joint spider member, the manufacturing method comprising: measuring gaps between bottom surfaces of the bearing cups and side surfaces of the grooves by acquiring first relationship data that indicates a relationship between a first pressing load and a first deformation amount of the arms when, with the yoke member alone, the first pressing load is applied to the arms in an approaching direction in which the arms approach each other so that the arms are subjected to elastic bending deformation; acquiring second relationship data that indicates a relationship between a second pressing load and a second deformation amount of the joint spider member and the bearing cups when, with the bearing cups fitted over the shaft portions, the second pressing load is applied to the bearing cups in an approaching direction in which the bearing cups approach each other so that the joint spider member and the bearing cups are subjected to elastic compressive deformation; acquiring a displacement amount of the bearing cups when, with the bearing cups and the joint spider member assembled to the yoke member, a third pressing load is applied to the bearing cups in the approaching direction; and calculating gaps between the bottom surfaces of the bearing cups and end surfaces of the shaft portions based on the first relationship data, the second relationship data, and the displacement amount of the bearing cups; and selecting a plate thickness for the snap rings based on the measured gaps and fitting the snap rings into the grooves to manufacture the universal joint. 4. The method for manufacturing a universal joint according to claim 3 , wherein the step of calculating gaps comprises, in a graph representing the pressing load on an axis of abscissas and the deformation amount and the displacement amount on an axis of ordinate, linearly approximating a group of the first relationship data to calculate a first line; linearly approximating a group of the second relationship data to calculate a second line and calculating a gradient of the second line; calculating a third line having the same gradient as the second line and passing through a point obtained by plotting on the graph the displacement amount resulting from application of the third pressing load; and calculating an intersection point between the first line and the third line, which corresponds to the bearing cup gap resulting from release of the third pressing load.