Power transmission shaft

The invention claimed is: 1. A power transmission shaft provided between a first shaft provided on a driving source side of a vehicle, and a second shaft provided on a driven wheel side, the power transmission shaft comprising: a shaft portion provided between the first shaft and the second shaft; and a bearing including a cylindrical portion, an internal spline portion, and an internal spline side annular groove, the cylindrical portion being provided to the shaft portion, and including a first end portion and a second end portion that are both end portions in a direction of a rotation axis of the shaft portion, the internal spline portion being formed on an inner circumference side of the cylindrical portion, and arranged to be engaged with an external spline portion formed on an outer circumference side of one of the first shaft and the second shaft by inserting the one of the first shaft and the second shaft into the cylindrical portion from the first end portion side of the cylindrical portion toward the second end portion side of the cylindrical portion, the internal spline side annular groove being formed on the inner circumference side of the cylindrical portion, and configured to hold a circlip provided in an external spline side annular groove formed on the outer circumference side of one of the first shaft and the second shaft to restrict movement of the one of the first shaft and the second shaft with respect to the cylindrical portion in the direction of the rotation axis of the shaft portion, and including a bottom surface, and a first side wall and a second side wall which are a pair of side walls provided on both sides in the direction of the rotation axis of the shaft portion in a section passing through the rotation axis of the shaft portion, the first side wall being provided on the first end portion side of the bottom surface, and including a first inclination surface inclined with respect to the rotation axis of the shaft portion so that a radius of the first side wall which is a shortest distance from the rotation axis of the shaft portion is gradually increased from the first end portion side toward the second end portion side, and on which the circlip is abutted in a state where a radius of the circlip is decreased within the internal spline side annular groove, and the second side wall being provided on the second end portion side of the bottom surface, and on which the circlip is abutted in the state where the radius of the circlip is decreased within the internal spline side annular groove, wherein an annular groove bottom surface radius is a shortest distance between the bottom surface and the rotation axis of the shaft portion; a spline tooth bottom surface radius is a shortest distance between a tooth bottom surface of the internal spline portion, and the rotation axis of the shaft portion; and the internal spline side annular groove has the annular groove bottom surface radius smaller than the spline tooth bottom surface radius, and wherein the circlip is not abutted on the bottom surface provided radially outside the abutment portion between the circlip and the first side wall, and the abutment portion between the circlip and the second side wall. 2. The power transmission shaft as claimed in claim 1 , wherein the circlip is abutted on the first inclination surface. 3. The power transmission shaft as claimed in claim 2 , wherein the circlip is abutted on a portion of the second side wall which is other than an inner end portion of the second side wall in a radial direction of the rotation axis of the shaft portion. 4. The power transmission shaft as claimed in claim 1 , wherein the second side wall includes a second raised arc surface which is provided at an inner end portion of the second side wall in a radial direction of the rotation axis of the shaft portion, and which protrudes toward a center of a section of the circlip in the section passing through the rotation axis of the shaft portion; and the circlip is abutted on the second raised arc surface. 5. The power transmission shaft as claimed in claim 1 , wherein the second side wall includes a second recessed arc surface which is provided at an inner end portion of the second side wall in a radial direction of the rotation axis of the shaft portion, and which is recessed in a direction opposite to a direction toward a center of a section of the circlip in the section passing through the rotation axis of the shaft portion; and the circlip is abutted on the second recessed arc surface. 6. The power transmission shaft as claimed in claim 1 , wherein the second side wall includes a second chamfering portion; the second chamfering portion is provided at an inner end portion of the second side wall in a radial direction of the rotation axis of the shaft portion; the second chamfering portion is formed in parallel with a line perpendicular to a line extending from the second chamfering portion to a center of a section of the circlip in the section passing through the rotation axis of the shaft portion; and the circlip is abutted on the second chamfering portion. 7. The power transmission shaft as claimed in claim 1 , wherein the second side wall includes a second inclination surface inclined with respect to the rotation axis of the shaft portion so that a radius of the second side wall which is a shortest distance from the rotation axis of the shaft portion is gradually decreased from the first end portion side toward the second end portion side; and the circlip is abutted on the second inclination surface. 8. The power transmission shaft as claimed in claim 7 , wherein a first inclination angle is an inferior angle of angles sandwiched by the first side wall and an inner circumference surface of the cylindrical portion to have a first apex which is an inner end portion of the first side wall in a radial direction of the rotation axis of the shaft portion, in the section passing through the rotation axis of the shaft portion; a second inclination angle is an inferior angle of angles sandwiched by the second side wall and the inner circumference surface of the cylindrical portion to have a second apex which is an inner end portion of the second side wall in the radial direction of the rotation axis of the shaft portion, in the section passing through the rotation axis of the shaft portion; and the internal spline side annular groove has the first inclination angle greater than the second inclination angle. 9. The power transmission shaft as claimed in claim 7 , wherein a first inclination angle is an inferior angle of angles sandwiched by the first side wall and an inner circumference surface of the cylindrical portion to have a first apex which is an inner end portion of the first side wall in a radial direction of the rotation axis of the shaft portion, in the section passing through the rotation axis of the shaft portion; a second inclination angle is an inferior angle of angles sandwiched by the second side wall and the inner circumference surface of the cylindrical portion to have a second apex which is an inner end portion of the second side wall in the radial direction of the rotation axis of the shaft portion, in the section passing through the rotation axis of the shaft portion; and the internal spline side annular groove has the first inclination angle smaller than the second inclination angle. 10. The power transmission shaft as claimed in claim 1 , wherein the first side wall includes a first recessed arc surface which is provided at an inner end portion of the first side wall in a radial direction of the rotation axis of the shaft portion, and which is recessed in a direction opposite to a direction toward a center of a section of the ci