Assembly procedure of a bearing unit—HUB flange

The invention claimed is: 1. An assembly method for a bearing-hub unit comprising: providing a rotatable hub that functions as a radially inner ring and a bell of a constant velocity joint, a bearing unit having a stationary radially outer ring, a first row of axially external rolling bodies, and a second row of axially external rolling bodies that are disposed between the radially outer ring and the hub, wherein the rolling bodies are housed inside corresponding cages, and sealing means, the method further comprising: a) press-fitting a first axially external sealing means, on a radially external cylindrical surface, of the rotatable hub, b) mounting the axially outer cage and rolling bodies in correspondence of an axially outer raceway of the hub, c) providing a step at the bottom of a groove that defines the axially outer raceway of the hub, and mounting the radially outer ring and inclination of the outer ring of a predetermined angle relative to the hub, d) mounting the axially internal rolling bodies, in correspondence with an axially inner raceway of the hub from the axially inner side, e) aligning the radially outer ring to the hub to eliminate the inclination of the outer ring, f) snappingly inserting the axially internal cage on rolling bodies from the axially inner side, and g) press-fitting a second axially internal sealing means on its own seat from the axially inner side. 2. The assembly method according to claim 1 , wherein the bearing-hub unit is provided with a symmetrical internal shape or that the radius (R) of the circumference of the centers of the axially outer rolling bodies is equal to the radius (R′) of the circumference of the centers of the axially inner rolling bodies. 3. The assembly method according to claim 1 , wherein the bearing-hub unit is provided with an asymmetrical internal shape, or that the radius (R) of the circumference of the centers of the axially outer rolling bodies is not equal to the radius (R′) of the circumference of the centers of the axially inner rolling bodies. 4. The assembly method according to claim 3 , wherein during step b) the cage and the rolling bodies that are a pre-assembled sub-unit, are assembled at the same time, if the diameter (B) of the axially internal shoulder is smaller or equal to the minimum diameter (A) of a groove that defines the axially outer raceway of the hub. 5. The assembly method according to claim 1 , wherein in order to perform step b) the dimension of the inner diameter (E) of the cage must be greater than the dimension of the diameter (B) of an axially inner shoulder of the hub. 6. The assembly method according to claim 1 , wherein during step b) the cage is mounted first and subsequently the rolling bodies are inserted within the same cage, if the diameter (B) of the axially internal shoulder is greater than the minimum diameter (A) of a groove that defines the axially outer raceway of the hub. 7. The assembly method according to claim 1 , wherein during step f) the diameter (B) of the shoulder, the inner diameter (E′) of the cage and a value of a radial safety distance (C) are according to the following relationship: B<E−2*C. 8. The assembly method according to claim 1 , wherein during step f) the rolling bodies are held in a position equidistant from one another by a specific “comb” tool.