Bearing cage and use thereof

What is claimed is: 1. A one-way snap-in cage for a deep groove ball bearing, comprising: an annular backbone portion, and a hanging out portion extending from the backbone portion towards an axial side, the hanging out portion comprising: a pocket for accommodating a rolling element of the bearing in a circumferential direction, and a pocket connection used to connect adjacent pockets, a bottom portion of the pocket being formed integrally with the backbone portion, and at other positions in the circumferential direction, the backbone portion extending in an axial direction to form the pocket connection, wherein the ratio H c /D w of a radial size H c of the cage in terms of thickness to the diameter Dw of the rolling element of the bearing satisfies the relation 17.679%≤H c /D w ≤37.389%, and wherein the radial size H c of the cage is equal in value to half of the difference between the maximum outer diameter D c_max and the minimum inner diameter D c_min of the cage as follows in the equation: H c =( D c_max −D c_min )/2. 2. The one-way snap-in cage according to claim 1 , wherein the ratio H c /D w of the radial size H c of the cage in terms of thickness to the diameter D w of the rolling element of the bearing further satisfies the relation 19.711%≤H c /D w ≤33.325%. 3. The one-way snap-in cage according to claim 2 , wherein the ratio H c /D w of the radial size H c of the cage in terms of thickness to the diameter D w of the rolling element of the bearing yet further satisfies the relation 20.523%≤H c /D w ≤31.293%. 4. The one-way snap-in cage according to claim 1 , wherein the backbone portion uses a single-layer structure, the ratio H b /D w of a radial size H b of the backbone portion in terms of thickness to the diameter D w of the rolling element of the bearing satisfies the relation 10.16%≤H b /D w ≤28.448%, wherein the radial size H b of the backbone portion in terms of thickness is defined as half of the difference between the maximum outer diameter D b_max and the minimum inner diameter D b_min of the backbone portion, that is, H b =(D b_max −D b_min )/2. 5. The one-way snap-in cage according to claim 4 , wherein the ratio H b /D w of the radial size H b of the backbone portion in terms of thickness to the diameter D w of the rolling element of the bearing further satisfies the relation 11.786%≤H b /D w ≤24.384%. 6. The one-way snap-in cage according to claim 5 , wherein the ratio H b /D w of the radial size H b of the backbone portion in terms of thickness to the diameter D w of the rolling element of the bearing yet further satisfies the relation 13.411%≤H b /D w ≤20.32%. 7. The one-way snap-in cage according to claim 1 , wherein the backbone portion uses a single-layer structure, the ratio H b /H of a radial size H b of the backbone portion in terms of thickness to a radial size H of the bearing in terms of thickness satisfies the relation 5%≤H b /H≤15%, wherein the radial size H b of the backbone portion is defined as half of the difference between the maximum outer diameter D b_max and the minimum inner diameter D b_min of the backbone portion, that is, H b =(D b_max −D b_min )/2; and a radial size H of the bearing in terms of thickness is equal in value to half of the difference between an outer diameter D and an inner diameter d of the bearing, that is, H=(D−d)/2. 8. The one-way snap-in cage according to claim 7 , wherein the ratio H b /H of the radial size H b of the backbone portion in terms of thickness to the radial size H of the bearing in terms of thickness further satisfies the relation 5.75%≤H b /H≤12.5%. 9. The one-way snap-in cage according to claim 8 , wherein the ratio H b /H of the radial size H b of the backbone portion in terms of thickness to the radial size H of the bearing in terms of thickness yet further satisfies the relation 6.25%≤H b /H≤10%. 10. The one-way snap-in cage according to claim 1 , wherein the backbone portion is partially integrated in the structure of the bottom portion of the pocket, and a laterally protruding part protrudes in an axial direction from the bottom portion of the pocket; or the backbone portion is completely integrated in the structure of the bottom portion of the pocket, and there is no laterally protruding part protruding in an axial direction from the bottom portion of the pocket. 11. The one-way snap-in cage according to claim 1 , wherein the pocket connection comprises a radial rib formed on a side of an axial free end of the hanging out portion and an axial rib formed between the backbone portion and the radial rib, wherein the axial rib comprises a converging portion, the diameter of which is less than that of the backbone portion, and a tail end of the converging portion extends outwards to form the radial rib; or the axial rib comprises a flaring portion, the diameter of which is greater than that of the backbone portion, and a tail end of the flaring portion converges inwards to form the radial rib. 12. A deep groove ball bearing, comprising: an inner ring, an outer ring, and at least one row of rolling elements disposed between the inner ring and the outer ring, wherein the one-way snap-in cage according to claim 1 is disposed on the at least one row of rolling elements. 13. A one-way snap-in cage for a deep groove ball bearing, comprising: an annular backbone portion, and a hanging out portion extending from the backbone portion towards an axial side, the hanging out portion comprising a pocket for accommodating a rolling element of the bearing in a circumferential direction and a pocket connection used to connect adjacent pockets, a bottom portion of the pocket being formed integrally with the backbone portion, and, at other positions in the circumferential direction, the backbone portion extending in an axial direction to form the pocket connection, wherein the ratio H c /H of a radial size H c of the cage in terms of thickness to a radial size H of the bearing in terms of thickness satisfies the relation 10.875%≤H c /H≤23%, wherein the radial size H c of the cage in terms of thickness is equal in value to half of the difference between the maximum outer diameter D c_max and the minimum inner diameter D c_min of the cage, that is, H c =(D c_max −D c_min )/2; and a radial size H of the bearing in terms of thickness is equal in value to half of the difference between an outer diameter D and an inner diameter d of the bearing, that is, H=(D−d)/2. 14. The one-way snap-in cage according to claim 13 , wherein the ratio H c /H of the radial size H c of the cage in terms of thickness to the radial size H of the bearing in terms of thickness further satisfies the relation 12.25%≤H c /H≤20.5%. 15. The one-way snap-in cage according to claim 14 , characterized in that: the ratio H c /H of the radial size H c of the cage in terms of thickness to the radial size H of the bearing in terms of thickness yet further satisfies the relation 16.125%≤H c /H≤19.125%. 16. A one-way snap-in cage for a deep groove ball bearing, comprising: an annular backbone portion, and a hanging out portion extending from the backbone portion towards an axial side, the hanging out portion comprising a pocket for accommodating a rolling element of the bearing in a circumferential direction and a pocket connection used to connect adjacent pockets, a bottom portion of the pocket being formed integrally with the backbone portion and, at other positions in the circumferential direction, the backbone portion extending in an axial direction to form the pocket connection, wherein the maximum