Pump

The invention claimed is: 1. A pump comprising: a rotor shaft extending along a rotor axis; a bearing body circumferentially encompassing the rotor shaft and comprising a radially outer bearing surface; and a locking ring circumferentially encompassing the rotor shaft and limiting an axial movement of the bearing body relative to the rotor shaft, wherein the locking ring comprises at least two radially inwardly protruding teeth, wherein the locking ring is radially expandable from a locking state to a mounting state against an elastic restoring force of the locking ring, wherein the locking ring is, in the mounting state, positionable at a desired axial position on the rotor shaft, wherein the teeth are configured to press, in the locking state, against a radial outer surface of the rotor shaft by the elastic restoring force of the locking ring, wherein the pump is a single stage or multistage centrifugal pump for pumping a fluid, wherein the fluid to be pumped serves as a lubricant on the radially outer bearing surface of the bearing body. 2. The pump according to claim 1 , wherein the locking ring is a first axial stop and further comprising a second axial stop body. 3. The pump according to claim 2 , wherein an impeller nut encompassing the rotor shaft for fixing an impeller to the rotor shaft is the second axial stop body. 4. The pump according to claim 2 , wherein the second axial stop body defines N≥1 engagement location(s) for preventing a rotational movement of the bearing body relative to the rotor shaft, wherein the bearing body comprises a first axial end facing the locking ring and a second axial end facing away from the locking ring, wherein the second axial end comprises N≥1 engagement location(s) positive-locking with the engagement location(s) of the second axial stop body. 5. The pump according to claim 2 , wherein the second axial stop body and the second axial end of the bearing body comprise N≥2 engagement locations, wherein the engagement locations are arranged in an N-fold symmetry with respect to the rotor axis. 6. The pump according to claim 5 , wherein a first one of the engagement locations is configured for a positive-locking fit having a lower tolerance in tangential and/or axial direction than a second one of the engagement locations. 7. The pump according to claim 6 , wherein at least said first engagement location at the second axial stop body and/or the second axial end of the bearing body comprises a convex axial contact surface for providing an only axial contact between the bearing body and the second axial stop body. 8. The pump according to claim 1 , wherein the locking ring defines a circumferential gap between a first circumferential end portion of the locking ring and a second circumferential end portion of the locking ring, wherein the gap is smaller in the locking state than in the mounting state. 9. The pump according to claim 8 , wherein the locking ring comprises a security hook extending from the first circumferential end portion and overlapping the circumferential gap, wherein the security hook is configured to hook into the second circumferential end portion of the locking ring for preventing, in the mounting state, a further radial expansion of the locking ring. 10. The pump according to claim 1 , wherein the locking ring comprises a stress portion between a first circumferential end portion of the locking ring and a second circumferential end portion of the locking ring, wherein an annulus area of the locking ring has a reduction in size from the stress portion towards the first circumferential end portion and from the stress portion towards the second circumferential end portion. 11. The pump according to claim 10 , wherein the teeth are located at M≥2 locking ring segments with a central angle α of 30°≤α≤90°, wherein the locking ring segments are arranged symmetrically with respect to a symmetry plane spanned by the rotor axis and a direct virtual connecting line between a center of a circumferential gap and a center of the stress portion, and wherein the circumferential gap is preferably located centrally in one of the locking ring segments. 12. The pump according to claim 1 , wherein the locking ring defines an envelope of maximal radial expansion, wherein the envelope of maximal radial expansion is equal in size to or smaller than the radius of the radially outer bearing surface. 13. The pump according to claim 1 , wherein each of the teeth of the locking ring forms an inward blade extending along 15% or less of the circumference of the rotor shaft. 14. The pump according to claim 1 , wherein the locking ring comprises a first one of the teeth at a first circumferential end portion of the locking ring and a second one of the teeth at a second circumferential end portion of the locking ring, wherein the first tooth and the second tooth extend over an arc length with a central angle β of less than 20°. 15. The pump according to claim 14 , wherein the locking ring comprises a third one of the teeth and a fourth one of the teeth at a stress portion between the first circumferential end portion of the locking ring and the second circumferential end portion of the locking ring, wherein the third tooth and the fourth tooth each extend over an arc length with a central angle γ of less than 60°. 16. The pump according to claim 1 , wherein the locking ring is configured to be bathed in the fluid to be pumped so that the fluid provides an abrasive environment facilitating, in the locking state, an impressing of the teeth of the locking ring into the radial outer surface of the rotor shaft. 17. The pump according to claim 1 , wherein the teeth are harder than the radial outer surface of the rotor shaft.