Pump assembly

What is claimed is: 1. A pump assembly comprising: a rotor axle extending along a rotor axis; an impeller fixed to the rotor axle; a pump housing accommodating the impeller; a drive motor comprising a stator and a rotor, wherein the rotor is fixed to the rotor axle for driving the impeller; a rotor can accommodating the rotor, wherein the rotor can comprises a rotor can flange; a stator housing accommodating the stator; and a bayonet ring, wherein the stator housing is secured to the pump housing by the bayonet ring and the bayonet ring is resiliently spring-loaded and axially biases the stator housing towards the impeller against the pump housing, the bayonet ring comprising circumferential first sections with a first radius and circumferential second sections with a second radius, the second radius being smaller than the first radius, the second sections being formed as radially inward projections cooperating with bayonet grooves in a radially outer surface of the stator housing, the first sections of the bayonet ring being secured in a circumferential groove of the pump housing. 2. The pump assembly according to claim 1 , wherein: the pump housing defines a first annular reference surface axially facing away from the impeller; the stator housing defines a second annular reference surface axially facing towards the impeller; and the second annular reference surface of the stator housing is axially biased against the first annular reference surface of the pump housing. 3. The pump assembly according to claim 2 , wherein the stator defines a second radial inner reference surface and the rotor can comprises a radial outer alignment surface that is aligned perpendicular to the first annular reference surface of the pump housing by radially abutting against the second radial inner reference surface of the stator. 4. The pump assembly according to claim 2 , wherein: the first annular reference surface is located radially more outward than a first radial inner reference surface; or the first annular reference surface is located axially further away from the impeller than a first radial inner reference surface; or the first annular reference surface is located radially more outward than a first radial inner reference surface and the first annular reference surface is located axially further away from the impeller than the first radial inner reference surface. 5. The pump assembly according to claim 3 , wherein: the second radial inner reference surface is located radially more inward than the second annular reference surface; or the second radial inner reference surface is located axially further away from the impeller than the second annular reference surface; or the second radial inner reference surface is located radially more inward than the second annular reference surface and the second radial inner reference surface is located axially further away from the impeller than the second annular reference surface. 6. The pump assembly according to claim 1 , wherein the bayonet ring is mainly a metallic component and the stator housing is mainly is a molded plastic component. 7. The pump assembly according to claim 1 , wherein: the bayonet ring is resiliently twistable around a bayonet ring circumferential direction between a first relaxed state and a second spring-loaded state; the first sections and the second sections have essentially a same axial distance to the impeller with the bayonet ring in the first relaxed state; and the first sections are axially closer to the impeller than the second sections with the bayonet ring in the second spring-loaded state. 8. The pump assembly according to claim 1 , wherein: each bayonet groove comprises a first section extending essentially parallel to the rotor axis and a second section; the second section has a first end at the first section and a second end circumferentially distanced from the first end; and the first end of the second section is located axially closer to the impeller than the second end of the second section. 9. The pump assembly according to claim 1 , further comprising: a first radial bearing ring in sliding contact with the rotor axle; a bearing retainer engaging the first radial bearing ring and centering the first radial bearing ring with respect to a first radial inner reference surface of the pump housing; and the rotor can flange has a radial distance to the pump housing and the rotor can comprises a radial inner centering surface centered by radially abutting against a radial outer centering surface of the bearing retainer. 10. The pump assembly according to claim 9 , wherein: the radial inner centering surface of the rotor can has at least three radial projections; or the radial outer centering surface of the bearing retainer has at least three radial projections; or the radial inner centering surface of the rotor can and the radial outer centering surface of the bearing retainer have at least three radial projections. 11. The pump assembly according to claim 1 , wherein the rotor can flange comprises an annular stop surface facing away from the impeller. 12. The pump assembly according to claim 11 , further comprising a locking ring secured in a circumferential groove of the pump housing, wherein the annular stop surface axially abuts against the locking ring. 13. The pump assembly according to claim 9 , wherein: the rotor can flange comprises an annular contact surface facing towards the impeller; and the bearing retainer comprises an annular biasing surface facing away from the impeller; the bearing retainer is resiliently spring-loaded and biases the annular biasing surface of the bearing retainer against the annular contact surface of the rotor can flange. 14. The pump assembly according to claim 13 , wherein: the annular contact surface of the rotor can flange has at least three axial projections; or the annular biasing surface of the bearing retainer has at least three axial projections; or the annular contact surface of the rotor can flange and the annular biasing surface of the bearing retainer have at least three axial projections.